Single-Phase Energy Measurement IC with 8052 MCU, RTC and LCD driver Preliminary Technical Data ADE7169F16 GENERAL FEATURES MICROPROCESSOR FEATURES Wide supply voltage operation 2.4 to 3.7V Battery supply input with Automatic switch-over Reference 1.2 V ± 1% (drift 50 ppm/°C Maximum) 64-Lead Quad Flat (LQFP) or Chip Scale (LCSP) Lead Free Packages Operating Temperature -40°C to 85°C 8052 based core Single-cycle 4MIPS 8052 core 8052 compatible instruction set 32.768 kHz external crystal with on-chip PLL Two external interrupt sources External reset pin Real Time Clock Counter for seconds, minutes and hours Automatic battery switchover for RTC back up Ultra-Low Battery Supply Current < 1μA Software clock calibration with temperature and offset compensation Integrated LCD driver 104-segment with 2, 3 or 4 Multiplexer 3V/5V driving capability Internally generated LCD drive voltages Temperature and Supply compensated drive voltages Low power battery mode Wake-up from I/O and UART LCD driver capability On-chip peripherals UART, SPI or I2C Watch-Dog timer Power Supply Monitoring with User Selectable Levels Memory: 16kBytes Flash Memory, 512 Bytes RAM Development tools Single pin emulation IDE based assembly and C source debugging ENERGY MEASUREMENT FEATURES High accuracy active, reactive energy measurement IC, supports IEC 62053-21, 62053-22, 62053-23 Two differential inputs with PGAs to support Shunt, Current Transformer and di/dt current sensors Selectable Digital integrator to support di/dt current sensor Digital parameters for Gain, offset and phase compensation Selectable No-load threshold level for Watt, VA, and VAR anti-creep Less than 0.1% error on active energy over a dynamic range of 1000 to 1 @ 25C Less than 0.5% error on reactive energy over a dynamic range of 1000 to 1 @ 25C Less than 0.5% error on rms measurements over a dynamic range of 1000 to 1 for current and 100:1 for voltage @ 25C Auto-calibration of offsets High frequency outputs supply proportional to Irms, active, reactive or apparent power Proprietary ADCs and DSP provide high accuracy over large variations in environmental conditions and time Temperature monitoring GENERAL DESCRIPTION The ADE7169F16 integrates Analog Devices Energy (ADE) Metering IC analog front end and fixed function DSP solution with an enhanced 8052 MCU core, a RTC, an LCD driver and all the peripherals to make an electronic energy meter with LCD display with a single part. The ADE Energy Measurement core includes Active, Reactive, Apparent Energy calculations, as well as voltage and current rms measurements. This information is ready to use for energy billing by using built-in energy scalars. Many power line supervisory features like SAG, Peak, Zero-crossing are also included in the energy measurement DSP to simplify energy meter design. The microprocessor functionality includes a single cycle 8052 core, a Real Time Clock with a power supply back-up pin, a UART, and a SPI or I2C interface. The ready to use information from the ADE core reduces the program memory size requirement thus making it easy to integrate complicated design in 16k Bytes of Flash memory. The ADE7169F16 also includes a 104-segment LCD driver. This driver generates voltages capable of driving 5V LCDs. Rev. PrD 09/06 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.326.8703 © 2006 Analog Devices, Inc. All rights reserved. ADE7169F16 Preliminary Technical Data 9 10 8 7 6 5 P1.0 (RxD) P1.1 (TxD) P1.2 (FP25) P1.3 (T2EX/FP24) P1.4 (T2/FP23) P1.5 (FP22) P1.6 (FP21) P1.7 (FP20) 36 37 39 38 40 41 42 43 P0.0 (BCTRL/INT1) P0.1 (FP19) P0.2 (CF1) P0.3 (CF2) P0.4 (MOSI/SDATA) P0.5 (MISO) P0.6 (SCLK/T0) P0.7 (SS/T1) 11 45 7 8 T0 T1 T2 T2EX 38 39 41 40 SS SCLK MISO MOSI/SDATA 39 CF1 CF2 43 42 38 REFIN/OUT 57 FUNCTIONAL BLOCK DIAGRAM 12 13 14 44 1.20V REF 19 16 52 IN 53 IPB 55 VP VN 49 DGND 63 3V/5V LCD CHARGE PUMP ENERGY ADC PGA1 17 15 MEASUREMENT 4 DSP 1 ADC PGA2 35 ... 50 18 ADC PGA1 .... IPA 20 14 12 11 DOWNLOADER DEBUGGER POWER SUPPLY CONTROL & MONITORING 1-PIN EMULATOR VSW ADC POR UART TIMER UART SERIAL PORT 8 7 RTC OSC 6 56 51 44 36 37 47 46 48 RESET EA SDEN TxD RxD XTAL1 XTAL2 INT0 INT1 5 59 LDO 9 PLL VINTA 61 VSWOUT 62 60 LDO 10 Figure 1. ADE7169F16 Functional Block Diagram Rev. PrD | Page 2 of 140 45 BATTERY ADC VDD 58 13 TEMP ADC VINTD TEMP SENSOR 64 VBAT 54 VDCIN AGND P2.0 (FP18) P2.1 (FP17) P2.2 (FP16) P2.3 (SDEN) LCDVP1 LCDVP2 LCDVA LCDVB LCDVC COM0 ... COM3 FP0 ... FP15 FP16 FP17 FP18 FP19 FP20 FP21 FP22 FP23 FP24 FP25 Preliminary Technical Data ADE7169F16 TABLE OF CONTENT FUNCTIONAL BLOCK DIAGRAM .............................................2 3.3V Peripherals and Wakeup Events.......................................32 Table of content .................................................................................3 Transitioning Between Operating Modes................................32 ADE7169F16—Specifications .........................................................7 Automatic Battery Switchover (PSM0 to PSM1)................32 Timing Specifications .....................................................................11 Entering Sleep Mode (PSM1 to PSM2)................................33 Absolute Maximum Ratings ..........................................................18 Servicing Wakeup Events (PSM2 to PSM1) ........................33 ESD Caution ................................................................................18 Automatic Switch to VDD (PSM2 to PSM0).........................33 Terminology.....................................................................................19 Automatic Switch to VDD (PSM1 to PSM0).........................33 Measurement Error.....................................................................19 Using the power management features ....................................33 Phase Error between Channels .................................................19 Energy Measurement......................................................................34 Power Supply Rejection..............................................................19 Access to energy measurement sfr............................................34 ADC Offset Error........................................................................19 Access to internal energy measurement registers...................34 Gain Error ....................................................................................19 Writing to Internal energy measurement registers ............34 Pin Descriptions ..............................................................................20 Reading Internal energy measurement registers ...............34 SFR Mapping....................................................................................22 Energy measurement REGISTERS...........................................35 Power Management ........................................................................23 Energy measurement internal registers details.......................37 Power management register details ..........................................23 Analog Inputs ..............................................................................41 Power Supply Architecture ........................................................25 Analog to Digital Conversion ...................................................42 Battery Switchover ......................................................................26 Anti-aliasing Filter..................................................................43 Switching from VDD to VBAT...................................................26 ADC Transfer Function .........................................................43 Switching from VBAT to VDD ...................................................26 Current Channel ADC...........................................................43 Power Supply Monitor Interrupt (PSM) ..................................26 Voltage Channel ADC............................................................44 Battery Switchover and Power Supply Restored PSM Interrupt ...................................................................................27 Channel Sampling...................................................................44 VSW Monitor PSM Interrupt ..................................................27 VBAT Monitor PSM Interrupt .................................................27 VDCIN Monitor PSM Interrupt................................................27 SAG Monitor PSM Interrupt.................................................28 Using the power supply features ...............................................28 Operating modes.............................................................................31 PSM0 (Normal mode) ................................................................31 PSM1 (Battery mode) .................................................................31 Fault Detection ............................................................................44 Channel selection Indication ................................................44 Fault Indication .......................................................................45 Fault with Active Input Greater than Inactive Input..........45 Fault with Inactive Input Greater than Active Input..........45 Calibration Concerns .............................................................45 di/dt Current Sensor and Digital Integrator............................45 Power quality measurements.....................................................47 Zero-Crossing Detection .......................................................47 PSM2 (Sleep mode) ....................................................................31 Rev. PrD | Page 3 of 140 ADE7169F16 Preliminary Technical Data Zero-Crossing Timeout......................................................... 47 Apparent Power Offset Calibration ..................................... 61 Period Measurement.............................................................. 47 Apparent Energy Calculation ............................................... 61 Line Voltage Sag Detection ................................................... 48 Integration Times under Steady Load................................. 62 Peak Detection........................................................................ 48 Apparent energy Pulse output .............................................. 62 Peak Level Record .................................................................. 49 Line Apparent Energy Accumulation.................................. 62 Phase Compensation.................................................................. 49 Apparent power no-Load detection .................................... 63 ADE7169F16 RMS Calculation................................................ 49 Energy-to-Frequency Conversion............................................ 63 Current Channel RMS Calculation...................................... 50 Pulse output configuration ................................................... 63 Current channel RMS Offset Compensation ..................... 50 Pulse output characteristic.................................................... 64 Voltage channel RMS Calculation ....................................... 51 Energy register scaling............................................................... 64 Voltage channel RMS Offset Compensation ...................... 51 Energy measurement interrupts............................................... 64 Active Power Calculation .......................................................... 51 Temperature, Battery and Supply Voltage Measurements ........ 66 Active power gain calibration............................................... 52 Temperature measurement ....................................................... 68 Active power offset calibration............................................. 52 Single Temperature Measurement ....................................... 68 Active power sign detection.................................................. 52 Background Temperature Measurements........................... 68 Active power no-Load detection.......................................... 52 Temperature ADC in PSM1 and PSM2 .............................. 68 Active Energy Calculation .................................................... 53 Temperature ADC interrupt................................................. 69 Integration time under steady Load .................................... 54 Battery measurement ................................................................. 69 Active energy accumulation modes..................................... 54 Single Battery Measurement................................................. 69 Active energy Pulse output ................................................... 55 Background Battery measurements..................................... 69 Line cycle active energy accumulation mode..................... 55 Battery ADC in PSM1 and PSM2 ........................................ 69 Reactive Power Calculation ...................................................... 56 Battery ADC interrupt .......................................................... 69 Reactive power gain calibration ........................................... 57 Supply Voltage Measurement ................................................... 69 Reactive power offset calibration ......................................... 57 Single Supply voltage Measurement .................................... 70 Sign of Reactive Power Calculation ..................................... 57 Background Supply Voltage Measurements ....................... 70 Reactive power sign detection .............................................. 57 Supply voltage ADC in PSM1 and PSM2 ........................... 70 Reactive power no-Load detection ...................................... 58 Supply voltage ADC interrupt.............................................. 70 Reactive Energy Calculation................................................. 58 8052 MCU CORE Architecture.................................................... 71 Integration time under steady Load .................................... 59 MCU registers............................................................................. 71 Reactive energy accumulation modes ................................. 59 Basic 8052 Registers ................................................................... 72 Reactive energy Pulse output................................................ 60 Standard 8052 SFRs.................................................................... 73 Line cycle reactive energy accumulation mode ................. 60 Memory Overview ..................................................................... 74 Apparent Power Calculation..................................................... 60 Addressing Modes...................................................................... 75 Rev. PrD | Page 4 of 140 Preliminary Technical Data ADE7169F16 Instruction set..............................................................................76 Flash memory organization.......................................................96 Read-Modify-Write Instructions ..............................................79 Using the Flash Memory............................................................97 Instructions that Affect Flags ....................................................79 ECON—Flash/EE Memory Control SFR ............................97 Interrupt System ..............................................................................82 Flash functions ......................................................................100 Standard 8051 Interrupt Architecture......................................82 Protecting the Flash..............................................................100 ADE7169F16 Interrupt Architecture .......................................82 Flash memory timing ...........................................................102 Interrupt SFR register list...........................................................82 In circuit programming............................................................102 Interrupt Priority.........................................................................84 Serial Downloading ..............................................................102 Interrupt Flags .............................................................................84 Timers.............................................................................................103 Interrupt Vectors .........................................................................87 Timer sfr register list ................................................................103 Watch DOG Functionality.........................................................87 Timer 0 and Timer 1.................................................................106 Watchdog Timer Interrupt ....................................................87 Timer/Counter 0 and 1 Data Registers ..............................106 Context Saving.............................................................................87 Timer/Counter 0 and 1 Operating Modes ........................106 LCD Driver ......................................................................................88 Timer 2 .......................................................................................107 LCD SFR Register list .................................................................88 Timer/Counter 2 Data Registers.........................................107 LCD Setup ....................................................................................92 Timer/Counter 2 Operating Modes ...................................107 LCD Timing and Waveforms ....................................................92 PLL ..................................................................................................109 BLINK mode................................................................................93 PLL SFR register list..................................................................109 Software Controlled Blink Mode ..........................................93 RTC - Real Time Clock ................................................................111 Automatic Blink Mode ...........................................................93 RTC SFR register list.................................................................111 Display Element Control............................................................93 Read and Write operations ......................................................114 Writing to LCD Data registers ..............................................93 Writing the RTC Registers...................................................114 Reading LCD Data registers ..................................................93 Reading the RTC Counter SFRs .........................................114 Voltage generation.......................................................................93 RTC Modes ................................................................................114 Power Consumption...............................................................94 RTC Interrupts ..........................................................................114 Contrast control ......................................................................94 Interval Timer Alarm ...........................................................114 Lifetime Performance.............................................................94 RTC CalibrationRTC................................................................114 LCD External Circuitry..............................................................94 UART serial interface ...................................................................116 LCD Function in PSM2..............................................................94 UART SFR register list..............................................................116 Example LCD Setup....................................................................95 UART operation modes ...........................................................119 Flash memory ..................................................................................96 Mode 0 (Shift Register with baud rate fixed at Fcore /12) .................................................................................................119 Flash memory Overview............................................................96 Flash/EE Memory Reliability ................................................96 Mode 1 (8-Bit UART, Variable Baud Rate)........................119 Rev. PrD | Page 5 of 140 ADE7169F16 Preliminary Technical Data Mode 2 (9- bit UART with baud fixed at Fcore/64 or Fcore/32) ................................................................................................. 119 Mode 3 (9-Bit UART with Variable Baud Rate)............... 120 UART Baud Rate Generation.................................................. 120 Mode 0 Baud Rate Generation ........................................... 120 Mode 2 Baud Rate Generation ........................................... 120 Modes 1 and 3 Baud Rate Generation ............................... 120 Timer 1 Generated Baud Rates........................................... 120 Timer 2 Generated Baud Rates........................................... 120 UART Timer Generated Baud Rates.................................. 121 UART additional features........................................................ 122 Enhanced Error Checking................................................... 122 UART TxD signal modulation ........................................... 122 Serial Peripheral Interface Interface (SPI)................................. 123 SPI SFR register list .................................................................. 123 SPI pins ...................................................................................... 126 MISO (Master In, Slave Out Data I/O Pin) ...................... 126 MOSI (Master Out, Slave In Pin)....................................... 126 SCLK (Serial Clock I/O Pin)............................................... 126 SS (Slave Select Pin) ............................................................. 126 SPI Master Operating Modes.................................................. 126 SPI Interrupt and Status Flags ................................................ 127 I2C COMPATIBLE INTERFACE ............................................... 129 Serial Clock Generation .......................................................... 129 Slave addresses.......................................................................... 129 I2C SFR register list.................................................................. 129 Read and Write Operations .................................................... 130 I2C Receive and Transmit FIFOs ........................................... 131 Dual Data Pointers ....................................................................... 132 I/O Ports ........................................................................................ 134 Parallel I/O ................................................................................ 134 Weak Internal Pullups Enabled.......................................... 134 Open Drain (Weak Internal Pullups Disabled) ............... 134 38 kHz Modulation .............................................................. 134 I/O SFR register list.................................................................. 135 Port 0.......................................................................................... 137 Port 1.......................................................................................... 138 Port 2.......................................................................................... 138 Outline Dimensions ..................................................................... 139 Ordering Guide............................................................................. 140 Rev. PrD | Page 6 of 140 ADE7169F16 Preliminary Technical Data ADE7169F16—SPECIFICATIONS Table 1. (VDD = 3.3 V ± 5%, AGND = DGND = 0 V, On-Chip Reference, XTAL = 32.768kHz, TMIN to TMAX = –40°C to +85°C) Parameter ENERGY METERING MEASUREMENT ACCURACY1 Phase Error between Channels (PF = 0.8 Capacitive) (PF = 0.5 Inductive) Active Energy Measurement Error2 Min Typ Max Unit Test Conditions/Comments ±0.05 ±0.05 0.1 ° ° % of reading Phase lead 37° Phase lag 60° Over a dynamic range of 1000 to 1 @25C AC Power Supply Rejection2 Output Frequency Variation DC Power Supply Rejection2 Output Frequency Variation Active Energy Measurement Bandwidth1, 2 Reactive Energy Measurement Error2 0.01 % 0.01 14 0.5 VRMS Measurement Error2 0.5 VRMS Measurement Bandwidth1, 2 IRMS Measurement Error2 14 0.5 IRMS Measurement Bandwidth1, 2 ANALOG INPUTS Maximum Signal Levels Input Impedance (DC) Bandwidth (–3 dB)1 ADC Offset Error2 Gain Error2 Current channel Range = 0.5 V Full scale Range = 0.25 V Full scale Range = 0.125 V Full scale Voltage channel Gain Error Match2 CF1 and CF2 pulse output Maximum output frequency Duty cycle Active High pulse width FAULT Detection Fault Detection Threshold Inactive Input <> Active Input 14 % kHz % of reading % of reading kHz % of reading kHz ±500 TBD 14 1 mV peak kΩ kHz mV VDD = 3.3 V + 100 mV rms/120 Hz IP = VP = ±100 mV rms VDD = 3.3 V ± 117 mV dc IP = VP = ±100 mV rms Over a dynamic range of 1000 to 1 @25C Over a dynamic range of 100 to 1 @25C Over a dynamic range of 1000 to 1 @25C VP – VN, IA – IN and IB – IN Differential input ±4 ±4 ±4 ±4 ±3 % % % % % Current channel = 0.5V dc Current channel = 0.25V dc Current channel = 0.125V dc Voltage channel = 0.5V dc 21.1 50 90 kHz % ms VP-VN = IAP-IN=500mV peak sine wave If CF1 or CF2 frequency > 5.55Hz If CF1 or CF2 frequency < 5.55Hz 6.25 %, of larger IA or IB active Input Swap Threshold Inactive Input <> Active Input 6.25 % of larger IA or IB active Accuracy Fault Mode Operation IA Active, IB = AGND 0.1 % of reading % of reading Seconds Seconds Over a dynamic range of 500 to 1 IB Active, IA = AGND Fault Detection Delay Swap Delay ANALOG PERIPHERALS 0.1 3 3 Rev. PrD | Page 7 of 140 Over a dynamic range of 500 to 1 ADE7169F16 Parameter Internal ADCs (Battery, Temperature, VDD) Power supply operating range No missing codes1 AC Power Supply Rejection DC Power Supply Rejection Integral Linearity Error Differential Linearity Error Conversion Delay4 Temperature sensor accuracy VDCIN ANALOG INPUT Maximum Signal Levels Input Impedance (DC) Low VDCIN detection threshold Power-On Reset (POR) VDD POR Voltage operating range Detection threshold POR active Time-out period Strobe period in Battery operation VSWOUT POR Voltage operating range (VSWOUT) Detection threshold POR active Time-out period VINTA and VINTD POR Voltage operating range (VSWOUT) Detection threshold POR active Time-out period BATTERY SWITCH OVER Voltage operating range (VSWOUT) VDD Î VBAT switching threshold (VSWOUT) VDD Î VBAT switching delay VBAT Î VDD switching threshold (VDD) VBAT Î VDD switching delay VSWOUT to VBAT leakage current LCD – Charge pump active LCDVP1 – LCDVP2 charge pump capacitance LCDVA, LCDVB, LCDVC decoupling capacitance LCDVA LCDVB LCDVB LCDVC LCD stand-by current V1 Segment line voltage V2 Segment line voltage V3 Segment line voltage DC voltage across Segment and COM pin Preliminary Technical Data Min Typ 2.2 8 Max Unit Test Conditions/Comments 3.7 V bits dB dB LSB3 LSB ms °C °C Measured on VSWOUT TBD TBD -1 -1 1 1 1 -1 -4 1 4 0 1.08 VSWOUT 1 1.2 1.32 1 1.6 1 1.8 V V ms Ms 3.7 2.2 V V ms 3.7 2.4 V V ms 3.7 TBD V V ms V ms nA TBD 1 2.25 TBD 2.4 2.75 TBD 2.75 V MΩ V 3.7 2.9 TBD TBD TBD TBD 1 200 nF 470 nF 0 0 0 0 1.7 4.0 3.4 5.1 100 LCDVA-0.1 LCDVA LCDVB-0.1 LCDVB LCDVC-0.1 LCDVC 50 LCD – Resistor ladder active Rev. PrD | Page 8 of 140 at 25°C between -40°C and 85°C V V V V nA V V V mV 1/2 bias modes 1/3 bias modes 1/3 bias mode 1/2 and 1/3 bias modes Current on segment line = -2μA Current on segment line = -2μA Current on segment line = -2μA LCDVC-LCDVB, LCDVC-LCDVA or LCDVBLCDVA Preliminary Technical Data Parameter Leakage current V1 Segment line voltage V2 Segment line voltage V3 Segment line voltage ON-CHIP REFERENCE Reference Error Power supply rejection Temperature Coefficient DIGITAL INTERFACE LOGIC INPUTS All inputs except XTAL1, XTAL2, BCTRL, INT0, INT1, RESET Input High Voltage, VINH Input Low Voltage, VINL BCTRL, INT0, INT1, RESET Input High Voltage, VINH Input Low Voltage, VINL Input currents RESET ADE7169F16 Min Typ LCDVA-0.1V LCDVB-0.1V LCDVC-0.1V ±12 LOGIC OUTPUTS Output High Voltage, VOH ISOURCE Output Low Voltage, VOL ISINK Floating state Leakage current Floating state Output Capacitance STARTUP TIME5 At Power-On From Power Saving Mode 2 (PSM2) From Power Saving Mode 1 (PSM1) POWER SUPPLY INPUTS VDD VBAT POWER SUPPLY OUTPUTS VBAT to VSWOUT ON-Resistance VDD to VSWOUT ON-Resistance VSWOUT output current drive VINTA, VINTD 50 0.4 V V 0.4 V V 2.0 1.3 ±10 -250 μA μA μA μA -50 μA ±10 100 10 30 32 32.768 12 12 4.096 32 50 33.5 2.4 2.25 kΩ kHz pF pF MHz kHz Crystal = 32.768kHz and CD[2:0]=0 Crystal = 32.768kHz and CD[2:0]=0b111 TBD TBD TBD ms μs μs 3.6 3.7 V V 25 6.1 1 2.75 Ω Ω mA V Rev. PrD | Page 9 of 140 Current on segment line = -2μA Current on segment line = -2μA Current on segment line = -2μA pF TBD 3.3 3.3 Test Conditions/Comments 1/2 and 1/3 bias modes – No load RESET = 0V RESET = VSWOUT = 3.3V Internal pull-up disabled, input – 0V or VOUT Internal pull-up enabled, input = 2V, VSWOUT=3.3V Internal pull-up enabled, input = 0.4V, VSWOUT=3.3V All digital input V μA V mA μA pF 80 0.4 2 ±10 3.0 2.4 Unit nA V V V mV dB ppm/°C 80 Port 0, 1 , 2 Input capacitance CRYSTAL OSCILLATOR Crystal Equivalent Series Resistance Crystal frequency XTAL1 Input Capacitance XTAL2 Output Capacitance MCU CLOCK RATE - Fcore Max ±20 LCDVA LCDVB LCDVC VDD = 3.3 V ± 5% VDD = 3.3 V ± 5% VBAT = 2.4V VDD = 3V ADE7169F16 Parameter VINTA power supply rejection VINTD power supply rejection POWER SUPPLY CURRENTS Current in Normal Mode (PSM0) Current in Normal Mode (PSM0) Current in PSM1 with VINTA disabled Current in PSM2 Preliminary Technical Data Min Typ 80 60 Max 3.5 2.1 880 1.5 1 Unit dB dB Test Conditions/Comments mA mA μA μA Fcore = 4.096 MHz Fcore = 1.024 MHz Fcore = 1.024 MHz These numbers are not production tested but are guaranteed by design and/or characterization data on production release See Terminology section for explanation of specifications. 3 LSB means Least Significant Bit 4 Delay between ADC conversion request and interrupt set 5 Delay between power supply valid and execution of first instruction by 8052 core 2 Rev. PrD | Page 10 of 140 Preliminary Technical Data ADE7169F16 TIMING SPECIFICATIONS AC inputs during testing are driven at VSWOUT – 0.5 V for Logic 1 and 0.45 V for Logic 0. Timing measurements are made at VIH min for Logic 1 and VIL max for Logic 0 as shown in Figure 2. For timing purposes, a port pin is no longer floating when a 100 mV change from load voltage occurs. A port pin begins to float when a 100 mV change from the loaded VOH/VOL level occurs as shown in Figure 2. CLOAD for all outputs = 80 pF, unless otherwise noted. VDD = 2.7 V to 3.6 V; all specifications TMIN to TMAX, unless otherwise noted. Table 2. CLOCK INPUT (External Clock Driven XTAL1) Parameter 32.768 kHz External Crystal Typ Max 30.52 6.26 6.26 9 9 TBD 4.096 Min tCK tCKL tCKH tCKR tCKF 1/tCORE TBD Unit μs μs μs ns ns MHz ADE7129F16 internal PLL locks onto a multiple (512 times) of the 32.768 kHz external crystal frequency to provide a stable 12.58 MHz internal clock for the system. The core can operate at this frequency or at a binary submultiple called Core_Clk, selected via the PLLCON SFR. DVDD – 0.5V 0.45V 0.2DVDD + 0.9V TEST POINTS 0.2DVDD – 0.1V VLOAD – 0.1V VLOAD VLOAD + 0.1V TIMING REFERENCE POINTS Figure 2. Timing Waveform Characteristics Rev. PrD | Page 11 of 140 VLOAD – 0.1V VLOAD VLOAD – 0.1V 04741-0-077 1 XTAL1 Period XTAL1 Width Low XTAL1 Width High XTAL1 Rise Time XTAL1 Fall Time Core Clock Frequency1 ADE7169F16 Preliminary Technical Data Table 3. I2C COMPATIBLE INTERFACE TIMING Parameter Parameter tL tH tSHD tDSU tDHD tRSU tPSU tBUF tR tF tSUP1 Min 1.95 1.95 TBD TBD SCLOCK Low Pulse Width SCLOCK High Pulse Width Start Condition Hold Time Data Setup Time Data Hold Time Setup Time for Repeated Start Stop Condition Setup Time Bus Free Time between a Stop Condition and a Start Condition Rise Time of Both SCLOCK and SDATA Fall Time of Both SCLOCK and SDATA Pulse Width of Spike Suppressed Max Unit μs μs μs μs μs μs μs μs ns ns ns TBD TBD TBD TBD 300 300 50 ____________________________________________ Input filtering on both the SCLOCK and SDATA inputs suppresses noise spikes less than 50 ns. tBUF tSUP SDATA (I/O) MSB tDSU tPSU LSB MSB tDSU 2-7 8 tL tF tDHD tR tRSU tH 1 PS ACK tDHD tSHD SCLK (I) tR 9 tSUP STOP START CONDITION CONDITION 1 S(R) REPEATED START Figure 3. I2C Compatible Interface Timing Rev. PrD | Page 12 of 140 tF 04741-0-080 1 Preliminary Technical Data ADE7169F16 Table 4. SPI MASTER MODE TIMING (CPHA = 1) Parameter tSL tSH tDAV tDSU tDHD tDF tDR tSR tSF Min 977 977 SCLOCK Low Pulse Width1 SCLOCK High Pulse Width1 Data Output Valid after SCLOCK Edge Data Input Setup Time before SCLOCK Edge Data Input Hold Time after SCLOCK Edge Data Output Fall Time Data Output Rise Time SCLOCK Rise Time SCLOCK Fall Time Typ Max TBD TBD TBD 10 10 10 10 25 25 25 25 ____________________________________________ Characterized under the following conditions: a. Core clock divider bits CD2, CD1, and CD0 in POWCON SFR set to 0, 0, and 0, respectively, that is, core clock frequency = 4.096/8 MHz. b. SPI bit-rate selection bits SPIR1 and SPR0 in SPI2CMOD SFR set to 0 and 0, respectively. SCLOCK (CPOL = 0) tSH tSL tSR SCLOCK (CPOL = 1) tDAV tDF tSF tDR MOSI MSB MISO MSB IN tDSU BITS 6–1 BITS 6–1 tDHD Figure 4. SPI Master Mode Timing (CPHA = 1) Rev. PrD | Page 13 of 140 LSB LSB IN 04741-0-081 1 Unit ns ns ns ns ns ns ns ns ns ADE7169F16 Preliminary Technical Data Table 5. SPI MASTER MODE TIMING (CPHA = 0) Parameter tSL tSH tDAV tDOSU tDSU tDHD tDF tDR tSR tSF Min 977 977 SCLOCK Low Pulse Width1 SCLOCK High Pulse Width1 Data Output Valid after SCLOCK Edge Data Output Setup before SCLOCK Edge Data Input Setup Time before SCLOCK Edge Data Input Hold Time after SCLOCK Edge Data Output Fall Time Data Output Rise Time SCLOCK Rise Time SCLOCK Fall Time Typ Max TBD TBD TBD TBD 10 10 10 10 25 25 25 25 1 Characterized under the following conditions: a. Core clock divider bits CD2, CD1, and CD0 in POWCON SFR set to 0, 0, and 0, respectively, that is, core clock frequency = 4.096/8 MHz. b. SPI bit-rate selection bits SPIR1 and SPR0 in SPI2CMOD SFR set to 0 and 0, respectively. SCLOCK (CPOL = 0) tSH tSL tSF tSR SCLOCK (CPOL = 1) tDAV tDOSU tDF tDR MOSI MISO MSB IN tDSU LSB BITS 6–1 BITS 6–1 LSB IN 04741-0-082 MSB tDHD Figure 5. SPI Master Mode Timing (CPHA = 0) Rev. PrD | Page 14 of 140 Unit ns ns ns ns ns ns ns ns ns ns Preliminary Technical Data ADE7169F16 Table 6. SPI SLAVE MODE TIMING (CPHA = 1) Parameter tSS tSL tSH tDAV tDSU tDHD tDF tDR tSR tSF tDIS SS to SCLOCK Edge SCLOCK Low Pulse Width SCLOCK High Pulse Width Data Output Valid after SCLOCK Edge Data Input Setup Time before SCLOCK Edge Data Input Hold Time after SCLOCK Edge Data Output Fall Time Data Output Rise Time SCLOCK Rise Time SCLOCK Fall Time MISO disable after SS rising edge tSFS SS High after SCLOCK Edge Min 0 977 977 Typ Max TBD Unit ns ns ns ns ns ns ns ns ns ns ns 0 ns TBD TBD TBD 10 10 10 10 25 25 25 25 1 SS tSFS tSS SCLOCK (CPOL = 0) tSH tSL tSR tSF SCLOCK (CPOL = 1) tDIS tDAV tDF MISO MOSI MSB BITS 6–1 BITS 6–1 MSB IN tDSU tDR tDHD Figure 6. SPI Slave Mode Timing (CPHA = 1) Rev. PrD | Page 15 of 140 LSB LSB IN ADE7169F16 Preliminary Technical Data Table 7. SPI SLAVE MODE TIMING (CPHA = 0) Parameter tSS tSL tSH tDAV tDSU tDHD tDF tDR tSR tSF tDOSS tDIS SS to SCLOCK Edge SCLOCK Low Pulse Width SCLOCK High Pulse Width Data Output Valid after SCLOCK Edge Data Input Setup Time before SCLOCK Edge Data Input Hold Time after SCLOCK Edge Data Output Fall Time Data Output Rise Time SCLOCK Rise Time SCLOCK Fall Time Data Output Valid after SS Edge MISO disable after SS rising edge tSFS SS High after SCLOCK Edge Min 0 977 977 Typ Max TBD Unit ns ns ns ns ns ns ns ns ns ns ns ns 0 ns TBD TBD TBD 10 10 10 10 25 25 25 25 20 SS tSFS tSS SCLOCK (CPOL = 0) tSH tSL tSR tSF SCLOCK (CPOL = 1) tDAV tDOSS tDF MISO MOSI MSB MSB IN tDSU tDIS tDR LSB BITS 6–1 BITS 6–1 LSB IN tDHD Figure 7. SPI Slave Mode Timing (CPHA = 0) Rev. PrD | Page 16 of 140 Preliminary Technical Data ADE7169F16 Table 8. UART Timing (Shift Register Mode) Parameter Serial Port Clock Cycle Time Output Data Setup to Clock Input Data Setup to Clock Input Data Hold after Clock Output Data Hold after Clock Min Variable Core_Clk Typ Max 12tcore tXLXL TxD (OUTPUT CLOCK) SET RI OR SET TI tQVXH tXHQX RxD (OUTPUT DATA) LSB BIT 1 BIT 6 tDVXH RxD (INPUT DATA) tXHDX LSB BIT 1 BIT 6 04741-0-086 TXLXL TQVXH TDVXH TXHDX TXHQX 4.09612.58 MHz Core_Clk Min Typ Max 2.93 TBD TBD TBD TBD MSB Figure 8. UART Timing in Shift Register Mode CS t1 t13 t9 SCLK DIN 0 0 A5 A4 A3 A2 A1 t10 A0 DB7 COMMAND BYTE t12 t11 t11 DOUT DB0 MOST SIGNIFICANT BYTE DB7 DB0 LEAST SIGNIFICANT BYTE 02875-0-083 Rev. PrD | Page 17 of 140 Unit μs μs μs μs μs ADE7169F16 Preliminary Technical Data ABSOLUTE MAXIMUM RATINGS TA = 25°C, unless otherwise noted. Table 9. Parameter VDD to DGND VBAT to DGND VDCIN to DGND Input LCD voltage to AGND LCDVA, LCDVB, LCDVC1 Analog Input Voltage to AGND VP, VN, IAP, IBPN and IN Digital Input Voltage to DGND Digital Output Voltage to DGND Operating Temperature Range Industrial Storage Temperature Range Junction Temperature 64-Lead LQFP, Power Dissipation θJA Thermal Impedance Lead Temperature, Soldering Vapor Phase (TBD sec) Infrared (TBD sec) 64-Lead CSP, Power Dissipation θJA Thermal Impedance Lead Temperature, Soldering Vapor Phase (TBD sec) Infrared (TBD sec) 1 Rating –0.3 V to +3.7 V –0.3 V to +3.7 V –0.3 V to VSWOUT + 0.3 V –0.3 V to VSWOUT + 0.3 V –2 V to +2 V Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. –0.3 V to VSWOUT + 0.3 V –0.3 V to VSWOUT + 0.3 V –40°C to +85°C –65°C to +150°C TBD°C TBD TBD°C/W TBD°C TBD°C TBD TBD°C/W TBD°C TBD°C When used with external resistor divider ESD CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although this product features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. Rev. PrD | Page 18 of 140 Preliminary Technical Data ADE7169F16 TERMINOLOGY MEASUREMENT ERROR The error associated with the energy measurement made by the ADE7169F16 is defined by the following formula: ⎛ Energy Re gister − True Energy ⎞ ⎟⎟ × 100% Percentage Error = ⎜⎜ True Energy ⎝ ⎠ PHASE ERROR BETWEEN CHANNELS The digital integrator and the high-pass filter (HPF) in the current channel have a non-ideal phase response. To offset this phase response and equalize the phase response between channels, two phase-correction networks are placed in the current channel: one for the digital integrator and the other for the HPF. The phase correction networks correct the phase response of the corresponding component and ensure a phase match between current channel and voltage channel to within ±0.1° over a range of 45 Hz to 65 Hz with the digital integrator off. With the digital integrator on, the phase is corrected to within ±0.4° over a range of 45 Hz to 65 Hz. POWER SUPPLY REJECTION This quantifies the ADE7169F16 measurement error as a percentage of reading when the power supplies are varied. For the ac PSR measurement, a reading at nominal supplies (3.3 V) is taken. A second reading is obtained with the same input signal levels when an ac (100 mV rms/120 Hz) signal is introduced onto the supplies. Any error introduced by this ac signal is expressed as a percentage of reading—see the Measurement Error definition. For the dc PSR measurement, a reading at nominal supplies (3.3 V) is taken. A second reading is obtained with the same input signal levels when the supplies are varied ±5%. Any error introduced is again expressed as a percentage of the reading. ADC OFFSET ERROR The dc offset associated with the analog inputs to the ADCs. It means that with the analog inputs connected to AGND, the ADCs still see a dc analog input signal. The magnitude of the offset depends on the gain and input range selection—see the Typical Performance Characteristics section. However, when HPF1 is switched on, the offset is removed from the current channel and the power calculation is not affected by this offset. The offsets can be removed by performing an offset calibration—see the Analog Inputs section. GAIN ERROR The difference between the measured ADC output code (minus the offset) and the ideal output code—see the Current Channel ADC and Voltage Channel ADC sections. It is measured for each of the input ranges on the current channel (0.5 V, 0.25 V, and 0.125 V). The difference is expressed as a percentage of the ideal code. Rev. PrD | Page 19 of 140 ADE7169F16 Preliminary Technical Data PIN DESCRIPTIONS Table 10. Pin Function Descriptions Pin No. Mnemonic Description 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 COM3/ FP27 COM2/ FP28 COM1 COM0 P1.2/FP25 P1.3/T2EX/FP24 P1.4/T2/FP23 P1.5/FP22 P1.6/FP21 P1.7/FP20 P0.1/FP19 P2.0/FP18 P2.1/FP17 P2.2/FP16 LCDVC LCDVP2 17, 18 19 LCDVB, LCDVA LCDVP1 35-20 36 37 38 FP0-15 P1.1/TxD P1.0/RxD P0.7 /SS/T1 Common output, COM3 is used for LCD backplane / LCD segment outputs 27 Common output, COM2 is used for LCD backplane / LCD segment outputs 28 Common output, COM1 is used for LCD backplanes Common output, COM0 is used for LCD backplanes General-purpose digital I/O / LCD segment outputs 25 General-purpose digital I/O / Timer 2 control input / LCD segment outputs 24 General-purpose digital I/O / Timer 2 input / LCD segment outputs 23 General-purpose digital I/O / LCD segment outputs 22 General-purpose digital I/O / LCD segment outputs 21 General-purpose digital I/O / LCD segment outputs 20 General-purpose digital I/O / LCD segment outputs 19 General-purpose digital I/O / LCD segment outputs 18 General-purpose digital I/O / LCD segment outputs 17 General-purpose digital I/O / LCD segment outputs 16 Output port for LCD levels. This pin should be decoupled with a 470nF capacitor. This pin is an analog output. A capacitor of 470nF should be connected between this pin and LCDVP1 for internal LCD charge pump device. Output ports for LCD levels. These pins should be decoupled with a 470nF capacitor. This pin is an analog output. A capacitor of 470nF should be connected between this pin and LCDVP2for internal LCD charge pump device. LCD segment outputs 0-15 General-purpose digital I/O / Transmitter Data Output 1 (Asynchronous) General-purpose digital I/O / Receiver Data Input 1 (Asynchronous) General-purpose digital I/O / Slave select when SPI is in Slave mode / Timer 1 input 39 40 41 42 P0.6/SCLK/T0 P0.5/MISO P0.4/MOSI/SDATA P0.3/CF2 43 P0.2/CF1 44 SDEN/P2.3 45 BCTRL/INT1/ P0.0 46 XTAL2 47 XTAL1 48 INT0 49, 50 VP, VN General-purpose digital I/O / Clock output for I2C or SPI port / Timer 0 input General-purpose digital I/O / Data In for SPI port General-purpose digital I/O / Data Line I2C compatible or Data Out for SPI port General-purpose digital I/O / Calibration Frequency Logic Output. The CF2 logic output gives instantaneous active, reactive or apparent power information. General-purpose digital I/O / Calibration Frequency Logic Output. The CF1 logic output gives instantaneous active, reactive or apparent power information. This pin is used to enable serial download mode when pulled low through a resistor on power-up or reset. On reset this pin will momentarily become an input and the status of the pin is sampled. If there is no pulldown resistor in place, the pin will go momentarilly high and then user code will execute. If a pull-down resistor is in place, the embedded serial download/debug kernel will execute and this pin remains low during internal program execution. This pin can also be used as a general purpose output. Digital Input for Battery control. This logic input connects VDD or VBAT to VSW internally when set to logic High or Low respectively. When left open, the connection between VDD or VBAT to VSW is selected internally / External Interrupt input / General-purpose digital I/O A crystal can be connected across this pin andXTAL1 as described above to provide a clock source for the ADE7169F16.The XTAL2 pin can drive one CMOS load when an external clock is supplied at XTAL1 or by the gate oscillator circuit. An external clock can be provided at this logic input. Alternatively, a parallel resonant AT crystal can be connected across XTAL1 and XTAL2 to provide a clock source for the ADE7169F16.The clock frequency for specified operation is 32.768 kHz. General-purpose digital I/O / Interrupt input Analog Inputs for Voltage Channel. These inputs are fully differential voltage inputs with a maximum differential level of ±500mV for specified operation. This channel also has an internal PGA. Rev. PrD | Page 20 of 140 Preliminary Technical Data ADE7169F16 Pin No. Mnemonic Description 51 EA 52, 53 IP, IN 54 55 AGND IPB 56 RESET This pin is used as an input for emulation. When held high, this input enables the device to fetch code from internal program memory locations.The ADE7169F16 does not support external code memory. This pin should not be left floating. Analog Inputs for Current Channel. These inputs are fully differential voltage inputs with a maximum differential level of ±500mV for specified operation. This channel also has an internal PGA. This pin provides the ground reference for the analog circuitry Analog Inputs for second Current Channel. This input is fully differential with a maximum differential level of ±500mVrefered to IN for specified operation. This channel also has an internal PGA. Reset input, Active low 57 REFIN/OUT 58 VBAT 59 VINTA 60 VDD 61 VSWOUT 62 VINTD 63 64 DGND VDCIN This pin provides access to the on-chip voltage reference. The on-chip reference has a nominal value of 1.2 V ± 8% and a typical temperature coefficient of 50 ppm/°C maximum 3.3V Power supply input from Battery. This pin is connected internally to VDD when the Battery is selected as the power supply for the ADE7169F16. This pin provides access to the on-chip 2.5V analog LDO. No external active circuitry should be connected to this pin. This pin should be decoupled with a 10μF capacitor in parallel with a ceramic 100nF capacitor. 3.3V Power supply input from regulator. This pin is connected internally to VDD when the regulator is selected as the power supply for the ADE7169F16. This pin should be decoupled with a 10μF capacitor in parallel with a ceramic 100nF capacitor. 3.3V Power supply output from ADE7169F16. This pin provides the supply voltage for the LDOs and internal cicuitry of the ADE7169F16. This pin should be decoupled with a 10μF capacitor in parallel with a ceramic 100nF capacitor. This pin provides access to the on-chip 2.5V digital LDO. No external active circuitry should be connected to this pin. This pin should be decoupled with a 10μF capacitor in parallel with a ceramic 100nF capacitor. This pin provides the ground reference for the digital circuitry Analog input for dc voltage monitoring. The maximum input voltage on this pin is xxxmV with respect to AGND. This pin is used to monitor the pre-regulated dc voltage. Rev. PrD | Page 21 of 140 ADE7169F16 Preliminary Technical Data SFR MAPPING IPSMF xF8 Table 13 STRBPER xF9 BATVTH Table 45 xFA Table 48 B xF3 SPIMOD1 I2CMOD Table 124 Table 129 SPIMOD2 I2CADR Table 125 xE9 Table 53 MIRQENL xD9 Table 38 xDA VRMSL xD1 xC0 Table 65 Table 63 Table 26 xD2 xB9 Table 140 Table 116 P1 x90 Table 139 Table 95 Table 138 SCRATCH4 xFE Table 20 xFF Table 12 RTCCOMP TEMPCAL xF7 Table 114 LCDSEGE2 xED INTPR xF6 Table 113 VSWADC Table 81 xEF MIRQENH xDB Table 40 WAV1H xE4 MIRQSTL xDC VRMSH xD3 Table 26 Table 26 Table 35 IRMSL xD4 Table 26 WAV2L xE5 Table 26 MIRQSTM xDD Table 36 xD5 Table 26 RCAP2H TL2 TH2 xCC Table 102 xCD Table 101 xC5 xBA Table 85 PINMAP0 xB2 Table 135 xBB Table 86 PINMAP1 xB3 Table 136 EDATA xBC Table 87 Table 21 PROTB0 xBD Table 88 Table 49 xDE Table 37 IRMSH xD6 Table 26 EADRL xC6 Table 91 PROTB1 xBE Table 89 xAC xAE Table 80 MIN HOUR INTVAL xA1 Table 107 xA2 Table 108 xA3 Table 109 xA4 Table 110 xA5 Table 111 xA6 Table 112 SPI2CTx x9A MADDPT x91 MDATL Table 26 x92 TMOD x89 Table 26 SPI2CRx x9B x8A SP x82 Table 26 LCDCONX x9C x8B Table 100 Table 72 MDATH x94 TL1 Table 98 DPL Table 57 Table 123 MDATM x93 TL0 Table 94 x81 Table 122 BATADC xDF xD7 x83 Table 26 TH0 x8C Table 97 Table 56 Mnemonic WDCON xC0 Table 65 Address Link to detailed table Table 51 EADRH xC7 Table 92 PROTR xBF Table 90 SBAUDF SBAUDT x9D Table 119 x9E Table 118 LCDCON x95 Table 71 LCDCLK x96 Table 75 CFG xAF Rev. PrD | Page 22 of 140 Table 58 DPCON xA7 Table 132 EPCFG x9F Table 134 LCDSEGE x97 Table 78 TH1 x8D Table 99 DPH Table 55 Table 50 TEMPADC LCDDAT Table 79 SEC SBUF Table 26 Table 137 HTHSEC x99 Table 117 WAV2H xE7 PINMAP2 xB4 LCDPTR Table 64 Table 26 MIRQSTH IRMSM xCB Table 103 PROTKY WAV2M xE6 TIMECON P0 x80 Table 26 IEIP2 TCON x88 Table 26 FLSHKY Table 74 xA9 SCON x98 Table 14 POWCON Table 84 MAPKEY xA0 BATPR xF5 RCAP2L ECON IE P2 Table 19 xCA Table 104 LCDCONY Table 62 Table 16 KYREG xB1 xA8 Table 15 xC1 Table 106 IP xB8 Table 39 WAV1M xE3 VRMSM Table 96 WDCON Table 26 MIRQENM T2CON xC8 xFD PERIPH xF4 xEC WAV1L PSW xD0 Table 18 IPSME xEA Table 126 xE2 Table 47 Table 46 xFC SCRATCH3 Table 130 xE0 ADCGO Table 17 SCRATCH2 SPI2CSTAT ACC xD8 xFB DIFFPROG xF0 xE8 SCRATCH1 PCON x87 Table 54 ADE7169F16 Preliminary Technical Data POWER MANAGEMENT Table 11. Power Management SFRs The ADE7169F16 has an elaborate power management circuitry that manages the regular power supply to Battery switch over and power supply failures. The power management functionalities can be accessed directly through the 8052 SFR – see Table 11. SFR address (hex) R/W Name Description 0xEC R/W IPSME Power Management Interrupt enable 0xF5 R/W BATPR Battery Switchover configuration 0xF8 R/W IPSMF Power Management Interrupt Flag 0xFF R/W INTPR Interrupt Wake-up Configuration POWER MANAGEMENT REGISTER DETAILS Table 12. Interrupt pins configuration SFR (INTPR, 0xFF) Bit Location 7 Bit Mnemonic RTCCAL Default Value 0 6-4 3-1 Reserved INT1PRG[2:0] 000 Description Control RTC calibration output When set uncalibrated clock at 1 Hz is output on CF1 pin. Controls the function of INT1T INT1PRG[2:0] x 0 0 0 INT0PRG 0 Function GPIO x 0 0 1 1 x BCTRL INT1 input disabled 1 1 x INT1 input enabled Controls the function of INT0 INT0PRG 0 Function INT0 input disabled 1 INT0 input enabled Table 13. Power Management Interrupt Flag SFR (IPSMF, 0xF8) Bit Location 7 Bit Addr. 0xFF Bit Name FPSR Default Value 0 6 0xFE FPSM 0 5 0xFD FSAG 0 4 3 0xFC 0xFB RESERVED FVSW 0 0 2 0xFA FBAT 0 1 0xF9 FBSO 0 Description Power Supply Restored Interrupt flag. Set when the VDD power supply has been restored. This occurs when the source of VSW changes from VBAT to VDD. PSM Interrupt flag. Set when an enabled PSM interrupt condition occurs. Voltage SAG Interrupt flag. Set when an ADE energy measurement SAG condition occurs. This bit must be kept cleared for proper operation VSW Monitor interrupt flag. Set when VSW changes by VSWDIF or when VSW measurement is ready. VBAT Monitor interrupt flag. Set when VBAT falls below BATVTH or when the VBAT measurement is ready. Battery Switchover interrupt flag. Rev. PrD | Page 23 of 140 ADE7169F16 0 0xF8 Preliminary Technical Data FVDC Set when VSW switches from VDD to VBAT. VDCIN Monitor interrupt flag. Set when VDCIN falls below 1.2V. 0 Table 14. Battery Switchover Configuration SFR (BATPR, 0xF5) Bit Location 7-2 1-0 Bit Mnemonic Reserved BATPRG [1:0] Default Value 00 00 Description These bits must be kept to 0 for proper operation Control bits for Battery Switchover. BATPRG [1:0] 0 0 0 1 1 X Function Battery Swichover Enabled on Low VDD Battery Swichover Enabled on Low VDD and Low VDCIN Battery Switchover Disabled Table 15. Peripheral Configuration SFR (PERIPH, 0xF4) Bit Location 7 6 Bit Mnemonic RXFLAG VSWSOURCE Default Value 0 1 Description 5 VDD_OK 1 If set, indicates that a RX Edge event triggered wakeup from PSM2 Indicates the power supply that is connected internally to VSW. 0 VSW=VBAT 1 VSW=VDD If set, indicates that VDD power supply is ok for operation 4 PLL_FLT 0 If set, indicates that PLL is not locked 3 REF_BAT_EN 0 2 1-0 Reserved RXPROG[1:0] 0 00 If set, Internal voltage reference enabled in PSM2 mode. This bit should be set if LCD On in PSM2 mode. This bit should be kept to zero Controls the function of the P1.0/RX pin. RXPROG [1:0] Function 0 0 GPIO 0 1 RX with wakeup disabled 1 1 RX with wakeup enabled Table 16. Power Management Interrupt Enable SFR (IPSME, 0xEC) Bit Location 7 6 5 4 3 2 1 0 Bit Mnemonic EPSR ADEIAUTCLR ESAG RESERVED EVSW EBAT EBSO EVDCIN Default Value 0 0 0 0 0 0 0 0 Description Enables a PSM interrupt when the Power Supply Restored flag is set. If set, the ADE interrupt status registers MIRQSTH/M/L registers will be read with reset. Enables a PSM interrupt when the voltage sag flag (FSAG) is set. This bit must be kept cleared for proper operation Enables a PSM interrupt when the VSW monitor flag (FVSW) is set. Enables a PSM interrupt when the VBAT monitor flag (FBAT) is set. Enables a PSM interrupt when the Battery Switchover flag (FBSO) is set. Enables a PSM interrupt when the VDCIN monitor flag (FVDCIN) is set. Table 17. Scratch Pad 1 SFR (SCRATCH1, 0xFB) Bit Location 7-0 Bit Mnemonic SCRATCH1 Default Value 0 Description Value can be written/read in this register. This value will be maintained in all the power saving modes of the ADE7169F16 Rev. PrD | Page 24 of 140 Preliminary Technical Data ADE7169F16 Table 18. Scratch Pad 2 SFR (SCRATCH2, 0xFC) Bit Location 7-0 Bit Mnemonic SCRATCH2 Default Value 0 Description Value can be written/read in this register. This value will be maintained in all the power saving modes of the ADE7169F16 Table 19. Scratch Pad 3 SFR (SCRATCH3, 0xFD) Bit Location 7-0 Bit Mnemonic SCRATCH3 Default Value 0 Description Value can be written/read in this register. This value will be maintained in all the power saving modes of the ADE7169F16 Table 20. Scratch Pad 4 SFR (SCRATCH4, 0xFE) Bit Location 7-0 Bit Mnemonic SCRATCH4 Default Value 0 Description Value can be written/read in this register. This value will be maintained in all the power saving modes of the ADE7169F16 Table 21. Power Control SFR (POWCON, 0xC5) Bit Location 7-5 Bit Mnemonic RESERVED Default Value 0 Description 4 COREOFF 0 Set this bit to shut down the core if in the PSM1 operating mode. 3 2-0 RESERVED CD[2:0] 010 Controls the core clock frequency, Fcore. Fcore=4.096MHz/2CD CD[2:0] Fcore (MHz) 0 0 0 4.096 0 0 1 2.048 0 1 0 1.024 0 1 1 0.512 1 0 0 0.256 1 0 1 0.128 1 1 0 0.064 1 1 1 0.032 Note: Writing data to the POWCON SFR involves a double instruction sequence. Global interrupts must first be disabled to ensure that the two instructions occur consecutively. The KYREG SFR is set to 0xA7 and immediately followed by a write to the POWCON SFR. For example: CLR EA ;Disable Interrupts while configuring to WDT MOV KYREG,#0A7h ;Write KYREG to 0xA7 to get write access to the POWCON SFR MOV POWCON, #10H ;Shutdown the core NOP NOP POWER SUPPLY ARCHITECTURE ADE7169F16 has two power supply inputs, VDD and VBAT, and requires only a single 3.3V power supply at VDD for full operation. A battery backup, or secondary power supply, with a maximum of 3.6V can be connected to the VBAT input. Internally, the ADE7169F16 connects VDD or VBAT to VSW, which is used to derive the power for the ADE7169F16 circuitry. The Rev. PrD | Page 25 of 140 ADE7169F16 Preliminary Technical Data VSWOUT output pin reflects the voltage at VSW, and has a maximum output current of TBD mA. This pin may also be used to power a limited number of peripheral components. The 2.5V analog supply, VINTA and the 2.5V supply for the core logic, VINTD, are derived by on-chip linear regulators from VSW. Figure 9 shows the power supply architecture of ADE7169F16. The ADE7169F16 provides automatic battery switchover between VDD and VBAT based on the voltage level detected at VDD or VDCIN. Additionally, the BCTRL input can also be used to trigger a battery switchover. The conditions for switching VSW from VDD to VBAT and back to VDD are described in the Battery Switchover section. VDCIN is an input pin that can be connected to a 0V to 3.3V DC signal. This input is intended for power supply supervisory purposes and does not provide power to the ADE7169F16 circuitry - see Battery Switchover section. V DCIN V DD V BAT VSWOUT ADC LDO BCTRL POWER SUPPLY MANAGEMENT VSW LDO V INTD MCU V INTA ADE LCD TEMPERATURE ADC Switching from VDD to VBAT There are three events that can be enabled to switch the internal power supply, VSW, from VDD to VBAT: 1. (VDCIN < 1.2 V): When VDCIN falls below 1.2V VSW switches from VDD to VBAT. This event is enabled when the BATTPROG[1:0] bits in the Battery Switchover Configuration SFR (BATPR, 0xF5) are clear. Setting this bit will disable switchover based on VDCIN. Battery switchover on low VDCIN is disabled by default. 2. (VDD < TBD V): When VDD falls below TBD V VSW switches from VDD to VBAT. This event is enabled when BATTPROG[1] in the Battery Switchover Configuration SFR (BATPR, 0xF5) is cleared. 3. Rising edge on BCTRL: When the battery control pin, BCTRL, goes high, VSW switches from VDD to VBAT. This external switchover signal can trigger a switchover to VBAT at any time. Setting bits INT1PRG[4:2] to 0bx01 in the Interrupt pins configuration SFR (INTPR, 0xFF) enables the battery control pin. SPI/I2C ADC SCRATCHPAD power supply is restored - see the Power Supply Monitor Interrupt (PSM) section. RTC UART 3.3V 2.5V Switching from VBAT to VDD To switch VSW back from VBAT to VDD all of the events that are enabled to force battery switchover must be false: Figure 9: Power Supply Architecture BATTERY SWITCHOVER ADE7169F16 monitors VDD, VBAT, and VDCIN. Automatic battery switchover from VDD to VBAT can be configured based on the status of VDD, VDCIN, or the BCTRL pin. Battery switchover is enabled by default. Setting bit 1 in the Battery Switchover Configuration SFR (BATPR, 0xF5), disables battery switchover so that VDD is always connected to VSW. The source of VSW is indicated by bit 6 in the Peripheral Configuration SFR (PERIPH, 0xF4), which is set when VSW is connected to VDD and cleared when VSW is connected to VBAT. The battery switchover functionality provided by the ADE7169F16 allows a seamless transition from VDD to VBAT. An automatic battery switchover option ensures a stable power supply to the ADE7169F16, as long as the external battery voltage is above TBD V. It allows continuous code execution even while the internal power supply is switching from VDD to VBAT and back. Note that the energy metering ADCs are not available when VBAT is being used for VSW. 1. (VDCIN < 1.2 V) and (VDD < TBD V) Enabled: If the low VDCIN condition is enabled, VSW switches to VDD after VDCIN remains above TBD V for TBD seconds and VDD remains above TBD V for TBD seconds. 2. (VDD < TBD V) Enabled: VSW switches back to VDD after VDD has been above TBD V for TBD seconds. 3. BCTRL Enabled: VSW switches back to VDD after BCTRL is low and number 1 or number 2 are satisfied. POWER SUPPLY MONITOR INTERRUPT (PSM) The Power Supply Monitor Interrupt (PSM) alerts the 8052 core of power supply events. The PSM interrupt is disabled by default. Setting the EPSM bit in the Interrupt Enable and Priority 2 SFR (IEIP2, 0xA9) enables the PSM interrupt. The Power Management Interrupt Enable SFR (IPSME, 0xEC) controls the events that result in a PSM interrupt. Figure 10 is a diagram illustrating how the PSM interrupt vector is shared among the PSM interrupt sources. The PSM interrupt flags are latched and must be cleared by writing to the flag register. Power supply monitor (PSM) interrupts can be enabled to indicate when battery switchover occurs and when the VDD Rev. PrD | Page 26 of 140 Preliminary Technical Data ADE7169F16 EPSR FPSR ESAG FSAG EVSW FVSW FPSM TRUE? EPSM Pending PSM interrupt EBAT FBAT EBSO FBSO EVDCIN FVDCIN IPSME Addr. 0ECh EPSR ADEAUTOCLR ESAG IPSMF Addr. 0F8h FPSR FPSM FSAG IEIP2 Addr. 0A9h reserved PTI reserved reserved reserved PSI EVSW EBAT EBSO EVDCIN FVSW FBAT FBSO FVDCIN EADE ETI EPSM ESI : Not involved in PSM Interrupt signal chain Figure 10: PSM Interrupt Sources Battery Switchover and Power Supply Restored PSM Interrupt The ADE7169F16 can be configured to generate a PSM interrupt when the source of VSW changes from VDD to VBAT, indicating battery switchover. Setting the EBSO bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC) enables this event to generate a PSM interrupt. The ADE7169F16 can also be configured to generate an interrupt when the source of VSW changes from VBAT to VDD, indicating that the VDD power supply has been restored. This event is enabled to generate a PSM interrupt by setting the EPSR bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC). The flags in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) for these interrupts, BSOF and PSRF are set regardless of whether the respective enable bits have been set. The battery switchover and power supply restore event flags, BSOF and PSRF, are latched. These events must be cleared by writing a zero to these bits. Bit 6 in the Peripheral Configuration SFR (PERIPH, 0xF4), VSWSOURCE, tracks the source of VSW. The bit is set when VSW is connected to VDD and cleared when VSW is connected to VBAT. VSW Monitor PSM Interrupt The ADE7169F16 can be configured to generate a PSM interrupt when VSW changes magnitude by more than a configurable threshold. This threshold is set in the Temperature and Supply Delta SFR (DIFFPROG, 0xF3) –see Supply Voltage Measurement section. Setting the EVSW bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC) enables this event to generate a PSM interrupt. The VSW voltage is measured using a dedicated ADC. These measurements take place in the background at intervals to check the change in VSW. Conversions can also be initiated by writing to the Start ADC Measurement SFR (ADCGO, 0xD8). The EVSW flag will indicate that a VSW measurement is ready. See the Supply Voltage Measurement section for details on how VSW is measured. VBAT Monitor PSM Interrupt The VBAT voltage is measured using a dedicated ADC. These measurements take place in the background at intervals to check the change in VBAT. The BATTF bit is set when the battery level is lower than the threshold set in the Battery detection threshold SFR (BATVTH, 0xFA) or when a new measurement is ready in the Battery ADC value SFR (BATADC, 0xDF) - see Battery measurement section. Setting the EBATT bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC) enables this event to generate a PSM interrupt. VDCIN Monitor PSM Interrupt The VDCIN voltage is monitored by a comparator. The FVDC bit in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) is set when the VDCIN input level is lower than 1.2 V. Setting the EVDCIN bit in the Power Management Interrupt Enable SFR Rev. PrD | Page 27 of 140 ADE7169F16 Preliminary Technical Data (IPSME, 0xEC) enables this event to generate a PSM interrupt. This event associated with the SAG monitoring can be used to detect a power supply - VDD - being compromised and trigger further actions prior to decide a switch of VDD to VBAT . Setting the ESAG bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC) enables this event to generate a PSM interrupt. USING THE POWER SUPPLY FEATURES SAG Monitor PSM Interrupt The ADE7169F16 energy measurement DSP monitors the ac voltage input at the VP and VN input pins. The SAGLVL register is used to set the threshold for a line voltage sag event. The SAGF bit in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) is set if the line voltage stays below the level set in the SAGLVL register for the number of line cycles set in the SAGCYC register, - see Line Voltage Sag Detection section. (240, 220, 110V typical) ac input BCTRL VP VN 5 - 12V dc PSU In an energy meter application, VDD, the 3.3V power supply, is typically generated from the ac line voltage and regulated to 3.3V by a voltage regulator IC. The pre-regulated DC voltage, typically 5V to 12V, can be connected to VDCIN through a resistor divider. A 3.6V battery can be connected to VBAT. Figure 11 shows how the ADE7169F16 power supply inputs would be set up in this application. SAG Detection VDCIN 3.3V Regulator Voltage Supervisory Voltage Supervisory VDD IPSMF SFR (Addr. 0xF8) Power Supply Management VSW VSWOUT VBAT Figure 11. Power Supply Management for Energy Meter Application Figure 12 shows the sequence of events that will be generated for the power meter application in Figure 11 if the main power supply generated by the PSU starts to fail. The sag detection can provide the earliest warning of a potential problem on VDD. When a sag event occurs, the user code can be configured to backup data and prepare for battery switchover if desired. The relative spacing of these interrupts will depend on the design of the power supply. Figure 13 shows the sequence of events that will be generated for the power meter application shown in Figure 11 if the main power supply starts to fail, with battery switchover on low VDCIN or low VDD enabled. Rev. PrD | Page 28 of 140 Preliminary Technical Data ADE7169F16 VP -VN SAG LEVEL trip point SAGCYC=1 VDCIN 1.2V VDD t1 2.75V t2 SAG Event (FSAG=1) If switchover on low VDD is enabled, Automatic Battery switchover VSW connected to VBAT VDCIN Event (FVDC=1) BSO Event (FBSO=1) Figure 12: Power Supply Management Interrupts and Battery Switchover with only VDD enabled for battery switchover VP -VN SAG LEVEL trip point SAGCYC=1 VDCIN 1.2V t1 VDD 2.75V SAG Event (FSAG=1) t3 VDCIN Event (FVDC=1) If switchover on low VDCIN is enabled, Automatic Battery switchover VSW connected to V BAT BSO Event (FBSO=1) Figure 13: Power Supply Management Interrupts and Battery Switchover with VDD or VDCIN enabled for battery switchover Time Comment t1 TBD Time between when VDCIN goes below 1.2 V and when VSWF is raised. t2 TBD Time between when VDD falls below TBD V and when battery switchover occurs. t3 TBD Time between when VDCIN falls below 1.2 V and when battery switchover occurs, if VDCIN is enabled to cause battery switchover. VDCIN_OPT[1:0] in the Battery Switchover Configuration SFR (BATPR, 0xF5) sets this timeout Table 22: Power Supply Event Timings Operating Modes Rev. PrD | Page 29 of 140 ADE7169F16 Preliminary Technical Data Finally, the transition between VDD and VBAT and the different Power Supply Modes (see Operating modessection) is represented in Figure 15. VP -VN SAG LEVEL Trip point VDCIN SAG EVENT VDCIN EVENT VDCIN EVENT 1.2V 30ms min. 30ms min. VBAT VDD 2.75V VSW Battery switch enabled on low VDCIN VSW Battery switch enabled on low VDD PSM0 PSM0 PSM1 or PSM2 PSM0 PSM0 PSM1 or PSM2 Figure 14: Power Supply Management transitions between modes Rev. PrD | Page 30 of 140 ADE7169F16 Preliminary Technical Data Table 23. SFR maintained in PSM2 OPERATING MODES I/O configuration PSM0 (NORMAL MODE) In PSM0, normal operating mode, VSW is connected to VDD. All of the analog and digital circuitries powered by VINTD and VINTA are enabled by default. The default clock frequency for PSM0, Fcore, established during a power-on-reset or software reset, is TBD MHz. PSM1 (BATTERY MODE) In PSM1, VSW is connected to VBAT. In this operating mode, the 8052 core and all of the digital circuitry are enabled by default. The analog circuitry for the ADE energy metering DSP powered by VINTA is disabled. This analog circuitry will automatically start up again once the VDD supply is above TBD V if the PWRDN bit in the MODE1 register (0x0B) is cleared. The default Fcore for PSM1, established during a power-on-reset or software reset, is 1.024 MHz. PSM2 (SLEEP MODE) PSM2 is a low power consumption sleep mode for use in battery operation. In this mode, VSW is connected to VBAT. All of the 2.5V digital and analog circuitry powered through VINTA and VINTD is disabled, including the MCU core, resulting in the following: Power Supply monitoring Interrupt pins configuration SFR Battery detection threshold SFR (INTPR, 0xFF) (BATVTH, 0xFA) Peripheral Configuration SFR (PERIPH, 0xF4) Battery Switchover Configuration SFR (BATPR, 0xF5) Port 0 Weak pull-up enable SFR (PINMAP0, 0xB2) Battery ADC value SFR (BATADC, 0xDF) Port 1 Weak pull-up enable SFR (PINMAP1, 0xB3) Peripheral ADC Strobe Period SFR (STRBPER, 0xF9) Port 2 Weak pull-up enable SFR (PINMAP2, 0xB4) Temperature and Supply Delta SFR (DIFFPROG, 0xF3) Scratch Pad 1 SFR (SCRATCH1, 0xFB) VSW ADC value SFR (VSWADC, 0xEF) Scratch Pad 2 SFR (SCRATCH2, 0xFC) Temperature ADC value SFR (TEMPADC, 0xD7) Scratch Pad 3 SFR (SCRATCH3, 0xFD) Scratch Pad 4 SFR (SCRATCH4, 0xFE) 1. The RAM in the MCU is no longer valid. 2. The program counter for the 8052, also held in volatile memory, becomes invalid when the 2.5V supply is shut down. Therefore, the program will not resume from where it left off but will always start from the power on reset vector when the ADE7169F16 comes out of PSM2. The 3.3V peripherals Temperature ADC, VBAT ADC, VSW ADC, RTC and LCD are active in PSM2. They can be enabled or disabled to reduce power consumption and are configured for PSM2 operation when the MCU core is active—see the individual peripherals for more information on their PSM2 configuration. The ADE7169F16 remains in PSM2 until an event occurs to wake it up. In PSM2, the ADE7169F16 provides 4 scratch pad RAM SFR that are maintained during this mode. These SFRs can be used to save data from PSM0 or PSM1 modes when entering PSM2 modes - see Table 16 to Table 20. In PSM2, the ADE7169F16 maintains some SFRs – see Table 23. The SFRs that are not listed in this table should be restored when the part enters PSM0 or PSM1 frm PSM2 mode. Peripherals – RTC Peripherals - LCD RTC Nominal Compensation SFR (RTCCOMP, 0xF6) LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) RTC Temperature LCD Configuration Y SFR Compensation SFR (TEMPCAL, (LCDCONY, 0xB1) 0xF7) LCD Configuration X SFR RTC Configuration SFR (LCDCONX, 0x9C) (TIMECON, 0xA1) LCD Configuration SFR Hundredths of a Second (LCDCON, 0x95) Counter SFR (HTHSEC, 0xA2) LCD Clock SFR (LCDCLK, 0x96) Seconds Counter SFR (SEC, 0xA3) LCD Segment Enable SFR Minutes Counter SFR (MIN, (LCDSEGE, 0x97) 0xA4) Hours Counter SFR (HOUR, 0xA5) Alarm Interval SFR (INTVAL, 0xA6) Rev. PrD | Page 31 of 140 ADE7169F16 Preliminary Technical Data ADE7169F16 to wake from PSM2 are listed in the Wakeup Events column in Table 24. 3.3V PERIPHERALS AND WAKEUP EVENTS Some of the 3.3V peripherals are capable of waking the ADE7169F16 from PSM2. The events that can cause the Table 24. 3.3V Peripherals and Wakeup Events 3.3V Peripheral Wakeup Event Temperature ADC ΔT VSW ADC Power Supply Management RTC I/O Ports External Reset Wakeup Enable Bits Maskable Flag Interrupt Vector - Comments ITADC The temperature ADC can wake-up the 8052 if the ITADC flag is set . This flag is set according to the description in the Temperature measurement section. This wakeup event can be disabled by disabling temperature measurements in the Temperature and Supply Delta SFR (DIFFPROG, 0xF3) in PSM2. Maskable VSWF IPSM The VSW measurement can wake-up the 8052. The ΔV VSWF is set according to the description in the Supply Voltage Measurement section. This wakeup event can be disabled by clearing the EVSW in the Power Management Interrupt Enable SFR (IPSME, 0xEC). PSR PSR IPSM NonThe 8052 will wake up if the power supply is maskable restored (if VSW switches to be connected to VDD). The VSWSOURCE flag, bit 6 of the Peripheral Configuration SFR (PERIPH, 0xF4) SFR, is set to indicate that VSW is connected to VDD. This is a nonmaskable wakeup event. Midnight Midnight IRTC NonThe ADE7169F16 will wake up at midnight every maskable day to update its calendar. This event is a nonmaskable wakeup event. Alarm Maskable Alarm IRTC Set an alarm to wake the ADE7169F16 after the desired amount of time. The RTC Alarm is enabled by setting the alarm bit in the RTC Configuration SFR (TIMECON, 0xA1). All I/O pins are treated as inputs. The weak pull-up on each I/O pin can be disabled individually in the Port 0 Weak pullup enable SFR (PINMAP0, 0xB2), Port 1 Weak pull-up enable SFR (PINMAP1, 0xB3) and Port 2 Weak pull-up enable SFR (PINMAP2, 0xB4) to decrease current consumption. The interrupts can be enabled/disabled. INT0PROG IE0 The edge of the interrupt is selected by TCON.IT0 INT0 =1 The IE0 flag bit in the TCON register will not be affected. IE1 The edge of the interrupt is selected by TCON.IT1 INT1 INT1PROG [2:0 ]= 11X The IE1 flag bit in the TCON register will not be affected. RX Edge RXPROG [1:0] PERIPH.7 An RX Edge event will occur if a rising or falling edge is = 11 detected on the RX line (RXFG) RESET LCD - Scratchpad - Nonmaskable - - - - - - - If the RESET pin is brought low while the ADE7169F16 is in PSM2, it will wake up to PSM1. The LCD can be enabled/disabled in PSM2. The LCD data memory will remain intact. The 4 SCRATCHx registers will remain intact in PSM2. TRANSITIONING BETWEEN OPERATING MODES Automatic Battery Switchover (PSM0 to PSM1) The operating mode of the ADE7169F16 is determined by the power supply connected to VSW. Therefore a change in the power supply such as when VSW switches from VDD to VBAT or when VSW switches to VDD changes the operating mode. This section describes events that change the operating mode. If any of the enabled battery switchover events occur (see the Battery Switchover section), VSW switches to VBAT. This switchover results in a transition from the PSM0 to PSM1 operating mode. When battery switchover occurs, the analog circuitry used in the ADE energy measurement DSP is disabled. Rev. PrD | Page 32 of 140 Preliminary Technical Data ADE7169F16 reset vector. To reduce power consumption, the user code can initiate a transition to PSM2. USING THE POWER MANAGEMENT FEATURES Entering Sleep Mode (PSM1 to PSM2) To reduce power consumption when VSW is connected to VBAT, user code can initiate sleep mode, PSM2, by setting bit 4 in the Power Control SFR (POWCON, 0xC5) to shut down the MCU core. Events capable of waking the MCU can be enabled—see the 3.3V Peripherals and Wakeup Events section. Servicing Wakeup Events (PSM2 to PSM1) The ADE7169F16 may need to wake up from PSM2 to service wakeup events – see the 3.3V Peripherals and Wakeup Events section. PSM1 code execution will begin at the power on reset vector. After servicing the wakeup event, the ADE7169F16 can return to PSM2 by setting bit 4 in the Power Control SFR (POWCON, 0xC5) to shut down the MCU core. Since program flow is different for each operating mode, the status of VSW must be known at all times. The VSWFLAG bit in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) indicates what VSW is connected to. This bit can be used to control program flow on wakeup. Since code execution always starts at the power on reset vector, bit 6 of the Peripheral Configuration SFR (PERIPH, 0xF4) can be tested to determine which power supply is being used and to branch to normal code execution or to wakeup event code execution. Power supply events can also occur when the MCU core is active. To be aware of events that change what VSW is connected to: ¾ Enable the battery switchover interrupt (EVSW) if VSW=VDD at power up. Automatic Switch to VDD (PSM2 to PSM0) ¾ If the conditions to switch VSW from VBAT to VDD occur (see the Battery Switchover section), the operating mode will switch to PSM0. When this switch occurs, the MCU core and the analog circuitry used in the ADE energy measurement DSP will start up again automatically. PSM0 code execution will begin at the power on reset vector. Enable the power supply restored interrupt (EPSR) if VSW=VBAT at power up. An early warning that battery switchover is about to occur is provided by SAG detection and possibly low VDCIN detection— see the Battery Switchover section. Automatic Switch to VDD (PSM1 to PSM0) If the conditions to switch VSW from VBAT to VDD occur (see the Battery Switchover section), the operating mode will switch to PSM0. When this switch occurs, the analog circuitry used in the ADE energy measurement DSP will start up automatically. Note that code execution will continue normally. A software reset can be performed to start PSM0 code execution at the power on For a user controlled battery switchover, enable automatic battery switchover on low VDD only. Then enable the low VDCIN event to generate the PSM interrupt. When a low VDCIN event occurs, start data backup. Upon completion of the data backup, enable battery switchover on low VDCIN. Then battery switchover will occur TBDms later. Power Supply Restored PSM0 PSM1 Normal Mode VSW connected to VDD Automatic Battery Switchover Battery Mode VSW connected to VBAT Wakeup Event Power Supply Restored User code directs MCU to shutdown core after servicing wakeup event PSM2 Sleep Mode VSW connected to VBAT Figure 15: Transitioning between Operating Modes Rev. PrD | Page 33 of 140 Preliminary Technical Data ADE7169F16 ENERGY MEASUREMENT The ADE7169F16 provides a fixed function energy measurement Digital Processing core that provides all the information needed to measure energy in a single phase energy meters. The ADE7169F16 provides two ways to access the energy measurements: Direct access through SFR for time sensitive information and indirect access through address and data SFR registers for the majority of the energy measurements. The IRMS, VRMS, interrupts and waveform registers are readily available through SFRs as shown in Table 25. Other energy measurement information is mapped to a page of memory that is accessed indirectly through. The address and data registers act as pointers to the energy measurement internal registers. ACCESS TO ENERGY MEASUREMENT SFR Access to the energy measurement SFRs is achieved by reading or writing to the SFR addresses detailed in Table 26. The internal data for the MIRQx SFRs are latched byte by byte into the SFR when the SFR is read. The WAV1x, WAV2x, VRMSx and IRMSx registers are all 3 bytes SFRs. The 24-bit data is latched into these SFRs when the High byte is read. Reading the Low or Medium byte before the High byte results in reading the date from the previous latched sample. Sample 8051 code to read the VRMS register is shown below: MOV MOV MOV ACCESS TO INTERNAL ENERGY MEASUREMENT REGISTERS Access to the internal energy measurement registers is achieved by writing to the Energy Measurement pointer address (SFR address 91h). The MADDPT register selects the energy measurement register to be accessed and determines if a read or a write is performed—see Table 25. Table 25. Energy Measurement pointer address SFR (MADDPT, 0x91) 5 4 3 2 Bit 7 Description 1: Write Energy Measurement internal 0: Read register address Writing to Internal energy measurement registers 1 The energy measurement core functions with an internal clock of 4.096 MHz/5 or 819.2 kHz. As the 8052 core functions with another clock, 4.096MHz / 2CD, synchronization between the two clock environments when CD = 0 or 1 is an issue. When data is written to the internal energy measurement a small wait period need to be implemented before another read or write to these registers is implemented. Sample 8051 code to write 0x0155 to the two bytes SAGLVL register, located at 14h in the energy measurement memory space is shown below: MOV MOV MOV MOV DJNZ MDATM,#01h MDATL,#55h MADDPT,#SAGLVL_W (address 0x94) A, #05h ACC, $ ;Next Write or read to Energy Measurement SFR can be done after this. Reading Internal energy measurement registers When bit7 of MADDPT SFR is cleared, the content of the internal energy measurement register designated by the address in MADDPT is transferred to the MDATA SFRs (MDATL, MDATM and MDATH). If the internal register is one byte long, only the MDATL SFR content is updated with a new value while MDATM and MDATH SFR content are reset to 00h. R1, VRMSH //latches data in VrmsH, VrmsM and VrmsL SFR R2, VRMSM R3, VRMSL 6 When bit7 of MADDPT SFR is set, the content of the MDATA SFRs (MDATL, MDATM and MDATH) is transferred to the internal energy measurement register designated by the address in MADDPT SFR. If the internal register is one byte long, only MDATL SFR content is copied to the internal register while MDATM and MDATH SFR contents are ignored. 0 The energy measurement core functions with an internal clock of 4.096 MHz/5 or 819.2 kHz. As the 8052 core functions with another clock, 4.096MHz / 2CD, synchronization between the two clock environments when CD = 0 or 1 is an issue. When data is read from the internal energy measurement, a small wait period need to be implemented before the MDATx SFRs are transferred to another SFR. Sample 8051 code to read the peak voltage in the 2-byte VPKLVL register, located at 0x16, into the data pointer is shown below: MOV MOV DJNZ MOV MOV Rev. PrD | Page 34 of 140 MADDPT,#VPKLVL_R (address 0x16) A, #05h ACC, $ DPH, MDATM DPL, MDATL Preliminary Technical Data ADE7169F16 Table 26. Energy measurement SFRs SFR address (hex) R/W Name Description 0x91 R/W MADDPT Energy Measurement Pointer Address 0x92 R/W MDATL Energy Measurement Pointer Data LSByte 0x93 R/W MDATM Energy Measurement Pointer Data Middle byte 0x94 R/W MDATH Energy Measurement Pointer Data MSByte 0xD1 R VRMSL Vrms measurement LSByte 0xD2 R VRMSM Vrms measurement Middle byte 0xD3 R VRMSH Vrms measurement MSByte 0xD4 R IRMSL Irms measurement LSByte 0xD5 R IRMSM Irms measurement Middle byte 0xD6 R IRMSH Irms measurement MSByte 0xD9 R/W MIRQENL Energy measurement interrupt enable LSByte 0xDA R/W MIRQENM Energy measurement interrupt enable Middle byte 0xDB R/W MIRQENH Energy measurement interrupt enable MSByte 0xDC R/W MIRQSTL Energy measurement interrupt status LSByte 0xDD R/W MIRQSTM Energy measurement interrupt status Middle byte 0xDE R/W MIRQSTH Energy measurement interrupt status MSByte 0xE2 R WAV1L Selection 1 sample LSByte 0xE3 R WAV1M Selection 1 sample Middle byte 0xE4 R WAV1H Selection 1 sample MSByte 0xE5 R WAV2L Selection 2 sample LSByte 0xE6 R WAV2M Selection 2 sample Middle byte 0xE7 R WAV2H Selection 2 sample MSByte ENERGY MEASUREMENT REGISTERS Table 27. Energy Measurement Register List Address MADDPT[6:0] Name R/W Length 0x00 0x01 0x02 0x03 Reserved WATTHR RWATTHR LWATTHR R R R 24 24 24 Signed /Unsigned S S S Default Value Description 0 0 0 Read Watt-hour accumulator without reset Read Watt-hour accumulator with reset Read Watt-hour accumulator synchronous to line cycle Rev. PrD | Page 35 of 140 ADE7169F16 Preliminary Technical Data Address MADDPT[6:0] Name R/W Length 0x04 0x05 0x06 0x07 0x08 0x09 0x0A VARHR RVARHR LVARHR VAHR RVAHR LVAHR PER_FREQ R R R R R R R 24 24 24 24 24 24 16 Signed /Unsigned S S S S S S U Default Value Description 0 0 0 0 0 0 0 Read VAR-hour accumulator without reset Read VAR-hour accumulator with reset Read VAR-hour accumulator synchronous to line cycle Read VA-hour accumulator without reset Read VA-hour accumulator with reset Read VA-hour accumulator synchronous to line cycle Read Line Period or Frequency register depending on Mode2 register Set basic configuration of energy measurement – see Table 28 Set basic configuration of energy measurement – see Table 29 Set configuration of waveform sample 1 and waveform sample 2 – see Table 30 Set level of energy no-load thresholds - Table 31 Set configuration of Watt, VAR accumulation and various tamper alarms – see Table 32 Set phase calibration register – see Phase Compensation section Set time out for Zero-crossing time out detection – see Zero-Crossing Timeout Set number of half line cycles for LWATTHR, LVARHR and LVAHR accumulators Set number of half line cycles for SAG detection – see Line Voltage Sag Detection Set detection level for SAG detection - see Line Voltage Sag Detection Set peak detection level for current peak detection – see Peak Detection Set peak detection level for voltage peak detection– see Peak Detection Read current peak level without reset – see Peak Detection Read current peak level with reset – see Peak Detection Read voltage peak level without reset – see Peak Detection Read voltage peak level with reset – see Peak Detection Set PGA gain of analog inputs – see Table 33 Set Matching Gain for IB current input Set Watt gain register Set VAR gain register Set VA gain register Set Watt offset register Set VAR offset register Set current rms offset register Set voltage rms offset register Set Watt energy scaling register Set VAR energy scaling register Set VA energy scaling register Set CF1 numerator register Set CF1 denominator register 0x0B MODE1 R/W 8 U 0x06 0x0C MODE2 R/W 8 U 0x40 0x0D WAVMODE R/W 8 U 0 0x0E 0x0F NLMODE ACCMODE R/W R/W 8 8 U U 0 0 0x10 PHCAL R/W 8 S 0x40 0x11 ZXTOUT R/W 12 0x12 LINCYC R/W 16 U 0xFFFF 0x13 SAGCYC R/W 8 U 0xFF 0x14 SAGLVL R/W 16 U 0 0x15 IPKLVL R/W 16 U 0xFFFF 0x16 VPKLVL R/W 16 U 0xFFFF 0x17 IPEAK R 24 U 0 0x18 RSTIPEAK R 24 U 0 0x19 VPEAK R 16 U 0 0x1A RSTVPEAK R 16 U 0 0x1B 0x1C 0x1D 0x1E 0x1F 0x20 0x21 0x22 0x23 0x24 0x25 0x26 0x27 0x28 GAIN IBGAIN WGAIN VARGAIN VAGAIN WATTOS VAROS IRMSOS VRMSOS WDIV VARDIV VADIV CF1NUM CF1DEN R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W 8 12 12 12 12 16 16 12 12 8 8 8 16 16 U S S S S S S S S U U U U U 0 0 0 0 0 0 0 0 0 0 0 0 0 0x003F 0x0FFF Rev. PrD | Page 36 of 140 Preliminary Technical Data ADE7169F16 Address MADDPT[6:0] Name R/W Length 0x29 0x2A 0x3D CF2NUM CF2DEN CALMODE R/W R/W R/W 16 16 8 Signed /Unsigned U U U Default Value Description 0 0x003F 0 Set CF2 numerator register Set CF2 denominator register Set Calibration Mode ENERGY MEASUREMENT INTERNAL REGISTERS DETAILS Table 28. MODE1 register (0x0B) Bit Location 7 Bit Mnemonic SWRST Default Value Description 0 6 5 4 3 2 1 0 DISZXLPF INTE SWAPBITS PWRDN DISCF2 DISCF1 DISHPF 0 0 0 0 1 1 0 Setting this bit will reset all of the energy measurement registers to their default values Setting this bit disables the zero-crossing lowpass filter Setting this bit enables the digital integrator for use with a di/dt sensor Setting this bit swaps CH1 & CH2 ADCs Setting this bit powers down voltage and current ADC’s Setting this bit disables Frequency output CF2 Setting this bit disables Frequency output CF1 Setting this bit disables the HPFs in voltage and current channels Table 29. MODE2 register (0x0C) Bit Location 7-6 Bit Mnemonic CF2SEL[1:0] Default Value Description 01 5-4 CF1SEL[1:0] 00 3 VARMSCFCON 0 2 1 ZXRMS FREQSEL 0 0 0 Reserved 1 Configuration bits for CF2 output CF2SEL[1:0] Source 00 CF2 frequency is proportional to active power 01 CF2 frequency is proportional to reactive power 1x CF2 frequency is proportional to apparent power or IRMS Configuration bits for CF1 output CF1SEL[1:0] Source 00 CF1 frequency is proportional to active power 01 CF1 frequency is proportional to reactive power 1x CF1 frequency is proportional to apparent power or IRMS Configuration bits for apparent power or IRMS for CF1 and CF2 outputs 0 If CF1SEL[1:0]=1x, CF1 is proportional to VA If CF2SEL[1:0]=1x, CF2 is proportional to VA 1 If CF1SEL[1:0]=1x, CF1 is proportional to IRMS If CF2SEL[1:0]=1x, CF2 is proportional to IRMS Note that CF1 cannot be proportional to VA if CF2 is proportional to IRMS and vice versa Logic one enables update of RMS values synchronously to voltage ZX Configuration bits to select PERIOD or FREQUENCY measurement for PER_FREQ register (0Ah) 0 PER_FREQ register holds a period measurement 1 PER_FREQ register holds a frequency measurement This bit should be kept to one Table 30. WAVMODE register (0x0D) Bit Location Bit Mnemonic Default Value Description Rev. PrD | Page 37 of 140 ADE7169F16 Preliminary Technical Data 7-5 WAV2SEL[2:0] 0 4-2 WAV1SEL[2:] 0 1-0 DTRT[1:0] 0 Waveform 2 selection for samples mode WAV2SEL[2:0] Source 000 Current 001 Voltage 010 Active Power multiplier output 011 Reactive Power multiplier output 100 VA multiplier output 101 IRMS LPF output others Reserved Waveform 1 selection for samples mode WAV1SEL[2:0] Source 000 Current 001 Voltage 010 Active Power multiplier output 011 Reactive Power multiplier output 100 VA multiplier output 101 IRMS LPF output (low 24-bit) others Reserved Waveform samples output data rate DTRT[1:0] Update rate (clock=MCLK/5=819.2kHz) 00 25.6Ksps(clock/32) 01 12.8Ksps(clock/64) 10 6.4Ksps(clock/128) 11 3.2Ksps(clock/256) Table 31. NLMODE register (0x0E) Bit Location 7 6 Bit Mnemonic Reserved IRMSNOLOAD Default Value Description 0 0 5-4 VANOLOAD[1:0] 0 3-2 VARNOLOAD[1:0] 0 1-0 APNOLOAD[1:0] 0 Reserved Logic one enables IRMS no-load thresold detection. The level is defined by the setting of the VANOLOADbits. Apparent Power No-load threshold [1:0] 00 No-load detection disabled 01 No-load enabled with threshold = 0.030% of Full scale 10 No-load enabled with threshold = 0.015% of Full scale 11 No-load enabled with threshold = 0.0075% of Full scale Reactive Power No-load threshold [1:0] 00 No-load detection disabled 01 No-load enabled with threshold = 0.015% of Full scale 10 No-load enabled with threshold = 0.0075% of Full scale 11 No-load enabled with threshold = 0.0037% of Full scale Active Power No-load threshold [1:0] 00 No-load detection disabled 01 No-load enabled with threshold = 0.015% of Full scale 10 No-load enabled with threshold = 0.0075% of Full scale 11 No-load enabled with threshold = 0.0037% of Full scale Table 32. ACCMODE register (0x0F) Bit Bit Default Description Rev. PrD | Page 38 of 140 Preliminary Technical Data ADE7169F16 Value Location 7 Mnemonic ICHANNEL 0 6 FAULTSIGN 0 5 VARSIGN 0 4 APSIGN 0 3 ABSVARM 0 2 SAVARM 0 1 POAM 0 0 ABSAM 0 This bit indicate the current channel used to measure energy in antitampering mode. 0 – Channel A 1 – Channel B Configuration bit to select event that will trigger a Fault interrupt 0 – FAULT interrupt occurs when part enters Fault Mode 1 – FAULT interrupt occurs when part enters Normal Mode Configuration bit to select event that will trigger an reactive power sign interrupt 0 – VARSIGN interrupt occurs when reactive power changes from positive to negative 1 - VARSIGN interrupt occurs when reactive power changes from negative to positive Configuration bit to select event that will trigger an active power sign interrupt 0 – APSIGN interrupt occurs when active power changes from positive to negative 1 - APSIGN interrupt occurs when active power changes from negative to positive Logic one enables absolute value accumulation of Reactive power in energy register and pulse output Logic one enables reactive power accumulation depending on the sign of the active power: If Active Power is positive, VAR is accumulated as it is; If Active Power is negative, the sign of the VAR is reversed for the accumulation. This accumulation mode affects both the VAR registers and the VARCF output. Logic one enables positive only accumulation of Active power in energy register and pulse output Logic one enables absolute value accumulation of Active power in energy register and pulse output Table 33. GAIN register (0x1B) Bit Location 7-5 Bit Mnemonic PGA2[2:0] Default Value Description 0 4-3 2-0 Reserved PGA1[2:0] 0 0 These bits define the voltage channel input gain [2:0] 000 Gain = 1 001 Gain = 2 010 Gain = 4 011 Gain = 8 100 Gain = 16 Reserved These bits define the current channel input gain [2:0] 000 Gain = 1 001 Gain = 2 010 Gain = 4 011 Gain = 8 100 Gain = 16 Table 34. CALMODE register (0x3D) Bit Bit Default Description Rev. PrD | Page 39 of 140 ADE7169F16 Preliminary Technical Data Location Mnemonic Value 7–6 5-4 Reserved SEL_I_CH[1:0] 0 0 3 2 1-0 V_CH_SHORT I_CH_SHORT Reserved 0 0 These bits should be kept cleared for proper operation These bits define the current channel used for energy measurements [1:0] 00 Current channel automatically selected by the tampering condition 01 Current channel connected to IA 10 Current channel connected to IB 11 Current channel automatically selected by the tampering condition Logic one short voltage channel to ground Logic one short Current channels to ground Table 35. Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) Bit Location 7 Interrupt Flag Description ADEIRQFLAG 6 5 Reserved FAULTSIGN 4 VARSIGN 3 APSIGN 2 VANOLOAD 1 0 RNOLOAD APNOLOAD This bit is set if any of the ADE status flags that are enabled to generate an ADE interrupt are set. This bit is automatically cleared when all of the enabled ADE status flags are cleared. Reserved. Logic one indicates that the Fault mode has changed according to the configuration of the ACCMODE register Logic one indicates that the reactive power sign changed according to the configuration of ACCMODE register Logic one indicates that the active power sign changed according to the configuration of ACCMODE register Logic one indicates that an interrupt was caused by apparent power no-load detected. This interrupt is also used to reflect the part entering the IRMS No load mode. Logic one indicates that an interrupt was caused by reactive power no-load detected. Logic one indicates that an interrupt was caused by active power no-load detected. Table 36. Interrupt Status Register 2 SFR (MIRQSTM, 0xDD) Bit Location 7 Interrupt Flag Description CF2 6 CF1 5 4 3 2 1 0 VAEOF REOF AEOF VAEHF REHF AEHF Logic one indicates that a pulse on CF2 has been issued. The flag is set even if CF2 pulse output is not enabled by clearing bit 2 of MODE1 register. Logic one indicates that a pulse on CF1 has been issued. The flag is set even if CF1 pulse output is not enabled by clearing bit 1 of MODE1 register. Logic one indicates that the VAHR register has overflowded Logic one indicates that the VARHR register has overflowded Logic one indicates that the WATTHR register has overflowded Logic one indicates that the VAHR register is half full Logic one indicates that the VARHR register is half full Logic one indicates that the WATTHR register is half full Table 37. Interrupt Status Register 3 SFR (MIRQSTH, 0xDE) Bit Location 7 6 5 4 3 Interrupt Flag Description RESET WFSM PKI PKV Indicates the end of a reset (for both sofware or hardware reset). Reserved Logic one indicates that new data is present in the Waveform Registers Logic one indicates that current channel has exceeded the IPKLVL value Logic one indicates that voltage channel has exceeded the VPKLVL value. Rev. PrD | Page 40 of 140 Preliminary Technical Data 2 CYCEND 1 ZXTO 0 ZX ADE7169F16 Logic one indicates the end of the energy accumulation over an integer number of half line cycles. Logic one indicates that no zero crossing on the line voltage happened for the last ZXTOUT half line cycles. Logic one indicates detection of a zero crossing in the voltage channel. Table 38. Interrupt Enable Register 1 SFR (MIRQENL, 0xD9) Bit Location 7-6 5 Interrupt Flag Description Reserved FAULTSIGN 4 3 2 VARSIGN APSIGN VANOLOAD 1 RNOLOAD 0 APNOLOAD Reserved. When this bit is set, the FAULTSIGN bit set creates a pending ADE interrupt to the 8052 core. When this bit is set, the VARSIGN bit set creates a pending ADE interrupt to the 8052 core. When this bit is set, the APSIGN bit set creates a pending ADE interrupt to the 8052 core. When this bit is set, the VANOLOAD bit set creates a pending ADE interrupt to the 8052 core. When this bit is set, the RNOLOAD bit set creates a pending ADE interrupt to the 8052 core. When this bit is set, the APNOLOAD bit set creates a pending ADE interrupt to the 8052 core. Table 39. Interrupt Enable Register 2 SFR (MIRQENM, 0xDA) Bit Location 7 6 5 4 3 2 1 0 Interrupt Flag Description CF2 CF1 VAEOF REOF AEOF VAEHF REHF AEHF When this bit is set, a CF2 pulse issued creates a pending ADE interrupt to the 8052 core. When this bit is set, a CF1 pulse issued creates a pending ADE interrupt to the 8052 core. When this bit is set, the VAEOF flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the REOF flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the AEOF flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the VAEHF flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the REHF flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the AEHF flag set creates a pending ADE interrupt to the 8052 core. Table 40. Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) Bit Location 7-6 5 4 3 2 1 0 Interrupt Flag Description WFSM PKI PKV CYCEND ZXTO ZX Reserved When this bit is set, the WFSM flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the PKI flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the PKV flag set creates a pending ADE interrupt to the 8052 core.. When this bit is set, the CYCEND flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the ZXTO flag set creates a pending ADE interrupt to the 8052 core. When this bit is set, the ZX flag set creates a pending ADE interrupt to the 8052 core. ANALOG INPUTS The ADE7169F16 has two fully differential voltage input channels. The maximum differential input voltage for input pairs VP/VN and IP/IN are ±0.5 V. In addition, the maximum signal level on analog inputs for VP/VN and IP/ IN is ±0.5 V with respect to AGND. amplifier) with possible gain selections of 1, 2, 4, 8, and 16. The gain selections are made by writing to the GAIN register in the Energy Measurement Register List—see Table 33 and Figure 17. Bits 0 to 2 select the gain for the PGA in the current channel, and the gain selection for the PGA in voltage channel is made via Bits 5 to 7. Figure 16 shows how a gain selection for the current channel is made using the gain register. Each analog input channel has a PGA (programmable gain Rev. PrD | Page 41 of 140 ADE7169F16 Preliminary Technical Data 7 6 5 GAIN[7:0] 4 3 2 1 0 0 0 0 0 0 0 0 0 A Σ-∆ modulator converts the input signal into a continuous serial stream of 1s and 0s at a rate determined by the sampling clock. In the ADE7169F16, the sampling clock is equal to MCLK/5. The 1-bit DAC in the feedback loop is driven by the serial data stream. The DAC output is subtracted from the input signal. If the loop gain is high enough, the average value of the DAC output (and therefore the bit stream) can approach that of the input signal level. For any given input value in a single sampling interval, the data from the 1-bit ADC is virtually meaningless. Only when a large number of samples are averaged is a meaningful result obtained. This averaging is carried out in the second part of the ADC, the digital low-pass filter. By averaging a large number of bits from the modulator, the lowpass filter can produce 24-bit data-words that are proportional to the input signal level. GAIN (K) SELECTION V1P VIN K ⋅ VIN V1N Figure 16. PGA in current channel In addition to the PGA, Channel 1 also has a full-scale input range selection for the ADC. The ADC analog input range selection is also made using the gain register—see Figure 17. As mentioned previously, the maximum differential input voltage is 0.5 V. GAIN REGISTER* CURRENT AND VOLTAGE CHANNELS PGA CONTROL 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 PGA 2 GAIN SELECT 000 = x 1 001 = x 2 010 = x 4 011 = x 8 100 = x 16 0 ADDR: 1BH PGA 1 GAIN SELECT 000 = x 1 001 = x 2 010 = x 4 011 = x 8 100 = x 16 RESERVED * REGISTER CONTENTS SHOW POWER-ON DEFAULTS Figure 17. ADE7169F16 Analog Gain Register ANALOG TO DIGITAL CONVERSION The ADE7169F16 has two sigma-delta Analog to Digital Converters (ADC). The outputs of these ADCs are mapped directly to waveform sampling SFRs (address 0xE2 to 0xE7) and are used for the energy measurement internal digital signal processing. In PSM1 (Battery mode)and PSM2 (Sleep mode), the ADCs are powered down to minimize power consumption. For simplicity, the block diagram in Figure 18 shows a firstorder Σ-Δ ADC. The converter is made up of the Σ-Δ modulator and the digital low-pass filter. The Σ-Δ converter uses two techniques to achieve high resolution from what is essentially a 1-bit conversion technique. The first is oversampling. Oversampling means that the signal is sampled at a rate (frequency), which is many times higher than the bandwidth of interest. For example, the sampling rate in the ADE7169F16 is MCLK/5 (819.2 kHz) and the band of interest is 40 Hz to 2 kHz. Oversampling has the effect of spreading the quantization noise (noise due to sampling) over a wider bandwidth. With the noise spread more thinly over a wider bandwidth, the quantization noise in the band of interest is lowered — see Figure 19. However, oversampling alone is not efficient enough to improve the signal-to-noise ratio (SNR) in the band of interest. For example, an oversampling ratio of 4 is required just to increase the SNR by only 6 dB (1 bit). To keep the oversampling ratio at a reasonable level, it is possible to shape the quantization noise so that the majority of the noise lies at the higher frequencies. In the Σ-Δ modulator, the noise is shaped by the integrator, which has a high-pass-type response for the quantization noise. The result is that most of the noise is at the higher frequencies where it can be removed by the digital low-pass filter. This noise shaping is shown in Figure 19. DIGITAL FILTER SIGNAL INTEGRATOR + R C + – LATCHED COMPARATOR – VREF SAMPLING FREQUENCY SHAPED NOISE NOISE 0 2 MCLK/5 ANALOG LOW-PASS FILTER ANTILALIAS FILTER (RC) DIGITAL LOW-PASS FILTER 409.6 FREQUENCY (kHz) 819.2 HIGH RESOLUTION OUTPUT FROM DIGITAL LPF SIGNAL 24 NOISE .....10100101..... 0 1-BIT DAC 2 409.6 FREQUENCY (kHz) 819.2 Figure 19. Noise Reduction Due to Oversampling and Noise Shaping in the Analog Modulator Figure 18. First-Order Σ-∆ ADC Rev. PrD | Page 42 of 140 02875-0-047 Preliminary Technical Data ADE7169F16 ALIASING EFFECTS Anti-aliasing Filter Figure 18 also shows an analog low-pass filter (RC) on the input to the modulator. This filter is present to prevent aliasing. Aliasing is an artifact of all sampled systems. Aliasing means that frequency components in the input signal to the ADC, which are higher than half the sampling rate of the ADC, appear in the sampled signal at a frequency below half the sampling rate. Figure 20 illustrates the effect. Frequency components (arrows shown in black) above half the sampling frequency (also know as the Nyquist frequency, i.e., 409.6 kHz) are imaged or folded back down below 409.6 kHz. This happens with all ADCs regardless of the architecture. In the example shown, only frequencies near the sampling frequency, i.e., 819.2 kHz, move into the band of interest for metering, i.e., 40 Hz to 2 kHz. This allows the use of a very simple LPF (low-pass filter) to attenuate high frequency (near 819.2 kHz) noise, and prevents distortion in the band of interest. For conventional current sensors, a simple RC filter (single-pole LPF) with a corner frequency of 10 kHz produces an attenuation of approximately 40 dB at 819.2 kHz — see Figure 20. The 20 dB per decade attenuation is usually sufficient to eliminate the effects of aliasing for conventional current sensors. However, for a di/dt sensor such as a Rogowski coil, the sensor has a 20 dB per decade gain. This neutralizes the –20 dB per decade attenuation produced by one simple LPF. Therefore, when using a di/dt sensor, care should be taken to offset the 20 dB per decade gain. One simple approach is to cascade two RC filters to produce the –40 dB per decade attenuation needed. IAP 0 409.6 ADC Transfer Function Both ADCs in the ADE7169F16 are designed to produce the same output code for the same input signal level. With a fullscale signal on the input of 0.5 V and an internal reference of 1.2 V, the ADC output code is nominally 2,684,354 or 28F5C2h. The maximum code from the ADC is ±4,194,304; this is equivalent to an input signal level of ±0.794 V. However, for specified performance, it is recommended that the full-scale input signal level of 0.5 V not be exceeded. Current Channel ADC Figure 21 shows the ADC and signal processing chain for the current channel. In waveform sampling mode, the ADC outputs a signed twos complement 24-bit data-word at a maximum of 25.6 kSPS (MCLK/160). With the specified full-scale analog input signal of 0.5 V (or 0.25 V or 0.125 V—see the Analog Inputs section) the ADC produces an output code that is approximately between 0x28F5C2 (+2,684,354d) and 0xD70A3E (–2,684,354d)—see Figure 21. MODE1[5] CURRENT RMS (IRMS) CALCULATION WAVEFORM SAMPLE REGISTER HPF DIGITAL INTEGRATOR* ADC ACTIVE AND REACTIVE POWER CALCULATION dt HPF PGA1 819.2 Figure 20. ADC and Signal Processing in current channel Outline Dimensions IN IBP 2 FREQUENCY (kHz) x1, x2, x4, REFERENCE x8, x16 {GAIN[2:0]} PGA1 I SAMPLING FREQUENCY IMAGE FREQUENCIES ADC 50Hz 0.5V, 0.25V, 0.125V, 62.5mV, 31.3mV CURRENT CHANNEL WAVEFORM DATA RANGE AFTER INTEGRATOR (50Hz) 0x342CD0 V1 CURRENT CHANNEL WAVEFORM DATA RANGE 0V 0x000000 0xCBD330 0x28F5C2 ANALOG INPUT RANGE 0x000000 60Hz 0xD70A3E 0x2B7850 0x000000 *WHEN DIGITAL INTEGRATOR IS ENABLED, FULL-SCALE OUTPUT DATA IS ATTENUATED DEPENDING ON THE SIGNAL FREQUENCY BECAUSE THE INTEGRATOR HAS A –20dB/DECADE FREQUENCY RESPONSE. WHEN DISABLED, THE OUTPUT WILL NOT BE FURTHER ATTENUATED. Figure 21. ADC and Signal Processing in Current Channel Rev. PrD | Page 43 of 140 0xD487B0 CURRENT CHANNEL WAVEFORM DATA RANGE AFTER INTEGRATOR (60Hz) ADE7169F16 Preliminary Technical Data maximum of 25.6 kSPS (MCLK/160). The ADC produces an output code that is approximately between 0x28F5 (+10,485d) and 0xD70B (–10,485d)—see Figure 22. Voltage Channel ADC Figure 21 shows the ADC and signal processing chain for the Voltage Channel. In waveform sampling mode, the ADC outputs a signed twos complement 24-bit data-word at a VP HPF PGA2 V2 ACTIVE AND REACTIVE POWER CALCULATION x1, x2, x4, REFERENCE x8, x16 {GAIN[7:5]} ADC VOLTAGE RMS (VRMS) CALCULATION WAVEFORM SAMPLE REGISTER VOLTAGE PEAK DETECT 0.5V, 0.25V, 0.125V, 62.5mV, 31.3mV V2 ZX DETECTION LPF1 0V VOLTAGE CHANNEL WAVEFORM DATA RANGE ANALOG INPUT RANGE f–3dB = 63.7Hz MODE1[6] 0x28F5 ZX SIGNAL DATA RANGE for 60Hz signal 0x1DD0 0x0000 0x0000 0xE230 0xD70B ZX SIGNAL DATA RANGE for 50Hz signal 0x2037 0x0000 0xDFC9 Figure 22. ADC and Signal Processing in Voltage Channel Channel Sampling The waveform samples of the current ADC and voltage ADC can also be routed to the waveform registers to be read by the MCU core. The active, reactive, apparent power, and energy calculation remain uninterrupted during waveform sampling. When in waveform sampling mode, one of four output sample rates can be chosen by using Bits 0 and 1 of the WAVMODE register (WAVSEL1,0). The output sample rate can be 25.6 kSPS, 12.8kSPS, 6.4 kSPS, or 3.2 kSPS—see Table 30. If the WFSM enable bit is set in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB), the 8052 core has a pending ADE interrupt. The sampled signals selected in the WAVMODE register will be latched into the Waveform SFRs when the waveform high byte (WAV1H or WAV2H) is read. The ADE interrupt stays active until the WFSM status bit is cleared—see Energy measurement interrupts section. FAULT DETECTION The ADE7169F16 incorporates a fault detection scheme that warns of fault conditions and allows the ADE7169F16 to continue accurate measurement during a fault event. The ADE7169F16 does this by continuously monitoring both current inputs (IA and IB). These currents will be referred for ease of understanding as phase and neutral (return) currents. In the ADE7169F16, a fault condition is defined when the difference between IA and IB is greater than 6.25% of the active channel. If a fault condition is detected and the inactive channel is larger than the active channel, the ADE7169F16 automatically switches to current measurement to the inactive channel. During a fault, the active, reactive, current rms and apparent powers are generated using the larger of the two currents. On power-up, IA is the current input selected for Active, Reactive, and Apparent power and Irms calculations. To prevent false alarm, averaging is done for the fault detection and a fault condition is detected approximately 1 second after the event. The fault detection is automatically disabled when the voltage signal is less than 0.3% of the full-scale input range. This eliminates false detection of a fault due to noise at light loads. Because the ADE7169F16 looks for a difference between the voltage signals on IA and IB, it is important that both current transducers be closely matched. Channel selection Indication The current channel selected for measurement is indicated by bit 7 (ICHANNEL) in the ACCMODE register (0x0F). When this bit is cleared, IA is selected and when it is set, IB is selected. Rev. PrD | Page 44 of 140 Preliminary Technical Data ADE7169F16 Fault Indication The ADE7169F16 provides an indication of the part going in or out of a fault condition. The new fault condition is indicated by the FAULTSIGN flag (bit5) in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC). When FAULTSIGN bit (bit 6) of ACCMODE register (0x0F) is cleared, the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when the part is entering fault condition. When FAULTSIGN bit (bit 6) of ACCMODE register (0x0F) is set, the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when the part is entering normal condition. When the FAULTSIGN bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), and the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set, the 8052 core has a pending ADE interrupt. Fault with Active Input Greater than Inactive Input If IA is the active current input (that is, being used for billing), and the voltage signal on IB (inactive input) falls below 93.75% of IA, and the FAULTSIGN bit (bit 6) of ACCMODE register (0x0F) is cleared, the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set. Both analog inputs are filtered and averaged to prevent false triggering of this logic output. As a consequence of the filtering, there is a time delay of approximately 3 s on the logic output after the fault event. The FAULTSIGN flag is independent of any activity. Because IA is the active input and it is still greater than IB, billing is maintained on IA, that is, no swap to the IB input occurs. IA remains the active input. Calibration Concerns Typically, when a meter is being calibrated, the voltage and current circuits are separated as shown in Figure 23. This means that current passes through only the phase or neutral circuit. Figure 23 shows current being passed through the phase circuit. This is the preferred option, because the ADE7169F16 starts billing on the input IA on power-up. The phase circuit CT is connected to IA in the diagram. As the current sensors are not perfectly matched, it is important to match current inputs. The ADE7169F16 provides a gain calibration register for IB, IBGAIN (address 0x1C). IBGAIN is a 12-bit signed 2-complement register that provides a gain resolution of 0.0244%/LSB. For calibration, a first measurement should be done on IA by setting SEL_I_CH bits to 0b01 in the CALMODE register (0x3D). This measurement should be compared to the measurement on IB. Measuring IB can be forced by setting SEL_I_CH bits to 0b10 in the CALMODE register (0x3D). The Gain error between these two measurements can be evaluated using: Error (% ) = Measurement (I B ) − Measurement (I A ) Measurement (I A ) The two channels IA and IB can then be matched by writing: – Error(%) / (1 + Error (%)) * 212 to IBGAIN register. This matching adjustment will be valid for all energy measurements, Active power, reactive power, Irms, and Apparent power, made by the ADE7169F16. IB RB CF VA AGND IN TEST CURRENT RB 0V CF CT RF RA CF Fault with Inactive Input Greater than Active Input If the difference between IB, the inactive input, and IA, the active input (that is, being used for billing), becomes greater than 6.25% of IB, and the FAULTSIGN bit (bit 6) of ACCMODE register (0x0F) is cleared, the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set. The analog input IB becomes the active input. Again, a time constant of about 3 s is associated with this swap. IA does not swap back to IA RF CT 0 NEUTRAL The current channel selected for measurement can also be forced. Setting one of the SELCH1A and SELCH1B bits in the CALMODE register (0x3D) selects IA and IB respectively. When both bits are cleared or set, the current channel used for measurement is selected automatically based on the Fault detection. the active channel until IA is greater than IB and the difference between IA and IB—in this order—becomes greater than 6.25% of IB. However, if FAULTSIGN bit (bit 6) of ACCMODE register (0x0F) is set, the FAULTSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set as soon as IA is within 6.25% of IB. This threshold eliminates potential chatter between IA and IB. PHASE The ADE7169F16 automatically switches from one channel to the other and reports the channel configuration in the ACCMODE register (0x0F). IB VN RF RF VP CT V 240V RMS Figure 23. Fault Conditions for Inactive Input Greater than Active Input di/dt CURRENT SENSOR AND DIGITAL INTEGRATOR A di/dt sensor detects changes in magnetic field caused by ac Rev. PrD | Page 45 of 140 ADE7169F16 Preliminary Technical Data current. Figure 24 shows the principle of a di/dt current sensor. –88.0 –88.5 + EMF (ELECTROMOTIVE FORCE) – INDUCED BY CHANGES IN MAGNETIC FLUX DENSITY (di/dt) PHASE (Degrees) MAGNETIC FIELD CREATED BY CURRENT (DIRECTLY PROPORTIONAL TO CURRENT) –89.0 –89.5 02875-0-035 –90.0 The flux density of a magnetic field induced by a current is directly proportional to the magnitude of the current. The changes in the magnetic flux density passing through a conductor loop generate an electromotive force (EMF) between the two ends of the loop. The EMF is a voltage signal, which is proportional to the di/dt of the current. The voltage output from the di/dt current sensor is determined by the mutual inductance between the current-carrying conductor and the di/dt sensor. The current signal needs to be recovered from the di/dt signal before it can be used. An integrator is therefore necessary to restore the signal to its original form. The ADE7169F16 has a built-in digital integrator to recover the current signal from the di/dt sensor. The digital integrator on the Current Channel is switched off by default when the ADE7169F16 is powered up. Setting INTE bit in the MODE1 register (0x0B) turns on the integrator. Figure 25 to Figure 28 show the magnitude and phase response of the digital integrator. –90.5 Figure 24. Principle of a di/dt Current Sensor 102 02875-0-037 Figure 26. Combined Phase Response of the Digital Integrator and Phase Compensator –1.0 –1.5 –2.0 GAIN (dB) –2.5 –3.0 –3.5 –4.0 –4.5 –5.0 –5.5 –6.0 40 45 10 50 55 60 FREQUENCY (Hz) 65 70 02875-0-038 Figure 27. Combined Gain Response of the Digital Integrator and Phase Compensator (40 Hz to 70 Hz) 0 –89.70 –10 –89.75 –20 –89.80 PHASE (Degrees) GAIN (dB) 103 FREQUENCY (Hz) FREQ –30 –40 –50 102 –89.90 –89.95 –90.00 103 FREQUENCY (Hz) –89.85 02875-0-036 –90.05 Figure 25. Combined Gain Response of the Digital Integrator and Phase Compensator 40 45 50 55 60 FREQUENCY (Hz) 65 70 02875-0-039 Figure 28. Combined Phase Response of the Digital Integrator and Phase Compensator (40 Hz to 70 Hz) Note that the integrator has a –20 dB/dec attenuation and an approximately –90° phase shift. When combined with a di/dt Rev. PrD | Page 46 of 140 Preliminary Technical Data ADE7169F16 sensor, the resulting magnitude and phase response should be a flat gain over the frequency band of interest. The di/dt sensor has a 20 dB/dec gain associated with it. It also generates significant high frequency noise, therefore a more effective antialiasing filter is needed to avoid noise due to aliasing—see the Anti-aliasing Filter section. The zero-crossing detection also drives the ZX flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE). If the ZX bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) is set, the 8052 core has a pending ADE interrupt. When the digital integrator is switched off, the ADE7169F16 can be used directly with a conventional current sensor such as a current transformer (CT) or with a low resistance current shunt. Zero-Crossing Timeout POWER QUALITY MEASUREMENTS Zero-Crossing Detection The ADE7169F16 has a zero-crossing detection circuit on the voltage channel. This zero crossing is used to produce an external zero-crossing signal (ZX), and it is also used in the calibration mode. The zero-crossing is generated, by default, from the output of LPF1. As explained in the following paragraph, this filter has a low cut-off frequency and is intended for use for 50 and 60Hz system. If needed this filter can be disabled to allow a higher frequency signal to be detected or to limit the group delay of the detection. If the voltage input fundamental frequency is below 60Hz and a time delay in ZX detection is acceptable, it is recommended to enable LPF1. Enabling LPF1 will limit the variability in the ZX detection by eliminating the high frequency components. Figure 29 shows how the zero-crossing signal is generated. VP x1, x2, x4, REFERENCE x8, x16 {GAIN [7:5]} PGA2 V2 The ADE interrupt stays active until the ZX status bit is cleared—see Energy measurement interrupts section. The zero-crossing detection also has an associated timeout register, ZXTOUT. This unsigned, 12-bit register is decremented (1 LSB) every 160/MCLK seconds. The register is reset to its user programmed full-scale value every time a zero crossing is detected on the voltage channel. The default power on value in this register is 0xFFF. If the internal register decrements to 0 before a zero crossing is detected and the ZXTOUT flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE) is set. If the ZXTO bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) is set, the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the ZXTO status bit is cleared—see Energy measurement interrupts section. The ZXOUT register (Address 0x11) can be written or read by the user—see Energy Measurement Register List. The resolution of the register is 160/MCLK seconds per LSB. Thus the maximum delay for an interrupt is 0.16 second (128/MCLK × 212) when MCLK = 4.096MHz. Figure 30 shows the mechanism of the zero-crossing timeout detection when the line voltage stays at a fixed dc level for more than CLKIN/160 × ZXTOUT seconds. HPF ADC 2 12-BIT INTERNAL REGISTER VALUE ZXTOUT VN ZERO CROSS ZX LPF1 f–3dB = 63.7Hz VOLTAGE CHANNEL MODE1[6] 43.24° @ 60Hz 1.0 0.73 ZX V2 ZXTO FLAG BIT Figure 30. Zero-Crossing Timeout Detection LPF1 Period or Frequency Measurements Figure 29. Zero-Crossing Detection on Voltage channel The zero-crossing signal ZX is generated from the output of LPF1 (bypassed or not). LPF1 has a single pole at 63.7 Hz (at MCLK = 4.096 MHz). As a result, there is a phase lag between the analog input signal V2 and the output of LPF1. The phase lag response of LPF1 results in a time delay of approximately 2 ms (@ 60 Hz) between the zero crossing on the analog inputs of the voltage channel and ZX detection. The ADE7169F16 provides the period or frequency measurement of the line. The period or frequency measurement is selected by clearing or setting FREQSEL bit in the MODE2 register (0x0C). The period/frequency register is an unsigned 16-bit register and is updated every period. If LPF1 is enabled, a settling time of 1.8 seconds is associated with this filter before the measurement is stable. Rev. PrD | Page 47 of 140 ADE7169F16 Preliminary Technical Data When the period measurement is selected, the measurement has a 2.44 μs/LSB (MCLK/10) when MCLK = 4.096 MHz, which represents 0.014% when the line frequency is 60 Hz. When the line frequency is 60 Hz, the value of the period register is approximately 0d6827. The length of the register enables the measurement of line frequencies as low as 12.5 Hz. The period register is stable at ±1 LSB when the line is established and the measurement does not change. Sag Level Set When the frequency measurement is selected, the measurement has a 0.0625 Hz/LSB resolution when MCLK = 4.096MHz which represents 0.104% when the line frequency is 60Hz. When the line frequency is 60Hz, the value of the frequency register is 0d960. The frequency register is stable at ±4 LSB when the line is established and the measurement does not change. Peak Detection The contents of the sag level register (2 bytes) are compared to the absolute value of the output from LPF1. Therefore, when LPF1 is enabled, writing 0x2038 to the SAG level register puts the sag detection level at full scale – see Figure 22. Writing 0x00 or 0x01 puts the sag detection level at 0. The SAG level register is compared to the input of the ZX detection and detection is made when the contents of the sag level register are greater. The ADE7169F16 can also be programmed to detect when the absolute value of the voltage or current channel exceeds a specified peak value. Figure 32 illustrates the behavior of the peak detection for the voltage channel. Both Voltage and Current Channels are monitored at the same time. V2 Line Voltage Sag Detection VPKLVL[15:0] In addition to the detection of the loss of the line voltage signal (zero crossing), the ADE7169F16 can also be programmed to detect when the absolute value of the line voltage drops below a certain peak value for a number of line cycles. This condition is illustrated in Figure 31. VOLTAGE CHANNEL PKV RESET LOW WHEN RSTSTATUS REGISTER IS READ PKV INTERRUPT FLAG FULL SCALE SAGLVL [15:0] READ RSTSTATUS REGISTER SAGCYC [7:0] = 0x04 3 LINE CYCLES SAG RESET LOW WHEN VOLTAGE CHANNEL EXCEEDS SAGLVL [15:0] AND SAG FLAG RESET SAG FLAG Figure 31. ADE7169F16 Sag Detection Figure 31 shows the line voltage falling below a threshold that is set in the sag level register (SAGLVL[15:0]) for three line cycles. The quantities 0 and 1 are not valid for the SAGCYC register, and the contents represent one more than the desired number of full line cycles. For example, when the sag cycle (SAGCYC[7:0]) contains 0x04, the SAG flag in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) is set at the end of the third line cycle for which the line voltage falls below the threshold. If the SAG enable bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC) is set the 8052 core has a pending Power Supply Monitoring interrupt. The PSM interrupt stays active until the SAG status bit is cleared—see Power Supply Monitor Interrupt (PSM) section. On Figure 31, the SAG flag is set as soon as the fifth line cycle from the time when the signal on the Voltage channel first dropped below the threshold level. Figure 32. ADE7169F16 Peak Level Detection Figure 32 shows a line voltage exceeding a threshold that is set in the voltage peak register (VPKLVL[15:0]). The voltage peak event is recorded by setting the PKV flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE). If the PKV enable bit is set in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB), the 8052 core has a pending ADE interrupt. Similarly, the current peak event is recorded by setting the PKI flag in Interrupt Status Register 3 SFR (MIRQSTH, 0xDE). The ADE interrupt stays active until the PKV or PKI status bits are cleared—see Energy measurement interrupts section. Peak Level Set The contents of the VPKLVL and IPKLVL registers are respectively compared to the absolute value of the voltage and current channels two most significant bytes. Thus, for example, the nominal maximum code from the Current Channel ADC with a full-scale signal is 0x28F5C2—see the Current Channel ADC section. Therefore, writing 0x28F5 to the IPKLVL register, for example, puts the current channel peak detection level at full scale and sets the current peak detection to its least sensitive value. Writing 0x00 puts the Current channel detection level at 0. The detection is done by comparing the contents of the IPKLVL register to the incoming Current channel sample. The PKI flag indicates that the peak level is exceeded if the PKI or Rev. PrD | Page 48 of 140 Preliminary Technical Data ADE7169F16 PKV bits are set in Interrupt Enable Register 3 SFR (MIRQENH, 0xDB), the 8052 core has a pending ADE interrupt. channel. A time advance of 4.88 μs is made by writing −4 (0x3C) to the time delay block, thus reducing the amount of time delay by 4.88 μs, or equivalently, a phase lead of approximately 0.1° at line frequency of 60 Hz. 0x3C represents –4 because the register is centered with 0 at 0x40. Peak Level Record The ADE7169F16 records the maximum absolute value reached by the voltage and current channels in two different registers— IPEAK and VPEAK, respectively. VPEAK and IPEAK are 16-bit unsigned registers. These registers are updated each time the absolute value of the waveform sample from the corresponding channel is above the value stored in the VPEAK or IPEAK register. The contents of the VPEAK register correspond to the maximum absolute value observed on the voltage channel input. The contents of IPEAK and VPEAK represent the maximum absolute value observed on the Current and Voltage input respectively. Reading the RSTVPEAK and RSTIPEAK registers clears their respective contents after the read operation. IPA HPF 24 PGA1 I ADC 1 IN LPF2 24 VP 1 PGA2 V DELAY BLOCK 1.22μs/LSB ADC 2 V 7 0 1 0 0 1 0 1 1 1 V 0.1° I CHANNEL 2 DELAY REDUCED BY 4.48μs (0.1°LEAD AT 60Hz) 0Bh IN PHCAL [5.0] V I PHCAL [7:0] --231.93μs TO +48.83μs 60Hz PHASE COMPENSATION 60Hz The ADE7169F16 must work with transducers, which could have inherent phase errors. For example, a phase error of 0.1° to 0.3° is not uncommon for a current transformer (CT). These phase errors can vary from part to part, and they must be corrected in order to perform accurate power calculations. The errors associated with phase mismatch are particularly noticeable at low power factors. The ADE7169F16 provides a means of digitally calibrating these small phase errors. The ADE7169F16 allows a small time delay or time advance to be introduced into the signal processing chain to compensate for small phase errors. Because the compensation is in time, this technique should be used only for small phase errors in the range of 0.1° to 0.5°. Correcting large phase errors using a time shift technique can introduce significant phase errors at higher harmonics. The phase calibration register (PHCAL[7:0]) is a twos complement signed single-byte register that has values ranging from 0x82 (–126d) to 0x68 (104d). The register is centered at 0x40, so that writing 0x40 to the register gives 0 delay. By changing the PHCAL register, the time delay in the Voltage channel signal path can change from – 231.93 μs to +48.83 μs (MCLK = 4.096 MHz). One LSB is equivalent to 1.22 μs (MCLK/5) time delay or advance. A line frequency of 60 Hz gives a phase resolution of 0.026° at the fundamental (i.e., 360° × 1.22 μs × 60 Hz) or 0.00732% of the line period. Similarly, a line frequency of 50Hz gives a phase resolution of 0.022° at the fundamental or 0.0061% of the line period. Figure 33 illustrates how the phase compensation is used to remove a 0.1° phase lead in Current channel due to the external transducer. To cancel the lead (0.1°) in Current channel, a phase lead must also be introduced into Voltage channel. The resolution of the phase adjustment allows the introduction of a phase lead in increment of 0.026°. The phase lead is achieved by introducing a time advance into Voltage Figure 33. Phase Calibration ADE7169F16 RMS CALCULATION Root mean square (rms) value of a continuous signal V(t) is defined as T VRMS = Vrms = 1 × V 2 (t ) dt T ∫ (2) 0 For time sampling signals, rms calculation involves squaring the signal, taking the average and obtaining the square root. The ADE7169F16 implements this method by serially squaring the input, averaging them and then taking the root square of the average. The averaging part of this signal processing is done by implementing a Low Pass filter (LPF3 in Figure 35 and Figure 36). This LPF has a -3dB cut-off frequency of 2Hz when MCLK = 4.096MHz. V(t) = 2 × V sin(ωt ) where: V is the rms voltage. V 2 (t ) = V 2 − V 2 cos(2ωt ) When this signal goes through LPF3, the cos(2ωt) term is attenuated and only the DC term Vrms2 goes through – see Figure 34. Rev. PrD | Page 49 of 140 V 2 (t ) = V 2 − V 2 cos (2ω t ) V(t)= 2 ⋅ V sin(ωω t) LPF3 INPUT V V 2 (t ) = V 2 Figure 34. ADE7169F16 RMS Signal Processing ADE7169F16 Preliminary Technical Data The rms signals can be read from the waveform register by setting the WAVMODE register (0x0D) and setting the WFSM bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB). Like the current and voltage channels waveform sampling modes, the waveform date is available at sample rates of 27.9 kSPS, 14 kSPS, 7 kSPS, or 3.5 kSPS. waveform sampling mode. The current channel rms value is stored in an unsigned 24-bit register (IRMS). One LSB of the current channel rms register is equivalent to one LSB of a current channel waveform sample. The update rate of the current channel rms measurement is MCLK/5. To minimize noise in the reading of the register, the Irms register can also be configured to be updated only with the zero crossing of the voltage input. This configuration is done by setting ZXRMS bit in the MODE2 register (0x0C). Important: When the current input is larger than 40% of Full scale, the Irms waveform sample register does not represent the true rms value processed. The rms value processed with this level of input is larger than the 24 bit read by the waveform register making the value read truncated on the high end. With the specified full-scale analog input signal of 0.5 V, the ADC produces an output code that is approximately ±0d2,684,354—see the Current Channel ADC section. The equivalent rms value of a full-scale ac signal is 0d1,898,124 (0x1CF68C). The current rms measurement provided in the ADE7169F16 is accurate to within 0.5% for signal input between full scale and full scale/1000. The conversion from the register value to amps must be done externally in the microprocessor using an amps/LSB constant. Current Channel RMS Calculation The ADE7169F16 simultaneously calculates the rms values for the Current and Voltage channel in different registers. The current channel rms calculation is done on the channel selected by SEL_I_CH bits in the CALMODE register (0x3D). Figure 35 shows the detail of the signal processing chain for the rms calculation on the current channel. The current channel rms value is processed from the samples used in the current channel 60Hz CURRENT CHANNEL WAVEFORM DATA RANGE WITH INTEGRATOR ON (60Hz) 0x2B7850 0x000000 0xD487B0 IRMSOS[11:0] IRMS(t) MODE1[5] IA sgn 225 226 227 HPF DIGITAL INTEGRATOR* HPF 218 217 216 0x00 HPF1 LPF3 24 + 24 IRMS[23:0] dt IB CURRENT CHANNEL WAVEFORM DATA RANGE WITH INTEGRATOR OFF 0x28F5C2 0x000000 0xD70A3E Figure 35. Current channel RMS Signal Processing Current channel RMS Offset Compensation be maintained at 0 when no input is present on current channel. The ADE7169F16 incorporates a current channel rms offset compensation register (IRMSOS). This is a 12-bit signed register that can be used to remove offset in the current channel rms calculation. An offset could exist in the rms calculation due to input noises that are integrated in the dc component of V2(t). The offset calibration allows the content of the IRMS register to One LSB of the current channel rms offset is equivalent to 16,384 LSB of the square of the current channel rms register. Assuming that the maximum value from the current channel rms calculation is 0d1,898,124 with full-scale ac inputs, then 1 LSB of the current channel rms offset represents 0.23% of measurement error at –60 dB down of full scale. Rev. PrD | Page 50 of 140 Preliminary Technical Data IRMS = ADE7169F16 2 IRMS 0 + IRMSOS × 32768 (4) where IRMS0 is the rms measurement without offset correction. scale/20. The conversion from the register value to volts must be done externally in the microprocessor using a volts/LSB constant. Voltage channel RMS Offset Compensation Voltage channel RMS Calculation Figure 36 shows the details of the signal processing chain for the rms calculation on Voltage channel. The Voltage channel rms value is processed from the samples used in the Voltage channel waveform sampling mode. Voltage channel rms value is stored in the unsigned 24-bit VRMS register. The update rate of the Voltage channel rms measurement is MCLK/5. To minimize noise in the reading of the register, the Vrms register can also be configured to be updated only with the zero crossing of the voltage input. This configuration is done by setting ZXRMS bit in the MODE2 register (0x0C). With the specified full-scale ac analog input signal of 0.5 V, the output from the LPF1 swings between 0x28F5 and 0xD70B at 60 Hz—see the Voltage Channel ADC section. The equivalent rms value of this full-scale ac signal is approximately 0d1,898,124 (0x1CF68C) in the VRMS register. The voltage rms measurement provided in the ADE7169F16 is accurate to within ±0.5% for signal input between full scale and full The ADE7169F16 incorporates a voltage channel rms offset compensation register (VRMSOS). This is a 12-bit signed register that can be used to remove offset in the voltage channel rms calculation. An offset could exist in the rms calculation due to input noises and dc offset in the input samples. The offset calibration allows the contents of the VRMS register to be maintained at 0 when no voltage is applied. One LSB of the voltage channel rms offset is equivalent to 64 LSB of the rms register. Assuming that the maximum value from the voltage channel rms calculation is 0d1,898,124 with full-scale ac inputs, then one LSB of the voltage channel rms offset represents 3.37% of measurement error at –60 dB down of full scale. VRMS = VRMS0 + 64 x VRMSOS (6) where VRMS0 is the rms measurement without offset correction. VOLTAGE SIGNAL (V(t)) 0x28F5 VRMOS[11:0] 0x0 sgn 216 215 28 27 26 0xD70B LPF1 VRMS[23:0] 0x28F5C2 LPF3 + + VOLTAGE CHANNEL 0x00 Figure 36. Voltage channel RMS Signal Processing ACTIVE POWER CALCULATION The average power over an integral number of line cycles (n) is given by the expression in Equation 10. Active power is defined as the rate of energy flow from source to load. It is defined as the product of the voltage and current waveforms. The resulting waveform is called the instantaneous power signal and is equal to the rate of energy flow at every instant of time. The unit of power is the watt or joules/sec. Equation 9 gives an expression for the instantaneous power signal in an ac system. P= ∫ nT 0 p (t )dt = VI (10) where: T is the line cycle period. P is referred to as the active or real power. v(t) = 2 × V sin(ωt ) (7) i(t) = 2 × I sin(ωt ) (8) where: V is the rms voltage. I is the rms current. p (t ) = v (t ) × i (t ) p(t ) = VI − VI cos(2ωt ) 1 nT Note that the active power is equal to the dc component of the instantaneous power signal p(t) in Equation 9, i.e., VI. This is the relationship used to calculate active power in the ADE7169F16. The instantaneous power signal p(t) is generated by multiplying the current and voltage signals. The dc component of the instantaneous power signal is then extracted by LPF2 (low-pass filter) to obtain the active power information. This process is illustrated in Figure 37. (9) Rev. PrD | Page 51 of 140 ADE7169F16 Preliminary Technical Data INSTANTANEOUS POWER SIGNAL For example, when 0x7FF is written to the watt gain register, the power output is scaled up by 50%. 0x7FF = 2047d, 2047/212 = 0.5. Similarly, 0x800 = –2048d (signed twos complement) and power output is scaled by –50%. Each LSB scales the power output by 0.0244%. The minimum output range is given when the watt gain register contents are equal to 0x800, and the maximum range is given by writing 0x7FF to the watt gain register. This can be used to calibrate the active power (or energy) calculation in the ADE7169F16. p(t) = v×i-v×i×cos(2ωt) 0x19999A ACTIVE REAL POWER SIGNAL = v × i VI 0xCCCCD 0x00000 Active power offset calibration CURRENT i(t) = 2×i×sin(ωt) VOLTAGE v(t) = 2×v×sin(ωt) 02875-0-060 Figure 37. Active Power Calculation Since LPF2 does not have an ideal “brick wall” frequency response—see Figure 38, the active power signal has some ripple due to the instantaneous power signal. This ripple is sinusoidal and has a frequency equal to twice the line frequency. Because the ripple is sinusoidal in nature, it is removed when the active power signal is integrated to calculate energy—see the Active Energy Calculation section. 0 –4 dB –8 –12 –16 The ADE7169F16 also incorporates an active power offset register (WATTOS[15:0]). This is a signed twos complement 16-bit register that can be used to remove offsets in the active power calculation—see Figure 37. An offset could exist in the power calculation due to crosstalk between channels on the PCB or in the IC itself. The offset calibration allows the contents of the active power register to be maintained at 0 when no power is being consumed. The 256 LSBs (WATTOS = 0x0100) written to the active power offset register are equivalent to 1 LSB in the waveform sample register. Assuming the average value, output from LPF2 is 0xCCCCD (838,861d) when inputs on the voltage and current channels are both at full scale. At −60 dB down on the current channel (1/1000 of the current channel full-scale input), the average word value output from LPF2 is 838.861 (838,861/1,000). One LSB in the LPF2 output has a measurement error of 1/838.861 × 100% = 0.119% of the average value. The active power offset register has a resolution equal to 1/256 LSB of the waveform register, therefore the power offset correction resolution is 0.000464%/LSB (0.119%/256) at –60 dB. Active power sign detection –20 –24 1 3 10 FREQUENCY (Hz) 30 100 02875-0-061 Figure 38. Frequency Response of LPF2 Active power gain calibration Figure 39 shows the signal processing chain for the active power calculation in the ADE7169F16. As explained, the active power is calculated by low-pass filtering the instantaneous power signal. Note that when reading the waveform samples from the output of LPF2, the gain of the active energy can be adjusted by using the multiplier and watt gain register (WGAIN[11:0]). The gain is adjusted by writing a twos complement 12-bit word to the watt gain register. Equation 11 shows how the gain adjustment is related to the contents of the watt gain register: ⎛ ⎧ WGAIN ⎫ ⎞ Output WGAIN = ⎜⎜ Active Power × ⎨1 + ⎬ ⎟⎟ 212 ⎭ ⎠ ⎩ ⎝ (11) The ADE7169F16 detects a change of sign in the active power. The APSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) record when a change of sign according to bit APSIGN in the ACCMODE register (0x0F) has occurred. If the APSIGN bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the APSIGN status bit is cleared—see Energy measurement interrupts section. When APSIGN in the ACCMODE register (0x0F) is cleared (default), the APSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when a transition from positive to negative active power has occurred. When APSIGN in the ACCMODE register (0x0F) is set, the APSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when a transition from negative to positive active power has occurred. Active power no-Load detection Rev. PrD | Page 52 of 140 Preliminary Technical Data ADE7169F16 The ADE7169F16 includes a no-load threshold feature on the active energy that eliminates any creep effects in the meter. The ADE7169F16 accomplishes this by not accumulating energy if the multiplier output is below the no-load threshold. When the active power is below the no-load threshold, the APNOLOAD flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set. If the APNOLOAD bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the APNOLOAD status bit is cleared—see Energy measurement interrupts section. APNOLOAD in the NLMODE register (0x0E). Setting these bits to 0b00 disable the no-load detection and setting them to 0b01, 0b10 or 0b11 set the no-load detection threshold to 0.015%, 0.0075% and 0.0037% of the full-scale output frequency of the multiplier respectively. The IEC62053-21 specification, states that the meter must start up with a load equal to or less than 0.4% Ib. If the nominal voltage input and the maximum current represent 50% of the full scale ADC input and Imax = 400% of Ib, the ADE7169F16 no-load threshold options translate to 0.24% of Ib, 0.12% of Ib and 0.06% of Ib respectively. The No-load threshold level is selectable by setting bits FOR WAVEF0RM SAMPLING WATTHR[23:0] 23 0 UPPER 24 BITS ARE ACCESSIBLE THROUGH WATTHR[23:0] REGISTER WATTOS[15:0] sgn 26 25 CURRENT CHANNEL 2-6 2-7 2-8 LPF2 WDIV[7:0] + + 48 + 0 % + VOLTAGE CHANNEL WGAIN[11:0] ACTIVE POWER SIGNAL 5 CLKIN OUTPUT LPF2 T TO DIGITAL TO FREQUENCY CONVERTER OUTPUTS FROM THE LPF2 ARE ACCUMULATED (INTEGRATED) IN THE INTERNAL ACTIVE ENERGY REGISTER WAVEFORM REGISTER VALUES TIME (nT) Figure 39. ADE7169F16 Active Energy Calculation Active Energy Calculation As stated earlier, power is defined as the rate of energy flow. This relationship can be expressed mathematically in Equation 12. P= dE dt (12) this internal register. This discrete time accumulation or summation is equivalent to integration in continuous time. Equation 14 expresses the relationship. ⎧∞ ⎫ E = ∫ p (t )dt = Lim ⎨∑ p (nT ) × T ⎬ t →0 ⎩ n =1 ⎭ (14) where: where: P is power. E is energy. n is the discrete time sample number. T is the sample period. Conversely, energy is given as the integral of power. The discrete time sample period (T) for the accumulation register in the ADE7169F16 is 1.22μs (5/MCLK). As well as calculating the energy, this integration removes any sinusoidal components that might be in the active power signal. Figure 39 shows this discrete time integration or accumulation. The active power signal in the waveform register is continuously added to the internal active energy register. ∫ E = Pdt (13) The ADE7169F16 achieves the integration of the active power signal by continuously accumulating the active power signal in an internal non-readable 49-bit energy register. The active energy register (WATTHR[23:0]) represents the upper 24 bits of Rev. PrD | Page 53 of 140 ADE7169F16 Preliminary Technical Data The Active Energy accumulation depends on the setting of the POAM and ABSAM bits in the ACCMODE register (0x0F). When both bits are cleared, the addition is signed and therefore negative energy is subtracted from the active energy contents. When both bits are set, the ADE7169F16 is set to be in the more restrictive mode, the Positive Only Accumulation mode. When POAM bit in the ACCMODE register (0x0F) is set, only positive power contributes to the active energy accumulation — see the Watt positive-only accumulation mode section. When ABSAM bit in the ACCMODE register (0x0F) is set, the absolute active power is used for the active energy accumulation — see the Watt absolute accumulation mode section. The output of the multiplier is divided by WDIV. If the value in the WDIV register is equal to 0, then the internal active energy register is divided by 1. WDIV is an 8-bit unsigned register. After dividing by WDIV, the active energy is accumulated in a 49-bit internal energy accumulation register. The upper 24 bits of this register are accessible through a read to the active energy register (WATTHR[23:0]). A read to the RWATTHR register returns the content of the WATTHR register and the upper 24 bits of the internal register are cleared. As shown in Figure 39, the active power signal is accumulated in an internal 49-bit signed register. The active power signal can be read from the waveform register by setting the WAVMODE register (0x0D) and setting the WFSM bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB). Like the current and voltage channels waveform sampling modes, the waveform date is available at sample rates of 27.9 kSPS, 14 kSPS, 7 kSPS, or 3.5 kSPS. Figure 40 shows this energy accumulation for full-scale signals (sinusoidal) on the analog inputs. The three curves displayed illustrate the minimum period of time it takes the energy register to roll over when the active power gain register contents are 0x7FF, 0x000, and 0x800. The watt gain register is used to carry out power calibration in the ADE7169F16. As shown, the fastest integration time occurs when the watt gain register is set to maximum full scale, i.e., 0x7FF. WATTHR [23:0] 0x7F,FFFF WGAIN = 0x7FF WGAIN = 0x000 WGAIN = 0x800 0x3F,FFFF 0x00,0000 3.41 6.82 10.2 13.7 Figure 40. Energy Register Rollover Time for Full-Scale Power (Minimum and Maximum Power Gain) Note that the energy register contents rolls over to full-scale negative (0x800000) and continues to increase in value when the power or energy flow is positive—see Figure 40. Conversely, if the power is negative, the energy register underflows to fullscale positive (0x7FFFFF) and continues to decrease in value. By using the interrupt enable register, the ADE7169F16 can be configured to issue an ADE interrupt to the 8052 core when the active energy register is half-full (positive or negative) or when an overflow or underflow occurs. Integration time under steady Load As mentioned in the last section, the discrete time sample period (T) for the accumulation register is 1.22 μs (5/CLKIN). With full-scale sinusoidal signals on the analog inputs and the WGAIN register set to 0x000, the average word value from each LPF2 is 0xCCCCD—see Figure 37. The maximum positive value that can be stored in the internal 49-bit register is 248 or 0xFFFF,FFFF,FFFF before it overflows. The integration time under these conditions with WDIV = 0 is calculated as follows: Time = 0 xFFFF, FFFF, FFFF × 1.22 μs = 409.6 s = 6.82 min (15) 0 xCCCCD When WDIV is set to a value different from 0, the integration time varies, as shown in Equation 16. Time = TimeWDIV =0 × WDIV (16) Active energy accumulation modes Watt signed accumulation mode The ADE7169F16 active energy default accumulation mode is a signed accumulation based on the active power information. Watt positive-only accumulation mode The ADE7169F16 is placed in positive-only accumulation mode by setting the POAM bit in the ACCMODE register (0x0F). In positive-only accumulation mode, the energy accumulation is done only for positive power, ignoring any occurrence of negative power above or below the no-load threshold, as shown in Figure 41. The CF pulse also reflects this accumulation method when in this mode. The default setting for this mode is off. Detection of the transitions in the direction of power flow, and no-load threshold are active in this mode. TIME (minutes) 0x40,0000 0x80,0000 Rev. PrD | Page 54 of 140 Preliminary Technical Data ADE7169F16 Active Power Calculation section. This pulse frequency output uses the calibrated signal after WGAIN and its behavior is consistent with the setting of the active energy accumulation mode in the ACCMODE register (0x0F). The pulse output is active low and should be preferably connected to an LED as shown on Figure 53. ACTIVE ENERGY Line cycle active energy accumulation mode NO-LOAD THRESHOLD ACTIVE POWER NO-LOAD THRESHOLD APSIGN Flag POS NEG POS INTERRUPT STATUS REGISTERS Figure 41. Energy Accumulation in Positive-Only Accumulation Mode Watt absolute accumulation mode The ADE7169F16 is placed in absolute accumulation mode by setting the ABSAM bit in the ACCMODE register (0x0F). In absolute accumulation mode, the energy accumulation is done using the absolute active power, ignoring any occurrence of power below the no-load threshold, as shown in Figure 42. The CF pulse also reflects this accumulation method when in this mode. The default setting for this mode is off. Detection of the transitions in the direction of power flow, and no-load threshold are active in this mode. ACTIVE ENERGY In line cycle energy accumulation mode, the energy accumulation of the ADE7169F16 can be synchronized to the voltage channel zero crossing so that active energy can be accumulated over an integral number of half line cycles. The advantage of summing the active energy over an integer number of line cycles is that the sinusoidal component in the active energy is reduced to 0. This eliminates any ripple in the energy calculation. Energy is calculated more accurately and in a shorter time because the integration period can be shortened. By using the line cycle energy accumulation mode, the energy calibration can be greatly simplified, and the time required to calibrate the meter can be significantly reduced. In line cycle energy accumulation mode, the ADE7169F16 accumulates the active power signal in the LWATTHR register for an integral number of line cycles, as shown in Figure 44. The number of half line cycles is specified in the LINCYC register. The ADE7169F16 can accumulate active power for up to 65,535 half line cycles. Because the active power is integrated on an integral number of line cycles, at the end of a line cycle energy accumulation cycle the CYCEND flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE) is set. If the CYCEND enable bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) is set, the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the CYCEND status bit is cleared—see Energy measurement interrupts section. Another calibration cycle will start as soon as the CYCEND flag is set. If the LWATTHR register is not read before a new CYCEND flag is set, the LWATTHR register will be overwritten by a new value. When a new half line cycles is written in LINECYC register, the LWATTHR register is reset and a new accumulation start at the next zero-crossing. The number of half line cycles is then counted until LINCYC is reached . This implementation provides a valid measurement at the first CYCEND interrupt after writing to the LINCYC register – see Figure 43. The line active energy accumulation uses the same signal path as the active energy accumulation. The LSB size of these two registers is equivalent. NO-LOAD THRESHOLD ACTIVE POWER NO-LOAD THRESHOLD APSIGN Flag APNOLOAD POS NEG POS APNOLOAD INTERRUPT STATUS REGISTERS Figure 42. Energy Accumulation in Absolute Accumulation Mode Active energy Pulse output ADE7169F16 also provides all the circuitry to have a pulse output that frequency is proportional to Active power – see Rev. PrD | Page 55 of 140 ADE7169F16 Preliminary Technical Data where: n is an integer. T is the line cycle period. LWATTHR REGISTER Since the sinusoidal component is integrated over an integer number of line cycles, its value is always 0. Therefore, CYCEND IRQ nT LINECYC VALUE E= Figure 43. Energy Accumulation when LINECYC changed E(t) = VInT ⎫ ⎧ ⎪nT ⎪ ⎪⎪ ⎪⎪ VI E(t) = VI dt − ⎨ cos (2πft)dt 2⎬ ⎪ ⎛ f ⎞ ⎪0 0 ⎟ ⎪ ⎪ 1+ ⎜ ⎪⎩ ⎝ 8.9 ⎠ ⎪⎭ ∫ (21) 0 From Equations 13 and 18, nT ∫VIdt + 0 ∫ (22) (20) TO DIGITAL TO FREQUENCY CONVERTER WGAIN[11:0] OUTPUT FROM LPF2 + % WATTOS[15:0] + 0 WDIV[7:0] 23 LPF1 FROM VOLTAGE CHANNEL ADC 48 ZERO CROSS DETECTION 0 LWATTHR [23:0] CALIBRATION CONTROL ACCUMULATE ACTIVE ENERGY IN INTERNAL REGISTER AND UPDATE THE LWATTHR REGISTER AT THE END OF LINCYC HALF LINE CYCLES LINCYC [15:0] Figure 44. Line Cycle Active Energy Accumulation Note that in this mode, the 16-bit LINCYC register can hold a maximum value of 65,535. In other words, the line energy accumulation mode can be used to accumulate active energy for a maximum duration over 65,535 half line cycles. At 60 Hz line frequency, it translates to a total duration of 65,535/120 Hz = 546 seconds. v(t) = 2V sin(ωt + θ) i(t) = 2 I sin(ωt ) π⎞ ⎛ i′(t ) = 2 I sin ⎜ ωt + ⎟ 2⎠ ⎝ REACTIVE POWER CALCULATION where: Reactive power is defined as the product of the voltage and current waveforms when one of these signals is phase-shifted by 90°. The resulting waveform is called the instantaneous reactive power signal. Equation 25 gives an expression for the instantaneous reactive power signal in an ac system when the phase of the current channel is shifted by +90°. θ is the phase difference between the voltage and current channel. V is the rms voltage. I is the rms current. q(t) = v(t) × i’(t) Rev. PrD | Page 56 of 140 (23) (24) (25) Preliminary Technical Data ADE7169F16 q(t) = VI sin (θ) + VI sin (2ωt + θ) The average reactive power over an integral number of lines (n) is given in Equation 26. Q= 1 nT nT ∫ q(t )dt = VI sin(θ ) (26) 0 where: T is the line cycle period. q is referred to as the reactive power. Note that the reactive power is equal to the dc component of the instantaneous reactive power signal q(t) in Equation 25. This is the relationship used to calculate reactive power in the ADE7169F16. The instantaneous reactive power signal q(t) is generated by multiplying Voltage and Current channels. In this case, the phase of Current channel is shifted by +90°. The dc component of the instantaneous reactive power signal is then extracted by a low-pass filter in order to obtain the reactive power information – see Figure 45. In addition, the phase shifting filter has a non-unity magnitude response. Because the phase-shift filter has a large attenuation at high frequency, the reactive power is primarily for the calculation at line frequency. The effect of harmonics is largely ignored in the reactive power calculation. Note that because of the magnitude characteristic of the phase shifting filter, the weight of the reactive power is slightly different from the active power calculation – see Energy register scaling. The frequency response of the LPF in the reactive signal path is identical to that of the LPF2 used in the average active power calculation. Since LPF2 does not have an ideal “brick wall” frequency response—see Figure 38, the reactive power signal has some ripple due to the instantaneous reactive power signal. This ripple is sinusoidal and has a frequency equal to twice the line frequency. Because the ripple is sinusoidal in nature, it is removed when the reactive power signal is integrated to calculate energy—see the Reactive Power Calculation section. The reactive power signal can be read from the waveform register by setting the WAVMODE register (0x0D) and setting the WFSM bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB). Like the current and voltage channels waveform sampling modes, the waveform date is available at sample rates of 27.9 kSPS, 14 kSPS, 7 kSPS, or 3.5 kSPS. Reactive power gain calibration Figure 45 shows the signal processing chain for the reactive power calculation in the ADE7169F16. As explained, the reactive power is calculated by low-pass filtering the instantaneous reactive power signal. Note that when reading the waveform samples from the output of LPF2, the gain of the reactive energy can be adjusted by using the multiplier and var gain register (VARGAIN[11:0]). The gain is adjusted by writing a twos complement 12-bit word to the var gain register. Equation 11 shows how the gain adjustment is related to the contents of the watt gain register: ⎛ ⎧ VARGAIN ⎫ ⎞ Output VARGAIN = ⎜⎜ Re active Power × ⎨1 + ⎬ ⎟⎟ 212 ⎩ ⎭⎠ ⎝ (11) The resolution of the VARGAIN register is the same as the WGAIN register – see Active power gain calibration section. VARGAIN can be used to calibrate the reactive power (or energy) calculation in the ADE7169F16. Reactive power offset calibration The ADE7169F16 also incorporates a reactive power offset register (VAROS[15:0]). This is a signed twos complement 16bit register that can be used to remove offsets in the reactive power calculation—see Figure 45. An offset could exist in the reactive power calculation due to crosstalk between channels on the PCB or in the IC itself. The offset calibration allows the contents of the reactive power register to be maintained at 0 when no power is being consumed. The 256 LSBs (VAROS = 0x100) written to the reactive power offset register are equivalent to 1 LSB in the waveform sample register. Sign of Reactive Power Calculation Note that the average reactive power is a signed calculation. The phase shift filter has –90° phase shift when the integrator is enabled, and +90° phase shift when the integrator is disabled. Table 41 summarizes the relationship between the phase difference between the voltage and the current and the sign of the resulting VAR calculation. Table 41. Sign of Reactive Power Calculation Angle Between 0° to 90° Between –90° to 0° Between 0° to 90° Between –90° to 0° Integrator Off Off On On Sign Positive Negative Positive Negative Reactive power sign detection The ADE7169F16 detects a change of sign in the reactive power. The VARSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) record when a change of sign according to bit VARSIGN in the ACCMODE register (0x0F) has occurred. If the VARSIGN bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the VARSIGN status bit is cleared—see Energy measurement interrupts section. When VARSIGN in the ACCMODE register (0x0F) is cleared Rev. PrD | Page 57 of 140 ADE7169F16 Preliminary Technical Data threshold. When the reactive power is below the no-load threshold, the RNOLOAD flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set. If the RNOLOAD bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the RNOLOAD status bit is cleared—see Energy measurement interrupts section. (default), the VARSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when a transition from positive to negative reactive power has occurred. When VARSIGN in the ACCMODE register (0x0F) is set, the VARSIGN flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) will be set when a transition from negative to positive reactive power has occurred. The No-load threshold level is selectable by setting bits RNOLOAD in the NLMODE register (0x0E). Setting these bits to 0b00 disable the no-load detection and setting them to 0b01, 0b10 or 0b11 set the no-load detection threshold to 0.015%, 0.0075% and 0.0037% of the full-scale output frequency of the multiplier respectively. Reactive power no-Load detection The ADE7169F16 includes a no-load threshold feature on the reactive energy that eliminates any creep effects in the meter. The ADE7169F16 accomplishes this by not accumulating reactive energy if the multiplier output is below the no-load FOR WAVEF0RM SAMPLING CURRENT CHANNEL HPF 0 VAROS[15:0] 90° PHASE SHIFTING FILTER sgn 26 25 Π 2 LPF2 + VOLTAGE CHANNEL VARHR[23:0] 23 UPPER 24 BITS ARE ACCESSIBLE THROUGH VARHR[23:0] REGISTER 2-6 2-7 2-8 VARDIV[7:0] + + 48 0 % + PHCAL[7:0] VARGAIN[11:0] REACTIVE POWER SIGNAL 5 CLKIN OUTPUT LPF2 T TO DIGITAL TO FREQUENCY CONVERTER OUTPUTS FROM THE LPF2 ARE ACCUMULATED (INTEGRATED) IN THE INTERNAL REACTIVE ENERGY REGISTER WAVEFORM REGISTER VALUES TIME (nT) Figure 45. ADE7169F16 Reactive Energy Calculation Reactive Energy Calculation As for active energy, the ADE7169F16 achieves the integration of the reactive power signal by continuously accumulating the reactive power signal in an internal non-readable 49-bit energy register. The reactive energy register (VARHR[23:0]) represents the upper 24 bits of this internal register. The discrete time sample period (T) for the accumulation register in the ADE7169F16 is 1.22μs (5/MCLK). As well as calculating the energy, this integration removes any sinusoidal components that might be in the active power signal. Figure 45 shows this discrete time integration or accumulation. The reactive power signal in the waveform register is continuously added to the internal reactive energy register. The reactive Energy accumulation depends on the setting of the SAVARM and ABSVARM bits in the ACCMODE register (0x0F). When both bits are cleared, the addition is signed and therefore negative energy is subtracted from the reactive energy contents. When both bits are set, the ADE7169F16 is set to be in the more restrictive mode, the Absolute Accumulation mode. When SAVARM bit in the ACCMODE register (0x0F) is set, the reactive power is accumulated depending on the sign of the active power. When active power is positive, the reactive power is added as it is to the reactive energy register. When active power is negative, the reactive power is subtracted to the reactive energy accumulator – see VAR anti-tamper accumulation mode. When ABSVARM bit in the ACCMODE register (0x0F) is set, the absolute reactive power is used for the reactive energy accumulation—see the VAR absolute accumulation mode section. The output of the multiplier is divided by VARDIV. If the value in the VARDIV register is equal to 0, then the internal reactive Rev. PrD | Page 58 of 140 Preliminary Technical Data ADE7169F16 energy register is divided by 1. VARDIV is an 8-bit unsigned register. After dividing by VARDIV, the reactive energy is accumulated in a 49-bit internal energy accumulation register. The upper 24 bits of this register are accessible through a read to the reactive energy register (VARHR[23:0]). A read to the RVARHR register returns the content of the VARHR register and the upper 24 bits of the internal register are cleared. As shown in Figure 45, the reactive power signal is accumulated in an internal 49-bit signed register. The reactive power signal can be read from the waveform register by setting the WAVMODE register (0x0D) and setting the WFSM bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB). Like the current and voltage channels waveform sampling modes, the waveform date is available at sample rates of 27.9 kSPS, 14 kSPS, 7 kSPS, or 3.5 kSPS. Figure 40 shows this energy accumulation for full-scale signals (sinusoidal) on the analog inputs. These curves also apply for the reactive energy accumulation Note that the energy register contents rolls over to full-scale negative (0x800000) and continues to increase in value when the power or energy flow is positive. Conversely, if the power is negative, the energy register underflows to full-scale positive (0x7FFFFF) and continues to decrease in value. By using the interrupt enable register, the ADE7169F16 can be configured to issue an ADE interrupt to the 8052 core when the reactive energy register is half-full (positive or negative) or when an overflow or underflow occurs. (0x0F). In this mode, the reactive power is accumulated depending on the sign of the active power. When active power is positive, the reactive power is added as it is to the reactive energy register. When active power is negative, the reactive power is subtracted to the reactive energy accumulator – see Figure 46. The CF pulse also reflects this accumulation method when in this mode. The default setting for this mode is off. Transitions in the direction of power flow, and no-load threshold are active in this mode. REACTIVE ENERGY NO-LOAD THRESHOLD REACTIVE POWER NO-LOAD THRESHOLD NO-LOAD THRESHOLD ACTIVE POWER Integration time under steady Load NO-LOAD THRESHOLD As mentioned in the active energy section, the discrete time sample period (T) for the accumulation register is 1.22 μs (5/CLKIN). With full-scale sinusoidal signals on the analog inputs and the VARGAIN and VARDIV registers set to 0x000, the integration time before the reactive energy register overflows is calculated as follows: Time = APSIGN Flag POS 0 xFFFF, FFFF, FFFF × 1.22 μs = 409.6 s = 6.82 min (15) 0 xCCCCD When VARDIV is set to a value different from 0, the integration time varies, as shown in Equation 16. Time = Time WDIV =0 × VARDIV NEG POS INTERRUPT STATUS REGISTERS (16) Reactive energy accumulation modes VAR signed accumulation mode The ADE7169F16 reactive energy default accumulation mode is a signed accumulation based on the reactive power information. Figure 46. Reactive Energy Accumulation in Anti-tamper Accumulation Mode VAR absolute accumulation mode The ADE7169F16 is placed in absolute accumulation mode by setting the ABSVARM bit in the ACCMODE register (0x0F). In absolute accumulation mode, the reactive energy accumulation is done using the absolute reactive power, ignoring any occurrence of power below the no-load threshold, as shown in Figure 42 for the active energy. The CF pulse also reflects this accumulation method when in this mode. The default setting for this mode is off. Transitions in the direction of power flow, and no-load threshold are active in this mode. VAR anti-tamper accumulation mode The ADE7169F16 is placed in VAR anti-tamper accumulation mode by setting the SAVARM bit in the ACCMODE register Rev. PrD | Page 59 of 140 ADE7169F16 Preliminary Technical Data Active energy Line cycle accumulation mode – see Line cycle active energy accumulation mode section. In line cycle energy accumulation mode, the ADE7169F16 accumulates the reactive power signal in the LVARHR register for an integral number of line cycles, as shown in Figure 48. The number of half line cycles is specified in the LINCYC register. The ADE7169F16 can accumulate active power for up to 65,535 half line cycles. Because the reactive power is integrated on an integral number of line cycles, at the end of a line cycle energy accumulation cycle the CYCEND flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE). If the CYCEND enable bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) is set, the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the CYCEND status bit is cleared—see Energy measurement interrupts section. Another calibration cycle will start as soon as the CYCEND flag is set. If the LVARHR register is not read before a new CYCEND flag is set, the LVARHR register will be overwritten by a new value. REACTIVE ENERGY NO-LOAD THRESHOLD REACTIVE POWER NO-LOAD THRESHOLD Figure 47. Reactive Energy Accumulation in Absolute Accumulation Mode Reactive energy Pulse output ADE7169F16 also provides all the circuitry to have a pulse output those frequency is proportional to reactive power – see Energy-to-Frequency Conversion section. This pulse frequency output uses the calibrated signal after VARGAIN and its behavior is consistent with the setting of the reactive energy accumulation mode in the ACCMODE register (0x0F). The pulse output is active low and should be preferably connected to an LED as shown on Figure 53. As for LWATTHR, when a new half line cycles is written in LINCYC register, the LVARHR register is reset and a new accumulation start at the next zero-crossing. The number of half line cycles is then counted until LINCY is reached. This implementation provides a valid measurement at the first CYCEND interrupt after writing to the LINCYC register. The line reactive energy accumulation uses the same signal path as the reactive energy accumulation. The LSB size of these two registers is equivalent. Line cycle reactive energy accumulation mode In line cycle energy accumulation mode, the energy accumulation of the ADE7169F16 can be synchronized to the voltage channel zero crossing so that reactive energy can be accumulated over an integral number of half line cycles. The advantage of this mode is similar to the ones explained in the TO DIGITAL TO FREQUENCY CONVERTER VARGAIN[11:0] OUTPUT FROM LPF2 + % VAROS[15:0] + 0 VARDIV[7:0] 23 LPF1 FROM VOLTAGE CHANNEL ADC 48 ZERO CROSS DETECTION 0 LVARHR [23:0] CALIBRATION CONTROL ACCUMULATE REACTIVE ENERGY IN INTERNAL REGISTER AND UPDATE THE LVARHR REGISTER AT THE END OF LINCYC HALF LINE CYCLES LINCYC [15:0] Figure 48 Line Cycle . Reactive Energy Accumulation Mode APPARENT POWER CALCULATION The apparent power is defined as the maximum power that can be delivered to a load. Vrms and Irms are the effective voltage and current delivered to the load; the apparent power (AP) is defined Rev. PrD | Page 60 of 140 Preliminary Technical Data ADE7169F16 as Vrms × Irms. Equation 28 gives an expression of the instantaneous power signal in an ac system with a phase shift. v(t ) = 2 Vrms sin(ω t ) i(t) = 2 I rms sin(ωt + θ) (27) p (t ) = v (t ) × i (t ) p(t) = Vrms I rms cos(θ) − Vrms I rms cos(2ωt + θ) (28) value—see Current Channel RMS Calculation and Voltage channel RMS Calculation sections. The voltage and current channels rms values are then multiplied together in the apparent power signal processing. Since no additional offsets are created in the multiplication of the rms values, there is no specific offset compensation in the apparent power signal processing. The offset compensation of the apparent power measurement is done by calibrating each individual rms measurement. Apparent Energy Calculation The apparent power is defined as Vrms × Irms. This expression is independent from the phase angle between the current and the voltage. The apparent energy is given as the integral of the apparent power. ∫ Apparent Energy = Apparent Power (t ) dt Figure 49 illustrates the signal processing in each phase for the calculation of the apparent power in the ADE7169F16. APPARENT POWER SIGNAL (P) Irms CURRENT RMS SIGNAL – i(t) MULTIPLIER 0x1A36E2 0x1CF68C 0x00 Vrms VAGAIN VOLTAGE RMS SIGNAL – v(t) 0x1CF68C 0x00 The ADE7169F16 achieves the integration of the apparent power signal by continuously accumulating the apparent power signal in an internal 48-bit register. The apparent energy register (VAHR[23:0]) represents the upper 24 bits of this internal register. This discrete time accumulation or summation is equivalent to integration in continuous time. Equation 31 expresses the relationship ⎧⎪ ∞ ⎪⎫ Apparent Energy = Lim ⎨ Apparent Power ( nT ) × T ⎬ T →0 ⎪ ⎪⎭ ⎩ n =0 TO DIGITAL TO FREQUENCY CONVERTER ∑ Figure 49. Apparent Power Signal Processing The apparent power signal can be read from the waveform register by setting the WAVMODE register (0x0D) and setting the WFSM bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB). Like the current and voltage channels waveform sampling modes, the waveform date is available at sample rates of 27.9 kSPS, 14 kSPS, 7 kSPS, or 3.5 kSPS. The gain of the apparent energy can be adjusted by using the multiplier and VAGAIN register (VAGAIN[11:0]). The gain is adjusted by writing a twos complement, 12-bit word to the VAGAIN register. Equation 29 shows how the gain adjustment is related to the contents of the VAGAIN register. ⎛ ⎧ VAGAIN ⎫ ⎞ OutputVAGAIN = ⎜⎜ Apparent Power × ⎨1 + ⎬ ⎟⎟ (29) 212 ⎭ ⎠ ⎩ ⎝ For example, when 0x7FF is written to the VAGAIN register, the power output is scaled up by 50%. 0x7FF = 2047d, 2047/212 = 0.5. Similarly, 0x800 = –2047d (signed twos complement) and power output is scaled by –50%. Each LSB represents 0.0244% of the power output. The apparent power is calculated with the current and voltage rms values obtained in the rms blocks of the ADE7169F16. (30) (31) where: n is the discrete time sample number. T is the sample period. The discrete time sample period (T) for the accumulation register in the ADE7169F16 is 1.22 μs (5/MCLK). Figure 50 shows this discrete time integration or accumulation. The apparent power signal is continuously added to the internal register. This addition is a signed addition even if the apparent energy remains theoretically always positive. The 49 bits of the internal register are divided by VADIV. If the value in the VADIV register is 0, then the internal apparent energy register is divided by 1. VADIV is an 8-bit unsigned register. The upper 24 bits are then written in the 24-bit apparent energy register (VAHR[23:0]). RVAHR register (24 bits long) is provided to read the apparent energy. This register is reset to 0 after a read operation. Apparent Power Offset Calibration Each rms measurement includes an offset compensation register to calibrate and eliminate the dc component in the rms Rev. PrD | Page 61 of 140 ADE7169F16 Preliminary Technical Data VAHR[23:0] 23 time varies, as shown in Equation 33. 0 Time = TimeWDIV = 0 × VADIV 48 0 VADIV APPARENT POWER % 48 + 0 (33) Apparent energy Pulse output ADE7169F16 also provides all the circuitry to have a pulse output those frequency is proportional to apparent power – see Energy-to-Frequency Conversion section. This pulse frequency output uses the calibrated signal after VAGAIN. This output can also be used to output a pulse those frequency is proportional to Irms. + APPARENT POWER SIGNAL = P T APPARENT POWER ARE ACCUMULATED (INTEGRATED) IN THE APPARENT ENERGY REGISTER Line Apparent Energy Accumulation The ADE7169F16 is designed with a special apparent energy accumulation mode, which simplifies the calibration process. By using the on-chip zero-crossing detection, the ADE7169F16 accumulates the apparent power signal in the LVAHR register for an integral number of half cycles, as shown in Figure 51. The line apparent energy accumulation mode is always active. TIME (nT) Figure 50. ADE7169F16 Apparent Energy Calculation Note that the apparent energy register is unsigned. By setting the VAEHF and VAEOF bits in the Interrupt Enable Register 2 SFR (MIRQENM, 0xDA), the ADE7169F16 can be configured to issue an ADE interrupt to the 8052 core when the apparent energy register is half full or when an overflow occurs. The half full interrupt for the unsigned apparent energy register is based on 24 bits as opposed to 23 bits for the signed active energy register. Integration Times under Steady Load As mentioned in the last section, the discrete time sample period (T) for the accumulation register is 1.22 μs (5/MCLK). With full-scale sinusoidal signals on the analog inputs and the VAGAIN register set to 0x000, the average word value from apparent power stage is 0x1A36E2—see the section. The maximum value that can be stored in the apparent energy register before it overflows is 224 or 0xFF,FFFF. The average word value is added to the internal register, which can store 248 or 0xFFFF,FFFF,FFFF before it overflows. Therefore, the integration time under these conditions with VADIV = 0 is calculated as follows: Time = The pulse output is active low and should be preferably connected to an LED as shown on Figure 53. 0 xFFFF, FFFF, FFFF × 1.22 μs = 199 s = 3.33 min (32) 0 xD 055 The number of half line cycles is specified in the LINCYC register, which is an unsigned 16-bit register. The ADE7169F16 can accumulate apparent power for up to 65535 combined half cycles. Because the apparent power is integrated on the same integral number of line cycles as the line active and reactive energy register, these values can be compared easily. The energies are calculated more accurately because of this precise timing control and provide all the information needed for reactive power and power factor calculation. At the end of an energy calibration cycle, the CYCEND flag in the Interrupt Status Register 3 SFR (MIRQSTH, 0xDE) is set. If the CYCEND enable bit in the Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) is enabled, the 8052 core has a pending ADE interrupt. As for LWATTHR, when a new half line cycles is written in LINECYC register, the LVAHR register is reset and a new accumulation start at the next zero-crossing. The number of half line cycles is then counted until LINCY is reached. This implementation provides a valid measurement at the first CYCEND interrupt after writing to the LINCYC register. The line apparent energy accumulation uses the same signal path as the apparent energy accumulation. The LSB size of these two registers is equivalent. When VADIV is set to a value different from 0, the integration Rev. PrD | Page 62 of 140 Preliminary Technical Data ADE7169F16 APPARENT POWER + 48 + 0 % LVAHR REGISTER IS UPDATED EVERY LINCYC ZERO CROSSINGS WITH THE TOTAL APPARENT ENERGY DURING THAT DURATION VADIV[7:0] 23 LPF1 FROM VOLTAGE CHANNEL ADC ZERO-CROSSING DETECTION 0 LVAHR [23:0] CALIBRATION CONTROL LINCYC [15:0] Figure 51. ADE7169F16 Line cycle Apparent Energy Accumulation Apparent power no-Load detection MODE2 Register 0x0C The ADE7169F16 includes a no-load threshold feature on the apparent energy that eliminates any creep effects in the meter. The ADE7169F16 accomplishes this by not accumulating energy if the multiplier output is below the no-load threshold. When the apparent power is below the no-load threshold, the VANOLOAD flag in the Interrupt Status Register 1 SFR (MIRQSTL, 0xDC) is set. If the VANOLOAD bit is set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the APNOLOAD status bit is cleared—see Energy measurement interrupts section. The No-load threshold level is selectable by setting bits VANOLOAD in the NLMODE register (0x0E). Setting these bits to 0b00 disable the no-load detection and setting them to 0b01, 0b10 or 0b11 set the no-load detection threshold to 0.030%, 0.015% and 0.0075% of the full-scale output frequency of the multiplier respectively. This no-load threshold can also be applied to the Irms pulse output when selected. The level of no-load threshold is the same as for the Apparent energy in this case. ENERGY-TO-FREQUENCY CONVERSION ADE7169F16 also provides two energy-to-frequency conversions for calibration purposes. After initial calibration at manufacturing, the manufacturer or end customer often verify the energy meter calibration. One convenient way to verify the meter calibration is for the manufacturer to provide an output frequency, which is proportional to the active, reactive, apparent power or Irms under steady load conditions. This output frequency can provide a simple, single-wire, optically isolated interface to external calibration equipment. Figure 52 illustrates the energy-to-frequency conversion in the ADE7169F16. CFxSEL[1:0] VARMSCFCON Irms CFxNUM VA VAR DFC WATT CFxDEN CFx Pulse output Figure 52. ADE7169F16 Energy-to-Frequency Conversion Two digital-to-frequency converters (DFC) are used to generate the pulsed outputs. When WDIV =0 or 1, the DFC generates a pulse each time 1 LSB in the energy register is accumulated. An output pulse is generated when CFxDEN/CFxNUM number of pulses are generated at the DFC output. Under steady load conditions, the output frequency is proportional to the active, reactive, Apparent power or Irms depending on the CFxSEL bit in the MODE2 register (0x0C). Both pulse outputs can be enabled or disabled by clearing or setting respectively bits DISCF1 and DISCF2 in the MODE1 register (0x0B). Both pulse outputs set a separate flag in the Interrupt Status Register 2 SFR (MIRQSTM, 0xDD), CF1 and CF2. If CF1 and CF2 enable bits in the Interrupt Enable Register 2 SFR (MIRQENM, 0xDA) are set, the 8052 core has a pending ADE interrupt. The ADE interrupt stays active until the CF1 or CF2 status bits are cleared—see Energy measurement interrupts section. Pulse output configuration The two pulse outputs circuitry have separate configuration bits in the MODE2 register (0x0C). Setting CFxSEL bits to 0b00, 0b01 or 0b1x configure the DFC to create a pulse output Rev. PrD | Page 63 of 140 ADE7169F16 Preliminary Technical Data proportional to Active power, reactive power, or Apparent/Irms respectively. no need to do reactive or apparent gai adjustment. The selection between Irms and Apparent power is done by the VARMSCFCON bit in the MODE2 register (0x0C). With this selection, CF2 cannot be proportional to apparent power if CF1 is proportional to Irms and vice-versa. Line Frequency = 50Hz Pulse output characteristic The pulse output for both DFC stays low for 90ms if the pulse period is larger than 180ms (5.56Hz). If the pulse period is smaller than 180ms, the duty cycle of the pulse output is 50%. The pulse output is active low and should be preferably connected to an LED as shown on Figure 53. VDD Table 42. Energy Registers scaling Line Frequency = 60Hz Integrator OFF VAR = 0.9952 × WATT VAR = 0.9949 × WATT VA = 0.9978 × WATT VA = 1.0015 × WATT Integrator ON VAR = 0.9997 × WATT VAR = 0.9999 × WATT VA = 0.9977 × WATT VA = 1.0015 × WATT Table 43. Gain compensation adjustments CF Line Frequency = 50Hz Line Frequency = 60Hz Integrator OFF Figure 53. CF Pulse output The maximum output frequency, with ac input signals at full scale and CFxNUM = 0x00 and CFxDEN = 0x00, is approximately 21.1 kHz. The ADE7169F16 incorporates two registers, CFxNUM[15:0] and CFxDEN[15:0] per DFC, to set the CFx frequency. These are unsigned 16-bit registers, which can be used to adjust the CFx frequency to a wide range of values. These frequencyscaling registers are 16-bit registers, which can scale the output frequency by 1/216 to 1 with a step of 1/216. If the value 0 is written to any of these registers, the value 1 would be applied to the register. The ratio CFxNUM / CFxDEN should be smaller than 1 to ensure proper operation. If the ratio of the registers CFxNUM / CFxDEN is greater than 1, the register values would be adjusted to a ratio of 1. For example, if the output frequency is 1.562 kHz while the contents of CFxDEN are 0 (0x000), then the output frequency can be set to 6.1 Hz by writing 0xFF to the CFxDEN register. ENERGY REGISTER SCALING The ADE7169F16 provides measurements of active, reactive, and apparent energies that use separate paths and filtering for calculation. The difference in data paths can result in small differences in LSB weight between active, reactive and apparent energy registers. These measurements are internally compensated so the scaling is nearly one to one. The relationship between the registers is show in Table 42. In Table 43, the relationship between WATTGAIN, VARGAIN and VAGAIN is given. These relationships can be used for calibration and simplify the adjustment of VAR and VA gains. As VAR and VA gains can be deducted from WGAIN, there is VARGAIN = 19.76 + WGAIN/0.9952 VARGAIN = 21 + WGAIN/0.9949 VAGAIN = 9.03 + WGAIN/0.9978 VAGAIN = -60.53 + WGAIN/1.0015 Integrator ON VARGAIN = 1.23 + WGAIN/0.9997 VARGAIN = 0.41 + WGAIN/0.9999 VAGAIN = 9.44 + WGAIN/0.9977 VAGAIN = -60.53 + WGAIN/1.0015 ENERGY MEASUREMENT INTERRUPTS The Energy Measurement part of the ADE7169F16 has its own interrupt vector for the 8052 core – Vector address 0x004B – see Interrupt Vectors section. The bits set in the Interrupt Enable Register 1 SFR (MIRQENL, 0xD9), Interrupt Enable Register 2 SFR (MIRQENM, 0xDA), and Interrupt Enable Register 3 SFR (MIRQENH, 0xDB) enables the energy measurement interrupts that are allowed to interrupt the 8052 core. If an event is not enabled, it cannot create a system interrupt. The ADE interrupt stays active until the status bit that has created the interrupt is cleared. Two methods can be used to clear the ADE interrupt: - When bit 6 (ADEIAUTCLR) of the Power Management Interrupt Enable SFR (IPSME, 0xEC) is set, all the status bits of the ADE irq status register (1, 2 or 3) are cleared when the register is read. - When bit 6 (ADEIAUTCLR) of the Power Management Rev. PrD | Page 64 of 140 Preliminary Technical Data ADE7169F16 Interrupt Enable SFR (IPSME, 0xEC) is cleared, a status bit of the ADE irq status register (1, 2 or 3) is cleared when a zero is written to this register bit. Rev. PrD | Page 65 of 140 Preliminary Technical Data ADE7169F16 TEMPERATURE, BATTERY AND SUPPLY VOLTAGE MEASUREMENTS variations in voltage. Battery measurements allow low battery detection to be performed. All ADC measurements are configured through the SFR detailed in Table 44. The ADE7169F16 includes temperature measurements as well as battery and supply voltage measurements. These measurements enable many forms of compensation. The temperature and supply voltage measurements can be used to compensate external circuitry. The RTC can be calibrated over temperature to ensure that it doesn’t drift. Supply voltage measurements allow the LCD contrast to be maintained despite The temperature, battery and supply voltage measurements can be configured to still be functional in PSM1 and PSM2. This is done bit setting bit RTCEN in the RTC Configuration SFR (TIMECON, 0xA1). Maintaining the temperature measurement active ensures that it is not necessary to wait for the temperature measurement to settle before using it for compensation. Table 44. Temperature, Battery and Supply voltage measurement SFRs SFR address (hex) R/W Name Description 0xF9 R/W STRBPER Strobing period configuration 0xF3 R/W DIFFPROG Temperature and supply Delta configuration 0xD8 R/W ADCGO ADC start configuration 0xFA R/W BATVTH Battery threshold configuration 0xEF R/W VSWADC VSW ADC value 0xDF R/W BATADC Battery ADC value 0xD7 R/W TEMPADC Temperature ADC value Table 45. Peripheral ADC Strobe Period SFR (STRBPER, 0xF9) Note: The strobing option only work when the RTCEN bit in RTC Configuration SFR (TIMECON, 0xA1) is set. Bit Bit Default Description Value Location Mnemonic 7-6 5-4 Reserved VSW_PERIOD[1:0] 0 3-2 BATT_PERIOD[1:0] 0 1-0 TEMP_PERIOD[1:0] 0 Reserved Period for background supply voltage measurements VSW_PERIOD[1:0] 0 0 No VSW measurement 0 1 8 minutes 1 0 2 minutes 1 1 1 minute Period for background battery level measurements BATT_PERIOD[1:0] 0 0 No Battery measurement 0 1 16 minutes 1 0 4 minutes 1 1 1 minute Period for background temperature measurements TEMP_PERIOD[1:0] 0 0 No Temperature measurements 0 1 8 minutes 1 0 2 minutes Rev. PrD | Page 66 of 140 Preliminary Technical Data ADE7169F16 1 1 1 minute Table 46. Temperature and Supply Delta SFR (DIFFPROG, 0xF3) Bit Location 7-6 5-3 Bit Mnemonic Reserved TEMP_DIFF[2:0] Default Value Description 0 0 2-0 VSW_DIFF[2:0] 0 Reserved Difference threshold between last temperature measurement interrupting 8052 and new temperature measurement that should interrupt 8052 TEMP_DIFF[2:0] 0 0 0 No Interrupt 0 0 1 < 1 LSB (≈ 0.8°C) 0 1 0 0 1 1 1 LSB (≈ 1.6°C) 1 0 0 1 0 1 2 LSB (≈ 3.2°C) 1 1 0 1 1 1 Every Temperature measurement Difference threshold between last supply voltage measurement interrupting 8052 and new temperature measurement that should interrupt 8052 VSW_DIFF[2:0] 0 0 0 No Interrupt 0 0 0 1 1 1 0 1 1 0 0 1 1 0 1 0 1 0 < 1 LSB (≈ 15mV) 1 1 1 Every VSW measurement 1 LSB (≈ 120 mV) Table 47. Start ADC Measurement SFR (ADCGO, 0xD8) Bit Location 7 Bit Name PLLACK Default Value Description 0 Reserved 0 2 0xDE – 0xDB 0xDA Set this bit to clear the PLL fault bit, PLL_FLT in the PERIPH register. A PLL fault is generated if a reset was caused because the PLL lost lock. Reserved VADC 0 1 0xD9 TADC 0 0 0xD8 BTADC 0 6-3 Bit Addr. 0xDF Set this bit to initiate a supply voltage measurement. This bit will be cleared when the measurement request is received by the ADC. Set this bit to initiate a temperature measurement. This bit will be cleared when the measurement request is received by the ADC. Set this bit to initiate a battery measurement. This bit will be cleared when the measurement request is received by the ADC. Table 48. Battery detection threshold SFR (BATVTH, 0xFA) Bit Location 7-0 Bit Mnemonic BATVTH Default Value Description 0 The battery ADC value is compared to this register, the battery threshold register. If BATADC is lower than the threshold, an interrupt is generated. Rev. PrD | Page 67 of 140 ADE7169F16 Preliminary Technical Data Table 49. VSW ADC value SFR (VSWADC, 0xEF) Bit Location 7-0 Bit Mnemonic VSWADC Default Value Description 0 The VSW ADC value in this register is updated when an ADC interrupt occurs. Table 50. Battery ADC value SFR (BATADC, 0xDF) Bit Location 7-0 Bit Mnemonic BATADC Default Value Description 0 The battery ADC value in this register is updated when an ADC interrupt occurs. Table 51. Temperature ADC value SFR (TEMPADC, 0xD7) Bit Location 7-0 Bit Mnemonic TEMPADC Default Value Description 0 The temperature ADC value in this register is updated when an ADC interrupt occurs. TEMPERATURE MEASUREMENT To set up background temperature measurements: To provide a digital temperature measurement, the ADE7169F16 includes a dedicated ADC. An 8-bit Temperature ADC value SFR (TEMPADC, 0xD7) holds the results of the temperature conversion. The resolution of the temperature measurement is TBD˚C/LSB. There are two ways to initiate a temperature conversion: 1. Initiate a single temperature measurement by setting the TEMP_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8). 2. Upon completion of this measurement, configure the TEMP_DIFF[2:0] bits to establish the change in temperature that will trigger an interrupt. 3. Set up the interval for background temperature measurements by configuring the TEMP_PERIOD[1:0] bits. - Single Temperature Measurement - Background Temperature Measurements Single Temperature Measurement Set the TEMP_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8) to get a temperature measurement. An interrupt will be generated when the conversion is done and the temperature measurement is available in the Temperature ADC value SFR (TEMPADC, 0xD7). Background Temperature Measurements Background temperature measurements are disabled by default. To configure the background temperature measurement mode, set a temperature measurement interval in the Peripheral ADC Strobe Period SFR (STRBPER, 0xF9). Then temperature measurements will be performed periodically in the background – see Table 45. When a temperature conversion completes, the new temperature ADC value is compared to the last temperature ADC value that created an interrupt. If the absolute difference between the two values is greater than the setting in the TEMP_DIFF bits in the Temperature and Supply Delta SFR (DIFFPROG, 0xF3), a TEMPADC interrupt is generated. This allows temperature measurements to take place completely in the background, only requiring MCU activity if the temperature has changed more than a configurable delta. Temperature ADC in PSM1 and PSM2 Depending on the operating mode of the ADE7169F16, a temperature conversion is initiated only by certain actions: PSM0: In this operating mode, the 8052 is active. Temperature measurements are available in the background measurement mode and by initiating a single measurement. PSM1: In this operating mode, the 8052 is active and the part is powered from battery. Single temperature measurements can be initiated by setting the TEMP_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8). Background temperature measurements are not available. PSM2: In this operating mode, the 8052 is not active. Temperature conversions are available through the background measurement mode only. The Temperature ADC value SFR (TEMPADC, 0xD7) is updated with a new value only when a temperature ADC interrupt occurs. Rev. PrD | Page 68 of 140 Preliminary Technical Data ADE7169F16 the BATTFLAG in the Power Management Interrupt Flag SFR (IPSMF, 0xF8) will be set. Temperature ADC interrupt The temperature ADC can generate an ADC interrupt when at least one of the following conditions occurs: 2. Set up the interval for background battery measurements by configuring the BATT_PERIOD[1:0] bits. - The difference between the new temperature ADC value and the last temperature ADC value generating an ADC interrupt is larger than the value set in the TEMP_DIFF bits. Battery ADC in PSM1 and PSM2 - The Temperature ADC conversion, initiated by setting Start ADC Measurement SFR (ADCGO, 0xD8), is finished. Depending on the operating mode, a battery conversion is initiated only by certain actions: When the ADC interrupt occurs, a new value is available in the Temperature ADC value SFR (TEMPADC, 0xD7). Note that there is no flag associated with this interrupt. PSM0: In this operating mode, the 8052 is active. Battery measurements are available in the background measurement mode and by initiating a single measurement. BATTERY MEASUREMENT PSM1: In this operating mode, the 8052 is active and the part is powered from battery. Single battery measurements can be initiated by setting the BATT_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8). Background battery measurements are not available. To provide a digital battery measurement, the ADE7169F16 includes a dedicated ADC. The battery measurement is available in an 8-bit SFR (Battery ADC value SFR (BATADC, 0xDF). The battery measurement has a resolution of 15 mV/LSB. A battery conversion can be initiated by two methods: - Single Battery Measurement PSM2: In this operating mode, the 8052 is not active. Battery conversions are available through the background measurement mode only. - Background Battery Measurements Battery ADC interrupt Single Battery Measurement The battery ADC can generate an ADC interrupt when at least one of the following conditions occurs: Set the BATT_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8) to get a battery measurement. An interrupt will be generated when the conversion is done and the battery measurement is available in the Battery ADC value SFR (BATADC, 0xDF). Background Battery measurements To configure background measurements for the battery, establish a measurement interval in the Peripheral ADC Strobe Period SFR (STRBPER, 0xF9). Then battery measurements will be performed periodically in the background – see Table 45. When a battery conversion completes, the battery ADC value is compared to the low battery threshold, established in the Battery detection threshold SFR (BATVTH, 0xFA). If it is below this threshold, a low battery flag is set. This low battery flag is the BATTFLAG bit in the Power Management Interrupt Flag SFR (IPSMF, 0xF8), used for power supply monitoring. This low battery flag can be enabled to generate the PSM interrupt by setting the EBATT bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC). This method allows battery measurements to take place completely in the background, only requiring MCU activity if the battery drops below a user specified threshold. To set up background battery measurements: 1. Configure the Battery detection threshold SFR (BATVTH, 0xFA) to establish a low battery threshold. If the BATADC measurement is below this threshold, - The new battery ADC value is smaller than the value set in the Battery detection threshold SFR (BATVTH, 0xFA), indicating a battery voltage loss. - A single battery measurement, initiated by setting the BATT_ADC_GO bit, is finished. When the battery flag is set in the Power Management Interrupt Flag SFR (IPSMF, 0xF8), a new ADC value is available in the Battery ADC value SFR (BATADC, 0xDF). This battery flag can be enabled as a source of the PSM interrupt to generate a PSM interrupt every time the battery drops below a set voltage threshold or after a single conversion initiated by setting the BATT_ADC_GO bit is ready. The Battery ADC value SFR (BATADC, 0xDF) is updated with a new value only when the Battery flag is set in the Power Management Interrupt Flag SFR (IPSMF, 0xF8). SUPPLY VOLTAGE MEASUREMENT To provide a digital supply voltage measurement, the ADE7169F16 includes a dedicated ADC. An 8-bit SFR (Table 49. VSW ADC value SFR (VSWADC, 0xEF)) holds the results of the conversion. The resolution of the supply voltage measurement is TBD V/LSB. There are two ways to initiate a supply voltage conversion: - Single Supply Voltage Measurement Rev. PrD | Page 69 of 140 ADE7169F16 Preliminary Technical Data - Background Supply Voltage Measurements 3. Single Supply voltage Measurement Set the VSW_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8) to get a supply voltage measurement. An interrupt will be generated when the conversion is done and the supply voltage measurement is available in the Table 49. VSW ADC value SFR (VSWADC, 0xEF). Background Supply Voltage Measurements Background supply voltage measurements are disabled by default. To configure the background supply voltage measurement mode, set a supply voltage measurement interval in the Peripheral ADC Strobe Period SFR (STRBPER, 0xF9). Then supply voltage measurements will be performed periodically in the background – see Table 45. When a supply voltage conversion completes, the new supply voltage ADC value is compared to the last supply voltage ADC value that created an interrupt. If the absolute difference between the two values is greater than the setting in the VSW_DIFF bits in the Temperature and Supply Delta SFR (DIFFPROG, 0xF3), a VSW ADC flag is set. This VSW ADC flag is the VSWFLAG in the Power Management Interrupt Flag SFR (IPSMF, 0xF8), used for power supply monitoring. This VSW ADC flag can be enabled to generate a PSM interrupt by setting the EVSW bit in the Power Management Interrupt Enable SFR (IPSME, 0xEC). This method allows supply voltage measurements to take place completely in the background, only requiring MCU activity if the supply voltage has changed more than a configurable delta. To set up background supply voltage measurements: 1. Initiate a single supply voltage measurement by setting the VSW_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8). 2. Upon completion of this measurement, configure the VSW_DIFF[2:0] bits to establish the change in temperature that will set the VSWFLAG in the Power Management Interrupt Flag SFR (IPSMF, 0xF8). Set up the interval for background supply voltage measurements by configuring the VSW_PERIOD[1:0] bits. Supply voltage ADC in PSM1 and PSM2 Depending on the operating mode of the ADE7169F16, a supply voltage conversion is initiated only by certain actions: PSM0: In this operating mode, the 8052 is active. Supply voltage measurements are available in the background measurement mode and by initiating a single measurement. PSM1: In this operating mode, the 8052 is active and the part is powered from battery. Single supply voltage measurements can be initiated by setting the TEMP_ADC_GO bit in the Start ADC Measurement SFR (ADCGO, 0xD8). Background supply voltage measurements are not available. PSM2: In this operating mode, the 8052 is not active. Supply voltage conversions are available through the background measurement mode only. The supply voltage Table 49. VSW ADC value SFR (VSWADC, 0xEF) is updated with a new value only when a supply voltage ADC interrupt occurs. Supply voltage ADC interrupt The supply voltage ADC can generate an ADC interrupt when at least one of the following conditions occurs: - The difference between the new supply voltage ADC value and the last supply voltage ADC value generating an ADC interrupt is larger than the value set in the VSW_DIFF bits. - The Supply voltage ADC conversion, initiated by setting TEMP_ADC_GO, is finished. When the ADC interrupt occurs, a new value is available in the VSW ADC value SFR (VSWADC, 0xEF). Note that there is no flag associated with this interrupt. Rev. PrD | Page 70 of 140 Preliminary Technical Data ADE7169F16 8052 MCU CORE ARCHITECTURE The ADE7169F16 has an 8052 MCU core and uses the 8051 instruction set. Some of the standard 8052 peripherals, such as the UART, have been enhanced. This section describes the standard 8052 core and enhancements that have been made to it in the ADE7169F16. The special function register (SFR) space is mapped into the upper 128 bytes of internal data memory space and is accessed by direct addressing only. It provides an interface between the CPU and all on-chip peripherals. A block diagram showing the programming model of the ADE7169F16 via the SFR area is shown in Figure 54. in the SFR area. The SFR registers include control, configuration, and data registers that provide an interface between the CPU and all on-chip peripherals. 256 BYTES GENERAL PURPOSE RAM STACK REGISTER BANKS All registers except the program counter (PC), instruction register (IR) and the four general-purpose register banks reside 16-kBYTE ELECTRICALLY REPROGRAMMABLE NONVOLATILE FLASH/EE PROGRAM/DATA MEMORY ENERGY MEASUREMENT POWER MANAGEMENT RTC 8051 COMPATIBLE CORE PC IR 256 BYTES XRAM 128-BYTE SPECIAL FUNCTION REGISTER AREA LCD DRIVER TEMPERATURE ADC BATTERY ADC OTHER ON-CHIP PERIPHERALS: SERIAL I/O WDT TIMERS Figure 54: ADE7169F16 Block Diagram MCU REGISTERS The registers used by the MCU are summarized hereafter. Table 52. 8051 SFRs SFR Address Bit Addressable Description A 0xE0 Yes Accumulator B 0xF0 Yes Auxiliary Math register PSW 0xD0 Yes Program status word - see Table 53 PCON 0x87 No Power Control register – see Table 54 DPL 0x82 No Data pointer LSByte – see Table 55 DPH 0x83 No Data pointer MSbyte – see Table 56 SP 0x81 No Stack pointer LSB byte – see Table 57 CFG 0xAF No Configuration register – see Table 58 Table 53. Program Status Word SFR (PSW, 0xD0) Bit Location 7 6 5 4-3 Bit Addr. 0xD7 0xD6 0xD5 0xD4, 0xD3 Bit Name CY AC F0 RS1, RS0 2 1 0 0xD2 0xD1 0xD0 OV F1 P Description Carry Flag. Modified by ADD, ADDC, SUBB, MUL, and DIV instructions. Auxiliary Carry Flag. Modified by ADD, and ADDC instructions. General-Purpose Flag availble to the user Register Bank Select Bits. RS1 RS0 Selected Bank 0 0 0 0 1 1 1 0 2 1 1 3 Overflow Flag. Modified by ADD, ADDC, SUBB, MUL and DIV instructions. General-Purpose Flag availble to the user. Parity Bit. The number of bits set in the Accumulator added to the value of the parity bit will always be an even number. Rev. PrD | Page 71 of 140 ADE7169F16 Preliminary Technical Data Table 54. Program Control SFR (PCON, 0x87) Bit Location 7 6-0 Default 0 0 Description Double baud rate control Reserved, should be left cleared Table 55. Data Pointer Low SFR (DPL, 0x82) Bits 7-0 Default 0 Description Contain the low byte of the data pointer Table 56. Data Pointer High SFR (DPH, 0x83) Bits 7-0 Default 0 Description Contain the high byte of the data pointer Table 57. Stack Pointer SFR (SP, 0x81) Bits 7-0 Default 7 Description Contain the 8 LSB of the pointer for the stack Table 58. Configuration SFR (CFG, 0xAF) Bit Location 7 6 5 4 3-2 1-0 Bit Mnemonic Description Reserved.. This bit should be left set for proper operation. EXTEN Enhanced UART enable bit 0 Standard 8052 UART without enhanced error checking features 1 Enhanced UART with enhanced error checking—see the UART additional features section. SCPS Synchronous communication selection bit 0 I2C port is selected for control of the shared I2C/SPI pins and SFRs 1 SPI port is selected for control of the shared I2C/SPI pins and SFRs MOD38EN 38kHz modulation enable bit 0 38kHz modulation is disabled. 1 38kHz modulation is enabled on the pins selected by the MOD38[7:0] bits in the EP_CFG SFR. Reserved XREN[1:0] Enable MOVX instruction to use 256 bytes of Extended RAM. XREN[1] OR XREN[0] =1 Disable MOVX instruction XREN[1] AND XREN[0] =0 BASIC 8052 REGISTERS Program Counter (PC): The Program Counter holds the two byte address of the next instruction to be fetched. The PC is initialized with 0x00 at Reset and is incremented after each instruction is performed. Note that the amount that is added to the PC depends on the number of bytes in the instruction, so the increment can range from one to three bytes. The program counter is not directly accessible to the user but can be directly modified by CALL and JMP instructions that change which part of the program is active. Instruction Register (IR): The Instruction Register holds the opcode of the instruction being executed. The opcode is the binary code that results from assembling an instruction. This register is not directly accessible to the user. Register Banks: There are four banks containing 8 byte-wide registers each, for a total of 32 bytes of registers. These registers are convenient for temporary storage of mathematical operands. An instruction involving the accumulator and a register can be executed in 1 clock cycle as opposed to 2 clock cycles to perform an instruction involving the accumulator and a literal or a byte of general purpose RAM. The register banks are located in the first 32 bytes of RAM. Rev. PrD | Page 72 of 140 Preliminary Technical Data ADE7169F16 The active register bank is selected by the RS0 and RS1 bits in the Program Status Word SFR (PSW, 0xD0). Stack Pointer (SP): The Stack Pointer keeps track of the current address of the top of the stack. To push a byte of data onto the stack, the stack pointer is incremented and the data is moved to the new top of the stack. To pop a byte of data off of the stack, the top byte of data is moved into the awaiting address and the stack pointer is decremented. The stack is a last in first out (LIFO) method of data storage because the most recent addition to the stack is the first to come off it. Accumulator: The accumulator is a working register, storing the results of many arithmetic or logical operations. The accumulator is used in more than half of the 8052 instructions where it is usually referred to as A. The status register (PSW) constantly monitors the number of bits that are set in the accumulator to determine if it has even or odd parity. The accumulator is stored in the SFR space - see Table 52. The stack is utilized during CALL and RET instructions to keep track of the address to move into the PC when returning from the function call. The stack is also manipulated when vectoring for interrupts, to keep track of the prior state of the PC. B Register: The B register is used by the multiply and divide instructions, MUL AB and DIV AB to hold one of the operands. Since it isn’t used for many instructions, it can be used as a scratchpad register like those in the register banks. The B register is stored in the SFR space - see Table 52. The stack resides into the extended internal RAM and the SP register holds the address of the stack into the externded RAM. The advantage of this solution is that the stack is segregated to the extended internal RAM. The use of the general purpose RAM can be limited to data storing and the use of the extended internal RAM limited to the stack pointer. This separation limits the chance of corruption of the data RAM with the stack pointer overflowing in data RAM. Data can still be stored in extended RAM by using the MOVX command. Program Status Word (PSW): The PSW register reflects the status of arithmetic and logical operations through carry, auxiliary carry and overflow flags. The parity flag reflects the parity of the contents of the accumulator, which can be helpful for communication protocols. The PSW bits are described in Table 53. The Program Status Word SFR (PSW, 0xD0) is bit addressable. Data Pointer (DPTR): The data pointer is made up of two 8-bit registers: DPH (high byte), and DPL (low byte). These provide memory addresses for internal code and data access. The DPTR can be manipulated as a 16-bit register (DPTR = DPH, DPL), or as two independent 8-bit registers (DPH, DPL) – see Table 55 and Table 56. To change the default starting address for the stack, move a value into the stack pointer, SP. For example, to enable the extended stack pointer and initialize it at the beginning of the XRAM space, use this code: MOV SP,#00H The ADE7169F16 supports dual data pointers. See the Dual Data Pointers section. FFH FFH 256 256BYTES BYTESOF OF ON-CHIP RAM DATA 256 BYTES OF ON-CHIP X-RAM DATA+STACK (DATA) 00H 00H Figure 55. Extended Stack Pointer Operation STANDARD 8052 SFRS The standard 8052 special function registers include the Accumulator, B, PSW, DPTR and SP SFRs described in the Basic 8052 Registers section. The 8052 also defines standard timers, serial port interface, interrupts, I/O ports and power down modes. Timer SFRs: The 8052 contains 3 16-bit timers, the identical Timer0 and Timer1 as well as a Timer2. These timers can also function as event counters. Timer2 has a capture feature where the value of the timer can be captured in two 8-bit registers upon the assertion of an external input signal - see Table 93 and Timers section. Serial Port SFRs: The full-duplex serial port peripheral requires two registers, one for setting up the baud rate and other communication parameters, and another byte for the transmit/receive buffer. The ADE7169F16 also provides Rev. PrD | Page 73 of 140 ADE7169F16 Preliminary Technical Data enhanced serial port functionality with a dedicated timer for baud rate generation with a fractional divisor and additional error detection. See Table 115 and UART serial interface section. • Flash Memory controller • Watchdog Timer Interrupt SFRs: There is a two-tiered interrupt system standard in the 8052 core. The priority level for each interrupt source is individually selectable as high or low. The ADE7169F16 enhances this interrupt system by creating in essence a third interrupt tier for a highest priority power supply management interrupt, PSM - See Interrupt System section. The ADE7169F16 contains three memory blocks: The ADE7169F16 provides 20 pins that can be used for general purpose I/O. These pins are mapped to Ports 0, 1 and 2 and are accessed through three bit-addressable 8052 SFRs P0, P1 and P2. Another enhanced feature of the ADE7169F16 is that the weak pull-ups standard on 8052 Ports 1, 2 and 3 can be disabled to make open drain outputs, as is standard on Port 0. The weak pull-ups can be enabled on a pin by pin basis. See the I/O Ports section. Power Control Register (PCON, 0x87): The 8052 core defines two power down modes; power down and idle. The ADE7169F16 enhances the power control capability of the traditional 8052 MCU with additional power management functions. The POWCON register is used to define power control specific functionality for the ADE7169F16. The Program Control SFR (PCON, 0x87) is not bit addressable. See the Power Management section. The ADE7169F16 provides many other peripherals not standard to the 8052 core. • ADE Energy Measurement DSP • RTC • LCD driver • Battery Switchover/Power Management • Temperature ADC • Battery ADC • • 16 kbytes of on-chip Flash/EE program and data memory • 256 bytes of general-purpose RAM • 256 bytes of internal extended RAM (XRAM) The 256 bytes of general-purpose RAM shares the upper 128 bytes of its address space with Special Function Registers. All of the memory spaces are shown in Figure 54. The addressing mode specifies which memory space to access. General Purpose RAM: General purpose RAM resides in memory locations 0x00 through 0xFF. It contains the register banks. 7FH GENERAL-PURPOSE AREA 30H 2FH SPI/I C communication 20H 1FH 11 18H 17H 10 10H 0FH FOUR BANKS OF EIGHT REGISTERS R0 TO R7 07H RESET VALUE OF STACK POINTER 01 08H 00 00H Figure 56. Lower 128 Bytes of Internal Data Memory Addresses 0x80 through 0xFF of General Purpose RAM are shared with the Special Function Registers. The mode of addressing determines which memory space is accessed as shown in Figure 57. FFh ACCESSIBLE BY INDIRECT ADDRESSING ONLY 80h 7Fh 2 BIT-ADDRESSABLE (BIT ADDRESSES) BANKS SELECTED VIA BITS IN PSW 04741-0-008 I/O Port SFRs: The 8052 core supports four I/O ports, P0 through P3 where Ports 0 and 2 are typically used for access to external code and data spaces. The ADE7169F16, unlike standard 8052 products, provides internal nonvolatile Flash memory so that an external code space is unnecessary. The onchip LCD driver requires many pins, some of which are dedicated for LCD functionality and others that can be configured at LCD or general purpose I/O. Due to the limited number of I/O pins, the ADE7169F16 does not allow access to external code and data spaces. MEMORY OVERVIEW ACCESSIBLE BY DIRECT ADDRESSING ONLY ACCESSIBLE BY DIRECT AND INDIRECT ADDRESSING 00h GENERAL PURPOSE RAM SPECIAL FUNCTION REGISTERS (SFRs) Figure 57: General Purpose RAM and SFR memory address overlap Rev. PrD | Page 74 of 140 Preliminary Technical Data ADE7169F16 Both direct and indirect addressing can be used to access General Purpose RAM from 0x00 through 0x7F but indirect addressing must be used to access General Purpose RAM with addresses in the range from 0x80 through 0xFF because they share the same address space with the Special Function Registers (SFRs). The 8052 core also has the means to access individual bits of certain addresses in the General Purpose RAM and Special Function Memory spaces. The individual bits of General Purpose RAM addresses 0x20 through 0x2F can be accessed through their bit addresses 0x00 through 0x7F. The benefit of bit addressing is that the individual bits can be accessed quickly, without the need for bit masking, which takes more code memory and execution time. The bit addresses for General Purpose RAM addresses 0x20 through 0x2F can be seen in Figure 58. Byte Address 0x2F 7F 0x2E 77 0x2D 6F 0x2C 67 0x2B 5F 0x2A 57 0x29 4F 0x28 47 0x27 3F 0x26 37 0x25 2F 0x24 27 0x23 1F 0x22 17 0x21 0F 0x20 07 Bit Addresses (hexa) 7E 76 6E 66 5E 56 4E 46 3E 36 2E 26 1E 16 0E 06 7D 75 6D 65 5D 55 4D 45 3D 35 2D 25 1D 15 0D 05 7C 74 6C 64 5C 54 4C 44 3C 34 2C 24 1C 14 0C 04 7B 73 6B 63 5B 53 4B 43 3B 33 2B 23 1B 13 0B 03 7A 72 6A 62 5A 52 4A 42 3A 32 2A 22 1A 12 0A 02 79 71 69 61 59 51 49 41 39 31 29 21 19 11 09 01 78 70 68 60 58 50 48 40 38 30 28 20 18 10 08 00 Figure 58: Bit Addressable Area of General Purpose RAM Bit addressing can be used for instructions that involve Boolean variable manipulation and program branching—see the Instruction set. Special Function Registers: Special Function Registers are registers that affect the function of the 8051 core or its peripherals. These registers are located in RAM with addresses 0x80 through 0xFF. They are only accessible through direct addressing as shown in Figure 57 . The individual bits of some of the SFRs can be accessed for use in Boolean and program branching instructions. These SFRs are labeled as bit-addressable and the bit addresses are given in the SFR Mapping. Extended Internal RAM (XRAM): The ADE7169F16 provides 256 bytes of extended on-chip RAM. No external RAM is supported. This RAM is located in addresses 0x0000 through 0x00FF in the Extended RAM space. To select the Extended RAM memory space, the extended indirect addressing modes are used. The internal XRAM is enabled in the Configuration SFR (CFG, 0xAF) by writing 01 to CFG[1:0]. FFh 00h 256 BYTES OF EXTENDED INTERNAL RAM (XRAM) Figure 59: Extended Internal RAM (XRAM) Space Code Memory: Code and data memory are stored in the 16kbyte Flash memory space. No external code memory is supported. To access Code memory, Code Indirect addressing is used. ADDRESSING MODES The 8052 core provides several addressing modes. The addressing mode determines how the core will interpret the memory location or data value specified in assembly language code. There are six addressing modes as shown in Table 59: Table 59. 8052 Addressing Modes Addressing Mode Example Bytes Core Clock Cycles Immediate MOV A, #A8h 2 2 MOV DPTR,#A8h 3 3 MOV A, A8h 2 2 MOV A, IE 2 2 MOV A, R0 1 1 Indirect MOV A,@R0 1 2 Extended Direct MOVX A, @DPTR 1 4 Extended Indirect MOVX A, @R0 1 4 Code Indirect MOVC A, @A+DPTR 1 4 MOVC A, @A+PC 1 4 JMP @A+DPTR 1 3 Direct Immediate Addressing: In Immediate Addressing, the expression entered after the number sign (#) will be evaluated by the assembler and stored in the memory address specified. Rev. PrD | Page 75 of 140 ADE7169F16 Preliminary Technical Data This number is referred to as a literal because it refers only to a value and not to a memory location. Instructions using this addressing mode will be slower than those between two registers since the literal must be stored and fetched from memory. The expression can be entered as a symbolic variable or an arithmetic expression; the value will be computed by the assembler. Direct Addressing: With Direct Addressing, the value at the source address is moved to the destination address. Direct Addressing provides the fastest execution time of all the addressing modes when an instruction is performed between registers using direct addressing. Note that indirect or direct addressing modes can be used to access general purpose RAM addresses 0x00 through 0x7F. An instruction with direct addressing that uses an address between 0x80 and 0xFF is referring to a special function memory location. Indirect Addressing: With Indirect Addressing, the value pointed to by the register is moved to the destination address. For example, to move the contents of internal RAM address 82h to the accumulator: MOV MOV R0,#82h A,@R0 The two instructions above require a total of four clock cycles and three bytes of storage in the program memory. Indirect addressing allows addresses to be computed, and is useful for indexing into data arrays stored in RAM. Note that an instruction that refers to addresses 00 through 7Fh is referring to internal RAM and indirect or direct addressing modes can be used. An instruction with indirect addressing that uses an address between 80h and FFh is referring to internal RAM, not to a SFR. Extended Direct Addressing: The DPTR register is used to access internal extended RAM in extended indirect addressing mode. The ADE7169F16 provides 256 bytes of internal extended RAM (XRAM), accessed through MOVX instructions. External memory spaces are not supported on this device. In extended direct addressing mode, the DPTR register points to the address of the byte of extended RAM. The following code will move the contents of extended RAM address 100h to the accumulator: MOV DPTR,#100h MOVX A,@DPTR The two instructions above require a total of seven clock cycles and four bytes of storage in the program memory. Extended Indirect Addressing: The internal extended RAM is accessed through a pointer to the address in indirect addressing mode. The ADE7169F16 provides 256 bytes of internal extended RAM, accessed through MOVX instructions. External memory is not supported on this device. In extended indirect addressing mode, a register holds the address of the byte of extended RAM. The following code will move the contents of extended RAM address 80h to the accumulator: MOV R0,#80h MOVX A,@R0 The two instructions above require six clock cycles and three bytes of storage. Note that there are 256 bytes of extended RAM, so both extended direct and extended indirect addressing can cover the whole address range. There is a storage and speed advantage to using extended indirect addressing because the additional byte of addressing available through the DPTR register that is not needed is not stored. From the three examples demonstrating the access of internal RAM from 80h through FFh and extended internal RAM from 00h through FFh, it can be seen that it is most efficient to use the entire internal RAM accessible through indirect access before moving to extended RAM. Code Indirect Addressing: The internal code memory can be accessed indirectly. This can be useful for implementing lookup tables and other arrays of constants that are stored in Flash. For example, to move the data stored in Flash memory at address 8002h into the Accumulator: MOV DPTR,#8002h CLR A MOVX A,@A+DPTR The Accumulator can be used as a variable index into the array of Flash memory located at DPTR. INSTRUCTION SET Table 60 documents the number of clock cycles required for eachinstruction. Most instructions are executed in one or two clock cycles,resulting in a 4 MIPS peak performance. Table 60. Instruction Set Mnemonic Arithmetic ADD A,Rn ADD A,@Ri Description Bytes Cycles Add register to A Add indirect memory to A 1 1 1 2 Rev. PrD | Page 76 of 140 Preliminary Technical Data Mnemonic ADD A,dir ADD A,#data ADDC A,Rn 1 1 ADDC A,@Ri ADDC A,dir ADD A,#data SUBB A,Rn SUBB A,@Ri SUBB A,dir SUBB A,#data INC A INC Rn INC @ INC dir INC DPTR DEC A DEC Rn DEC @Ri DEC dir MUL AB DIV AB DA A A Logic ANL A,Rn ADE7169F16 Description Add direct byte to A Add immediate to A Add register to A with carry Add indirect memory to A with carry Add direct byte to A with carry Add immediate to A with carry Subtract register from A with borrow Subtract indirect memory from A with borrow Subtract direct from A with borrow Subtract immediate from A with borrow Increment A Increment register Ri Increment indirect memory Increment direct byte Increment data pointer Decrement A Decrement register Decrement indirect memory Decrement direct byte Multiply A by B Divide A by B Decimal adjust A Bytes 2 2 1 1 2 2 1 1 2 2 1 1 1 2 1 1 1 1 2 1 1 1 Cycles 2 2 1 2 2 2 1 2 2 2 1 1 2 2 3 1 1 2 2 9 9 2 AND register to A 1 1 ANL A,@Ri AND indirect memory to A 1 2 ANL A,dir AND direct byte to A 2 2 ANL A,#data AND immediate to A 2 2 ANL dir,A AND A to direct byte 2 2 ANL dir,#data AND immediate data to direct byte 3 3 ORL A,Rn OR register to A 1 1 ORL A,@Ri OR indirect memory to A 1 2 ORL A,dir OR direct byte to A 2 2 ORL A,#data OR immediate to A 2 2 ORL dir,A OR A to direct byte 2 2 ORL dir,#data OR immediate data to direct byte 3 3 XRL A,Rn Exclusive-OR register to A 1 1 XRL A,@Ri Exclusive-OR indirect memory to A 2 2 XRL A,#data Exclusive-OR immediate to A 2 2 XRL dir,A Exclusive-OR A to direct byte 2 2 XRL A, dir Exclusive-OR indirect memory to A 2 2 XRL dir,#data Exclusive-OR immediate data to direct 3 3 CLR A CPL A SWAP A RL A RLC A RR A RRC A Clear A Complement A Swap nibbles of A Rotate A left Rotate A left through carry Rotate A right Rotate A right through carry 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Rev. PrD | Page 77 of 140 ADE7169F16 Mnemonic Preliminary Technical Data Description Bytes Cycles MOV A,Rn Move register to A 1 1 MOV A,@Ri Move indirect memory to A 1 2 MOV Rn,A Move A to register 1 1 MOV @Ri,A Move A to indirect memory 1 2 MOV A,dir Move direct byte to A 2 2 MOV A,#data Move immediate to A 2 2 MOV Rn,#data Move register to immediate 2 2 MOV dir,A Move A to direct byte 2 2 MOV Rn,dir Move register to direct byte 2 2 Data Transfer MOV dir,Rn Move direct to register 2 2 MOV @Ri,#data Move immediate to indirect memory 2 2 MOV dir,@Ri Move indirect to direct memory 2 2 MOV @Ri,dir Move direct to indirect memory 2 2 MOV dir,dir Move direct byte to direct byte 3 3 MOV dir,#data Move immediate to direct byte 3 3 MOV DPTR,#data Move immediate to data pointer 3 3 MOVC A,@A+DPTR Move code byte relative DPTR to A 1 4 MOVC A,@A+PC Move code byte relative PC to A 1 1 4 MOVX A,@Ri Move external (A8) data to A 1 4 MOVX A,@DPTR Move external (A16)data to A 1 4 MOVX @Ri,A Move A to external data (A8) 1 4 MOVX @DPTR,A Move A to external data (A16) 1 4 PUSH dir Push direct byte onto stack 2 2 POP dir Pop direct byte from stack 2 2 XCH A,Rn Exchange A and register 1 1 XCH A,@Ri Exchange A and indirect memory 1 2 XCHD A,@Ri Exchange A and indirect memory nibble 1 2 XCH A,dir Exchange A and direct byte 2 2 CLR C Clear carry 1 1 CLR bit Clear direct bit 2 2 SETB C Set carry 1 1 Boolean SETB bit Set direct bit 2 2 CPL C Complement carry 1 1 CPL bit Complement direct bit 2 2 ANL C,bit AND direct bit and carry 2 2 ANL C,/bit AND direct bit inverse to carry 2 2 ORL C,bit OR direct bit and carry 2 2 ORL C,/bit OR direct bit inverse to carry 2 2 MOV C,bit Move direct bit to carry 2 2 MOV bit,C Move carry to direct bit 2 2 Branching Rev. PrD | Page 78 of 140 Preliminary Technical Data Mnemonic JMP @A+DPTR ADE7169F16 Description Jump indirect relative to DPTR Bytes 1 Cycles 3 RET Return from subroutine 1 4 RETI Return from interrupt 1 4 ACALL addr11 Absolute jump to subroutine 2 3 AJMP addr11 Absolute jump unconditional 2 3 SJMP rel Short jump (relative address) 2 3 JC rel Jump on carry equal to 1 2 3 JNC rel Jump on carry equal to 0 2 3 JZ rel Jump on accumulator =0 2 3 JNZ rel Jump on accumulator not equal to 0 2 3 DJNZ Rn,rel Decrement register,JNZ relative 2 3 LJMP Long jump unconditional 3 4 LCALL addr16 Long jump to subroutine 3 4 JB bit,rel Jump on direct bit =1 3 4 JNB bit,rel Jump on direct bit =0 3 4 JBC bit,rel Jump on direct bit =1 and clear 3 4 CJNE A,dir,rel Compare A,direct JNE relative 3 4 CJNE A,#data,rel Compare A,immediate JNE relative 3 4 CJNE Rn,#data,rel Compare register,immediate JNE relative 3 4 CJNE @Ri,#data,rel Compare indirect,immediate JNE relative 3 4 DJNZ dir,rel Decrement direct byte,JNZ relative 3 4 No operation 1 1 Miscellaneous NOP READ-MODIFY-WRITE INSTRUCTIONS Some 8051 instructions read the latch while others read the pin. The state of the pin is read for instructions that input a port bit. Instructions that read the latch rather than the pins are the ones that read a value, possibly change it, and rewrite it to the latch. Since these instructions involve modifying the port, it is assumed that the pins being modified are outputs, so the output state of the pin is read from the latch. This prevents a possible misinterpretation of the voltage level of a pin. For example, if a port pin is used to drive the base of a transistor, a 1 is written to the bit, to turn the transistor on. If the CPU reads the same port bit at the pin rather than the latch, it reads the base voltage of the transistor and interprets it as Logic 0. Reading the latch rather than the pin returns the correct value of 1. The instructions that read the latch rather than the pins are called read-modify-write instructions, and are listed in Table 61. When the destination operand is a port or a port bit, these instructions read the latch rather than the pin. Table 61. Read-Modify-Write Instructions Instruction Example ANL ORL XRL JBC CPL INC DEC DJNZ ANL P0, A ORL P1, A XRL P2, A JBC P1.1, LABEL CPL P2.0 INC P2 DEC P2 DJNZ P0, LABEL MOV PX.Y, C1 MOV P0.0,C CLR PX.Y1 SETB PX.Y1 CLR P0.0 SETB P0.0 Logical AND Logical OR Logical EX-OR Jump if Bit = 1 and clear bit Complement bit Increment Decrement Decrement and jump if not zero Move Carry to Bit Y of Port X Clear Bit Y of Port X Set Bit Y of Port X ___________________________________________ 1 These instructions read the port byte (all 8 bits), modify the addressed bit, and write the new byte back to the latch. INSTRUCTIONS THAT AFFECT FLAGS Many instructions explicitly modify the Carry bit such as the MOV C, bit and CLR C instructions. Other instructions that affect status flags are listed in this section. Description Rev. PrD | Page 79 of 140 ADE7169F16 ADD Preliminary Technical Data operands are unsigned. A, source Function: Adds the source to the Accumulator. OV Set if there is a borrow is needed for bit 6 or bit 7 but not for both. Used to indicate an overflow for signed subtraction. This flag will be set if a negative number subtracted from a positive yields a negative result or it a positive number subtracted from a negative number yields a positive result. Status Flags Referenced by Instruction: None Status Flags Affected: Status Flag Description C Set if there is a carry out of bit 7. Cleared otherwise. Used to indicate an overflow if the operands are unsigned. AC Set if a borrow is needed for bit 3. Cleared otherwise. OV Set if there is a carry out of bit 6 or a carry out of bit 7 but not if both are set. Used to indicate an overflow for signed addition. This flag will be set if two positive operands yield a negative result or two negative operands yield a positive result. MUL AB Set if there is a carry out of bit 3. Cleared otherwise. Status Flags Referenced by Instruction: None Status Flags Affected: None AC ADDC A, source Function: Adds the source and the Carry bit to the Accumulator Status Flags Referenced by Instruction: Carry Status Flags Affected: Status Flag Description C Set if there is a carry out of bit 7. Cleared otherwise. Used to indicate an overflow if the operands are unsigned. OV AC SUBB Set if there is a carry out of bit 6 or a carry out of bit 7 but not if both are set. Used to indicate an overflow for signed addition. This flag will be set if two positive operands yield a negative result or two negative operands yield a positive result. Set if there is a carry out of bit 3. Cleared otherwise. Function: Multiplies the Accumulator by the B register. This operation is unsigned. The lower byte of the 16-bit product is stored in the Accumulator and the higher byte is left in the B register. Status Flag Description C Cleared OV Set if the result is greater than 255. Cleared otherwise. DIV Function: Divides the Accumulator by the B register. This operation is unsigned. The integer part of the quotient is stored in the Accumulator and the remainder goes into the B register. Status Flags Referenced by Instruction: None Status Flags Affected: Status Flag Description C Cleared OV Cleared unless the B register was equal to 0, in which case the results of the division are undefined and the OV flag is set. A, source Function: Subtract the source byte and the carry (borrow) flag from the Accumulator. Status Flags Referenced by Instruction: Carry (Borrow) Status Flags Affected: Status Flag Description C Set if there is a borrow needed for of bit 7. Cleared otherwise. Used to indicate an overflow if the AB DA A Function: Adjusts the Accumulator to hold two four bit digits after the addition of two binary coded decimals (BCDs) with the ADD or ADDC instructions. If the AC bit is set or if the value of bits 0-3 exceed 9, 0x06 is added to the accumulator to correct the lower four bits. If the carry bit was set when the instruction began, or if 0x06 was added to the accumulator in the first step, 0x60 is added to the accumulator to correct the higher four bits. Rev. PrD | Page 80 of 140 Preliminary Technical Data ADE7169F16 Status Flags Referenced by Instruction: Carry, AC Status Flags Affected: Status Flag Description C Set if the result is greater than 99h. Cleared otherwise. RRC A Function: Rotates the accumulator to the right through the carry flag. The old LSB of the Accumulator becomes the new carry flag and the old carry flag is loaded into the new MSB of the Accumulator. Status Flags Referenced by Instruction: Carry Status Flags Affected: Status Flag Description C Equal to the state of ACC.0 before execution of the instruction RLC A Function: Rotates the accumulator to the left through the carry flag. The old MSB of the Accumulator becomes the new carry flag and the old carry flag is loaded into the new LSB of the Accumulator. Status Flags Referenced by Instruction: Carry Status Flags Affected: Status Flag Description C Equal to the state of ACC.7 before execution of the instruction CJNE destination, source, relative jump Function: Compares the value of the source to the value of the destination and branches to the location set by the relative jump if they are not equal. If the values are equal, program execution continues with the instruction after the CJNE instruction. Status Flags Referenced by Instruction: None Status Flags Affected: Status Flag Description C Set if the source value is greater than the destination value. Cleared otherwise. Rev. PrD | Page 81 of 140 ADE7169F16 Preliminary Technical Data INTERRUPT SYSTEM The unique power management architecture of the ADE7169F16 includes an operating mode where the 8052 MCU core is shut down, PSM2. There are events that can be configured to wake the 8052 MCU core from the PSM2 operating mode where the MCU core is shut down. A distinction is drawn here between events that can trigger the wakeup of the 8052 MCU core and events that can trigger an interrupt when the MCU core is active. Events that can wake the core are referred to as wakeup events while events that can interrupt the program flow when the MCU is active are called interrupts. See the 3.3V Peripherals and Wakeup Events section to learn more about events that can wake the 8052 core from PSM2. The ADE7169F16 provides 12 interrupt sources with three priority levels. The power management interrupt is alone at the highest priority level. The other two priority levels are configurable through the Interrupt priority SFR (IP, 0xB8) and Interrupt Enable and Priority 2 SFR (IEIP2, 0xA9). Figure 60: Standard 8051 Interrupt Priority Levels A Priority 1 interrupt can interrupt the service routine of a Priority 0 interrupt, and if two interrupts of different priorities occur at the same time, the Priority 1 interrupt is serviced first. An interrupt cannot be interrupted by another interrupt of the same priority level. If two interrupts of the same priority level occur simultaneously, a polling sequence is observed. See the Interrupt Priority section. ADE7169F16 INTERRUPT ARCHITECTURE The ADE7169F16 provides advanced power supply monitoring features. To ensure a fast response to time critical power supply issues, such as a loss of line power, the power supply monitoring interrupt should be able to interrupt any interrupt service routine. In order to enable the user to make full use of the standard 8051 interrupt priority levels, an additional priority level was added for the power supply management, PSM, interrupt. The PSM interrupt is the only interrupt at this highest interrupt priority level. STANDARD 8051 INTERRUPT ARCHITECTURE High The 8051 standard interrupt architecture includes two tiers of interrupts, where some interrupts are assigned a high priority and others are assigned a low priority. High Figure 61: ADE7169F16 Interrupt Architecture Priority 1 Priority 0 Low Low PSM Priority 1 Priority 0 See the Power Supply Monitor Interrupt (PSM) section for more information on the PSM interrupt. INTERRUPT SFR REGISTER LIST The control and configuration of the interrupt system is carried out through three interrupt-related SFRs: SFR Address Default Value Bit Addressable Description IE IP IEIP2 0xA8 0xB8 0xA9 0x00 0x00 0xA0 Yes Yes No Interrupt Enable Register Interrupt Priority Register Secondary Interrupt Enable Register WDCON 0xC0 0x10 Yes Watchdog timer configuration Table 62. Interrupt Enable SFR (IE, 0xA8) Bit Location 7 Bit Addr. 0xAF Bit Name EA 6 5 4 3 2 0xAE 0xAD 0xAC 0xAB 0xAA ETEMP ET2 ES ET1 EX1 Description Set by the user to enable all interrupt sources. Cleared by the user to disable all interrupt sources. Set by the user to enable the temperature ADC interrupt. Set by the user to enable the Timer 2 interrupt. Set by the user to enable the UART serial port interrupt. Set by the user to enable the Timer 1 interrupt. Set by the user to enable External Interrupt 1 (INT1). 1 0xA9 ET0 Set by the user to enable the Timer 0 interrupt. Rev. PrD | Page 82 of 140 Preliminary Technical Data 0 0xA8 EX0 ADE7169F16 Set by the user to enable External Interrupt 0 ( ). Table 63. Interrupt priority SFR (IP, 0xB8) Bit Location Bit Name Description 7 Bit Addr. 0xBF PADE 6 5 4 3 2 0xBE 0xBD 0xBC 0xBB 0xBA PTEMP PT2 PS PT1 PX1 ADE Energy Measurement Interrupt Priority (1 = High; 0 = Low). Temperature ADC Interrupt Priority (1 = High; 0 = Low). Timer 2 Interrupt Priority (1 = High; 0 = Low). UART Serial Port Interrupt Priority (1 = High; 0 = Low). Timer 1 Interrupt Priority (1 = High; 0 = Low). INT1 (External Interrupt 1) priority (1 = High; 0 = Low). 1 0 0xB9 0xB8 PT0 PX0 Timer 0 Interrupt Priority (1 = High; 0 = Low). INT0 (External Interrupt 0) Priority (1 = High; 0 = Low). Table 64. Interrupt Enable and Priority 2 SFR (IEIP2, 0xA9) Bit Location 7 6 5 4 3 2 1 0 Bit Mnemonic Description PTI RTC Interrupt Priority (1 = High; 0 = Low). PSI EADE ETI EPSM ESI SPI/I2C Interrupt Priority (1 = High; 0 = Low). Set by the user to enable the Energy Metering Interrupt (ADE) Set by the user to enable the RTC Interval Timer interrupt. Set by the user to enable the PSM Power Supply Management interrupt. Set by the user to enable the SPI/I2C interrupt. Table 65. WatchDog Timer SFR (WDCON, 0xC0) Bit Location 7-4 Bit Addr. 3 0xC3 0xC7 – 0xC4 Bit Name PRE[3:0] Default Value Description 7 WDIR 0 Watchdog pre-scaler. In normal mode, the 16-bit watchdog timer is clocked by the input clock (32.768kHz). The PRE bits set which of the upper bits of the counter are 29 PRE used as the watchdog output following: t × watchdog = 2 CLKIN [3:0] Watchdog Timeout 0000 15.6ms 0001 31.2ms 0010 62.5ms 0011 125ms 0100 250ms 0101 500ms 0110 1s 0111 2s 1000 0 Automatic Reset 1001 0 Serial download reset 1010 to 1111 Not a valid selection Watchdog interrupt response bit. When clear, watchdog will generate a system reset when the watchdog time out period has expired When set, the watchdog will generate a interrupt when the watchdog time out period has expired. Rev. PrD | Page 83 of 140 ADE7169F16 Preliminary Technical Data 2 0xC2 WDS 0 1 0xC1 WDE 1 0 0xC0 WDWR 0 WDS Watchdog status bit. This bit is set to indicate that a watchdog timeout has occurred. WDS is cleared by writing a zero or by an external hardware reset. A watchdog reset will not clear WDS. The bit can therefore be used to distinguish between a watchdog reset and a hardware reset from the RESET pin. WDE Watchdog enable bit. When set, enables the watchdog and clears its counter (e.g. 2 above). The watchdog counter is subsequently cleared again whenever the WDE bit is set. If the watchdog is not cleared within its selected timeout period it will generate a system reset or watchdog interrupt, depending on the WDIR bit. The watchdog is disabled (and WDE cleared) by any of the following: Write zero to WDE Watchdog reset (WDIR = 0) Hardware reset PSM interrupt LOCK interrupt. WDWR Watchdog write enable bit. To write data into the WDCON SFR involves a double instruction sequence. The WDWR bit must be set and the following instruction must be a write instruction to the WDCON SFR. This sequence is necessary so that the WDCON SFR is protected from code execution upsets that might unintentionally modify this SFR. Interrupts should be disabled during this operation due to the consecutive instruction cycles. e.g. Disable Watch dog 1 write to WDCON e.g. 2 Clear WDE bit CLR EA SETB WDWR CLR WDE SETB EA INTERRUPT PRIORITY If two interrupts of the same priority level occur simultaneously, the polling sequence, as shown in Table 66, is observed. Table 66. Priority within Interrupt Level Source IPSM IRTC IADE WDT ITEMP IE0 TF0 IE1 TF1 ISPI/I2CI RI/TI TF2/EXF2 Priority 0 (Highest) 1 2 3 4 5 6 7 8 9 10 11 (Lowest) Description Power Supply Monitor Interrupt RTC Interval Timer interrupt ADE Energy measurement interrupt Watchdog Timer Overflow Interrupt Temperature ADC interrupt External Interrupt 0 Timer/Counter 0 Interrupt External Interrupt 1 Timer/Counter 1 Interrupt SPI/I2C Interrupt UART Serial Port Interrupt Timer/Counter 2 Interrupt INTERRUPT FLAGS The interrupt and status flags associated with the interrupt vectors are shown in Table 67 and Table 68. Most of the interrupts have flags associated with them. Rev. PrD | Page 84 of 140 Preliminary Technical Data ADE7169F16 Table 67. Interrupt Flags Interrupt Source Flags IE0 TF0 IE1 TF1 RI + TI TCON.1 TCON.5 TCON.3 TCON.7 SCON.1 SCON.0 T2CON.7 T2CON.6 - TF2 + EXF2 ITEMP (Temperature ADC) IPSM (Power Supply) IADE (Energy Measurement DSP) IPSMF.6 Bit Address IE0 TF0 IE1 TF1 TI RI TF2 EXF2 FPSM MIRQSTL.7 Details External Interrupt 0 Timer 0 External Interrupt 1 Timer 1 Transmit Interrupt Receive Interrupt Timer 2 overflow flag Timer 2 external flag The Temperature ADC interrupt does not have an interrupt flag associated with it. PSM interrupt flag Read MIRQSTH, MIRQSTM, MIRQSTL. If the AUTOCLR bit in the IPSME SFR is set, each of these bytes will be reset after they are read. This is done on a per byte basis. Reading MIRQSTH reads and clears only MIRQSTH. Table 68. Status Flags Interrupt Source Flags ITEMP (Temperature ADC) ISPI/I2CI SPI2CSTAT SPI2CSTAT TIMECON.7 TIMECON.2 WDCON.2 IRTC (RTC Interval Timer) WDT (Watchdog Timer) Bit Address WDS Details The Temperature ADC interrupt does not have an status flag associated with it. SPI Interrupt Status register I2C Interrupt Status register RTC Midnight flag RTC Alarm flag Watchdog Timeout flag A functional block diagram of the interrupt system is shown in Figure 62. Note that the PSM interrupt is the only interrupt in the highest priority level. If an external wakeup event occurs to wake the ADE7169F16 from PSM2, a pending external interrupt will be generated. When the EX0 or EX1 bits are set in the Interrupt Enable SFR (IE, 0xA8) to enable external interrupts, the program counter will be loaded with the IE0 or IE1 interrupt vector. The IE0 and IE1 interrupt flags in the TCON register will not be affected by events that occur when the 8052 MCU core is shut down during PSM2 — see the Power Supply Monitor Interrupt (PSM) section. The RTC, temperature ADC and I2C/SPI interrupts are latched such that pending interrupts cannot be cleared without entering their respective interrupt service routines. Clearing the RTC Midnight and Alarm flags will not clear a pending RTC interrupt. Similarly, clearing the I2C/SPI status bits in the SPI Interrupt Status Register SFR (SPISTAT, 0xEA) will not cancel a pending I2C/SPI interrupt. These interrupts will remain pending until the RTC or I2C/SPI interrupt vectors are enabled. Their respective interrupt service routines will be entered shortly thereafter. Figure 62 shows how the interrupts are cleared when the interrupt service routines are entered. Some interrupts with multiple interrupt sources are not automatically cleared, specifically the PSM, ADE, UART and Timer 2 interrupt vectors. Note that the INT0 and INT1 interrupts are only cleared if the external interrupt is configured to be triggered by a falling edge, by setting IT0 in the Timer/Counter 0 and 1 Control SFR (TCON, 0x88). If INT0 or INT1 is configured to interrupt on a low level, the interrupt service routine will be reentered until the respective pin goes high. Rev. PrD | Page 85 of 140 ADE7169F16 Preliminary Technical Data IE/IEIP2 REGISTERS IP/IEIP2 REGISTERS PRIORITY LEVEL LOW PSM RTC IPSMF HIGH HIGHEST FPSM (IPSMF.6) IPSME IN OUT MIDNIGHT ALARM LATCH RESET ADE MIRQSTH MIRQSTM MIRQSTL MIRQSTL.7 MIRQENHMIRQENM MIRQENL WATCHDOG TIMEOUT WATCHDOG TEMP ADC WDIR IN OUT TEMPADC INTERRUPT LATCH RESET PSM2 IT0 EXTERNAL INTERRUPT 0 TIMER 0 0 INT0 IE0 1 TF0 PSM2 IT1 EXTERNAL INTERRUPT 1 TIMER 1 INT1 0 IE1 1 UART TIMER 2 IT1 TF1 SPI INTERRUPT I2C/SPI INTERRUPT POLLING SEQUENCE IT0 I2C INTERRUPT CFG.5 1 IN OUT 0 RESET LATCH RI TI TF2 EXF2 INDIVIDUAL INTERRUPT ENABLES GLOBAL INTERRUPT ENABLE (EA) Rev. PrD | Page 86 of 140 LEGEND AUTOMATIC CLEAR SIGNAL Preliminary Technical Data ADE7169F16 Figure 62: Interrupt System Functional Block Diagram INTERRUPT VECTORS When an interrupt occurs, the program counter is pushed onto the stack, and the corresponding interrupt vector address is loaded into the program counter. When the interrupt service routine has been completed, the program counter is popped off the stack by a RETI instruction. This allows program execution to resume from where it was interrupted. The interrupt vector addresses are shown in Table 69. Table 69. Interrupt Vector Addresses Source IE0 TF0 IE1 TF1 RI + TI TF2 + EXF2 ITEMP (Temperature ADC) ISPI/I2CI IPSM (Power Supply) IADE (Energy Measurement DSP) IRTC (RTC Interval Timer) WDT (Watchdog Timer) examine the stack or other variables that could have led the program astray. The watchdog timer interrupt also allows the watchdog to be used as a long interval timer. Note that the Watchdog Timer Interrupt is automatically configured as a high priority interrupt. This interrupt cannot be disabled by the EA bit in the IE register. Even if all of the other interrupts are disabled, the watchdog is kept active to watch over the program. Interrupt Latency The 8051 architecture requires that at least one instruction executes between interrupts. To ensure this, the 8051 MCU core hardware prevents the program counter from jumping to an ISR immediately after completing a RETI instruction or an access of the IP and IE registers. Vector Address 0x0003 0x000B 0x0013 0x001B 0x0023 0x002B 0x0033 0x003B 0x0043 0x004B 0x0053 0x005B The shortest interrupt latency is 3.25 instruction cycles, 800ns with a clock of 4.096MHz. The longest interrupt latency for a high priority interrupt results when a pending interrupt is generated during a low priority interrupt RETI, followed by a multiply instruction. This results in a maximum interrupt latency of 16.25 instruction cycles, 4us with a clock of 4.096MHz. CONTEXT SAVING WATCH DOG FUNCTIONALITY The watchdog timer generates a device reset or interrupt within a reasonable amount of time if the ADE7169F16 enters an erroneous state, possibly due to a programming error or electrical noise. The watchdog is enabled by default with a time out of 2 seconds and will create a system reset if not cleared within 2 seconds. The watchdog function can be disabled by clearing the WDE (watchdog enable) bit in the watchdog control (WatchDog Timer SFR (WDCON, 0xC0). When enabled, the watchdog circuit generates a system reset or interrupt (WDS) if the user program fails to set the WDE bit within a predetermined amount of time (see the PRE3…0 bits in Table 65). The watchdog timer is clocked from the 32 kHz external crystal connected between the CLKIN and CLKOUT pins. The WDCON SFR can be written only by user software if the double write sequence described in WDWR is initiated on every write access to the WDCON SFR Watchdog Timer Interrupt If the watchdog timer is not cleared within the watchdog timeout period, a system reset will occur unless the watchdog timer interrupt is enabled. The watchdog timer interrupt enable bit is located in the WatchDog Timer SFR (WDCON, 0xC0). Enabling the watchdog timer interrupt allows the program to When the 8052 vectors to an interrupt, only the program counter is saved on the stack. Therefore the interrupt service routine must be written to ensure that registers that are used in the main program are restored to their pre-interrupt state. Common registers that may be modified in the ISR are the accumulator, and the PSW register. Any general purpose registers that are used as scratchpads in the ISR should also be restored before exiting the interrupt. The example 8051 code shown below shows how to restore some commonly used registers: GeneralISR: ; save the current Accumulator value PUSH ACC ; save the current status and register bank selection PUSH PSW ; service interrupt … ; restore the status and register bank selection POP PSW ; restore the accumulator POP ACC RETI Rev. PrD | Page 87 of 140 Preliminary Technical Data ADE7169F16 LCD SFR REGISTER LIST LCD DRIVER The LCD module is capable of directly driving an LCD panel of 24 x 4 segments without compromising any ADE7169F16 functionalities. Using shared pins, the driver can accommodate an LCD with up to 26 x 4 segments. It is capable of driving LCDs with 2x, 3x and 4x multiplexing. LCD waveform voltages generated through internal charge pump circuitry support up to 5V LCDs. An external resistor ladder for LCD waveform voltage generation is also supported. The ADE7169F16 has an embedded LCD control circuit, LCD driver and power supply circuit. The LCD module is functional in all Operating modes. There are six LCD control registers that configure the driver for the specific type of LCD in the end system and set up the user display preferences. The LCD Configuration SFR (LCDCON, 0x95), LCD Configuration X SFR (LCDCONX, 0x9C) and LCD Configuration Y SFR (LCDCONY, 0xB1) SFRs contains general LCD driver configuration information including the LCD enable and reset, as well as method of LCD voltage generation and the multiplex level. The LCD Clock SFR (LCDCLK, 0x96) configures timing settings for LCD frame rate and blink rate. LCD pins are configured for LCD functionality in the LCD Segment Enable SFR (LCDSEGE, 0x97) and LCD Segment Enable 2 SFR (LCDSEGE2, 0xED). Table 70. LCD Driver SFRs SFR address (hex) R/W Name Description 0x95 R/W LCDCON LCD Configuration SFR 0x96 R/W LCDCLK LCD Clock 0x97 R/W LCDSEGE LCD Segment Enable 0x9C R/W LCDCONX LCD Configuration X 0xAC R/W LCDPTR LCD Pointer 0xAE R/W LCDDAT LCD Data 0xB1 R/W LCDCONY LCD Configuration Y 0xED R/W LCDSEGE2 LCD Segment Enable 2 Table 71. LCD Configuration SFR (LCDCON, 0x95) Bit Location 7 Bit Mnemonic LCDEN Default Value Description 0 6 LCDRST 0 5 BLINKEN 0 4 LCDPSM2 0 3 CLKSEL 0 2 BIAS 0 1-0 LMUX[1:0] 0 LCD enable. If this bit is set, the LCD driver is enabled. LCD data registers are reset to zero. If this bit is set, the LCD data registers will be reset to zero. Blink Mode enable bit. If this bit is set, blink mode is enabled. The blink mode is configured by the BLKMOD[1:0] and BLKFREQ[1:0] bits in the LCD Clock SFR (LCDCLK, 0x96) Force LCD off when in PSM2 (Sleep mode). 0 The LCD is disabled or enabled in PSM2 by LCDEN bit. 1 The LCD is disabled in PSM2 regarless of LCDEN setting. LCD clock selection fLCDCLK 0 2048Hz 1 128Hz Bias Mode 0 1/2 1 1/3 LCD Multiplex level Rev. PrD | Page 88 of 140 Preliminary Technical Data ADE7169F16 LMUX[1:0] 0 0 0 1 1 0 1 1 Reserved 2x FP27/COM3 is used as FP27 FP28/COM2 is used as FP28 3x FP27/COM3 is used as FP27 FP28/COM2 is used as COM2 4x FP27/COM3 is used as COM3 FP28/COM2 is used as COM2 Table 72. LCD Configuration X SFR (LCDCONX, 0x9C) Bit Location 7 6 Bit Mnemonic Reserved EXTRES Default Value Description 0 0 5-0 BIASLVL[5:0] 0 Reserved External Resistor Ladder selection bit. 0 External resistor ladder is disabled. Charge pump is enabled. 1 External resistor ladder is enabled. Charge pump is disabled. Bias Level Selection bits. See Table 73. Table 73. LCD bias voltage when contrast control is enabled BLVL[5] 0 1 VA (V) 1/2 Bias BLVL[4 : 0] Vref × 31 ⎛ BLVL[4 : 0] ⎞ Vref × ⎜1 + ⎟ 31 ⎝ ⎠ 1/3 Bias VB VC VB VC VB = VA VC = 2 x VA VB = 2 x VA VC = 3 x VA Table 74. LCD Configuration Y SFR (LCDCONY, 0xB1) Bit Location 7 6 Bit Mnemonic Reserved INV_LVL Default Value Description 0 0 5-2 Reserved 0 This bit should be kept cleared for proper operation Frame Inversion Mode Enable bit If this bit is set, frames are inverted every other frame If this bit is cleared, frames are not inverted These bits should be kept cleared for proper operation 1 UPDATEOVER 0 0 REFRESH 0 Update finished flag bit. This bit is updated by LCD driver. When set, indicates that the LCD memory has been updated and a new frame has begun. Refresh LCD data memory bit, this bit should be set by user. When set, the LCD driver does not use the data in the LCD data registers to update display. The LCD data registers can be updated by the 8052. When clear, the LCD driver will use the data in the LCD data registers to update display at the next frame. Table 75. LCD Clock SFR (LCDCLK, 0x96) Bit Location Bit Mnemonic Default Value Description Rev. PrD | Page 89 of 140 ADE7169F16 Preliminary Technical Data 7-6 BLKMOD[1:0] 0 5-4 BLKFREQ[1:0] 0 3-0 FD[3:0] 0 Blink Mode Clock Source Configuration bits BLKMOD[1:0] 0 0 The blink rate is controlled by software. The display is OFF. 0 1 The blink rate is controlled by software. The display is ON. 1 0 The blink rate is 2 Hz 1 1 The blink rate is set by BLKFREQ[1:0] Blink Rate Configuration bits These bits control LCD blink rate if BLKMOD[1:0]=11 BLKFREQ[1: Blink rate (Hz) 0] 0 0 1 0 1 1/2 1 0 1/3 1 1 1/4 LCD Frame Rate Selection bits. See Table 76 and Table 77. Table 76. LCD frame rate selection for fLCDCLK=2048Hz (LCDCON[3]=0) 2x multiplexing 3x multiplexing 4x multiplexing FD3 FD2 FD1 FD0 fLCD(Hz) Frame Rate (Hz) fLCD(Hz) Frame Rate (Hz) fLCD(Hz) Frame Rate (Hz) 0 0 0 1 256 128 512 170.7 512 128 0 0 1 0 170.7 85.3 341.3 113.8 341.3 85.3 0 0 1 1 128 64 256 85.3 256 64 0 1 0 0 102.4 51.2 204.8 68.3 204.8 51.2 0 1 0 1 85.3 42.7 170.7 56.9 170.7 42.7 0 1 1 0 73.1 36.6 146.3 48.8 146.3 36.6 0 1 1 1 64 32 128 42.7 128 32 1 0 0 0 56.9 28.5 113.8 37.9 113.8 28.5 1 0 0 1 51.2 25.6 102.4 34.1 102.4 25.6 1 0 1 0 46.5 23.25 93.1 31 93.1 23.25 1 0 1 1 42.7 21.35 85.3 28.4 85.3 21.35 1 1 0 0 39.4 19.7 78.8 26.3 78.8 19.7 1 1 0 1 36.6 18.3 73.1 24.4 73.1 18.3 1 1 1 0 34.1 17.05 68.3 22.8 68.3 17.05 1 1 1 1 32 16 64 21.3 64 16 0 0 0 0 16 8 32 10.7 32 8 Table 77. LCD frame rate selection for fLCDCLK=128Hz (LCDCON[3]=1) FD3 FD2 FD1 FD0 fLCD(Hz) 2x multiplexing 3x multiplexing 4x multiplexing Frame Rate (Hz) Frame Rate (Hz) Frame Rate (Hz) Rev. PrD | Page 90 of 140 Preliminary Technical Data ADE7169F16 1 1 1 1 128 64 42.7 32 0 0 0 0 64 32 21.3 16 0 0 0 1 32 16 10.7 8 0 0 1 0 21.3 10.6 10.7 8 0 0 1 1 16 8 10.7 8 : Boxes shaded in grey are not within the range of typical LCD frame rates Table 78. LCD Segment Enable SFR (LCDSEGE, 0x97) Bit Location 7 Bit Mnemonic FP25EN Default Value Description 0 6 FP24EN 0 5 FP23EN 0 4 FP22EN 0 3 FP21EN 0 2 FP20EN 0 1-0 FDELAY 0 FP25 Function Select bit 0 General Purpose I/O 1 LCD Function FP24 Function Select bit 0 General Purpose I/O 1 LCD Function FP23 Function Select bit 0 General Purpose I/O 1 LCD Function FP22 Function Select bit 0 General Purpose I/O 1 LCD Function FP21 Function Select bit 0 General Purpose I/O 1 LCD Function FP20 Function Select bit 0 General Purpose I/O 1 LCD Function Delay before powerdown? FDELAY[1:0] 0 0 No timeout 0 1 2 cycles 1 0 4 cycles 1 1 8 cycles Table 79. LCD Pointer SFR (LCDPTR, 0xAC) Bit Location 7 Bit Mnemonic W/R Default Value Description 0 Read or Write LCD bit If this bit is set, the data in LCDDAT will be written to the address indicated by the bits LCDPTR[5 :0] 6 5-0 RESERVED ADDRESS 0 0 Reserved LCD Memory Address - See Table 82. Rev. PrD | Page 91 of 140 ADE7169F16 Preliminary Technical Data Table 80. LCD Data SFR (LCDDAT, 0xAE) Bit Location 7-0 Bit Mnemonic LCDDATA Default Value 0 Description Data to be written into or read out of the LCD Memory SFRs. Table 81. LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) Bit Location 7-4 Bit Mnemonic RESERVED Default Value Description 0 Reserved 3 FP19EN 0 2 FP18EN 0 1 FP17EN 0 0 FP16EN 0 FP19 Function Select bit 0 General Purpose I/O 1 LCD Function FP18 Function Select bit 0 General Purpose I/O 1 LCD Function FP17 Function Select bit 0 General Purpose I/O 1 LCD Function FP16 Function Select bit 0 General Purpose I/O 1 LCD Function LCD SETUP LCD TIMING AND WAVEFORMS The LCD Configuration SFR (LCDCON, 0x95) configures the LCD module to drive the type of LCD in the user end system. The BIAS and LMUX[1:0] bits in this SFR should be set according to the LCD specifications. An LCD segment acts like a capacitor that is charged and discharged at a certain rate. The rate at which these capacitors are charged and discharged, the refresh rate, determines the visual characteristics of the LCD. A slow refresh rate will result in the user being able to see the LCD blink on and off in between refreshes. A fast refresh rate will present a screen that appears to be lit up continuously. However, a faster refresh rate consumes more power. The COM2/FP28 and COM3/FP27 pins default to LCD segment lines. Selecting the 3x multiplex level in the LCD Configuration SFR (LCDCON, 0x95) by setting LMUX[1:0] to 2d, changes the FP28 pin functionality to COM2. The 4x multiplex level selection, LMUX[1:0]=3d, changes the FP28 pin to COM2 and the FP27 pin to COM3. LCD segments FP0-FP15 are enabled by default. Additional pins are selected for LCD functionality in the LCD Segment Enable SFR (LCDSEGE, 0x97) and LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) where there are individual enable bits for segment pins FP16-25. The LCD pins do not have to be enabled sequentially. For example, if the alternate function of FP23, the timer 2 input, is required, then any of the other shared pins, FP16-25, could be enabled instead. The Display Element Control section contains details about setting up the LCD data memory to turn individual LCD segments ON and OFF. Setting the LCDRST bit in the LCD Configuration SFR (LCDCON, 0x95) will reset the LCD data memory to its default, zero. A power on reset also clears the LCD data memory. The frame rate, or refresh rate, for the LCD module is derived from the LCD clock, fLCDCLK. The LCD clock is selected as 2048Hz or 128Hz by the CLKSEL bit in the LCD Configuration X SFR (LCDCONX, 0x9C). The minimum refresh rate that is needed for the LCD to appear solid, without blinking, is independent of the multiplex level. The LCD waveform frequency, fLCD, is the frequency at which the LCD switches which common line is active. Thus the LCD waveform frequency depends heavily on the multiplex level. The frame rate and LCD waveform frequency are set by fLCDCLK, the multiplex level and the FD[3:0] frame rate selection bits in the LCD Clock SFR (LCDCLK, 0x96). The LCD module provides 16 different frame rates for fLCDCLK=2048Hz, ranging from 8 to 128Hz for an LCD with 4x multiplexing. There are fewer options available with fLCDCLK=128Hz, ranging from 8 to 32Hz for a 4x multiplexed Rev. PrD | Page 92 of 140 Preliminary Technical Data ADE7169F16 LCD. The 128Hz clock is beneficial for battery operation because it consumes less power than the 2048Hz clock. The frame rate is set by the FD[3:0] bits in the LCD Clock SFR (LCDCLK, 0x96)—see Table 76 and Table 77. 07h FP15 FP15 FP15 FP15 FP14 FP14 FP14 FP14 06h FP13 FP13 FP13 FP13 FP12 FP12 FP12 FP12 05h FP11 FP11 FP11 FP11 FP10 FP10 FP10 FP10 The LCD waveform is inverted at twice the LCD waveform frequency, fLCD. This way each frame has an average DC offset of zero. ADC offset would degrade the lifetime and performance of the LCD. 04h FP9 FP9 FP9 FP9 FP8 FP8 FP8 FP8 03h FP7 FP7 FP7 FP7 FP6 FP6 FP6 FP6 02h FP5 FP5 FP5 FP5 FP4 FP4 FP4 FP4 BLINK MODE 01h FP3 FP3 FP3 FP3 FP2 FP2 FP2 FP2 Blink mode is enabled by setting the BLINKEN bit in the LCD Configuration SFR (LCDCON, 0x95). This mode is used to alternate between LCD on and off states so that the LCD screen appears to blink. There are two blinking modes: a software controlled blink mode and an automatic blink mode. 00h FP1 FP1 FP1 FP1 FP0 FP0 FP0 FP0 Software Controlled Blink Mode The LCD blink rate can be controlled by user code with the BLKMOD[1:0] bits in the LCD Clock SFR (LCDCLK, 0x96) by toggling the bits to turn the display on and off at a rate determined by the MCU code. Automatic Blink Mode There are five blink rates available if the RTC peripheral is enabled (enable the RTC by…xxx). These blink rates are selected by the BLKMOD[1:0] and BLKFREQ[1:0] bits in the LCD Clock SFR (LCDCLK, 0x96) – see Table 75. DISPLAY ELEMENT CONTROL A bank of 15 bytes of data memory located in the LCD module controls the on or off state of each segment of the LCD. The LCD data memory is stored in addresses 0 through 14 in the LCD module. Each byte configures the on and off states of two segment lines. The LSBs store the state of the even numbered segment lines and the MSBs store the state of the odd numbered segment lines. For example, LCD data address zero refers to segment lines one and zero—see Table 82. Note that the LCD data memory is maintained in the PSM2 operating mode. Table 82. LCD Data Memory accessed indirectly through LCD Pointer SFR (LCDPTR, 0xAC) and LCD Data SFR (LCDDAT, 0xAE) LCD Memory Address COM3 COM2 COM1 COM0 0Eh COM# designates the common lines FP# designates the segment lines The LCD data memory is accessed indirectly through the LCD Pointer SFR (LCDPTR, 0xAC)and Table 80. LCD Data SFR (LCDDAT, 0xAE). Moving a value to the LCD Pointer SFR (LCDPTR, 0xAC) selects the LCD data byte to be accessed and initiates a read or write operation—see Table 79. Writing to LCD Data registers To update the LCD data memory, first set the LSB of the LCD Configuration Y SFR (LCDCONY, 0xB1) to freeze the data being displayed on the LCD while updating it. Then, move the data to the LCD Data SFR (LCDDAT, 0xAE) prior to accessing the LCD Pointer SFR (LCDPTR, 0xAC). When the MSB of the LCD Pointer SFR (LCDPTR, 0xAC) is set, the content of the LCD Data SFR (LCDDAT, 0xAE) is transferred to the internal LCD data memory designated by the address in the LCD Pointer SFR (LCDPTR, 0xAC). Clear the LSB of the LCD Configuration Y SFR (LCDCONY, 0xB1) when all of the data memory has been updated to allow to use the new LCD set up for display. Sample 8052 code to update the segments attached to pins FP10 and FP11 on is shown below: ORL MOV MOV ANL LCDCONY,#01h ; start updating the data LCDDATA,#FFh LCDPTR,#80h OR 05h LCDCONY,#0FEh ; update finished Reading LCD Data registers COM3 COM2 COM1 COM0 FP28 FP28 FP28 FP28 0Dh FP27 FP27 FP27 FP27 FP26 FP26 FP26 FP26 0Ch FP25 FP25 FP25 FP25 FP24 FP24 FP24 FP24 0Bh FP23 FP23 FP23 FP23 FP22 FP22 FP22 FP22 0Ah FP21 FP21 FP21 FP21 FP20 FP20 FP20 FP20 09h FP19 FP19 FP19 FP19 FP18 FP18 FP18 FP18 08h FP17 FP17 FP17 FP17 FP16 FP16 FP16 FP16 When the MSB of the LCD Pointer SFR (LCDPTR, 0xAC) is cleared, the content of the LCD Data memory address designated by LCDPTR are transferred to the LCD Data SFR (LCDDAT, 0xAE). Sample 8052 code to read the contents of LCD data memory address 07h, which holds the on and off state of the segments attached to FP14 and FP15, is shown below: MOV MOV LCDPTR,#NOT 80h AND 07h R1, LCDDATA VOLTAGE GENERATION The ADE7169F16 provides two ways to generate the LCD Rev. PrD | Page 93 of 140 ADE7169F16 Preliminary Technical Data waveform voltage levels. The on-chip charge pump option can generate 5V. This makes it possible to use 5V LCDs with the 3.3V ADE7169F16. There is also an option to use an external resistor ladder with a 3.3V LCD. The EXTRES bit in the LCD Configuration X SFR (LCDCONX, 0x9C) selects the resistor ladder or charge pump option. When selecting how to generate the LCD waveform voltages, the following should be considered: • Power Consumption • Contrast Control • Lifetime Performance LCD EXTERNAL CIRCUITRY The voltage generation selection is made by bit EXTRES in the LCD Configuration X SFR (LCDCONX, 0x9C). This bit is clear by default for charge pump voltage generation but can be set to enable an external resistor ladder. Charge Pump: Voltage generation through the charge pump requires external capacitors to store charge. The external connections to VA, VB, and VC as well as VP1 and VP2 are shown in LCD Configuration X SFR (LCDCONX, 0x9C). LCDVC Power Consumption 470nF LCDVB In most LCDs, a high amount of current is required when the LCD waveforms change state. The external resistor ladder option draws a constant amount of current whereas the charge pump circuitry allows dynamic current consumption. If the LCD module is used with the internal charge pump option, when the display is disabled, the voltage generation is disabled, so that no power is consumed by the LCD function. This feature will result in significant power savings if the display is turned off in battery operation. 470nF LCDVA Charge Pump LCDVP1 and LCD Waveform LCDVP2 Circuitry 470nF 100nF Figure 63: External circuitry for Charge Pump option Contrast control External Resistor Ladder: The electrical characteristics of the liquid in the LCD change over temperature, requiring adjustments in the LCD waveform voltages to ensure a readable display. An added benefit of the internal charge pump voltage generation is a configurable bias voltage that can be compensated over temperature and supply to maintain contrast on the LCD. These compensations can be performed based on the ADE7169F16 temperature and supply voltage measurements—see the Temperature, Battery and Supply Voltage Measurements section. This dynamic contrast control is not easily implemented with external resistor ladder voltage generation. To enable the external resistor ladder option, set the EXTRES bit in the LCD Configuration X SFR (LCDCONX, 0x9C). When EXTRES=1, the LCD waveform voltages are supplied by the external resistor ladder. Since the LCD voltages are not being generated on-chip, the LCD bias compensation implemented to maintain contrast over temperature and supply is not possible. The LCD bias voltage sets the contrast of the display when the charge-pump provides the LCD waveform voltages. The ADE7169F16 provides 64 bias levels selectable using the BLVL bits in the LCD Configuration X SFR (LCDCONX, 0x9C). The voltage level on LCDVA, LCDVB and LCDVC depend on the the Interntal voltage reference value (Vref), BLVL[5:0] selection and the biasing selected as described in Table 73. The external circuitry needed for the resistor ladder option is shown in Figure 64. The resistors required should be in the range of 10k to 100k and based on the current required by the LCD being used. LCDVC LCDVB LCDVA LCD Waveform LCDVP1 Circuitry LCDVP2 Lifetime Performance DC offset on a segment will degrade its performance over time. The voltages generated through the internal charge pump switch faster than those generated by the external resistor ladder, reducing the likelihood of a DC voltage being applied to a segment and increasing the lifetime of the LCD. Figure 64: External circuitry for External Resistor Ladder option LCD FUNCTION IN PSM2 The LCDPSM2 bit in the LCD Configuration SFR (LCDCON, 0x95) and the LCDEN bit in the LCD Configuration SFR Rev. PrD | Page 94 of 140 Preliminary Technical Data ADE7169F16 To setup the same 3.3V LCD for use with an external resistor ladder: ; setup LCD pins to have LCD functionality (LCDCON, 0x95) control LCD functionality in the PSM2 operating mode. LCDPSM2 LCDEN Comments 0 0 The display is OFF in PSM2. MOV MOV 0 1 The display is ON in PSM2. 1 X The display is OFF in PSM2. Note that the LCD configuration and data memory is retained when the display is turned off. EXAMPLE LCD SETUP An example to set up the LCD peripheral for a specific LCD is described below. Type of LCD: 5V, 4x multiplexed with 1/3 bias, 96 segments Voltage Generation: Internal Charge Pump Refresh Rate: 64Hz LCDSEG, #FP20EN+FP21EN+FP22EN+FP23EN LCDSEGX, #FP16EN+FP17EN+FP18EN+FP19EN ; setup LCDCON for fLCDCLK=2048Hz, 1/3 bias and 4x multiplexing MOV LCDCON, #BIAS+LMUX1+LMUX0 ; setup LCDCONX for external resistor ladder MOV LCDCONX, #EXTRES ; set up refresh rate for 64Hz with fLCDCLK=2048Hz, from Table 76 MOV LCDCLK, #FD3+FD2+FD1+FD0 ; set up LCD data registers with data to be displayed using ; LCDPTR and LCDDATA registers ; turn all segments on FP25 ON and FP26 OFF ORL LCDCONY,#01h ; start data memory refresh MOV LCDDAT, #F0H MOV LCDPTR, #80h OR 0DH ANL LCDCONY,#0FEh ; end of data memory refresh ORL LCDCON,#LCDEN ; enable LCD A 96 segment LCD with 4x multiplexing requires 96/4=24 segment lines. There are 16 pins that automatically dedicated for use as LCD segments, FP0 to FP15. Eight more pins must be chosen for the LCD function. Since the LCD has 4x multiplexing, all four common lines are used so COM2/FP28 and COM3/FP27 cannot be utilized as segment lines. Based on the alternate functions of the pins used for FP16 through FP25, FP16-23 are chosen for the seven remaining segment lines. These pins will be enabled for LCD functionality in the LCD Segment Enable SFR (LCDSEGE, 0x97) and LCD Segment Enable 2 SFR (LCDSEGE2, 0xED). To determine contrast setting for this 5V LCD, look in Table 73 to find the BIASLVL[5:0] setting that corresponds to a VC of 5V in 1/3 Bias Mode. The nominal bias level setting for this LCD is BIASLVL[5:0]=[111111]. The LCD is setup with the following 8052 code: ; setup LCD pins to have LCD functionality MOV LCDSEG, # FP20EN+FP21EN+FP22EN+FP23EN MOV LCDSEGX, #FP16EN+FP17EN+FP18EN+FP19EN ; setup LCDCON for fLCDCLK=2048Hz, 1/3 bias and 4x multiplexing MOV LCDCON, #BIAS+LMUX1+LMUX0 ; setup LCDCONX for charge pump and BIASLVL[1110111] MOV LCDCONX, #BIASLVL5+BIASLVL4+BIASLVL3+ BIASLVL2+BIASLVL1+BIASLVL0 ; set up refresh rate for 64Hz with fLCDCLK=2048Hz, from Table 76 MOV LCDCLK, #FD3+FD2+FD1+FD0 ; set up LCD data registers with data to be displayed using ; LCDPTR and LCDDATA registers ; turn all segments on FP25 ON and FP26 OFF ORL LCDCONY,#01h ; start data memory refresh MOV LCDDAT, #F0H MOV LCDPTR, #80h OR 0DH ANL LCDCONY,#0FEh ; end of data memory refresh ORL LCDCON,#LCDEN ; enable LCD Rev. PrD | Page 95 of 140 ADE7169F16 Preliminary Technical Data FLASH MEMORY endurance figure of 20,000 cycles of operation at 25°C. FLASH MEMORY OVERVIEW Retention is the ability of the Flash memory to retain its programmed data over time. Again, the parts have been qualified in accordance with the formal JEDEC Retention Lifetime Specification (A117) at a specific junction temperature (TJ = 55°C). As part of this qualification procedure, the Flash memory is cycled to its specified endurance limit described previously, before data retention is characterized. This means that the Flash memory is guaranteed to retain its data for its full specified retention lifetime every time the Flash memory is reprogrammed. It should also be noted that retention lifetime, based on an activation energy of 0.6 eV, derates with TJ as shown in Figure 65. The 16 kbytes of flash memory are provided on-chip to facilitate code execution without any external discrete ROM device requirements. The program memory can be programmed incircuit, using the serial download mode provided or using conventional third party memory programmers. 300 250 Endurance quantifies the ability of the Flash/EE memory to be cycled through many program, read, and erase cycles. In real terms, a single endurance cycle is composed of four independent, sequential events: Initial page erase sequence 2. Read/verify sequence 3. Byte program sequence 4. Second read/verify sequence 150 100 0 40 The Flash memory arrays on the ADE7169F16 are fully qualified for two key Flash/EE memory characteristics: Flash/EE memory cycling endurance and Flash/EE memory data retention. ADI SPECIFICATION 100 YEARS MIN. AT TJ = 55°C 50 Flash/EE Memory Reliability 1. 200 50 60 70 90 80 TJ JUNCTION TEMPERATURE (°C) 100 110 04741-0-028 The ADE7169F16 provides 16kbytes of flash program/information memory. This memory is segmented into 32 pages of 512 bytes each. So, to reprogram one byte of flash memory, the 511 bytes in that page must be erased. The flash memory can be erased by page or all at once in a mass erase. There is a command to verify that a flash write operation has completed successfully. The ADE7169F16 flash memory controller also offers configurable flash memory protection. RETENTION (Years) Flash memory is a type of non-volatile memory that is incircuit programmable. The default, erased, state of a byte of flash memory is 0xFF. When a byte of flash memory is programmed, the required bits change from one to zero. The flash memory must be erased to turn the zeros back to ones. However, a byte of flash memory cannot be erased individually. The entire segment, or page, of flash memory that contains the byte must be erased. Figure 65. Flash/EE Memory Data Retention FLASH MEMORY ORGANIZATION The 16kbytes of flash memory provided by the ADE7169F16 are segmented into 32 pages of 512 bytes each. It is up to the user to decide which Flash memory he would like to allocate for data memory. It is recommended that each page be dedicated solely to program or data memory so that an instance does not arise where the program counter is loaded with data memory instead of an opcode from the program memory or where program memory is erased to update a byte of data memory. In reliability qualification, every byte in both the program and data Flash/EE memory is cycled from 00H to FFH until a first fail is recorded, signifying the endurance limit of the on-chip Flash/EE memory. As indicated in the specification table, the ADE7169F16 flash memory endurance qualification has been carried out in accordance with JEDEC Specification A117 over the industrial temperature range of –40°C, +25°C and +85°C. The results allow the specification of a minimum endurance figure over supply and temperature of 100,000 cycles, with a minimum Rev. PrD | Page 96 of 140 Preliminary Technical Data 0x3FFF 0x3E00 0x3DFF 0x3C00 0x3BFF 0x3A00 0x39FF 0x3800 0x37FF 0x3600 0x35FF 0x3400 0x33FF 0x3200 0x31FF 0x3000 0x2FFF 0x2E00 0x2DFF 0x2C00 0x2BFF 0x2A00 0x29FF 0x2800 0x27FF 0x2600 0x25FF 0x2400 0x23FF 0x2200 0x21FF 0x2000 PAGE 31 PAGE 30 PAGE 29 PAGE 28 PAGE 27 PAGE 26 PAGE 25 PAGE 24 PAGE 23 PAGE 22 PAGE 21 PAGE 20 PAGE 19 PAGE 18 PAGE 17 PAGE 16 0x1FFF 0x1E00 0x1DFF READ PROTECT 0x1C00 0x1BFF BIT 7 0x1A00 0x19FF 0x1800 0x17FF 0x1600 0x15FF READ PROTECT 0x1400 0x13FF BIT 6 0x1200 0x11FF 0x1000 0x0FFF 0x0E00 0x0DFF READ PROTECT 0x0C00 0x0BFF BIT 5 0x0A00 0x09FF 0x0800 0x07FF 0x0600 0x05FF READ PROTECT 0x0400 0x03FF BIT 4 0x0200 0x01FF 0x0000 CONTAINS PROTECTION SETTINGS ADE7169F16 USING THE FLASH MEMORY PAGE 15 PAGE 14 PAGE 13 READ PROTECT BIT 3 PAGE 12 PAGE 11 PAGE 10 PAGE 9 READ PROTECT BIT 2 The 16 kbytes of Flash memory are configured as 32 pages, each of 512 bytes. As with the other ADE7169F16 peripherals, the interface to this memory space is via a group of registers mapped in the SFR space – see . A data register, EDATA, holds the byte of data to be accessed. The byte of flash memory is addressed via the EADRH and EADRL registers. The Flash SFRs Table 83. Flash SFRs SFR Address Default Value Bit Addressable Description ECON 0xB9 0x00 No FLSHKY PROTKY 0xBA 0xBB 0xFF 0xFF No No Flash Control Flash Key Flash Protection Key EDATA 0xBC 0x00 No Flash Data PROTB0 0xBD 0xFF No Flash W/E Protection 0 PROTB1 0xBE 0xFF No Flash W/E Protection 1 PROTR 0xBF 0xFF No Flash Read protection EADRL 0xC6 0x00 No Flash Low address EADRH 0xC7 0x00 No Flash High address PAGE 8 PAGE 7 PAGE 6 PAGE 5 READ PROTECT BIT 1 PAGE 4 PAGE 3 PAGE 2 PAGE 1 READ PROTECT BIT 0 PAGE 0 Figure 66: Flash Memory Organization The flash memory can be protected from read or write/erase access. The protection is implemented in part of the last page of the flash memory, Page 31. Four of the bytes from this page are used to set up write/erase protection for each of the pages. Another byte is used for configuring read protection of the flash memory. The read protection is selected for groups of four pages. Finally, there is a byte used to store the key required for modifying the protection scheme. If any code protection is required, the last page of flash memory must be write/erase protected at a minimum. The implication of write/erase protecting the last page is that the content of the 506 bytes in this page that are available to the user must not change. Finally, ECON is an 8-bit control register that can be written to with one of seven Flash memory access commands to trigger various read, write, erase, and verify functions. Figure 67 demonstrates the steps required for access to the flash memory. ECON Command Address Thus it is recommended that if code protection is enabled, this last page should be used for program memory only if the firmware does not need to be updated in the field. If the firmware must be protected and can be updated at a future date, the last page should be used only for constants used by the program code that will not need to be read during emulation or debug. Therefore, Pages 0 through 30 are for general program and data memory use. It is recommended that Page 31 is used for constants or code that will not need to be updated. Note that the last 6 bytes of Page 31 are reserved for protecting the flash memory. EADRH EADRL Flash Protection Key FLSHKY ADDRESS DECODER FLSHKY=0x3B? PROTECTION DECODER ACCESS ALLOWED? TRUE: ACCESS ALLOWED ECON=0 FALSE: ACCESS DENIED ECON=1 Figure 67: Flash Memory Read/Write/Erase Protection Block Diagram ECON—Flash/EE Memory Control SFR Programming Flash memory is done through the Flash memory control Flash Control SFR (ECON, 0xB9). This SFR allows the user to read, write, erase, or verify the 16 kbytes of Flash memory. As a method of security, a key must be written to the FLSHKY register to initiate any user access to the flash Rev. PrD | Page 97 of 140 ADE7169F16 Preliminary Technical Data memory. Upon completion of the flash memory operation, the FLSHKY register is reset such that it must be written prior to another flash memory operation. Requiring the key to be set before an access to the flash memory decreases the likelihood of user code or data being overwritten by a program that has run amuck. done performing the requested operation. Then the PC increments to continue with the next instruction. Any interrupts requests that occur while the flash controller is performing an operation are not handled until the flash operation is complete. All peripherals, such as timers and counters, will continue to operate as configured throughout the flash memory access. The program counter, PC, is held on the instruction where the ECON register is written to until the flash memory controller is Table 84. Flash Control SFR (ECON, 0xB9) Bit Location 7-0 Bit Mnemonic ECON Default Value Description 0 1 2 3 4 5 8 Write byte: The value in EDATA is written to the Flash memory, at the page address given by EADRH and EARDL. Note that the byte being addressed must be pre-erased Erase page: A 512-byte page of Flash memory address is erased. The page is selected by the address in EADRH/L. Any address in the page can be written to EADRH/L to select it for erasure. Erase all: All 16kbytes of the Flash memory are erased. Note: This command is used during serial and parallel download modes but should not be executed by user code. Read byte: The byte in the Flash memory, addressed by EADRH/L, is read into EDATA. Erase page and write byte: The page that holds the byte addressed by EADRH/L is erased. Then, data in EDATA is written to the byte of flash memory addressed by EADRH/L. Protect code: See Protecting the Flash. Table 85. Flash Key SFR (FLSHKY, 0xBA) Bit Location 7-0 Bit Mnemonic FLSHKY Default Value Description 0xFF The content of this SFR is compared to the Flash key – 0x3B. If the two values match the next ECON operation is allowed - see Protecting the Flash. Table 86. Flash Protection Key SFR (PROTKY, 0xBB) Bit Location 7-0 Bit Mnemonic PROTKY Default Value Description 0xFF The content of this SFR is compared to the Flash memory location at address 0x3FFA. If the two values match, the update of the Write/Erase and Read protection set up is allowed - see Protecting the Flash. If the protection Key in the flash is 0xFF, PROTKY SFR value is not used for comparison. The PROTKY SFR is also used to write the protection key in the flash. This is done by writing the desired value in PROTKY and write 0x08 in the ECON SFR. This operation can only be done once. Table 87. Flash Data SFR (EDATA, 0xBC) Bit Location 7-0 Bit Mnemonic EDATA Default Value Description 0 Flash pointer data Table 88. Flash Write/Erase Protection 0 SFR (PROTB0, 0xBD) Bit Bit Default Description Rev. PrD | Page 98 of 140 Preliminary Technical Data Location 7-0 Mnemonic PROTB0 ADE7169F16 Value 0xFF This SFR is used to write the write/erase protection bits for pages 0 to 7 of the Flash memory – see Protecting the Flash. Clearing the bit enables the protection. PROTB0.7: Page 7 PROTB0.6: Page 6 PROTB0.5: Page 5 PROTB0.4: Page 4 PROTB0.3: Page 3 PROTB0.2: Page 2 PROTB0.1: Page 1 PROTB0.0: Page 0 Table 89. Flash Write/Erase Protection 1 SFR (PROTB1, 0xBE) Bit Location 7-0 Bit Mnemonic PROTB1 Default Value Description 0xFF This SFR is used to write the write/erase protection bits for pages 8 to 15 of the Flash memory – see Protecting the Flash. Clearing the bit enables the protection. PROTB1.7: Page 15 PROTB1.6: Page 14 PROTB1.5: Page 13 PROTB1.4: Page 12 PROTB1.3: Page 11 PROTB1.2: Page 10 PROTB1.1: Page 9 PROTB1.0: Page 8 Table 90. Flash Read Protection SFR (PROTR, 0xBF) Bit Location 7-0 Bit Mnemonic PROTR Default Value Description 0xFF This SFR is used to write the read protection bits for pages 0 to 31 of the Flash memory – see Protecting the Flash. Clearing the bit enables the protection. PROTR.7: Page 28 to 31 PROTR.6: Page 24 to 27 PROTR.5: Page 20 to 23 PROTR.4: Page 16 to 19 PROTR.3: Page 12 to 15 PROTR.2: Page 8 to 11 PROTR.1: Page 4 to 7 PROTR.0: Page 0 to 3 Table 91. Flash Low Byte Address SFR (EADRL, 0xC6) Bit Location 7-0 Bit Mnemonic EADRL Default Value Description 0 Flash pointer low byte address This SFR is also used to write the write/erase protection bits for pages 16 to 23 of the Flash memory – see Protecting the Flash. Clearing the bit enables the protection. EADRL.7: Page 23 EADRL.6: Page 22 EADRL.5: Page 21 Rev. PrD | Page 99 of 140 ADE7169F16 Preliminary Technical Data EADRL.4: Page 20 EADRL.3: Page 19 EADRL.2: Page 18 EADRL.1: Page 17 EADRL.0: Page 16 Table 92. Flash High Byte Address SFR (EADRH, 0xC7) Bit Location 7-0 Bit Mnemonic EADRH Default Value Description 0 Flash pointer high byte address This SFR is also used to write the write/erase protection bits for pages 24 to 31 of the Flash memory – see Protecting the Flash. Clearing the bit enables the protection. EADRH.7: Page 31 EADRH.6: Page 30 EADRH.5: Page 29 EADRH.4: Page 28 EADRH.3: Page 27 EADRH.2: Page 26 EADRH.1: Page 25 EADRH.0: Page 24 Flash functions Sample 8051 code is provided below to demonstrate how to use the Flash functions. For these examples, the byte of flash memory, 0x3C00 is accessed. MOV ECON, #04H ; Read Byte ; Data is ready in EDATA register Write Byte: Write F3H into flash memory byte 0x3C00. Erase Page and Write Byte: Erase the page containing flash memory byte 0x3C00 and then write F3H to that address. Note that the other 511 bytes in this page will be erased. MOV EDATA, #F3h MOV EADRH, #3Ch MOV EADRL, #00h MOV FLSHKY, #3Bh MOV ECON, #01H MOV EDATA, #F3h MOV EADRH, #3Ch MOV EADRL, #00h MOV FLSHKY, #3Bh MOV ECON, #05H ; Data to be written ; Setup byte address ; Write Flash security key. ; Write Byte ; Select page through byte address ; Write Flash security key. ; Erase Page ; Write Flash security key. ; Erase page and then write byte PROTECTING THE FLASH Erase Page: Erase the page containing flash memory byte 0x3C00. MOV EADRH, #3Ch MOV EADRL, #00h MOV FLSHKY, #3Bh MOV ECON, #02H ; Data to be written ; Setup byte address Two forms of protection are offered for this flash memory: read protection and write/erase protection. The read protection ensures that any pages that are read protected will not be able to be read by the end user. The write protection ensures that the flash memory cannot be erased or written over. This protects the end system from tampering and can prevent the code from being overwritten in the event of a runaway program. Erase All: Erase all of the 16kbyte flash memory MOV FLSHKY, #3Bh MOV ECON, #03H ; Write Flash security key. ; Erase All Read Byte: Read flash memory byte 0x3C00. MOV EADRH, #3Ch MOV EADRL, #00h MOV FLSHKY, #3Bh ; Setup byte address ; Write Flash security key. Write/erase protection is individually selectable for all of the 32 pages. Read protection is selected in groups of 4 pages. See Figure 66 for the groupings. The protection bits are stored in the last flash memory locations, addresses 0x3FFA through 0x3FFF– see Figure 68. 4 bytes are reserved for write/erase protection, 1 byte for read protection and another byte to set the protection security key. The user must enable read and write/erase protection for the last page at a minimum for the entire protection scheme to work. Rev. PrD | Page 100 of 140 Preliminary Technical Data ADE7169F16 Remark: The read protection does not prevent MOVC commands to be executed within the code. Note that once the protection key is configured, it cannot be modified. There is an additional layer of protection offered by a protection security key. The user can setup a protection security key so that the protection scheme cannot be changed without this key. Once the protection key has been configured, it may not be modified. Enabling Flash Protection by Code The protection byts in the Flash can be programmed using Flash controller command and programming ECON to 0x08. The EADRH, EADRL, PROTB1 and PROTB0 bytes are used in this case to store the data to be written to the 32 bits of write protection. Note that the EADRH and EADRL registers are not used as data pointers here, but to store write protection data. EADRH 0x3FFF WP 31 WP 30 WP 29 WP 28 WP 27 WP 26 WP 25 WP 24 EADRL 0x3FFE WP 23 WP 22 WP 21 WP 20 WP 19 WP 18 WP 17 WP 16 0x3FFD WP 15 WP 14 WP 13 WP 12 WP 11 WP 10 WP 9 WP 9 0x3FFC WP 7 WP 6 WP 5 WP 4 WP 3 WP 2 WP 1 WP 0 RP RP RP RP RP RP 0x3FFB 31-28 27-24 23-20 19-16 15-12 11-8 RP 7-4 RP 3-0 PROTB1 PROTB0 PROTR PROTKY 0x3FFA 0x3FF9 PROTECTION KEY 4. Run the protection command by writing 08H to the ECON register. 5. Reset the chip to activate the new protection. To enable read and write/erase protection for the last page only, use the following 8051 code. Writing the flash protection command to the ECON register initiates programming the protection bits in the flash. ; enable write/erase protection on the last page only MOV EADRH, #07FH MOV EADRL, #0FFH MOV PROTB1, #FFH MOV PROTB0, #FFH ; enable read protection on the last four pages only MOV PROTR, #07FH ; set up a protection key of 0A3H. This command can be ; omitted to use the default protection key of 0xFF MOV PROTKY, #0A3H ; write the flash key to the FLSHKY register to enable flash ; access. The flash access key is not configurable. MOV FLSHKY, #3BH ; write flash protection command to the ECON register MOV ECON, #08H 0x3E00 Figure 68: Flash Protection in Page 31 Enabling Flash Protection by emulator commands The sequence for writing the protection bits is: 1. Set up the EADRH, EADRL, PROTB1 and PROTB0 registers with the write/erase protection bits. When erased, the protection bits default to 1, like any other bit of Flash memory. The default protection setting is for no protection. To enable protection, write a 0 to the bits corresponding to the pages that should be protected. 2. Set up the PROTR register with the read protection bits. Note that every read protection bit protects four pages. To enable the read protection bit, write a 0 to the bits that should be read protected. 3. To enable the protection key, write to the PROTKY register. If enabled, the protection key will be required to modify the protection scheme. The protection key, flash memory address 0x3FFA defaults to FFH so if the PROTKY register is not written to, it will remain 0xFFH. If the protection key is written to, the PROTKY register must be written with this value every time the protection functionality is accessed. Another way to set the Flash protection bytes is to use some reserved emulator commands available only in download mode. These commands write directly to the SFRs and can be used to duplicate the operation mentioned in the Enabling Flash Protection by Code paragraph. Once these Flash bytes are written, the part can exit emulation mode by reset and the protections will be effective. This method can be used in production and implemented after downloading the program. The commands used for this operation are an extension of the commands listed in the application note uC004 – Understanding the Serial Download Protocol: - Command with ASCII code ‘I’ or 0x49 write the data into R0 - Command with ASCII code ‘F’ or 0x46 write R0 into the SFR address defined in the data of this command Omitting the protocol defined in uC004, the sequence to load protections are similar to the sequence presented mentioned in the Enabling Flash Protection by Code paragraph.except that two emulator commands are necessary to replace one assembly Rev. PrD | Page 101 of 140 ADE7169F16 Preliminary Technical Data command. For example to write the protection value in EADRH the two following commands need to be executed: VERIFY BYTE - Command ‘I ‘ with Data = Value of protection byte 0x3FFF - Command ‘F’ with Data = 0xC7 Note that the core microcontroller operation is idled until the requested flash memory operation is complete. In practice, this means that even though the Flash operation is typically initiated with a two-machine-cycle MOV instruction (to write to the Flash Control SFR (ECON, 0xB9)), the next instruction is not executed until the Flash/EE operation is complete. This means that the core cannot respond to interrupt requests until the Flash/EE operation is complete, although the core peripheral functions such as counter/ timers continue to count as configured throughout this period. Following this protocol, the protection can be written to the Flash using the same sequence as mentioned in the Enabling Flash Protection by Code paragraph. When the part is reset the protection will be effective. Notes on Flash Protection The flash protection scheme is disabled by default so that none of the pages of the flash are protected from reading or writing/erasing. The last page must be read and write/erase protected for the protection scheme to work. To activate the protection settings, the ADE7169F16 must be reset after configuring the protection. After configuring protection on the last page and resetting the part, protections that have been enabled can only be removed by mass erasing the flash memory. The protection bits are read and erase protected by enabling read and write/erase protection the last page, but the protection bits are never truly write protected. Protection bits can be programmed modified from a 1 to a 0, even after the last page has been protected. In this way, more protection can be added but none can be removed. Serial Downloading The ADE7169F16 facilitates code download via the standard UART serial port. The parts enter serial download mode after a reset or a power cycle if the SDEN pin is pulled low through an external 1 kΩ resistor. Once in serial download mode, the hidden embedded download kernel executes. This allows the user to download code to the full 16 kbytes of Flash memory while the device is in circuit in its target application hardware. Protection configured in the last page of the ADE7169F16 affects whether flash memory can be accessed in serial download mode. Read protected pages cannot be read. Write/erase protected pages cannot be written or erased. The configuration bits cannot be programmed in serial download mode. The protection scheme is intended to protect the end system. Protection should be disabled while developing and emulating code. Flash memory timing Typical program and erase times for the flash memory are as follows: Bytes Affected Flash Memory Timing WRITE BYTE 1 byte 30us ERASE PAGE 512 bytes 20ms ERASEALL 16 kbytes 200ms READ BYTE 1 bytes 100ns ERASEPAGE and WRITE BYTE 512 bytes 21ms 100ns IN CIRCUIT PROGRAMMING If a page of code is write/erase protected, it cannot be written over even if an erase all command is issued. The write/erase protected page will not be updated if new code is downloaded. If a page is read protected, this part of the code cannot be read or emulated. Command 1 byte Rev. PrD | Page 102 of 140 Preliminary Technical Data ADE7169F16 TIMERS The ADE7169F16 has three 16-bit timer/ counters: Timer 0, Timer 1, and Timer 2. The timer/counter hardware is included on-chip to relieve the processor core of the overhead inherent in implementing timer/counter functionality in software. Each timer/counter consists of two 8-bit registers: THx and TLx (x = 0, 1, or 2). All three can be configured to operate either as timers or as event counters. When functioning as a timer, the TLx register is incremented every machine cycle. Thus, one can think of it as counting machine cycles. Because a machine cycle on a single-cycle core consists of one core clock period, the maximum count rate is the core clock frequency. When functioning as a counter, the TLx register is incremented by a 1-to-0 transition at its corresponding external input pin: T0, T1, or T2. When the samples show a high in one cycle and a low in the next cycle, the count is incremented. Because it takes two machine cycles (two core clock periods) to recognize a 1-to-0 transition, the maximum count rate is half the core clock frequency. There are no restrictions on the duty cycle of the external input signal, but, to ensure that a given level is sampled at least once before it changes, it must be held for a minimum of one full machine cycle. User configuration and control of all timer operating modes is achieved via the SFRs in Table 93. Table 93. Timer SFRs SFR Address Bit Addressable Description TCON 0x88 Yes Timer0 and Timer1 Control Register – see Table 95 TMOD 0x89 No Timer Mode register– see Table 94 TL0 0x8A No Timer0 LSB– see Table 98 TL1 0x8B No Timer1 LSB– see Table 100 TH0 0x8C No Timer0 MSB– see Table 97 TH1 0x8D No Timer1 MSB– see Table 99 T2CON 0xC8 Yes Timer2 Control Register – see Table 96 RCAP2L 0xCA No Timer2 Reload/Capture LSB – see Table 104 RCAP2H 0xCB No Timer2 Reload/Capture MSB – see Table 103 TL2 0xCC No Timer2 LSB – see Table 102 TH2 0xCD No Timer2 MSB – see Table 101 TIMER SFR REGISTER LIST Table 94. Timer/Counter 0 and 1 Mode SFR (TMOD, 0x89) Bit Location 7 Bit Mnemonic Gate1 Default Value 0 6 C_T1 0 5-4 T1_M1, T1_M0 00 Description Timer 1 Gating Control. Set by software to enable Timer/Counter 1 only while the INT1 pin is high and the TR1 control is set. Cleared by software to enable Timer 1 whenever the TR1control bit is set. Timer 1 Timer or Counter Select Bit. Set by software to select counter operation (input from T1 pin). Cleared by software to select the timer operation (input from internal system clock). Timer 1 Mode Select bits M1 M0 Description 0 0 0 1 TH1 operates as an 8-bit timer/counter. TL1 serves as 5-bit prescaler. 16-Bit Timer/Counter. TH1 and TL1 are cascaded; there is no prescaler. Rev. PrD | Page 103 of 140 ADE7169F16 Preliminary Technical Data 1 3 Gate0 0 2 C_T0 0 1-0 T0_M1, T0_M0 00 0 8-Bit Autoreload Timer/Counter. TH1 holds a value that is to be reloaded into TL1 each time it overflows. 1 1 Timer/Counter 1 Stopped. Timer 0 Gating Control. Set by software to enable Timer/Counter 0 only while the INT0 pin is high and the TR0 control bit is set. Cleared by software to enable Timer 0 whenever the TR0 control bit is set. Timer 0 Timer or Counter Select Bit. Set by software to the select counter operation (input from T0 pin). Cleared by software to the select timer operation (input from internal system clock). Timer 0 Mode Select Bits M1 M0 Description 0 0 TH0 operates as an 8-bit timer/counter. TL0 serves as a 5-bit prescaler. 0 1 16-Bit Timer/Counter. TH0 and TL0 are cascaded; there is no prescaler. 1 0 8-Bit Autoreload Timer/Counter. TH0 holds a value that is to be reloaded into TL0 each time it overflows. 1 1 TL0 is an 8-bit timer/counter controlled by the standard Timer 0 control bits. TH0 is an 8-bit timer only, controlled by Timer 1 control bits. Table 95. Timer/Counter 0 and 1 Control SFR (TCON, 0x88) Bit Location 7 Bit Addr. 0x8F Bit Name TF1 Default Value 0 6 0x8E TR1 0 5 0x8D TF0 0 4 0x8C TR0 0 3 0x8B IE11 0 2 0x8A IT11 0 1 0x89 IE01 0 0 0x88 IT01 0 Description Timer 1 Overflow Flag. Set by hardware on a Timer/Counter 1 overflow. Cleared by hardware when the program counter (PC) vectors to the interrupt service routine. Timer 1 Run Control Bit. Set by the user to turn on Timer/Counter 1. Cleared by the user to turn off Timer/Counter 1. Timer 0 Overflow Flag. Set by hardware on a Timer/Counter 0 overflow. Cleared by hardware when the PC vectors to the interrupt service routine. Timer 0 Run Control Bit. Set by the user to turn on Timer/Counter 0. Cleared by the user to turn off Timer/Counter 0. External Interrupt 1 (INT1) Flag. Set by hardware by a falling edge or by a zero level applied to the external interrupt pin, INT1, depending on the state of Bit IT1. Cleared by hardware when the PC vectors to the interrupt service routine only if the interrupt was transition-activated. If level-activated, the external requesting source controls the request flag rather than the on-chip hardware. External Interrupt 1 (IE1) Trigger Type. Set by software to specify edge-sensitive detection, that is, 1-to-0 transition. Cleared by software to specify level-sensitive detection, that is, zero level. External Interrupt 0 (INT0) Flag. Set by hardware by a falling edge or by a zero level being applied to the external interrupt pin, INT0, depending on the statue of Bit IT0. Cleared by hardware when the PC vectors to the interrupt service routine only if the interrupt was transition-activated. If level-activated, the external requesting source controls the request flag rather than the on-chip hardware. External Interrupt 0 (IE0) Trigger Type. Set by software to specify edge-sensitive detection, that is, 1-to-0 transition. Cleared by software to specify level-sensitive detection, that is, zero level. __________________________________________ Rev. PrD | Page 104 of 140 Preliminary Technical Data 2 ADE7169F16 These bits are not used to control Timer/Counters 0 and 1, but are used instead to control and monitor the external INT0 and INT1 interrupt pins. Table 96. Timer/Counter 2 Control SFR (T2CON, 0xC8) Bit Location 7 Bit Addr. 0xCF Bit Name TF2 Default Value 0 6 0xCE EXF2 0 5 0xCD RCLK 0 4 0xCC TCLK 0 3 0xCB EXEN2 0 2 0xCA TR2 0 1 0xC9 CNT2 0 0 0xC8 CAP2 0 Description Timer 2 Overflow Flag. Set by hardware on a Timer 2 overflow. TF2 cannot be set when either RCLK = 1 or TCLK = 1. Cleared by user software. Timer 2 External Flag. Set by hardware when either a capture or reload is caused by a negative transition on T2EX and EXEN2 = 1. Cleared by user software. Receive Clock Enable Bit. Set by the user to enable the serial port to use Timer 2 overflow pulses for its receive clock in serial port Modes 1 and 3. Cleared by the user to enable Timer 1 overflow to be used for the receive clock. Transmit Clock Enable Bit. Set by the user to enable the serial port to use Timer 2 overflow pulses for its transmit clock in serial port Modes 1 and 3. Cleared by the user to enable Timer 1 overflow to be used for the transmit clock. Timer 2 External Enable Flag. Set by the user to enable a capture or reload to occur as a result of a negative transition on T2EX if Timer 2 is not being used to clock the serial port. Cleared by the user for Timer 2 to ignore events at T2EX. Timer 2 Start/Stop Control Bit. Set by the user to start Timer 2. Cleared by the user to stop Timer 2. Timer 2 Timer or Counter Function Select Bit. Set by the user to select the counter function (input from external T2 pin). Cleared by the user to select the timer function (input from on-chip core clock). Timer 2 Capture/Reload Select Bit. Set by the user to enable captures on negative transitions at T2EX if EXEN2 = 1. Cleared by the user to enable autoreloads with Timer 2 overflows or negative transitions at T2EX when EXEN2 = 1. When either RCLK = 1 or TCLK = 1, this bit is ignored and the timer is forced to autoreload on Timer 2 overflow. Table 97. Timer 0 High byte SFR (TH0, 0x8C) Bit Location 7-0 Bit Mnemonic TH0 Default Value Description 0 Timer 0 Data high byte Table 98. Timer 0 Low byte SFR (TL0, 0x8A) Bit Location 7-0 Bit Mnemonic TL0 Default Value Description 0 Timer 0 Data high byte Table 99. Timer 1 High byte SFR (TH1, 0x8D) Bit Location 7-0 Bit Mnemonic TH1 Default Value 0 Description Timer 1 Data high byte Table 100. Timer 1 Low byte SFR (TL1, 0x8B) Bit Location 7-0 Bit Mnemonic TL1 Default Value 0 Description Timer 1 Data high byte Rev. PrD | Page 105 of 140 ADE7169F16 Preliminary Technical Data Table 101. Timer 2 High byte SFR (TH2, 0xCD) Bit Location Bit Mnemonic 7-0 Default Value 0 TH2 Description Timer 2 Data high byte Table 102. Timer 2 Low byte SFR (TL2, 0xCC) Bit Location Bit Mnemonic 7-0 Default Value 0 TL2 Description Timer 2 Data high byte Table 103. Timer 2 Reload/capture High byte SFR (RACP2H, 0xCB) Bit Location Bit Mnemonic 7-0 Default Value 0 TH2 Description Timer 2 Reload/capture high byte Table 104. Timer 2 Reload/capture Low byte SFR (RACP2L, 0xCA) Bit Location Bit Mnemonic 7-0 Default Value 0 TL2 Description Timer 2 Reload/capture low byte This section describes the operating modes for Timer/Counters 0 and 1. Unless otherwise noted, these modes of operation are the same for both Timer 0 and Timer 1. As the count rolls over from all 1s to all 0s, it sets the timer overflow flag, TF0. TF0 can then be used to request an interrupt. The counted input is enabled to the timer when TR0 = 1 and either Gate = 0 or INT0 = 1. Setting Gate = 1 allows the timer to be controlled by external input INT0 to facilitate pulsewidth measurements. TR0 is a control bit in the Timer/Counter 0 and 1 Control SFR (TCON, 0x88); the Gate bit is in Timer/Counter 0 and 1 Mode SFR (TMOD, 0x89). The 13-bit register consists of all 8 bits of Timer 0 High byte SFR (TH0, 0x8C) and the lower 5 bits of Timer 0 Low byte SFR (TL0, 0x8A). The upper 3 bits of Timer 0 Low byte SFR (TL0, 0x8A) are indeterminate and should be ignored. Setting the run flag (TR0) does not clear the registers. Mode 0 (13-Bit Timer/Counter) Mode 1 (16-Bit Timer/Counter) Mode 0 configures an 8-bit timer/counter. Figure 69 shows Mode 0 operation. Note that the divide-by-12 prescaler is not present on the single-cycle core. Mode 1 is the same as Mode 0 except that the Mode 1 timer register runs with all 16 bits. Mode 1 is shown in Figure 70. TIMER 0 AND TIMER 1 Timer/Counter 0 and 1 Data Registers Each timer consists of two 8-bit registers: Timer 0 High byte SFR (TH0, 0x8C), Timer 0 Low byte SFR (TL0, 0x8A), Timer 1 High byte SFR (TH1, 0x8D) and Timer 1 Low byte SFR (TL1, 0x8B) These can be used as independent registers or combined into a single 16-bit register, depending on the timers’ mode configuration – see Table 97 to Table 100. Timer/Counter 0 and 1 Operating Modes FCORE C/T = 0 FCORE TL0 TH0 (8 BITS) (8 BITS) C/T = 0 TL0 TH0 (5 BITS) (8 BITS) INTERRUPT INTERRUPT TF0 C/T = 1 TF0 P0.6/T0 C/T = 1 CONTROL TR0 P0.6/T0 CONTROL TR0 04741-0-050 GATE INT0 04741-0-049 GATE INT0 Figure 69. Timer/Counter 0, Mode 0 In this mode, the timer register is configured as a 13-bit register. Rev. PrD | Page 106 of 140 Figure 70. Timer/Counter 0, Mode 1 Preliminary Technical Data ADE7169F16 Mode 2 (8-Bit Timer/Counter with Autoreload) Mode 2 configures the timer register as an 8-bit counter (TL0) with automatic reload as shown in Figure 71. Overflow from TL0 not only sets TF0, but also reloads TL0 with the contents of TH0, which is preset by software. The reload leaves TH0 unchanged. FCORE C/T = 0 TL0 (8 BITS) INTERRUPT TF0 cycles) and takes over the use of TR1 and TF1 from Timer 1. Therefore, TH0 then controls the Timer 1 interrupt. Mode 3 is provided for applications requiring an extra 8-bit timer or counter. When Timer 0 is in Mode 3, Timer 1 can be turned on and off by switching it out of and into its own Mode 3, or it can still be used by the serial interface as a baud rate generator. In fact, it can be used in any application not requiring an interrupt from Timer 1 itself. CORE CLK/12 FCORE C/T = 1 P0.6/T0 C/T = 0 CONTROL TL0 (8 BITS) TR0 INTERRUPT TF0 C/T = 1 RELOAD TH0 (8 BITS) INT0 CONTROL 04741-0-051 GATE P0.6/T0 Figure 71. Timer/Counter 0, Mode 2 TR0 GATE INT0 Mode 3 (Two 8-Bit Timer/Counters) TIMER 2 Timer/Counter 2 also has two pairs of 8-bit data registers associated with it: Timer 2 High byte SFR (TH2, 0xCD), Timer 2 Low byte SFR (TL2, 0xCC), Timer 2 Reload/capture High byte SFR (RACP2H, 0xCB) and Timer 2 Reload/capture Low byte SFR (RACP2L, 0xCA). These are used as both timer data registers and as timer capture/reload registers – see Table 101 to Table 104. Timer/Counter 2 Operating Modes The following sections describe the operating modes for Timer/Counter 2. The operating modes are selected by bits in the Timer/Counter 2 Control SFR (T2CON, 0xC8) as shown in Table 96 and Table 105. Table 105. T2CON Operating Modes CAP2 0 1 X X TR2 1 1 1 0 INTERRUPT TF1 TR1 Figure 72. Timer/Counter 0, Mode 3 16-Bit Autoreload Mode Timer/Counter 2 Data Registers RCLK (or) TCLK 0 0 1 X TH0 (8 BITS) FCORE/12 04741-0-052 Mode 3 has different effects on Timer 0 and Timer 1. Timer 1 in Mode 3 simply holds its count. The effect is the same as setting TR1 = 0. Timer 0 in Mode 3 establishes TL0 and TH0 as two separate counters. This configuration is shown in Figure 72. TL0 uses the Timer 0 control bits C/T, Gate, TR0, INT0, and TF0. TH0 is locked into a timer function (counting machine Mode 16-Bit Autoreload 16-Bit Capture Baud Rate Off Autoreload mode has two options that are selected by bit EXEN2 in Timer/Counter 2 Control SFR (T2CON, 0xC8). If EXEN2 = 0, when Timer 2 rolls over, it not only sets TF2 but also causes the Timer 2 registers to be reloaded with the 16-bit value in registers Timer 2 Reload/capture High byte SFR (RACP2H, 0xCB) and Timer 2 Reload/capture Low byte SFR (RACP2L, 0xCA), which are preset by software. If EXEN2 = 1, Timer 2 still performs the above, but with the added feature that a 1-to-0 transition at external input T2EX also triggers the 16bit reload and sets EXF2. Autoreload mode is shown in Figure 73. 16-Bit Capture Mode Capture mode has two options that are selected by Bit EXEN2 in T2CON. If EXEN2 = 0, Timer 2 is a 16-bit timer or counter that, upon overflowing, sets bit TF2, the Timer 2 overflow bit, which can be used to generate an interrupt. If EXEN2 = 1, Timer 2 still performs the above, but a l-to-0 transition on external input T2EX causes the current value in the Timer 2 registers, TL2 and TH2, to be captured into registers RCAP2L and RCAP2H, respectively. In addition, the transition at T2EX causes bit EXF2 in T2CON to be set, and EXF2, like TF2, can generate an interrupt. Capture mode is shown in Figure 74. The Rev. PrD | Page 107 of 140 ADE7169F16 Preliminary Technical Data baud rate generator mode is selected by RCLK = 1 and/or TCLK = 1. In either case, if Timer 2 is used to generate the baud rate, the TF2 interrupt flag does not occur. Therefore, Timer 2 interrupts do not occur, so they do not have to be disabled. In this mode, FCORE the EXF2 flag can, however, still cause interrupts, which can be used as a third external interrupt. Baud rate generation is described as part of the UART serial port operation in UART serial interface section. C/ T2 = 0 TL2 (8 BITS) TH2 (8 BITS) RCAP2L RCAP2H C/ T2 = 1 P1.4/T2 CONTROL TR2 RELOAD TRANSITION DETECTOR TF2 TIMER INTERRUPT EXF2 P1.3/T2EX 04741-0-053 CONTROL EXEN2 Figure 73. Timer/Counter 2, 16-Bit Autoreload Mode FCORE C/ T2 = 0 TL2 (8 BITS) TH2 (8 BITS) TF2 C/ T2 = 1 P1.4/T2 CONTROL TR2 TIMER INTERRUPT CAPTURE TRANSITION DETECTOR RCAP2L RCAP2H CONTROL EXEN2 Figure 74. Timer/Counter 2, 16-Bit Capture Mode Rev. PrD | Page 108 of 140 04741-0-054 EXF2 P1.3/T2EX Preliminary Technical Data ADE7169F16 PLL The ADE7169F16 is intended for use with a 32.768 kHz watch crystal. A PLL locks onto a multiple of this frequency to provide a stable 4.096 MHz clock for the system. The core can operate at this frequency or at binary submultiples of it to allow power saving when maximum core performance is not required. The default core clock is the PLL clock divided by 4 or 1.024 MHz. The ADE energy measurement clock is derived from the PLL clock and is maintained at 4.096/5 MHz, 819.2 kHz across all CD settings. The PLL is controlled by the CD[2:0] bits in the Power Control SFR (POWCON, 0xC5). To protect erroneous changes to the Power Control SFR (POWCON, 0xC5), a key is required to modify the register. First the POWCON Key SFR (KYREG, 0xC1) is written with the key, 0xA7, and then a new value is written to the Power Control SFR (POWCON, 0xC5). If the PLL loses lock, the MCU is reset and the PLLFAULT bit is set in the Peripheral Configuration SFR (PERIPH, 0xF4). Set the PLL_FLT_ACK bit in the Start ADC Measurement SFR (ADCGO, 0xD8) to acknowledge the PLL fault, clearing the PLLFAULT flag. PLL SFR REGISTER LIST Power Control SFR (POWCON, 0xC5) Bit Location 7-5 Bit Mnemonic RESERVED Default Value 0 Description 4 COREOFF 0 Set this bit to shut down the core if in the PSM1 operating mode. 3 2-0 RESERVED CD[2:0] 010 Controls the core clock frequency, Fcore. Fcore=4.096MHz/2CD CD[2:0] Fcore (MHz) 0 0 0 4.096 0 0 1 2.048 0 1 0 1.024 0 1 1 0.512 1 0 0 0.256 1 0 1 0.128 1 1 0 0.064 1 1 1 0.032 Table 106. POWCON Key SFR (KYREG, 0xC1) Bit Location 7-0 Bit Mnemonic KYREG Default Value Description 0 Write 0xA7 to the KYREG SFR before writing the POWCON SFR, to unlock it. Peripheral Configuration SFR (PERIPH, 0xF4) Bit Location 7 6 Bit Mnemonic RXFLAG VSWSOURCE Default Value 0 1 5 VDD_OK 0 If set, indicates that a RX Edge event triggered wakeup from PSM2 Indicates the power supply that is connected internally to VSW. 0 VSW=VBAT 1 VSW=VDD If set, indicates that VDD power supply is ok for operation 4 PLL_FLT 0 If set, indicates that PLL is not locked 3 RESERVED 2 EXTREFEN 0 Description Set this bit if an external reference is connected to the REFIN pin. Rev. PrD | Page 109 of 140 ADE7169F16 1-0 RXPROG[1:0] Preliminary Technical Data 00 Controls the function of the P1.0/RX pin. RXPROG [1:0] Function 0 0 GPIO 0 1 RX with wakeup disabled 1 1 RX with wakeup enabled Start ADC Measurement SFR (ADCGO, 0xD8) Bit Location 7 Bit Name PLL_FTL_ACK Default Value Description 0 Reserved 0 2 0xDE – 0xDB 0xDA Set this bit to clear the PLL fault bit, PLL_FLT in the PERIPH register. A PLL fault is generated if a reset was caused because the PLL lost lock. Reserved VSW_ADC_GO 0 1 0xD9 TEMP_ADC_GO 0 0 0xD8 BATT_ADC_GO 0 6-3 Bit Addr. 0xDF Set this bit to initiate a supply voltage measurement. This bit will be cleared when the measurement request is received by the ADC. Set this bit to initiate a temperature measurement. This bit will be cleared when the measurement request is received by the ADC. Set this bit to initiate a battery measurement. This bit will be cleared when the measurement request is received by the ADC. Rev. PrD | Page 110 of 140 Preliminary Technical Data ADE7169F16 RTC - REAL TIME CLOCK The ADE7169F16 has an embedded Real Time Clock (RTC) – see Figure 75. The external 32.768 kHz crystal is used as the clock source for the RTC. Calibration is provided to compensate the nominal crystal frequency and for variations in the external crystal frequency over temperature. By default, the RTC is maintained active in all the Power Saving Modes. The RTC counters retain their values through watchdog resets and external resets and are only reset during a power on reset. 32.768kHz CRYSTAL RTCCOMP TEMPCAL CALIBRATION CALIBRATED RTCEN 32.768kHz ITS1 ITS0 8-BIT PRESCALER HUNDREDTHS COUNTER HTHSEC INTERVAL TIMEBASE SELECTION MUX SECOND COUNTER SEC ITEN MINUTE COUNTER MIN HOUR COUNTER HOUR MIDNIGHT EVENT 8-BIT INTERVAL COUNTER EQUAL? INTVAL SFR Figure 75: RTC implementation RTC SFR REGISTER LIST SFR Address Bit Addressable Description TIMECON 0xA1 No RTC configuration HTHSEC 0xA2 No Hundredth of a second counter SEC 0xA3 No Seconds counter MIN 0xA4 No Minutes counter HOUR 0xA5 No Hours counter INTVAL 0xA6 No Alarm interval RTCCOMP 0xF6 No RTC nominal compensation Rev. PrD | Page 111 of 140 ALARM EVENT ADE7169F16 TEMPCAL 0xF7 Preliminary Technical Data No RTC temperature compensation Table 107. RTC Configuration SFR (TIMECON, 0xA1) Bit Location 7 Bit Mnemonic MIDNIGHT Default Value Description 0 6 TFH 0 5-4 ITS[1:0] 0 3 SIT 0 2 ALARM 0 Midnight Flag This bit is set when the RTC rolls over to 00:00:00:00. It can be cleared by the user to indicate that the midnight event has been serviced. In twentyfour hour mode, the midnight flag is raised once a day at midnight. Twenty-four hour mode 0 256 Hour mode. The HOUR register will roll over from 255 to 0. 1 24 Hour mode. The HOUR register will roll over from 23 to 0. Note: This bit is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Interval Timer Timebase Selection ITS[1:0] Timebase 0 0 1/128 second 0 1 Second 1 0 Minute 1 1 Hour Interval Timer One-Time Alarm 0 The ALARM flag will be set after INTVAL counts and then another interval count will start. 1 The ALARM flag will be set after one time interval. Interval Timer Alarm Flag This bit is set when the configured time interval has elapsed. It can be cleared by the user to indicate that the alarm event has been serviced. 1 ITEN 0 0 RTCEN 1 Interval Timer Enable 0 The interval timer is disabled. The 8-bit interval timer counter is reset. 1 Set this bit to enable the interval timer. The RTCEN bit must also be set to enable the interval timer. RTC Enable. Also Temperature, Battery and Supply ADC Background Strobe Enable 0 The RTC and interval timer are disabled and the RTC registers are cleared. When this bit is clear, the background ADC strobe timer is disabled. 1 The RTC is enabled. The background ADC strobe timer is enabled. Note: This bit is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Table 108. Hundredths of a Second Counter SFR (HTHSEC, 0xA2) Bit Location 7-0 Bit Mnemonic HTHSEC Default Value Description 0 This counter updates every 1/128 second, referenced from the calibrated 32kHz clock. It overflows from 127 to 00, incrementing the seconds counter, SEC. Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Rev. PrD | Page 112 of 140 Preliminary Technical Data ADE7169F16 Table 109. Seconds Counter SFR (SEC, 0xA3) Bit Location 7-0 Bit Mnemonic SEC Default Value Description 0 This counter updates every second, referenced from the calibrated 32kHz clock. It overflows from 59 to 00, incrementing the minutes counter, MIN. Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Table 110. Minutes Counter SFR (MIN, 0xA4) Bit Location 7-0 Bit Mnemonic MIN Default Value Description 0 This counter updates every minute, referenced from the calibrated 32kHz clock. It overflows from 59 to 00, incrementing the hours counter, HOUR. Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Table 111. Hours Counter SFR (HOUR, 0xA5) Bit Location 7-0 Bit Mnemonic HOUR Default Value Description 0 This counter updates every hour, referenced from the calibrated 32kHz clock. If the TFH bit in the RTC Configuration SFR (TIMECON, 0xA1) is set, the HOUR SFR overflows from 23 to 00, setting the MIDNIGHT bit and creating a pending RTC interrupt. If the TFH bit in the RTC Configuration SFR (TIMECON, 0xA1) is clear, the HOUR SFR overflows from 255 to 00, setting the MIDNIGHT bit and creating a pending RTC interrupt. Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Table 112. Alarm Interval SFR (INTVAL, 0xA6) Bit Location 7-0 Bit Mnemonic INTVAL Default Value Description 0 The interval timer counts according to the timebase established in the ITS[1:0] bits of the RTC Configuration SFR (TIMECON, 0xA1). Once the number of counts is equal to INTVAL, the ALARM flag is set and a pending RTC interrupt is created. Note that the interval counter is 8-bits so it could count up to 255 seconds, for example. Table 113. RTC Nominal Compensation SFR (RTCCOMP, 0xF6) Bit Location 7-0 Bit Mnemonic RTCCOMP Default Value Description 0 The RTCCOMP SFR holds the nominal RTC compensation value at 25°C. Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). Table 114. RTC Temperature Compensation SFR (TEMPCAL, 0xF7) Bit Location 7-0 Bit Mnemonic TEMPCAL Default Value Description 0 The TEMPCAL SFR is adjusted based on the temerature read in the TEMPADC to calibrate the RTC over temperature. This allows the external crystal shift to be compensated over temperature. Rev. PrD | Page 113 of 140 ADE7169F16 Preliminary Technical Data Note: This register is retained during a watchdog reset or an external reset. It is reset after a power on reset (POR). READ AND WRITE OPERATIONS Writing the RTC Registers The RTC circuitry runs off a 32.768 kHz clock. It takes up to two 32 kHz clock cycles from when the MCU writes an RTC register until it is successfully updated in the RTC. Interval Timer Alarm Reading the RTC Counter SFRs The RTC cannot be stopped to read the current time because stopping the RTC would introduce an error in its timekeeping. So the RTC is read on the fly. Therefore the counter registers must be checked for overflow. This can be accomplished through the following 8052 assembly code: ReadAgain: MOV MOV MOV MOV MOV CJNE R0, HTHSEC R1, SEC R2, MIN R3, HOUR A, HTHSEC A, 00h, ReadAgain The MIDNIGHT and ALARM flags are set when the midnight and alarm events occur, respectively. The user should manage these flags to keep track of which event caused an RTC interrupt by servicing the event and clearing the appropriate flag in the RTC ISR. ; using Bank 0 ; 00h is R0 in Bank 0 The RTC can be used as an interval timer. When the interval timer is enabled by setting the ITEN bit in the RTC Configuration SFR (TIMECON, 0xA1), the interval timer clock source selected by the ITS1 and ITS0 bits is passed through to an 8-bit counter. This counter increments on every interval timer clock pulse until the 8-bit counter is equal to the value in the Alarm Interval SFR (INTVAL, 0xA6). Then an alarm event is generated, setting the ALARM flag and creating a pending RTC interrupt. If the SIT bit in the RTC Configuration SFR (TIMECON, 0xA1) is clear then the 8-bit counter is cleared and starts counting again. If the SIT bit is set then the 8-bit counter is held in reset after the alarm occurs. The RTC alarm event will wake the 8052 MCU core if the MCU is in PSM2 when the alarm event occurs. RTC MODES The RTC can be configured in a 24 hour mode or a 256 hour mode. A midnight event is generated when the RTC hour counter rolls over from 23 to 0 or 255 to 0, depending on whether the TFH bit is set in the RTC Configuration SFR (TIMECON, 0xA1). The midnight event sets the MIDNIGHT flag in the RTC Configuration SFR (TIMECON, 0xA1) and a pending RTC interrupt is created. The RTC midnight event will wake the 8052 MCU core if the MCU is asleep in PSM2 when the midnight event occurs. In the 24 hour mode, the midnight event is generated once a day, at midnight. The 24 hour mode is useful for updating a software calendar to keep track of the current day. The 256 hour mode will result in power savings during extended operation in PSM2 because the MCU core will be wpken less frequently. RTC INTERRUPTS The RTC Midnight and Alarm Interrupts are enabled by setting the ETI bit in the Interrupt Enable and Priority 2 SFR (IEIP2, 0xA9). When a midnight or alarm event occurs, a pending RTC interrupt is generated. If the RTC interrupt is enabled, the program will vector to the RTC interrupt address and the pending interrupt will be cleared. If the RTC interrupt is disabled, then the RTC interrupt will remain pending until the RTC interrupt is enabled. Then the program will vector to the RTC interrupt address. RTC CALIBRATION The RTC provides registers to calibrate the nominal external crystal frequency and its variation over temperature. Up to ±248ppm frequency error can be calibrated out by the RTC circuitry, which adds or subtracts pulses from the external crystal signal. The nominal crystal frequency should be calibrated with the RTCCOMP register so that the clock going into the RTC is precisely 32.768 kHz at 25°C. The RTC Temperature Compensation SFR (TEMPCAL, 0xF7) is used to compensate for the external crystal drift over temperature by adding or subtracting additional pulses based on temperature. The LSB of each RTC compensation register represents a ±2ppm frequency error. The RTC compensation circuitry adds the RTC Temperature Compensation SFR (TEMPCAL, 0xF7) and the RTC Nominal Compensation SFR (RTCCOMP, 0xF6) to determine how much compensation is required and the sum of these two registers is limited to ±248ppm. Calibration Flow: TBD During calibration, user software writes the RTC with the current time. The RTC should be stopped to perform this setup. The user should wait at least one 32 kHz clock period after clearing the RTCEN bit in the RTC Configuration SFR Rev. PrD | Page 114 of 140 Preliminary Technical Data ADE7169F16 (TIMECON, 0xA1) to ensure that the RTC is stopped before writing the counter registers. Then the RTC should be started again by setting the RTCEN bit. Note that it takes up to two 32 kHz clock periods to update the RTC counter SFRs. This can be accomplished using the following 8052 assembly code where the current time is held in R0 through R3. SetupRTC: MOV TIMECON,#040h ; stop the RTC ; wait at least one 32 kHz clock period (30.5us) MOV TCON, #03h ; TL0 is an 8-bit timer MOV TL0,#00h ; waits 62.5us at 4.096MHz CLR TF0 ; clear overflow flag SETB TR0 ; start Timer0 Timeout: JNZ TF0, Timeout MOV HTHSEC, R0 ; using Bank 0 MOV SEC, R1 MOV MIN, R2 MOV HOUR, R3 MOV TIMECON, #041h ; start the RTC Rev. PrD | Page 115 of 140 ADE7169F16 Preliminary Technical Data the second byte is complete. The physical interface to the UART is provided via the RxD (P1.0) and TxD (P1.1) pins, while the firmware interface is through the SFRs presented in Table 115. UART SERIAL INTERFACE The ADE7169F16 UART can be configured in one of four modes: Both the serial port receive and transmit registers are accessed through the SBUF SFR (SFR address = 0x99). Writing to SBUF loads the transmit register, and reading SBUF accesses a physically separate receive register. - Shift register with baud rate fixed at Fcore/12 - 8-bit UART with variable baud rate - 9- bit UART with baud rate fixed at Fcore/64 or Fcore/32 - 9 bit UART with variable baud rate Variable baud rates are defined by using an internal timer to generate any rate between 300 and 115200 bauds/s. The UART serial interface provided in the ADE7169F16 is a full-duplex serial interface. It is also receive buffered, by storing the first received byte in a receive buffer until the reception of An enhanced UART mode is offered by using UART Timer and providing enhanced frame error, break error and overwrite error detection. This mode is enabled by setting the EXTEN bit in the CFG SFR—see the UART additional features section. The SBAUDT and SBAUDF SFR are used to configure UART Timer and to indicate the enhanced UART errors. UART SFR REGISTER LIST Table 115. Serial port SFRs SFR Address Bit Addressable Description SCON 0x98 Yes Serial Communications Control register – see Table 116 SBUF 0x99 No Serial Port Buffer – see Table 117 SBAUDT 0x9E No Enhanced error checking – see Table 118 SBAUDF 0x9D No Enhanced Fractional Divider – see Table 119 Table 116. SCON SFR Bit Description SFR (SCON, 0x98) Bit Location Bit Addr. Bit Name Default Value Description 7-6 0x9F, 0x9E SM0, SM1 00 UART Serial Mode Select Bits. These bits select the serial port operating mode as follows: 5 0x9D SM2 0 SM0 SM1 Selected Operating Mode. 0 0 Mode 0: Shift register, fixed baud rate (Fcore/12). 0 1 Mode 1: 8-bit UART, variable baud rate. 1 0 Mode 2: 9-bit UART, fixed baud rate (Fcore/32) or (Fcore/16). 1 1 Mode 3: 9-bit UART, variable baud rate. Multiprocessor Communication Enable Bit. Enables multiprocessor communication in Modes 2 and 3 and framing error detection in Mode 1. In Mode 0, SM2 should be cleared. In Mode 1, if SM2 is set, RI is not activated if a valid stop bit was not received. If SM2 is cleared, RI is set as soon as the byte of data is received. Rev. PrD | Page 116 of 140 Preliminary Technical Data ADE7169F16 In Modes 2 or 3, if SM2 is set, RI is not activated if the received ninth data bit in RB8 is 0. If SM2 is cleared, RI is set as soon as the byte of data is received. 4 0x9C REN 0 Serial Port Receive Enable Bit. Set by user software to enable serial port reception. Cleared by user software to disable serial port reception. 3 0x9B TB8 0 Serial Port Transmit (Bit 9). The data loaded into TB8 is the ninth data bit transmitted in Modes 2 and 3. 2 0x9A RB8 0 Serial Port Receiver Bit 9. The ninth data bit received in Modes 2 and 3 is latched into RB8. For Mode 1, the stop bit is latched into RB8. 1 0x99 TI 0 Serial Port Transmit Interrupt Flag. Set by hardware at the end of the eighth bit in Mode 0, or at the beginning of the stop bit in Modes 1, 2, and 3. TI must be cleared by user software. 0 0x98 RI 0 Serial Port Receive Interrupt Flag. Set by hardware at the end of the eighth bit in Mode 0, or halfway through the stop bit in Modes 1, 2, and 3. RI must be cleared by user software. Table 117. Serial port Buffer SFR (SBUF, 0x99) Bit Location 7-0 Bit Mnemonic SBUF Default Value 0 Description Serial port data buffer Table 118. Enhanced Serial baud rate control SFR (SBAUDT, 0x9E) Bit Location 7 Bit Mnemonic OWE Default Value 0 6 FE 0 5 BE 0 4-3 2, 1, 0 SBTH1, SBTH0 DIV2, DIV1, DIV0 0 0 Description Overwrite Error. This bit is set when new data is received and RI=1. It indicates that SBUF was not read before the next character was transferred in, causing the prior SBUF data to be lost. Frame Error. This bit is set when the received frame did not have a valid stop bit. This bit is read only and updated every time a frame is received. Break Error. This bit is set whenever the receive data line (Rx) is low for longer than a full transmission frame, the time required for a start bit, 8 data bits, a parity bit and half a stop bit. This bit is updated every time a frame is received. Extended divider ratio for baud rate setting as shown in Table 120 Binary Divider DIV2 0 0 0 0 1 1 1 1 DIV1 0 0 1 1 0 0 1 1 DIV0 0 1 0 1 0 1 0 1 Divide by 1. See Table 120. Divide by 2. See Table 120. Divide by 4. See Table 120. Divide by 8. See Table 120. Divide by 16. See Table 120. Divide by 32. See Table 120. Divide by 64. See Table 120. Divide by 128. See Table 120. Rev. PrD | Page 117 of 140 ADE7169F16 Preliminary Technical Data Table 119. UART Timer Fractional Divider SFR (SBAUDF, 0x9D) Bit Location 7 Bit Mnemonic UARTBAUDEN Default value 0 6 5 4 3 2 1 0 ---SBAUDF.5 SBAUDF.4 SBAUDF.3 SBAUDF.2 SBAUDF.1 SBAUDF.0 0 0 0 0 0 0 Description UART Baud Rate Enable Set to enable UART Timer to generate the baud rate. When set, PCON.7, T2CON.4, and T2CON.5 are ignored. Cleared to let the baud rate be generated as per a standard 8052. Not Implemented. Write Don’t Care. UART Timer Fractional Divider Bit 5. UART Timer Fractional Divider Bit 4. UART Timer Fractional Divider Bit 3. UART Timer Fractional Divider Bit 2. UART Timer Fractional Divider Bit 1. UART Timer Fractional Divider Bit 0. Table 120. Common Baud Rates Using UART Timer with a 4.096 MHz FLL Clock Ideal Baud 115200 115200 CD 0 1 SBTH 0 0 DIV 1 0 SBAUDT 01H 00H SBAUDF 87H 87H % Error + 0.16 + 0.16 57600 57600 0 1 0 0 2 1 02H 01H 87H 87H + 0.16 + 0.16 38400 38400 38400 0 1 2 0 0 0 2 1 0 02H 01H 00H ABH ABH ABH - 0.31 - 0.31 - 0.31 19200 19200 19200 19200 0 1 2 3 0 0 0 0 3 2 1 0 03H 02H 01H 00H ABH ABH ABH ABH - 0.31 - 0.31 - 0.31 - 0.31 9600 9600 9600 9600 9600 0 1 2 3 4 0 0 0 0 0 4 3 2 1 0 04H 03H 02H 01H 00H ABH ABH ABH ABH ABH - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 4800 4800 4800 4800 4800 4800 0 1 2 3 4 5 0 0 0 0 0 0 5 4 3 2 1 0 05H 04H 03H 02H 01H 00H ABH ABH ABH ABH ABH ABH - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 2400 2400 2400 2400 2400 2400 2400 0 1 2 3 4 5 6 0 0 0 0 0 0 0 6 5 4 3 2 1 0 06H 05H 04H 03H 02H 01H 00H ABH ABH ABH ABH ABH ABH ABH - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 Rev. PrD | Page 118 of 140 Preliminary Technical Data 300 300 300 300 300 300 300 300 0 1 2 3 4 5 6 7 ADE7169F16 2 1 0 0 0 0 0 0 7 7 7 6 5 4 3 2 17H 0FH 07H 06H 05H 04H 03H 02H ABH ABH ABH ABH ABH ABH ABH ABH - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 - 0.31 UART OPERATION MODES Mode 0 (Shift Register with baud rate fixed at Fcore /12) Figure 77. 8-Bit Variable Baud Rate Mode 0 is selected when the SM0 and SM1 bits in the SCON SFR are clear. In this shift register mode, serial data enters and exits through RxD. TxD outputs the shift clock. The baud rate is fixed at Fcore/12. Eight data bits are transmitted or received. Transmission is initiated by any instruction that writes to SBUF. The data is shifted out of the RxD line. The 8 bits are transmitted with the least significant bit (LSB) first. Reception is initiated when the receive enable bit (REN) is 1 and the receive interrupt bit (RI) is 0. When RI is cleared, the data is clocked into the RxD line, and the clock pulses are output from the TxD line as shown in Figure 76. DATA BIT 0 DATA BIT 1 DATA BIT 6 All of the following conditions must be met at the time the final shift pulse is generated to receive a character: • If the extended UART is disabled (EXTEN=0 in the CFG SFR), RI must be zero to receive a character. This ensures that the data in SBUF will not be overwritten if the last received character has not been read. • If frame error checking is enabled by setting SM2, the received stop bit must be set to receive a character. This ensures that every character received comes from a valid frame, with both a start and a stop bit) DATA BIT 7 04741-0-055 RxD (DATA OUT) Reception is initiated when a 1-to-0 transition is detected on RxD. Assuming that a valid start bit is detected, character reception continues. The 8 data bits are clocked into the serial port shift register. TxD (SHIFT CLOCK) Figure 76. 8-Bit Shift Register Mode Mode 1 (8-Bit UART, Variable Baud Rate) If any of these conditions are not met, the received frame is irretrievably lost, and the receive interrupt flag, RI, is not set. Mode 1 is selected by clearing SM0 and setting SM1. Each data byte (LSB first) is preceded by a start bit (0) and followed by a stop bit (1). Therefore, each frame consists of 10 bits transmitted on TxD or received on RxD. If the received frame has met the above criteria, the following events occur: The baud rate is set by a timer overflow rate. Timer 1 or Timer 2 can be used to generate baud rates or both timers can be used simultaneously where one generates the transmit rate and the other generates the receive rate. There is also a dedicated timer for baud rate generation, UART Timer, which has a fractional divisor to precisely generate any baud rate—see the UART Timer Generated Baud Rates section. Transmission is initiated by a write to SBUF. Next a stop bit (a 1) is loaded into the 9th bit position of the transmit shift register. The data is output bit-by-bit until the stop bit appears on TxD and the transmit interrupt flag (TI) is automatically set as shown in Figure 77. TxD STOP BIT D0 D1 D2 D3 D4 D5 D6 D7 TI (SCON.1) SET INTERRUPT I.E., READY FOR MORE DATA 04741-0-056 START BIT • The 8 bits in the receive shift register are latched into SBUF. • The 9th bit (stop bit) is clocked into RB8 in SCON. • The receiver interrupt flag (RI) is set. Mode 2 (9- bit UART with baud fixed at Fcore/64 or Fcore/32) Mode 2 is selected by setting SM0 and clearing SM1. In this mode, the UART operates in 9-bit mode with a fixed baud rate. The baud rate is fixed at Fcore/64 by default, although by setting the SMOD bit in PCON, the frequency can be doubled to Fcore/32. Eleven bits are transmitted or received: a start bit (0), 8 data bits, a programmable 9th bit, and a stop bit (1). The 9th bit is most often used as a parity bit or as part of a multiprocessor communication protocol, although it can be used for anything, including a ninth data bit if required. To use the 9th data bit as part of a communication protocol for a Rev. PrD | Page 119 of 140 ADE7169F16 Preliminary Technical Data multiprocessor network such as RS-485, the 9th bit is set to indicate that the frame contains the address of the device that the master would like to communicate with. The devices on the network are always listening for a packet with the 9th bit set and are configured such that if the 9th bit is clear, the frame will not be valid and a receive interrupt will not be generated. If the 9th bit is set, all of the devices on the network will receive the address and get a receive character interrupt. The devices will examine the address and if it matches a device’s preprogrammed address, the device will configure itself to listen to all incoming frames, even those with the 9th bit clear. Since the master has initiated communication with that device, all the following packets with the 9th bit clear are intended specifically for the addressed device until another packet with the 9th bit set is received. If the address does not match, the device will continue listening for address packets. To transmit, the 8 data bits must be written into SBUF. The ninth bit must be written to TB8 in SCON. When transmission is initiated, the 8 data bits from SBUF are loaded into the transmit shift register (LSB first). The 9th data bit, held in TB8, is loaded into the 9th bit position of the transmit shift register. The transmission starts at the next valid baud rate clock. The transmit interrupt flag, TI, is set as soon as the transmission has completed, when the stop bit appears on TxD. All of the following conditions must be met at the time the final shift pulse is generated to receive a character: • • If the extended UART is disabled (EXTEN=0 in the CFG SFR), RI must be zero to receive a character. This ensures that the data in SBUF will not be overwritten if the last received character has not been read. If multiprocessor communication is enabled by setting SM2, the received 9th bit must be set to receive a character. This ensures that only frames with the 9th bit set, frames that contain addresses, generate a receive interrupt. If any of these conditions are not met, the received frame is irretrievably lost, and the receive interrupt flag, RI, is not set. Reception for Mode 2 is similar to that of Mode 1. The 8 data bytes are input at RxD (LSB first) and loaded onto the receive shift register. If the received frame has met the above criteria, the following events occur: • The 8 bits in the receive shift register are latched into SBUF. • The 9th data bit is latched into RB8 in SCON. • or Timer 2 can be used to generate baud rates or both timers can be used simultaneously where one generates the transmit rate and the other generates the receive rate. There is also a dedicated timer for baud rate generation, UART Timer, which has a fractional divisor to precisely generate any baud rate—see the UART Timer Generated Baud Rates section. The operation of the 9-bit UART is the same as for Mode 2, but the baud rate can be varied. In all four modes, transmission is initiated by any instruction that uses SBUF as a destination register. Reception is initiated in Mode 0 when RI = 0 and REN = 1. Reception is initiated in the other modes by the incoming start bit if REN = 1. UART BAUD RATE GENERATION Mode 0 Baud Rate Generation The baud rate in Mode 0 is fixed: ⎛ Fcore ⎞ ⎟ ⎝ 12 ⎠ Mode 2 Baud Rate Generation Mode 0 Baud Rate = ⎜ The baud rate in Mode 2 depends on the value of the SMOD bit in the PCON SFR. If SMOD = 0, the baud rate is 1/32 of the core clock. If SMOD = 1, the baud rate is 1/16 of the core clock: Mode 2 Baud Rate = 2 SMOD × Fcore 32 Modes 1 and 3 Baud Rate Generation The baud rates in Modes 1 and 3 are determined by the overflow rate of the timer generating the baud rate: either Timer 1 or Timer 2 or the dedicated baud rate generator, UART Timer, which has an integer and fractional divisor. Timer 1 Generated Baud Rates When Timer 1 is used as the baud rate generator, the baud rates in Modes 1 and 3 are determined by the Timer 1 overflow rate and the value of SMOD as follows: Modes 1 and 3 Baud Rate = 2 SMOD × Timer 1 Overflow Rate 32 The Timer 1 interrupt should be disabled in this application. The timer itself can be configured for either timer or counter operation, and in any of its three running modes. In the most typical application, it is configured for timer operation in autoreload mode (high nibble of TMOD = 0010 binary). In that case, the baud rate is given by the formula SMOD Modes 1 and 3 Baud Rate = 2 × 32 The receiver interrupt flag (RI) is set. Mode 3 (9-Bit UART with Variable Baud Rate) Mode 3 is selected by setting both SM0 and SM1. In this mode, the 8051 UART serial port operates in 9-bit mode with a variable baud rate. The baud rate is set by a timer overflow rate. Timer 1 Fcore (256 − TH 1) Timer 2 Generated Baud Rates Baud rates can also be generated by using Timer 2. Using Timer 2 is similar to using Timer 1 in that the timer must overflow 16 times before a bit is transmitted or received. Because Timer 2 has a 16-bit autoreload mode, a wider range of baud rates is Rev. PrD | Page 120 of 140 Preliminary Technical Data ADE7169F16 possible. Modes 1 and 3 Baud Rate = and receive can be simultaneously different. Setting RCLK and/or TCLK puts Timer 2 into its baud rate generator mode as shown in Figure 78. 1 × Timer 2 Overflow Rate 16 In this case, the baud rate is given by the formula Therefore, when Timer 2 is used to generate baud rates, the timer increments every two clock cycles rather than every core machine cycle as before. It increments six times faster than Timer 1, and, therefore, baud rates six times faster are possible. Because Timer 2 has 16-bit autoreload capability, very low baud rates are still possible. Modes 1 and 3 Baud Rate = Fcore (16 × [65536 − (RCAP2 H : RCAP2 L )]) Timer 2 is selected as the baud rate generator by setting the TCLK and/or RCLK in T2CON. The baud rates for transmit TIMER 1 OVERFLOW 2 0 FCORE SMOD C/ T2 = 0 TL2 (8 BITS) T2 PIN 1 CONTROL TH2 (8 BITS) TIMER 2 OVERFLOW 1 0 RCLK C/ T2 = 1 1 0 TR2 TCLK NOTE: AVAILABILITY OF ADDITIONAL EXTERNAL INTERRUPT RELOAD TX CLOCK 16 RCAP2L T2EX PIN EXF 2 RCAP2H TIMER 2 INTERRUPT CONTROL 04741-0-057 TRANSITION DETECTOR RX CLOCK 16 EXEN2 Figure 78. Timer 2, UART Baud Rates UART Timer Generated Baud Rates FCORE The high integer dividers in a UART block mean that high speed baud rates are not always possible. Also, generating baud rates requires the exclusive use of a timer, rendering it unusable for other applications when the UART is required. To address this problem, the ADE7169F16 has a dedicated baud rate timer (UART Timer) specifically for generating highly accurate baud rates. UART Timer can be used instead of Timer 1 or Timer 2 for generating very accurate high speed UART baud rates including 115200. UART Timer also allows a much wider range of baud rates to be obtained. In fact, every desired bit rate from 12 bps to 393216 bps can be generated to within an error of ±0.8%. UART Timer also frees up the other three timers, allowing them to be used for different applications. A block diagram of UART Timer is shown in Figure 79. TIMER 1/TIMER 2 Tx CLOCK FRACTIONAL DIVIDER ⎟ (1 + SBAUDF/64) TIMER 1/TIMER 2 Rx CLOCK 1 0 1 0 ⎟ 2 D IV+SBTH Rx CLOCK ⎟ 32 UART Timer Rx/Tx CLOCK UARTBAUDEN Tx CLOCK Figure 79. UART Timer, UART Baud Rate Two SFRs Enhanced Serial baud rate control SFR (SBAUDT, 0x9E) and UART Timer Fractional Divider SFR (SBAUDF, 0x9D) are used to control UART Timer. SBAUDT is the baud rate control SFR; it sets up the integer divider (DIV) and the extended divider (SBTH) for UART Timer. Rev. PrD | Page 121 of 140 ADE7169F16 Preliminary Technical Data The appropriate value to write to the DIV[2:0] and SBTH[1:0] bits can be calculated using the following formula where Fcore is defined in POWCON SFR. Note that the DIV value must be rounded down to the nearest integer. DIV+ SBTH = ⎛ ⎞ Fcore ⎟⎟ log⎜⎜ ⎝ 16 × Baud Rate ⎠ log(2) bit UART through the SM2 and RB8 bits. Setting the SM2 bit prevent frames without a stop bit from being received. The stop bit is latched into the RB8 bit in the SCON register. This bit can be examined to determine if a valid frame was received. The 8052 does not however, provide frame error checking for a 9-bit UART. This enhanced error checking functionality is available through the frame error bit, FE in the SBAUDT SFR. The FE bit will be set on framing errors for both 8-bit and 9-bit UARTs. RX START D0 SBAUDF is the fractional divider ratio required to achieve the required baud rate. The appropriate value for SBAUDF can be calculated with the following formula: D1 D2 D3 D4 D5 D6 D7 STOP D8 STOP RI FE EXTEN=1 SBAUDF = Figure 80: UART Timing in Mode 1 ⎛ ⎞ Fcore 64 ∗ ⎜⎜ − 1⎟⎟ DIV + SBTH × Baud Rate ⎝ 16 ⋅ 2 ⎠ RX START D0 D1 D2 D3 D4 D5 D6 D7 RI Note that SBAUDF should be rounded to the nearest integer. Once the values for DIV and SBAUDF are calculated, the actual baud rate can be calculated with the following formula: Actual Baud Rate = Fcore ⎛ SBAUDF ⎞ 16 ⋅ 2 DIV + SBTH ⋅ ⎜1 + ⎟ 64 ⎝ ⎠ For example, to get a baud rate of 9600 while operating at a core clock frequency of 4.096 MHz, with the PLL CD bits equal to zero, DIV + SBTH = log(4096000/(16 × 9600))/log2 = 4.74 = 4 Note that the DIV result is rounded down. SBAUDF = 64*(4096000/(16*23*9600)-1) = 42.67 = 2BH Therefore, the actual baud rate is 9570 bps, which gives an error of 0.31%. UART ADDITIONAL FEATURES Enhanced Error Checking The extended UART provides frame error, break error and overwrite error detection. Framing errors occur when a stop bit is not present at the end of the frame. A missing stop bit implies that the data in the frame may not have been received properly. Break error detection indicates if the Rx line has been low for longer than a 9-bit frame. It indicates that the data just received, a zero, or NUL character, is not valid because the master has disconnected. Overwrite error detection indicates if the received data isn’t read fast enough and as result, a byte of data has been lost. The 8052 standard UART offers frame error checking for an 8- FE EXTEN=1 Figure 81: UART Timing in Modes 2 and 3 The 8052 standard UART does not provide break error detection. However for an 8-bit UART, it can be determined that a break error occurred if the received character is zero, a NUL character, and there was no stop bit because the RB8 bit is low. Break error detection is not possible for a 9-bit 8052 UART because the stop bit is not recorded. The ADE7169F16 enhanced break error detection is available through the BE bit in the SBAUDT SFR. The 8052 standard UART prevents overwrite errors by not allowing a character to be received if the RI, receive interrupt flag, is set. However, it does not indicate if a character has been lost because the RI bit was set when the frame was received. The enhanced UART overwrite error detection provides this information. When the enhanced 8052 UART is enabled, a frame will be received regardless of the state of the RI flag. If RI=1 when a new byte is received, the byte in SCON is overwritten, and the overwrite error flag will be set. The overwrite error flag will be cleared when SBUF is read. The extended UART is enabled by setting the EXTEN bit in the CFG SFR. UART TxD signal modulation There is an internal 38 kHz signal which can be ORed with the UART transmit signal for use in remote control applications— see the 38 kHz Modulation section. One of the events that can wake the MCU from sleep mode is activity on the UART RX pin—see the 3.3V Peripherals and Wakeup Events section. Rev. PrD | Page 122 of 140 Preliminary Technical Data ADE7169F16 The SPI port can be configured for Master or Slave operation. The physical interface to the SPI is done via MISO (P0.3), MOSI (P0.2), SCLK (P0.4) and SS (P0.5) pins, while the firmware interface is done via the SPI Configuration Register SFR (SPIMOD1, 0xE8), SPI Configuration Register SFR (SPIMOD2, 0xE9), SPI Interrupt Status Register SFR (SPISTAT, 0xEA), SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A) and SPI Receive Buffer SFR (SPI2CRx, 0x9B). Note that the SPI pins are shared with the I2C pins. Therefore, the user can enable only one interface at a time. The SCPS bit in the CFG SFR selects which peripheral is active. SERIAL PERIPHERAL INTERFACE INTERFACE (SPI) The ADE7169F16 integrates a complete hardware serial peripheral interface on-chip. The SPI interface is full duplex so that eight bits of data are synchronously transmitted and received simultaneously. This SPI implementation is double buffered. This allows the user to read the last byte of received data while a new byte is shifted in. The next byte to be transmitted can be loaded while the current byte is shifted out. SPI SFR REGISTER LIST SFR Address Name R/W Length 0x9A 0x9B 0xE8 0xE9 0xEA SPI2CTx SPI2CRx SPIMOD1 SPIMOD2 SPI2CSTAT W R R/W R/W R/W 8 8 8 8 8 Default Value Description SPI Data out register SPI Data in register SPI configuration register SPI configuration register SPI/I2C Interrupt Status register 0 0x10 0 0 Table 121: SPI SFR register list Table 122. SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A) Bit Location 7-0 Bit Mnemonic SPI2CTx Default Value Description 0 SPI or I2C transmit buffer When SPI2CTx SFR is written, its content is transfered to the transmit FIFO input. When a write is requested, the FIFO output is sent on the SPI or I2C bus. Table 123. SPI Receive Buffer SFR (SPI2CRx, 0x9B) Bit Location 7-0 Bit Mnemonic SPI2CRx Default Value Description 0 SPI or I2C receive buffer When SPI2CRx SFR is read, one byte from the Receive FIFO output is transfered to SPI2CRx SFR. A new data from the SPI or I2C bus is written to the FIFO input. Table 124. SPI Configuration Register SFR (SPIMOD1, 0xE8) Bit Location 7-5 Bit Addr. 5 0xEF – 0xEE 0xED 4 0xEC Bit Name Reserved Default Value Description 0 Reserved INTMOD 0 AUTO_SS 1 SPI Interrupt mode 0: SPI Interrupt set when SPI Rx buffer full 1: SPI interrupt set when SPI Tx buffer empty Master Mode: SS output control. See Figure 82. 0 The SS is held low while this bit is clear. This allows manual chip select control using the SS pin. 1 Single Byte Read or Write: The SS will go low during a single byte transmission and then return high. Continuous Transfer: The SS will go low during the duration of the multibyte continuous transfer and then return high. 3 0xEB SSE 0 Slave Mode: SS input enable Rev. PrD | Page 123 of 140 ADE7169F16 Preliminary Technical Data 2 0xEA RxOFW 0 1-0 0xE9 – 0xE8 SPIR[1:0] 0 When this bit is set to logic one, the SS pin is defined as the Slave Select input pin for the SPI slave interface Receive buffer overflow write enable 0 If the SPIRX SFR has not been read when a new data byte is received, the new byte will be discarded. 1 If the SPIRX SFR has not been read when a new data byte is received, the new byte will overwrite the old data. Master Mode: SPI SCLK frequency [1:0] 00 Fcore / 8 = 512kHz if Fcore = 4.096MHz 01 Fcore / 16 = 256kHz if Fcore = 4.096MHz 10 Fcore / 32 = 128kHz if Fcore = 4.096MHz 11 Fcore / 64 = 64kHz if Fcore = 4.096MHz Table 125. SPI Configuration Register SFR (SPIMOD2, 0xE9) Bit Location 7 Bit Mnemonic SPICONT Default Value Description 0 Master Mode: SPI continuous transfer mode enable bit 0 6 SPIEN 0 5 SPIODO 0 The SPI interface will stop after one byte is transferred and SS will be deasserted. A new data transfer can be intiated after a stalled period. 1 The SPI interface will continue transferring data until no valid data is availbale in the SPITx SFR. SS will remain asserted until SPITx SFR and the transmit shift register is empty. SPI interface enable bit 0 The SPI interface is disabled. 1 The SPI interface is enabled SPI Open Drain Outputs configuration bit 0 Internal pull-up resistors are connected to the SPI outputs 1 4 3 SPIMS_b SPICPOL 0 0 The SPI outputs are open-drain and need external pull-up resistors SPI Master Mode enable bit 0 The SPI interface is defined as a Slave 1 The SPI interface is defined as a Master SPI clock polarity configuration bit – see Figure 84. 0 2 SPICPHA 0 1 SPILSBF 0 The default state of SCLK is low and the first SCLK edge is rising. Depending on SPICPHA bit, the SPI data output changes state on the falling or rising edge of SCLK while the SPI data input is sampled on the rising or falling edge of SCLK. 1 The default state of SCLK is high and the first SCLK edge is falling. Depending on SPICPHA bit, the SPI data output changes state on the rising or falling edge of SCLK while the SPI data input is sampled on the falling or rising edge of SCLK. SPI clock phase configuration bit – see Figure 84. 0 The SPI data output changes state when SS goes low, at the second edge of SCLK and then every two subsequent edges while the SPI data input is sampled at the first SCLK edge and then every two subsequent edges. 1 The SPI data output changes state at the first edge of SCLK and then every two subsequent edges while the SPI data input is sampled at the second SCLK edge and then every two subsequent edges. Master Mode: LSB first configuration bit Rev. PrD | Page 124 of 140 Preliminary Technical Data 0 TIMODE ADE7169F16 0 0 The MSB of the SPI outputs is transmitted first 1 The LSB of the SPI outputs is transmitted first Transfer and interrupt mode of the SPI interface. 0 Transfer is initiated when data is read from SPIRx SFR and an interrupt is generated when there is new data in the SPIRx SFR. 1 Transfer is initiated when data is written to the SPITx SFR and an interrupt is generated when the SPITx SFR is empty. Table 126. SPI Interrupt Status Register SFR (SPISTAT, 0xEA) Bit Location 7 Interrupt Flag Default Value BUSY 0 6 MMERR 0 5 SPIRxOF 0 Description SPI Peripheral Busy Flag 0 The SPI peripheral is idle 1 The SPI peripheral is busy transferring data in slave or master mode. SPI Multi-Master Error Flag 0 A multiple master error has not occurred. 1 If the SS_EN bit is set, enabling the Slave Select input and the SS is asserted while the SPI peripheral is transferring data as a master, then this flag is raised to indicate the error. SPI Receive Overflow Error Flag. Reading the SPIRx SFR will clear this bit. SPIR TIMODE xOF 0 X The SPIRX register contains valid data 1 4 SPIRxIRQ 0 3 SPIRxBF 0 2 SPITxUF 0 1 SPITxIRQ 0 1 This bit is set if the SPIRX register is not read before the end of the next byte transfer. If the RxOF_EN bit is set and this condition occurs, SPIRX will be overwritten. SPI Receive Mode Interrupt Flag. Reading the SPIRx SFR will clear this bit. SPIRxI TIMODE RQ 0 X The SPIRX register does not contain new data. 1 0 This bit is set when the SPIRX register contains new data. If the SPI/I2C interrupt is enabled, an interrupt will be generated when this bit is set. If the SPIRX register isn’t read before the end of the current byte transfer, the transfer will stop and the SS will be deasserted. 1 1 The SPIRX register contains new data. Status bit for SPI Rx buffer. When set the Rx FIFO is full. A read of the SPIRx will clear this flag Status bit for SPI Tx buffer. When set the Tx FIFO is underflowing and data can be write into SPITx. A read of the SPISTAT SFR or a write to the SPITx SFR will clear this flag. SPI Transmit Mode Interrupt Flag. Writing new data to the SPITx SFR will clear this bit. SPITxIRQ TIMODE 0 X The SPITX register is full. 1 0 The SPITX register is empty. 1 1 This bit is set when the SPITX register is empty. If the SPI/I2C interrupt is enabled, an interrupt will be generated when this bit is set. If new data isn’t written into the SPITX SFR before the end of the current byte transfer, the transfer will stop and the SS will be deasserted. Rev. PrD | Page 125 of 140 ADE7169F16 0 Preliminary Technical Data SPITxBF 0 Status bit for SPI Tx buffer. When set, the SPI Tx buffer is full. SPI PINS MISO (Master In, Slave Out Data I/O Pin) The MISO pin is configured as an input line in master mode and as an output line in slave mode. The MISO line on the master (data in) should be connected to the MISO line in the slave device (data out).The data is transferred as byte-wide (8bit) serial data, MSB first. MOSI (Master Out, Slave In Pin) The MOSI pin is configured as an output line in master mode and as an input line in slave mode. The MOSI line on the master (data out) should be connected to the MOSI line in the slave device (data in).The data is transferred as byte-wide (8bit) serial data, MSB first. SCLK (Serial Clock I/O Pin) The master serial clock (SCLK) is used to synchronize the data being transmitted and received through the MOSI and MISO data lines. The SCLK pin is configured as an output in master mode and as an input in slave mode. In master mode, the bit rate, polarity, and phase of the clock are controlled by the SPI Configuration Register SFR (SPIMOD1, 0xE8) and SPI Configuration Register SFR (SPIMOD2, 0xE9). In slave mode, the SPI Configuration Register SFR (SPIMOD2, 0xE9) must be configured with the phase and polarity of the expected input clock. In both master and slave modes, the data is transmitted on one edge of the SCLK signal and sampled on the other. It is important, therefore, that CPHA and CPOL are configured the same for the master and slave devices. SS (Slave Select Pin) In SPI slave mode, a transfer is initiated by the assertion of SS low. The SPI port will then transmit and receive 8-bit data until the data is concluded by deassertion of SS. In slave mode, SS is always an input. In SPI master mode, the SS can be used to control data transfer to a slave device. In the automatic slave select control mode, the SS is asserted low to select the slave device and then raised to deselect the slave device after the transfer is complete. Automatic slave select control is enabled by setting the AUTO_SS bit in the SPI Configuration Register SFR (SPIMOD1, 0xE8). In a multi-master system, the SS can be configured as an input so that the SPI peripheral can operate as a slave in some situations and as a master in other situations. In this case, the slave selects for the slaves controlled by this SPI peripheral should be generated with general I/O pins. SPI MASTER OPERATING MODES The double buffered receive and transmit registers can be used to maximize the throughput of the SPI peripheral by continuously streaming out data in master mode. The continuous transmit mode is designed to use the full capacity of the SPI. In this mode, the master will transmit and receive data until the SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A) register is empty at the start of a byte transfer. Continuous mode is enabled by setting the SPICONT bit in the SPI Configuration Register SFR (SPIMOD2, 0xE9).The SPI peripheral also offers a single byte read and a single byte write function. In master mode, the type of transfer is handled automatically depending on the configuration of bits 0 and 7 of the SPI Configuration Register SFR (SPIMOD2, 0xE9). Table 127 shows the sequence of events that should be performed for each master operating mode. Based on the SS configuration, some of these events will take place automatically. Table 127. Procedures for using SPI as a Master Mode SPIMOD[7] SPIMOD[0] Description of operation = TIMODE = SPICONT bit Single Byte Read 0 0 Step1: Read SPIRx SFR Step2: SS is asserted low and read routine is initiated Step 3: SPIRxIRQ Interrupt flag is set when the SPIRx SFR is full Step 4: SS is deasserted high Step 5: Read SPIRx SFR to clear SPIRxIRQ Interrupt flag Single Byte Write 0 1 Step 1: Write to SPITx SFR Step 2: SS is asserted low and write routine is initiated Step 3: SPITxIRQ Interrupt Flag is set when SPITx register is empty Step 4: SS is deasserted high Step 5: Write to SPITx SFR to clear SPITxIRQ Interrupt flag Rev. PrD | Page 126 of 140 Preliminary Technical Data Continuous 1 1 ADE7169F16 Step 1: Write to SPITx SFR Step 2: SS is asserted low and write routine is initiated Step 3: Wait for SPITxIRQ Interrupt flag to write to SPITx SFR. Transfer will continue until the SPITX register and transmit shift registers are empty. Step 4: SPITxIRQ Interrupt Flag is set when SFRTx register is empty Step 5: SS is deasserted high Step 6: Write to SPITx SFR to clear SPITxIRQ Interrupt flag Figure 82 shows the SPI output for certain automatic chip select and continuous mode selections. Note that if the continuous mode is not used, a short delay is inserted between transfers. SS SCLK AUTO_SS=1 SPICONT=1 DIN DOUT DIN1 DIN2 DOUT1 DOUT2 SCLK AUTO_SS=1 SPICONT=0 DIN1 The SPI interface has several status flags that indicate the status of the double buffered receive and transmit registers. Figure 83 shows when the status and interrupt flags are raised. The transmit interrupt occurs when the transmit shift register is loaded with the data in the SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A) register. If the SPI master is in transmit operating mode and the SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A) register has not been written with new data by the beginning of the next byte transfer, the transmit operation stops. When a new byte of data is received in the SPI Receive Buffer SFR (SPI2CRx, 0x9B) register, the SPI receive interrupt flag is raised. If the data in the SPI Receive Buffer SFR (SPI2CRx, 0x9B) register is not read before new data is ready to be loaded into the SPI Receive Buffer SFR (SPI2CRx, 0x9B), an overflow condition has occurred. This overflow condition, indicated by the SPIRxOF flag, will force the new data to be discarded or overwritten if the RxOF_EN bit is set. SS DIN SPI INTERRUPT AND STATUS FLAGS DIN2 SPITX SPIRX SPITxIRQ=1 DOUT DOUT1 SPIRxIRQ=1 DOUT2 TRANSMIT SHIFT REGISTER RECEIVE SHIFT REGISTER SS SPITX (empty) Stops Transfer if TIMODE=1 SCLK TRANSMIT SHIFT REGISTER AUTO_SS=0 SPICONT=0 (manual SS control) DIN DIN1 SPIRX (full) SPIRxOF=1 RECEIVE SHIFT REGISTER DIN2 Figure 83: SPI Receive and Transmit Interrupt and Status Flags DOUT DOUT1 DOUTz2 Figure 82: Automatic Chip Select and Continuous Mode Output Rev. PrD | Page 127 of 140 ADE7169F16 Preliminary Technical Data SCLK (SPICPOL = 1) SCLK (SPICPOL = 0) SS_b MISO ? MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB MOSI ? MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB SPICPHA = 1 SPIRx1 and SPITx1 Flags SPIRx0 and SPITx0 Flags MISO MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB ? MOSI MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB ? SPICPHA = 0 SPIRx1 and SPITx1 Flags SPIRx0 and SPITx0 Flags Figure 84. SPI timing configurations Rev. PrD | Page 128 of 140 Preliminary Technical Data ADE7169F16 SERIAL CLOCK GENERATION I2C COMPATIBLE INTERFACE The I2C master in the system generates the serial clock for a transfer. The master channel can be configured to operate in Fast mode (256 kHz) or Standard mode (32 kHz). The ADE7169F16 supports a fully licensed* I2C interface. The I2C interface is implemented as a full hardware master. SDATA is the data I/O pin, and SCLK is the serial clock. These two pins are shared with the MOSI and SCLK pins of the onchip SPI interface. Therefore, the user can enable only one interface or the other on these pins at any given time. The SCPS bit in the CFG SFR selects which peripheral is active. The bit-rate is defined in the I2CMODE SFR as follow : f SCL = f core 16 × 2 SCLDIV [1:0 ] SLAVE ADDRESSES The two pins used for data transfer, SDA and SCL are configured in a Wired-AND format that allows arbitration in a multi-master system. The I2CADR SFR contains the slave device ID. The LSB of this register contains a read/write request. A write to this SFR will start the I2C communication. The transfer sequence of a I2C system consists of a master device initiating a transfer by generating a START condition while the bus is idle. The master transmits the address of the slave device and the direction of the data transfer in the initial address transfer. If the slave acknowledges then the data transfer is initiated. This continues until the master issues a STOP condition and the bus becomes idle. I2C SFR REGISTER LIST The I2C peripheral interface consists of five SFRs: - I2CMOD - SPI2CSTAT - I2CADR - SPI2CTx - SPI2CRx. As the SPI and I2C serial interfaces share the same pins, I2CMODE, SPI2CSTAT, SPI2CTx and SPI2CRx SFRs are also shared with SPIMODE1, SPI2CSTAT, SPITx and SPIRx SFRs respectively. SFR Address Name R/W Length 0x9A 0x9B 0xE8 0xE9 0xEA SPI2CTx SPI2CRx I2CMOD I2CADR SPI2CSTAT W R R/W R/W R/W 8 8 8 8 8 Default Value 0 0 0 0 Description SPI Data out register SPI Data in register SPI configuration register SPI configuration register SPI/I2C Interrupt Status register Table 128: SPI SFR register list Table 129. I2C Mode Register SFR (I2CMOD, 0xE8) Bit Location 7 6-5 Bit Addr. 0xEF 0xEE – 0xED Bit Name I2CEN Default Value Description 0 I2CR[1:0] 0 I2C enable bit When this bit is set to logic one, the I2C interface is enabled. A write to the I2CADR SFR will start a communication I2C SCLK frequency [1:0] Rev. PrD | Page 129 of 140 ADE7169F16 4-0 0xEC – oxE8 Preliminary Technical Data I2CRCT[4:0] 0 00 Fcore / 16 = 256kHz if Fcore = 4.096MHz 01 Fcore / 32 = 128kHz if Fcore = 4.096MHz 10 Fcore / 64 = 624Hz if Fcore = 4.096MHz 11 Fcore / 128= 32kHz if Fcore = 4.096MHz Configures the length of the I2C received FIFO buffer. The I2C peripheral will stop when I2CRCT[4:0] + 1 bytes have been read or if an error has occured Table 130. I2C Slave Address SFR (I2CADR, 0xE9) Bit Location 7-1 Bit Mnemonic I2CSLVADR Default Value Description 0 0 I2CR_W 0 Address of the I2C slave being adressed Writing to this register start the I2C transmission (Read or write) Command bit for Read or Write When this bit is set to logic one, a read command will be transmitted on the I2C bus. Data from slave in SPI2CRx SFR is expected after command byte When this bit is set to logic zero, a write command will be transmitted on the I2C bus. Data to slave is expected in SPI2CTx SFR Table 131. I2C Interrupt Status Register SFR (I2CSTAT, 0xEA) Bit Location 7 Bit Mnemonic I2CBUSY Default Value Description 0 6 I2CNOACK 0 5 I2CRxIRQ 0 4 I2CTxIRQ 0 3-2 I2CFIFOSTAT[1:0] 0 1 0 I2CACC_ERR I2CTxWR_ERR 0 0 This bit is set to logic one when the I2C interface is used. When set, the Tx FIFO is emptied I2C no acknlowledgement transmit interrupt This bit is set to logic one when the slave device did not send an acknlowledgement. The I2C communication is stopped after this event. Erased by clearing bit. I2C receive interrupt This bit is set to logic one when the receive FIFO is not empty This bit is cleared to logic zero by reading the SPI2CRx SFR and the FIFO is empty I2C transmit interrupt This bit is set to logic one when the transmit FIFO is empty This bit is cleared to logic zero by writing to the SPI2CTx SFR Status bit for 3 or 4 bytes deep I2C FIFO. The FIFO monitored in these 2 bits is the one currently used in I2C communication (Receive or Transmit) as only one of them is active at a time [1:0] 00 FIFO empty 01 Reserved 10 FIFO Half full 11 FIFO Full Set when trying to write and read at the same time Set when write was attempted when I2C transmit FIFO was full An I2C interrupt occurs * Purchase of licensed I2C components of Analog Devices or one of its sublicensed Associated Companies conveys a license for the purchaser under the Philips I2C Patent Rights to use the ADE7XXX in an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips. READ AND WRITE OPERATIONS Figure 85 and Figure 86 depict I2C read and write operations, respectively. Note that the LSB of the I2CADR register is used to select Rev. PrD | Page 130 of 140 Preliminary Technical Data ADE7169F16 whether a read or write operation is performed on the slave device. During the read operation, the master acknowledges are generated automatically by the I2C peripheral. The master generated NACK before the end of a read operation is also generated automatically after I2CRCT[4:0] bytes have been read from the slave. If the I2CADR register is updated during a transmission, instead of generating a STOP at the end of the read or write operation, the master will generate a START condition and continue with the next communication. 1 9 1 9 1 9 SCL SDA A6 A5 A4 A3 A2 A1 A0 R/W START BY MASTER D7 D6 D5 D4 D3 D2 D1 D0 ACK BY SLAVE D7 D6 D5 D4 D3 D2 D1 D0 ACK BY MASTER FRAME 1 SERIAL BUS ADDRESS BYTE NACK BY STOP BY MASTER MASTER FRAME 2 DATA BYTE 1 FROM SLAVE FRAME N+1 DATA BYTE N FROM SLAVE Figure 85: I2C Read operation 1 9 1 9 SCL SDA A6 A5 A4 A3 A2 A1 START BY MASTER A0 R/W D7 D6 D5 D4 D3 D2 D1 ACK BY SLAVE FRAME 1 SERIAL BUS ADDRESS BYTE D0 ACK BY SLAVE STOP BY MASTER FRAME 2 DATA BYTE 1 FROM MASTER Figure 86: I2C Write operation I2C RECEIVE AND TRANSMIT FIFOS The I2C peripheral has a four byte receive FIFO and a four byte transmit FIFO. The buffers reduce the overhead associated with using the I2C peripheral. Figure 87 shows the operation of the I2C receive and transmit FIFOs. full. If the peripheral is reading from a slave address, the communication will stop once the number of received bytes equals the number set in the I2CRCT[4:0] bits. An error such as not receiving an acknowledge will also cause the communication to terminate. Code to read RX FIFO: Code to fill TX FIFO: The TX FIFO can be loaded with four bytes to be transmitted to the slave at the beginning of a write operation. When the transmit FIFO is empty, the I2C transmit interrupt flag will be set and the PC will vector to the I2C interrupt vector if this interrupt is enabled. If a new byte is not loaded into the TX FIFO before it is needed in the transmit shift register, the communication will stop. An error such as not receiving an acknowledge will also cause the communication to terminate. In case of an error during a write operation, the TX FIFO will be flushed. MOV MOV MOV MOV MOV MOV MOV MOV I2CTX, TXDATA1 I2CTX, TXDATA2 I2CTX, TXDATA3 I2CTX, TXDATA4 ; Result: A=RXDATA1 ; Result: A=RXDATA2 ; Result: A=RXDATA3 ; Result: A=RXDATA4 I2CRX I2CTX TXDATA4 4 Byte FIFO A, I2CRX A, I2CRX A, I2CRX A, I2CRX RXDATA1 TXDATA3 4 Byte FIFO RXDATA2 TXDATA2 RXDATA3 TXDATA1 RXDATA4 TRANSMIT SHIFT REGISTER RECEIVE SHIFT REGISTER The RX FIFO allows four bytes to be read in from the slave before the MCU has to read the data. A receive interrupt can be generated after each byte is received or when the RX FIFO is Rev. PrD | Page 131 of 140 Figure 87: I2C FIFO operation ADE7169F16 Preliminary Technical Data DUAL DATA POINTERS The ADE7169F16 incorporates two data pointers. The second data pointer is a shadow data pointer and is selected via the data pointer control SFR (DPCON). DPCON features automatic hardware post-increment and post-decrement as well as an automatic data pointer toggle. Table 132. Data Pointer Control SFR SFR (DPCON, 0xA7) Bit Location Bit Mnemonic Default Value Description 7 ---- 0 Not Implemented. Write Don’t Care. 6 DPT 0 Data Pointer Automatic Toggle Enable. Cleared by the user to disable auto swapping of the DPTR. Set in user software to enable automatic toggling of the DPTR after each MOVX or MOVC instruction. 5, 4 3, 2 DP1m1, DP1m0 DP0m1, DP0m0 0 0 Shadow Data Pointer Mode. These bits enable extra modes of the shadow data pointer operation, allowing more compact and more efficient code size and execution. DP1m1 DP1m0 Behavior of the Shadow Data Pointer 0 0 8052 behavior. 0 1 DPTR is post-incremented after a MOVX or a MOVC instruction. 1 0 DPTR is post-decremented after a MOVX or MOVC instruction. 1 1 DPTR LSB is toggled after a MOVX or MOVC instruction. (This instruction can be useful for moving 8-bit blocks to/from 16-bit devices.) Main Data Pointer Mode. These bits enable extra modes of the main data pointer operation, allowing more compact and more efficient code size and execution. DP0m1 DP0m0 Behavior of the Main Data Pointer 0 0 8052 behavior. 0 1 DPTR is post-incremented after a MOVX or a MOVC instruction. 1 0 DPTR is post-decremented after a MOVX or MOVC instruction. 1 1 DPTR LSB is toggled after a MOVX or MOVC instruction. (This instruction is useful for moving 8-bit blocks to/from 16-bit devices.) 1 ---- 0 Not Implemented. Write Don’t Care. 0 DPSEL 0 Data Pointer Select. Cleared by the user to select the main data pointer. This means that the contents of this 16bit register are placed into the DPL, and DPH SFRs. Set by the user to select the shadow data pointer. This means that the contents of a separate 16-bit register appear in the DPL, and DPH SFRs. Note the following: • The Dual Data Pointer section is the only place in which main and shadow data pointers are distinguished. Rev. PrD | Page 132 of 140 Preliminary Technical Data ADE7169F16 Whenever the DPTR is mentioned elsewhere in this data sheet, active DPTR is implied. • Only the MOVC/MOVX @DPTR instructions automatically post-increment and post-decrement the DPTR. Other MOVC/MOVX instructions, such as MOVC PC or MOVC @Ri, do not cause the DPTR to automatically post-increment and post-decrement. To illustrate the operation of DPCON, the following code copies 256 bytes of code memory at Address D000H into XRAM, starting from Address 0000H. MOV DPTR,#0 ;Main DPTR = 0 MOV DPCON,#55H ;Select shadow DPTR ;DPTR1 increment mode ;DPTR0 increment mode ;DPTR auto toggling ON MOV DPTR,#0D000H ;DPTR = D000H MOVELOOP: CLR A MOVC A,@A+DPTR ;Get data ;Post Inc DPTR ;Swap to Main DPTR(Data) MOVX @DPTR,A ;Put ACC in XRAM ;Increment main DPTR ;Swap Shadow DPTR(Code) MOV A, DPL JNZ MOVELOOP Rev. PrD | Page 133 of 140 ADE7169F16 Preliminary Technical Data I/O PORTS PARALLEL I/O The ADE7169F16 uses three input/output ports to exchange data with external devices. In addition to performing generalpurpose I/O, some are capable of driving an LCD or performing other alternate functions for the peripheral functions available on-chip. In general, when a peripheral is enabled, the pins associated with it cannot be used as a general-purpose I/O. The I/O port can be configured through the SFRs in Table 133. Table 133. I/O port SFRs SFR Address Bit Addressable Description of the flip-flop is placed on the internal bus in response to a read latch signal from the CPU. The level of the port pin itself is placed on the internal bus in response to a read pin signal from the CPU. Some instructions that read a port activate the read latch signal, and others activate the read pin signal. See the Read-Modify-Write Instructions section for details. Weak Internal Pullups Enabled A pin with the weak internal pull-up enabled is used as an input by writing a 1 is written to the pin. The pin will be pulled high by the internal pull-ups and the pin will be read using the circuitry shown in Figure 88. If the pin is driven low externally, it will source current because of the internal pull-ups. P0 0x80 Yes Port 0 register P1 0x90 Yes Port 1 register If used as an output, a pin with an internal pull-up enabled, will be written with a 1 or a 0 to control the level of the output. If a 0 is written to the pin, it will drive a logic low output voltage (VOL) and is capable of sinking TBD mA. P2 0xA0 Yes Port 2 register Open Drain (Weak Internal Pull-ups Disabled) EPCFG 0x9F No Extended Port Configuration PINMAP0 0xB2 No Port 0 weak pull-up enable PINMAP1 0xB3 No Port 1 weak pull-up enable PINMAP2 0xB4 No Port 2 weak pull-up enable The three bidirectional I/O ports have internal pull-ups that can be enabled or disabled individually for each pin. The internal pull-ups are enabled by default. Disabling an internal pull-up causes a pin to become open-drain. Weak internal pull-ups are configured through PINMAPx SFRs. DVDD ALTERNATE OUTPUT FUNCTION READ LATCH INTERNAL BUS D WRITE TO LATCH CL Q INTERNAL PULL-UP Closed: PINMAPx.x=0 Open: PINMAPx.x=1 To use an open-drain pin as a general purpose output, an external pull-up resistor is required. Open drain outputs are convenient for changing the voltage to a logic high. The ADE7169F16 is a 3.3V device so an external resistor pulled up to 5V may ease interfacing to a 5V IC although most 5V ICs are tolerant of 3.3V inputs. Pins with 0s written to them drive a logic low output voltage (VOL) and are capable of sinking 1.6 mA. 38 kHz Modulation The ADE7169F16 provides a 38 kHz modulation signal. The 38 kHz modulation is accomplished by internally XORing the level written to the MOD38 pin with a 38 kHz square wave. Then when a zero is written to the MOD38 pin, it is modulated as shown in Figure 89. Level written to MOD38 Px.x PIN Q When the weak internal pull-up on a pin is disabled, the pin becomes open drain. To use this open-drain pin as a high impedance input, a 1 is written to the pin. The pin will be read using the circuitry shown in Figure 88. The open drain option is preferable for inputs because it draws less current than the internal pull-ups were enabled. 38kHz Modulation Signal LATCH Output at MOD38 Pin READ PIN ALTERNATE INPUT FUNCTION Figure 89: 38 kHz Modulation Figure 88. Port 0 Bit Latch and I/O Buffer Figure 88 shows a typical bit latch and I/O buffer for an I/O pin. The bit latch (one bit in the port’s SFR) is represented as a Type D flip-flop, which clocks in a value from the internal bus in response to a write to latch signal from the CPU. The Q output Uses for this 38 kHz modulation include IR modulation of a UART transmit signal or a low power signal to drive a LED. The modulation can be enabled or disabled with the MOD38EN bit in the CFG SFR. The 38 kHz modulation is available on eight pins, selected by the MOD38[7:0] bits in the Extended Port Configuration SFR (EPCFG, 0x9F). Rev. PrD | Page 134 of 140 ADE7169F16 Preliminary Technical Data I/O SFR REGISTER LIST Table 134. Extended Port Configuration SFR (EPCFG, 0x9F) Bit Location 7 6 5 4 3 2 Bit Mnemonic MOD38_FP21 MOD38_FP22 MOD38_FP23 MOD38_TxD MOD38_CF1 MOD38_SSb Default Value Description 0 0 0 0 0 0 Enable 38kHz modulation on P1.6/FP21 pin Enable 38kHz modulation on P1.5/FP22 pin Enable 38kHz modulation on P1.4/FP23/T2 pin Enable 38kHz modulation on P1.1/Tx pin Enable 38kHz modulation on P0.2/CF1 pin Enable 38kHz modulation on P0.7/SS/T1pin 1 0 MOD38_MISO MOD38_CF2 0 0 Enable 38kHz modulation on P0.5/MISO pin Enable 38kHz modulation on P0.3/CF2 pin Table 135. Port 0 Weak pull-up enable SFR (PINMAP0, 0xB2) Bit Location 7 6 5 4 3 2 1 0 Bit Mnemonic PINMAP0.7 PINMAP0.6 PINMAP0.5 PINMAP0.4 PINMAP0.3 PINMAP0.2 PINMAP0.1 PINMAP0.0 Default Value Description 0 0 0 0 0 0 0 0 The weak pull-up on P0.7 is disabled when this bit is set The weak pull-up on P0.6 is disabled when this bit is set The weak pull-up on P0.5 is disabled when this bit is set The weak pull-up on P0.4 is disabled when this bit is set The weak pull-up on P0.3 is disabled when this bit is set The weak pull-up on P0.2 is disabled when this bit is set The weak pull-up on P0.1 is disabled when this bit is set The weak pull-up on P0.0 is disabled when this bit is set Table 136. Port 1 Weak pull-up enable SFR (PINMAP1, 0xB3) Bit Location 7 6 5 4 3 2 1 0 Bit Mnemonic PINMAP1.7 PINMAP1.6 PINMAP1.5 PINMAP1.4 PINMAP1.3 PINMAP1.2 PINMAP1.1 PINMAP1.0 Default Value Description 0 0 0 0 0 0 0 0 The weak pull-up on P1.7 is disabled when this bit is set The weak pull-up on P1.6 is disabled when this bit is set The weak pull-up on P1.5 is disabled when this bit is set The weak pull-up on P1.4 is disabled when this bit is set The weak pull-up on P1.3 is disabled when this bit is set The weak pull-up on P1.2 is disabled when this bit is set The weak pull-up on P1.1 is disabled when this bit is set The weak pull-up on P1.0 is disabled when this bit is set Table 137. Port 2 Weak pull-up enable SFR (PINMAP2, 0xB4) Bit Location 7-6 5 4 3 2 1 0 Bit Mnemonic Reserved PINMAP2.5 Reserved PINMAP2.3 PINMAP2.2 PINMAP2.1 PINMAP2.0 Default Value Description 0 0 0 0 0 0 0 Reserved. Should be left cleared The weak pull-up on Reset is disabled when this bit is set The weak pull-up on EA is disabled when this bit is set Reserved. Should be left cleared The weak pull-up on P2.2 is disabled when this bit is set The weak pull-up on P2.1 is disabled when this bit is set The weak pull-up on P2.0 is disabled when this bit is set Table 138. Port 0 SFR (P0, 0x80) Note: When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set Rev. PrD | Page 135 of 140 ADE7169F16 Bit Location Preliminary Technical Data Bit Name T1 Default Value 1 Description 7 Bit Addr. 0x87 6 5 4 3 2 1 0 0x86 0x85 0x84 0x83 0x82 0x81 0x80 T0 1 1 1 1 1 1 1 This bit reflects the state of P0.6/SCLK/T0 pin. It can be written or read. This bit reflects the state of P0.5/MISO pin. It can be written or read. This bit reflects the state of P0.4/MOSI/SDATA pin. It can be written or read. This bit reflects the state of P0.3/CF2 pin. It can be written or read. This bit reflects the state of P0.2/CF1 pin. It can be written or read. This bit reflects the state of P0.1 pin. It can be written or read. This bit reflects the state of P0.0/INT1/BCTRL pin. It can be written or read. CF2 CF1 INT1 This bit reflects the state of P0.7/SS/T1 pin. It can be written or read. Table 139. Port 1 SFR (P1, 0x90) Note: When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set Bit Location Bit Bit Default Description Addr. Name value 7 0x97 1 This bit reflects the state of P1.7 pin. It can be written or read. 6 0x96 1 This bit reflects the state of P1.6 pin. It can be written or read. 5 0x95 1 This bit reflects the state of P1.5 pin. It can be written or read. 4 0x94 T2 1 This bit reflects the state of P1.4/T2 pin. It can be written or read. 3 0x93 T2EX 1 This bit reflects the state of P1.3/T2EX pin. It can be written or read. 2 0x92 1 This bit reflects the state of P1.2 pin. It can be written or read. 1 0x91 TxD 1 This bit reflects the state of P1.1/TxD pin. It can be written or read. 0 0x90 RxD 1 This bit reflects the state of P1.0/RxD pin. It can be written or read. Table 140. Port 2 SFR (P2, 0xA0) Note: When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set Bit Location Bit Bit Default Description Addr. Name Value 7-2 0x3F These bits are unused and should be left set 0x97 – 0x92 1 0x91 P2.1 1 This bit reflects the state of P2.1 pin. It can be written or read. 0 0x90 P2.0 1 This bit reflects the state of P2.0 pin. It can be written or read. Table 141. Port 0 Alternate Functions Pin No. P0.0 Alternate Function Alternate Function Enable BCTRL external battery control input Set INT1PROG[2:0]=X01 in the Interrupt pins configuration SFR (INTPR, 0xFF) INT1 external interrupt Set EX1 in the Interrupt Enable SFR (IE, 0xA8). INT1 wakeup from PSM2 operating mode Set INT1PROG[2:0]=11X in the Interrupt pins configuration SFR (INTPR, 0xFF) P0.1 FP19 LCD Segment Pin P0.2 CF1 ADE Calibration Frequency output P0.3 CF2 ADE Calibration Frequency output P0.4 MOSI SPI Data line Set FP19EN in the LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) Clear the DISCF1 bit in the ADE energy measurement internal MODE1 register (0x0B) Clear the DISCF2 bit in the ADE energy measurement internal MODE1 register (0x0B) Set the SCPS bit in the CFG SFR and set the SPIEN bit in the SPI Configuration Register SFR (SPIMOD1, 0xE8). Clear the SCPS bit in the Configuration SFR (CFG, 0xAF) and set the I2CEN bit in the I2C Mode Register SFR (I2CMOD, 0xE8). SDATA I2C Data line Rev. PrD | Page 136 of 140 Preliminary Technical Data P0.5 MISO SPI Data line P0.6 SCLK serial clock for I2C or SPI T0 Timer0 input P0.7 SS SPI slave select input for SPI in slave mode ADE7169F16 Set the SCPS bit in the Configuration SFR (CFG, 0xAF) and set the SPIEN bit in the SPI Configuration Register SFR (SPIMOD2, 0xE9) Set the I2CEN bit in the I2CMOD SFR or the SPIEN bit in the SPI Configuration Register SFR (SPIMOD2, 0xE9) to enable the I2C or SPI interface Set the CNT0 bit in the Timer/Counter 0 and 1 Mode SFR (TMOD, 0x89) to enable T0 as an external event counter Set the SS_EN bit in the SPI Configuration Register SFR (SPIMOD1, 0xE8) SS SPI slave select output for SPI in master mode Set the SPIMS_b bit in the SPI Configuration Register SFR (SPIMOD2, 0xE9) T1 Timer 1 input Set the CNT1 bit in the Timer/Counter 0 and 1 Mode SFR (TMOD, 0x89) to enable T1 as an external event counter Table 142. Port 1 Alternate Functions Pin No. P1.0 Alternate Function Alternate Function Enable RxD Receiver Data Input for UART Set the REN bit in the SCON SFR Bit Description SFR (SCON, 0x98). Set RXPROG[1:0]=11 in the Peripheral Configuration SFR (PERIPH, 0xF4) RX Edge wakeup from PSM2 operating mode P1.1 P1.2 P1.3 P1.4 P1.5 P1.6 P1.7 TxD Transmitter Data Output for UART FP25 LCD Segment Pin FP24 LCD Segment Pin T2EX Timer 2 control input FP23 LCD Segment Pin T2 Timer 2 input FP22 LCD Segment Pin FP21 LCD Segment Pin FP20 LCD Segment Pin Set FP25EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Set FP24EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Set EXEN2 in the Timer/Counter 2 Control SFR (T2CON, 0xC8) Set FP23EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Set the CNT2 bit in the Timer/Counter 2 Control SFR (T2CON, 0xC8) to enable T2 as an external event counter Set FP22EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Set FP21EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Set FP20EN in the LCD Segment Enable SFR (LCDSEGE, 0x97) Table 143. Port 2 Alternate Functions Pin No. P2.0 Alternate Function Alternate Function Enable FP18 LCD Segment Pin P2.1 FP17 LCD Segment Pin P2.2 FP16 LCD Segment Pin P2.3 SDEN Serial Download pin sampled on reset. P2.3 is an output only. Set FP18EN in the LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) Set FP17EN in the LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) Set FP16EN in the LCD Segment Enable 2 SFR (LCDSEGE2, 0xED) Enabled by default. PORT 0 Port 0 is controlled directly through the bit-addressable Port 0 SFR (80H). The weak internal pull-ups for Port 0 are configured through the Port 0 Weak pull-up enable SFR (PINMAP0, 0xB2); they are enabled by default. Disable the weak internal pull-up by writing a one to P0CFG..x. Port 0 pins also have various secondary functions as described in Table 141. The alternate functions of Port 0 pins can be activated only if Rev. PrD | Page 137 of 140 ADE7169F16 Preliminary Technical Data the corresponding bit latch in the P0 SFR contains a 1. Otherwise, the port pin remains at 0. PORT 1 Port 1 is an 8-bit bidirectional port controlled directly through the bit-addressable Port 1 SFR (90H). The weak internal pull-ups for Port 1 are configured through the Port 1 Weak pull-up enable SFR (PINMAP1, 0xB3); they are enabled by default. Disable the weak internal pull-up by writing a one to P1CFG..x. Port 1 pins also have various secondary functions as described in Table 142. The alternate functions of Port 1 pins can be activated only if the corresponding bit latch in the P1 SFR contains a 1. Otherwise, the port pin remains at 0. PORT 2 Port 2 is a 4-bit bidirectional port controlled directly through the bit-addressable Port 2 SFR (A0H). Note that P2.3 can be used as an output only. The weak internal pull-ups for Port 2 are configured through the Port 2 Weak pull-up enable SFR (PINMAP2, 0xB4); they are enabled by default. Disable the weak internal pull-up by writing a one to P2CFG..x. Port 2 pins also have various secondary functions as described in Table 143. The alternate functions of Port 2 pins can be activated only if the corresponding bit latch in the P2 SFR contains a 1. Otherwise, the port pin remains at 0. Rev. PrD | Page 138 of 140 ADE7169F16 Preliminary Technical Data OUTLINE DIMENSIONS Dimensions shown in millimeters Rev. PrD | Page 139 of 140 ADE7169F16 Preliminary Technical Data ORDERING GUIDE Table 144. Model ADE7169ASTF16 ADE7169ASTZF16 ADE7169ASTF16-RL ADE7169ASTZF16-RL ADE7169ACPF16 ADE7169ACPZF16 ADE7169ACPF16-RL ADE7169ACPZF16-RL EVAL-ADE7169F16EB Package Description 64-Lead LQFP 64-Lead Lead Free LQFP 64-Lead LQFP in Reel 64-Lead Lead Free LQFP in Reel 64-Lead CSP 64-Lead Lead Free CSP 64-Lead CSP in Reel 64-Lead Lead Free CSP in Reel ADE7169 Evaluation Board Package Option* LQFP-64 LQFP-64 LQFP-64 LQFP-64 LFCSP-64 LFCSP-64 LFCSP-64 LFCSP-64 © 2006 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. PR06353-0-9/06(PrD) Rev. PrD | Page 140 of 140 Temperature Range −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C −40°C to +85°C