Single-Phase Energy Measurement IC with
8052 MCU, RTC, and LCD Driver
ADE7518
GENERAL FEATURES
MICROPROCESSOR FEATURES
Wide supply voltage operation: 2.4 V to 3.7 V
Internal bipolar switch between regulated and battery inputs
Ultralow power operation with power saving modes
Full operation: 4 mA to 1.6 mA (PLL clock dependent)
Battery mode: 3.2 mA to 400 μA (PLL clock dependent)
Sleep mode
Real-time clock (RTC) mode: 1.5 μA
RTC and LCD mode: 27 μA
Reference: 1.2 V ± 0.1% (10 ppm/°C drift)
64-lead RoHS package option
Low profile quad flat package (LQFP)
Operating temperature range: −40°C to +85°C
8052-based core
Single-cycle 4 MIPS 8052 core
8052-compatible instruction set
32.768 kHz external crystal with on-chip PLL
Two external interrupt sources
External reset pin
Low power battery mode
Wake-up from I/O, alarm, and universal asynchronous
receiver/transmitter (UART)
LCD driver operation
Real-time clock
Counter for seconds, minutes, and hours
Automatic battery switchover for RTC backup
Operation down to 2.4 V
Ultralow battery supply current: 1.5 μA
Selectable output frequency: 1 Hz to 16.384 kHz
Embedded digital crystal frequency compensation for
calibration and temperature variation: 2 ppm resolution
Integrated LCD driver
108-segment driver
2×, 3×, or 4× multiplexing
LCD voltages generated with external resistors
On-chip peripherals
UART, SPI or I2C, and watchdog timer
Power supply management with user-selectable levels
Memory: 16 kB flash memory, 512 bytes RAM
Development tools
Single-pin emulation
IDE-based assembly and C-source debugging
ENERGY MEASUREMENT FEATURES
Proprietary analog-to-digital converters (ADCs) and digital
signal processing (DSP) provide high accuracy active
(WATT), reactive (VAR), and apparent energy (VA)
measurement
Less than 0.1% error on active energy over a dynamic
range of 1000 to 1 @ 25°C
Less than 0.5% error on reactive energy over a dynamic
range of 1000 to 1 @ 25°C
Less than 0.5% error on root mean square (rms)
measurements over a dynamic range of 500 to 1 for
current (Irms) and 100 to 1 for voltage (Vrms) @ 25°C
Supports IEC 62053-21, IEC 62053-22, IEC 62053-23,
EN 50470-3 Class A, Class B, and Class C, and ANSI C12-16
Differential input with programmable gain amplifiers (PGAs)
supports shunts and current transformers
High frequency outputs proportional to Irms, active, reactive,
or apparent power (AP)
Rev. 0
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: 781.461.3113
©2009 Analog Devices, Inc. All rights reserved.
ADE7518
TABLE OF CONTENTS
General Features ............................................................................... 1 Phase Compensation ................................................................. 46 Energy Measurement Features........................................................ 1 RMS Calculation ........................................................................ 46 Microprocessor Features.................................................................. 1 Active Power Calculation .......................................................... 48 Revision History ............................................................................... 3 Active Energy Calculation ........................................................ 50 General Description ......................................................................... 4 Reactive Power Calculation ...................................................... 53 Functional Block Diagram .............................................................. 4 Reactive Energy Calculation ..................................................... 54 Specifications..................................................................................... 5 Apparent Power Calculation ..................................................... 58 Energy Metering ........................................................................... 5 Apparent Energy Calculation ................................................... 59 Analog Peripherals ....................................................................... 6 Ampere-Hour Accumulation ................................................... 60 Digital Interface ............................................................................ 7 Energy-to-Frequency Conversion............................................ 61 Timing Specifications .................................................................. 9 Energy Register Scaling ............................................................. 62 Absolute Maximum Ratings.......................................................... 14 Energy Measurement Interrupts .............................................. 62 Thermal Resistance .................................................................... 14 8052 MCU CORE Architecture .................................................... 63 ESD Caution ................................................................................ 14 MCU Registers ............................................................................ 63 Pin Configuration and Function Descriptions ........................... 15 Basic 8052 Registers ................................................................... 65 Typical Performance Characteristics ........................................... 17 Standard 8052 SFRs.................................................................... 66 Terminology .................................................................................... 20 Memory Overview ..................................................................... 66 SFR Mapping ................................................................................... 21 Addressing Modes ...................................................................... 67 Power Management ........................................................................ 22 Instruction Set ............................................................................ 69 Power Management Register Details ....................................... 22 Read-Modify-Write Instructions ............................................. 71 Power Supply Architecture ........................................................ 25 Instructions That Affect Flags .................................................. 71 Battery Switchover...................................................................... 25 Dual Data Pointers ......................................................................... 73 Power Supply Management (PSM) Interrupt ......................... 26 Interrupt System ............................................................................. 74 Using the Power Supply Features ............................................. 28 Standard 8052 Interrupt Architecture ..................................... 74 Operating Modes ............................................................................ 30 Interrupt Architecture ............................................................... 74 PSM0 (Normal Mode) ............................................................... 30 Interrupt Registers...................................................................... 74 PSM1 (Battery Mode) ................................................................ 30 Interrupt Priority ........................................................................ 75 PSM2 (Sleep Mode).................................................................... 30 Interrupt Flags ............................................................................ 76 3.3 V Peripherals and Wake-Up Events ................................... 31 Interrupt Vectors ........................................................................ 78 Transitioning Between Operating Modes ............................... 32 Interrupt Latency........................................................................ 78 Using the Power Management Features .................................. 32 Context Saving ............................................................................ 78 Energy Measurement ..................................................................... 33 Watchdog Timer ............................................................................. 79 Access to Energy Measurement SFRs ...................................... 33 LCD Driver ...................................................................................... 81 Access to Internal Energy Measurement Registers ................ 33 LCD Registers ............................................................................. 81 Energy Measurement Registers ................................................ 35 LCD Setup ................................................................................... 84 Energy Measurement Internal Registers Details .................... 36 LCD Timing and Waveforms.................................................... 84 Interrupt Status/Enable SFRs .................................................... 38 Blink Mode .................................................................................. 85 Analog Inputs .............................................................................. 40 Display Element Control ........................................................... 85 Analog-to-Digital Conversion .................................................. 41 LCD External Circuitry ............................................................. 86 Power Quality Measurements ................................................... 44 LCD Function in PSM2 ............................................................. 86 Rev. 0 | Page 2 of 128
ADE7518
Flash Memory ..................................................................................87 UART Additional Features ......................................................111 Overview ......................................................................................87 Serial Peripheral Interface (SPI) ..................................................112 Flash Memory Organization......................................................88 SPI Registers ..............................................................................112 Using the Flash Memory ............................................................88 SPI Pins.......................................................................................115 Protecting the Flash Memory ....................................................91 SPI Master Operating Modes ..................................................116 In-Circuit Programming ............................................................92 SPI Interrupt and Status Flags .................................................117 Timers ...............................................................................................93 I C-Compatible Interface .............................................................118 Timer Registers............................................................................93 Serial Clock Generation ...........................................................118 Timer 0 and Timer 1 ...................................................................95 Slave Addresses..........................................................................118 Timer 2 .........................................................................................96 I2C Registers ...............................................................................118 PLL ....................................................................................................98 Read and Write Operations .....................................................119 PLL Registers ...............................................................................98 I2C Receive and Transmit FIFOs.............................................120 Real-Time Clock........................................................................... 100 I/O Ports .........................................................................................121 RTC Registers ........................................................................... 100 Parallel I/O .................................................................................121 Read and Write Operations .................................................... 103 I/O Registers ..............................................................................122 RTC Modes ............................................................................... 103 Port 0...........................................................................................125 RTC Interrupts ......................................................................... 103 Port 1...........................................................................................125 RTC Calibration ....................................................................... 104 Port 2...........................................................................................125 UART Serial Interface .................................................................. 105 Determining the Version of the ADE7518 ................................126 UART Registers ........................................................................ 105 Outline Dimensions ......................................................................127 UART Operation Modes ......................................................... 108 Ordering Guide .........................................................................127 2
UART Baud Rate Generation ................................................. 109 REVISION HISTORY
1/09—Revision 0: Initial Version
Rev. 0 | Page 3 of 128
ADE7518
GENERAL DESCRIPTION
The ADE75181 integrates the Analog Devices, Inc., energy
(ADE) metering IC analog front end and fixed function DSP
solution with an enhanced 8052 MCU core, an RTC, an LCD
driver, and all the peripherals to make an electronic energy
meter with an LCD display in a single part.
The microprocessor functionality includes a single-cycle 8052 core,
a real-time clock with a power supply backup pin, a UART, and an
SPI or I2C® interface. The ready-to-use information from the
ADE core reduces the program memory size requirement, making
it easy to integrate complicated design into 16 kB of flash
memory.
The ADE measurement core includes active, reactive, and 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,
such as SAG, peak, and zero crossing, are included in the energy
measurement DSP to simplify energy meter design.
The ADE7518 also includes a 108-segment LCD driver. This
driver generates waveforms capable of driving LCDs up to 3.3 V.
38 39 40 41
39 38 7
6
45 11 43 42 41 40 39 38
37 36 5
6
7
P1.7 (FP20)
P1.5 (FP22)
8
P1.6 (FP21)
P1.2 (FP25)
P1.3 (T2EX/FP24)
P1.4 (T2/FP23)
P1.0 (RxD)
P1.1 (TxD)
P0.2 (CF1/RTCCAL)
P0.3 (CF2)
P0.4 (MOSI/SDATA)
P0.5 (MISO)
P0.6 (SCLK/T0)
P0.7 (SS/T1)
P0.1 (FP19)
P0.0 (BCTRL/INT1)
T2EX
T1
T2
T0
MOSI/SDATA
SCLK
MISO
43 42
SS
CF1
57
CF2
REFIN/OUT
FUNCTIONAL BLOCK DIAGRAM
9 10
12 P2.0 (FP18)
13 P2.1 (FP17)
1.20V
REF
VP 49
VN 50
44 P2.3 (SDEN)
LCD
LEVELS
ADC
+
PGA2
–
ADC
ENERGY
MEASUREMENT
DSP
SINGLE
CYCLE
8052
MCU
PROGRAM MEMORY
16kB FLASH
USER RAM
256 BYTES
AGND 54
POR
64
60
61
62
59
56
51
44
36
37
47
46
48
45
VINTA
RESET
EA
SDEN
TxD
RxD
XTAL1
XTAL2
INT0
INT1
OSC
VINTD
RTC
VSWOUT
UART
SERIAL
PORT
VDD
UART
TIMER
VDCIN
LDO
PLL
Figure 1.
1
LCDVA
17
LCDVB
15
LCDVC
4
COM0
Patents pending.
Rev. 0 | Page 4 of 128
...
COM3
...
20 FP15
DOWNLOADER
DEBUGGER
1-PIN
EMULATOR
POWER SUPPLY
CONTROL AND
MONITORING
LDO
LCDVP2
18
35 FP0
WATCHDOG
TIMER
USER XRAM
256 BYTES
VBAT 58
LCDVP1
16
1
108-SEGMENT
LCD DRIVER
DGND 63
19
...
IN 53
+
PGA1
–
14 P2.2 (FP16)
.. .
IP 52
ADE7518
3 × 16-BIT
COUNTER
TIMERS
14
FP16
13
FP17
12
FP18
11
FP19
10
FP20
9
FP21
8
FP22
7
FP23
6
FP24
5
FP25
55
FP26
07327-001
SPI/I2C
SERIAL
INTERFACE
ADE7518
SPECIFICATIONS
VDD = 3.3 V ± 5%, AGND = DGND = 0 V, on-chip reference XTAL = 32.768 kHz, TMIN to TMAX = −40°C to +85°C, unless otherwise noted.
ENERGY METERING
Table 1.
Parameter
MEASUREMENT ACCURACY1
Phase Error Between Channels
PF = 0.8 Capacitive
PF = 0.5 Inductive
Active Energy Measurement Error2
AC Power Supply Rejection2
Output Frequency Variation
DC Power Supply Rejection2
Output Frequency Variation
Active Energy Measurement Bandwidth1
Reactive Energy Measurement Error2
Vrms Measurement Error2
Vrms Measurement Bandwidth1
Irms Measurement Error2
Irms Measurement Bandwidth1
ANALOG INPUTS
Maximum Signal Levels
Min
Duty Cycle
Active High Pulse Width
1
2
Max
Unit
Test Conditions/Comments
±0.05
±0.05
0.1
Degrees
Degrees
% of reading
0.01
%
37° phase lead
60° phase lag
Over a dynamic range of 1000 to 1 @ 25°C
VDD = 3.3 V + 100 mV rms/120 Hz
IP = VP = ±100 mV rms
VDD = 3.3 V ± 117 mV dc
0.01
8
0.5
0.5
3.9
0.5
3.9
%
kHz
% of reading
% of reading
kHz
% of reading
kHz
±400
±400
Input Impedance (DC)
ADC Offset Error2
Gain Error2
Current Channel
Voltage Channel
Gain Error Match
CF1 AND CF2 PULSE OUTPUT
Maximum Output Frequency
Typ
Over a dynamic range of 1000 to 1 @ 25°C
Over a dynamic range of 100 to 1 @ 25°C
Over a dynamic range of 500 to 1 @ 25°C
mV peak
mV peak
kΩ
mV
mV
VP − VN differential input
IP − IN differential input
IP = 0.4 V dc or IP = 0.4 dc
Voltage channel = 0.4 V dc
±0.2
%
%
%
13.5
kHz
50
90
%
ms
VP − VN = 400 mV peak, IP − IN = 250 mV,
PGA1 = 2 sine wave
If CF1 or CF2 frequency, >5.55 Hz
If CF1 or CF2 frequency, <5.55 Hz
770
±10
±1
−3
−3
+3
+3
PGA1 = PGA2 = 1
PGA1 = 16
These specifications are not production tested but are guaranteed by design and/or characterization data on production release.
See the Terminology section for definition.
Rev. 0 | Page 5 of 128
ADE7518
ANALOG PERIPHERALS
Table 2.
Parameter
POWER-ON RESET (POR)
VDD POR
Detection Threshold
POR Active Timeout Period
VSWOUT POR
Detection Threshold
POR Active Timeout Period
VINTD POR
Detection Threshold
POR Active Timeout Period
VINTA POR
Detection Threshold
POR Active Timeout Period
BATTERY SWITCHOVER
Voltage Operating Range (VSWOUT)
VDD to VBAT Switching
Switching Threshold (VDD)
Switching Delay
VBAT to VDD Switching
Switching Threshold (VDD)
Switching Delay
VSWOUT To VBAT Leakage Current
LCD, RESISTOR LADDER ACTIVE
Leakage Current
V1 Segment Line Voltage
V2 Segment Line Voltage
V3 Segment Line Voltage
ON-CHIP REFERENCE
Reference Error
Power Supply Rejection
Temperature Coefficient
Min
Typ
2.5
Max
Unit
2.95
V
ms
2.2
V
ms
2.22
V
ms
2.15
V
ms
3.7
V
2.95
V
ns
ms
When VDD to VBAT switch activated by VDD
When VDD to VBAT switch activated by VDCIN
V
ms
nA
Based on VDD > 2.75 V
VBAT = 0 V, VSWOUT = 3.43 V, TA = 25°C
±20
LCDVA
LCDVB
LCDVC
nA
V
V
V
1/2 and 1/3 bias modes, no load
Current on segment line = −2 μA
Current on segment line = −2 μA
Current on segment line = −2 μA
±0.9
mV
dB
ppm/°C
TA = 25°C
33
1.8
20
2.03
16
2.05
120
2.4
2.5
10
30
2.5
2.95
30
10
LCDVA − 0.1
LCDVB − 0.1
LCDVC − 0.1
80
10
Rev. 0 | Page 6 of 128
50
Test Conditions/Comments
ADE7518
DIGITAL INTERFACE
Table 3.
Parameter
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
Port 0, Port 1, Port 2
Input Capacitance
FLASH MEMORY
Endurance1
Data Retention2
CRYSTAL OSCILLATOR
Crystal Equivalent Series Resistance
Crystal Frequency
XTAL1 Input Capacitance
XTAL2 Output Capacitance
MCU CLOCK RATE (fCORE)
LOGIC OUTPUTS
Output High Voltage, VOH
ISOURCE
Output Low Voltage, VOL3
ISINK
START-UP TIME4
PSM0 Power-On Time
From Power Saving Mode 1 (PSM1)
Min
Max
Unit
0.4
V
V
0.4
V
V
2.0
1.3
−3.75
10
100
±100
−8.5
10,000
20
30
32
32.768
12
12
4.096
32
50
33.5
2.4
3.13
2.4
Test Conditions/Comments
nA
nA
μA
pF
RESET = VSWOUT = 3.3 V
Internal pull-up disabled, input = 0 V or VSWOUT
Internal pull-up enabled, input = 0 V, VSWOUT = 3.3 V
All digital inputs
Cycles
Years
TJ = 85°C
kΩ
kHz
pF
pF
MHz
kHz
Crystal = 32.768 kHz and CD[2:0] = 0b000
Crystal = 32.768 kHz and CD[2:0] = 0b111
V
μA
V
mA
VDD = 3.3 V ± 5%
448
ms
VDD at 2.75 V to PSM0 code execution
130
ms
VDD at 2.75 V to PSM0 code execution
48
186
ms
ms
Wake-up event to PSM1 code execution
VDD at 2.75 V to PSM0 code execution
80
0.4
2
PSM1 → PSM0
From Power Saving Mode 2 (PSM2)
PSM2 → PSM1
PSM2 → PSM0
POWER SUPPLY INPUTS
VDD
VBAT
INTERNAL POWER SUPPLY SWITCH (VSWOUT)
VBAT to VSWOUT On Resistance
VDD to VSWOUT On Resistance
VBAT ←→ VDD Switching Open Time
BCTRL State Change and Switch Delay
VSWOUT Output Current Drive
POWER SUPPLY OUTPUTS
VINTA
VINTD
VINTA Power Supply Rejection
VINTD Power Supply Rejection
Typ
3.3
3.3
40
18
1
2.25
2.3
3.46
3.7
V
V
22
10.2
Ω
Ω
ns
μs
mA
6
2.75
2.70
60
50
V
V
dB
dB
Rev. 0 | Page 7 of 128
VDD = 3.3 V ± 5%
VBAT = 2.4 V
VDD = 3.13 V
ADE7518
Parameter
POWER SUPPLY CURRENTS
Current in Normal Mode (PSM0)
Current in PSM1
Current in PSM2
POWER SUPPLY CURRENTS
Current in Normal Mode (PSM0)
Min
Typ
Max
Unit
Test Conditions/Comments
4
2.1
1.6
3.2
5.3
4.25
mA
mA
mA
mA
3
3.9
mA
3.2
880
38
1.5
5.05
mA
μA
μA
μA
fCORE = 4.096 MHz, LCD and meter active
fCORE = 1.024 MHz, LCD and meter active
fCORE = 32.768 kHz, LCD and meter active
fCORE = 4.096 MHz, meter DSP active, metering ADC
powered down
fCORE = 4.096 MHz, metering ADC and DSP powered
down
fCORE = 4.096 MHz, LCD active, VBAT = 3.7 V
fCORE = 1.024 MHz, LCD active
LCD active at 3.3 V + RTC (real-time clock)
RTC only, TA = 25°C, VBAT = 3.3 V
4
5.3
mA
fCORE = 4.096 MHz, LCD and meter active
1
Endurance is qualified as per JEDEC Standard 22 Method A117 and measured at −40°C, +25°C, +85°C, and +125°C.
Retention lifetime equivalent at junction temperature (TJ) = 85°C as per JEDEC Standard 22 Method A117. Retention lifetime derates with junction temperature.
3
Test performed with all the I/Os set to a low output level.
4
Delay between power supply valid and execution of first instruction by 8052 core.
2
Rev. 0 | Page 8 of 128
ADE7518
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.
TIMING SPECIFICATIONS
AC inputs during testing were driven at VSWOUT − 0.5 V for Logic 1
and 0.45 V for Logic 0. Timing measurements were made at VIH
minimum for Logic 1 and VIL maximum for Logic 0, as shown in
Figure 2.
VLOAD – 0.1V
0.2VSWOUT + 0.9V
TEST POINTS
0.2VSWOUT – 0.1V
0.45V
VLOAD – 0.1V
TIMING
REFERENCE
POINTS
VLOAD
VLOAD + 0.1V
VLOAD
VLOAD – 0.1V
07327-002
VSWOUT – 0.5V
For Table 4 to Table 9, CLOAD = 80 pF for all outputs, VDD = 2.7 V to
3.6 V, and all specifications TMIN to TMAX, unless otherwise noted.
Figure 2. Timing Waveform Characteristics
Table 4. Clock Input (External Clock Driven XTAL1) Parameters
Parameter
tCK
tCKL
tCKH
tCKR
tCKF
1/tCORE
1
Description
XTAL1 period
XTAL1 width low
XTAL1 width high
XTAL1 rise time
XTAL1 fall time
Core clock frequency1
Min
0.032768
32.768 kHz External Crystal
Typ
Max
30.52
6.26
6.26
9
9
1.024
4.096
Unit
μs
μs
μs
ns
ns
MHz
The ADE7518 internal PLL locks onto a multiple (512 times) of the 32.768 kHz external crystal frequency to provide a stable 4.096 MHz internal clock for the system.
The core can operate at this frequency or at a binary submultiple defined by the CD[2:0] bits, selected via the POWCON SFR (see Table 24).
Table 5. I2C-Compatible Interface Timing Parameters (400 kHz)
Parameter
tBUF
tL
tH
tSHD
tDSU
tDHD
tRSU
tPSU
tR
tF
tSUP1
Typ
1.3
1.36
1.14
251.35
740
400
12.5
400
200
300
50
Unit
μs
μs
μs
μs
ns
ns
ns
ns
ns
ns
ns
Input filtering on both the SCLK and SDATA inputs suppresses noise spikes of less than 50 ns.
tBUF
tSUP
SDATA (I/O)
MSB
tDSU
tPSU
LSB
MSB
tDSU
8
2 TO 7
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. 0 | Page 9 of 128
tF
07327-003
1
Description
Bus-free time between stop condition and start condition
SCLK low pulse width
SCLK high pulse width
Start condition hold time
Data setup time
Data hold time
Setup time for repeated start
Stop condition setup time
Rise time of both SCLK and SDATA
Fall time of both SCLK and SDATA
Pulse width of spike suppressed
ADE7518
Table 6. SPI Master Mode Timing (SPICPHA = 1) Parameters
Parameter
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
Min
2SPIR × tCORE1
2SPIR × tCORE1
Typ
Max
3 × tCORE1
0
tCORE1
19
19
19
19
tCORE depends on the clock divider or CD[2:0] bits of the POWCON SFR (see Table 24); tCORE = 2CD/4.096 MHz.
SCLK
(SPICPOL = 0)
tSH
tSL
tSR
SCLK
(SPICPOL = 1)
tDAV
tDF
tSF
tDR
MOSI
MSB
MSB IN
MISO
tDSU
BITS [6:1]
BITS [6:1]
tDHD
Figure 4. SPI Master Mode Timing (SPICPHA = 1)
Rev. 0 | Page 10 of 128
LSB
LSB IN
07327-004
1
Description
SCLK low pulse width
SCLK high pulse width
Data output valid after SCLK edge
Data input setup time before SCLK edge
Data input hold time after SCLK edge
Data output fall time
Data output rise time
SCLK rise time
SCLK fall time
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ADE7518
Table 7. SPI Master Mode Timing (SPICPHA = 0) Parameters
Parameter
tSL
tSH
tDAV
tDOSU
tDSU
tDHD
tDF
tDR
tSR
tSF
Min
2SPIR × tCORE1
2SPIR × tCORE1
Typ
(SPIR + 1) × tCORE1
(SPIR + 1) × tCORE1
Max
3 × tCORE1
75
0
tCORE1
19
19
19
19
tCORE depends on the clock divider or CD[2:0] bits of the POWCON SFR (see Table 24); tCORE = 2CD/4.096 MHz.
SCLK
(SPICPOL = 0)
tSH
tSL
tSR
SCLK
(SPICPOL = 1)
tSF
tDAV
tDOSU
tDF
tDR
MOSI
MSB
MISO
MSB IN
tDSU
BITS [6:1]
BITS [6:1]
LSB
LSB IN
07327-005
1
Description
SCLK low pulse width
SCLK high pulse width
Data output valid after SCLK edge
Data output setup before SCLK edge
Data input setup time before SCLK edge
Data input hold time after SCLK edge
Data output fall time
Data output rise time
SCLK rise time
SCLK fall time
tDHD
Figure 5. SPI Master Mode Timing (SPICPHA = 0)
Rev. 0 | Page 11 of 128
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ADE7518
Table 8. SPI Slave Mode Timing (SPICPHA = 1) Parameters
Parameter
tSS
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
tSFS
Min
145
6 × tCORE1
6 × tCORE1
Typ
Max
25
0
2 × tCORE1 + 0.5
19
19
19
19
0
tCORE depends on the clock divider or CD[2:0] bits of the POWCON SFR (see Table 24); tCORE = 2CD/4.096 MHz.
SS
tSFS
tSS
SCLK
(SPICPOL = 0)
tSL
tSH
tSR
SCLK
(SPICPOL = 1)
tDAV
tDF
MSB
MISO
MOSI
MSB IN
tDSU
tDR
BITS [6:1]
BITS [6:1]
tDHD
Figure 6. SPI Slave Mode Timing (SPICPHA = 1)
Rev. 0 | Page 12 of 128
tSF
LSB
LSB IN
07327-006
1
Description
SS to SCLK edge
SCLK low pulse width
SCLK high pulse width
Data output valid after SCLK edge
Data input setup time before SCLK edge
Data input hold time after SCLK edge
Data output fall time
Data output rise time
SCLK rise time
SCLK fall time
SS high after SCLK edge
Unit
ns
ns
ns
ns
ns
μs
ns
ns
ns
ns
ns
ADE7518
Table 9. SPI Slave Mode Timing (SPICPHA = 0) Parameters
Parameter
tSS
tSL
tSH
tDAV
tDSU
tDHD
tDF
tDR
tSR
tSF
tDOSS
tSFS
Min
145
6 × tCORE1
6 × tCORE1
Typ
Max
25
0
2 × tCORE1 + 0.5
19
19
19
19
0
0
tCORE depends on the clock divider or CD[2:0] bits of the POWCON SFR (see Table 24); tCORE = 2CD/4.096 MHz.
SS
tSFS
tSS
SCLK
(SPICPOL = 0)
tSL
tSH
tSR
SCLK
(SPICPOL = 1)
tSF
tDAV
tDOSS
tDF
MSB
MISO
MOSI
BITS [6:1]
BITS [6:1]
MSB IN
tDSU
tDR
LSB
LSB IN
07327-007
1
Description
SS to SCLK edge
SCLK low pulse width
SCLK high pulse width
Data output valid after SCLK edge
Data input setup time before SCLK edge
Data input hold time after SCLK edge
Data output fall time
Data output rise time
SCLK rise time
SCLK fall time
Data output valid after SS edge
SS high after SCLK edge
tDHD
Figure 7. SPI Slave Mode Timing (SPICPHA = 0)
Rev. 0 | Page 13 of 128
Unit
ns
ns
ns
ns
ns
μs
ns
ns
ns
ns
ns
ns
ADE7518
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted.
Table 10.
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, IP,
and IN
Digital Input Voltage to DGND
Digital Output Voltage to DGND
Operating Temperature Range (Industrial)
Storage Temperature Range
64-Lead LQFP, Power Dissipation
Lead Temperature
Soldering
Time
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
THERMAL RESISTANCE
θJA is specified for the worst-case conditions, that is, a device
soldered in a circuit board for surface-mount packages.
−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
1W
300°C
30 sec
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; 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.
Table 11. Thermal Resistance
Package Type
64-Lead LQFP
ESD CAUTION
When used with external resistor divider.
Rev. 0 | Page 14 of 128
θJA
60
θJC
20.5
Unit
°C/W
ADE7518
VP
VN
EA
IP
IN
AGND
REFIN/OUT
RESET
FP26
VBAT
VINTA
VDD
VSWOUT
VINTD
DGND
VDCIN
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
COM3/FP27
1
COM2/FP28
2
COM1
48
INT0
47
XTAL1
3
46
XTAL2
COM0
4
45
BCTRL/INT1/P0.0
P1.2/FP25
5
44
SDEN/P2.3
P1.3/T2EX/FP24
6
43
P0.2/CF1/RTCCAL
P1.4/T2/FP23
7
42
8
ADE7518
P0.3/CF2
P1.5/FP22
41
P0.4/MOSI/SDATA
P1.6/FP21
9
TOP VIEW
(Not to Scale)
40
P0.5/MISO
39
P0.6/SCLK/T0
P0.1/FP19 11
38
P0.7/SS/T1
P2.0/FP18 12
37
P1.0/RxD
P2.1/FP17 13
36
P1.1/TxD
P2.2/FP16 14
35
FP0
LCDVC 15
34
FP1
LCDVP2 16
33
FP2
PIN 1
P1.7/FP20 10
07327-008
FP3
FP4
FP5
FP6
FP7
FP8
FP9
FP10
FP11
FP12
FP13
FP14
FP15
LCDVP1
LCDVA
LCDVB
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
Figure 8. Pin Configuration
Table 12. Pin Function Descriptions
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Mnemonic
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
16
17
LCDVP2
LCDVB
18
LCDVA
19
LCDVP1
35 to 20
36
FP0 to F15
P1.1/TxD
Description
Common Output 3 or LCD Segment Output 27. COM3 is used for LCD backplane.
Common Output 2 or LCD Segment Output 28. COM2 is used for LCD backplane.
Common Output 1. COM1 is used for LCD backplane.
Common Output 0. COM0 is used for LCD backplane.
General-Purpose Digital I/O Port 1.2 or LCD Segment Output 25.
General-Purpose Digital I/O Port 1.3, Timer 2 Control Input, or LCD Segment Output 24.
General-Purpose Digital I/O Port 1.4, Timer 2 Input, or LCD Segment Output 23.
General-Purpose Digital I/O Port 1.5 or LCD Segment Output 22.
General-Purpose Digital I/O Port 1.6 or LCD Segment Output 21.
General-Purpose Digital I/O Port 1.7 or LCD Segment Output 20.
General-Purpose Digital I/O Port 0.1 or LCD Segment Output 19.
General-Purpose Digital I/O Port 2.0 or LCD Segment Output 18.
General-Purpose Digital I/O Port 2.1 or LCD Segment Output 17.
General-Purpose Digital I/O Port 2.2 or LCD Segment Output 16.
This pin is internally connected to VDD. A resistor should be connected between LCDVC and LCDVB to
generate the top two voltages for the LCD waveforms (see the LCD Driver section).
This pin is internally connected to LCDVP1 (see the LCD Driver section).
This pin is an input voltage for the LCD driver. A resistor should be connected between LCDVB and LCDVC to
generate an intermediate voltage for the LCD driver. In 1/3 bias LCD mode, another resistor must be
connected between LCDVB and LCDVA to generate another intermediate voltage. In 1/2 bias LCD mode,
LCDVB and LCDVA are internally connected (see the LCD Driver section).
This pin is an input voltage for the LCD driver. A resistor should be connected between LCDVA and LCDVP1
to generate an intermediate voltage for the LCD driver. In 1/3 bias LCD mode, another resistor must be
connected between LCDVB and LCDVA to generate another intermediate voltage. In 1/2 bias LCD mode,
LCDVB and LCDVA are internally connected (see the LCD Driver section).
This pin is an input voltage for the LCD driver. A resistor should be connected between LCDVA and LCDVP1
to generate an intermediate voltage for the LCD driver. Another resistor must be connected between
LCDVP1 and DGND to generate another intermediate voltage (see the LCD Driver section).
LCD Segment Output 0 to LCD Segment Output 15.
General-Purpose Digital I/O Port 1.1 or Transmitter Data Output (Asynchronous).
Rev. 0 | Page 15 of 128
ADE7518
Pin No.
37
38
39
40
41
42
Mnemonic
P1.0/RxD
P0.7/SS/T1
P0.6/SCLK/T0
P0.5/MISO
P0.4/MOSI/SDATA
P0.3/CF2
43
P0.2/CF1/RTCCAL
44
SDEN/P2.3
45
BCTRL/INT1/P0.0
46
XTAL2
47
XTAL1
48
49, 50
INT0
VP, VN
51
EA
52, 53
IP, IN
54
55
56
57
AGND
FP26
RESET
REFIN/OUT
58
VBAT
59
VINTA
60
VDD
61
VSWOUT
62
VINTD
63
64
DGND
VDCIN
Description
General-Purpose Digital I/O Port 1.0 or Receiver Data Input (Asynchronous).
General-Purpose Digital I/O Port 0.7, Slave Select When SPI is in Slave Mode, or Timer 1 Input.
General-Purpose Digital I/O Port 0.6, Clock Output for I2C or SPI Port, or Timer 0 Input.
General-Purpose Digital I/O Port 0.5 or Data Input for SPI Port.
General-Purpose Digital I/O Port 0.4, Data Output for SPI Port, or I2C-Compatible Data Line.
General-Purpose Digital I/O Port 0.3 or Calibration Frequency Logic Output 2. The CF2 logic output gives
instantaneous active, reactive, Irms, or apparent power information.
General-Purpose Digital I/O Port 0.2, Calibration Frequency Logic Output 1, or RTC Calibration Frequency
Logic Output. The CF1 logic output gives instantaneous active, reactive, Irms, or apparent power information.
The RTCCAL logic output gives access to the calibrated RTC output.
Serial Download Mode Enable or Digital Output Port P2.3. This pin is used to enable serial download mode
through a resistor when pulled low on power-up or reset. On reset, this pin momentarily becomes an input
and the status of the pin is sampled. If there is no pull-down resistor in place, the pin momentarily goes high
and then user code is executed. If the pin is pulled down on reset, the embedded serial download/debug
kernel executes, and this pin remains low during the internal program execution. After reset, this pin can be
used as a digital output port pin (P2.3).
Digital Input for Battery Control, External Interrupt Input 1, or General-Purpose Digital I/O Port 0.0. This logic
input connects VDD or VBAT to VSWOUT internally when set to logic high or logic low, respectively. When left
open, the connection between VDD and VSWOUT or between VBAT and VSWOUT is selected internally.
A crystal can be connected across this pin and XTAL1 (see the XTAL1 pin description) to provide a clock
source for the ADE7518. The XTAL2 pin can drive one CMOS load when an external clock is supplied at XTAL1
or by the gate oscillator circuit. An internal 6 pF capacitor is connected to this pin.
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 ADE7518. The clock frequency for
specified operation is 32.768 kHz. An internal 6 pF capacitor is connected to this pin.
External Interrupt Input 0.
Analog Inputs for Voltage Channel. These inputs are fully differential voltage inputs with a maximum
differential level of ±400 mV for specified operation. This channel also has an internal PGA.
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 ADE7518 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 ±400 mV for specified operation. This channel also has an internal PGA.
This pin provides the ground reference for the analog circuitry.
LCD Segment Output 26.
Reset Input, Active Low.
This pin provides access to the on-chip voltage reference. The on-chip reference has a nominal value of
1.2 V ± 0.1% and a typical temperature coefficient of 50 ppm/°C maximum. This pin should be decoupled
with a 1 μF capacitor in parallel with a ceramic 100 nF capacitor.
Power Supply Input from the Battery with a 2.4 V to 2.7 V Range. This pin is connected internally to VDD when
the battery is selected as the power supply for the ADE7518.
This pin provides access to the on-chip 2.5 V analog LDO. No external active circuitry should be connected to
this pin. This pin should be decoupled with a 10 μF capacitor in parallel with a ceramic 100 nF capacitor.
3.3 V Power Supply Input from the Regulator. This pin is connected internally to VDD when the regulator is
selected as the power supply for the ADE7518. This pin should be decoupled with a 10 μF capacitor in
parallel with a ceramic 100 nF capacitor.
3.3 V Power Supply Output. This pin provides the supply voltage for the LDOs and internal circuitry of the
ADE7518. This pin should be decoupled with a 10 μF capacitor in parallel with a ceramic 100 nF capacitor.
This pin provides access to the on-chip 2.5 V digital LDO. No external active circuitry should be connected to
this pin. This pin should be decoupled with a 10 μF capacitor in parallel with a ceramic 100 nF 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 VSWOUT with respect to
AGND. This pin is used to monitor the preregulated dc voltage.
Rev. 0 | Page 16 of 128
ADE7518
TYPICAL PERFORMANCE CHARACTERISTICS
2.0
1.5
2.0
MID CLASS C
GAIN = 1
INTERNAL REFERENCE
1.0
ERROR (% of Reading)
ERROR (% of Reading)
1.0
0.5
GAIN = 1
INTERNAL REFERENCE
1.5
+85°C; PF = 1
+25°C; PF = 1
0
–40°C; PF = 1
–0.5
–1.0
–1.5
+85°C; PF = 0.866
+25°C; PF = 0.866
–40°C; PF = 0.866
0.5
0
+85°C; PF = 0
+25°C; PF = 0
–40°C; PF = 0
–0.5
–1.0
–1.5
1
10
100
CURRENT CHANNEL (% of Full Scale)
Figure 9. Active Energy Error as a Percentage of Reading (Gain = 1) over
Temperature with Internal Reference
1.5
–2.0
0.1
07327-009
–2.0
0.1
1.5
ERROR (% of Reading)
ERROR (% of Reading)
+25°C; PF = 0.5
+85°C; PF = 0.5
–40°C; PF = 0.5
MID CLASS C
GAIN = 1
INTERNAL REFERENCE
1.0
MID CLASS C
0
–0.5
100
2.0
1.0
+25°C; PF = 1
+85°C; PF = 1
–40°C; PF = 1
10
Figure 12. Reactive Energy Error as a Percentage of Reading (Gain = 1) over
Power Factor with Internal Reference
GAIN = 1
INTERNAL REFERENCE
0.5
1
CURRENT CHANNEL (% of Full Scale)
07327-012
MID CLASS C
MID CLASS C
–1.0
0.5
+25°C; PF = 1
+85°C; PF = 1
0
–40°C; PF = 1
–0.5
–1.0
–1.5
10
100
07327-010
1
CURRENT CHANNEL (% of Full Scale)
Figure 10. Active Energy Error as a Percentage of Reading (Gain = 1) over
Power Factor with Internal Reference
10
100
Figure 13. Current RMS Error as a Percentage of Reading (Gain = 1) over
Temperature with Internal Reference
2.0
GAIN = 1
INTERNAL REFERENCE
1.5
1.5
1.0
1.0
0.5
0
–0.5
1
CURRENT CHANNEL (% of Full Scale)
ERROR (% of Reading)
ERROR (% of Reading)
2.0
–2.0
0.1
07327-013
MID CLASS C
–1.5
0.1
+85°C; PF = 0
+25°C; PF = 0
–40°C; PF = 0
–1.0
GAIN = 1
INTERNAL REFERENCE
0.5
+25°C; PF = 1
+25°C; PF = 0.5
MID CLASS C
+85°C; PF = 1
+85°C; PF = 0.5
0
–0.5
–40°C; PF = 1
–40°C; PF = 0.5
–1.0
–1.5
–1.5
–2.0
0.1
–2.0
0.1
10
100
Figure 11. Reactive Energy Error as a Percentage of Reading (Gain = 1) over
Temperature with Internal Reference
1
10
CURRENT CHANNEL (% of Full Scale)
100
07327-014
1
CURRENT CHANNEL (% of Full Scale)
07327-011
MID CLASS C
Figure 14. Current RMS Error as a Percentage of Reading (Gain = 1) over
Power Factor with Internal Reference
Rev. 0 | Page 17 of 128
ADE7518
0.5
1.5
GAIN = 1
INTERNAL REFERENCE
0.4
1.0
0.2
Irms; 3.3V
0.1
Vrms; 3.3V
Irms; 3.43V
ERROR (% of Reading)
0.3
ERROR (% of Reading)
GAIN = 8
INTERNAL REFERENCE
Vrms; 3.43V
Vrms; 3.13V
0
–0.1
Irms; 3.13V
–0.2
–0.3
MID CLASS C
0.5
PF = 1
PF = –0.5
0
PF = +0.5
–0.5
MID CLASS C
–1.0
1
10
100
CURRENT CHANNEL (% of Full Scale)
Figure 15. Voltage and Current RMS Error as a Percentage of Reading (Gain = 1)
over Power Supply with Internal Reference
1.0
–1.5
0.1
07327-015
–0.5
0.1
GAIN = 8
0.8 INTERNAL REFERENCE
0.6
0.2
PF = 0.5
0
MID CLASS B
–0.2
–0.4
0
–0.2
–0.8
–0.8
45
50
55
60
65
70
Figure 16. Active Energy Error as a Percentage of Reading (Gain = 1) over
Frequency with Internal Reference
0.4
–1.0
0.1
10
100
Figure 19. Reactive Energy Error as a Percentage of Reading (Gain = 8) over
Power Factor with Internal Reference
1.5
GAIN = 8
INTERNAL REFERENCE
1.0
0.2
VAR; 3.3V
ERROR (% of Reading)
0.3
VAR; 3.43V
WATT; 3.3V
0
–0.1
1
CURRENT CHANNEL (% of Full Scale)
GAIN = 1
INTERNAL REFERENCE
0.1
PF = –0.5
–0.4
–0.6
40
PF = 1
PF = +0.5
0.2
–0.6
LINE FREQUENCY (Hz)
ERROR (% of Reading)
0.4
07327-019
ERROR (% of Reading)
PF = 1
07327-016
ERROR (% of Reading)
MID CLASS B
0.4
0.5
100
1.0
0.6
–1.0
10
Figure 18. Active Energy Error as a Percentage of Reading (Gain = 8) over
Power Factor with Internal Reference
GAIN = 1
INTERNAL REFERENCE
0.8
1
CURRENT CHANNEL (% of Full Scale)
07327-018
–0.4
VAR; 3.13V
WATT; 3.13V
WATT; 3.43V
–0.2
–0.3
MID CLASS C
0.5
PF = 1
PF = +0.5
0
–0.5
PF = –0.5
MID CLASS C
–1.0
1
10
CURRENT CHANNEL (% of Full Scale)
100
–1.5
0.1
07327-017
–0.5
0.1
Figure 17. Active and Reactive Energy Error as a Percentage of Reading (Gain = 1)
over Power Supply with Internal Reference
1
10
CURRENT CHANNEL (% of Full Scale)
100
07327-020
–0.4
Figure 20. Current RMS Error as a Percentage of Reading (Gain = 8) over
Power Factor with Internal Reference
Rev. 0 | Page 18 of 128
ADE7518
1.0
2.0
1.5
GAIN = 16
INTERNAL REFERENCE
MID CLASS C
0.8
GAIN = 16
INTERNAL REFERENCE
0.6
–40°C; PF = 0
+85°C; PF = 0
+85°C; PF = 0.866
–40°C; PF = 0.866
0.5
ERROR (% of Reading)
ERROR (% of Reading)
1.0
+25°C; PF = 1
0
–40°C; PF = 1
–0.5
+85°C; PF = 1
–1.0
0.4
0.2
0
+25°C; PF = 0.866
+25°C; PF = 0
–0.2
–0.4
–0.6
–1.5
10
100
CURRENT CHANNEL (% of Full Scale)
–1.0
0.1
07327-021
1
Figure 21. Active Energy Error as a Percentage of Reading (Gain = 16) over
Temperature with Internal Reference
MID CLASS C
1.5
ERROR (% of Reading)
0
+85°C; PF = 1
–40°C; PF = 1
–40°C; PF = 0.5
–0.5
–1.0
0.5
–40°C; PF = 1
0
+25°C; PF = 1
–0.5
+85°C; PF = 1
–1.0
–1.5
–1.5
MID CLASS C
MID CLASS C
1
10
100
CURRENT CHANNEL (% of Full Scale)
–2.0
0.1
07327-022
–2.0
0.1
Figure 22. Active Energy Error as a Percentage of Reading (Gain = 16) over
Power Factor with Internal Reference
1.5
GAIN = 16
INTERNAL REFERENCE
MID CLASS C
1.0
ERROR (% of Reading)
–0.2
100
2.0
+85°C; PF = 0
0.2
0
10
Figure 25. Current RMS Error as a Percentage of Reading (Gain = 16) over
Temperature with Internal Reference
GAIN = 16
INTERNAL REFERENCE
0.4
1
CURRENT CHANNEL (% of Full Scale)
0.6
ERROR (% of Reading)
MID CLASS C
07327-025
ERROR (% of Reading)
GAIN = 16
INTERNAL REFERENCE
1.0
+85°C; PF = 0.5
+25°C; PF = 1
+25°C; PF = 0.5
0.5
0.8
100
2.0
GAIN = 16
INTERNAL REFERENCE
1.0
1.0
10
Figure 24. Reactive Energy Error as a Percentage of Reading (Gain = 16) over
Power Factor with Internal Reference
2.0
1.5
1
CURRENT CHANNEL (% of Full Scale)
07327-024
–0.8
MID CLASS C
–2.0
0.1
–40°C; PF = 0
+25°C; PF = 0
–0.4
0.5
–40°C; PF = 1
+25°C; PF = 1
–40°C; PF = 0.5
0
–0.5
+85°C; PF = 0.5
+25°C; PF = 0.5
+85°C; PF = 1
–1.0
–0.6
–1.5
–0.8
1
10
CURRENT CHANNEL (% of Full Scale)
100
Figure 23. Reactive Energy Error as a Percentage of Reading (Gain = 16) over
Temperature with Internal Reference
1
10
CURRENT CHANNEL (% of Full Scale)
100
07327-026
MID CLASS C
–2.0
0.1
07327-023
–1.0
0.1
Figure 26. Current RMS Error as a Percentage of Reading (Gain = 16) over
Power Factor with Internal Reference
Rev. 0 | Page 19 of 128
ADE7518
TERMINOLOGY
Measurement Error
The error associated with the energy measurement made by the
ADE7518 is defined by the following formula:
Percentage Error =
⎛ Energy Register − True Energy ⎞
⎜
⎟ × 100%
⎜
⎟
True Energy
⎝
⎠
Phase Error Between Channels
The digital integrator and the high-pass filter (HPF) in the current
channel have a nonideal 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 (PSR)
PSR quantifies the ADE7518 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
ADC offset error is 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
Gain error is the difference between the measured ADC output
code (minus the offset) and the ideal output code (see the
Current Channel ADC section and the Voltage Channel ADC
section). It is measured for each of the gain settings on the
current channel (1, 2, 4, 8, and 16). The difference is expressed
as a percentage of the ideal code.
Rev. 0 | Page 20 of 128
ADE7518
SFR MAPPING
Table 13.
Mnemonic
INTPR
SCRATCH4
SCRATCH3
SCRATCH2
SCRATCH1
IPSMF
TEMPCAL
RTCCOMP
BATPR
PERIPH
B
LCDSEGE2
IPSME
SPISTAT
SPI2CSTAT
SPIMOD2
I2CADR
SPIMOD1
I2CMOD
WAV2H
WAV2M
WAV2L
WAV1H
WAV1M
WAV1L
ACC
MIRQSTH
MIRQSTM
MIRQSTL
MIRQENH
MIRQENM
MIRQENL
IRMSH
IRMSM
IRMSL
VRMSH
VRMSM
VRMSL
PSW
TH2
TL2
RCAP2H
RCAP2L
T2CON
EADRH
EADRL
POWCON
KYREG
WDCON
PROTR
Address
0xFF
0xFE
0xFD
0xFC
0xFB
0xF8
0xF7
0xF6
0xF5
0xF4
0xF0
0xED
0xEC
0xEA
0xEA
0xE9
0xE9
0xE8
0xE8
0xE7
0xE6
0xE5
0xE4
0xE3
0xE2
0xE0
0xDE
0xDD
0xDC
0xDB
0xDA
0xD9
0xD6
0xD5
0xD4
0xD3
0xD2
0xD1
0xD0
0xCD
0xCC
0xCB
0xCA
0xC8
0xC7
0xC6
0xC5
0xC1
0xC0
0xBF
Details
Table 15
Table 23
Table 22
Table 21
Table 20
Table 16
Table 116
Table 115
Table 17
Table 18
Table 45
Table 77
Table 19
Table 131
Table 135
Table 130
Table 134
Table 129
Table 133
Table 29
Table 29
Table 29
Table 29
Table 29
Table 29
Table 45
Table 39
Table 38
Table 37
Table 42
Table 41
Table 40
Table 29
Table 29
Table 29
Table 29
Table 29
Table 29
Table 46
Table 99
Table 100
Table 101
Table 102
Table 94
Table 89
Table 88
Table 24
Table 105
Table 65
Table 87
Mnemonic
PROTB1
PROTB0
EDATA
PROTKY
FLSHKY
ECON
IP
PINMAP2
PINMAP1
PINMAP0
LCDCONY
CFG
LCDDAT
LCDPTR
IEIP2
IE
DPCON
INTVAL
HOUR
MIN
SEC
HTHSEC
TIMECON
P2
EPCFG
SBAUDT
SBAUDF
LCDCONX
SPI2CRx
SPI2CTx
SBUF
SCON
LCDSEGE
LCDCLK
LCDCON
MDATH
MDATM
MDATL
MADDPT
P1
TH1
TH0
TL1
TL0
TMOD
TCON
PCON
DPH
DPL
SP
P0
Rev. 0 | Page 21 of 128
Address
0xBE
0xBD
0xBC
0xBB
0xBA
0xB9
0xB8
0xB4
0xB3
0xB2
0xB1
0xAF
0xAE
0xAC
0xA9
0xA8
0xA7
0xA6
0xA5
0xA4
0xA3
0xA2
0xA1
0xA0
0x9F
0x9E
0x9D
0x9C
0x9B
0x9A
0x99
0x98
0x97
0x96
0x95
0x94
0x93
0x92
0x91
0x90
0x8D
0x8C
0x8B
0x8A
0x89
0x88
0x87
0x83
0x82
0x81
0x80
Details
Table 86
Table 85
Table 84
Table 83
Table 82
Table 81
Table 59
Table 140
Table 139
Table 138
Table 70
Table 52
Table 76
Table 75
Table 60
Table 58
Table 56
Table 114
Table 113
Table 112
Table 111
Table 110
Table 109
Table 143
Table 137
Table 123
Table 124
Table 69
Table 128
Table 127
Table 122
Table 121
Table 74
Table 71
Table 68
Table 29
Table 29
Table 29
Table 29
Table 142
Table 97
Table 95
Table 98
Table 96
Table 92
Table 93
Table 47
Table 49
Table 48
Table 51
Table 141
ADE7518
POWER MANAGEMENT
The ADE7518 has elaborate power management circuitry that manages the regular power supply to battery switchover and power supply
failures. The power management functionalities can be accessed directly through the 8052 SFRs (see Table 14).
Table 14. Power Management SFRs
SFR Address
0xEC
0xF5
0xF8
0xFF
0xF4
0xC5
0xFB
0xFC
0xFD
0xFE
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Mnemonic
IPSME
BATPR
IPSMF
INTPR
PERIPH
POWCON
SCRATCH1
SCRATCH2
SCRATCH3
SCRATCH4
Description
Power Management Interrupt Enable. See Table 19.
Battery Switchover Configuration. See Table 17.
Power Management Interrupt Flag. See Table 16.
Interrupt Pins Configuration. See Table 15.
Peripheral Configuration SFR. See Table 18.
Power Control. See Table 24.
Scratch Pad 1. See Table 20.
Scratch Pad 2. See Table 21.
Scratch Pad 3. See Table 22.
Scratch Pad 4. See Table 23.
POWER MANAGEMENT REGISTER DETAILS
Table 15. Interrupt Pins Configuration SFR (INTPR, 0xFF)
Bit
7
Mnemonic
RTCCAL
Default
0
6 to 5
FSEL[1:0]
00
4
3 to 1
Reserved
INT1PRG[2:0]
N/A
000
Description
Controls the RTC calibration output. When this bit is set, the RTC calibration frequency selected by
FSEL[1:0] is output on the P0.2/CF1/RTCCAL pin.
Sets the RTC calibration output frequency and calibration window.
FSEL[1:0]
Result (Calibration Window, Frequency)
00
30.5 sec, 1 Hz
01
30.5 sec, 512 Hz
10
0.244 sec, 500 Hz
11
0.244 sec, 16.384 kHz
Controls the function of INT1.
INT1PRG[2:0]
x00
x01
01x
11x
0
INT0PRG
0
Result
GPIO enabled
BCTRL enabled
INT1 input disabled
INT1 input enabled
Controls the function of INT0.
INT0PRG
0
1
Result
INT0 input disabled
INT0 input enabled
Writing to the Interrupt Pins Configuration SFR (INTPR, 0xFF)
To protect the RTC from runaway code, a key must be written to the Key SFR (KYREG, 0xC1) to obtain write access to INTPR. KYREG
(see Table 105) should be set to 0xEA to unlock this SFR and then reset to zero after a timekeeping register is written to. The RTC
registers can be written using the following 8052 assembly code:
MOV
KYREG, #0EAh
MOV
INTPR, #080h
Rev. 0 | Page 22 of 128
ADE7518
Table 16. Power Management Interrupt Flag SFR (IPSMF, 0xF8)
Bit
7
Address
0xFF
Mnemonic
FPSR
Default
0
6
5
4
3
2
1
0
0xFE
0xFD
0xFC
0xFB
0xFA
0xF9
0xF8
FPSM
FSAG
Reserved
Reserved
Reserved
FBSO
FVDCIN
0
0
0
0
0
0
0
Description
Power Supply Restored Interrupt Flag. Set when the VDD power supply has been restored.
This occurs when the source of VSWOUT 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.
This bit must be kept cleared for proper operation.
This bit must be kept cleared for proper operation.
Battery Switchover Interrupt Flag. Set when VSWOUT switches from VDD to VBAT.
VDCIN Monitor Interrupt Flag. Set when VDCIN falls below 1.2 V.
Table 17. Battery Switchover Configuration SFR (BATPR, 0xF5)
Bit
7 to 2
1 to 0
Mnemonic
Reserved
BATPRG[1:0]
Default
0
00
Description
These bits must be kept to 0 for proper operation.
Control Bits for Battery Switchover.
BATPRG[1:0] Result
00
Battery switchover enabled on low VDD
01
Battery switchover enabled on low VDD and low VDCIN
1x
Battery switchover disabled
Table 18. Peripheral Configuration SFR (PERIPH, 0xF4)
Bit
7
6
5
4
Mnemonic
RXFLAG
VSWSOURCE
VDD_OK
PLL_FLT
Default
0
1
1
0
3
2
1 to 0
Reserved
Reserved
RXPROG[1:0]
0
0
00
Description
If set, indicates that an Rx edge event triggered wake-up from PSM2.
Indicates the power supply that is internally connected to VSWOUT (0 VSWOUT = VBAT, 1 VSWOUT = VDD).
If set, indicates that the VDD power supply is ready for operation.
If set, indicates that a PLL fault occurred where the PLL lost lock. Set the PLL_FTL_ACK bit (see
Table 107) in the Start ADC Measurement SFR (ADCGO, 0xD8) to acknowledge the fault and clear
the PLL_FLT bit.
This bit should be kept to 0.
This bit should be kept to 0.
Controls the function of the P1.0/RxD pin.
RXPROG[1:0] Result
00
GPIO
01
RxD with wake-up disabled
11
RxD with wake-up enabled
Table 19. Power Management Interrupt Enable SFR (IPSME, 0xEC)
Bit
7
6
5
4 to 2
1
0
Mnemonic
EPSR
Reserved
ESAG
Reserved
EBSO
EVDCIN
Default
0
0
0
0
0
0
Description
Enables a PSM interrupt when the power supply restored flag (FPSR) is set.
Reserved.
Enables a PSM interrupt when the voltage SAG flag (FSAG) is set.
These bits must be kept cleared for proper operation.
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 20. Scratch Pad 1 SFR (SCRATCH1, 0xFB)
Bit
7 to 0
Mnemonic
SCRATCH1
Default
0
Description
Value can be written/read in this register. This value is maintained in all the power saving modes.
Rev. 0 | Page 23 of 128
ADE7518
Table 21. Scratch Pad 2 SFR (SCRATCH2, 0xFC)
Bit
7 to 0
Mnemonic
SCRATCH2
Default
0
Description
Value can be written/read in this register. This value is maintained in all the power saving modes.
Table 22. Scratch Pad 3 SFR (SCRATCH3, 0xFD)
Bit
7 to 0
Mnemonic
SCRATCH3
Default
0
Description
Value can be written/read in this register. This value is maintained in all the power saving modes.
Table 23. Scratch Pad 4 SFR (SCRATCH4, 0xFE)
Bit
7 to 0
Mnemonic
SCRATCH4
Default
0
Description
Value can be written/read in this register. This value is maintained in all the power saving modes.
Clearing the Scratch Pad Registers (SCRATCH1, 0xFB to SCRATCH4, 0xFE)
Note that these scratch pad registers are only cleared when the part loses VDD and VBAT. They are not cleared by software, watchdog, or
PLL reset and, therefore, need to be set correctly in these situations.
Table 24. Power Control SFR (POWCON, 0xC5)
Bit
7
6
Mnemonic
Reserved
METER_OFF
Default
1
0
5
4
3
2 to 0
Reserved
COREOFF
Reserved
CD[2:0]
0
0
0
010
Description
Reserved.
Set this bit to turn off the modulators and energy metering DSP circuitry to reduce power if
metering functions are not needed in PSM0.
This bit should be kept at 0 for proper operation.
Set this bit to shut down the core and enter PSM2 if in PSM1 operating mode.
Reserved.
Controls the core clock frequency, fCORE. fCORE = 4.096 MHz/2CD.
CD[2:0]
Result (fCORE in MHz)
000
4.096
001
2.048
010
1.024
011
0.512
100
0.256
101
0.128
110
0.064
111
0.032
Writing to the Power Control SFR (POWCON, 0xC5)
Writing data to the POWCON SFR involves writing 0xA7 into the Key SFR (KYREG, 0xC1), which is described in Table 105, followed by
a write to the POWCON SFR. For example,
MOV KYREG,#0A7h
;Write KYREG to 0xA7 to get write access to the POWCON SFR
MOV POWCON,#10h
;Shutdown the core
Rev. 0 | Page 24 of 128
ADE7518
POWER SUPPLY ARCHITECTURE
The ADE7518 has two power supply inputs, VDD and VBAT, and
requires only a single 3.3 V power supply at VDD for full operation.
A battery backup, or secondary power supply, with a maximum
of 3.7 V, can be connected to the VBAT input. Internally, the
ADE7518 connects VDD or VBAT to VSWOUT, which is used to derive
power for the ADE7518 circuitry. The VSWOUT output pin reflects
the voltage at the internal power supply (VSWOUT) and has a
maximum output current of 6 mA. This pin can also be used
to power a limited number of peripheral components. The 2.5 V
analog supply (VINTA) and the 2.5 V supply for the core logic
(VINTD) are derived by on-chip linear regulators from VSWOUT.
Figure 27 shows the power supply architecture of ADE7518.
The ADE7518 provides automatic battery switchover between
VDD and VBAT based on the voltage level detected at VDD or VDCIN.
Additionally, the BCTRL input can be used to trigger a battery
switchover. The conditions for switching VSWOUT 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 0 V to
3.3 V dc signal. This input is intended for power supply supervisory purposes and does not provide power to the ADE7518
circuitry (see the Battery Switchover section).
VDCIN VDD
VBAT
VSWOUT
LDO
BCTRL
POWER SUPPLY
MANAGEMENT
VSW
LDO
VINTD
VINTA
MCU
The battery switchover functionality provided by the ADE7518
allows a seamless transition from VDD to VBAT. An automatic
battery switchover option ensures a stable power supply to the
ADE7518, as long as the external battery voltage is above 2.75 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 VSWOUT.
Power supply management (PSM) interrupts can be enabled to
indicate when battery switchover occurs and when the VDD
power supply is restored (see the Power Supply Management
(PSM) Interrupt section).
VDD to VBAT
The following three events switch the internal power supply
(VSWOUT) from VDD to VBAT:
•
•
•
ADE
SPI/I2C
SCRATCHPAD
LCD
RTC
3.3V
2.5V
07327-027
UART
Figure 27. Power Supply Architecture
BATTERY SWITCHOVER
Switching from VBAT to VDD
To switch VSWOUT from VBAT to VDD, all of the following events
that are enabled to force battery switchover must be false:
•
The ADE7518 monitors VDD, VBAT, and VDCIN. Automatic battery
switchover from VDD to VBAT can be configured based on the
status of the VDD, VDCIN, or 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 VSWOUT (see Table 17). The source of
VSWOUT is indicated by Bit 6 in the Peripheral Configuration SFR
(PERIPH, 0xF4), which is described in Table 18. Bit 6 is set
when VSWOUT is connected to VDD and cleared when VSWOUT is
connected to VBAT.
VDCIN < 1.2 V. When VDCIN falls below 1.2 V, VSWOUT switches
from VDD to VBAT. This event is enabled when the
BATPRG[1:0] bits in the Battery Switchover Configuration
SFR (BATPR, 0xF5) = 0b01. Setting these bits disables
switchover based on VDCIN. Battery switchover on low
VDCIN is disabled by default.
VDD < 2.75 V. When VDD falls below 2.75 V, VSWOUT switches
from VDD to VBAT. This event is enabled when BATPRG[1:0] in
the BATPR SRF are cleared.
Falling edge on BCTRL. When the battery control pin,
BCTRL, goes low, VSWOUT switches from VDD to VBAT. This
external switchover signal can trigger a switchover to VBAT
at any time. Setting the bits INT1PRG[2:0] to 0bx01 in the
Interrupt Pins Configuration SFR (INTPR, 0xFF) enables
the battery control pin (see Table 15).
•
•
Rev. 0 | Page 25 of 128
VDCIN < 1.2 V and VDD < 2.75 V enabled. If the low VDCIN
condition is enabled, VSWOUT switches to VDD after VDCIN
remains above 1.2 V and VDD remains above 2.75 V.
VDD < 2.75 V enabled. VSWOUT switches back to VDD after
VDD remains above 2.75 V.
BCTRL enabled. VSWOUT switches back to VDD after BCTRL
is high, and the first or second bullet point is satisfied.
ADE7518
The Power Management Interrupt Enable SFR (IPSME, 0xEC)
controls the events that result in a PSM interrupt (see Table 19).
Figure 28 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 IPSMF flag
register (see Table 16).
POWER SUPPLY MANAGEMENT (PSM) INTERRUPT
The power supply management (PSM) interrupt 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 (see Table 60).
EPSR
FPSR
ESAG
FSAG
FPSM
TRUE?
EPSM
PENDING PSM
INTERRUPT
EBSO
FBSO
IPSME ADDR. 0xEC
EPSR
RESERVED
ESAG
RESERVED
RESERVED
RESERVED
EBSO
EVDCIN
IPSMF ADDR. 0xF8
FPSR
FPSM
FSAG
RESERVED
RESERVED
RESERVED
FBSO
FVDCIN
IEIP2 ADDR. 0xA9
RESERVED
PTI
RESERVED
PSI
EADE
ETI
EPSM
ESI
NOT INVOLVED IN PSM INTERRUPT SIGNAL CHAIN
Figure 28. PSM Interrupt Sources
Rev. 0 | Page 26 of 128
07327-028
EVDCIN
FVDCIN
ADE7518
Battery Switchover and Power Supply Restored
PSM Interrupt
VDCIN Monitor PSM Interrupt
The ADE7518 can be configured to generate a PSM interrupt
when the source of VSWOUT 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 (see Table 19).
The ADE7518 can also be configured to generate an interrupt
when the source of VSWOUT changes from VBAT to VDD, indicating
that the VDD power supply has been restored. Setting the EPSR bit
in the Power Management Interrupt Enable SFR (IPSME, 0xEC)
enables this event to generate a PSM interrupt.
The flags in the IPSMF SFR for these interrupts, FBSO and
FPSR, are set regardless of whether the respective enable bits
have been set. The battery switchover and power supply restore
event flags, FBSO and FPSR, are latched. These events must be
cleared by writing 0 to these bits. Bit 6 in the Peripheral
Configuration SFR (PERIPH, 0xF4), VSWSOURCE, tracks the
source of VSWOUT. The bit is set when VSWOUT is connected to VDD
and cleared when VSWOUT is connected to VBAT.
The VDCIN voltage is monitored by a comparator. The FVDCIN
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 IPSME SFR enables this event to generate
a PSM interrupt. This event, which is associated with the SAG
monitoring, can be used to detect a power supply (VDD) being
compromised and to trigger further actions prior to deciding a
switch of VDD to VBAT.
SAG Monitor PSM Interrupt
The ADE7518 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 FSAG 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 the Line Voltage SAG Detection section for more information. Setting the ESAG bit in the Power Management Interrupt
Enable SFR (IPSME, 0xEC) enables this event to generate a
PSM interrupt.
Rev. 0 | Page 27 of 128
ADE7518
USING THE POWER SUPPLY FEATURES
In an energy meter application, the 3.3 V power supply (VDD)
is typically generated from the ac line voltage and regulated to
3.3 V by a voltage regulator IC. The preregulated dc voltage,
typically 5 V to 12 V, can be connected to VDCIN through a resistor divider. A 3.6 V battery can be connected to VBAT. Figure 29
shows how the ADE7518 power supply inputs are set up in this
application.
When a SAG event occurs, user code can be configured to back
up data and prepare for battery switchover if desired. The relative spacing of these interrupts depends on the design of the
power supply.
Figure 31 shows the sequence of events that occurs if the main
power supply starts to fail in the power meter application shown
in Figure 29, with battery switchover on low VDCIN or low VDD
enabled.
Finally, the transition between VDD and VBAT and the different
power supply modes (see the Operating Modes section) are
represented in Figure 32 and Figure 33.
Figure 30 shows the sequence of events that occurs if the main
power supply generated by the PSU starts to fail in the power
meter application shown in Figure 29. The SAG detection can
provide the earliest warning of a potential problem on VDD.
BCTRL 45
(240V, 220V, 110V TYPICAL)
AC INPUT
VP
49
SAG
DETECTION
VN
50
5V TO 12V DC
VDCIN
64
VOLTAGE
SUPERVISORY
VOLTAGE
SUPERVISORY
PSU
3.3V
REGULATOR
POWER SUPPLY
MANAGEMENT
IPSMF SFR
(ADDR. 0xF8)
VDD
60
VSW
VSWOUT 61
07327-029
VBAT 58
Figure 29. Power Supply Management for Energy Meter Application
VP – VN
SAG LEVEL TRIP POINT
SAGCYC = 1
VDCIN
1.2V
t1
VDD
2.75V
t2
VDCIN EVENT
(FVDCIN = 1)
IF SWITCHOVER ON LOW VDD IS ENABLED,
AUTOMATIC BATTERY SWITCHOVER
VSWOUT CONNECTED TO VBAT
BSO EVENT
(FBSO = 1)
Figure 30. Power Supply Management Interrupts and Battery Switchover with Only VDD Enabled for Battery Switchover
Rev. 0 | Page 28 of 128
07327-030
SAG EVENT
(FSAG = 1)
ADE7518
Table 25. Power Supply Event Timing Operating Modes
Parameter
t1
t2
t3
Time
10 ns min
10 ns min
30 ms typ
t4
130 ms typ
Description
Time between when VDCIN falls below 1.2 V and when FVDCIN is raised.
Time between when VDD falls below 2.75 V and when battery switchover occurs.
Time between when VDCIN falls below 1.2 V and when battery switchover occurs if VDCIN is enabled to cause
battery switchover.
Time between when power supply restore conditions are met (VDCIN above 1.2 V and VDD above 2.75 V if
BATPR[1:0] = 0b01 or VDD above 2.75 V if BATPR[1:0] = 0b00) and when VSWOUT switches to VDD.
VP – VN
SAG LEVEL TRIP POINT
SAGCYC = 1
VDCIN
1.2V
t3
t1
VDD
2.75V
VDCIN EVENT
(FVDCIN = 1)
IF SWITCHOVER ON LOW VDCIN IS
ENABLED, AUTOMATIC BATTERY
SWITCHOVER VSWOUT CONNECTED TO VBAT
BSO EVENT
(FBSO = 1)
Figure 31. Power Supply Management Interrupts and Battery Switchover with VDD or VDCIN Enabled for Battery Switchover
VP − VN
SAG LEVEL
TRIP POINT
VDCIN
SAG EVENT
VDCIN EVENT
VDCIN EVENT
1.2V
30ms MIN
130ms MIN
VBAT
VDD
2.75V
PSM0
BATTERY SWITCH
ENABLED ON
LOW VDCIN
VSW
BATTERY SWITCH
ENABLED ON
LOW VDD
PSM0
PSM1 OR PSM2
PSM0
PSM0
PSM1 OR PSM2
Figure 32. Power Supply Management Transitions Between Modes
Rev. 0 | Page 29 of 128
07327-032
VSW
07327-031
SAG EVENT
(FSAG = 1)
ADE7518
OPERATING MODES
PSM0 (NORMAL MODE)
PSM2 (SLEEP MODE)
In PSM0, normal operating mode, VSWOUT is connected to VDD.
All of the analog circuitry and digital circuitry powered by
VINTD and VINTA are enabled by default. In normal mode, the
default clock frequency, fCORE, established during a power-on
reset or software reset, is 1.024 MHz.
PSM2 is a low power consumption sleep mode for use in battery
operation. In this mode, VSWOUT is connected to VBAT. All of the
2.5 V digital and analog circuitry powered through VINTA and VINTD
are disabled, including the MCU core, resulting in the following:
PSM1 (BATTERY MODE)
In PSM1, battery mode, VSWOUT 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
automatically restarts, and the switch to the VDD power supply
occurs when the VDD supply is above 2.75 V and the PWRDN
bit in the MODE1 register (0x0B) is cleared (see Table 31). The
default fCORE for PSM1, established during a power-on reset or
software reset, is 1.024 MHz.
•
•
The RAM in the MCU is no longer valid.
The program counter for the 8052, also held in volatile
memory, becomes invalid when the 2.5 V supply is shut
down. Therefore, the program does not resume from
where it left off but always starts from the power-on reset
vector when the ADE7518 exits PSM2.
The 3.3 V peripherals (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 Table 27 for more information about the individual
peripherals and their PSM2 configuration). The ADE7518
remains in PSM2 until an event occurs to wake them up.
In PSM2, the ADE7518 provides four scratch pad RAM SFRs
that are maintained during this mode. These SFRs can be used
to save data from PSM0 or PSM1 when entering PSM2 (see
Table 20 to Table 23).
In PSM2, the ADE7518 maintains some SFRs (see Table 26).
The SFRs that are not listed in this table should be restored
when the part enters PSM0 or PSM1 from PSM2.
Table 26. SFRs Maintained in PSM2
I/O Configuration
Interrupt Pins Configuration SFR
(INTPR, 0xFF), see Table 15
Peripheral Configuration SFR
(PERIPH, 0xF4), see Table 18
Port 0 Weak Pull-Up Enable SFR
(PINMAP0, 0xB2), see Table 138
Port 1 Weak Pull-Up Enable SFR
(PINMAP1, 0xB3), see Table 139
Port 2 Weak Pull-Up Enable SFR
(PINMAP2, 0xB4), see Table 140
Scratch Pad 1 SFR
(SCRATCH1, 0xFB), see Table 20
Scratch Pad 2 SFR
(SCRATCH2, 0xFC), see Table 21
Scratch Pad 3 SFR
(SCRATCH3, 0xFD), see Table 22
Scratch Pad 4 SFR
(SCRATCH4, 0xFE), see Table 23
Power Supply Management
Battery Switchover Configuration
SFR (BATPR, 0xF5), see Table 17
RTC Peripherals
RTC Nominal Compensation SFR
(RTCCOMP, 0xF6), see Table 115
RTC Temperature Compensation
SFR (TEMPCAL, 0xF7),
see Table 116
RTC Configuration SFR
(TIMECON, 0xA1), see Table 109
Hundredths of a Second
Counter SFR
(HTHSEC, 0xA2), see Table 110
Seconds Counter SFR
(SEC, 0xA3), see Table 111
Minutes Counter SFR
(MIN, 0xA4), see Table 112
Hours Counter SFR
(HOUR, 0xA5), see Table 113
Alarm Interval SFR
(INTVAL, 0xA6), see Table 114
Rev. 0 | Page 30 of 128
LCD Peripherals
LCD Segment Enable 2 SFR
(LCDSEGE2, 0xED), see Table 77
LCD Configuration Y SFR
(LCDCONY, 0xB1), see Table 70
LCD Configuration X SFR
(LCDCONX, 0x9C), see Table 69
LCD Configuration SFR
(LCDCON, 0x95), see Table 68
LCD Clock SFR
(LCDCLK, 0x96), see Table 71
LCD Segment Enable SFR
(LCDSEGE, 0x97), see Table 74
LCD Pointer SFR
(LCDPTR, 0xAC), see Table 75
LCD Data SFR
(LCDDAT, 0xAE), see Table 76
ADE7518
3.3 V PERIPHERALS AND WAKE-UP EVENTS
Some of the 3.3 V peripherals are capable of waking the ADE7518
from PSM2. The events that can cause the ADE7518 to wake up
from PSM2 are listed in the Wake-Up Event column in Table 27.
The interrupt flag associated with these events must be cleared
prior to executing instructions that put the ADE7518 in PSM2
mode after wake-up.
Table 27. 3.3 V Peripherals and Wake-Up Events
3.3 V
Peripheral
Power Supply
Management
Wake-Up
Event
PSR
Wake-Up
Enable Bits
Nonmaskable
Flag
PSR
Interrupt
Vector
IPSM
RTC
Midnight
Nonmaskable
Midnight
IRTC
Alarm
Maskable
Alarm
IRTC
INT0
INT0PRG = 1
IE0
INT1
INT1PRG[2:0] =
11x
IE1
Rx Edge
RXPROG[1:0] =
11
RESET
Nonmaskable
I/O Ports1
External Reset
LCD
Scratch Pad
1
PERIPH[7]
(RXFLAG)
Comments
The ADE7518 wakes up if the power supply is restored (if
VSWOUT switches to be connected to VDD). The VSWSOURCE
flag, Bit 6 of the Peripheral Configuration SFR (PERIPH, 0xF4),
is set to indicate that VSWOUT is connected to VDD.
The ADE7518 wakes up at midnight every day to update its
calendars. The RTC interrupt needs to be serviced and
acknowledged prior to entering PSM2 mode.
An alarm can be set to wake the ADE7518 after the desired
amount of time. The RTC alarm is enabled by setting the
ALARM bit in the RTC Configuration SFR (TIMECON, 0xA1).
The RTC interrupt needs to be serviced and acknowledged
prior to entering PSM2 mode.
The edge of the interrupt is selected by Bit IT0 in the TCON
register. The IE0 flag bit in the TCON register is not affected.
The Interrupt 0 interrupt needs to be serviced and
acknowledged prior to entering PSM2 mode.
The edge of the interrupt is selected by Bit IT1 in the TCON
register. The IE1 flag bit in the TCON register is not affected.
The Interrupt 1 interrupt needs to be serviced and
acknowledged prior to entering PSM2 mode.
An Rx edge event occurs if a rising or falling edge is detected
on the Rx line. The UART RxD flag needs to be cleared prior
to entering PSM2 mode.
If the RESET pin is brought low while the ADE7518 is in
PSM2, the ADE7518 wakes up to PSM1.
The LCD can be enabled/disabled in PSM2. The LCD data
memory remains intact.
The four SCRATCHx registers remain intact in PSM2.
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 Pull-Up 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.
Rev. 0 | Page 31 of 128
ADE7518
TRANSITIONING BETWEEN OPERATING MODES
Automatic Switch to VDD (PSM1 to PSM0)
The operating mode of the ADE7518 is determined by the power
supply connected to VSWOUT. Therefore, changes in the power
supply, such as when VSWOUT switches from VDD to VBAT or when
VSWOUT switches to VDD, alter the operating mode. This section
describes events that change the operating mode.
If the conditions to switch VSWOUT from VBAT to VDD occur (see
the Battery Switchover section), the operating mode switches to
PSM0. When this switch occurs, the analog circuitry used in the
ADE energy measurement DSP automatically restarts. Note that
normal code execution continues. A software reset can be performed to start PSM0 code execution at the power-on reset vector.
Automatic Battery Switchover (PSM0 to PSM1)
USING THE POWER MANAGEMENT FEATURES
If any of the enabled battery switchover events occur (see the
Battery Switchover section), VSWOUT 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. To reduce power
consumption, the user code can initiate a transition to PSM2.
Because program flow is different for each operating mode, the
status of VSWOUT must be known at all times. The VSWSOURCE
bit in the Peripheral Configuration SFR (PERIPH, 0xF4) indicates
what VSWOUT is connected to (see Table 18). This bit can be used
to control program flow on wake-up. Because code execution
always starts at the power-on reset vector, Bit 6 of the PERIPH
SRF can be tested to determine which power supply is being
used and to branch to normal code execution or to wake up
event code execution. Power supply events can also occur when
the MCU core is active. To be aware of the events that change
what VSWOUT is connected to, use the following guidelines:
Entering Sleep Mode (PSM1 to PSM2)
To reduce power consumption when VSWOUT 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 3.3 V Peripherals and Wake-Up Events section).
•
Servicing Wake-Up Events (PSM2 to PSM1)
The ADE7518 may need to wake up from PSM2 to service
wake-up events (see the 3.3 V Peripherals and Wake-Up Events
section). PSM1 code execution begins at the power-on reset
vector. After servicing the wake-up event, the ADE7518 can be
returned to PSM2 by setting Bit 4 in the Power Control SFR
(POWCON, 0xC5) to shut down the MCU core.
•
Enable the battery switchover interrupt (EBSO)
if VSWOUT = VDD at power-up.
Enable the power supply restored interrupt (EPSR)
if VSWOUT = 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).
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. Battery switchover
occurs 30 ms later.
Automatic Switch to VDD (PSM2 to PSM0)
If the conditions to switch VSWOUT from VBAT to VDD occur (see
the Battery Switchover section), the operating mode switches to
PSM0. When this switch occurs, the MCU core and the analog
circuitry used in the ADE energy measurement DSP automatically
restart. PSM0 code execution begins at the power-on reset vector.
POWER SUPPLY
RESTORED
PSM0
NORMAL MODE
VSWOUT CONNECTED TO VDD
PSM1
AUTOMATIC BATTERY
SWITCHOVER
POWER SUPPLY
RESTORED
BATTERY MODE
VSWOUT CONNECTED TO VBAT
WAKE-UP
EVENT
USER CODE DIRECTS MCU
TO SHUT DOWN CORE AFTER
SERVICING WAKE-UP EVENT
Figure 33. Transitioning Between Operating Modes
Rev. 0 | Page 32 of 128
07327-033
PSM2
SLEEP MODE
VSWOUT CONNECTED TO VBAT
ADE7518
ENERGY MEASUREMENT
The ADE7518 offers a fixed function, energy measurement,
digital processing core that provides all the information needed
to measure energy in single-phase energy meters. The part
provides two ways to access the energy measurements: direct
access through SFRs for time sensitive information and indirect
access through address and data SFR registers for the majority
of energy measurements. The Irms, Vrms, interrupts, and waveform
registers are readily available through SFRs, as shown in Table 29.
Other energy measurement information is mapped to a page
of memory that is accessed indirectly through the MADDPT,
MDATL, MDATM, and MDATH SFRs. The address and data
registers act as pointers to the energy measurement internal
registers.
ACCESS TO ENERGY MEASUREMENT SFRs
Access to the energy measurement SFRs is achieved by reading
or writing to the SFR addresses detailed in Table 29. 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-byte
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 data from the previous latched sample.
Sample code to read the VRMSx register is as follows:
MOV
R1, VRMSH
MOV
R2, VRMSM
MOV
R3, VRMSL
;latches data in VRMSH,
VRMSM, and VRMSL SFRs
ACCESS TO INTERNAL ENERGY MEASUREMENT
REGISTERS
Access to the internal energy measurement registers is achieved
by writing to the Energy Measurement Pointer Address SFR
(MADDPT, 0x91). This SFR selects the energy measurement
register to be accessed and determines if a read or a write is
performed (see Table 28).
Table 28. Energy Measurement Pointer Address SFR
(MADDPT, 0x91)
Bit
7
6 to 0
Description
1 = write, 0 = read
Energy measurement internal register address
Writing to the Internal Energy Measurement Registers
When Bit 7 of the Energy Measurement Pointer Address SFR
(MADDPT, 0x91) is set, the contents of the MDATx SFRs
(MDATL, MDATM, and MDATH) are transferred to the internal
energy measurement register designated by the address in the
MADDPT SFR. If the internal register is 1 byte long, only the
MDATL SFR content is copied to the internal register, and the
MDATM SFR and MDATH SFR contents are ignored.
The energy measurement core functions with an internal clock
of 4.096 MHz ∕ 5, or 819.2 kHz. Because the 8052 core functions
with another clock, 4.096 MHz ∕ 2CD, synchronization between
the two clock environments when CD = 0 or 1 is an issue. When
data is written to the internal energy measurement registers, a
small wait period needs to be implemented before another read
or write to these registers can take place.
Sample code to write 0x0155 to the 2-byte SAGLVL register
located at 0x14 in the energy measurement memory space is
as follows:
MOV
MDATM,#01h
MOV
MDATL,#55h
MOV
MADDPT,#SAGLVL_W (Address 0x94)
MOV
A,#05h
DJNZ
ACC,$
;Next write or read to energy
measurement SFR can be done after
this.
Reading the Internal Energy Measurement Registers
When Bit 7 of Energy Measurement Pointer Address SFR
(MADDPT, 0x91) is cleared, the content of the internal energy
measurement register designated by the address in MADDPT
is transferred to the MDATx SFRs. If the internal register is
1 byte long, only the MDATL SFR content is updated with a
new value, whereas the MDATM SFR and MDATH SFR contents
are reset to 0x00.
The energy measurement core functions with an internal clock
of 4.096 MHz ∕ 5, or 819.2 kHz. Because the 8052 core functions
with another clock, 4.096 MHz ∕ 2CD, synchronization between
the two clock environments when CD = 0 or 1 is an issue. When
data is read from the internal energy measurement registers, a
small wait period needs to be implemented before the MDATx
SFRs are transferred to another SFR.
Sample code to read the peak voltage in the 2-byte VPKLVL
register located at 0x16 into the data pointer is as follows:
MOV
MADDPT,#VPKLVL_R (Address 0x16)
MOV
A,#05h
DJNZ
ACC,$
MOV
DPH,MDATM
MOV
DPL,MDATL
Rev. 0 | Page 33 of 128
ADE7518
Table 29. Energy Measurement SFRs
Address
0x91
0x92
0x93
0x94
0xD1
0xD2
0xD3
0xD4
0xD5
0xD6
0xD9
0xDA
0xDB
0xDC
0xDD
0xDE
0xE2
0xE3
0xE4
0xE5
0xE6
0xE7
R/W
R/W
R/W
R/W
R/W
R
R
R
R
R
R
R/W
R/W
R/W
R/W
R/W
R/W
R
R
R
R
R
R
IP
Description
Energy Measurement Pointer Address.
Energy Measurement Pointer Data Lowest Significant Byte.
Energy Measurement Pointer Data Middle Byte.
Energy Measurement Pointer Data Most Significant Byte.
Vrms Measurement Lowest Significant Byte.
Vrms Measurement Middle Byte.
Vrms Measurement Most Significant Byte.
Irms Measurement Lowest Significant Byte.
Irms Measurement Middle Byte.
Irms Measurement Most Significant Byte.
Energy Measurement Interrupt Enable Lowest Significant Byte.
Energy Measurement Interrupt Enable Middle Byte.
Energy Measurement Interrupt Enable Most Significant Byte.
Energy Measurement Interrupt Status Lowest Significant Byte.
Energy Measurement Interrupt Status Middle Byte.
Energy Measurement Interrupt Status Most Significant Byte.
Selection 1 Sample Lowest Significant Byte.
Selection 1 Sample Middle Byte.
Selection 1 Sample Most Significant Byte.
Selection 2 Sample Lowest Significant Byte.
Selection 2 Sample Middle Byte.
Selection 2 Sample Most Significant Byte.
×1, ×2, ×4,
×8, ×16
{GAIN[2:0]}
WGAIN[11:0]
MULTIPLIER
PGA1
I
Mnemonic
MADDPT
MDATL
MDATM
MDATH
VRMSL
VRMSM
VRMSH
IRMSL
IRMSM
IRMSH
MIRQENL
MIRQENM
MIRQENH
MIRQSTL
MIRQSTM
MIRQSTH
WAV1L
WAV1M
WAV1H
WAV2L
WAV2M
WAV2H
ADC
LPF2
HPF
CF1NUM[15:0]
IN
WATTOS[15:0]
π
2
PHCAL[7:0]
VARGAIN[11:0]
CF1
DFC
Ф
LPF2
CF1DEN[15:0]
IRMSOS[11:0]
VAROS[15:0]
CF2NUM[15:0]
VAGAIN[11:0]
VRMSOS[11:0]
VP
VN
PGA2
ADC
HPF
×2
CF2
DFC
LPF
VARDIV[7:0]
CF2DEN[15:0]
LPF
VADIV[7:0]
%
%
%
METERING SFRs
Figure 34. Energy Metering Block Diagram
Rev. 0 | Page 34 of 128
WDIV[7:0]
07327-034
×2
ADE7518
ENERGY MEASUREMENT REGISTERS
Table 30. Energy Measurement Register List
Address
MADDPT[6:0]
0x01
0x02
0x03
0x04
0x05
0x06
0x07
Mnemonic
WATTHR
RWATTHR
LWATTHR
VARHR
RVARHR
LVARHR
VAHR
R/W
R
R
R
R
R
R
R
Length
(Bits)
24
24
24
24
24
24
24
Signed/
Unsigned
S
S
S
S
S
S
S
Default
0
0
0
0
0
0
0
0x08
RVAHR
R
24
S
0
0x09
LVAHR
R
24
S
0
0x0A
PER_FREQ
R
16
U
0
0x0B
0x0C
0x0D
MODE1
MODE2
WAVMODE
R/W
R/W
R/W
8
8
8
U
U
U
0x06
0x40
0
0x0E
0x0F
NLMODE
ACCMODE
R/W
R/W
8
8
U
U
0
0
0x10
0x11
PHCAL
ZXTOUT
R/W
R/W
8
12
S
U
0x40
0x0FFF
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
0x18
0x19
0x1A
0x1B
0x1C
0x1D
0x1E
0x1F
0x20
0x21
0x22
0x23
0x24
0x25
0x26
0x27
0x28
IPEAK
RSTIPEAK
VPEAK
RSTVPEAK
GAIN
Reserved
WGAIN
VARGAIN
VAGAIN
WATTOS
VAROS
IRMSOS
VRMSOS
WDIV
VARDIV
VADIV
CF1NUM
CF1DEN
R
R
R
R
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
24
24
24
24
8
12
12
12
12
16
16
12
12
8
8
8
16
16
U
U
U
U
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
0
0
0
0
0x003F
Description
Reads Wh accumulator without reset.
Reads Wh accumulator with reset.
Reads Wh accumulator synchronous to line cycle.
Reads VARh accumulator without reset.
Reads VARh accumulator with reset.
Reads VARh accumulator synchronous to line cycle.
Reads VAh accumulator without reset. If the VARMSCFCON bit in
MODE2 register (0x0C) is set, this register accumulates Irms.
Reads VAh accumulator with reset. If the VARMSCFCON bit in
MODE2 register (0x0C) is set, this register accumulates Irms.
Reads VAh accumulator synchronous to line cycle. If the VARMSCFCON
bit in MODE2 register (0x0C) is set, this register accumulates Irms.
Reads line period or frequency register depending on MODE2
register.
Sets basic configuration of energy measurement (see Table 31).
Sets basic configuration of energy measurement (see Table 32).
Sets configuration of Waveform Sample 1 and Waveform Sample 2
(see Table 33).
Sets energy level of no load thresholds (see Table 34).
Sets configuration of WATT, VAR accumulation, and various tamper
alarms (see Table 35).
Sets phase calibration register (see the Phase Compensation section).
Sets timeout for zero-crossing timeout detection (see the ZeroCrossing Timeout section).
Sets number of half-line cycles for LWATTHR, LVARHR, and LVAHR
accumulators.
Sets number of half-line cycles for SAG detection (see the Line
Voltage SAG Detection section).
Sets detection level for SAG detection (see the Line Voltage SAG
Detection section).
Sets peak detection level for current peak detection (see the Peak
Detection section).
Sets peak detection level for voltage peak detection (see the Peak
Detection section).
Reads current peak level without reset (see the Peak Detection section).
Reads current peak level with reset (see the Peak Detection section).
Reads voltage peak level without reset (see the Peak Detection section).
Reads voltage peak level with reset (see the Peak Detection section).
Sets PGA gain of analog inputs (see Table 36).
Reserved.
Sets WATT gain register.
Sets VAR gain register.
Sets VA gain register.
Sets WATT offset register.
Sets VAR offset register.
Sets current rms offset register.
Sets voltage rms offset register.
Sets WATT energy scaling register.
Sets VAR energy scaling register.
Sets VA energy scaling register.
Sets CF1 numerator register.
Sets CF1 denominator register.
Rev. 0 | Page 35 of 128
ADE7518
Address
MADDPT[6:0]
0x29
0x2A
0x3B
0x3C
0x3D
0x3E
0x3F
Mnemonic
CF2NUM
CF2DEN
Reserved
Reserved
Reserved
Reserved
Reserved
Length
(Bits)
16
16
R/W
R/W
R/W
Signed/
Unsigned
U
U
Default
0
0x003F
0
0x0300
0
0
0
Description
Sets CF2 numerator register.
Sets CF2 denominator register.
This register must be kept at its default value for proper operation.
This register must be kept at its default value for proper operation.
This register must be kept at its default value for proper operation.
This register must be kept at its default value for proper operation.
This register must be kept at its default value for proper operation.
ENERGY MEASUREMENT INTERNAL REGISTERS DETAILS
Table 31. MODE1 Register (0x0B)
Bit
7
6
5
4
3
2
1
0
Mnemonic
SWRST
DISZXLPF
Reserved
SWAPBITS
PWRDN
DISCF2
DISCF1
DISHPF
Default
0
0
0
0
0
1
1
0
Description
Setting this bit resets all of the energy measurement registers to their default values.
Setting this bit disables the zero-crossing low-pass filter.
This bit must be kept at its default value for proper operation.
Setting this bit swaps CH1 ADC and CH2 ADC.
Setting this bit powers down voltage and current ADCs.
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 32. MODE2 Register (0x0C)
Bit
7 to 6
Mnemonic
CF2SEL[1:0]
Default
01
5 to 4
CF1SEL[1:0]
00
3
VARMSCFCON
0
2
1
ZXRMS
FREQSEL
0
0
WAVEN
0
Description
Configuration Bits for CF2 Output.
CF2SEL[1:0]
Result
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]
Result
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, CF2 Outputs, and VA Accumulation
Registers (VAHR, RVAHR, and LVAHR). Note that CF1 cannot be proportional to VA if CF2 is
proportional to Irms and vice versa.
VARMSCFCON Result
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.
Logic 1 enables update of rms values synchronously to Voltage ZX.
Configuration Bits to Select Period or Frequency Measurement for PER_FREQ Register (0x0A).
FREQSEL
Result
0
PER_FREQ register holds a period measurement.
1
PER_FREQ register holds a frequency measurement.
When this bit is set, the waveform sampling mode is enabled.
Rev. 0 | Page 36 of 128
ADE7518
Table 33. WAVMODE Register (0x0D)
Bit
7 to 5
Mnemonic
WAV2SEL[2:0]
Default
000
4 to 2
WAV1SEL[2:0]
000
1 to 0
DTRT[1:0]
00
Description
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 = fCORE/5 = 819.2 kHz)
00
25.6 kSPS (clock/32)
01
12.8 kSPS (clock/64)
10
6.4 kSPS (clock/128)
11
3.2 kSPS (clock/256)
Table 34. NLMODE Register (0x0E)
Bit
7
6
Mnemonic
DISVARCMP
IRMSNOLOAD
Default
0
0
5 to 4
VANOLOAD[1:0]
00
3 to 2
VARNOLOAD[1:0]
00
1 to 0
APNOLOAD[1:0]
00
Description
Setting this bit disables fundamental VAR gain compensation over line frequency.
Logic 1 enables Irms no load threshold detection. The level is defined by the setting of the
VANOLOAD bits.
Apparent Power No Load Threshold.
VANOLOAD[1:0]
Result
00
No load detection disabled
01
No load detection enabled with threshold = 0.030% of full scale
10
No load detection enabled with threshold = 0.015% of full scale
11
No load detection enabled with threshold = 0.0075% of full scale
Reactive Power No Load Threshold.
VARNOLOAD[1:0]
Result
00
No load detection disabled
01
No load detection enabled with threshold = 0.015% of full scale
10
No load detection enabled with threshold = 0.0075% of full scale
11
No load detection enabled with threshold = 0.0037% of full scale
Active Power No Load Threshold.
APNOLOAD[1:0]
Result
00
No load detection disabled
01
No load detection enabled with threshold = 0.015% of full scale
10
No load detection enabled with threshold = 0.0075% of full scale
11
No load detection enabled with threshold = 0.0037% of full scale
Rev. 0 | Page 37 of 128
ADE7518
Table 35. ACCMODE Register (0x0F)
Bit
7 to 6
5
Mnemonic
Reserved
VARSIGN
Default
0
0
4
APSIGN
0
3
2
ABSVARM
SAVARM
0
0
1
POAM
0
0
ABSAM
0
Description
These bits should be left at their default value for proper operation.
Configuration bit to select the event that triggers a reactive power sign interrupt. If set to 0, VARSIGN
interrupt occurs when reactive power changes from positive to negative. If this bit is set to 1, VARSIGN
interrupt occurs when reactive power changes from negative to positive.
Configuration bit to select event that triggers an active power sign interrupt. If set to 0, APSIGN
interrupt occurs when active power changes from positive to negative. If this bit is set to 1, APSIGN
interrupt occurs when active power changes from negative to positive.
Logic 1 enables absolute value accumulation of reactive power in energy register and pulse output.
Logic 1 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 (VARHR,
RVARHR, LVARHR) and the pulse output when connected to VAR.
Logic 1 enables positive-only accumulation of active power in the WATTHR energy register and
pulse output.
Logic 1 enables absolute value accumulation of active power in the WATTHR energy register and
pulse output.
Table 36. GAIN Register (0x1B)
Bit
7 to 5
Mnemonic
PGA2[2:0]
Default
000
4
3
Reserved
CFSIGN_OPT
0
0
2 to 0
PGA1[2:0]
000
Description
These bits define the voltage channel input gain.
PGA2[2:0]
Result
000
Gain = 1
001
Gain = 2
010
Gain = 4
011
Gain = 8
100
Gain = 16
Reserved.
This bit defines where the CF change of sign detection (APSIGN or VARSIGN) is implemented.
CFSIGN_OPT
Result
0
Filtered power signal
1
On a per CF pulse basis
These bits define the current channel input gain.
PGA1[2:0]
Result
000
Gain = 1
001
Gain = 2
010
Gain = 4
011
Gain = 8
100
Gain = 16
INTERRUPT STATUS/ENABLE SFRS
Table 37. Interrupt Status 1 SFR (MIRQSTL, 0xDC)
Bit
7
Interrupt Flag
ADEIRQFLAG
6
5
4
3
2
Reserved
Reserved
VARSIGN
APSIGN
VANOLOAD
1
0
RNOLOAD
APNOLOAD
Description
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.
Reserved.
Logic 1 indicates that the reactive power sign has changed according to the configuration of the ACCMODE register.
Logic 1 indicates that the active power sign has changed according to the configuration of the ACCMODE register.
Logic 1 indicates that an interrupt has been caused by an apparent power no load detection. This interrupt is
also used to reflect the part entering the Irms no load mode.
Logic 1 indicates that an interrupt has been caused by a reactive power no load detection.
Logic 1 indicates that an interrupt has been caused by an active power no load detection.
Rev. 0 | Page 38 of 128
ADE7518
Table 38. Interrupt Status 2 SFR (MIRQSTM, 0xDD)
Bit
7
Interrupt Flag
CF2
6
CF1
5
4
3
2
1
0
VAEOF
REOF
AEOF
VAEHF
REHF
AEHF
Description
Logic 1 indicates that a pulse on CF2 has been issued. The flag is set even if the CF2 pulse output is not
enabled by clearing Bit 2 of the MODE1 register.
Logic 1 indicates that a pulse on CF1 has been issued. The flag is set even if the CF1 pulse output is not
enabled by clearing Bit 1 of the MODE1 register.
Logic 1 indicates that the VAHR register has overflowed.
Logic 1 indicates that the VARHR register has overflowed.
Logic 1 indicates that the WATTHR register has overflowed.
Logic 1 indicates that the VAHR register is half full.
Logic 1 indicates that the VARHR register is half full.
Logic 1 indicates that the WATTHR register is half full.
Table 39. Interrupt Status 3 SFR (MIRQSTH, 0xDE)
Bit
7
6
5
4
3
2
1
0
Interrupt Flag
RESET
Reserved
WFSM
PKI
PKV
CYCEND
ZXTO
ZX
Description
Indicates the end of a reset (for both software and hardware reset).
Reserved.
Logic 1 indicates that new data is present in the waveform registers (Address 0xE2 to Address 0xE7).
Logic 1 indicates that the current channel has exceeded the IPKLVL value
Logic 1 indicates that the voltage channel has exceeded the VPKLVL value.
Logic 1 indicates the end of the energy accumulation over an integer number of half-line cycles.
Logic 1 indicates that no zero crossing on the line voltage happened for the last ZXTOUT half-line cycles.
Logic 1 indicates detection of a zero crossing in the voltage channel.
Table 40. Interrupt Enable 1 SFR (MIRQENL, 0xD9)
Bit
7 to 5
4
3
2
1
0
Interrupt Enable Bit
Reserved
VARSIGN
APSIGN
VANOLOAD
RNOLOAD
APNOLOAD
Description
Reserved.
When this bit is set, the VARSIGN flag set creates a pending ADE interrupt to the 8052 core.
When this bit is set, the APSIGN flag set creates a pending ADE interrupt to the 8052 core.
When this bit is set, the VANOLOAD flag set creates a pending ADE interrupt to the 8052 core.
When this bit is set, the RNOLOAD flag set creates a pending ADE interrupt to the 8052 core.
When this bit is set, the APNOLOAD flag set creates a pending ADE interrupt to the 8052 core.
Table 41. Interrupt Enable 2 SFR (MIRQENM, 0xDA)
Bit
7
6
5
4
3
2
1
0
Interrupt Enable Bit
CF2
CF1
VAEOF
REOF
AEOF
VAEHF
REHF
AEHF
Description
When this bit is set, a CF2 pulse creates a pending ADE interrupt to the 8052 core.
When this bit is set, a CF1 pulse 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 42. Interrupt Enable 3 SFR (MIRQENH, 0xDB)
Bit
7 to 6
5
4
3
2
1
0
Interrupt Enable Bit
Reserved
WFSM
PKI
PKV
CYCEND
ZXTO
ZX
Description
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.
Rev. 0 | Page 39 of 128
ADE7518
ANALOG INPUTS
The ADE7518 has two fully differential voltage input channels.
The maximum differential input voltage for input pairs VP/VN
and IP/IN is ±0.4 V.
6
5
0
0
0
GAIN[7:0]
4 3 2
0
0
0
1
0
0
0
GAIN (K)
SELECTION
VP
K × VIN
VIN
VN
07327-035
Each analog input channel has a programmable gain amplifier
(PGA) with possible gain selections of 1, 2, 4, 8, and 16. The
gain selections are made by writing to the GAIN register (see
Table 36 and Figure 36). Bit 0 to Bit 2 select the gain for the PGA
in the current channel, and Bit 5 to Bit 7 select the gain for the
PGA in the voltage channel. Figure 35 shows how a gain selection
for the current channel is made using the gain register.
7
Figure 35. PGA in Current Channel
GAIN REGISTER*
CURRENT AND VOLTAGE CHANNELS PGA CONTROL
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
PGA1 GAIN SELECT
000 = ×1
001 = ×2
010 = ×4
011 = ×8
100 = ×16
CFSIGN_OPT
RESERVED
*REGISTER CONTENTS SHOW POWER-ON DEFAULTS.
Figure 36. Analog Gain Register
Rev. 0 | Page 40 of 128
07327-036
PGA2 GAIN SELECT
000 = ×1
001 = ×2
010 = ×4
011 = ×8
100 = ×16
ADDR:
0x1B
ADE7518
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 37).
ANALOG-TO-DIGITAL CONVERSION
Each ADE7518 has two Σ-Δ analog-to-digital converters
(ADCs). The outputs of these ADCs are mapped directly to
waveform sampling SFRs (Address 0xE2 to Address 0xE7) and
are used for energy measurement internal digital signal processing.
In PSM1 (battery mode) and PSM2 (sleep mode), the ADCs are
powered down to minimize power consumption.
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 four is required 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 37.
For simplicity, the block diagram in Figure 38 shows a firstorder Σ-Δ ADC. The converter is made up of the Σ-Δ modulator
and the digital low-pass filter.
A Σ-Δ modulator converts the input signal into a continuous serial
stream of 1s and 0s at a rate determined by the sampling clock.
In the ADE7518, the sampling clock is equal to 4.096 MHz/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.
DIGITAL
FILTER
SIGNAL
ANTIALIAS
FILTER (RC)
SHAPED
NOISE
NOISE
For any given input value in a single sampling interval, the data
from the 1-bit ADC is virtually meaningless. A meaningful
result is obtained only when a large number of samples is
averaged. This averaging is carried into the second part of the
ADC, the digital low-pass filter. By averaging a large number of
bits from the modulator, the low-pass filter can produce 24-bit
data-words that are proportional to the input signal level.
0
2
409.6
FREQUENCY (kHz)
0
2
409.6
FREQUENCY (kHz)
Figure 37. Noise Reduction Due to Oversampling and
Noise Shaping in the Analog Modulator
INTEGRATOR
LATCHED
COMPARATOR
+
DIGITAL
LOW-PASS
FILTER
–
24
VREF
... 10100101 ...
1-BIT DAC
Figure 38. First-Order Σ-∆ ADC
Rev. 0 | Page 41 of 128
07327-038
C
819.2
07327-037
NOISE
MCLK/5
R
819.2
HIGH RESOLUTION
OUTPUT FROM DIGITAL
LPF
SIGNAL
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) that is many times higher than the bandwidth
of interest. For example, the sampling rate in the ADE7518 is
4.096 MHz/5, or 819.2 kHz, and the band of interest is 40 Hz to
2 kHz. Oversampling has the effect of spreading the quantization
ANALOG
LOW-PASS FILTER
SAMPLING
FREQUENCY
ADE7518
ALIASING EFFECTS
Figure 38 also shows an analog low-pass filter (RC) on the input
to the modulator. This filter is present to prevent aliasing, 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 39
illustrates the effect. Frequency components (the black arrows)
above half the sampling frequency (also known as the Nyquist
frequency, that is, 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 in Figure 39, only frequencies
near the sampling frequency (819.2 kHz) move into the band of
interest for metering (40 Hz to 2 kHz). This allows the use of a
very simple low-pass filter (LPF) 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 39). 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.
×1, ×2, ×4
×8, ×16
{GAIN[2:0]}
SAMPLING
FREQUENCY
IMAGE
FREQUENCIES
0
2
409.6
FREQUENCY (kHz)
Figure 39. ADC and Signal Processing in Current Channel Outline Dimensions
ADC Transfer Function
Both ADCs in the ADE7518 are designed to produce the same
output code for the same input signal level. With a full-scale
signal on the input of 0.4 V and an internal reference of 1.2 V,
the ADC output code is nominally 2,147,483, or 0x20C49B. 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 0.4 V not be exceeded.
Current Channel ADC
Figure 40 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 (4.096 MHz/160).
With the specified full-scale analog input signal of 0.4 V and
PGA1 = 1, the ADC produces an output code that is approximately
between 0x20C49B (+2,147,483d) and 0xDF3B65 (−2,147,483d).
For inputs of 0.25 V, 0.125 V, 82.6 mV, and 31.3 mV with PGA1 = 2,
4, 8, and 16, respectively, the ADC produces an output code that
is approximately between 0x28F5C2 (+2,684,354d) and 0xD70A3E
(–2,684,354d).
CURRENT RMS (I rms)
CALCULATION
REFERENCE
WAVEFORM SAMPLE
REGISTER
IP
PGA1
I
819.2
ADC
HPF
IN
ACTIVE AND REACTIVE
POWER CALCULATION
V1
0.25V, 0.125V,
62.5mV, 31.3mV
CURRENT CHANNEL
WAVEFORM
DATA RANGE
0V
0x28F5C2
0x000000
07327-040
ANALOG
INPUT
RANGE
07327-039
Antialiasing Filter
0xD70A3E
Figure 40. ADC and Signal Processing in Current Channel with PGA1 = 1, 2, 4, 8, or 16
Rev. 0 | Page 42 of 128
ADE7518
Voltage Channel ADC
Figure 41 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 maximum
of 25.6 kSPS (MCLK/160). The ADC produces an output code
that is approximately between 0x28F5 (+10,485d) and 0xD70B
(−10,485d).
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.
ACTIVE AND REACTIVE
POWER CALCULATION
HPF
PGA2
V2
REFERENCE
VOLTAGE RMS (Vrms)
CALCULATION
WAVEFORM SAMPLE
REGISTER
ADC
VN
0.5V, 0.25V,
0.125V, 62.5mV,
31.3mV
The ADE interrupt stays active until the WFSM status bit is
cleared (see the Energy Measurement Interrupts section).
VOLTAGE PEAK DETECT
V2
ZX DETECTION
LPF1
0V
VOLTAGE CHANNEL
WAVEFORM
DATA RANGE
ANALOG
INPUT
RANGE
0x28F5
f–3dB = 63.7Hz
MODE1[6]
ZX SIGNAL
DATA RANGE FOR 60Hz SIGNAL
0x1DD0
0x0000
0x0000
0xE230
0xD70B
ZX SIGNAL
DATA RANGE FOR 50Hz SIGNAL
0x2037
0x0000
0xDFC9
Figure 41. ADC and Signal Processing in Voltage Channel
Rev. 0 | Page 43 of 128
07327-041
VP
×1, ×2, ×4,
×8, ×16
{GAIN[7:5]}
When in waveform sampling mode, one of four output sample
rates can be chosen by using the DTRT[1:0] bits of the WAVMODE
register (see Table 33). The output sample rate can be 25.6 kSPS,
12.8 kSPS, 6.4 kSPS, or 3.2 kSPS. If the WFSM enable bit is set
in the Interrupt Enable 3 SFR (MIRQENH, 0xDB), the 8052
core has a pending ADE interrupt. The sampled signals selected
in the WAVMODE register are latched into the Waveform SFRs
when the waveform high byte (WAV1H or WAV2H) is read.
ADE7518
(MIRQSTH, 0xDE) and the ZXTO bit in the Interrupt Enable 3
SFR (MIRQENH, 0xDB) is set, the 8052 core has a pending
ADE interrupt.
POWER QUALITY MEASUREMENTS
Zero-Crossing Detection
Each ADE7518 has a zero-crossing detection circuit on the
voltage channel. This zero crossing is used to produce a zerocrossing internal signal (ZX) and is used in calibration mode.
The zero-crossing is generated by default from the output of
LPF1. This filter has a low cutoff frequency and is intended for
50 Hz and 60 Hz systems. 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 60 Hz and a time delay in ZX detection is
acceptable, it is recommended to enable LPF1. Enabling LPF1
limits the variability in the ZX detection by eliminating the high
frequency components. Figure 42 shows how the zero-crossing
signal is generated.
×1, ×2, ×4,
×8, ×16
VP
Figure 43 shows the mechanism of the zero-crossing timeout
detection when the line voltage stays at a fixed dc level for more
than MCLK/160 × ZXTOUT seconds.
12-BIT INTERNAL
REGISTER VALUE
ZXTOUT
REFERENCE
{GAIN[7:5]}
PGA2
V2
The ADE interrupt stays active until the ZXTO status bit is
cleared (see the Energy Measurement Interrupts section). The
ZXTOUT register (Address 0x11) can be written to or read from
the 8052 by the user (see the energy measurement register list in
Table 30). The resolution of the register is 160/MCLK seconds
per LSB. Thus, the maximum delay for an interrupt is 0.16 sec
(1/MCLK × 212) when MCLK = 4.096 MHz.
HPF
ADC 2
VOLTAGE
CHANNEL
VN
ZERO
CROSSING
ZX
ZXTO
FLAG
BIT
MODE1[6]
Figure 43. Zero-Crossing Timeout Detection
43.24° @ 60Hz
1.0
0.73
Period or Frequency Measurements
07327-042
ZX
V2
07327-043
LPF1
f–3dB = 63.7Hz
LPF1
Figure 42. Zero-Crossing Detection on the 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 zero-crossing detection also drives the ZX flag in the Interrupt
Status 3 SFR (MIRQSTH, 0xDE). If the ZX bit in the Interrupt
Enable 3 SFR (MIRQENH, 0xDB) is set, the 8052 core has a
pending ADE interrupt. The ADE interrupt stays active until
the ZX status bit is cleared (see the Energy Measurement
Interrupts section).
Zero-Crossing Timeout
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 in the Interrupt Status 3 SFR
The ADE7518 provides the period or frequency measurement
of the line. The period or frequency measurement is selected
by clearing or setting the FREQSEL bit in the MODE2 register
(0x0C). The period/frequency register, PER_FREQ register
(0x0A), is an unsigned 16-bit register that 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.
When the period measurement is selected, the measurement has a
2.44 μs/LSB (4.096 MHz/10) resolution, 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.
When the frequency measurement is selected, the measurement
has a 0.0625 Hz/LSB resolution when MCLK = 4.096 MHz,
which represents 0.104% when the line frequency is 60 Hz.
When the line frequency is 60 Hz, 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.
Rev. 0 | Page 44 of 128
ADE7518
V2
Line Voltage SAG Detection
In addition to detection of the loss of the line voltage signal
(zero crossing), the ADE7518 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 44.
VPKLVL[15:0]
PKV RESET
LOW WHEN
MIRQSTH SFR
IS READ
VOLTAGE CHANNEL
FULL SCALE
07327-045
PKV INTERRUPT
FLAG
SAGLVL[15:0]
RESET BIT PKV
IN MIRQSTH SFR
SAGCYC[7:0] = 0x04
3 LINE CYCLES
Figure 45. Peak Level Detection
07327-044
SAG FLAG
SAG RESET LOW
WHEN VOLTAGE
CHANNEL EXCEEDS
SAGLVL[15:0] AND
SAG FLAG RESET
Figure 44. SAG Detection
Figure 44 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, FSAG in the Power Management
Interrupt Flag SFR (IPSMF, 0xF8) is set at the end of the third
line cycle after the line voltage falls below the threshold. If the SAG
enable bit (ESAG) in the Power Management Interrupt Enable SFR
(IPSME, 0xEC) is set, the 8052 core has a pending power supply
management interrupt. The PSM interrupt stays active until the
ESAG bit is cleared (see the Power Supply Management (PSM)
Interrupt section).
In Figure 44, the SAG flag (FSAG) is set on the fifth line cycle
after the signal on the voltage channel first drops below the
threshold level.
SAG Level Set
The 2-byte contents of the SAG level register (SAGLVL, 0x14)
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 44). 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.
Peak Detection
The ADE7518 can also be programmed to detect when the
absolute value of the voltage or current channel exceeds a
specified peak value. Figure 45 illustrates the behavior of the
peak detection for the voltage channel. Both voltage and current
channels are monitored at the same time.
Figure 45 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 3 SFR
(MIRQSTH, 0xDE). If the PKV enable bit is set in the Interrupt
Enable 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 3 SFR (MIRQSTH, 0xDE).
The ADE interrupt stays active until the PKV or PKI status bit
is cleared (see the Energy Measurement Interrupts section).
Peak Level Set
The contents of the VPKLVL and IPKLVL registers are compared
to the absolute value of the voltage and the 2 MSBs of the current
channel, respectively. 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 puts the peak detection
level of the current channel 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 PKV bit is set in the Interrupt
Enable 3 SFR (MIRQENH, 0xDB), the 8052 core has a pending
ADE interrupt.
Peak Level Record
Each ADE7518 records the maximum absolute value reached by
the voltage and current channels in two different registers,
IPEAK and VPEAK, respectively. Each register is a 24-bit
unsigned register that is 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.
Rev. 0 | Page 45 of 128
ADE7518
PHASE COMPENSATION
RMS CALCULATION
The ADE7518 must work with transducers that can 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 to
perform accurate power calculations. The errors associated with
phase mismatch are particularly noticeable at low power factors.
The ADE7518 provides a means of digitally calibrating these
small phase errors. The part 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 only be used 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 root mean square (rms) value of a continuous signal V(t) is
defined as
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).
HPF
VP
1
PGA2
V
VN
7
0
1 0 0 1 0 1 1 1
V
0.1°
I
where V is the rms voltage.
LPF2
LPF3
V 2 (t ) = V 2
07327-047
V
Figure 47. RMS Signal Processing
The Irms signal can be read from the waveform register by setting
the WAVMODE register (0x0D) and setting the WFSM bit in
the Interrupt Enable 3 SFR (MIRQENH, 0xDB). Like the current
and voltage channels waveform sampling modes, the waveform
data is available at a sample rate of 25.6 kSPS, 12.8 kSPS, 6.4 kSPS,
or 3.2 kSPS.
V
I
60Hz
(3)
INPUT
PHCAL[7:0]
–231.93µs TO +48.83µs
60Hz
(2)
It is important to note that when the current input is larger than
40% of full scale, the Irms waveform sample register does not
represent the true processed rms value. 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.
CHANNEL 2 DELAY
REDUCED BY 4.48µs
(0.1°LEAD AT 60Hz)
0x0B IN PHCAL[7:0]
DELAY BLOCK
1.22µs/LSB
ADC 2
V (t ) = 2 × V sin(ωt )
V (t ) = √2 × V sin(ωt )
24
24
For time sampling signals, rms calculation involves squaring the
signal, taking the average, and obtaining the square root. The
ADE7518 implements this method by serially squaring the input,
averaging them, and then taking the square root of the average.
The averaging part of this signal processing is done by implementing a low-pass filter (LPF3 in Figure 47, Figure 48, and Figure 50).
This LPF has a −3 dB cutoff frequency of 2 Hz when MCLK =
4.096 MHz.
V 2 (t) = V 2 – V 2 cos (2ωt)
ADC 1
IN
0
07327-046
I
(1)
When this signal goes through LPF3, the cos(2ωt) term is attenuated and only the dc term Vrms2 goes through (shown as V2 in
Figure 47).
Figure 46 illustrates how the phase compensation is used to
remove a 0.1° phase lead in the current channel due to the
external transducer. To cancel the lead (0.1°) in the current
channel, a phase lead must also be introduced into the voltage
channel. The resolution of the phase adjustment allows the
introduction of a phase lead in increments of 0.026°. The phase
lead is achieved by introducing a time advance into the voltage
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 a
line frequency of 60 Hz (0x3C represents −4 because the register is
centered with 0 at 0x40).
PGA1
∫
1
× V 2 (t ) dt
T
V 2 (t ) = V 2 − V 2 cos(2ωt )
The PHCAL register is centered at 0x40, meaning that writing
0x40 to the register results in 0 delay. By changing this 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 a 1.22 μs (4.096 MHz/5) time delay or advance.
A line frequency of 60 Hz gives a phase resolution of 0.026° at
the fundamental (that is, 360° × 1.22 μs × 60 Hz).
IP
T
Vrms =
Figure 46. Phase Calibration
Rev. 0 | Page 46 of 128
ADE7518
Current Channel RMS Calculation
Each ADE7518 simultaneously calculates the rms values for the
current and voltage channels in different registers. Figure 48 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 waveform sampling
mode and 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
4.096 MHz/5. To minimize noise in the reading of the register,
the Irms register can also be configured to update only with the
zero crossing of the voltage input. This configuration is done by
setting the ZXRMS bit in the MODE2 register (0x0C).
With the different specified full-scale analog input signal PGA1
values, the ADC produces an output code that is approximately
±0d2,147,483 (PGA1 = 1) or ±0d2,684,354 (PGA1 = 2, 4, 8, or 16).
See the Current Channel ADC section. Similarly, the equivalent
rms value of a full-scale ac signal is 0d1,518,499 (0x172BA3)
when PGA = 1 and 0d1,898,124 (0x1CF68C) when PGA1 = 2,
4, 8, or 16. The current rms measurement provided in the
ADE7518 is accurate to within 0.5% for signal inputs between
full scale and full scale/500. The conversion from the register
value to amps must be done externally in the microprocessor
using an amps/LSB constant.
Current Channel RMS Offset Compensation
The ADE7518 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 can exist in the rms calculation due to
input noises that are integrated into the dc component of V2(t).
One LSB of the current channel rms offset is equivalent to
16,384 LSBs 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 from full scale.
I rms = Irms 0 2 + IRMSOS × 32,768
(4)
where Irms0 is the rms measurement without offset correction.
IRMSOS[11:0]
sgn 225 226 227
Irms(t)
218 217 216
0x00
HPF1
24
LPF3
+
24
Irms[23:0]
CURRENT CHANNEL
WAVEFORM
DATA RANGE
0x28F5C2
0x000000
07327-048
IP
HPF
0xD70A3E
Figure 48. Current Channel RMS Signal Processing with PGA1 = 1, 2, 4, 8, or 16
Rev. 0 | Page 47 of 128
ADE7518
Voltage Channel RMS Calculation
where:
v is the rms voltage.
i is the rms current.
Figure 50 shows details of the signal processing chain for the
rms calculation on the voltage channel. The voltage channel
rms value is processed from the samples used in the voltage
channel waveform sampling mode and is stored in the unsigned
24-bit Vrms register.
p (t ) = v (t ) × i (t )
p(t ) = VI − VI cos(2ωt )
The average power over an integral number of line cycles (n) is
given by the expression in Equation 9.
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 update only with the
zero crossing of the voltage input. This configuration is done
by setting the ZXRMS bit in the MODE2 register (0x0C).
P=
1
nT
nT
∫0
p(t )dt = VI
(9)
where:
T is the line cycle period.
P is referred to as the active or real power.
With the specified full-scale ac analog input signal of 0.4 V, the
output from the LPF1 in Figure 50 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 ADE7518 is accurate to within
±0.5% for signal input between full scale and full scale/20.
The conversion from the register value to volts must be done
externally in the microprocessor using a V/LSB constant.
Note that the active power is equal to the dc component of the
instantaneous power signal p(t) in Equation 9, that is, VI. This
is the relationship used to calculate active power in the ADE7518.
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 49.
Voltage Channel RMS Offset Compensation
INSTANTANEOUS
POWER SIGNAL
The ADE7518 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 can exist in the rms calculation due to input noises
and dc offset in the input samples. One LSB of the voltage
channel rms offset is equivalent to 64 LSBs 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
1 LSB of the voltage channel rms offset represents 3.37% of
measurement error at −60 dB down from full scale.
p(t) = v × i – v × i × cos(2ωt)
0x19999A
ACTIVE REAL POWER
SIGNAL = v × i
VI
0xCCCCD
0x00000
CURRENT
i(t) = √2 × i × sin(ωt)
(5)
where Vrms0 is the rms measurement without offset correction.
07327-050
Vrms = Vrms0 + 64 × VRMSOS
(8)
VOLTAGE
v(t) = √2 × v × sin(ωt)
ACTIVE POWER CALCULATION
Figure 49. Active Power Calculation
Active power is defined as the rate of energy flow from source
to load. It is 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 watt or joules/second. Equation 8 gives an
expression for the instantaneous power signal in an ac system.
v (t ) = 2 × V sin(ωt )
(6)
i (t ) = 2 × I sin(ωt )
(7)
Because LPF2 does not have an ideal brick wall frequency response
(see Figure 51), 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 of its
sinusoidal nature, the ripple is removed when the active power
signal is integrated to calculate energy (see the Active Energy
Calculation section).
VOLTAGE SIGNAL (V(t))
VRMSOS[11:0]
0x0
0xD70B
LPF1
sgn 216 215
28 27 26
LPF3
+
VOLTAGE CHANNEL
+
Figure 50. Voltage Channel RMS Signal Processing
Rev. 0 | Page 48 of 128
VRMSx[23:0]
0x28F5C2
0x00
07327-049
0x28F5
ADE7518
0
(838,861/1000). 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.
ATTENUATION (dB)
–4
–8
Active Power Sign Detection
–12
–16
–24
1
3
10
FREQUENCY (Hz)
30
100
07327-051
–20
Figure 51. Frequency Response of LPF2
Active Power Gain Calibration
Figure 52 shows the signal processing chain for the active
power calculation in the ADE7518. As explained previously,
the active power is calculated by filtering the output of the
multiplier with a low-pass filter. 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 10 shows how the gain adjustment is related to the
contents of the watt gain register.
⎛
⎧ WGAIN ⎫ ⎞
Output WGAIN = ⎜⎜ Active Power × ⎨1 +
⎬ ⎟⎟
212 ⎭ ⎠
⎩
⎝
(10)
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 watt gain register can be used to calibrate the
active power (or energy) calculation in the ADE7518.
Active Power Offset Calibration
The ADE7518 also incorporates an active power offset register
(WATTOS[15:0]). It is a signed, twos complement, 16-bit register
that can be used to remove offsets in the active power calculation
(see Figure 49). An offset can 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 ADE7518 detects a change of sign in the active power. The
APSIGN flag in the Interrupt Status 1 SFR (MIRQSTL, 0xDC)
records when a change of sign has occurred according to Bit
APSIGN in the ACCMODE register (0x0F). If the APSIGN flag
is set in the Interrupt Enable 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 the
Energy Measurement Interrupts section).
When APSIGN in the ACCMODE register (0x0F) is cleared
(default), the APSIGN flag in the Interrupt Status 1 SFR
(MIRQSTL, 0xDC) is set when a transition from positive to
negative active power has occurred.
If APSIGN in the ACCMODE register (0x0F) is set, the
APSIGN flag in the MIRQSTL SFR is set when a transition
from negative to positive active power occurs.
Active Power No Load Detection
The ADE7518 includes a no load threshold feature on the active
energy that eliminates any creep effects in the meter. The part
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 1 SFR (MIRQSTL, 0xDC) is set. If the APNOLOAD bit is
set in the Interrupt Enable 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 the Energy
Measurement Interrupts section).
The no load threshold level is selectable by setting the
APNOLOAD bits in the NLMODE register (0x0E). Setting
these bits to 0b00 disables the no load detection, and setting
them to 0b01, 0b10, or 0b11 sets the no load detection threshold
to 0.015%, 0.0075%, or 0.0037%, respectively, of the multiplier’s
full-scale output frequency. The IEC 62053-21 specification
states that the meter must start up with a load equal to or less
than 0.4% IP, which translates to 0.0167% of the full-scale
output frequency of the multiplier.
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 below full scale on the
current channel (1/1000 of the current channel full-scale input),
the average word value output from LPF2 is 838.861
Rev. 0 | Page 49 of 128
ADE7518
shows this discrete time integration or accumulation. The active
power signal in the waveform register is continuously added to
the internal active energy register.
ACTIVE ENERGY CALCULATION
As stated in the Active Power Calculation section, power is
defined as the rate of energy flow. This relationship can be
expressed mathematically in Equation 11.
P=
dE
dt
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 ADE7518 is set to be in the more
restrictive mode, the positive-only accumulation mode.
(11)
where:
P is power.
E is energy.
When POAM in the ACCMODE register (0x0F) is set, only positive power contributes to the active energy accumulation. When
ABSAM 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).
Conversely, energy is given as the integral of power.
E = ∫ P (t )dt
(12)
The ADE7518 achieves the integration of the active power signal by
continuously accumulating the active power signal in an internal,
nonreadable, 49-bit energy register. The active energy register
(WATTHR[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 13
expresses the relationship.
⎧∞
⎫
E = ∫ p (t ) dt = lim ⎨∑ p ( nT ) × T ⎬
t →0
=
1
n
⎩
⎭
The output of the multiplier is divided by the value in the
WDIV register. If the value in the WDIV register is equal to 0,
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 52, 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 3
SFR (MIRQENH, 0xDB). Like the current and voltage channels
waveform sampling modes, the waveform data is available at a
sample rate of 25.6 kSPS, 12.8 kSPS, 6.4 kSPS, or 3.2 kSPS.
(13)
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 ADE7518 is 1.22 μs (5/MCLK). In addition to
calculating the energy, this integration removes any sinusoidal
components that may be in the active power signal. Figure 52
FOR WAVEFORM
SAMPLING
23
WATTHR[23:0]
UPPER 24 BITS ARE
ACCESSIBLE THROUGH
WATTHR[23:0] REGISTER
0
WATTOS[15:0]
sgn 26 25
CURRENT
CHANNEL
LPF2
+
2–6 2–7 2–8
WDIV[7:0]
+
%
+
48
0
+
VOLTAGE
CHANNEL
WGAIN[11:0]
OUTPUTS FROM THE LPF2 ARE
ACCUMULATED (INTEGRATED) IN
THE INTERNAL ACTIVE ENERGY REGISTER
ACTIVE POWER
SIGNAL
WAVEFORM
REGISTER
VALUES
07327-052
5
MCLK
OUTPUT LPF2
T
TO
DIGITAL-TO-FREQUENCY
CONVERTER
TIME (nT)
Figure 52. Active Energy Calculation
Rev. 0 | Page 50 of 128
ADE7518
Figure 53 shows this energy accumulation for full-scale signals
(sinusoidal) on the analog inputs. The three displayed curves
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 ADE7518. As shown, the fastest
integration time occurs when the watt gain register is set to
maximum full scale, that is, 0x7FF.
WATTHR[23:0]
(15)
Active Energy Accumulation Modes
Watt-Signed Accumulation Mode
The ADE7518 active energy default accumulation mode is a
watt-signed accumulation based on the active power information.
The ADE7518 is placed in watt positive-only accumulation mode
by setting the POAM bit in the ACCMODE register (0x0F). In
this mode, the energy accumulation is only done for positive
power, ignoring any occurrence of negative power above or
below the no load threshold (see Figure 54). 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 detection of no load threshold
are active in this mode.
WGAIN = 0x7FF
WGAIN = 0x000
WGAIN = 0x800
0x3F,FFFF
3.41
Time = TimeWDIV = 0 × WDIV
Watt Positive-Only Accumulation Mode
0x7F,FFFF
0x00,0000
When WDIV is set to a value other than 0, the integration time
varies, as shown in Equation 15.
6.82
10.2
13.7
TIME (Minutes)
07327-053
0x40,0000
0x80,0000
Figure 53. Energy Register Rollover Time for Full-Scale Power
(Minimum and Maximum Power Gain)
Note that the energy register contents roll over to full-scale
negative (0x800000) and continue to increase in value when the
power or energy flow is positive (see Figure 53). Conversely, if
the power is negative, the energy register underflows to fullscale positive (0x7FFFFF) and continues to decrease in value.
ACTIVE ENERGY
NO LOAD
THRESHOLD
ACTIVE POWER
By using the interrupt enable register, the ADE7518 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.
NO LOAD
THRESHOLD
POS
As mentioned previously, the discrete time sample period (T)
for the accumulation register is 1.22 μs (5/MCLK). With fullscale sinusoidal signals on the analog inputs and the WGAIN
register set to 0x000, the average word value from each LPF2
is 0xCCCCD (see Figure 49). 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 when WDIV = 0 is calculated in the
following equation:
Time =
0 xFFFF, FFFF, FFFF
× 1.22 μs = 409.6 sec = 6.82 min (14)
0 xCCCCD
NEG
POS
INTERRUPT STATUS REGISTERS
07327-054
APSIGN FLAG
Integration Time Under Steady Load: Active Energy
Figure 54. Energy Accumulation in Positive-Only Accumulation Mode
Watt-Absolute Accumulation Mode
The ADE7518 is placed in watt-absolute accumulation mode by
setting the ABSAM bit in the ACCMODE register (0x0F). In this
mode, the energy accumulation is done using the absolute
active power, ignoring any occurrence of power below the no
load threshold (see Figure 55). 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 detection of a no load threshold are active in
this mode.
Rev. 0 | Page 51 of 128
ADE7518
Line Cycle Active Energy Accumulation Mode
In line cycle active energy accumulation mode, the energy
accumulation of the ADE7518 can be synchronized to the
voltage channel zero crossing so that active energy can be
accumulated over an integer 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 more quickly because
the integration period can be shortened. By using this mode,
the energy calibration can be greatly simplified, and the time
required to calibrate the meter can be significantly reduced.
ACTIVE ENERGY
NO LOAD
THRESHOLD
ACTIVE POWER
NO LOAD
THRESHOLD
In line cycle active energy accumulation mode, the ADE7518
accumulates the active power signal in the LWATTHR register
for an integral number of line cycles, as shown in Figure 56. The
number of half-line cycles is specified in the LINCYC register.
APNOLOAD
POS
NEG
POS
APNOLOAD
INTERRUPT STATUS REGISTERS
07327-055
APSIGN FLAG
The ADE7518 can accumulate active power for up to 65,535
half-line cycles. Because the active power is integrated on an
integer number of line cycles, the CYCEND flag in the Interrupt
Status 3 SFR (MIRQSTH, 0xDE) is set at the end of an active
energy accumulation line cycle. If the CYCEND enable bit in
the Interrupt Enable 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 the Energy
Measurement Interrupts section). Another calibration cycle
starts 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 is overwritten by a new value.
Figure 55. Energy Accumulation in Watt-Absolute Accumulation Mode
Active Energy Pulse Output
All of the ADE7518 circuitry has a pulse output whose frequency is
proportional to active power (see the Active Power Calculation
section). This pulse frequency output uses the calibrated signal
from the WGAIN register output, 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 in Figure 66.
TO
DIGITAL-TO-FREQUENCY
CONVERTER
WGAIN[11:0]
OUTPUT
FROM
LPF2
+
%
0
WDIV[7:0]
23
LPF1
FROM VOLTAGE
CHANNEL
ADC
48
ZERO-CROSSING
DETECTION
CALIBRATION
CONTROL
0
LWATTHR[23:0]
LINCYC[15:0]
Figure 56. Line Cycle Active Energy Accumulation
Rev. 0 | Page 52 of 128
ACTIVE ENERGY
IS ACCUMULATED IN
THE INTERNAL REGISTER,
AND THE LWATTHR
REGISTER IS UPDATED
AT THE END OF THE LINCYC
HALF-LINE CYCLES
07327-056
WATTOS[15:0]
+
ADE7518
When a new half-line cycle is written in the LINCYC register,
the LWATTHR register is reset, and a new accumulation starts
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 57). The line active energy
accumulation uses the same signal path as the active energy
accumulation. The LSB size of these two registers is equivalent.
v(t ) = 2 V sin(ωt + θ )
(19)
i(t ) = 2 I sin(ωt )
π
i ′(t ) = 2 I sin⎛⎜ ωt + ⎞⎟
2⎠
⎝
(20)
where:
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)
LWATTHR REGISTER
(21)
q(t) = VI sin (θ) + VI sin (2ωt + θ)
The average reactive power over an integer number of lines (n)
is given in Equation 22.
07327-057
CYCEND IRQ
LINCYC
VALUE
Q=
Figure 57. Energy Accumulation When LINCYC Changes
(16)
where:
n is an integer.
T is the line cycle period.
Because the sinusoidal component is integrated over an integer
number of line cycles, its value is always 0. Therefore,
nT
E = ∫ VIdt + 0
(17)
0
E(t) = VInT
nT
∫ q(t )dt = VI sin(θ)
(22)
0
where:
T is the line cycle period.
q is referred to as the reactive power.
From the information in Equation 8 and Equation 9,
⎧
⎫
⎪
⎪
nT
⎪
⎪nT
VI
E (t ) = ∫ VIdt − ⎨
cos(2πft )dt
2 ⎬∫
0
⎪
⎛ f ⎞ ⎪0
⎟ ⎪
⎪ 1+ ⎜
⎝ 8.9 ⎠ ⎭
⎩
1
nT
(18)
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 of over 65,535 half-line cycles. At
a 60 Hz line frequency, this translates to a total duration of
65,535/120 Hz = 546 sec.
REACTIVE POWER CALCULATION
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 21 gives an expression for the instantaneous reactive power signal in an ac system when the phase of
the current channel is shifted by 90°.
Note that the reactive power is equal to the dc component of
the instantaneous reactive power signal q(t) in Equation 21.
The instantaneous reactive power signal q(t) is generated by
multiplying the voltage and current channels. In this case, the
phase of the current channel is shifted by 90°. The dc component
of the instantaneous reactive power signal is then extracted by
a low-pass filter to obtain the reactive power information (see
Figure 58).
In addition, the phase-shifting filter has a nonunity magnitude
response. Because the phase-shifted filter has a large attenuation
at high frequency, the reactive power is primarily for 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 that of the active power calculation
(see the Energy Register Scaling section).
The frequency response of the LPF in the reactive signal path is
identical to the one used for LPF2 in the average active power
calculation. Because LPF2 does not have an ideal brick wall
frequency response (see Figure 51), 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.
The reactive power signal can be read from the waveform register
by setting the WAVMODE register (0x0D) and the WFSM bit in
the Interrupt Enable 3 SFR (MIRQENH, 0xDB). Like the current
and voltage channels waveform sampling modes, the waveform
data is available at a sample rate of 25.6 kSPS, 12.8 kSPS, 6.4 kSPS,
or 3.2 kSPS.
Rev. 0 | Page 53 of 128
ADE7518
Reactive Power Gain Calibration
Figure 58 shows the signal processing chain for the ADE7518
reactive power calculation. As explained in the Reactive Power
Calculation section, the reactive power is calculated by applying a
low-pass filter to 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 by writing a twos complement, 12-bit word
to the VAR gain register (VARGAIN[11:0]). Equation 23 shows
how the gain adjustment is related to the contents of the watt
gain register.
Output VARGAIN =
⎛
⎧ VARGAIN ⎫ ⎞
⎜ Reactive Power × ⎨1 +
⎬⎟
212
⎩
⎭⎠
⎝
(23)
The resolution of the VARGAIN register is the same as the
WGAIN register (see the Active Power Gain Calibration
section). VARGAIN can be used to calibrate the reactive
power (or energy) calculation in the ADE7518.
Reactive Power Offset Calibration
The ADE7518 also incorporates a reactive power offset register
(VAROS[15:0]). This is a signed, twos complement, 16-bit register
that can be used to remove offsets in the reactive power calculation
(see Figure 58). An offset may 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 WAVMODE 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 43 summarizes how the relationship of the phase difference
between the voltage and the current affects the sign of the resulting
VAR calculation.
Table 43. 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 ADE7518 detects a change of sign in the reactive power.
The VARSIGN flag in the Interrupt Status 1 SFR (MIRQSTL,
0xDC) records when a change of sign has occurred according
to the VARSIGN bit in the ACCMODE register (0x0F). If the
VARSIGN bit is set in the Interrupt Enable 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 the Energy Measurement Interrupts section).
When VARSIGN in the ACCMODE register (0x0F) is cleared
(default), the VARSIGN flag in the Interrupt Status 1 SFR
(MIRQSTL, 0xDC) is set when a transition from positive to
negative reactive power occurs.
If VARSIGN in the ACCMODE register (0x0F) is set, the
VARSIGN flag in the Interrupt Status 1 SFR (MIRQSTL,
0xDC) is set when a transition from negative to positive
reactive power occurs.
Reactive Power No Load Detection
The ADE7518 includes a no load threshold feature on the reactive
energy that eliminates any creep effects in the meter. The ADE7518
accomplishes this by not accumulating reactive energy when
the multiplier output is below the no load threshold. When the
reactive power is below the no load threshold, the RNOLOAD
flag in the Interrupt Status 1 SFR (MIRQSTL, 0xDC) is set. If the
RNOLOAD bit is set in the Interrupt Enable 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 the Energy Measurement Interrupts section).
The no load threshold level is selectable by setting the
VARNOLOAD bits in the NLMODE register (0x0E). Setting
these bits to 0b00 disables the no load detection, and setting
them to 0b01, 0b10, or 0b11 sets the no load detection threshold
to 0.015%, 0.0075%, and 0.0037% of the full-scale output
frequency of the multiplier, respectively.
REACTIVE ENERGY CALCULATION
As for reactive energy, the ADE7518 achieves the integration of
the reactive power signal by continuously accumulating the
reactive power signal in an internal, nonreadable, 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 ADE7518 is 1.22 μs (5/MCLK). As well as calculating the
energy, this integration removes any sinusoidal components
that may be in the active power signal. Figure 58 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 ADE7518 is set to be in the more
restrictive mode, the absolute accumulation mode.
Rev. 0 | Page 54 of 128
ADE7518
When SAVARM 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 from the
reactive energy accumulator (see the VAR Antitamper
Accumulation Mode section).
As shown in Figure 58, 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 3
SFR (MIRQENH, 0xDB). Like the current and voltage channel
waveform sampling modes, the waveform data is available at a
sample rate of 25.6 kSPS, 12.8 kSPS, 6.4 kSPS, or 3.2 kSPS.
When ABSVARM 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).
Figure 53 shows this energy accumulation for full-scale signals
(sinusoidal) on the analog inputs. These curves also apply for
the reactive energy accumulation.
The output of the multiplier is divided by VARDIV. If the value
in the VARDIV register is equal to 0, the internal reactive
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.
Note that the energy register contents roll over to full-scale
negative (0x800000) and continue to increase in value when
the power or energy flow is positive. Conversely, if the power is
negative, the reactive energy register underflows to full-scale
positive (0x7FFFFF) and continues to decrease in value.
By using the interrupt enable register, the ADE7518 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.
FOR WAVEFORM
SAMPLING
HPF
0
VAROS[15:0]
90° PHASE
SHIFTING FILTER
sgn 26 25
Π
2
LPF2
+
2–6 2–7 2–8
VARDIV[7:0]
+
%
+
48
0
+
PHCAL[7:0]
VARGAIN[11:0]
REACTIVE POWER
SIGNAL
TO
DIGITAL-TO-FREQUENCY
CONVERTER
T
5
MCLK
OUTPUTS FROM THE LPF2 ARE
ACCUMULATED (INTEGRATED) IN
THE INTERNAL REACTIVE ENERGY
REGISTER
WAVEFORM
REGISTER
VALUES
OUTPUT LPF2
VOLTAGE
CHANNEL
UPPER 24 BITS ARE
ACCESSIBLE THROUGH
VARHR[23:0] REGISTER
07327-058
CURRENT
CHANNEL
23
VARHR[23:0 ]
TIME (nT)
Figure 58. Reactive Energy Calculation
Rev. 0 | Page 55 of 128
ADE7518
Integration Time Under Steady Load: Reactive Energy
As mentioned in the Active Energy Calculation 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 VARGAIN and VARDIV registers set to
0x000, the integration time before the reactive energy register
overflows is calculated in Equation 24.
Time =
0xFFFF, FFFF, FFFF
× 1.22 μs = 409.6 sec = 6.82 min (24)
0xCCCCD
REACTIVE ENERGY
NO LOAD
THRESHOLD
REACTIVE POWER
When VARDIV is set to a value other than 0, the integration
time varies, as shown in Equation 25.
(25)
Reactive Energy Accumulation Modes
VAR-Signed Accumulation Mode
NO LOAD
THRESHOLD
The ADE7518 reactive energy default accumulation mode is a
signed accumulation based on the reactive power information.
ACTIVE POWER
VAR Antitamper Accumulation Mode
The ADE7518 is placed in VAR antitamper accumulation mode
by setting the SAVARM bit in the ACCMODE register (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
from the reactive energy accumulator (see Figure 59). 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.
NO LOAD
THRESHOLD
APSIGN FLAG
Rev. 0 | Page 56 of 128
POS
NEG
POS
INTERRUPT STATUS REGISTERS
Figure 59. Reactive Energy Accumulation in
Antitamper Accumulation Mode
07327-059
Time = TimeWDIV = 0 × VARDIV
NO LOAD
THRESHOLD
ADE7518
VAR Absolute Accumulation Mode
Line Cycle Reactive Energy Accumulation Mode
The ADE7518 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 by using the absolute reactive power and ignoring any
occurrence of power below the no load threshold for the active
energy (see Figure 60). The CF pulse also reflects this accumulation method when in absolute accumulation 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.
In line cycle reactive energy accumulation mode, the energy
accumulation of the ADE7518 can be synchronized to the
voltage channel zero crossing so that reactive energy can be
accumulated over an integer number of half-line cycles. The
advantage of this mode is similar to that described in the Line
Cycle Active Energy Accumulation Mode section.
In line cycle active energy accumulation mode, the ADE7518
accumulates the reactive power signal in the LVARHR register
for an integral number of line cycles, as shown in Figure 61. The
number of half-line cycles is specified in the LINCYC register.
The ADE7518 can accumulate active power for up to 65,535
half-line cycles.
Because the reactive power is integrated on an integer number
of line cycles, the CYCEND flag in the Interrupt Status 3 SFR
(MIRQSTH, 0xDE) is set at the end of an active energy accumulation line cycle. If the CYCEND enable bit in the Interrupt Enable 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 the Energy Measurement Interrupts
section). Another calibration cycle starts 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 is overwritten by a
new value.
REACTIVE ENERGY
NO LOAD
THRESHOLD
07327-060
REACTIVE POWER
NO LOAD
THRESHOLD
Figure 60. Reactive Energy Accumulation in Absolute Accumulation Mode
Reactive Energy Pulse Output
When a new half-line cycle is written in the LINCYC register,
the LVARHR register is reset, and a new accumulation starts 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. The line reactive energy accumulation
uses the same signal path as the reactive energy accumulation.
The LSB size of these two registers is equivalent.
The ADE7518 provides all the circuitry with a pulse output
whose frequency is proportional to reactive power (see the
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 preferably be connected to an
LED, as shown in Figure 66.
TO
DIGITAL-TO-FREQUENCY
CONVERTER
VARGAIN[11:0]
OUTPUT
FROM
LPF2
+
%
0
VARDIV[7:0]
23
LPF1
FROM VOLTAGE
CHANNEL ADC
48
ZERO-CROSSING
DETECTION
CALIBRATION
CONTROL
0
LVARHR[23:0]
LINCYC[15:0]
Figure 61. Line Cycle Reactive Energy Accumulation Mode
Rev. 0 | Page 57 of 128
REACTIVE ENERGY
IS ACCUMULATED IN
THE INTERNAL REGISTER,
AND THE LWATTHR
REGISTER IS UPDATED
AT THE END OF THE LINCYC
HALF-LINE CYCLES
07327-061
VAROS[15:0]
+
ADE7518
APPARENT POWER CALCULATION
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, respectively. Therefore, the apparent
power (AP) = Vrms × Irms. This equation is independent from the
phase angle between the current and the voltage.
Equation 29 gives an expression of the instantaneous power
signal in an ac system with a phase shift.
v(t ) = 2 Vrms sin(ω t )
(26)
i (t ) = 2 I rms sin(ωt + θ)
(27)
p (t ) = v (t ) × i (t )
(28)
p(t ) = Vrms I rms cos(θ) − Vrms I rms cos(2ωt + θ)
(29)
Figure 62 illustrates the signal processing for the calculation of
the apparent power in the ADE7518.
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 3 SFR (MIRQENH, 0xDB). Like the
current and voltage channel waveform sampling modes, the
waveform data is available at a sample rate of 25.6 kSPS, 12.8 kSPS,
6.4 kSPS, or 3.2 kSPS.
The gain of the apparent energy can be adjusted by using the
multiplier and by writing a twos complement, 12-bit word to the
VAGAIN register (VAGAIN[11:0]). Equation 30 shows how the
gain adjustment is related to the contents of the VAGAIN register.
Output VAGAIN =
⎛
⎧ VAGAIN ⎫ ⎞
⎜ Apparent Power × ⎨1 +
⎬⎟
2 12
⎩
⎭⎠
⎝
(30)
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 ADE7518.
Apparent Power Offset Calibration
Each rms measurement includes an offset compensation register to
calibrate and eliminate the dc component in the rms value (see the
Current Channel RMS Calculation section and the Voltage
Channel RMS Calculation section). The voltage and current
channels rms values are then multiplied together in the apparent power signal processing. Because 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.
VARMSCFCON
APPARENT POWER
SIGNAL (P)
Irms
0x1A36E2
CURRENT RMS SIGNAL – i(t)
0x1CF68C
0x00
VAGAIN
VOLTAGE RMS SIGNAL – v(t)
0x1CF68C
TO
DIGITAL-TO-FREQUENCY
CONVERTER
0x00
Figure 62. Apparent Power Signal Processing
Rev. 0 | Page 58 of 128
07327-062
Vrms
ADE7518
provided to read the apparent energy. This register is reset to 0
after a read operation.
APPARENT ENERGY CALCULATION
The apparent energy is given as the integer of the apparent power.
Apparent Energy = ∫ Apparent Power(t )dt
Note that the apparent energy register is unsigned. By setting
the VAEHF and VAEOF bits in the Interrupt Enable 2 SFR
(MIRQENM, 0xDA), the ADE7518 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.
(31)
The ADE7518 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 32
expresses the relationship.
Integration Times Under Steady Load: Apparent Energy
As mentioned in the Apparent Energy Calculation 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 the apparent power stage is 0x1A36E2 (see the
Apparent Power Calculation 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:
⎧∞
⎫
Apparent Energy = lim ⎨∑ Apparent Power ( nT ) × T ⎬ (32)
T →0
⎩n=0
⎭
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 ADE7518 is 1.22 μs (5/MCLK).
Figure 63 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 theoretically remains positive.
Time =
0xFFFF, FFFF, FFFF
× 1.22 μs = 199 sec = 3.33 min
0xD055
The 49 bits of the internal register are divided by VADIV. If the
value in the VADIV register is 0, 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]). The RVAHR register (24 bits long) is
When VADIV is set to a value other than 0, the integration time
varies, as shown in Equation 34.
Time = TimeWDIV = 0 × VADIV
23
VAHR[23:0]
0
48
0
VADIV
APPARENT POWER
or
Irms
%
48
+
0
+
APPARENT POWER OR Irms IS
ACCUMULATED (INTEGRATED)
IN THE APPARENT ENERGY
REGISTER
07327-063
APPARENT
POWER SIGNAL = P
T
(33)
TIME (nT)
Figure 63. Apparent Energy Calculation
Rev. 0 | Page 59 of 128
(34)
ADE7518
Apparent Energy Pulse Output
Apparent Power No Load Detection
All ADE7518 circuitry has a pulse output whose frequency is
proportional to apparent power (see the 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 whose frequency is proportional to Irms.
The ADE7518 includes a no load threshold feature on the
apparent power that eliminates any creep effects in the meter.
The ADE7518 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 1 SFR (MIRQSTL, 0xDC) is set.
If the VANOLOAD bit is set in the Interrupt Enable 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 the Energy Measurement Interrupts section).
The pulse output is active low and should preferably be connected
to an LED, as shown in Figure 66.
Line Apparent Energy Accumulation
The ADE7518 is designed with a special apparent energy
accumulation mode that simplifies the calibration process.
By using the on-chip zero-crossing detection, the ADE7518
accumulates the apparent power signal in the LVAHR register
for an integral number of half cycles, as shown in Figure 64. Line
apparent energy accumulation mode is always active.
The no load threshold level is selectable by setting the
VANOLOAD bits in the NLMODE register (0x0E). Setting
these bits to 0b00 disables the no load detection, and setting
them to 0b01, 0b10, or 0b11 sets the no load detection threshold
to 0.030%, 0.015%, and 0.0075% of the full-scale output frequency of the multiplier, respectively.
The number of half-line cycles is specified in the LINCYC register, which is an unsigned 16-bit register. The ADE7518 can
accumulate apparent power for up to 65,535 combined half
cycles. Because the apparent power is integrated on the same
integral number of line cycles as the line active register and
reactive energy register, these values can easily be compared.
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.
This no load threshold can also be applied to the Irms pulse
output when selected. In this case, the level of no load threshold
is the same as for the apparent energy.
AMPERE-HOUR ACCUMULATION
In a tampering situation where no voltage is available to the
energy meter, the ADE7518 is capable of accumulating the
ampere-hour instead of apparent power into VAHR, RVAHR, and
LVAHR. When Bit 3 (VARMSCFCON) of the MODE2 register
(0x0C) is set, VAHR, RVAHR, LVAHR, and the input for the
digital-to-frequency converter accumulate Irms instead of
apparent power. All the signal processing and calibration
registers available for apparent power and energy accumulation
remain the same when ampere-hour accumulation is selected.
However, the scaling difference between Irms and apparent
power requires independent values for gain calibration in the
VAGAIN, VADIV, CFxNUM, and CFxDEN registers.
At the end of an energy calibration cycle, the CYCEND flag
in the Interrupt Status 3 SFR (MIRQSTH, 0xDE) is set. If the
CYCEND enable bit in the Interrupt Enable 3 SFR (MIRQENH,
0xDB) is enabled, the 8052 core has a pending ADE interrupt.
As for LWATTHR, when a new half-line cycle is written
in the LINCYC register, the LVAHR register is reset and a new
accumulation starts 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. The
line apparent energy accumulation uses the same signal path as
the apparent energy accumulation. The LSB size of these two
registers is equivalent.
+
%
+
48
0
LVAHR REGISTER IS
UPDATED EVERY LINCYC
ZERO CROSSING WITH THE
TOTAL APPARENT ENERGY
DURING THAT DURATION
VADIV[7:0]
23
LPF1
FROM
VOLTAGE CHANNEL
ADC
ZERO-CROSSING
DETECTION
CALIBRATION
CONTROL
0
LVAHR[23:0]
LINCYC[15:0]
Figure 64. Line Cycle Apparent Energy Accumulation
Rev. 0 | Page 60 of 128
07327-064
APPARENT POWER
or Irms
ADE7518
ENERGY-TO-FREQUENCY CONVERSION
Pulse Output Configuration
The ADE7518 also provides two energy-to-frequency conversions
for calibration purposes. After initial calibration at manufacturing,
the manufacturer or end customer often verifies the energy
meter calibration. One convenient way to do this is for the
manufacturer to provide an output frequency that is proportional to the active power, reactive power, 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 65 illustrates the energyto-frequency conversion in the ADE7518.
The two pulse output circuits have separate configuration bits
in the MODE2 register (0x0C). Setting the CFxSEL bits to
0b00, 0b01, or 0b1x configures the DFC to create a pulse output
proportional to active power, to reactive power, or to apparent
power or Irms, respectively.
MODE 2 REGISTER 0x0C
Pulse Output Characteristic
VARMSCFCON CFxSEL[1:0]
Irms
The pulse output for both DFCs stays low for 90 ms if the pulse
period is longer than 180 ms (5.56 Hz). If the pulse period is
shorter than 180 ms, the duty cycle of the pulse output is 50%.
The pulse output is active low and should preferably be connected
to an LED, as shown in Figure 66.
CFxNUM
DFC
WATT
÷
CFx PULSE
OUTPUT
VDD
07327-065
VA
VAR
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 CF1 cannot be proportional to apparent
power if CF2 is proportional to Irms.
CFxDEN
CF
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 a CFxNUM/CFxDEN number
of pulses are generated at the DFC output. Under steady load
conditions, the output frequency is proportional to the active
power, reactive power, apparent power, or Irms, depending on
the CFxSEL bits in the MODE2 register (0x0C).
Both pulse outputs can be enabled or disabled by clearing or
setting Bit DISCF1 and Bit DISCF2 in the MODE1 register
(0x0B), respectively.
Both pulse outputs set separate flags in the Interrupt Status 2 SFR
(MIRQSTM, 0xDD), CF1 and CF2. If the CF1 and CF2 enable
bits in the Interrupt Enable 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 the
Energy Measurement Interrupts section).
07327-066
Figure 65. Energy-to-Frequency Conversion
Figure 66. 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 ADE7518 incorporates two registers per DFC, CFxNUM[15:0]
and CFxDEN[15:0], to set the CFx frequency. These are unsigned
16-bit registers that can be used to adjust the CFx frequency to
a wide range of values. These frequency scaling registers are
16-bit registers that can scale the output frequency by 1/216 to 1
with a step of 1/216.
If 0 is written to any of these registers, 1 is applied to the register. The ratio CFxNUM/CFxDEN should be less than 1 to
ensure proper operation. If the ratio of the CFxNUM/CFxDEN
registers is greater than 1, the register values are adjusted to a
ratio of 1. For example, if the output frequency is 1.562 kHz and
the content of CFxDEN is 0 (0x000), the output frequency can
be set to 6.1 Hz by writing 0xFF to the CFxDEN register.
Rev. 0 | Page 61 of 128
ADE7518
ENERGY REGISTER SCALING
ENERGY MEASUREMENT INTERRUPTS
The ADE7518 provides measurements of active, reactive, and
apparent energies that use separate paths and filtering for calculation. The difference in data paths may result in small differences
in LSB weight between active, reactive, and apparent energy
registers. These measurements are internally compensated so that
the scaling is nearly one to one. The relationship between these
registers is shown in Table 44.
The energy measurement part of the ADE7518 has its own
interrupt vector for the 8052 core, Vector Address 0x004B (see
the Interrupt Vectors section). The bits set in the Interrupt
Enable 1 SFR (MIRQENL, 0xD9), Interrupt Enable 2 SFR
(MIRQENM, 0xDA), and Interrupt Enable 3 SFR (MIRQENH,
0xDB) enable the energy measurement interrupts that are
allowed to interrupt the 8052 core. If an event is not enabled,
it cannot create a system interrupt.
Table 44. Energy Registers Scaling
Line Frequency = 50 Hz
VAR = 0.9952 × WATT
VA = 0.9978 × WATT
VAR = 0.9997 × WATT
VA = 0.9977 × WATT
Line Frequency = 60 Hz
VAR = 0.9949 × WATT
VA = 1.0015 × WATT
VAR = 0.9999 × WATT
VA = 1.0015 × WATT
Integrator
Off
Off
On
On
The ADE interrupt stays active until the status bit that has created
the interrupt is cleared. The status bit is cleared when a zero is
written to this register bit.
Rev. 0 | Page 62 of 128
ADE7518
8052 MCU CORE ARCHITECTURE
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 ADE7518 via the SFR area is shown
in Figure 67.
16kB ELECTRICALLY
REPROGRAMMABLE
NONVOLATILE
FLASH/EE
PROGRAM/DATA
MEMORY
256 BYTES
GENERALPURPOSE
RAM
STACK
REGISTER
BANKS
ENERGY
MEASUREMENT
POWER
MANAGEMENT
RTC
8051COMPATIBLE
CORE
PC
IR
128-BYTE
SPECIAL
FUNCTION
REGISTER
AREA
256 BYTES XRAM
All registers except the program counter (PC), the instruction
register (IR), and the four general-purpose register banks
reside in the SFR area. The SFR registers include power
control, configuration, and data registers that provide an
interface between the CPU and all on-chip peripherals.
LCD DRIVER
BATTERY
ADC
OTHER ON-CHIP
PERIPHERALS:
• SERIAL I/O
• WDT
• TIMERS
07327-067
The ADE7518 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 its enhancements used in the ADE7518.
Figure 67. Block Diagram
MCU REGISTERS
The registers used by the MCU are summarized in this section.
Table 45. 8052 SFRs
Address
0xE0
0xF0
0xD0
0x87
0x82
0x83
0x83 and 0x82
0x81
0xAF
Mnemonic
ACC
B
PSW
PCON
DPL
DPH
DPTR
SP
CFG
Bit Addressable
Yes
Yes
Yes
No
No
No
No
No
No
Description
Accumulator.
Auxiliary Math.
Program Status Word (see Table 46).
Program Control (see Table 47).
Data Pointer Low (see Table 48).
Data Pointer High (see Table 49).
Data Pointer (see Table 50).
Stack Pointer (see Table 51).
Configuration (see Table 52).
Table 46. Program Status Word SFR (PSW, 0xD0)
Bit
7
6
5
4 to 3
Address
0xD7
0xD6
0xD5
0xD4, 0xD3
Mnemonic
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 Available to the User.
Register Bank Select Bits.
RS1
RS0
Result (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 Available to the User.
Parity Bit. The number of bits set in the accumulator added to the value of the parity bit is always an
even number.
Rev. 0 | Page 63 of 128
ADE7518
Table 47. Program Control SFR (PCON, 0x87)
Table 50. Data Pointer SFR (DPTR, 0x82 and 0x83)
Bit
7
6 to 0
Bit
15 to 0
Default
0
0
Description
SMOD Bit. Double baud rate control.
Reserved. Should be left cleared.
Default
0
Description
Contain the 2-byte address of the data pointer.
DPTR is a combination of DPH and DPL SFRs.
Table 51. Stack Pointer SFR (SP, 0x81)
Table 48. Data Pointer Low SFR (DPL, 0x82)
Bit
7 to 0
Default
0
Description
Contain the low byte of the data pointer.
Bit
7 to 0
Default
7
Description
Contain the eight LSBs of the pointer for the
stack.
Table 49. Data Pointer High SFR (DPH, 0x83)
Bit
7 to 0
Default
0
Description
Contain the high byte of the data pointer.
Table 52. Configuration SFR (CFG, 0xAF)
Bit
7
6
Mnemonic
Reserved
EXTEN
5
SCPS
4
MOD38EN
3 to 2
1 to 0
Reserved
XREN1,
XREN0
Description
This bit should be left set for proper operation.
Enhanced UART Enable Bit.
EXTEN
Result
0
Standard 8052 UART without enhanced error-checking features.
1
Enhanced UART with enhanced error checking (see the UART Additional Features section).
Synchronous Communication Selection Bit.
SCPS
Result
0
I2C port is selected for control of the shared I2C/SPI pins (MOSI, MISO, SCLK, and SS) and SFRs.
1
SPI port is selected for control of the shared I2C/SPI pins (MOSI, MISO, SCLK, and SS) and SFRs.
38 kHz Modulation Enable Bit.
MOD38EN
Result
0
38 kHz modulation is disabled.
1
38 kHz modulation is enabled on the pins selected by the MOD38[7:0] bits in the
Extended Port Configuration SFR (EPCFG, 0x9F).
XRENx
XREN1 OR XREN0 = 1
XREN1 AND XREN0 = 0
Result
Enables MOVX instruction to use 256 bytes of extended RAM.
Disables MOVX instruction.
Rev. 0 | Page 64 of 128
ADE7518
BASIC 8052 REGISTERS
Data Pointer (DPTR)
Program Counter (PC)
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 48 and Table 49.
Instruction Register (IR)
The instruction register holds the operations code of the
instruction being executed. The operations code 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 that each contains eight byte-wide registers
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 one
clock cycle, as opposed to two 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.
The active register bank is selected by the RS0 and RS1 bits in
the Program Status Word SFR (PSW, 0xD0).
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 program 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 45).
B Register
The ADE7518 supports dual data pointers. See the Dual Data
Pointers section. Note that the Dual Data Pointers section is the
only section in the data sheet where the main and shadow data
pointers are distinguished. Whenever the data pointer (DPTR) is
mentioned elsewhere in the data sheet, active DPTR is implied.
Stack Pointer (SP)
The stack pointer keeps track of the current address at 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 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.
The stack is utilized to store the program address when CALL
and RET instructions are executed so that the program can
return to this address 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.
The stack resides in the internal extended RAM, and the SP
register holds the address of the stack in the extended RAM
(XRAM). The advantage of this solution is that the stack is
segregated to the internal XRAM. The use of the general-purpose
RAM can be limited to data storage, and the use of the extended
internal RAM can be limited to the stack pointer. This separation
limits the chance of data RAM corruption when the stack pointer
overflows in data RAM.
Data can still be stored in XRAM by using the MOVX command.
0xFF
The B register is used by the multiply and divide instructions,
MUL AB and DIV AB, to hold one of the operands. Because
the B register is not used for many instructions, it can be used
as a scratch pad register, such as those in the register banks.
The B register is stored in the SFR space (see Table 45).
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 accumulator contents,
which can be helpful for communication protocols. The PSW
bits are described in Table 46. The Program Status Word SFR
(PSW, 0xD0) is bit addressable.
0xFF
256 BYTES OF
RAM
256 BYTES OF
ON-CHIP XRAM
(DATA)
0x00
DATA + STACK
0x00
07327-068
The program counter holds the 2-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 added to the PC depends on the number of bytes in the
instruction, so the increment can range from one byte 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.
Figure 68. Extended Stack Pointer Operation
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 the following code:
MOV
Rev. 0 | Page 65 of 128
SP,#00H
ADE7518
STANDARD 8052 SFRS
Program Control Register (PCON, 0x87)
The standard 8052 special function registers include the ACC,
B, PSW, DPTR, and SP SFRs described in the Basic 8052 Registers
section. The standard 8052 SFRs also define the timers, the
serial port interface, the interrupts, the I/O ports, and the
power-down modes.
The 8052 core defines two power-down modes: power-down
and idle. The ADE7518 enhances the power control capability
of the traditional 8052 MCU with additional power management
functions. The Power Control SFR (POWCON, 0xC5) is used
to define power control-specific functionality for the ADE7518.
The Program Control SFR (PCON, 0x87) is not bit addressable
(see the Power Management section).
The 8052 contains three 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 91 and the 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 for the transmit/receive buffer. The
ADE7518 also has enhanced serial port functionality with a
dedicated timer for baud rate generation with a fractional
divisor and additional error detection. See Table 120 and the
UART Serial Interface section.
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 ADE7518 enhances this interrupt system
by creating, in essence, a third interrupt tier for the highest
priority, the power supply management (PSM) interrupt (see
the Interrupt System section).
I/O Port SFRs
The 8052 core supports four I/O ports, Port 0 through Port 3,
where Port 0 and Port 2 are typically used to access external
code and data spaces. The ADE7518, unlike standard 8052
products, provides internal nonvolatile flash memory so that an
external code space is unnecessary. The on-chip LCD driver
requires many pins, some of which are dedicated for LCD
functionality, and others that can be configured as LCD or
general-purpose inputs/outputs. Due to the limited number of
I/O pins, the ADE7518 does not allow access to external code
and data spaces.
The ADE7518 has many other peripherals not standard to the
8052 core, including
•
•
•
•
•
•
•
ADE energy measurement DSP
RTC
LCD driver
Battery switchover/power management
SPI/I2C communication
Flash memory controller
Watchdog timer
MEMORY OVERVIEW
The ADE7518 contains the following memory blocks:
•
•
•
16 kB 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 share the upper 128 bytes
of its address space with special function registers. All of the
memory spaces are shown in Figure 69. The addressing mode
specifies which memory space to access.
General-Purpose RAM
General-purpose RAM resides in the 0x00 through 0xFF
memory locations and contains the register banks.
0x7F
GENERAL-PURPOSE
AREA
0x30
0x2F
BIT-ADDRESSABLE
(BIT ADDRESSES)
BANKS
SELECTED
VIA
BITS IN PSW
0x20
0x1F
11
0x18
The ADE7518 provides 20 pins that can be used for generalpurpose I/O. These pins are mapped to Port 0, Port 1, and Port 2.
They are accessed through three bit-addressable 8052 SFRs, P0,
P1, and P2. Another enhanced feature of the ADE7518 is that
the weak pull-ups that are standard on 8052 Port 1, Port 2, and
Port 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).
0x17
10
0x10
0x0F
FOUR BANKS OF EIGHT
REGISTERS R0 TO R7
01
0x08
0x07
00
RESET VALUE OF
STACK POINTER
0x00
07327-069
Timer SFRs
Figure 69. Lower 128 Bytes of Internal Data Memory
Address 0x80 through Address 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 70.
Rev. 0 | Page 66 of 128
ADE7518
0xFF
Extended Internal RAM (XRAM)
ACCESSIBLE BY
DIRECT ADDRESSING
ONLY
The ADE7518 provides 256 bytes of extended on-chip RAM,
which is located in Address 0x0000 through Address 0x00FF in
the extended RAM space. No external RAM is supported. 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].
ACCESSIBLE BY
DIRECT AND INDIRECT
ADDRESSING
0x00
07327-070
GENERAL-PURPOSE RAM
SPECIAL FUNCTION REGISTERS (SFRs)
0x00FF
Figure 70. General-Purpose RAM and SFR Memory Address Overlap
Both direct and indirect addressing can be used to access generalpurpose RAM from 0x00 through 0x7F. However, only indirect
addressing can be used to access general-purpose RAM from
0x80 through 0xFF because this address space shares the same
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 Address 0x20 to RAM Address 0x2F can be accessed
through Bit Address 0x00 through Bit Address 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 Address 0x20 through RAM Address
0x2F can be seen in Figure 71.
BYTE
ADDRESS
BIT ADDRESSES (HEXA)
7F
7E
7D
7C
7B
7A
79
78
77
76
75
74
73
72
71
70
0x2D
6F
6E
6D
6C
6B
6A
69
68
0x2C
67
66
65
64
63
62
61
60
0x2B
5F
5E
5D
5C
5B
5A
59
58
0x2A
57
56
55
54
53
52
51
50
0x29
4F
4E
4D
4C
4B
4A
49
48
0x28
47
46
45
44
43
42
41
40
0x27
3F
3E
3D
3C
3B
3A
39
38
0x26
37
36
35
34
33
32
31
30
0x25
2F
2E
2D
2C
2B
2A
29
28
0x24
27
26
25
24
23
22
21
20
0x23
1F
1E
1D
1C
1B
1A
19
18
0x22
17
16
15
14
13
12
11
10
0x21
0F
0E
0D
0C
0B
0A
09
08
0x20
07
06
05
04
03
02
01
00
0x0000
Figure 72. Extended Internal RAM (XRAM) Space
Code Memory
Code and data memory are stored in the 16 kB 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 interprets the memory location
or data value specified in assembly language code. There are six
addressing modes, as shown in Table 53.
Table 53. 8052 Addressing Modes
Addressing Mode
Immediate
Direct
Indirect
Extended Direct
Extended Indirect
Code Indirect
07327-071
0x2F
0x2E
256 BYTES OF
EXTENDED INTERNAL
RAM (XRAM)
07327-072
0x80
0x7F
ACCESSIBLE BY
INDIRECT ADDRESSING
ONLY
Example
MOV A, #A8h
MOV DPTR, #A8h
MOV A, A8h
MOV A, IE
MOV A, R0
MOV A, @R0
MOVX A, @DPTR
MOVX A, @R0
MOVC A, @A+DPTR
MOVC A, @A+PC
JMP @A+DPTR
Bytes
2
3
2
2
1
1
1
1
1
1
1
Core Clock
Cycles
2
3
2
2
1
2
4
4
4
4
3
Immediate Addressing
Figure 71. 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 section).
Special Function Registers
Special function registers are registers that affect the function of
the 8052 core or its peripherals. These registers are located in
RAM in Address 0x80 through Address 0xFF. They are only
accessible through direct addressing, as shown in Figure 70.
In immediate addressing, the expression entered after the
number sign (#) is evaluated by the assembler and stored in the
specified memory address. 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 are slower than those
between two registers because the literal must be stored and
fetched from memory. The expression can be entered as a
symbolic variable or an arithmetic expression; the value is
computed by the assembler.
The individual bits of some 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 section.
Rev. 0 | Page 67 of 128
ADE7518
Direct Addressing
Extended Indirect 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. Note that indirect or direct
addressing modes can be used to access general-purpose RAM
Address 0x00 through RAM Address 0x7F. An instruction with
direct addressing that uses an address between 0x80 and 0xFF is
referring to a special function memory location.
The internal extended RAM is accessed through a pointer to the
address in indirect addressing mode. The ADE7518 has 256 bytes
of internal extended RAM, accessed through MOVX instructions.
External memory is not supported on the devices.
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 0x82 to the accumulator,
use the following instructions:
MOV
R0,#82h
MOV
A,@R0
These two instructions require a total of four clock cycles and
three bytes of storage in the program memory.
Indirect addressing allows addresses to be computed, which is
useful for indexing into data arrays stored in RAM.
Note that an instruction that refers to Address 0x00 through
Address 0x7F is referring to internal RAM, and indirect or
direct addressing modes can be used. An instruction with
indirect addressing that uses an address between 0x80 and
0xFF is referring to internal RAM, not to an SFR.
Extended Direct Addressing
The DPTR register (see Table 50) is used to access internal
extended RAM in extended indirect addressing mode. The
ADE7518 has 256 bytes of 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
moves the contents of extended RAM Address 0x100 to the
accumulator:
MOV
DPTR,#100h
MOVX
A,@DPTR
In extended indirect addressing mode, a register holds the address
of the byte of extended RAM. The following code moves the
contents of extended RAM Address 0x80 to the accumulator:
MOV
R0,#80h
MOVX
A,@R0
These two instructions require six clock cycles and three bytes
of storage.
Note that there are 256 bytes of extended RAM; therefore, 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 0x80 through 0xFF, and the access of extended
internal RAM from 0x00 through 0xFF, 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 0x8002 into the accumulator,
use the following code:
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.
These two instructions require a total of seven clock cycles and
four bytes of storage in the program memory.
Rev. 0 | Page 68 of 128
ADE7518
INSTRUCTION SET
Table 54 documents the number of clock cycles required for each instruction. Most instructions are executed in one or two clock cycles,
resulting in a 4-MIPS peak performance.
Table 54. Instruction Set
Mnemonic
Arithmetic
ADD A, Rn
ADD A, @Ri
ADD A, dir
ADD A, #data
ADDC A, Rn 1 1
ADDC A, @Ri
ADDC A, dir
ADDC 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
Logic
ANL A, Rn
ANL A, @Ri
ANL A, dir
ANL A, #data
ANL dir, A
ANL dir, #data
ORL A, Rn
ORL A, @Ri
ORL A, dir
ORL A, #data
ORL dir, A
ORL dir, #data
XRL A, Rn
XRL A, @Ri
XRL A, #data
XRL dir, A
XRL A, dir
XRL dir, #data
CLR A
CPL A
SWAP A
RL A
Description
Bytes
Cycles
Add register to A
Add indirect memory to A
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
1
1
2
2
1
1
2
2
1
1
2
2
1
1
1
2
1
1
1
1
2
1
1
1
1
2
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
AND indirect memory to A
AND direct byte to A
AND immediate to A
AND A to direct byte
AND immediate data to direct byte
OR register to A
OR indirect memory to A
OR direct byte to A
OR immediate to A
OR A to direct byte
OR immediate data to direct byte
Exclusive OR register to A
Exclusive OR indirect memory to A
Exclusive OR immediate to A
Exclusive OR A to direct byte
Exclusive OR indirect memory to A
Exclusive OR immediate data to direct
Clear A
Complement A
Swap nibbles of A
Rotate A left
1
1
2
2
2
3
1
1
2
2
2
3
1
2
2
2
2
3
1
1
1
1
1
2
2
2
2
3
1
2
2
2
2
3
1
2
2
2
2
3
1
1
1
1
Rev. 0 | Page 69 of 128
ADE7518
Mnemonic
RLC A
RR A
RRC A
Data Transfer
MOV A, Rn
MOV A, @Ri
MOV Rn, A
MOV @Ri, A
MOV A, dir
MOV A, #data
MOV Rn, #data
MOV dir, A
MOV Rn, dir
MOV dir, Rn
MOV @Ri, #data
MOV dir, @Ri
MOV @Ri, dir
MOV dir, dir
MOV dir, #data
MOV DPTR, #data
MOVC A, @A+DPTR
MOVC A, @A+PC
MOVX A, @Ri
MOVX A, @DPTR
MOVX @Ri, A
MOVX @DPTR, A
PUSH dir
POP dir
XCH A, Rn
XCH A, @Ri
XCHD A, @Ri
XCH A, dir
Boolean
CLR C
CLR bit
SETB C
SETB bit
CPL C
CPL bit
ANL C, bit
ANL C, /bit
ORL C, bit
ORL C, /bit OR
MOV C, bit
MOV bit, C
Branching
JMP @A+DPTR
RET
RETI
ACALL addr11
AJMP addr11
SJMP rel
JC rel
Description
Rotate A left through carry
Rotate A right
Rotate A right through carry
Bytes
1
1
1
Cycles
1
1
1
Move register to A
Move indirect memory to A
Move A to register
Move A to indirect memory
Move direct byte to A
Move immediate to A
Move register to immediate
Move A to direct byte
Move register to direct byte
Move direct to register
Move immediate to indirect memory
Move indirect to direct memory
Move direct to indirect memory
Move direct byte to direct byte
Move immediate to direct byte
Move immediate to data pointer
Move code byte relative DPTR to A
Move code byte relative PC to A
Move external (A8) data to A
Move external (A16) data to A
Move A to external data (A8)
Move A to external data (A16)
Push direct byte onto stack
Pop direct byte from stack
Exchange A and register
Exchange A and indirect memory
Exchange A and indirect memory nibble
Exchange A and direct byte
1
1
1
1
2
2
2
2
2
2
2
2
2
3
3
3
1
1
1
1
1
1
2
2
1
1
1
2
1
2
1
2
2
2
2
2
2
2
2
2
2
3
3
3
4
4
4
4
4
4
2
2
1
2
2
2
Clear carry
Clear direct bit
Set carry
Set direct bit
Complement carry
Complement direct bit
AND direct bit and carry
AND direct bit inverse to carry
OR direct bit and carry
Direct bit inverse to carry
Move direct bit to carry
Move carry to direct bit
1
2
1
2
1
2
2
2
2
2
2
2
1
2
1
2
1
2
2
2
2
2
2
2
Jump indirect relative to DPTR
Return from subroutine
Return from interrupt
Absolute jump to subroutine
Absolute jump unconditional
Short jump (relative address)
Jump on carry equal to 1
1
1
1
2
2
2
2
3
4
4
3
3
3
3
Rev. 0 | Page 70 of 128
ADE7518
Mnemonic
JNC rel
JZ rel
JNZ rel
DJNZ Rn, rel
LJMP
LCALL addr16
JB bit, rel
JNB bit, rel
JBC bit, rel
CJNE A, dir, rel
CJNE A, #data, rel
CJNE Rn, #data, rel
CJNE @Ri, #data, rel
DJNZ dir, rel
Miscellaneous
NOP
Description
Jump on carry = 0
Jump on accumulator = 0
Jump on accumulator ≠ 0
Decrement register, JNZ relative
Long jump unconditional
Long jump to subroutine
Jump on direct bit = 1
Jump on direct bit = 0
Jump on direct bit = 1 and clear
Compare A, direct JNE relative
Compare A, immediate JNE relative
Compare register, immediate JNE relative
Compare indirect, immediate JNE relative
Decrement direct byte, JNZ relative
Bytes
2
2
2
2
3
3
3
3
3
3
3
3
3
3
Cycles
3
3
3
3
4
4
4
4
4
4
4
4
4
4
No operation
1
1
READ-MODIFY-WRITE INSTRUCTIONS
INSTRUCTIONS THAT AFFECT FLAGS
Some 8052 instructions read the latch and 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 pin are the ones
that read a value, possibly change it, and rewrite it to the latch.
Because these instructions involve modifying the port, it is
assumed that the pin being modified is an output, 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 on the transistor. 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.
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.
ADD A, Source
This instruction adds the source to the accumulator. No status
flags are referenced by the instruction.
Affected Status Flags
C
Set if there is a carry out of Bit 7. Cleared otherwise.
Used to indicate an overflow if the operands are
unsigned.
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 is set if two
positive operands yield a negative result or if two
negative operands yield a positive result.
Table 55. Read-Modify-Write Instructions
AC
Set if there is a carry out of Bit 3. Cleared otherwise.
Instruction
ANL
ORL
XRL
JBC
CPL
INC
DEC
DJNZ
MOV PX.Y,C1
CLR PX.Y1
SETB PX.Y1
ADDC A, Source
The instructions that read the latch rather than the pin are
called read-modify-write instructions and are listed in Table 55.
When the destination operand is a port or a port bit, these
instructions read the latch rather than the pin.
1
Example
ANL P0, A
ORL P1, A
XRL P2, A
JBC P1.1, LABEL
CPL P2.0
INC P2
DEC P2
DJNZ P0, LABEL
MOV P0.0, C
CLR P0.0
SETB P0.0
Description
Logic AND.
Logic OR.
Logic XOR.
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.
This instruction adds the source and the carry bit to the accumulator. The carry status flag is referenced by the instruction.
Affected Status Flags
C
Set if there is a carry out of Bit 7. Cleared otherwise.
Used to indicate an overflow if the operands are
unsigned.
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 is set if two positive
operands yield a negative result or if two negative
operands yield a positive result.
AC
Set if there is a carry out of Bit 3. Cleared otherwise.
These instructions read the port byte (all eight bits), modify the addressed
bit, and write the new byte back to the latch.
Rev. 0 | Page 71 of 128
ADE7518
SUBB A, Source
of Bit 0 to Bit 3 exceeds nine, 0x06 is added to the accumulator
to correct the lower four bits. If the carry bit is set when the
instruction begins, or if 0x06 is added to the accumulator in the
first step, 0x60 is added to the accumulator to correct the higher
four bits.
This instruction subtracts the source byte and the carry
(borrow) flag from the accumulator. It references the carry
(borrow) status flag.
Affected Status Flags
C
OV
AC
The carry and AC status flags are referenced by this instruction.
Set if there is a borrow needed for Bit 7. Cleared
otherwise. Used to indicate an overflow if the
operands are unsigned.
Affected Status Flag
C
Set if the result is greater than 0x99. Cleared otherwise.
Set if there is a borrow needed for Bit 6 or Bit 7, but
not for both. Used to indicate an overflow for signed
subtraction. This flag is set if a negative number
subtracted from a positive yields a negative result or
if a positive number subtracted from a negative
number yields a positive result.
RRC A
Set if a borrow is needed for Bit 3. Cleared otherwise.
Affected Status Flag
This instruction 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.
The carry status flag is referenced by this instruction.
MUL AB
C
This instruction 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. No status flags are referenced by the instruction.
RLC A
Affected Status Flags
C
Cleared.
OV
Set if the result is greater than 255. Cleared otherwise.
Equal to the state of ACC.0 before execution of the
instruction.
This instruction 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.
The carry status flag is referenced by this instruction.
Affected Status Flag
DIV AB
This instruction 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.
No status flags are referenced by the instruction.
Affected Status Flags
C
Cleared.
OV
Cleared unless the B register is equal to 0, in which
case the results of the division are undefined and the
OV flag is set.
C
CJNE Destination, Source, Relative Jump
This instruction compares the source value to the destination
value 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.
No status flags are referenced by this instruction.
Affected Status Flag
C
DA A
Equal to the state of ACC.7 before execution of the
instruction.
This instruction adjusts the accumulator to hold two 4-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
Rev. 0 | Page 72 of 128
Set if the source value is greater than the destination
value. Cleared otherwise.
ADE7518
DUAL DATA POINTERS
The ADE7518 incorporates two data pointers. The second data
pointer is a shadow data pointer and is selected via the Data Pointer
Control SFR (DPCON, 0xA7). DPCON features automatic hardware postincrement and postdecrement, as well as an automatic
data pointer toggle.
To illustrate the operation of DPCON, the following code copies
256 bytes of code memory at Address 0xD000 into XRAM,
starting from Address 0x0000:
MOV DPTR,#0
;Main DPTR = 0
MOV DPCON,#55H
;Select shadow DPTR
Note that this is the only section of the data sheet where the
main and shadow data pointers are distinguished. Whenever the
data pointer (DPTR) is mentioned elsewhere in the data sheet,
active DPTR is implied.
In addition, only the MOVC/MOVX @DPTR instructions
automatically postincrement and postdecrement the DPTR.
Other MOVC/MOVX instructions, such as MOVC PC
or MOVC @Ri, do not cause the DPTR to automatically
postincrement and postdecrement.
;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
Table 56. Data Pointer Control SFR (DPCON, 0xA7)
Bit
7
6
Mnemonic
5 to 4
DP1m1,
DP1m0
00
3to 2
DP0m1,
DP0m0
00
1
0
DPT
DPSEL
Default
0
0
0
0
Description
Not Implemented. Write don’t care.
Data Pointer Automatic Toggle Enable. Cleared by the user to disable autoswapping of the DPTR.
Set in user software to enable automatic toggling of the DPTR after each MOVX or MOVC instruction.
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
Result (Behavior of the Shadow Data Pointer)
0
0
8052 behavior.
0
1
DPTR is postincremented after a MOVX or MOVC instruction.
1
0
DPTR is postdecremented 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
Result (Behavior of the Main Data Pointer)
0
0
8052 behavior.
0
1
DPTR is postincremented after a MOVX or MOVC instruction.
1
0
DPTR is postdecremented 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.
Not Implemented. Write don’t care.
Data Pointer Select. Cleared by the user to select the main data pointer, meaning that the contents of
this 16-bit register are placed into the DPL SFR and DPH SFR. Set by the user to select the shadow data
pointer, meaning that the contents of a separate 16-bit register appear in the DPL SFR and DPH SFR.
Rev. 0 | Page 73 of 128
ADE7518
INTERRUPT SYSTEM
The ADE7518 provides 12 interrupt sources with three priority
levels. The power management interrupt is at the highest priority
level. The other two priority levels are configurable through the
Interrupt Priority SFR (IP, 0xB8) and the Interrupt Enable and
Priority 2 SFR (IEIP2, 0xA9).
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).
INTERRUPT ARCHITECTURE
The ADE7518 possesses advanced power supply managment
features. To ensure a fast response to time-critical power supply
issues, such as a loss of line power, the power supply managment
interrupt should be able to interrupt any interrupt service routine.
To enable the user to have full use of the standard 8052 interrupt
priority levels, an additional priority level is added for the power
supply management (PSM) interrupt. The PSM interrupt is the
only interrupt at this highest interrupt priority level.
HIGH
PRIORITY 1
STANDARD 8052 INTERRUPT ARCHITECTURE
LOW
PRIORITY 1
PRIORITY 0
07327-073
The 8052 standard interrupt architecture includes two tiers of
interrupts, where some interrupts are assigned a high priority
and others are assigned a low priority.
HIGH
PSM
LOW
PRIORITY 0
07327-074
The unique power management architecture of the ADE7518
includes an operating mode (PSM2) where the 8052 MCU core
is shut down. Events can be configured to wake the 8052 MCU
core from the PSM2 operating mode. A distinction is drawn
here between events that can trigger the wake-up 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 wake-up events, whereas events that can interrupt the
program flow when the MCU is active are called interrupts.
See the 3.3 V Peripherals and Wake-Up Events section to learn
more about events that can wake the 8052 core from PSM2.
Figure 74. Interrupt Architecture
See the Power Supply Management (PSM) Interrupt section for
more information on the PSM interrupt.
INTERRUPT REGISTERS
Figure 73. Standard 8052 Interrupt Priority Levels
A Priority 1 interrupt can interrupt the service routine of a
Priority 0 interrupt, and if two interrupts of different priorities
The control and configuration of the interrupt system is carried
out through four interrupt-related SFRs discussed in this section.
Table 57. Interrupt SFRs
SFR
IE
IP
IEIP2
WDCON
Address
0xA8
0xB8
0xA9
0xC0
Default
0x00
0x00
0xA0
0x10
Bit Addressable
Yes
Yes
No
Yes
Description
Interrupt Enable (see Table 58).
Interrupt Priority (see Table 59).
Interrupt Enable and Priority 2 (see Table 60).
Watchdog Timer (see Table 65 and the Writing to the Watchdog Timer SFR
(WDCON, 0xC0) section).
Table 58. Interrupt Enable SFR (IE, 0xA8)
Bit
7
6
5
4
3
2
1
0
Address
0xAF
0xAE
0xAD
0xAC
0xAB
0xAA
0xA9
0xA8
Mnemonic
EA
Reserved
ET2
ES
ET1
EX1
ET0
EX0
Description
Enables All Interrupt Sources. Set by the user. Cleared by the user to disable all interrupt sources.
This bit should be left cleared for proper operation.
Enables the Timer 2 Interrupt. Set by the user.
Enables the UART Serial Port Interrupt. Set by the user.
Enables the Timer 1 Interrupt. Set by the user.
Enables the External Interrupt 1 (INT1). Set by the user.
Enables the Timer 0 Interrupt. Set by the user.
Enables External Interrupt 0 (INT0). Set by the user.
Rev. 0 | Page 74 of 128
ADE7518
Table 59. Interrupt Priority SFR (IP, 0xB8)
Bit
7
6
5
4
3
2
1
0
Address
0xBF
0xBE
0xBD
0xBC
0xBB
0xBA
0xB9
0xB8
Mnemonic
PADE
Reserved
PT2
PS
PT1
PX1
PT0
PX0
Description
ADE Energy Measurement Interrupt Priority (1 = high, 0 = low).
This bit should be left cleared for proper operation.
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).
Timer 0 Interrupt Priority (1 = high, 0 = low).
INT0 (External Interrupt 0) Priority (1 = high, 0 = low).
Table 60. Interrupt Enable and Priority 2 SFR (IEIP2, 0xA9)
Bit
7
6
5
4
3
2
1
0
Mnemonic
Reserved
PTI
Reserved
PSI
EADE
ETI
EPSM
ESI
Description
Reserved.
RTC Interrupt Priority (1 = high, 0 = low).
Reserved.
SPI/I2C Interrupt Priority (1 = high, 0 = low).
Enables the Energy Metering Interrupt (ADE). Set by the user.
Enables the RTC Interval Timer Interrupt. Set by the user.
Enables the PSM Power Supply Management Interrupt. Set by the user.
Enables the SPI/I2C Interrupt. Set by the user.
INTERRUPT PRIORITY
If two interrupts of the same priority level occur simultaneously, the polling sequence is observed (as shown in Table 61).
Table 61. Priority Within Interrupt Level
Source
IPSM
IRTC
IADE
WDT
IE0
TF0
IE1
TF1
ISPI/I2CI
RI/TI
TF2/EXF2
Priority
0 (Highest)
1
2
3
4
5
6
7
8
9
10 (Lowest)
Description
Power Supply Management Interrupt.
RTC Interval Timer Interrupt.
ADE Energy Measurement Interrupt.
Watchdog Timer Overflow 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.
Rev. 0 | Page 75 of 128
ADE7518
INTERRUPT FLAGS
The interrupt flags and status flags associated with the interrupt vectors are shown in Table 62 and Table 63. Most of the interrupts have
flags associated with them.
Table 62. Interrupt Flags
Interrupt Source
IE0
TF0
IE1
TF1
RI + TI
TF2 + EXF2
IPSM (Power Supply)
IADE (Energy Measurement DSP)
Flag
TCON.1
TCON.5
TCON.3
TCON.7
SCON.1
SCON.0
T2CON.7
T2CON.6
IPSMF.6
MIRQSTL.7
Bit Name
IE0
TF0
IE1
TF1
TI
RI
TF2
EXF2
FPSM
ADEIRQFLAG
Description
External Interrupt 0.
Timer 0.
External Interrupt 1.
Timer 1.
Transmit Interrupt.
Receive Interrupt.
Timer 2 Overflow Flag.
Timer 2 External Flag.
PSM Interrupt Flag.
Read MIRQSTH, MIRQSTM, MIRQSTL.
Flag
SPI2CSTAT1
SPI2CSTAT1
TIMECON.7
TIMECON.2
WDCON.2
Bit Name
N/A
N/A
MIDNIGHT
ALARM
WDS
Description
SPI Interrupt Status Register.
I2C Interrupt Status Register.
RTC Midnight Flag.
RTC Alarm Flag.
Watchdog Timeout Flag.
Table 63. Status Flags
Interrupt Source
ISPI/I2CI
IRTC (RTC Interval Timer)
WDT (Watchdog Timer)
1
There is no specific flag for ISPI/I2CI; however, all flags for SPI2CSTAT need to be read to assess the reason for the interrupt.
A functional block diagram of the interrupt system is shown in
Figure 75. Note that the PSM interrupt is the only interrupt in
the highest priority level.
If an external wake-up event occurs to wake the ADE7518 from
PSM2, a pending external interrupt is generated. When the EX0
or EX1 bit in the Interrupt Enable SFR (IE, 0xA8) is set to enable
external interrupts, the program counter is loaded with the IE0
or IE1 interrupt vector. The IE0 and IE1 interrupt flags in the
TCON register are not affected by events that occur when the
8052 MCU core is shut down during PSM2. See the Power
Supply Management (PSM) Interrupt section.
The RTC and I2C/SPI interrupts are latched such that pending
interrupts cannot be cleared without entering their respective
interrupt service routines. Clearing the RTC midnight flags and
alarm flags does not clear a pending RTC interrupt. Similarly,
clearing the I2C/SPI status bits in the SPI Interrupt Status SFR
(SPISTAT, 0xEA) does not cancel a pending I2C/SPI interrupt.
These interrupts remain pending until the RTC or I2C/SPI
interrupt vectors are enabled. Their respective interrupt service
routines are entered shortly thereafter.
Figure 75 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 Timer/Counter 1 Control SFR (TCON,
0x88). If INT0 or INT1 is configured to interrupt on a low level,
the interrupt service routine is re-entered until the respective
pin goes high.
Rev. 0 | Page 76 of 128
ADE7518
IE/IEIP2 REGISTERS
PSM
RTC
IP/IEIP2 REGISTERS
PRIORITY LEVEL
LOW
IPSMF
HIGH HIGHEST
FPSM
(IPSMF.6)
IPSME
IN/OUT
LATCH
MIDNIGHT
ALARM
RESET
ADE
WATCHDOG
EXTERNAL
INTERRUPT 0
TIMER 0
EXTERNAL
INTERRUPT 1
MIRQSTH
MIRQSTM
MIRQSTL
MIRQENH
MIRQENM
MIRQENL
MIRQSTL.7
WATCHDOG TIMEOUT
WDIR
INT0
PSM2
IT0
0
IE0
1
IT0
TF0
INTERRUPT
POLLING
SEQUENCE
PSM2
IT1
INT1 0
IE1
1
IT1
TF1
TIMER 1
SPI INTERRUPT CFG.5
UART
TIMER 2
I2C INTERRUPT
1
IN/OUT
LATCH
0
RESET
RI
TI
TF2
EXF2
INDIVIDUAL
INTERRUPT
ENABLE
GLOBAL
INTERRUPT
ENABLE (EA)
Figure 75. Interrupt System Functional Block Diagram
Rev. 0 | Page 77 of 128
LEGEND
AUTOMATIC
CLEAR SIGNAL
07327-075
I2C/SPI
ADE7518
INTERRUPT VECTORS
CONTEXT SAVING
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
is complete, 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 64.
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 used in the main
program are restored to their preinterrupt state. Common
registers that can be modified in the ISR are the accumulator
register and the PSW register. Any general-purpose registers
that are used as scratch pads in the ISR should also be restored
before exiting the interrupt. The following example 8052 code
shows how to restore some commonly used registers:
Table 64. Interrupt Vector Addresses
Source
IE0
TF0
IE1
TF1
RI + TI
TF2 + EXF2
Reserved
ISPI/I2CI
IPSM (Power Supply)
IADE (Energy Measurement DSP)
IRTC (RTC Interval Timer)
WDT (Watchdog Timer)
Vector Address
0x0003
0x000B
0x0013
0x001B
0x0023
0x002B
0x0033
0x003B
0x0043
0x004B
0x0053
0x005B
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
INTERRUPT LATENCY
The 8052 architecture requires that at least one instruction
executes between interrupts. To ensure this, the 8052 MCU
core hardware prevents the program counter from jumping to
an ISR immediately after completing an RETI instruction or an
access of the IP and IE registers.
PSW
; restore the accumulator
The shortest interrupt latency is 3.25 instruction cycles, 800 ns
with a clock of 4.096 MHz. 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, 4 μs with a clock of 4.096 MHz.
Rev. 0 | Page 78 of 128
POP
RETI
ACC
ADE7518
WATCHDOG TIMER
The watchdog timer generates a device reset or interrupt within
a reasonable amount of time if the ADE7518 enters an erroneous
state, possibly due to a programming error or electrical noise. The
watchdog is enabled by default with a timeout of two seconds and
creates a system reset if not cleared within two seconds. The
watchdog function can be disabled by clearing the watchdog
enable bit (WDE) in the Watchdog Timer SFR (WDCON, 0xC0).
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 (set by PRE[3:0]). The watchdog timer is
clocked from the 32.768 kHz external crystal connected between
the XTAL1 and XTAL2 pins.
The WDCON SFR can be written only by user software if the
double write sequence described in the Writing to the Watchdog
Timer SFR (WDCON, 0xC0) section is initiated on every write
access to the WDCON SFR.
To prevent any code from inadvertently disabling the watchdog,
a watchdog protection can be activated. This watchdog protection
locks in the watchdog enable and event settings so that they cannot
be changed by user code. The protection is activated by clearing
a watchdog protection bit in the flash memory. The watchdog
protection bit is the most significant bit at Address 0x3FFA of
the flash memory. When this bit is cleared, the WDIR bit is forced
to 0, and the WDE bit is forced to 1. Note that the sequence for
configuring the flash protection bits must be followed to modify
the watchdog protection bit at Address 0x3FFA (see the Protecting
the Flash Memory section).
Table 65. Watchdog Timer SFR (WDCON, 0xC0)
Bit
7 to 4
Address
0xC7 to
0xC4
Mnemonic
PRE[3:0]
Default
7
Description
Watchdog Prescaler. In normal mode, the 16-bit watchdog timer is clocked by the input
clock (32.768 kHz). The PREx bits set which of the upper bits of the counter are used as the
watchdog output, as follows:
tWATCHDOG = 2 PRE ×
3
0xC3
WDIR
0
2
0xC2
WDS
0
1
0xC1
WDE
1
0
0xC0
WDWR
0
29
XTAL1
PRE[3:0]
Result (Watchdog Timeout)
0000
15.6 ms
0001
31.2 ms
0010
62.5 ms
0011
125 ms
0100
250 ms
0101
500 ms
0110
1 sec
0111
2 sec
1000
0 sec, automatic reset
1001
0 sec, serial download reset
1010 to 1111
Not a valid selection
Watchdog Interrupt Response Bit. When cleared, the watchdog generates a system reset
when the watchdog timeout period has expired. When set, the watchdog generates an
interrupt when the watchdog timeout period has expired.
Watchdog Status Bit. This bit is set to indicate that a watchdog timeout has occurred. It is
cleared by writing a 0 or by an external hardware reset. A watchdog reset does not clear
WDS; therefore, it can be used to distinguish between a watchdog reset and a hardware
reset from the RESET pin.
Watchdog Enable Bit. When set, this bit enables the watchdog and clears its counter. The
watchdog counter is subsequently cleared again whenever WDE is set. If the watchdog is
not cleared within its selected timeout period, it generates a system reset or watchdog
interrupt, depending on the WDIR bit.
Watchdog Write Enable Bit. See the Writing to the Watchdog Timer SFR (WDCON, 0xC0)
section.
Rev. 0 | Page 79 of 128
ADE7518
Table 66. Watchdog and Flash Protection Byte in Flash (Flash Address = 0x3FFA)
Bit
7
Mnemonic
WDPROT_PROTKY7
Default
1
6 to 0
PROTKY[6:0]
0xFF
Description
This bit holds the protection for the watchdog timer and the seventh bit of the flash protection key.
When this bit is cleared, the watchdog enable (WDE) and interrupt response bits (WDIR) cannot
be changed by user code. The watchdog configuration is then fixed to WDIR = 0 and WDE = 1.
The watchdog timeout in PRE[3:0] can still be modified by user code.
The value of this bit is also used to set the flash protection key. If this bit is cleared to protect the
watchdog, then the default value for the flash protection key is 0x7F instead of 0xFF (see the
Protecting the Flash Memory section for more information on how to clear this bit).
These bits hold the flash protection key. The content of this flash address is compared to the
Flash Protection Key SFR (PROTKY, 0xBB) when the protection is being set or changed. If the two
values match, the new protection is written to Flash Address 0x3FFF to Flash Address 0x3FFB.
See the Protecting the Flash Memory section for more information on how to configure these bits.
Writing to the Watchdog Timer SFR (WDCON, 0xC0)
Watchdog Timer Interrupt
Writing data to 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.
If the watchdog timer is not cleared within the watchdog timeout
period, a system reset occurs unless the watchdog timer interrupt
is enabled. The watchdog timer interrupt enable bit (WDIR) is
located in the Watchdog Timer SFR (WDCON, 0xC0). Enabling
the WDIR bit allows the program to examine the stack or other
variables that may have led the program to execute inappropriate
code. The watchdog timer interrupt also allows the watchdog to
be used as a long interval timer.
Disable Watch dog
CLR EA
SETB WDWR
CLR WDE
SETB EA
This sequence is necessary to protect the WDCON SFR from
code execution upsets that may unintentionally modify this
SFR. Interrupts should be disabled during this operation due to
the consecutive instruction cycles.
Note that WDIR is automatically configured as a high priority
interrupt. This interrupt cannot be disabled by the EA bit in the
IE register (see Table 58). Even if all of the other interrupts are
disabled, the watchdog is kept active to watch over the program.
Rev. 0 | Page 80 of 128
ADE7518
LCD REGISTERS
LCD DRIVER
Using shared pins, the LCD module is capable of directly driving
an LCD panel of 17 × 4 segments without compromising any
ADE7518 functions. It is capable of driving LCDs with 2×, 3×,
and 4× multiplexing. The LCD waveform voltages are generated
through an external resistor ladder.
Each ADE7518 has an embedded LCD control circuit, driver, and
power supply circuit. The LCD module is functional in all operating modes (see the Operating Modes section).
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), the LCD Configuration X SFR (LCDCONX, 0x9C), and
the LCD Configuration Y SFR (LCDCONY, 0xB1) contain general
LCD driver configuration information, including the LCD enable
and reset, as well as the method of LCD voltage generation and
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 the LCD Segment Enable 2 SFR
(LCDSEGE2, 0xED).
Table 67. LCD Driver SFRs
SFR Address
0x95
0x96
0x97
0x9C
0xAC
0xAE
0xB1
0xED
Mnemonic
LCDCON
LCDCLK
LCDSEGE
LCDCONX
LCDPTR
LCDDAT
LCDCONY
LCDSEGE2
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Description
LCD Configuration (see Table 68).
LCD Clock (see Table 71).
LCD Segment Enable (see Table 74).
LCD Configuration X (see Table 69).
LCD Pointer (see Table 75).
LCD Data (see Table 76).
LCD Configuration Y (see Table 70).
LCD Segment Enable 2 (see Table 77).
Table 68. LCD Configuration SFR (LCDCON, 0x95)
Bit
7
6
5
Mnemonic
LCDEN
LCDRST
BLINKEN
Default
0
0
0
4
LCDPSM2
0
3
CLKSEL
0
2
BIAS
0
1 to 0
LMUX[1:0]
00
Description
LCD Enable. If this bit is set, the LCD driver is enabled.
LCD Data Registers Reset. If this bit is set, the LCD data registers are 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).
Forces LCD off when in PSM2 (sleep mode).
LCDPSM2
Result
0
The LCD is disabled or enabled in PSM2 by the LCDEN bit.
1
The LCD is disabled in PSM2 regardless of LCDEN setting.
LCD Clock Selection.
CLKSEL
Result
0
fLCDCLK = 2048 Hz.
1
fLCDCLK = 128 Hz.
Bias Mode.
BIAS
Result
0
1/2. In this mode, LCDVA is internally connected to LCDVB (see Figure 76).
1
1/3 (see Figure 77).
LCD Multiplex Level.
LMUX[1:0]
Result
00
Reserved.
01
2× Multiplexing. FP27/COM3 is used as FP27. FP28/COM2 is used as FP28.
10
3× Mulitplexing. FP27/COM3 is used as FP27. FP28/COM2 is used as COM2.
11
4× Multiplexing. FP27/COM3 is used as COM3. FP28/COM2 is used as COM2.
Rev. 0 | Page 81 of 128
ADE7518
Table 69. LCD Configuration X SFR (LCDCONX, 0x9C)
Bit
7
6
Mnemonic
Reserved
EXTRES
Default
0
0
5 to 0
Reserved
0
Description
Reserved.
External Resistor Ladder Selection Bit.
EXTRES
Result
0
External resistor ladder is disabled.
1
External resistor ladder is enabled.
These bits should be set to 0 for proper operation.
Table 70. LCD Configuration Y SFR (LCDCONY, 0xB1)
Bit
7
6
Mnemonic
Reserved
INV_LVL
Default
0
0
5 to 2
1
Reserved
UPDATEOVER
0
0
0
REFRESH
0
Description
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.
Update Finished Flag Bit. This bit is updated by the LCD driver. When set, this bit 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 the user. When this bit is set, the LCD driver
does not use the data in the LCD data registers to update the display. The LCD data registers can be
updated by the 8052. When this bit is cleared, the LCD driver uses the data in the LCD data registers to
update the display at the next frame.
Table 71. LCD Clock SFR (LCDCLK, 0x96)
Bit
7 to 6
Mnemonic
BLKMOD[1:0]
Default
00
5 to 4
BLKFREQ[1:0]
00
3 to 0
FD[3:0]
0
Description
Blink Mode Clock Source Configuration Bits.
BLKMOD[1:0]
Result
00
The blink rate is controlled by software. The display is off.
01
The blink rate is controlled by software. The display is on.
10
The blink rate is 2 Hz.
11
The blink rate is set by BLKFREQ[1:0].
Blink Rate Configuration Bits. These bits control the LCD blink rate if BLKMOD[1:0] = 11.
BLKFREQ[1:0]
Result (Blink Rate)
00
1 Hz
01
1/2 Hz
10
1/3 Hz
11
1/4 Hz
LCD Frame Rate Selection Bits. See Table 72 and Table 73.
Rev. 0 | Page 82 of 128
ADE7518
Table 72. LCD Frame Rate Selection for fLCDCLK = 2048 Hz (LCDCON[3] = 0)
FD3
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
1
FD2
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
FD1
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
FD0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
2× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
256
1281
170.7
85.3
128
64
102.4
51.2
85.3
42.7
73.1
36.6
64
32
56.9
28.5
51.2
25.6
46.5
23.25
42.7
21.35
39.4
19.7
36.6
18.3
34.1
17.05
32
16
16
8
3× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
341.3
170.71
341.3
113.81
256
85.3
204.8
68.3
170.7
56.9
146.3
48.8
128
42.7
113.8
37.9
102.4
34.1
93.1
31
85.3
28.4
78.8
26.3
73.1
24.4
68.3
22.8
64
21.3
32
10.7
4× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
512
1281
341.3
85.3
256
64
204.8
51.2
170.7
42.7
146.3
36.6
128
32
113.8
28.5
102.4
25.6
93.1
23.25
85.3
21.35
78.8
19.7
73.1
18.3
68.3
17.05
64
16
32
8
Not within the range of typical LCD frame rates.
Table 73. LCD Frame Rate Selection for fLCDCLK = 128 Hz (LCDCON[3] = 1)
FD3
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
1
FD2
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
FD1
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
FD0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
2× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
32
161
21.3
10.6
16
8
16
8
16
8
16
8
16
8
16
8
16
8
16
8
16
8
16
8
16
8
16
8
128
64
64
32
3× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
32
10.7
128
42.7
64
21.3
4× Multiplexing
fLCD (Hz)
Frame Rate (Hz)
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
32
8
128
32
64
16
Not within the range of typical LCD frame rates.
Table 74. LCD Segment Enable SFR (LCDSEGE, 0x97)
Bit
7
6
5
4
3
2
1 to 0
Mnemonic
FP25EN
FP24EN
FP23EN
FP22EN
FP21EN
FP20EN
Reserved
Default
0
0
0
0
0
0
0
Description
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.
These bits should be left at 0 for proper operation.
Rev. 0 | Page 83 of 128
ADE7518
Table 75. LCD Pointer SFR (LCDPTR, 0xAC)
Bit
7
Mnemonic
R/W
Default
0
6
5 to 0
Reserved
ADDRESS
0
0
Description
Read or Write LCD Bit. If this bit = 1, the data in LCDDAT is written to the address indicated by
the LCDPTR[5:0] bits.
Reserved.
LCD Memory Address (see Table 78).
Table 76. LCD Data SFR (LCDDAT, 0xAE)
Bit
7 to 0
Mnemonic
LCDDATA
Default
0
Description
Data to be written into or read out of the LCD Memory SFRs.
Table 77. LCD Segment Enable 2 SFR (LCDSEGE2, 0xED)
Bit
7 to 4
3
2
1
0
Mnemonic
Reserved
FP19EN
FP18EN
FP17EN
FP16EN
Default
0
0
0
0
0
Description
Reserved.
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. This rate, the refresh rate, determines
the visual characteristics of the LCD. A slow refresh rate results
in the LCD blinking on and off between refreshes. A fast refresh
rate presents a screen that appears to be continuously lit. In
addition, a faster refresh rate consumes more power.
The COM2/FP28 and COM3/FP27 pins default to LCD segment
lines. Selecting the 3× multiplex level in the LCD Configuration
SFR (LCDCON, 0x95) by setting LMUX[1:0] = 10 changes the
FP28 pin functionality to COM2. The 4× multiplex level selection,
LMUX[1:0] = 11, changes the FP28 pin functionality to COM2
and the FP27 pin functionality to COM3.
LCD segments FP0 to FP15 and FP26 are enabled by default.
Additional pins are selected for LCD functionality in the LCD
Segment Enable SFR (LCDSEGE, 0x97) and the LCD Segment
Enable 2 SFR (LCDSEGE2, 0xED), where there are individual
enable bits for the FP16 to FP25 segment pins. The LCD pins do
not have to be enabled sequentially. For example, if the alternate
function of FP23, the Timer 2 input, is required, any of the
other shared pins, FP16 to FP25, can 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) resets the LCD data
memory to its default (0). 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 2048 Hz
or 128 Hz by the CLKSEL bit in the LCD Configuration SFR
(LCDCON, 0x95). The minimum refresh rate 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 the active common line. Thus, the LCD
waveform frequency depends heavily on the multiplex level.
The frame rate and LCD waveform frequency are set by the
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
= 2048 Hz, ranging from 8 Hz to 128 Hz for an LCD with 4×
multiplexing. Fewer options are available with fLCDCLK = 128 Hz,
ranging from 8 Hz to 32 Hz for a 4× multiplexed LCD. The
128 Hz clock is beneficial for battery operation because it
consumes less power than the 2048 Hz clock. The frame rate is
set by the FD[3:0] bits in the LCD Clock SFR (LCDCLK, 0x96);
see Table 72 and Table 73.
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 degrades the lifetime and performance of
the LCD.
Rev. 0 | Page 84 of 128
ADE7518
BLINK MODE
Writing to LCD Data Registers
Blink mode is enabled by setting the BLINKEN bit in the LCD
Configuration SFR (LCDCON, 0x95). This mode is used to
alternate between the LCD on state and LCD off state so that
the LCD screen appears to blink. There are two blinking modes:
a software controlled blink mode and an automatic blink mode.
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
LCDPTR SFR is set, the content of the LCDDAT SFR is transferred to the internal LCD data memory designated by the address
in the LCDPTR SFR. Clear the LSB of the LCD Configuration Y
SFR (LCDCONY, 0xB1) when all of the data memory has been
updated to allow the use of the new LCD setup for display.
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. These blink rates are
selected by the BLKMOD[1:0] and BLKFREQ[1:0] bits in the
LCD Clock SFR (LCDCLK, 0x96); see Table 71.
DISPLAY ELEMENT CONTROL
To update the segments attached to the FP10 and FP11 pins, use
the following sample 8052 code:
ORL
LCDCONY,#01h ;start updating the data
MOV
LCDDAT,#FFh
MOV
LCDPTR,#80h OR 05h
ANL
LCDCONY,#0FEh ;update finished
A bank of 15 bytes of data memory located in the LCD module
controls the on or off state of each LCD segment. The LCD data
memory is stored in Address 0 through Address 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 Memory Address 0 refers to segment
lines one and zero (see Table 78). Note that the LCD data memory
is maintained in PSM2 operating mode.
Reading LCD Data Registers
MOV
LCDPTR,#07h
The LCD data memory is accessed indirectly through the LCD
Pointer SFR (LCDPTR, 0xAC) and LCD Data SFR (LCDDAT,
0xAE). Moving a value to the LCDPTR SFR selects the LCD
data byte to be accessed and initiates a read or write operation
(see Table 75).
MOV
R1, LCDDAT
When the MSB of the LCD Pointer SFR (LCDPTR, 0xAC) is
cleared, the content of the LCD data memory address designated by
LCDPTR is transferred to the LCD Data SFR (LCDDAT, 0xAE).
Sample 8052 code to read the contents of LCD Data Memory
Address 0x07, which holds the on and off state of the segments
attached to FP14 and FP15, is as follows:
Table 78. LCD Data Memory Accessed Indirectly Through LCD Pointer SFR (LCDPTR, 0xAC) and LCD Data SFR (LCDDAT, 0xAE)1, 2
LCD Memory Address
0x0E
0x0D
0x0C
0x0B
0x0A
0x09
0x08
0x07
0x06
0x05
0x04
0x03
0x02
0x01
0x00
1
2
COM3
FP27
FP25
FP23
FP21
FP19
FP17
FP15
FP13
FP11
FP9
FP7
FP5
FP3
FP1
LCD Pointer SFR (LCDPTR, 0xAC)
COM2
COM1
COM0
FP27
FP25
FP23
FP21
FP19
FP17
FP15
FP13
FP11
FP9
FP7
FP5
FP3
FP1
FP27
FP25
FP23
FP21
FP19
FP17
FP15
FP13
FP11
FP9
FP7
FP5
FP3
FP1
FP27
FP25
FP23
FP21
FP19
FP17
FP15
FP13
FP11
FP9
FP7
FP5
FP3
FP1
COMx designates the common lines.
FPx designates the segment lines.
Rev. 0 | Page 85 of 128
COM3
FP28
FP26
FP24
FP22
FP20
FP18
FP16
FP14
FP12
FP10
FP8
FP6
FP4
FP2
FP0
LCD Pointer SFR (LCDDAT, 0xAE)
COM2
COM1
COM0
FP28
FP28
FP28
FP26
FP26
FP26
FP24
FP24
FP24
FP22
FP22
FP22
FP20
FP20
FP20
FP18
FP18
FP18
FP16
FP16
FP16
FP14
FP14
FP14
FP12
FP12
FP12
FP10
FP10
FP10
FP8
FP8
FP8
FP6
FP6
FP6
FP4
FP4
FP4
FP2
FP2
FP2
FP0
FP0
FP0
ADE7518
LCD EXTERNAL CIRCUITRY
Example LCD Setup
The voltage generation selection is made by setting Bit EXTRES
in the LCD Configuration X SFR (LCDCONX, 0x9C). This bit
is cleared by default and needs to be set to enable an external
resistor ladder.
An example of how to set up the LCD peripheral for a specific
LCD is described in this section with the following parameters:
External Resistor Ladder
To enable the external resistor ladder, 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. Because the LCD voltages are not
generated on chip, the LCD bias compensation implemented to
maintain contrast over temperature and supply is not possible.
The external circuitry needed for the resistor ladder option is
shown in Figure 77. The resistors required should be in the
range of 10 kΩ to 100 kΩ and based on the current required
by the LCD being used.
Type of LCD: 4× multiplexed with 1/3 bias, 96 segments
Refresh rate: 64 Hz
A 96-segment LCD with 4× multiplexing requires 96/4 = 24
segment lines. Sixteen pins, FP0 to FP15, are automatically
dedicated for use as LCD segments. Eight more pins must be
chosen for the LCD function. Because the LCD has 4× multiplexing, all four common lines are used. As a result, COM2/FP28
and COM3/FP27 cannot be used as segment lines. Based on the
alternate functions of the pins used for FP16 through FP25,
FP16 to FP23 are chosen for the eight remaining segment lines.
These pins are enabled for LCD functionality in the LCD
Segment Enable SFR (LCDSEGE, 0x97) and LCD Segment
Enable 2 SFR (LCDSEGE2, 0xED).
The LCD is set up with the following 8052 code:
LCDVC
LCDVB
; setup LCD pins to have LCD functionality
LCDVA
MOV
LCDSEG,#FP20EN+FP21EN+FP22EN+FP23EN
LCDVP1
MOV
LCDSEGX,#FP16EN+FP17EN+FP18EN+FP19EN
LCDVP2
07327-076
LCD WAVEFORM
CIRCUITRY
•
•
Figure 76. External Circuitry for External Resistor Ladder Option 1/2 Bias
Configuration
; set up LCDCON for fLCDCLK = 2048 Hz, 1/3
bias and 4× multiplexing
MOV
LCDCON,#BIAS+LMUX1+LMUX0
; set up LCDCONX for resistor ladder
LCDVC
MOV
LCDCONX,#40h
LCDVB
LCD WAVEFORM
CIRCUITRY
; set up refresh rate for 64 Hz with fLCDCLK =
2048 Hz
LCDVP2
07327-077
LCDVA
LCDVP1
MOV
Figure 77. External Circuitry for External Resistor Ladder Option1/3 Bias
Configuration
LCD FUNCTION IN PSM2
LCDCLK,#FD3+FD2+FD1+FD0
; set up LCD data registers with data to be
displayed using
; LCDPTR and LCDDATA registers
; turn all segments on FP27 on and FP26 off
The LCDPSM2 and LCDEN bits in the LCD Configuration SFR
(LCDCON, 0x95) control LCD functionality in PSM2 operating
mode (see Table 79).
ORL
LCDCONY,#01h ; start data memory
refresh
Table 79. Bits Controlling LCD Functionality in PSM2 Mode
MOV
LCDPSM2
0
0
1
ANL
LCDCONY,#0FEh ; end of data memory
refresh
LCDEN
0
1
X
Result
The display is off in PSM2.
The display is on in PSM2.
The display is off in PSM2.
MOV
ORL
In addition, note that the LCD configuration and data memory
is retained when the display is turned off.
LCDDAT,#F0H
LCDPTR, #80h OR 0DH
LCDCON,#LCDEN ; enable LCD
To set up the same 3.3 V LCD for use with an external resistor
ladder,
; set up LCDCONX for external resistor
ladder
MOV
Rev. 0 | Page 86 of 128
LCDCONX,#EXTRES
ADE7518
FLASH MEMORY
OVERVIEW
Flash memory is a type of nonvolatile memory that is in-circuit
programmable. The default state of a byte of flash memory is 0xFF
(erased). When a byte of flash memory is programmed, the
required bits change from 1 to 0. The flash memory must be
erased to turn the 0s back to 1s. 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.
The ADE7518 provides 16 kB of flash program/information
memory. This memory is segmented into 32 pages of 512 bytes
each. Therefore, to reprogram one byte of flash memory, the
other 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 ADE7518 flash memory controller also offers
configurable flash memory protection.
The 16 kB 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 or emulation options provided or
using conventional third party memory programmers.
In reliability qualification, every byte in both the program and
data Flash/EE memory is cycled from 0x00 to 0xFF until a first
fail is recorded, signifying the endurance limit of the on-chip
Flash/EE memory.
As indicated in the Specifications section, the ADE7518 flash
memory endurance qualification has been carried out in
accordance with JEDEC Standard 22 Method 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
endurance figure of 20,000 cycles of operation at 25°C.
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 Standard 22 Method 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 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 78.
300
The flash memory arrays on the ADE7518 are fully qualified for
two key Flash/EE memory characteristics: Flash/EE memory
cycling endurance and Flash/EE memory data retention.
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 the following four
independent, sequential events:
Initial page erase sequence.
Read/verify sequence.
Byte program sequence.
Second read/verify sequence.
ANALOG DEVICES
SPECIFICATION
100 YEARS MIN.
AT TJ = 55°C
200
150
100
50
0
40
50
60
70
90
80
TJ JUNCTION TEMPERATURE (°C)
100
Figure 78. Flash/EE Memory Data Retention
Rev. 0 | Page 87 of 128
110
07327-078
1.
2.
3.
4.
RETENTION (Years)
Flash/EE Memory Reliability
ADE7518
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.
FLASH MEMORY ORGANIZATION
The 16 kB of flash memory provided by the ADE7518 are segmented into 32 pages of 512 bytes each. It is up to the user to
decide which flash memory to allocate for data memory. It is
recommended that each page be dedicated solely to program
memory or to data memory. Doing so prevents the program
counter from being loaded with data memory instead of an
operations code from the program memory. It also prevents
program memory used to update a byte of data memory from
being erased.
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
0x1FFF
PAGE 31
PAGE 30
PAGE 29
READ
PROTECT
BIT 7
0x1800
0x17FF
PAGE 27
PAGE 25
READ
PROTECT
BIT 6
0x0E00
0x0DFF
READ
PROTECT
BIT 5
0x0800
0x07FF
PAGE 19
PAGE 17
PAGE 16
0x0C00
0x0BFF
0x0A00
0x09FF
PAGE 20
PAGE 18
0x1400
0x13FF
0x1000
0x0FFF
PAGE 23
PAGE 21
0x1600
0x15FF
0x1200
0x11FF
PAGE 24
PAGE 22
0x1C00
0x1BFF
0x1A00
0x19FF
PAGE 28
PAGE 26
0x1E00
0x1DFF
0x0600
0x05FF
READ
PROTECT
BIT 4
0x0400
0x03FF
0x0200
0x01FF
0x0000
Therefore, Page 0 through Page 30 are for general program and
data memory use. It is recommended that Page 31 be used for
constants or code that do not need to be updated. Note that the
last six bytes of Page 31 are reserved for protecting the flash
memory.
PAGE 15
PAGE 14
PAGE 13
READ
PROTECT
BIT 3
USING THE FLASH MEMORY
PAGE 12
The 16 kB of flash memory are configured as 32 pages, each of
512 bytes. As with the other ADE7518 peripherals, the interface
to this memory space is via a group of registers mapped in the
SFR space (see Table 80).
PAGE 11
PAGE 10
PAGE 9
READ
PROTECT
BIT 2
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. 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.
PAGE 8
PAGE 7
PAGE 6
PAGE 5
READ
PROTECT
BIT 1
Table 80. The Flash SFRs
PAGE 4
PAGE 3
PAGE 2
PAGE 1
READ
PROTECT
BIT 0
SFR
ECON
FLSHKY
PROTKY
Address
0xB9
0xBA
0xBB
Default
0x00
0xFF
0xFF
Bit
Addressable
No
No
No
EDATA
PROTB0
0xBC
0xBD
0x00
0xFF
No
No
PROTB1
0xBE
0xFF
No
PROTR
0xBF
0xFF
No
EADRL
0xC6
0x00
No
EADRH
0xC7
0x00
No
PAGE 0
07327-079
0x3FFF
Thus, if code protection is enabled, it is recommended to use
this last page 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 utilized by the program code.
CONTAINS PROTECTION SETTINGS.
Figure 79. Flash Memory Organization
The flash memory can be protected from read or write/erase
(W/E) 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 page.
Another byte is used for configuring read protection of the flash
memory. The read protection is selected for groups of four pages.
Finally, one byte is used to store the key required for modifying
the protection scheme. The last page of flash memory must be
write/erase protected for any flash protection to be active.
Figure 80 demonstrates the steps required for access to the flash
memory.
ECON
COMMAND
FLASH
PROTECTION KEY
FLSHKY
ADDRESS
DECODER
PROTECTION
DECODER
ACCESS
ALLOWED?
FLSHKY = 0 × 3B?
TRUE: ACCESS
ALLOWED
ECON = 0
FALSE: ACCESS
DENIED
ECON = 1
Figure 80. Flash Memory Read/Write/Erase Protection Block Diagram
Rev. 0 | Page 88 of 128
07327-080
ADDRESS
EADRH EADRL
Description
Flash Control
Flash Key
Flash Protection
Key
Flash Data
Flash W/E
Protection 0
Flash W/E
Protection 1
Flash Read
Protection
Flash Low Byte
Address
Flash High
Byte Address
ADE7518
ECON—Flash/EE Memory Control SFR
Programming flash memory is done through the Flash Control
SFR (ECON, 0xB9). This SFR allows the user to read, write, erase,
or verify the 16 kB 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 memory. Upon completion of the flash memory
operation, the FLSHKY register is reset so that it must be written
to 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
inappropriately modified during its execution.
The program counter (PC) is held on the instruction where the
ECON register is written to until the flash memory controller is
done performing the requested operation. Then, the PC increments to continue with the next instruction.
Any interrupt 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, continue
to operate as configured throughout the flash memory access.
Table 81. Flash Control SFR (ECON, 0xB9)
Bit
7 to 0
Mnemonic
ECON
Value
1
2
3
4
5
8
Description
Write Byte. The value in EDATA is written to the flash memory at the page address given by EADRH and
EADRL. 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/EADRL. Any address in the page can be written to EADRH/EADRL to select it for erasure.
Erase All. All 16 kB of the flash memory are erased. Note that 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/EADRL is read into EDATA.
Erase Page and Write Byte. The page that holds the byte addressed by EADRH/EADRL is erased. Data in
EDATA is then written to the byte of flash memory addressed by EADRH/EADRL.
Protect Code (see the Protecting the Flash Memory section).
Table 82. Flash Key SFR (FLSHKY, 0xBA)
Bit
7 to 0
Mnemonic
FLSHKY
Default
0xFF
Description
The content of this SFR is compared to the flash key, 0x3B. If the two values match, the next ECON
operation is allowed (see the Protecting the Flash Memory section).
Table 83. Flash Protection Key SFR (PROTKY, 0xBB)
Bit
7 to 0
Mnemonic
PROTKY
Default
0xFF
Description
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 setup is allowed (see the Protecting the Flash
Memory section).
If the protection key in the flash is 0xFF, the PROTKY SFR value is not used for comparison. This SFR is
also used to write the protection key in the flash. This is done by writing the desired value in PROTKY
and by writing 0x08 in the ECON SFR. This operation can only be done once.
Table 84. Flash Data SFR (EDATA, 0xBC)
Bit
7 to 0
Mnemonic
EDATA
Default
0
Description
Flash Pointer Data.
Table 85. Flash Write/Erase Protection 0 SFR (PROTB0, 0xBD)
Bit
7 to 0
Mnemonic
PROTB0
Default
0xFF
Description
This SFR is used to write the write/erase protection bits for Page 0 to Page 7 of the flash memory
(see the Protecting the Flash Memory section). Clearing the bits enables the protection.
PROTB0.7 PROTB0.6 PROTB0.5 PROTB0.4 PROTB0.3 PROTB0.2 PROTB0.1 PROTB0.0
Page 7
Page 6
Page 5
Page 4
Page 3
Page 2
Page 1
Page 0
Table 86. Flash Write/Erase Protection 1 SFR (PROTB1, 0xBE)
Bit
7 to 0
Mnemonic
PROTB1
Default
0xFF
Description
This SFR is used to write the write/erase protection bits for Page 8 to Page15 of the flash memory
(see the Protecting the Flash Memory section). Clearing the bits enables the protection.
PROTB1.7 PROTB1.6 PROTB1.5 PROTB1.4 PROTB1.3 PROTB1.2 PROTB1.1 PROTB1.0
Page 15
Page 14
Page 13
Page 12
Page 11
Page 10
Page 9
Page 8
Rev. 0 | Page 89 of 128
ADE7518
Table 87. Flash Read Protection SFR (PROTR, 0xBF)
Bit
7 to 0
Mnemonic
PROTR
Default
0xFF
Description
This SFR is used to write the read protection bits for Page 0 to Page 31 of the flash memory
(see the Protecting the Flash Memory section). Clearing the bits enables the protection.
PROTR.7
PROTR.6
PROTR.5
PROTR.4
PROTR.3
PROTR.2
PROTR.1
Page 28 to Page 24 to Page 20 to Page 16 to Page 12 to Page 8 to
Page 4 to
Page 31
Page 27
Page 23
Page 19
Page 15
Page 11
Page 7
PROTR.0
Page 0 to
Page 3
Table 88. Flash Low Byte Address SFR (EADRL, 0xC6)
Bit
7 to 0
Mnemonic
EADRL
Default
0
Description
Flash Pointer Low Byte Address. This SFR is also used to write the write/erase protection bits for Page 16
to Page 23 of the flash memory (see the Protecting the Flash Memory section). Clearing the bits enables
the protection.
EADRL.7
EADRL.6
EADRL.5
EADRL.4
EADRL.3
EADRL.2
EADRL.1
EADRL.0
Page 23
Page 22
Page 21
Page 20
Page 19
Page 18
Page 17
Page 16
Table 89. Flash High Byte Address SFR (EADRH, 0xC7)
Bit
7 to 0
Mnemonic
EADRH
Default
0
Description
Flash Pointer High Byte Address. This SFR is also used to write the write/erase protection bits for Page 24
to Page 31 of the flash memory (see the Protecting the Flash Memory section). Clearing the bits enables
the protection.
EADRH.7
EADRH.6
EADRH.5
EADRH.4
EADRH.3
EADRH.2
EADRH.1
EADRH.0
Page 31
Page 30
Page 29
Page 28
Page 27
Page 26
Page 25
Page 24
Flash Functions
Erase All
Sample 8052 code is provided in this section to demonstrate
how to use the flash functions. For these examples, the byte of
Flash Memory 0x3C00 is accessed.
Erase all of the 16 kB flash memory.
MOV FLSHKY,#3Bh
key
; Write flash security
Write Byte
MOV ECON,#03h
; Erase all
Write 0xF3 into Flash Memory Byte 0x3C00.
Read Byte
MOV EDATA,#F3h
; Data to be written
Read Flash Memory Byte 0x3C00.
MOV EADRH,#3Ch
; Set up byte address
MOV EADRH,#3Ch
MOV EADRL,#00h
; Set up byte address
MOV EADRL,#00h
MOV FLSHKY,#3Bh
key.
; Write flash security
MOV FLSHKY,#3Bh
key
; Write flash security
MOV ECON,#01h
; Write byte
MOV ECON,#04h
; Read byte
Erase Page
; Data is ready in EDATA
register
Erase the page containing Flash Memory Byte 0x3C00.
MOV EADRh,#3Ch
byte address
Erase Page and Write Byte
; Select page through
MOV EADRL,#00h
MOV FLSHKY,#3Bh
key
; Write flash security
MOV ECON,#02h
; Erase Page
Erase the page containing Flash Memory Byte 0x3C00 and then
write 0xF3 to that address. Note that the other 511 bytes in this
page are erased.
MOV EDATA,#F3h
; Data to be written
MOV EADRH,#3Ch
; Set up byte address
MOV EADRL,#00h
MOV FLSHKY,#3Bh
key
; Write flash security
MOV ECON,#05h
write byte
; Erase page and then
Rev. 0 | Page 90 of 128
ADE7518
PROTECTING THE FLASH MEMORY
The sequence for writing the protection bits is as follows:
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 are not 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 an unexpected disruption of the normal execution
of the program.
1.
Write/erase protection is individually selectable for all 32 pages.
Read protection is selected in groups of four pages (see Figure 79
for the groupings). The protection bits are stored in the last flash
memory locations, Address 0x3FFA through Address 0x3FFF (see
Figure 81); four bytes are reserved for write/erase protection,
one byte is for read protection, and another byte sets the protection
security key. The user must enable read and write/erase protection
for the last page for the entire protection scheme to work.
2.
3.
Note that the read protection does not prevent MOVC
commands from being executed within the code.
There is an additional layer of protection offered by a protection
security key. The user can set up this security key so that the
protection scheme cannot be changed without this key. Once
the protection key has been configured, it cannot be modified.
Enabling Flash Protection by Code
The protection bytes in the flash memory can be programmed
using the flash controller command and programming ECON to
0x08. In this case, the EADRH, EADRL, PROTB1, and PROTB0
bytes are used 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.
0x3FFF
WP
31
WP
30
WP
29
WP
28
WP
27
WP
26
WP
25
WP
24
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
8
0x3FFC
WP
7
WP
6
WP
5
WP
4
WP
3
WP
2
WP
1
WP
0
RP
11:8
RP
7:4
RP
3:0
EADRH
EADRL
PROTB1
PROTB0
PROTR
RP
RP
RP
RP
RP
0x3FFB 31:28 27:24 23:20 19:16 15:12
PROTKY
0x3FFA
0x3FF9
WDOG
LOCK
4.
5.
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.
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.
To enable the protection key, write to the PROTKY register.
If enabled, the protection key is required to modify the
protection scheme. The protection key, Flash Memory
Address 0x3FFA, defaults to 0xFF; if the PROTKY register
is not written to, it remains 0xFF. If the protection key is
written to, the PROTKY register must be written with this
value every time the protection functionality is accessed.
Note that once the protection key is configured, it cannot
be modified. Also, note that the most significant bit of
Address 0x3FFA is used to enable a lock mechanism for
the watchdog settings (see the Watchdog Timer section
for more information).
Run the protection command by writing 0x08 to the
ECON register.
Reset the chip to activate the new protection.
To enable read and write/erase protection for the last page only, use
the following 8052 code. Writing the flash protection command
to the ECON register initiates programming of the protection
bits in the flash.
; 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
PROTECTION KEY
07327-081
; write the flash key to the FLSHKY register
to enable flash
0x3E00
; access. The flash access key is not
configurable.
MOV FLSHKY,#3Bh
Figure 81. Flash Protection in Page 31
; write flash protection command to the ECON
register
MOV ECON,#08h
Rev. 0 | Page 91 of 128
ADE7518
Enabling Flash Protection by Emulator Commands
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 section. When these flash bytes are written, the part
can exit emulation mode by a reset and the protections are
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
Application Note uC004, Understanding the Serial Download
Protocol, available at www.analog.com.
•
•
Command with ASCII Code I or 0x49 writes the data into R0.
Command with ASCII Code F or 0x46 writes R0 into the
SFR address defined in the data of this command.
By omitting the protocol defined in Application Note uC004,
Understanding the Serial Download Protocol, the sequence to
load protections is similar to the sequence presented in the
Enabling Flash Protection by Code section, except that two
emulator commands are necessary to replace one assembly
command. For example, to write the protection value in
EADRH, the two following commands need to be executed:
•
•
Command I with data = value of Protection Byte 0x3FFF.
Command F with data = 0xC7.
Following this protocol, the protection can be written to the
flash using the same sequence as mentioned in the Enabling
Flash Protection by Code section. When the part is reset, the
protection is effective.
Protection bits can be modified from 1 to 0, even after the last
page has been protected. In this way, more protection can be
added but none can be removed.
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
shown in Table 90.
Table 90. Flash Memory Program and Erase Times
Command
Write Byte
Erase Page
Erase All
Read Byte
Erase Page and Write Byte
Verify Byte
Bytes
Affected
1 byte
512 bytes
16 kB
1 byte
512 bytes
1 byte
Flash Memory
Timing
30 μs
20 ms
200 ms
100 ns
21 ms
100 ns
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 counters and timers, continue to count as
configured throughout this period.
IN-CIRCUIT PROGRAMMING
Notes on Flash Protection
Serial Downloading
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 ADE7518 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. When in serial download mode, the hidden embedded download kernel executes. This allows the user to download
code to the full 16 kB of flash memory while the device is in-circuit
in its target application hardware.
The last page must be read and write/erase protected for the
protection scheme to work.
To activate the protection settings, the ADE7518 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 on the
last page, but the protection bits are never truly write protected.
Protection configured in the last page of the ADE7518 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.
Rev. 0 | Page 92 of 128
ADE7518
TIMERS
The ADE7518 has three 16-bit timer/counters: Timer/Counter 0,
Timer/Counter 1, and Timer/Counter 2. The timer/counter
hardware is included on chip to relieve the processor core of
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 timers can be configured to
operate as timers or as event counters.
When functioning as a timer, the TLx register is incremented
every machine cycle. Thus, users 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 listed in Table 91.
Table 91. Timer SFRs
SFR
TCON
TMOD
TL0
TL1
TH0
TH1
T2CON
RCAP2L
RCAP2H
TL2
TH2
Address
0x88
0x89
0x8A
0x8B
0x8C
0x8D
0xC8
0xCA
0xCB
0xCC
0xCD
Bit Addressable
Yes
No
No
No
No
No
Yes
No
No
No
No
Description
Timer/Counter 0 and Timer/Counter 1 Control (see Table 93).
Timer/Counter 0 and Timer/Counter 1 Mode (see Table 92).
Timer 0 Low Byte (see Table 96).
Timer 1 Low Byte (see Table 98).
Timer 0 High Byte (see Table 95).
Timer 1 High Byte (see Table 97).
Timer/Counter 2 Control (see Table 94).
Timer 2 Reload/Capture Low Byte (see Table 102).
Timer 2 Reload/Capture High Byte (see Table 101).
Timer 2 Low Byte (see Table 100).
Timer 2 High Byte (see Table 99).
TIMER REGISTERS
Table 92. Timer/Counter 0 and Timer/Counter 1 Mode SFR (TMOD, 0x89)
Bit
7
Mnemonic
Gate1
Default
0
6
C/T1
0
5 to 4
T1/M1,
T1/M0
00
3
Gate0
0
2
C/T0
0
1 to 0
T0/M1,
T0/M0
00
Description
Timer 1 Gating Control. Set by software to enable Timer/Counter 1 only when the INT1 pin is high and the
TR1 control is set. Cleared by software to enable Timer 1 whenever the TR1 control bit is set.
Timer 1 Timer or Counter Select Bit. Set by software to select counter operation (input from the T1 pin).
Cleared by software to select the timer operation (input from the internal system clock).
Timer 1 Mode Select Bits.
T1/M[1:0] Result
00
TH1 operates as an 8-bit timer/counter. TL1 serves as a 5-bit prescaler.
01
16-Bit Timer/Counter. TH1 and TL1 are cascaded; there is no prescaler.
10
8-Bit Autoreload Timer/Counter. TH1 holds a value to reload into TL1 each time it overflows.
11
Timer/Counter 1 stopped.
Timer 0 Gating Control. Set by software to enable Timer/Counter 0 only when 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 the T0 pin).
Cleared by software to the select timer operation (input from the internal system clock).
Timer 0 Mode Select Bits.
T0/M[1:0] Result
00
TH0 operates as an 8-bit timer/counter. TL0 serves as a 5-bit prescaler.
01
16-Bit Timer/Counter. TH0 and TL0 are cascaded; there is no prescaler.
10
8-Bit Autoreload Timer/Counter. TH0 holds a value to reload into TL0 each time it overflows.
11
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.
Rev. 0 | Page 93 of 128
ADE7518
Table 93. Timer/Counter 0 and Timer/Counter 1 Control SFR (TCON, 0x88)
Bit
7
Address
0x8F
Mnemonic
TF1
Default
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
1
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 state 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.
These bits are not used to control Timer/Counter 0 and Timer/Counter 1 but are instead used to control and monitor the external INT0 and INT1 interrupt pins.
Table 94. Timer/Counter 2 Control SFR (T2CON, 0xC8)
Bit
7
Address
0xCF
Mnemonic
TF2
Default
0
6
0xCE
EXF2
0
5
0xCD
RCLK
0
4
0xCC
TCLK
0
3
0xCB
EXEN2
0
2
1
0xCA
0xC9
TR2
C/T2
0
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 pin 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 Mode 1 and Serial Port Mode 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 Mode 1 and Serial Port Mode 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.
Rev. 0 | Page 94 of 128
ADE7518
Table 95. Timer 0 High Byte SFR (TH0, 0x8C)
Mode 0 (13-Bit Timer/Counter)
Bit
7 to 0
Mode 0 configures an 8-bit timer/counter. Figure 82 shows
Mode 0 operation. Note that the divide-by-12 prescaler is not
present on the single cycle core.
Mnemonic
TH0
Default
0
Description
Timer 0 Data High Byte.
Table 96. Timer 0 Low Byte SFR (TL0, 0x8A)
Bit
7 to 0
Mnemonic
TL0
Default
0
fCORE
Description
Timer 0 Data Low Byte.
C/T0 = 0
TL0
TH0
(5 BITS) (8 BITS)
C/T0 = 1
Table 97. Timer 1 High Byte SFR (TH1, 0x8D)
Mnemonic
TH1
Default
0
Description
Timer 1 Data High Byte.
Table 98. Timer 1 Low Byte SFR (TL1, 0x8B)
Bit
7 to 0
Mnemonic
TL1
Default
0
Mnemonic
TH2
Default
0
INT0
Figure 82. Timer/Counter 0, Mode 0
Description
Timer 2 Data High Byte.
Table 100. Timer 2 Low Byte SFR (TL2, 0xCC)
Bit
7 to 0
Mnemonic
TL2
Default
0
Description
Timer 2 Data Low Byte.
Table 101. Timer 2 Reload/Capture High Byte SFR
(RCAP2H, 0xCB)
Bit
7 to 0
Mnemonic
TH2
Default
0
Description
Timer 2 Reload/
Capture High Byte.
Table 102. Timer 2 Reload/Capture Low Byte SFR
(RCAP2L, 0xCA)
Bit
7 to 0
Mnemonic
TL2
Default
0
CONTROL
TR0
GATE
Description
Timer 1 Data Low Byte.
Table 99. Timer 2 High Byte SFR (TH2, 0xCD)
Bit
7 to 0
P0.6/T0
07327-082
Bit
7 to 0
INTERRUPT
TF0
In this mode, the timer register is configured as a 13-bit register.
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
Gate0 = 0 or INT0 = 1. Setting Gate0 = 1 allows the timer to be
controlled by external input INT0 to facilitate pulse width
measurements. TR0 is a control bit in the Timer/Counter 0 and
Timer/Counter 1 Control SFR (TCON, 0x88); the Gate0/Gate1
bits are in the Timer/Counter 0 and Timer/Counter 1 Mode SFR
(TMOD, 0x89). The 13-bit register consists of all eight bits of
Timer 0 High Byte SFR (TH0, 0x8C) and the lower five bits of
Timer 0 Low Byte SFR (TL0, 0x8A). The upper three bits of the
TL0 SFR are indeterminate and should be ignored. Setting the
run flag (TR0) does not clear the registers.
Mode 1 (16-Bit Timer/Counter)
Description
Timer 2 Reload/
Capture Low Byte.
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 83.
fCORE
TIMER 0 AND TIMER 1
C/T0 = 0
TL0
TH0
(8 BITS) (8 BITS)
Timer/Counter 0 and Timer/Counter 1 Data Registers
C/T0 = 1
P0.6/T0
TR0
CONTROL
07327-083
Each timer consists of two 8-bit registers. They are 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 timer
mode configuration (see Table 95 to Table 98).
INTERRUPT
TF0
GATE
INT0
Timer/Counter 0 and Timer/Counter 1 Operating Modes
This section describes the operating modes for Timer/Counter 0
and Timer/Counter 1. Unless otherwise noted, these modes of
operation are the same for both Timer 0 and Timer 1.
Rev. 0 | Page 95 of 128
Figure 83. Timer/Counter 0, Mode 1
ADE7518
Mode 2 (8-Bit Timer/Counter with Autoreload)
TIMER 2
Mode 2 configures the timer register as an 8-bit counter (TL0)
with automatic reload, as shown in Figure 84. 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.
Timer/Counter 2 Data Registers
fCORE
C/T0 = 0
TL0
(8 BITS)
INTERRUPT
TF0
Timer/Counter 2 Operating Modes
C/T0 = 1
P0.6/T0
CONTROL
TR0
INT0
07327-084
RELOAD
TH0
(8 BITS)
GATE
Figure 84. Timer/Counter 0, Mode 2
Mode 3 (Two 8-Bit Timer/Counters)
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 85.
TL0 uses the Timer 0 control bits, C/T0, Gate0 (see Table 92),
TR0, TF0 (see Table 93), and INT0. TH0 is locked into a timer
function (counting machine cycles) and takes over the use of
TR1 and TF1 from Timer 1. Therefore, TH0 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 be used
by the serial interface as a baud rate generator. In fact, Timer 1
can be used in any application not requiring an interrupt from
Timer 1 itself.
CORE
CLK/12
fCORE
C/T0 = 0
TL0
(8 BITS)
INTERRUPT
TF0
C/T0 = 1
P0.6/T0
CONTROL
TR0
GATE
INT0
TH0
(8 BITS)
INTERRUPT
TF1
07327-085
fCORE/12
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 (RCAP2H, 0xCB), and Timer 2 Reload/Capture Low Byte
SFR (RCAP2L, 0xCA). These are used as both timer data registers
and as timer capture/reload registers (see Table 99 to Table 102).
TR1
Figure 85. Timer/Counter 0, Mode 3
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 94 and Table 103.
Table 103. T2CON Operating Modes
RCLK or TCLK
0
0
1
X
CAP2
0
1
X
X
TR2
1
1
1
0
Mode
16-bit autoreload
16-bit capture
Baud rate
Off
16-Bit Autoreload Mode
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 both the
Timer 2 Reload/Capture High Byte SFR (RCAP2H, 0xCB) and
Timer 2 Reload/Capture Low Byte SFR (RCAP2L, 0xCA)
registers, which are preset by software. If EXEN2 = 1, Timer 2
performs the same events as when EXEN2 = 0 but adds a 1-to-0
transition at the external input T2EX, which triggers the 16-bit
reload and sets EXF2. Autoreload mode is shown in Figure 86.
16-Bit Capture Mode
Capture mode has two options that are selected by Bit EXEN2
in Timer/Counter 2 Control SFR (T2CON, 0xC8). 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 performs the same events
as when EXEN2 = 0 but adds a l-to-0 transition on external
input T2EX, which causes the current value in the Timer 2
registers, TL2 and TH2, to be captured into the RCAP2L and
RCAP2H registers, 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 87.
The 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 and do not have to be disabled. In this mode, the EXF2 flag
can, however, still cause interrupts that can be used as a third
external interrupt. Baud rate generation is described as part of the
UART serial port operation in the UART Serial Interface section.
Rev. 0 | Page 96 of 128
ADE7518
fCORE
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
P1.3/
T2EX
EXF2
07327-086
CONTROL
EXEN2
Figure 86. Timer/Counter 2, 16-Bit Autoreload Mode
fCORE
C/ T2 = 0
TL2
(8 BITS)
C/ T2 = 1
P1.4/T2
TH2
(8 BITS)
TF2
CONTROL
TR2
TIMER
INTERRUPT
CAPTURE
TRANSITION
DETECTOR
RCAP2L
RCAP2H
P1.3/
T2EX
EXF2
07327-087
CONTROL
EXEN2
Figure 87. Timer/Counter 2, 16-Bit Capture Mode
Rev. 0 | Page 97 of 128
ADE7518
PLL
The ADE7518 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 savings
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 MHz/5 MHz, or 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
POWCON SRF, a key is required to modify the register. First,
the Key SFR (KYREG, 0xC1) is written with the key, 0xA7, and
then a new value is written to the POWCON SFR.
If the PLL loses lock, the MCU is reset and the PLL_FLT bit is
set in the Peripheral Configuration SFR (PERIPH, 0xF4). Set
the PLLACK bit in the Start ADC Measurement SFR (ADCGO,
0xD8) to acknowledge the PLL fault, clearing the PLL_FLT bit.
PLL REGISTERS
Table 104. Power Control SFR (POWCON, 0xC5)
Bit
7
6
Mnemonic
Reserved
METER_OFF
Default
1
0
5
4
3
2 to 0
Reserved
COREOFF
Reserved
CD[2:0]
0
0
010
Description
Reserved.
Set this bit to turn off the modulators and energy metering DSP circuitry to reduce power if metering
functions are not needed in PSM0.
This bit should be kept at 0 for proper operation.
Set this bit to shut down the core if in PSM1 operating mode.
Reserved.
Controls the core clock frequency (fCORE). fCORE = 4.096 MHz/2CD.
CD[2:0]
Result (fCORE in MHz)
000
4.096
001
2.048
010
1.024
011
0.512
100
0.256
101
0.128
110
0.064
111
0.032
Writing to the Power Control SFR (POWCON, 0xC5)
Note that writing data to the POWCON SFR involves writing 0xA7 into the Key SFR (KYREG, 0xC1) followed by a write to the
POWCON SFR.
Table 105. Key SFR (KYREG, 0xC1)
Bit
7 to 0
Mnemonic
KYREG
Default
0
Description
Write 0xA7 to the KYREG SFR before writing to the POWCON SFR to unlock it.
Write 0xEA to the KYREG SFR before writing to the INTPR, HTHSEC, SEC, MIN, or HOUR timekeeping
registers to unlock it.
Rev. 0 | Page 98 of 128
ADE7518
Table 106. Peripheral Configuration SFR (PERIPH, 0xF4)
Bit
7
6
Mnemonic
RXFLAG
VSWSOURCE
Default
0
1
5
4
3
2
1 to 0
VDD_OK
PLL_FLT
REF_BAT_EN
Reserved
RXPROG[1:0]
1
0
0
0
00
Description
If this bit is set, indicates that an Rx edge event triggered wake-up from PSM2.
Indicates the power supply that is connected internally to VSWOUT. If this bit is set, VSWOUT =
VDD. If this bit is cleared, VSWOUT = VBAT.
If this bit is set, indicates that VDD power supply is acceptable for operation.
If this bit is set, indicates that PLL is not locked.
If this bit is set, the internal voltage reference is enabled in PSM2 mode.
This bit should be kept to zero.
Controls the function of the P1.0/RxD pin.
RXPROG[1:0]
Result
00
GPIO
01
Rx with wake-up disabled
11
Rx with wake-up enabled
Table 107. Start ADC Measurement SFR (ADCGO, 0xD8)
Bit
7
Address
0xDF
Mnemonic
PLL_FTL_ACK
Default
0
6 to 0
0xDE to 0xD8
Reserved
0
Description
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.
Rev. 0 | Page 99 of 128
ADE7518
REAL-TIME CLOCK
The ADE7518 has an embedded real-time clock (RTC), as
shown in Figure 88. 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 power saving modes. The RTC
counters retain their values through watchdog resets and
external resets. They are only reset during a power-on reset.
32.768kHz
CRYSTAL
RTCCOMP
TEMPCAL
CALIBRATION
CALIBRATED
32.768kHz
RTCEN
ITS1
ITEN
MINUTES COUNTER
MIN
SFR
TIMECON
HTHSEC
Address
0xA1
0xA2
SEC
MIN
HOUR
INTVAL
RTCCOMP
0xA3
0xA4
0xA5
0xA6
0xF6
TEMPCAL
0xF7
MOV
KYREG,#0EAh
MOV
INTPR,#080h
MIDNIGHT EVENT
8-BIT
INTERVAL COUNTER
EQUAL?
INTVAL SFR
ALARM
EVENT
07327-088
HOURS COUNTER
HOUR
Table 108. Real-Time Clock SFR
Description
RTC Configuration (see Table 109).
Hundredths of a Second Counter
(see Table 110).
Seconds Counter (see Table 111).
Minutes Counter (see Table 112).
Hours Counter (see Table 113).
Alarm Interval (see Table 114).
RTC Nominal Compensation
(see Table 115).
RTC Temperature Compensation
(see Table 116).
To protect the RTC from runaway code, a key must be written
to the KYREG register to obtain write access to the Interrupt
Pins Configuration SFR (INTPR, 0xFF), Hundredths of a
Second Counter SFR (HTHSEC, 0xA2), Seconds Counter SFR
(SEC, 0xA3), Minutes Counter SFR (MIN, 0xA4), and Hours
Counter SFR (HOUR, 0xA5). KYREG should be set to 0xEA to
unlock it and reset it to zero after a timekeeping register is
written to. The RTC registers can be written using the following
8052 assembly code:
HUNDREDTHS COUNTER
HTHSEC
INTERVAL
TIMEBASE
SELECTION
MUX
Note that all the real-time clock SFRs are not bit addressable.
Protecting the RTC from Runaway Code
ITS0
8-BIT
PRESCALER
SECONDS COUNTER
SEC
RTC REGISTERS
Figure 88. RTC Implementation
Rev. 0 | Page 100 of 128
ADE7518
Table 109. RTC Configuration SFR (TIMECON, 0xA1)
Bit
7
Mnemonic
MIDNIGHT
Default
0
6
TFH
0
5 to 4
ITS[1:0]
00
3
SIT
0
2
ALARM
0
1
ITEN
0
0
Reserved
1
Description
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 24-hour mode, the midnight flag is raised once a
day at midnight. When this interrupt is used for wake-up from PSM2 to PSM1, the RTC interrupt must be
serviced and the flag cleared to be allowed to enter PSM2.
24-Hour Mode. This bit is retained during a watchdog reset or an external reset. It is reset after a poweron reset (POR).
TFH
Result
0
256-Hour Mode. The HOUR register rolls over from 255 to 0.
1
24-Hour Mode. The HOUR register rolls over from 23 to 0.
Interval Timer Time Base Selection.
ITS[1:0]
Result (Time Base)
00
1/128 sec.
01
Second.
10
Minute.
11
Hour.
Interval Timer 1 Alarm.
SIT
Result
0
The ALARM flag is set after INTVAL counts and then another interval count starts.
1
The ALARM flag is 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. This bit cannot be set to 1 by user code.
Interval Timer Enable.
ITEN
Result
0
The interval timer is disabled. The 8-bit interval timer counter is reset.
1
Set this bit to enable the interval timer.
This bit must be left set for proper operation.
Table 110. Hundredths of a Second Counter SFR (HTHSEC, 0xA2)
Bit
7 to 0
Mnemonic
HTHSEC
Default
0
Description
This counter updates every 1/128 second, referenced from the calibrated 32.768 kHz clock. It overflows
from 127 to 00, incrementing the seconds counter (SEC). This register is retained during a watchdog
reset or an external reset. It is reset after a POR.
Table 111. Seconds Counter SFR (SEC, 0xA3)
Bit
7 to 0
Mnemonic
SEC
Default
0
Description
This counter updates every second, referenced from the calibrated 32.768 kHz clock. It overflows from 59 to
00, incrementing the minutes counter (MIN). This register is retained during a watchdog reset or an
external reset. It is reset after a POR.
Table 112. Minutes Counter SFR (MIN, 0xA4)
Bit
7 to 0
Mnemonic
MIN
Default
0
Description
This counter updates every minute, referenced from the calibrated 32.768 kHz clock. It overflows from 59 to
00, incrementing the hours counter (HOUR). This register is retained during a watchdog reset or an
external reset. It is reset after a POR.
Table 113. Hours Counter SFR (HOUR, 0xA5)
Bit
7 to 0
Mnemonic
HOUR
Default
0
Description
This counter updates every hour, referenced from the calibrated 32.768 kHz 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 is cleared, the HOUR SFR overflows from
255 to 00, setting the MIDNIGHT bit and creating a pending RTC interrupt. This register is retained during
a watchdog reset or an external reset. It is reset after a POR.
Rev. 0 | Page 101 of 128
ADE7518
Table 114. Alarm Interval SFR (INTVAL, 0xA6)
Bit
7 to 0
Mnemonic
INTVAL
Default
0
Description
The interval timer counts according to the time base 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 eight bits. Therefore, it can count up to
255 seconds, for example.
Table 115. RTC Nominal Compensation SFR (RTCCOMP, 0xF6)
Bit
7 to 0
Mnemonic
RTCCOMP
Default
0
Description
The RTCCOMP SFR holds the nominal RTC compensation value at 25°C. This register is retained during
a watchdog reset or an external reset. It is reset after a POR.
Table 116. RTC Temperature Compensation SFR (TEMPCAL, 0xF7)
Bit
7 to 0
Mnemonic
TEMPCAL
Default
0
Description
The TEMPCAL SFR is adjusted based on a temperature read. This allows the external crystal shift to be
compensated over temperature. This register is retained during a watchdog reset or an external reset.
It is reset after a POR.
Table 117. Interrupt Pins Configuration SFR (INTPR, 0xFF)
Bit
7
Mnemonic
RTCCAL
Default
0
6 to 5
FSEL[1:0]
00
4
3 to 1
Reserved
INT1PRG[2:0]
0
000
Description
Controls the RTC calibration output. When set, the RTC calibration frequency selected by FSEL[1:0] is
output on the P0.2/CF1/RTCCAL pin.
Sets RTC calibration output frequency and calibration window.
FSEL[1:0]
Result (Calibration Window, Frequency)
00
30.5 sec, 1 Hz
01
30.5 sec, 512 Hz
10
0.244 sec, 500 Hz
11
0.244 sec, 16.384 kHz
This bit must be set to 0 for proper operation.
Controls the function of INT1.
INT1PRG[2:0]
x00
x01
01x
11x
0
INT0PRG
0
Result
GPIO
BCTRL
INT1 input disabled
INT1 input enabled
Controls the function of INT0.
INT0PRG
0
1
Result
INT0 input disabled
INT0 input enabled
Table 118. Key SFR (KYREG, 0xC1)
Bit
7 to 0
Mnemonic
KYREG
Default
0
Description
Write 0xA7 to this SFR before writing to the POWCON SFR, which unlocks KYREG.
Write 0xEA to this SFR before writing to the INTPR, HTHSEC, SEC, MIN, or HOUR timekeeping registers
to unlock KYREG.
Rev. 0 | Page 102 of 128
ADE7518
READ AND WRITE OPERATIONS
RTC MODES
Writing to the RTC Registers
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 TIMECON SFR, and a pending RTC interrupt is
created. The RTC midnight event wakes the 8052 MCU core if
the MCU is asleep in PSM2 when the midnight event occurs.
The RTC circuitry runs off a 32.768 kHz clock. The timekeeping
registers, Hundredths of a Second Counter SFR (HTHSEC, 0xA2),
Seconds Counter SFR (SEC, 0xA3), Minutes Counter SFR (MIN,
0xA4), and Hours Counter SFR (HOUR, 0xA5), are updated
with a 32.768 kHz clock. However, the RTC Configuration SFR
(TIMECON, 0xA1) and Alarm Interval SFR (INTVAL, 0xA6)
are updated with a 128 Hz clock. It takes up to two 128 Hz clock
cycles from when the MCU writes to the TIMECON SFR or the
INTVAL SFR until there is a successful update in the RTC.
To protect the RTC timekeeping registers from runaway code,
a key must be written to the Key SFR (KYREG, 0xC1), which is
described in Table 105, to obtain write access to the HTHSEC,
SEC, MIN, and HOUR SFRs. KYREG should be set to 0xEA to
unlock the timekeeping registers and reset to 0 after a timekeeping
register is written to. The RTC registers can be written to using
the following 8052 assembly code:
MOV
RTCKey,#0EAh
CALL
UpdateRTC
…
UpdateRTC:
MOV
KYREG,RTCKey
MOV
SEC,#30
MOV
KYREG,RTCKey
MOV
MIN,#05
MOV
KYREG,RTCKey
MOV
HOUR,#04
MOV
KYREG,#00h
Reading the RTC Counter SFRs
The RTC cannot be stopped to read the current time because
stopping the RTC introduces an error in its timekeeping.
Therefore, the RTC is read on the fly, and the counter registers
must be checked for overflow. This can be accomplished
through the following 8052 assembly code:
ReadAgain:
R0,HTHSEC
MOV
R1,SEC
MOV
R2,MIN
MOV
R3,HOUR
MOV
A,HTHSEC
RTC INTERRUPTS
The RTC midnight interrupt and alarm interrupt 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 vectors to the RTC interrupt address and the pending
interrupt is cleared. If the RTC interrupt is disabled, the RTC
interrupt remains pending until the RTC interrupt is enabled.
The program then vectors to the RTC interrupt address.
The MIDNIGHT flag and ALARM flag are set when the midnight event and alarm event 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 interrupt servicing routine.
RET
MOV
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 results in power savings during extended operation in
PSM2 because the MCU core wakes up less frequently.
; using Bank 0
CJNE A, 00h, ReadAgain ; 00h is R0 in
Bank 0
Note that if the ADE7518 is awakened by an RTC event, either
by the MIDNIGHT event or the ALARM event, the pending
RTC interrupt must be serviced before the device can go back
to sleep again. The ADE7518 keeps waking up until this interrupt has been serviced.
Interval Timer Alarm
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 an 8-bit counter. This
counter increments on every interval timer clock pulse until it 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 cleared, the 8-bit
counter is also cleared and starts counting again. If the SIT bit is
set, the 8-bit counter is held in reset after the alarm occurs.
Rev. 0 | Page 103 of 128
ADE7518
Take care when changing the interval timer time base. The
recommended procedure is as follows:
with FSEL[1:0] = 00 and 512 Hz with FSEL[1:0] = 01 in the
Interrupt Pins Configuration SFR (INTPR, 0xFF).
1.
A shorter window of 0.244 sec is offered for fast calibration
during PSM0 or PSM1. Two output frequencies are offered for
this RTC calibration output mode: 500 Hz with FSEL[1:0] = 10
and 16.384 kHz with FSEL[1:0] = 11 in the INTPR SFR. Note
that for the 0.244 sec calibration window, the RTC is clocked
125 times faster than in normal mode, resulting in timekeeping
registers that represent seconds/125, minutes/125, and hours/125
instead of seconds, minutes, and hours. Therefore, this mode
should be used for calibration only.
2.
3.
4.
If the Alarm Interval SFR (INTVAL, 0xA6) is going to
be modified, write to this register first. Then, wait for
one 128 Hz clock cycle to synchronize with the RTC,
64,000 cycles at a 4.096 MHz instruction cycle clock.
Disable the interval timer by clearing the ITEN bit in the
RTC Configuration SFR (TIMECON, 0xA1). Then, wait
for one 128 Hz clock cycle to synchronize with the RTC,
64,000 cycles at a 4.096 MHz instruction cycle clock.
Read the TIMECON SFR to ensure that the ITEN bit is
clear. If it is not, wait for another 128 Hz clock cycle.
Set the time base bits (ITS[1:0]) in the TIMECON SFR to
configure the interval. Wait for a 128 Hz clock cycle for this
change to take effect.
The RTC alarm event wakes the 8052 MCU core if the MCU is
in PSM2 when the alarm event occurs.
RTC CALIBRATION
The RTC provides registers to calibrate the nominal external
crystal frequency and its variation over temperature. A frequency
error up to ±248 ppm can be calibrated by the RTC circuitry,
which adds or subtracts pulses from the external crystal signal.
The nominal crystal frequency should be calibrated with the
RTC nominal compensation 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
±2 ppm 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. Note that
the sum of these two registers is limited to ±248 ppm.
Table 119. RTC Calibration Options
Option
Normal Mode 0
Normal Mode 1
Calibration Mode 0
Calibration Mode 1
The RTC calibration is accurate to within ±2 ppm over a 30.5 sec
window in all operational modes: PSM0, PSM1, and PSM2. Two
output frequencies are offered for the normal RTC mode: 1 Hz
Calibration
Window (Sec)
30.5
30.5
0.244
0.244
fRTCCAL (Hz)
1
512
500
16,384
When no RTC compensation is applied, that is, when RTC
Nominal Compensation SFR (RTCCOMP, 0xF6) and RTC
Temperature Compensation SFR (TEMPCAL, 0xF7) are equal
to 0, the nominal compensation required to account for the
error in the external crystal can be determined. In this case, it is
not necessary to wait for an entire calibration window to determine
the error in the pulse output. Calculating the error in frequency
between two consecutive pulses on the P0.2/CF1/RTCCAL pin
is sufficient.
The value to write to the RTC Nominal Compensation SFR
(RTCCOMP, 0xF6) is calculated from the % error or seconds per
day error on the frequency output. Each LSB of the RTCCOMP
SFR represents 2 ppm of correction where 1 sec/day error is
equal to 11.57 ppm.
RTCCOMP = 5000 × (% Error )
RTCCOMP =
Calibration Flow
An RTC calibration pulse output is provided on the P0.2/CF1/
RTCCAL pin. Enable the RTC output by setting the RTCCAL
bit in the Interrupt Pins Configuration SFR (INTPR, 0xFF).
FSEL[1:0]
00
01
10
11
1
× (sec/day Error )
2 × 11.57
During calibration, user software writes the RTC with the
current time. Refer to the Read and Write Operations section
for more information on how to read and write the RTC
timekeeping registers.
Rev. 0 | Page 104 of 128
ADE7518
UART SERIAL INTERFACE
The ADE7518 UART can be configured in one of four modes.
•
•
•
•
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 baud/sec and 115,200 baud/sec.
The UART serial interface provided in the ADE7518 is a fullduplex serial interface. It is also receive-buffered by storing the
first received byte in a receive buffer until the reception of the
second byte is complete. The physical interface to the UART is
provided via the RxD (P1.0) and TxD (P1.1) pins, whereas the
firmware interface is through the SFRs presented in Table 120.
Both the serial port receive and transmit registers are accessed
through the Serial Port Buffer SFR (SBUF, 0x99). Writing to
SBUF loads the transmit register, and reading SBUF accesses a
physically separate receive register.
An enhanced UART mode is offered by using the UART timer
and by providing enhanced frame error, break error, and overwrite
error detection. This mode is enabled by setting the EXTEN bit
in the Configuration SFR (CFG, 0xAF) (see the UART Additional
Features section). The Enhanced Serial Baud Rate Control SFR
(SBAUDT, 0x9E) and UART Timer Fractional Divider SFR
(SBAUDF, 0x9D) are used to configure the UART timer and to
indicate the enhanced UART errors.
UART REGISTERS
Table 120. Serial Port SFRs
SFR
SCON
SBUF
SBAUDT
SBAUDF
Address
0x98
0x99
0x9E
0x9D
Bit Addressable
Yes
No
No
No
Description
Serial Communications Control Register (see Table 121).
Serial Port Buffer (see Table 122).
Enhanced Serial Baud Rate Control (see Table 123).
UART Timer Fractional Divider (see Table 124).
Table 121. Serial Communications Control Register SFR (SCON, 0x98)
Bit
7 to 6
Address
0x9F, 0x9E
Mnemonic
SM0, SM1
Default
00
5
0x9D
SM2
0
4
0x9C
REN
0
3
0x9B
TB8
0
2
0x9A
RB8
0
1
0x99
TI
0
0
0x98
RI
0
Description
UART Serial Mode Select Bits. These bits select the serial port operating mode.
SM[1:0]
Result (Selected Operating Mode)
00
Mode 0, shift register, fixed baud rate at fCORE/12.
01
Mode 1, 8-bit UART, variable baud rate.
10
Mode 2, 9-bit UART, fixed baud rate at fCORE/32 or fCORE/16.
11
Mode 3, 9-bit UART, variable baud rate.
Multiprocessor Communication Enable Bit. Enables multiprocessor communication in
Mode 2 and Mode 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.
In Mode 2 or Mode 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.
Serial Port Receive Enable Bit. Set by user software to enable serial port reception.
Cleared by user software to disable serial port reception.
Serial Port Transmit Bit 9. The data loaded into TB8 is the ninth data bit transmitted in
Mode 2 and Mode 3.
Serial Port Receiver Bit 9. The ninth data bit received in Mode 2 and Mode 3 is latched
into RB8. For Mode 1, the stop bit is latched into RB8.
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 Mode 1, Mode 2, and Mode 3.
TI must be cleared by user software.
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 Mode 1, Mode 2, and Mode 3.
RI must be cleared by user software.
Rev. 0 | Page 105 of 128
ADE7518
Table 122. Serial Port Buffer SFR (SBUF, 0x99)
Bit
7 to 0
Mnemonic
SBUF
Default
0
Description
Serial Port Data Buffer.
Table 123. Enhanced Serial Baud Rate Control SFR (SBAUDT, 0x9E)
Bit
7
Mnemonic
OWE
Default
0
6
FE
0
5
BE
0
4, 3
2 to 0
SBTH[1:0]
DIV[2:0]
0
000
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. Write a 0 to
this bit to clear it.
Frame Error. This bit is set when the received frame does not have a valid stop bit. This bit is read
only and is 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, which is the time required for a start bit, eight 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 125.
Binary Divider. See Table 125.
DIV[2:0]
Result
000
Divide by 1.
001
Divide by 2.
010
Divide by 4.
011
Divide by 8.
100
Divide by 16.
101
Divide by 32.
110
Divide by 64.
111
Divide by 128.
Table 124. UART Timer Fractional Divider SFR (SBAUDF, 0x9D)
Bit
7
Mnemonic
UARTBAUDEN
Default
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 this bit is set, PCON[7] (SMOD), T2CON[4] (TCLK), and T2CON[5] (RCLK) 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.
Rev. 0 | Page 106 of 128
ADE7518
Table 125. Common Baud Rates Using UART Timer with a 4.096 MHz PLL Clock
Ideal Baud
115,200
115,200
57,600
57,600
38,400
38,400
38,400
19,200
19,200
19,200
19,200
9600
9600
9600
9600
9600
4800
4800
4800
4800
4800
4800
2400
2400
2400
2400
2400
2400
2400
300
300
300
300
300
300
300
300
CD
0
1
0
1
0
1
2
0
1
2
3
0
1
2
3
4
0
1
2
3
4
5
0
1
2
3
4
5
6
0
1
2
3
4
5
6
7
SBTH
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2
1
0
0
0
0
0
0
DIV
1
0
2
1
2
1
0
3
2
1
0
4
3
2
1
0
5
4
3
2
1
0
6
5
4
3
2
1
0
7
7
7
6
5
4
3
2
SBAUDT
0x01
0x00
0x02
0x01
0x02
0x01
0x00
0x03
0x02
0x01
0x00
0x04
0x03
0x02
0x01
0x00
0x05
0x04
0x03
0x02
0x01
0x00
0x06
0x05
0x04
0x03
0x02
0x01
0x00
0x17
0x0F
0x07
0x06
0x05
0x04
0x03
0x02
Rev. 0 | Page 107 of 128
SBAUDF
0x87
0x87
0x87
0x87
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
0xAB
% Error
+0.16
+0.16
+0.16
+0.16
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
−0.31
ADE7518
All of the following conditions must be met at the time the final
shift pulse is generated to receive a character:
UART OPERATION MODES
Mode 0 (Shift Register with Baud Rate Fixed at fCORE/12)
Mode 0 is selected when the SM0 and SM1 bits in the Serial
Communications Control Register Bit Description SFR (SCON,
0x98) are cleared. 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 the
Serial Port Buffer SFR (SBUF, 0x99). The data is shifted out of
the RxD line. The eight bits are transmitted with the least
significant bit (LSB) first.
DATA BIT 1
DATA BIT 6
If the received frame has met the previous criteria, the following
events occur:
•
DATA BIT 7
07327-089
DATA BIT 0
TxD
(SHIFT CLOCK)
Mode 1 (8-Bit UART, Variable Baud Rate)
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.
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, the 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 the Serial Port Buffer SFR
(SBUF, 0x99). Next, a stop bit (1) is loaded into the ninth 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 90.
TxD
STOP BIT
D0
D1
D2
D3
D4
D5
D6
•
•
The eight bits in the receive shift register are latched into
the SBUF SFR.
The ninth bit (stop bit) is clocked into RB8 in the SCON SFR.
The receiver interrupt flag (RI) is set.
Mode 2 (9-Bit UART with Baud Fixed at fCORE/64 or fCORE/32)
Figure 89. 8-Bit Shift Register Mode
START
BIT
•
If the extended UART is disabled (EXTEN = 0 in the CFG
SFR), RI must be 0 to receive a character. This ensures that
the data in the SBUF SFR is not 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 bit and a stop bit.
If any of these conditions are not met, the received frame is
irretrievably lost, and the receive interrupt flag (RI) is not set.
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 89.
RxD
(DATA OUT)
•
D7
SET INTERRUPT
(FOR EXAMPLE,
READY FOR MORE DATA)
Figure 90. 8-Bit Variable Baud Rate
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 eight data bits are clocked into the
serial port shift register.
07327-090
TI
(SCON.1)
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 setting the
SMOD bit in the Program Control SFR (PCON, 0x87) doubles
the frequency to fCORE/32. Eleven bits are transmitted or received:
a start bit (0), eight data bits, a programmable ninth bit, and a
stop bit (1). The ninth 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 ninth data bit as part of a communication protocol for
a multiprocessor network such as RS-485, the ninth bit is set to
indicate that the frame contains the address of the device with
which the master wants to communicate. The devices on the
network are always listening for a packet with the ninth bit set
and are configured such that if the ninth bit is cleared, the frame
is not valid, and a receive interrupt is not generated. If the ninth
bit is set, all devices on the network receive the address and obtain a
receive character interrupt. The devices examine the address and,
if it matches one of the device’s preprogrammed addresses, that
device configures itself to listen to all incoming frames, even those
with the ninth bit cleared. Because the master has initiated
communication with that device, all the following packets with
the ninth bit cleared are intended specifically for that addressed
device until another packet with the ninth bit set is received. If
the address does not match, the device continues to listen for
address packets.
Rev. 0 | Page 108 of 128
ADE7518
To transmit, the eight data bits must be written into the Serial
Port Buffer SFR (SBUF, 0x99). The ninth bit must be written
to TB8 in the Serial Communications Control Register SFR
(SCON, 0x98). When transmission is initiated, the eight data
bits from SBUF are loaded into the transmit shift register (LSB
first). The ninth data bit, held in TB8, is loaded into the ninth
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 completes, 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 0 to receive a character. This ensures that
the data in SBUF is not overwritten if the last received
character has not been read.
If multiprocessor communication is enabled by setting
SM2, the received ninth bit must be set to receive a character.
This ensures that only frames with the ninth bit set, that is,
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 eight
data bytes are input at RxD (LSB first) and loaded onto the
receive shift register. If the received frame has met the previous
criteria, the following events occur:
•
•
•
The eight bits in the receive shift register are latched into
the SBUF SFR.
The ninth data bit is latched into RB8 in the SCON SFR.
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 8052 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
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, the 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.
⎛f
⎞
Mode 0 Baud Rate = ⎜ CORE ⎟
⎝ 12 ⎠
Mode 2 Baud Rate Generation
The baud rate in Mode 2 depends on the value of the PCON[7]
(SMOD) bit in the Program Control SFR (PCON, 0x87). 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 =
2SMOD
× fCORE
32
Mode 1 and Mode 3 Baud Rate Generation
The baud rates in Mode 1 and Mode 3 are determined by the
overflow rate of the timer generating the baud rate, that is,
either Timer 1, 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 Mode 1 and Mode 3 are determined by the Timer 1 overflow
rate. The value of SMOD is as follows:
Mode 1 or Mode 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, 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 following formula:
SMOD
Mode 1 or Mode 3 Baud Rate = 2
×
32
f CORE
( 256 − TH1)
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 possible.
Mode 1 or Mode 3 Baud Rate =
1
× Timer 2 Overflow Rate
16
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. Timer 2 is selected as the baud rate
generator by setting TCLK and/or RCLK in Timer/Counter 2
Control SFR (T2CON, 0xC8). The baud rates for transmit and
receive can be simultaneously different. Setting RCLK and/or
Rev. 0 | Page 109 of 128
ADE7518
TCLK puts Timer 2 into its baud rate generator mode, as shown
in Figure 92.
fCORE
TIMER 1/TIMER 2
Tx CLOCK
FRACTIONAL ÷(1 + SBAUDF/64)
DIVIDER
In this case, the baud rate is given by the following formula:
Mode 1 or Mode 3 Baud Rate =
fCORE
(16 × [65536 − (RCAP2H : RCAP2L )])
TIMER 1/TIMER 2
Rx CLOCK
1
0
1
0
÷2DIV + SBTH
÷32
UART Timer Generated Baud Rates
UARTBAUDEN
UART TIMER
Rx/Tx CLOCK
The high integer dividers in a UART block mean that high speed
baud rates are not always possible. In addition, 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, each ADE7518 has a dedicated baud rate timer
(UART timer) specifically for generating highly accurate baud
rates. The UART timer can be used instead of Timer 1 or Timer 2
for generating very accurate high speed UART baud rates,
including 115,200 bps. This timer also allows a much wider
range of baud rates to be obtained. In fact, every desired bit rate
from 12 bps to 393,216 bps can be generated to within an error
of ±0.8%. The UART timer also frees up the other three timers,
allowing them to be used for different applications. A block
diagram of the UART timer is shown in Figure 91.
Tx CLOCK
Figure 91. 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 the UART timer. SBAUDT is the
baud rate control SFR; it sets up the integer divider (DIV) and
the extended divider (SBTH) for the UART timer.
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 the POWCON SFR (see Table 24). Note that the DIV
value must be rounded down to the nearest integer.
⎛
⎞
f CORE
⎟
log⎜
⎜ 16 × Baud Rate ⎟
⎝
⎠
DIV + SBTH =
log(2)
TIMER 1
OVERFLOW
2
0
fCORE
SMOD
C/ T2 = 0
TH2
(8 BITS)
TIMER 2
OVERFLOW
1
0
RCLK
C/ T2 = 1
16
1
TR2
T2EX
PIN
Rx
CLOCK
0
TCLK
RELOAD
NOTE: AVAILABILITY OF ADDITIONAL
EXTERNAL INTERRUPT
16
RCAP2L
EXF 2
RCAP2H
Tx
CLOCK
TIMER 2
INTERRUPT
CONTROL
07327-092
TRANSITION
DETECTOR
1
CONTROL
TL2
(8 BITS)
T2
PIN
07327-091
Rx CLOCK
EXEN2
Figure 92. Timer 2, UART Baud Rates
Rev. 0 | Page 110 of 128
ADE7518
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:
D0
D1
D2
D3
D4
D5
D6
D7
STOP
D8
STOP
RI
FE
EXTEN = 1
Figure 93. UART Timing in Mode 1
Note that SBAUDF should be rounded to the nearest integer.
After the values for DIV and SBAUDF are calculated, the actual
baud rate can be calculated with the following formula:
Rx
START
D0
D1
D2
D3
D4
D5
D6
D7
f CORE
16 × 2 DIV + SBTH × ⎛⎜1 +
⎝
RI
SBAUDF ⎞
⎟
64
⎠
07327-094
Actual Baud Rate =
START
07327-093
⎛
⎞
fCORE
SBAUDF = 64 × ⎜
− 1⎟
⎜ 16 × 2 DIV + SBTH × Baud Rate
⎟
⎝
⎠
Rx
FE
EXTEN = 1
For example, to obtain a baud rate of 9600 bps while operating
at a core clock frequency of 4.096 MHz with the PLL CD bits
equal to 0,
4,096,000 ⎞
log⎛⎜
⎟
⎝ 16 × 9600 ⎠
DIV + SBTH =
= 4.74 = 4
log(2)
Note that the DIV result is rounded down.
4,096,000
SBAUDF = 64 × ⎛⎜
− 1⎞⎟ = 42.67 = 0x2B
⎝ 16 × 2 3 × 9600 ⎠
Thus, the actual baud rate is 9570 bps, resulting in a 0.31% error.
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 whether the Rx line has been
low for longer than a 9-bit frame. It indicates that the data just
received, a 0 or null character, is not valid because the master has
disconnected. Overwrite error detection indicates when the
received data has not been read fast enough and, as a result, a
byte of data has been lost.
The 8052 standard UART offers frame-error checking for an 8-bit
UART through the SM2 and RB8 bits. Setting the SM2 bit prevents
frames without a stop bit from being received. The stop bit is
latched into the RB8 bit in the Serial Communications Control
Register SFR (SCON, 0x98). 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 Enhanced Serial Baud Rate Control
SFR (SBAUDT, 0x9E). The FE bit is set on framing errors for
both 8-bit and 9-bit UARTs.
Figure 94. UART Timing in Mode 2 and Mode 3
The 8052 standard UART does not provide break error detection.
However, for an 8-bit UART, a break error can be detected when
the received character is 0, a null character, and when there is a
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 ADE7518 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 when the receive interrupt
flag, RI, is set. However, it does not indicate if a character has
been lost because the RI bit is set when the frame is received.
The enhanced UART overwrite error detection provides this
information. When the enhanced 8052 UART is enabled, a
frame is 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 is set. The overwrite error flag is
cleared when SBUF is read.
The extended UART is enabled by setting the EXTEN bit in the
Configuration SFR (CFG, 0xAF).
UART TxD Signal Modulation
There is an internal 38 kHz signal that can be OR’ed 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 RxD pin (see the 3.3 V Peripherals and Wake-Up
Events section).
Rev. 0 | Page 111 of 128
ADE7518
SERIAL PERIPHERAL INTERFACE (SPI)
The ADE7518 integrates a complete hardware serial peripheral
interface on-chip. The SPI is full duplex so that eight bits of data
are synchronously transmitted and simultaneously received.
This SPI implementation is double buffered, allowing users 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.
The SPI port can be configured for master or slave operation. The
physical interface to the SPI is via the MISO (P0.5), MOSI (P0.4),
SCLK (P0.6), and SS (P0.7) pins, whereas the firmware interface
is via the SPI Configuration SFR 1 (SPIMOD1, 0xE8), the SPI
Configuration SFR 2 (SPIMOD2, 0xE9), the SPI Interrupt
Status SFR (SPISTAT, 0xEA), the SPI/I2C Transmit Buffer SFR
(SPI2CTx, 0x9A), and the SPI/I2C 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
Configuration SFR (CFG, 0xAF) selects which peripheral is active.
SPI REGISTERS
Table 126. SPI SFR List
SFR Address
0x9A
0x9B
0xE8
0xE9
0xEA
Name
SPI2CTx
SPI2CRx
SPIMOD1
SPIMOD2
SPISTAT
R/W
W
R
R/W
R/W
R/W
Length (Bits)
8
8
8
8
8
Default
0
0
0x10
0
0
Description
SPI/I2C Transmit Buffer (see Table 127).
SPI/I2C Receive Buffer (see Table 128).
SPI Configuration SFR 1 (see Table 129).
SPI Configuration SFR 2 (see Table 130).
SPI Interrupt Status (see Table 131).
Table 127. SPI/I2C Transmit Buffer SFR (SPI2CTx, 0x9A)
Bit
7 to 0
Mnemonic
SPI2CTx
Default
0
Description
SPI or I2C Transmit Buffer. When SPI2CTx SFR is written, its content is transferred to the transmit FIFO
input. When a write is requested, the FIFO output is sent on the SPI or I2C bus.
Table 128. SPI/I2C Receive Buffer SFR (SPI2CRx, 0x9B)
Bit
7 to 0
Mnemonic
SPI2CRx
Default
0
Description
SPI or I2C Receive Buffer. When SPI2CRx SFR is read, one byte from the receive FIFO output is
transferred to the SPI2CRx SFR. A new data byte from the SPI or I2C bus is written to the FIFO input.
Rev. 0 | Page 112 of 128
ADE7518
Table 129. SPI Configuration SFR 1 (SPIMOD1, 0xE8)
Bit
7 to 6
5
Address
0xEF to 0xEE
0xED
Mnemonic
Reserved
INTMOD
Default
0
0
4
0xEC
AUTO_SS
1
Description
Reserved.
SPI Interrupt Mode.
INTMOD
Result
0
SPI interrupt is set when SPI Rx buffer is full.
1
SPI interrupt is set when SPI Tx buffer is empty.
Master Mode, SS Output Control (see Figure 95).
AUTO_SS
0
3
0xEB
SS_EN
0
2
0xEA
RxOFW
0
1 to 0
0xE9 to0xE8
SPIR[1:0]
0
Result
The SS pin is held low while this bit is cleared. This allows manual chip select
control using the SS pin.
1
Single Byte Read or Write. The SS pin goes low during a single byte
transmission and then returns high.
Continuous Transfer. The SS pin goes low during the duration of the
multibyte continuous transfer and then returns high.
Slave Mode, SS Input Enable.
When this bit is set to Logic 1, the SS pin is defined as the slave select input pin for the SPI
slave interface.
Receive Buffer Overflow Write Enable.
RxOFW
Result
0
If the SPI2CRx SFR has not been read when a new data byte is received,
the new byte is discarded.
1
If the SPI2CRx SFR has not been read when a new data byte is received,
the new byte overwrites the old data.
Master Mode, SPI SCLK Frequency.
SPIR[1:0] Result
00
fCORE/8 = 512 kHz (if fCORE = 4.096 MHz).
01
fCORE/16 = 256 kHz (if fCORE = 4.096 MHz).
10
fCORE/32 = 128 kHz (if fCORE = 4.096 MHz).
11
fCORE/64 = 64 kHz (if fCORE = 4.096 MHz).
Rev. 0 | Page 113 of 128
ADE7518
Table 130. SPI Configuration SFR 2 (SPIMOD2, 0xE9)
Bit
7
Mnemonic
SPICONT
Default
0
6
SPIEN
0
5
SPIODO
0
4
SPIMS_b
0
3
SPICPOL
0
2
SPICPHA
0
1
SPILSBF
0
0
TIMODE
1
Description
Master Mode, SPI Continuous Transfer Mode Enable Bit.
SPICONT Result
0
The SPI interface stops after one byte is transferred and SS is deasserted. A new data transfer can
be initiated after a stalled period.
1
The SPI interface continues to transfer data until no valid data is available in the SPI2CTx SFR. SS
remains asserted until the SPI2CTx SFR and the transmit shift registers are empty.
SPI Interface Enable Bit.
SPIEN
Result
0
The SPI interface is disabled.
1
The SPI interface is enabled.
SPI Open-Drain Output Configuration Bit.
SPIODO
Result
0
Internal pull-up resistors are connected to the SPI outputs.
1
The SPI outputs are open drain and need external pull-up resistors. The pull-up voltage should
not exceed the specified operating voltage.
SPI Master Mode Enable Bit.
SPIMS_b Result
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 97).
SPICPOL Result
0
The default state of SCLK is low, and the first SCLK edge is rising. Depending on the 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 the 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 97).
SPICPHA Result
0
The SPI data output changes state when SS goes low at the second edge of SCLK and then every
two subsequent edges, whereas 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, whereas the SPI data input is sampled at the second SCLK edge and then every two
subsequent edges.
Master Mode, LSB First Configuration Bit.
SPILSBF
Result
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.
TIMODE Result
1
This bit must be left set for proper operation.
Rev. 0 | Page 114 of 128
ADE7518
Table 131. SPI Interrupt Status SFR (SPISTAT, 0xEA)
Bit
7
Mnemonic
BUSY
Default
0
6
MMERR
0
5
SPIRxOF
0
4
SPIRxIRQ
0
3
2
SPIRxBF
SPITxUF
0
0
1
SPITxIRQ
0
0
SPITxBF
0
Description
SPI Peripheral Busy Flag.
BUSY
Result
0
The SPI peripheral is idle.
1
The SPI peripheral is busy transferring data in slave or master mode.
SPI Multimaster Error Flag.
MMERR
Result
0
A multiple master error has not occurred.
1
If the SS_EN bit is set, enabling the slave select input and asserting the SS pin while the SPI
peripheral is transferring data as a master, this flag is raised to indicate the error.
Write a 0 to this bit to clear it.
SPI Receive Overflow Error Flag. Reading the SPI2CRx SFR clears this bit.
SPIRxOF
TIMODE Result
0
X
The SPI2CRx register contains valid data.
1
1
This bit is set if the SPI2CRx register is not read before the end of the next byte
transfer. If the RxOFW bit is set and this condition occurs, SPI2CRx is overwritten.
SPI Receive Mode Interrupt Flag. Reading the SPI2CRx SFR clears this bit.
SPIRxIRQ TIMODE Result
0
X
The SPI2CRx register does not contain new data.
1
0
This bit is set when the SPI2CRx register contains new data. If the SPI/I2C
interrupt is enabled, an interrupt is generated when this bit is set. If the SPI2CRx
register is not read before the end of the current byte transfer, the transfer stops
and the SS pin is deasserted.
1
1
The SPI2CRx register contains new data.
Status Bit for SPI Rx Buffer. When set, the Rx FIFO is full. A read of the SPI2CRx clears this flag.
Status Bit for SPI Tx Buffer. When set, the Tx FIFO is underflowing and data can be written into SPI2CTx.
Write a 0 to this bit to clear it.
SPI Transmit Mode Interrupt Flag. Writing new data to the SPI2CTx SFR clears this bit.
SPITxIRQ TIMODE Result
0
X
The SPI2CTx register is full.
1
0
The SPI2CTx register is empty.
1
1
This bit is set when the SPI2CTx register is empty. If the SPI/I2C interrupt is
enabled, an interrupt is generated when this bit is set. If new data is not written
into the SPI2CTx SFR before the end of the current byte transfer, the transfer
stops, and the SS pin is deasserted. Write a 0 to this bit to clear it.
Status Bit for SPI Tx Buffer. When set, the SPI Tx buffer is full. Write a 0 to this bit to clear it.
SPI PINS
SCLK (Serial Clock I/O Pin)
MISO (Master In, Slave Out Data 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.
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
(8-bit) 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 (8-bit)
serial data, MSB first.
In master mode, the bit rate, polarity, and phase of the clock are
controlled by the SPI Configuration SFR 1 (SPIMOD1, 0xE8) and
SPI Configuration SFR 2 (SPIMOD2, 0xE9).
In slave mode, the SPI Configuration SFR 2 (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 the SPICPHA and SPICPOL bits be configured
the same for the master and slave devices.
Rev. 0 | Page 115 of 128
ADE7518
In SPI slave mode, a transfer is initiated by the assertion of SS
low. The SPI port then transmits and receives 8-bit data until
the data is concluded by the deassertion of SS according to the
SPICON bit setting. In slave mode, SS is always an input.
Figure 95 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
In SPI master mode, the SS can be used to control data transfer
to a slave device. In 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 SFR 1 (SPIMOD1, 0xE8).
AUTO_SS = 1
SPICONT = 1
DOUT
In a multimaster 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 others. In this case, the slave selects for the
slaves that are controlled by this SPI peripheral should be generated with general I/O pins.
In master mode, the type of transfer is handled automatically,
depending on the configuration of the SPICONT bit in the SPI
Configuration SFR 2 (SPIMOD2, 0xE9). The following procedures show the sequence of events that should be performed for
each master operating mode. Based on the SS configuration,
some of these events take place automatically.
Procedures for Using SPI as a Master
Single Byte Mode—SPICONT (SPIMOD2[7]) = 0
1.
2.
3.
4.
5.
Write to SPI2CTx SFR.
SS is asserted low and a write routine is initiated.
SPITxIRQ interrupt flag is set when the SPI2CTx register
is empty.
SS is deasserted high.
Write to SPI2CTx SFR to clear the SPITxIRQ interrupt flag.
4.
5.
6.
DIN2
DOUT1
DOUT2
SCLK
AUTO_SS = 1
SPICONT = 0
DIN
DOUT
DIN1
DIN2
DOUT1
DOUT2
DIN1
DIN2
SS
SCLK
AUTO_SS = 0
SPICONT = 0
(MANUAL SS CONTROL)
DIN
DOUT
DOUT1
DOUT2
Figure 95. Automatic Chip Select and Continuous Mode Output
Note that reading the content of the SPI/I2C Receive Buffer SFR
(SPI2CRx, 0x9B) should be done using a 2-cycle instruction set,
such as MOV A or SPI2CRX. Using a 3-cycle instruction, such
as MOV 0x3D or SPI2CRX, does not transfer the correct information into the target register.
Continuous Byte Mode—SPICONT (SPIMOD2[7]) = 1
1.
2.
3.
DIN1
SS
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. Continuous transmit mode is
designed to use the full capacity of the SPI. In this mode, the
master transmits and receives data until the SPI/I2C Transmit
Buffer SFR (SPI2CTx, 0x9A) is empty at the start of a byte
transfer. Continuous mode is enabled by setting the SPICONT bit
in the SPI Configuration SFR 2 (SPIMOD2, 0xE9). The SPI
peripheral also offers a single byte read/write function.
DIN
07327-095
SS (Slave Select Pin)
Write to SPI2CTx SFR.
SS is asserted low and write routine is initiated.
Wait for the SPITxIRQ interrupt flag to write to SPI2CTx
SFR. Transfer continues until the SPI2CTx register and
transmit shift registers are empty.
SPITxIRQ interrupt flag is set when the SPI2CTx register
is empty.
SS is deasserted high.
Write to SPI2CTx SFR to clear the SPITxIRQ interrupt flag.
Rev. 0 | Page 116 of 128
ADE7518
The SPI interface has several status flags that indicate the status
of the double-buffered receive and transmit registers. Figure 96
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).
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.
2
When a new byte of data is received in the SPI/I C Receive Buffer
SFR (SPI2CRx, 0x9B), the SPI receive interrupt flag is raised.
If the data in the SPI/I2C Receive Buffer SFR (SPI2CRx, 0x9B) is
not read before new data is ready to be loaded into the SPI/I2C
Receive Buffer SFR (SPI2CRx, 0x9B), an overflow condition has
occurred. This overflow condition, indicated by the SPIRxOF
flag, forces the new data to be discarded or overwritten if the
RxOFW bit is set.
SPITx
SPIRx
SPITxIRQ = 1
TRANSMIT SHIFT REGISTER
SPIRxIRQ = 1
RECEIVE SHIFT REGISTER
SPITx (EMPTY)
SPIRx (FULL)
STOPS TRANSFER IF TIMODE = 1
TRANSMIT SHIFT REGISTER
Figure 96. SPI Receive and Transmit Interrupt and Status Flags
SCLK
(SPICPOL = 1)
SCLK
(SPICPOL = 0)
SS
SPICPHA = 1
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
SPIRx AND
SPITx FLAGS
WITH INTMOD = 1
SPIRx AND
SPITx FLAGS
WITH INTMOD = 0
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
?
SPIRx AND
SPITx FLAGS
WITH INTMOD = 1
SPIRx AND
SPITx FLAGS
WITH INTMOD = 0
07327-097
SPICPHA = 0
Figure 97. SPI Timing Configurations
Rev. 0 | Page 117 of 128
SPIRxOF = 1
RECEIVE SHIFT REGISTER
07327-096
SPI INTERRUPT AND STATUS FLAGS
ADE7518
I2C-COMPATIBLE INTERFACE
The ADE7518 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 on-chip
SPI interface. Therefore, the user can enable only one interface
on these pins at any given time. The SCPS bit in the Configuration
SFR (CFG, 0xAF) selects which peripheral is active.
The two pins used for data transfer, SDATA and SCLK, are
configured in a wire-AND format that allows arbitration in a
multimaster system.
The transfer sequence of an 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 the start condition, the data transfer is
initiated. This continues until the master issues a stop condition
and the bus becomes idle.
SERIAL CLOCK GENERATION
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 bit rate is defined in the I2CMOD SFR as follows:
f SCLK =
f CORE
16 × 2 I 2CR[1:0]
SLAVE ADDRESSES
The I2C Slave Address SFR (I2CADR, 0xE9) contains the slave
device ID. The LSB of this register contains a read/write request.
A write to this SFR starts the I2C communication.
I2C REGISTERS
The I2C peripheral interface consists of five SFRs.
•
•
•
•
•
I2CMOD
SPI2CSTAT
I2CADR
SPI2CTx
SPI2CRx
Because the SPI and I2C serial interfaces share the same pins,
they also share the same SFRs, such as the SPI2CTx and SPI2CRx
SFRs. In addition, the I2CMOD, I2CADR, and SPI2CSTAT SFRs
are shared with the SPIMOD1, SPIMOD2, and SPISTAT SFRs,
respectively.
Table 132. I2C SFR List
SFR Address
0x9A
0x9B
0xE8
0xE9
0xEA
Name
SPI2CTx
SPI2CRx
I2CMOD
I2CADR
SPI2CSTAT
R/W
W
R
R/W
R/W
R/W
Length
8
8
8
8
8
Default
0
0
0
0
0
Description
SPI/I2C Transmit Buffer (see Table 127).
SPI/I2C Receive Buffer (see Table 128).
I2C Mode (see Table 133).
I2C Slave Address (see Table 134).
I2C Interrupt Status Register (see Table 135).
Table 133. I2C Mode SFR (I2CMOD, 0xE8)
Bit
7
Address
0xEF
Mnemonic
I2CEN
Default
0
6 to 5
0xEE to 0xED
I2CR[1:0]
00
4 to 0
0xEC to 0xE8
I2CRCT[4:0]
0
Description
I2C Enable Bit. When this bit is set to Logic 1, the I2C interface is enabled. A write to the
I2CADR SFR starts a communication.
I2C SCLK Frequency.
I2CR[1:0] Result
00
fCORE/16 = 256 kHz if fCORE = 4.096 MHz.
01
fCORE/32 = 128 kHz if fCORE = 4.096 MHz.
10
fCORE/64 = 64 Hz if fCORE = 4.096 MHz.
11
fCORE/128 = 32 kHz if fCORE = 4.096 MHz.
Configures the length of the I2C received FIFO buffer. The I2C peripheral stops when
I2CRCT, Bits[4:0] + 1 byte have been read or if an error occurs.
Table 134. I2C Slave Address SFR (I2CADR, 0xE9)
Bit
7 to 1
0
Mnemonic
I2CSLVADR
I2CR_W
Default
0
0
Description
Address of the I2C Slave Being Addressed. Writing to this register starts the I2C transmission (read or write).
Command Bit for Read or Write. When this bit is set to Logic 1, a read command is transmitted on the
I2C bus. Data from the slave in the SPI2CRx SFR is expected after a command byte. When this bit is set
to Logic 0, a write command is transmitted on the I2C bus. Data to slave is expected in the SPI2CTx SFR.
Rev. 0 | Page 118 of 128
ADE7518
Table 135. I2C Interrupt Status Register SFR (SPI2CSTAT, 0xEA)
Bit
7
6
Mnemonic
I2CBUSY
I2CNOACK
Default
0
0
5
I2CRxIRQ
0
4
I2CTxIRQ
0
3 to 2
I2CFIFOSTAT[1:0]
00
1
0
I2CACC_ERR
I2CTxWR_ERR
0
0
Description
This bit is set to Logic 1 when the I2C interface is used. When this bit is set, the Tx FIFO is emptied.
I2C No Acknowledgement Transmit Interrupt. This bit is set to Logic 1 when the slave device
does not send an acknowledgement. The I2C communication is stopped after this event.
Write a 0 to this bit to clear it.
I2C Receive Interrupt. This bit is set to Logic 1 when the receive FIFO is not empty.
Write a 0 to this bit to clear it.
I2C Transmit Interrupt. This bit is set to Logic 1 when the transmit FIFO is empty.
Write a 0 to this bit to clear it.
Status Bits for 3- or 4-Byte Deep I2C FIFO. The FIFO monitored in these two bits is the one currently
used in I2C communication (receive or transmit) because only one FIFO is active at a time.
I2CFIFOSTAT[1:0]
Result
00
FIFO empty
01
Reserved
10
FIFO half full
11
FIFO full
Set when trying to write and read at the same time. Write a 0 to this bit to clear it.
Set when write was attempted when I2C transmit FIFO was full. Write a 0 to this bit to clear it.
READ AND WRITE OPERATIONS
1
9
1
9
1
9
SCLK
A6
A5
A4
A3
A2
A1
A0
START BY
MASTER
R/W
D7
D6
D5
D4
D3
D2
D1
D0
ACK BY
SLAVE
D7
D6
ACK BY
MASTER
FRAME 1
SERIAL BUS ADDRESS BYTE
D5
D4
D3
D2
D1
D0
NACK BY STOP BY
MASTER MASTER
FRAME N + 1
DATA BYTE N FROM SLAVE
FRAME 2
DATA BYTE 1 FROM MASTER
07327-098
SDATA
Figure 98. I2C Read Operation
1
9
1
9
SCLK
START BY
MASTER
A6
A5
A4
A3
A2
A1
A0
FRAME 1
SERIAL BUS ADDRESS BYTE
R/W
ACK BY
SLAVE
D7
D6
D5
D4
D3
D2
D1
D0
FRAME 2
DATA BYTE 1 FROM MASTER
ACK BY
SLAVE
STOP BY
MASTER
07327-099
SDATA
Figure 99. I2C Write Operation
Figure 98 and Figure 99 depict I2C read and write operations,
respectively. Note that the LSB of the I2CADR register is used to
select 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 mastergenerated NACK (no acknowledge) before the end of a read
operation is also automatically generated after the I2CRCT,
Bits[4:0] 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 generates a
start condition and continues with the next communication.
Reading the SPI/I2C Receive Buffer SFR (SPI2CRx, 0x9B)
Reading the SPI2CRx SFR should be done with a 2-cycle
instruction, such as
Mov a, spi2crx or Mov R0, spi2crx.
A 3-cycle instruction such as
Mov 3dh, spi2crx
does not transfer the right data into RAM Address 0x3D.
Rev. 0 | Page 119 of 128
ADE7518
The I2C peripheral has a 4-byte receive FIFO and a 4-byte transmit
FIFO. The buffers reduce the overhead associated with using
the I2C peripheral. Figure 100 shows the operation of the I2C
receive and transmit FIFOs.
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 is set,
and the PC vectors 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 stops.
An error, such as not receiving an acknowledge, also causes the
communication to terminate. In case of an error during a write
operation, the Tx FIFO is flushed.
be generated after each byte is received or when the Rx FIFO
is full. If the peripheral is reading from a slave address, the
communication stops once the number of received bytes equals
the number set in I2CRCT, Bits [4:0]. An error, such as not
receiving an acknowledge, also causes the communication to
terminate.
CODE TO FILL Tx FIFO:
MOV
MOV
MOV
MOV
I2CTx,
I2CTx,
I2CTx,
I2CTx,
CODE TO READ Rx FIFO:
TxDATA1
TxDATA2
TxDATA3
TxDATA4
MOV A,
MOV A,
MOV A,
MOV A,
I2CRx;
I2CRx;
I2CRx;
I2CRx;
I2CRx
I2CTx
TxDATA4
4-BYTE FIFO
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
Rev. 0 | Page 120 of 128
TxDATA3
TxDATA2
RESULT: A = RxDATA1
RESULT: A = RxDATA2
RESULT: A = RxDATA3
RESULT: A = RxDATA4
RxDATA1
4-BYTE FIFO
RxDATA2
RxDATA3
TxDATA1
RxDATA4
TRANSMIT SHIFT REGISTER
RECEIVE SHIFT REGISTER
Figure 100. I2C FIFO Operation
07327-100
I2C RECEIVE AND TRANSMIT FIFOS
ADE7518
I/O PORTS
PARALLEL I/O
Weak Internal Pull-Ups Enabled
The ADE7518 uses three input/output ports to exchange data
with external devices. In addition to performing general-purpose
I/O, some are capable of driving an LCD or performing alternate
functions for the peripherals 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 listed in Table 136.
A pin with weak internal pull-up enabled is used as an input by
writing a 1 to the pin. The pin is pulled high by the internal pullups, and the pin is read using the circuitry shown in Figure 101.
If the pin is driven low externally, it sources current because of
the internal pull-ups.
Table 136. I/O Port SFRs
Address
0x80
0x90
0xA0
0x9F
Bit Addressable
Yes
Yes
Yes
No
PINMAP0
0xB2
No
PINMAP1
0xB3
No
PINMAP2
0xB4
No
Description
Port 0.
Port 1.
Port 2.
Extended Port
Configuration.
Port 0 Weak
Pull-Up Enable.
Port 1 Weak
Pull-Up Enable.
Port 2 Weak
Pull-Up Enable.
Open Drain (Weak Internal Pull-Ups Disabled)
When the weak internal pull-up on a pin is disabled, the pin
becomes open drain. Use this open-drain pin as a high impedance
input by writing a 1 to the pin. The pin is read using the circuitry
shown in Figure 101. The open-drain option is preferable for
inputs because it draws less current than the internal pull-ups
that were enabled.
38 kHz Modulation
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 the PINMAPx SFRs.
Figure 101 shows a typical bit latch and I/O buffer for an I/O pin.
The bit latch (one bit in each 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
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.
The ADE7518 provides a 38 kHz modulation signal. The
38 kHz modulation is accomplished by internally XOR’ing the
level written to the I/O pin with a 38 kHz square wave. Then,
when a 0 is written to the I/O pin, it is modulated as shown in
Figure 102.
LEVEL WRITTEN
TO MOD38
38kHz MODULATION
SIGNAL
38kHz MODULATED
OUTPUT PIN
Figure 102. 38 kHz Modulation
Uses for this 38 kHz modulation include IR modulation of
a UART transmit signal or a low power signal to drive an
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).
DVDD
ALTERNATE
OUTPUT
FUNCTION
READ
LATCH
WRITE
TO LATCH
READ
PIN
D
INTERNAL
PULL-UP
CLOSED: PINMAPx.x = 0
OPEN: PINMAPx.x = 1
Px.x
PIN
Q
CL Q
LATCH
ALTERNATE
INPUT
FUNCTION
07327-101
INTERNAL
BUS
07327-102
SFR
P0
P1
P2
EPCFG
A pin with internal pull-up enabled is used as an output by
writing a 1 or a 0 to the pin to control the level of the output.
If a 0 is written to the pin, it drives a logic low output voltage
(VOL) and is capable of sinking 1.6 mA.
Figure 101. Port 0 Bit Latch and I/O Buffer
Rev. 0 | Page 121 of 128
ADE7518
I/O REGISTERS
Table 137. Extended Port Configuration SFR (EPCFG, 0x9F)
Bit
7
6
5
4
3
2
1
0
Mnemonic
MOD38_FP21
MOD38_FP22
MOD38_FP23
MOD38_TxD
MOD38_CF1
MOD38_SSb
MOD38_MISO
MOD38_CF2
Default
0
0
0
0
0
0
0
0
Description
Enable 38 kHz modulation on P1.6/FP21 pin.
Enable 38 kHz modulation on P1.5/FP22 pin.
Enable 38 kHz modulation on P1.4/T2/FP23 pin.
Enable 38 kHz modulation on P1.1/TxD pin.
Enable 38 kHz modulation on P0.2/CF1/RTCCAL pin.
Enable 38 kHz modulation on P0.7/SS/T1 pin.
Enable 38 kHz modulation on P0.5/MISO pin.
Enable 38 kHz modulation on P0.3/CF2 pin.
Table 138. Port 0 Weak Pull-Up Enable SFR (PINMAP0, 0xB2)
Bit
7
6
5
4
3
2
1
0
Mnemonic
PINMAP0.7
PINMAP0.6
PINMAP0.5
PINMAP0.4
PINMAP0.3
PINMAP0.2
PINMAP0.1
PINMAP0.0
Default
0
0
0
0
0
0
0
0
Description
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 139. Port 1 Weak Pull-Up Enable SFR (PINMAP1, 0xB3)
Bit
7
6
5
4
3
2
1
0
Mnemonic
PINMAP1.7
PINMAP1.6
PINMAP1.5
PINMAP1.4
PINMAP1.3
PINMAP1.2
PINMAP1.1
PINMAP1.0
Default
0
0
0
0
0
0
0
0
Description
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 140. Port 2 Weak Pull-Up Enable SFR (PINMAP2, 0xB4)
Bit
7 to 6
5
4
3
2
1
0
Mnemonic
Reserved
PINMAP2.5
Reserved
PINMAP2.3
PINMAP2.2
PINMAP2.1
PINMAP2.0
Default
0
0
0
0
0
0
0
Description
Reserved. Should be left cleared.
The weak pull-up on RESET is disabled when this bit is set.
Reserved. Should be left cleared.
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.
Rev. 0 | Page 122 of 128
ADE7518
Table 141. Port 0 SFR (P0, 0x80)
Bit
7
6
5
4
3
2
1
0
1
Address
0x87
0x86
0x85
0x84
0x83
0x82
0x81
0x80
Mnemonic
T1
T0
CF2
CF1
INT1
Default
1
1
1
1
1
1
1
1
Description1
This bit reflects the state of the P0.7/SS/T1 pin. It can be written or read.
This bit reflects the state of the P0.6/SCLK/T0 pin. It can be written or read.
This bit reflects the state of the P0.5/MISO pin. It can be written or read.
This bit reflects the state of the P0.4/MOSI/SDATA pin. It can be written or read.
This bit reflects the state of the P0.3/CF2 pin. It can be written or read.
This bit reflects the state of the P0.2/CF1/RTCCAL pin. It can be written or read.
This bit reflects the state of the P0.1/FP19 pin. It can be written or read.
This bit reflects the state of the BCTRL/INT1/P0.0 pin. It can be written or read.
When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set.
Table 142. Port 1 SFR (P1, 0x90)
Bit
7
6
5
4
3
2
1
0
1
Address
0x97
0x96
0x95
0x94
0x93
0x92
0x91
0x90
Mnemonic
T2
T2EX
TxD
RxD
Default
1
1
1
1
1
1
1
1
Description1
This bit reflects the state of the P1.7/FP20 pin. It can be written or read.
This bit reflects the state of the P1.6/FP21 pin. It can be written or read.
This bit reflects the state of the P1.5/FP22 pin. It can be written or read.
This bit reflects the state of the P1.4/T2/FP23 pin. It can be written or read.
This bit reflects the state of the P1.3/T2EX/FP24 pin. It can be written or read.
This bit reflects the state of the P1.2/FP25 pin. It can be written or read.
This bit reflects the state of the P1.1/TxD pin. It can be written or read.
This bit reflects the state of the P1.0/RxD pin. It can be written or read.
When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set.
Table 143. Port 2 SFR (P2, 0xA0)
Bit
7 to 4
3
2
1
0
1
Address
0x97 to 0x94
0x93
0x92
0x91
0x90
Mnemonic
P2.3
P2.2
P2.1
P2.0
Default
0x1F
1
1
1
1
Description1
These bits are unused and should remain set.
This bit reflects the state of the SDEN/P2.3 pin. It can be written only.
This bit reflects the state of the P2.2/FP16 pin. It can be written or read.
This bit reflects the state of the P2.1/FP17 pin. It can be written or read.
This bit reflects the state of the P2.0/FP18 pin. It can be written or read.
When an alternate function is chosen for a pin of this port, the bit controlling this pin should always be set.
Rev. 0 | Page 123 of 128
ADE7518
Table 144. Port 0 Alternate Functions
Pin No.
P0.0
Alternate Function
BCTRL External Battery Control Input
INT1 External Interrupt
Alternate Function Enable
Set INT1PRG[2:0] = x01 in the Interrupt Pins Configuration SFR (INTPR, 0xFF).
Set EX1 in the Interrupt Enable SFR (IE, 0xA8).
INT1 Wake-up from PSM2 Operating Mode
Set INT1PRG[2:0] = 11x in the Interrupt Pins Configuration SFR (INTPR, 0xFF).
P0.1
P0.2
FP19 LCD Segment Pin
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 Configuration SFR (CFG, 0xAF) and set the SPIEN bit in
the SPI Configuration SFR 2 (SPIMOD2, 0xE9).
Clear the SCPS bit in the Configuration SFR (CFG, 0xAF) and set the I2CEN bit
in the I2C Mode SFR (I2CMOD, 0xE8).
Set the SCPS bit in the Configuration SFR (CFG, 0xAF) and set the SPIEN bit in
the SPI Configuration SFR 2 (SPIMOD2, 0xE9).
Set the I2CEN bit in the I2C Mode SFR (I2CMOD, 0xE8) or the SPIEN bit in the
SPI Configuration SFR 2 (SPIMOD2, 0xE9) to enable the I2C or SPI interface.
Set the C/T0 bit in the Timer/Counter 0 and Timer/Counter 1 Mode SFR (TMOD,
0x89) to enable T0 as an external event counter.
Set the SS_EN bit in the SPI Configuration SFR 1 (SPIMOD1, 0xE8).
Set the SPIMS_b bit in the SPI Configuration SFR 2 (SPIMOD2, 0xE9).
Set the C/T1 bit in the Timer/Counter 0 and Timer/Counter 1 Mode SFR (TMOD,
0x89) to enable T1 as an external event counter.
SDATA I2C Data Line
P0.5
MISO SPI Data Line
P0.6
SCLK Serial Clock for I2C or SPI
T0 Timer 0 Input
P0.7
SS SPI Slave Select Input for SPI in Slave Mode
SS SPI Slave Select Output for SPI in Master Mode
T1 Timer 1 Input
Table 145. Port 1 Alternate Functions
Pin No.
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
Alternate Function
RxD Receiver Data Input for UART
Rx Edge Wake-up from PSM2 Operating Mode
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
Alternate Function Enable
Set the REN bit in the Serial Communications Control Register SFR (SCON, 0x98).
Set RXPROG[1:0] = 11 in the Peripheral Configuration SFR (PERIPH, 0xF4).
This pin becomes TxD as soon as data is written into SBUF.
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 C/T2 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 146. Port 2 Alternate Functions
Pin No.
P2.0
P2.1
P2.2
P2.3
Alternate Function
FP18 LCD Segment Pin
FP17 LCD Segment Pin
FP16 LCD Segment Pin
SDEN serial download pin sampled on reset. P2.3 is
an output only.
Alternate Function Enable
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.
Rev. 0 | Page 124 of 128
ADE7518
PORT 0
Port 0 is controlled directly through the bit-addressable Port 0
SFR (P0, 0x80). 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. The weak internal pull-up is
disabled by writing a 1 to PINMAP0.x.
Port 0 pins also have various secondary functions as described
in Table 144. The alternate functions of Port 0 pins can be
activated only if the corresponding bit latch in the Port 0 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 (P1, 0x90). 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. The weak internal pull-up is disabled by writing a 1 to
PINMAP1.x.
Port 1 pins also have various secondary functions as described
in Table 145. The alternate functions of Port 1 pins can be
activated only if the corresponding bit latch in the Port 1 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 (P2, 0xA0). Note that P2.3 can be
used as an output only. Consequently, any read operation, such
as a CPL P2.3, cannot be executed on this I/O. 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. The weak internal pull-up is disabled by writing a 1 to
PINMAP2.x.
Port 2 pins also have various secondary functions as described
in Table 146. The alternate functions of Port 2 pins can be
activated only if the corresponding bit latch in the Port 2 SFR
contains a 1. Otherwise, the port pin remains at 0.
Rev. 0 | Page 125 of 128
ADE7518
DETERMINING THE VERSION OF THE ADE7518
The ADE7518 holds in its internal flash registers a value that
defines its version. This value helps to determine if users have the
latest version of the part. The ADE7518 version corresponding to
this data sheet is ADE7518V3.4.
To access this value, the following procedure can be followed:
1.
2.
3.
4.
5.
Launch HyperTerminal with a 9600 baud rate.
Put the part in serial download mode by first holding
SDEN to logic low and then resetting the part.
Hold the SDEN pin.
Press and release the RESET pin.
The following string should appear on the HyperTerminal
screen: ADE7518V3.4
Rev. 0 | Page 126 of 128
ADE7518
OUTLINE DIMENSIONS
0.75
0.60
0.45
12.20
12.00 SQ
11.80
1.60
MAX
64
49
1
48
PIN 1
10.20
10.00 SQ
9.80
TOP VIEW
(PINS DOWN)
0.15
0.05
0.20
0.09
7°
3.5°
0°
SEATING
PLANE
16
33
32
17
0.08
COPLANARITY
VIEW A
VIEW A
0.50
BSC
LEAD PITCH
ROTATED 90° CCW
0.27
0.22
0.17
COMPLIANT TO JEDEC STANDARDS MS-026-BCD
051706-A
1.45
1.40
1.35
Figure 103. 64-Lead Low Profile Quad Flat Package [LQFP]
(ST-64-2)
Dimensions shown in millimeters
ORDERING GUIDE
Model
ADE7518ASTZF81
ADE7518ASTZF8-RL1
ADE7518ASTZF161
ADE7518ASTZF16-RL1
1
Antitamper
No
No
No
No
di/dt Sensor
Interface
No
No
No
No
VAR
Yes
Yes
Yes
Yes
Flash (kB)
8
8
16
16
Temperature
Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Z = RoHS Compliant Part.
Rev. 0 | Page 127 of 128
Package Description
64-Lead LQFP
64-Lead LQFP, Reel
64-Lead LQFP
64-Lead LQFP, Reel
Package
Option
ST-64-2
ST-64-2
ST-64-2
ST-64-2
ADE7518
NOTES
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 these components in an I2C system, provided that the system conforms to the I2C Standard Specification as defined by Philips.
©2009 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D07327-0-1/09(0)
Rev. 0 | Page 128 of 128