a MicroConverter ®, Dual-Channel 16-Bit ADCs with Embedded Flash MCU ADuC816 FEATURES High-Resolution Sigma-Delta ADCs Dual 16-Bit Independent ADCs Programmable Gain Front End 16-Bit No Missing Codes, Primary ADC 13-Bit p-p Resolution @ 20 Hz, 20 mV Range 16-Bit p-p Resolution @ 20 Hz, 2.56 V Range Memory 8 Kbytes On-Chip Flash/EE Program Memory 640 Bytes On-Chip Flash/EE Data Memory Flash/EE, 100 Year Retention, 100 Kcycles Endurance 256 Bytes On-Chip Data RAM 8051-Based Core 8051-Compatible Instruction Set (12.58 MHz Max) 32 kHz External Crystal, On-Chip Programmable PLL Three 16-Bit Timer/Counters 26 Programmable I/O Lines 11 Interrupt Sources, Two Priority Levels Power Specified for 3 V and 5 V Operation Normal: 3 mA @ 3 V (Core CLK = 1.5 MHz) Power-Down: 20 A (32 kHz Crystal Running) On-Chip Peripherals On-Chip Temperature Sensor 12-Bit Voltage Output DAC Dual Excitation Current Sources Reference Detect Circuit Time Interval Counter (TIC) UART Serial I/O I2C ®-Compatible and SPI® Serial I/O Watchdog Timer (WDT), Power Supply Monitor (PSM) APPLICATIONS Intelligent Sensors (IEEE1451.2-Compatible) Weigh Scales Portable Instrumentation Pressure Transducers 4–20 mA Transmitters GENERAL DESCRIPTION The ADuC816 is a complete smart transducer front-end, integrating two high-resolution sigma-delta ADCs, an 8-bit MCU, and program/data Flash/EE Memory on a single chip. This low power device accepts low-level signals directly from a transducer. The two independent ADCs (Primary and Auxiliary) include a temperature sensor and a PGA (allowing direct measurement of low-level signals). The ADCs with on-chip digital filtering are MicroConverter is a registered trademark of Analog Devices, Inc. SPI is a registered trademark of Motorola, Inc. I2C is a registered trademark of Philips Semiconductors, Inc. REV. A 0 REV. 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 which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. FUNCTIONAL BLOCK DIAGRAM AVDD AVDD ADuC816 AIN1 AIN2 MUX CURRENT SOURCE MUX IEXC1 IEXC2 AGND AIN3 AIN4 PRIMARY 16-BIT - ADC PGA BUF MUX AIN5 AUXILIARY 16-BIT - ADC 12-BIT VOLTAGE O/P DAC BUF DAC 8051-BASED MCU WITH ADDITIONAL PERIPHERALS TEMP SENSOR INTERNAL BANDGAP VREF PROG. CLOCK DIVIDER EXTERNAL VREF DETECT OSC & PLL REFIN– REFIN+ XTAL1 8 KBYTES FLASH/EE PROGRAM MEMORY 640 BYTES FLASH/EE DATA MEMORY 256 BYTES USER RAM 3 16 BIT TIMER/COUNTERS 1 TIME INTERVAL COUNTER ON-CHIP MONITORS POWER SUPPLY MONITOR WATCHDOG TIMER 4 PARALLEL PORTS I2C-COMPATIBLE UART AND SPI SERIAL I/O XTAL2 intended for the measurement of wide dynamic range, low frequency signals, such as those in weigh scale, strain gauge, pressure transducer, or temperature measurement applications. The ADC output data rates are programmable and the ADC output resolution will vary with the programmed gain and output rate. The device operates from a 32 kHz crystal with an on-chip PLL generating a high-frequency clock of 12.58 MHz. This clock is, in turn, routed through a programmable clock divider from which the MCU core clock operating frequency is generated. The microcontroller core is an 8052 and therefore 8051-instructionset-compatible. The microcontroller core machine cycle consists of 12 core clock periods of the selected core operating frequency. 8 Kbytes of nonvolatile Flash/EE program memory are provided on-chip. 640 bytes of nonvolatile Flash/EE data memory and 256 bytes RAM are also integrated on-chip. The ADuC816 also incorporates additional analog functionality with a 12-bit DAC, current sources, power supply monitor, and a bandgap reference. On-chip digital peripherals include a watchdog timer, time interval counter, three timers/counters, and three serial I/O ports (SPI, UART, and I2C-compatible). On-chip factory firmware supports in-circuit serial download and debug modes (via UART), as well as single-pin emulation mode via the EA pin. A functional block diagram of the ADuC816 is shown above with a more detailed block diagram shown in Figure 12. V supply. supply. When When operating operating The part operates from a single 3 V or 5 V from 3 V supplies, the power dissipation dissipation for for the the part part isis below below 10 mW. The ADuC816 is housed in 52-lead and 56-lead a 52-leadMQFP MQFP package. LFCSP packages. One Technology 02062-9106, U.S.A. Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, Tel: www.analog.com Tel: 781.329.4700 781/329-4700 World Wide Web Site: http://www.analog.com Fax: Inc. Devices, All rightsInc., reserved. Fax: 781.461.3113 781/326-8703 ©2001–20 Analog Devices, © Analog 2001 ADuC816 TABLE OF CONTENTS Using the Flash/EE Memory Interface . . . . . . . . . . . . . . . . . . . . Erase-All . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Program a Byte . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . USER INTERFACE TO OTHER ON-CHIP ADuC816 PERIPHERALS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . On-Chip PLL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Time Interval Counter (TIC) . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Supply Monitor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SERIAL PERIPHERAL INTERFACE . . . . . . . . . . . . . . . . . . . . . MISO (Master In, Slave Out Data I/O Pin), Pin 14 . . . . . . . . . MOSI (Master Out, Slave In Pin), Pin 27 . . . . . . . . . . . . . . . . . SCLOCK (Serial Clock I/O Pin), Pin 26 . . . . . . . . . . . . . . . . . . SS (Slave Select Input Pin), Pin 13 . . . . . . . . . . . . . . . . . . . . . . Using the SPI Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Interface—Master Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Interface—Slave Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . I2C-COMPATIBLE INTERFACE . . . . . . . . . . . . . . . . . . . . . . . . 8051-COMPATIBLE ON-CHIP PERIPHERALS . . . . . . . . . . . . Parallel I/O Ports 0–3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Timers/Counters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TIMER/COUNTER 0 AND 1 OPERATING MODES . . . . . . . . Mode 0 (13-Bit Timer/Counter) . . . . . . . . . . . . . . . . . . . . . . . . Mode 1 (16-Bit Timer/Counter) . . . . . . . . . . . . . . . . . . . . . . . . Mode 2 (8-Bit Timer/Counter with Autoreload) . . . . . . . . . . . . Mode 3 (Two 8-Bit Timer/Counters) . . . . . . . . . . . . . . . . . . . . Timer/Counter 2 Data Registers . . . . . . . . . . . . . . . . . . . . . . . . TH2 and TL2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RCAP2H and RCAP2L . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Timer/Counter 2 Operating Modes . . . . . . . . . . . . . . . . . . . . . . 16-Bit Autoreload Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16-Bit Capture Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . UART SERIAL INTERFACE . . . . . . . . . . . . . . . . . . . . . . . . . . . SBUF . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mode 0: 8-Bit Shift Register Mode . . . . . . . . . . . . . . . . . . . . . . Mode 1: 8-Bit UART, Variable Baud Rate . . . . . . . . . . . . . . . . Mode 2: 9-Bit UART with Fixed Baud Rate . . . . . . . . . . . . . . . Mode 3: 9-Bit UART with Variable Baud Rate . . . . . . . . . . . . . UART Serial Port Baud Rate Generation . . . . . . . . . . . . . . . . . Timer 1 Generated Baud Rates . . . . . . . . . . . . . . . . . . . . . . . . . Timer 2 Generated Baud Rates . . . . . . . . . . . . . . . . . . . . . . . . . INTERRUPT SYSTEM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interrupt Priority . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADuC816 HARDWARE DESIGN CONSIDERATIONS . . . . . . Clock Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . External Memory Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power-On Reset Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Supplies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power-Saving Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Grounding and Board Layout Recommendations . . . . . . . . . . . ADuC816 System Self-Identification . . . . . . . . . . . . . . . . . . . . . OTHER HARDWARE CONSIDERATIONS . . . . . . . . . . . . . . . In-Circuit Serial Download Access . . . . . . . . . . . . . . . . . . . . . . Embedded Serial Port Debugger . . . . . . . . . . . . . . . . . . . . . . . . Single-Pin Emulation Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . Enhanced-Hooks Emulation Mode . . . . . . . . . . . . . . . . . . . . . . Typical System Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . QUICKSTART DEVELOPMENT SYSTEM . . . . . . . . . . . . . . . Download—In-Circuit Serial Downloader . . . . . . . . . . . . . . . . . DeBug—In-Circuit Debugger . . . . . . . . . . . . . . . . . . . . . . . . . . ADSIM—Windows Simulator . . . . . . . . . . . . . . . . . . . . . . . . . . OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 TIMING SPECIFICATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . . . . . . . . . . . . 18 ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 PIN FUNCTION DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . 19 ADuC816 BLOCK DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . 21 MEMORY ORGANIZATION . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 OVERVIEW OF MCU-RELATED SFRS . . . . . . . . . . . . . . . . . . 23 Accumulator SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 B SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Stack Pointer SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Data Pointer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Program Status Word SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Power Control SFR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 SPECIAL FUNCTION REGISTERS . . . . . . . . . . . . . . . . . . . . . 24 SFR INTERFACE TO THE PRIMARY AND AUXILIARY ADCs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 ADCSTAT (ADC Status Register) . . . . . . . . . . . . . . . . . . . . . . 25 ADCMODE (ADC Mode Register) . . . . . . . . . . . . . . . . . . . . . 26 ADC0CON (Primary ADC Control Register) . . . . . . . . . . . . . . 27 ADC1CON (Auxiliary ADC Control Register) . . . . . . . . . . . . . 28 SF (Sinc Filter Register) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 ICON (Current Sources Control Register) . . . . . . . . . . . . . . . . 29 ADC0H/ADC0M (Primary ADC Conversion Result Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 ADC1H/ADC1L (Auxiliary ADC Conversion Result Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 OF0H/OF0M (Primary ADC Offset Calibration Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 OF1H/OF1L (Auxiliary ADC Offset Calibration Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 GN0H/GN0M (Primary ADC Gain Calibration Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 GN1H/GN1L (Auxiliary ADC Gain Calibration Registers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 PRIMARY AND AUXILIARY ADC CIRCUIT DESCRIPTION OVERVIEW . . . . . . . . . . . . . . . . . . . . . . . . . . 31 Primary ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 Auxiliary ADC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 PRIMARY AND AUXILIARY ADC NOISE PERFORMANCE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Analog Input Channels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Primary and Auxiliary ADC Inputs . . . . . . . . . . . . . . . . . . . . . . 33 Analog Input Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Programmable Gain Amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Bipolar/Unipolar Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Burnout Currents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Excitation Currents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Reference Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Reference Detect . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Sigma-Delta Modulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 Digital Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35 ADC Chopping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Calibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 NONVOLATILE FLASH/EE MEMORY . . . . . . . . . . . . . . . . . . 37 Flash/EE Memory Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Flash/EE Memory and the ADuC816 . . . . . . . . . . . . . . . . . . . . 37 ADuC816 Flash/EE Memory Reliability . . . . . . . . . . . . . . . . . . 37 Using the Flash/EE Program Memory . . . . . . . . . . . . . . . . . . . . 38 Flash/EE Program Memory Security . . . . . . . . . . . . . . . . . . . . . 38 Using the Flash/EE Data Memory . . . . . . . . . . . . . . . . . . . . . . . 39 ECON–Flash/EE Memory Control SFR . . . . . . . . . . . . . . . . . . 39 Flash/EE Memory Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40 –2– 40 40 40 41 41 42 43 46 47 48 48 48 48 48 49 49 49 50 51 51 51 54 54 54 54 54 55 55 55 56 56 56 57 57 58 58 58 58 58 59 59 60 61 62 62 62 63 63 64 64 64 65 65 65 65 65 66 66 67 67 67 67 68 REV. REV. A 0 ADuC816 1 SPECIFICATIONS (AVDD = 2.7 V to 3.6 V or 4.75 V to 5.25 V, DVDD = 2.7 V to 3.6 V or 4.75 V to 5.25 V, REFIN(+) = 2.5 V; REFIN(–) = AGND; AGND = DGND = 0 V; XTAL1/XTAL2 = 32.768 kHz Crystal; all specifications TMIN to TMAX unless otherwise noted.) Parameter ADC SPECIFICATIONS Conversion Rate Primary ADC No Missing Codes2 Resolution Output Noise Integral Nonlinearity Offset Error Offset Error Drift Full-Scale Error3 Gain Error Drift4 ADC Range Matching Power Supply Rejection (PSR) Common-Mode DC Rejection On AIN ADuC816BS Unit Test Conditions/Comments 5.4 105 Hz min Hz max On Both Channels Programmable in 0.732 ms Increments 16 13 16 Bits min Bits p-p typ Bits p-p typ See Table IX and X in ADC Description ±1 ±3 ± 10 ± 10 0.5 ± 0.5 ± 0.5 95 80 20 Hz Update Rate Range = ± 20 mV, 20 Hz Update Rate Range = ± 2.56 V, 20 Hz Update Rate p-p Resolution at this Range/Update Rate Setting Is Limited Only by the Number of Bits Available from ADC Output Noise Varies with Selected Update Rate and Gain Range LSB max μV typ nV/°C typ μV typ LSB typ ppm/°C typ LSB typ dBs typ dBs typ 95 90 90 dBs typ dBs typ dBs typ On REFIN Common-Mode 50 Hz/60 Hz Rejection2 On AIN 95 On REFIN Normal Mode 50 Hz/60 Hz Rejection2 On AIN On REFIN Auxiliary ADC No Missing Codes2 Resolution Output Noise Integral Nonlinearity Offset Error Offset Error Drift Full-Scale Error5 Gain Error Drift4 Power Supply Rejection (PSR) Normal Mode 50 Hz/60 Hz Rejection2 On AIN On REFIN DAC PERFORMANCE DC Specifications6 Resolution Relative Accuracy Differential Nonlinearity Offset Error Gain Error7 AC Specifications2, 6 Voltage Output Settling Time Digital-to-Analog Glitch Energy REV. REV. A 0 dBs typ Range = ± 20 mV to ± 640 mV Range = ± 1.28 V to ± 2.56 V AIN = 18 mV AIN = 7.8 mV, Range = ± 20 mV AIN = 1 V, Range = ± 2.56 V At DC, AIN = 7.8 mV, Range = ± 20 mV At DC, AIN = 1 V, Range = ± 2.56 V At DC, AIN = 1 V, Range = ± 2.56 V 20 Hz Update Rate 50 Hz/60 Hz ± 1 Hz, AIN = 7.8 mV, Range = ± 20 mV 50 Hz/60 Hz ± 1 Hz, AIN = 1 V, Range = ± 2.56 V 50 Hz/60 Hz ± 1 Hz, AIN = 1 V, Range = ± 2.56 V 90 dBs typ 90 dBs typ 60 60 dBs typ dBs typ 16 16 See Table XI in ADC Description ±1 –2 1 –2.5 ± 0.5 80 Bits min Bits p-p typ LSB max LSB typ μV/°C typ LSB typ ppm/°C typ dBs typ AIN = 1 V, 20 Hz Update Rate 60 60 dBs typ dBs typ 50 Hz/60 Hz ± 1 Hz 50 Hz/60 Hz ± 1 Hz, 20 Hz Update Rate 12 ±3 –1 ± 50 ±1 ±1 Bits LSB typ LSB max mV max % max % typ AVDD Range VREF Range 15 10 μs typ nVs typ Settling Time to 1 LSB of Final Value 1 LSB Change at Major Carry –3– 50 Hz/60 Hz ± 1 Hz, 20 Hz Update Rate 50 Hz/60 Hz ± 1 Hz, 20 Hz Update Rate Range = ± 2.5 V, 20 Hz Update Rate Output Noise Varies with Selected Update Rate Guaranteed 12-Bit Monotonic ADuC816–SPECIFICATIONS1 Parameter INTERNAL REFERENCE ADC Reference Reference Voltage Power Supply Rejection Reference Tempco DAC Reference Reference Voltage Power Supply Rejection Reference Tempco ADuC816BS Unit Test Conditions/Comments 1.25 ± 1% 45 100 V min/max dBs typ ppm/°C typ Initial Tolerance @ 25°C, VDD = 5 V 2.5 ± 1% 50 ± 100 V min/max dBs typ ppm/°C typ Initial Tolerance @ 25°C, VDD = 5 V ANALOG INPUTS/REFERENCE INPUTS Primary ADC Differential Input Voltage Ranges8, 9 Bipolar Mode (ADC0CON.3 = 0) Analog Input Current2 Analog Input Current Drift Absolute AIN Voltage Limits Auxiliary ADC Input Voltage Range8, 9 Average Analog Input Current Average Analog Input Current Drift2 Absolute AIN Voltage Limits10 External Reference Inputs REFIN(+) to REFIN(–) Range2 Average Reference Input Current Average Reference Input Current Drift “NO Ext. REF” Trigger Voltage ADC SYSTEM CALIBRATION Full-Scale Calibration Limit Zero-Scale Calibration Limit Input Span ANALOG (DAC) OUTPUTS Voltage Range Resistive Load Capacitive Load Output Impedance ISINK TEMPERATURE SENSOR Accuracy Thermal Impedance (θJA) ± 20 ± 40 ± 80 ± 160 ± 320 ± 640 ± 1.28 ± 2.56 ±1 ±5 AGND + 100 mV AVDD – 100 mV mV mV mV mV mV mV V V nA max pA/°C typ V min V max 0 to VREF V 125 ±2 AGND – 30 mV AVDD + 30 mV nA/V typ pA/V/°C typ V min V max 1 AVDD 1 ± 0.1 0.3 0.65 V min V max μA/V typ nA/V/°C typ V min V max +1.05 × FS –1.05 × FS 0.8 × FS 2.1 × FS V max V min V min V max 0 to VREF 0 to AVDD 10 100 0.5 50 V typ V typ kΩ typ pF typ Ω typ μA typ ±2 90 °C typ °C/W typ –4– External Reference Voltage = 2.5 V RN2, RN1, RN0 of ADC0CON Set to 0 0 0 (Unipolar Mode 0 mV to 20 mV) 0 0 1 (Unipolar Mode 0 mV to 40 mV) 0 1 0 (Unipolar Mode 0 mV to 80 mV) 0 1 1 (Unipolar Mode 0 mV to 160 mV) 1 0 0 (Unipolar Mode 0 mV to 320 mV) 1 0 1 (Unipolar Mode 0 mV to 640 mV) 1 1 0 (Unipolar Mode 0 V to 1.28 V) 1 1 1 (Unipolar Mode 0 V to 2.56 V) Unipolar Mode, for Bipolar Mode See Note 11 Input Current Will Vary with Input Voltage on the Unbuffered Auxiliary ADC Both ADCs Enabled NOXREF Bit Active if VREF < 0.3 V NOXREF Bit Inactive if VREF > 0.65 V DACRN = 0 in DACCON SFR DACRN = 1 in DACCON SFR From DAC Output to AGND From DAC Output to AGND REV. A 0 REV. ADuC816 Parameter ADuC816BS TRANSDUCER BURNOUT CURRENT SOURCES AIN+ Current –100 Unit Test Conditions/Comments nA typ AIN+ is the Selected Positive Input to the Primary ADC AIN– is the Selected Negative Input the Auxiliary ADC AIN– Current +100 nA typ Initial Tolerance @ 25°C Drift Drift ± 10 0.03 % typ %/°C typ –200 ± 10 200 ±1 20 1 0.1 AVDD – 0.6 AGND μA typ % typ ppm/°C typ % typ ppm/°C typ μA/V typ μA/V typ V max min 0.8 0.4 2.0 V max V max V min DVDD = 5 V DVDD = 3 V 1.3/3 0.95/2.5 0.8/1.4 0.4/1.1 0.3/0.85 0.3/0.85 V min/V max V min/V max V min/V max V min/V max V min/V max V min/V max DVDD = 5 V DVDD = 3 V DVDD = 5 V DVDD = 3 V DVDD = 5 V DVDD = 3 V ± 10 –10 min, –40 max ± 10 ± 10 35 min, 105 max μA max μA min/μA max μA max μA max μA min/μA max ± 10 –180 –660 –20 –75 5 μA max μA min μA max μA min μA max pF typ VIN = 0 V or VDD VIN = 0 V, DVDD = 5 V, Internal Pull-Up VIN = VDD, DVDD = 5 V VIN = 0 V, DVDD = 5 V VIN = VDD, DVDD = 5 V, Internal Pull-Down VIN = VDD, DVDD = 5 V VIN = 2 V, DVDD = 5 V EXCITATION CURRENT SOURCES Output Current Initial Tolerance @ 25°C Drift Initial Current Matching @ 25°C Drift Matching Line Regulation (AVDD) Load Regulation Output Compliance LOGIC INPUTS All Inputs Except SCLOCK, RESET, and XTAL1 VINL, Input Low Voltage VINH, Input High Voltage SCLOCK and RESET Only (Schmitt-Triggered Inputs)2 VT+ VT– VT+ – VT– Input Currents Port 0, P1.2–P1.7, EA SCLOCK, SDATA/MOSI, MISO, SS11 RESET P1.0, P1.1, Ports 2 and 3 Input Capacitance CRYSTAL OSCILLATOR (XTAL1 AND XTAL2) Logic Inputs, XTAL1 Only 0.8 VINL, Input Low Voltage 0.4 3.5 VINH, Input High Voltage 2.5 XTAL1 Input Capacitance 18 XTAL2 Output Capacitance 18 REV. A REV. 0 V max V max V min V min pF typ pF typ –5– Available from Each Current Source Matching Between Both Current Sources AVDD = 5 V + 5% VIN = 450 mV, DVDD = 5 V All Digital Inputs DVDD = 5 V DVDD = 3 V DVDD = 5 V DVDD = 3 V ADuC816–SPECIFICATIONS1 Parameter ADuC816BS Unit Test Conditions/Comments 2.4 2.4 0.4 0.4 0.4 ± 10 5 V min V min V max V max V μA max pF typ VDD = 5 V, ISOURCE = 80 μA VDD = 3 V, ISOURCE = 20 μA ISINK = 8 mA, SCLOCK, SDATA/MOSI ISINK = 10 mA, P1.0 and P1.1 ISINK = 1.6 mA, All Other Outputs max 2.63 4.63 ± 3.5 2.63 4.63 ± 3.5 V min V max % max V min V max % max Four Trip Points Selectable in This Range Programmed via TPA1–0 in PSMCON 0 2000 ms min ms max Nine Timeout Periods in This Range Programmed via PRE3–0 in WDCON 98.3 kHz min Clock Rate Generated via On-Chip PLL Programmable via CD2–0 Bits in PLLCON SFR 12.58 MHz max 300 1 ms typ ms typ 1 1 1 3.4 ms typ ms typ ms typ ms typ 0.9 3.3 3.3 sec typ ms typ ms typ 2 LOGIC OUTPUTS (Not Including XTAL2) VOH, Output High Voltage VOL, Output Low Voltage12 Floating State Leakage Current Floating State Output Capacitance POWER SUPPLY MONITOR (PSM) AVDD Trip Point Selection Range AVDD Power Supply Trip Point Accuracy DVDD Trip Point Selection Range DVDD Power Supply Trip Point Accuracy WATCHDOG TIMER (WDT) Timeout Period MCU CORE CLOCK RATE MCU Clock Rate2 START-UP TIME At Power-On From Idle Mode From Power-Down Mode Oscillator Running Wake Up with INT0 Interrupt Wake Up with SPI/I2C Interrupt Wake Up with TIC Interrupt Wake Up with External RESET Oscillator Powered Down Wake Up with External RESET After External RESET in Normal Mode After WDT Reset in Normal Mode Four Trip Points Selectable in This Range Programmed via TPD1–0 in PSMCON OSC_PD Bit = 0 in PLLCON SFR OSC_PD Bit = 1 in PLLCON SFR Controlled via WDCON SFR 13 FLASH/EE MEMORY RELIABILITY CHARACTERISTICS Endurance14 100,000 Data Retention15 100 Cycles min Years min DVDD and AVDD Can Be Set Independently POWER REQUIREMENTS Power Supply Voltage AVDD, 3 V Nominal Operation AVDD, 5 V Nominal Operation DVDD, 3 V Nominal Operation DVDD, 5 V Nominal Operation 2.7 3.6 4.75 5.25 2.7 3.6 4.75 5.25 V min V max V min V max V min V max V min V max –6– REV. REV. A 0 ADuC816 Parameter POWER REQUIREMENTS (continued) Power Supply Currents Normal Mode16, 17 DVDD Current AVDD Current DVDD Current AVDD Current Power Supply Currents Idle Mode16, 17 DVDD Current AVDD Current DVDD Current ADuC816BS Unit Test Conditions/Comments 4 2.1 170 15 8 170 mA max mA max μA max mA max mA max μA max DVDD = 4.75 V to 5.25 V, Core CLK = 1.57 MHz DVDD = 2.7 V to 3.6 V, Core CLK = 1.57 MHz AVDD = 5.25 V, Core CLK = 1.57 MHz DVDD = 4.75 V to 5.25 V, Core CLK = 12.58 MHz DVDD = 2.7 V to 3.6 V, Core CLK = 12.58 MHz AVDD = 5.25 V, Core CLK = 12.58 MHz 1.2 750 140 2 1 140 mA max μA typ μA typ mA typ mA typ μA typ DVDD = 4.75 V to 5.25 V, Core CLK = 1.57 MHz DVDD = 2.7 V to 3.6 V, Core CLK = 1.57 MHz Measured @ AVDD = 5.25 V, Core CLK = 1.57 MHz DVDD = 4.75 V to 5.25 V, Core CLK = 12.58 MHz DVDD = 2.7 V to 3.6 V, Core CLK = 12.58 MHz Measured at AVDD = 5.25 V, Core CLK = 12.58 MHz Core CLK = 1.57 MHz or 12.58 MHz DVDD = 4.75 V to 5.25 V, Osc. On, TIC On DVDD = 2.7 V to 3.6 V, Osc. On, TIC On Measured at AVDD = 5.25 V, Osc. On or Osc. Off DVDD = 4.75 V to 5.25 V, Osc. Off DVDD = 2.7 V to 3.6 V, Osc. Off Core CLK = 1.57 MHz, AVDD = DVDD = 5 V AVDD Current Power Supply Currents Power-Down Mode16, 17 DVDD Current 50 20 1 AVDD Current DVDD Current 20 5 Typical Additional Power Supply Currents (AIDD and DIDD) PSM Peripheral 50 Primary ADC 1 Auxiliary ADC 500 DAC 150 Dual Current Sources 400 μA max μA max μA max μA max μA typ μA typ mA typ μA typ μA typ μA typ NOTES 1 Temperature Range –40°C to +85°C. 2 These numbers are not production tested but are guaranteed by Design and/or Characterization data on production release. 3 The primary ADC is factory-calibrated at 25°C with AVDD = DVDD = 5 V yielding this full-scale error. If user power supply or temperature conditions are significantly different from these, an Internal Full-Scale Calibration will restore this error to this level. 4 Gain Error Drift is a span drift. To calculate Full-Scale Error Drift, add the Offset Error Drift to the Gain Error Drift times the full-scale input. 5 The auxiliary ADC is factory-calibrated at 25°C with AVDD = DVDD = 5 V yielding this full-scale error of –2.5 LSB. A system zero-scale and full-scale calibration will remove this error altogether. 6 DAC linearity and AC Specifications are calculated using: reduced code range of 48 to 4095, 0 to V REF reduced code range of 48 to 3995, 0 to V DD. 7 Gain Error is a measure of the span error of the DAC. 8 In general terms, the bipolar input voltage range to the primary ADC is given by Range ADC = ± (VREF 2RN)/125, where: VREF = REFIN(+) to REFIN(–) voltage and V REF = 1.25 V when internal ADC V REF is selected. RN = decimal equivalent of RN2, RN1, RN0, e.g., V REF = 2.5 V and RN2, RN1, RN0 = 1, 1, 0 the Range ADC = ± 1.28 V. In unipolar mode the effective range is 0 V to 1.28 V in our example. 9 1.25 V is used as the reference voltage to the ADC when internal V REF is selected via XREF0 and XREF1 bits in ADC0CON and ADC1CON respectively. 10 In bipolar mode, the Auxiliary ADC can only be driven to a minimum of A GND – 30 mV as indicated by the Auxiliary ADC absolute AIN voltage limits. The bipolar range is still –V REF to +V REF; however, the negative voltage is limited to –30 mV. 11 Pins configured in I 2C-compatible mode or SPI mode, pins configured as digital inputs during this test. 12 Pins configured in I 2C-compatible mode only. 13 Flash/EE Memory Reliability Characteristics apply to both the Flash/EE program memory and Flash/EE data memory. 14 Endurance is qualified to 100 Kcycles as per JEDEC Std. 22 method A117 and measured at –40 °C, +25°C and +85°C, typical endurance at 25°C is 700 Kcycles. 15 Retention lifetime equivalent at junction temperature (T J) = 55°C as per JEDEC Std. 22, Method A117. Retention lifetime based on an activation energy of 0.6eV will derate with junction temperature as shown in Figure 27 in the Flash/EE Memory description section of this data sheet. 16 Power Supply current consumption is measured in Normal, Idle, and Power-Down Modes under the following conditions: Normal Mode: Reset = 0.4 V, Digital I/O pins = open circuit, Core Clk changed via CD bits in PLLCON, Core Executing internal software loop. Idle Mode: Reset = 0.4 V, Digital I/O pins = open circuit, Core Clk changed via CD bits in PLLCON, PCON.0 = 1, Core Execution suspended in idle mode. Power-Down Mode: Reset = 0.4 V, All P0 pins and P1.2–P1.7 pins = 0.4 V, All other digital I/O pins are open circuit, Core Clk changed via CD bits in PLLCON, PCON.1 = 1, Core Execution suspended in power-down mode, OSC turned ON or OFF via OSC_PD bit (PLLCON.7) in PLLCON SFR. 17 DVDD power supply current will typically increase by 3 mA (3 V operation) and 10 mA (5 V operation) during a Flash/EE memory program or erase cycle. Specifications subject to change without notice REV. A REV. 0 –7– ADuC816 TIMING SPECIFICATIONS1, 2, 3 (AVDD = 2.7 V to 3.6 V or 4.75 V to 5.25 V, DVDD = 2.7 V to 3.6 V or 4.75 V to 5.25 V; all specifications TMIN to TMAX unless otherwise noted.) 32.768 kHz External Crystal Min Typ Max Parameter CLOCK INPUT (External Clock Driven XTAL1) tCK XTAL1 Period tCKL XTAL1 Width Low tCKH XTAL1 Width High tCKR XTAL1 Rise Time tCKF XTAL1 Fall Time 1/tCORE ADuC816 Core Clock Frequency4 tCORE ADuC816 Core Clock Period5 tCYC ADuC816 Machine Cycle Time6 30.52 15.16 15.16 20 20 0.098 12.58 0.636 7.6 0.95 122.45 Unit Figure μs μs μs ns ns MHz μs μs 1 1 1 1 1 NOTES 1 AC inputs during testing are driven at DV DD – 0.5 V for a Logic 1, and 0.45 V for a Logic 0. Timing measurements are made at V IH min for a Logic 1, and V IL max for a Logic 0 as shown in Figure 2. 2 For timing purposes, a port pin is no longer floating when a 100 mV change from load voltage occurs. A port pin begins to float when a 100 mV change from the loaded VOH/VOL level occurs as shown in Figure 2. 3 CLOAD for Port0, ALE, PSEN outputs = 100 pF; CLOAD for all other outputs = 80 pF unless otherwise noted. 4 ADuC816 internal PLL locks onto a multiple (384 times) the external crystal frequency of 32.768 kHz to provide a Stable 12.583 MHz internal clock for the system. The core can operate at this frequency or at a binary submultiple called Core_Clk, selected via the PLLCON SFR. 5 This number is measured at the default Core_Clk operating frequency of 1.57 MHz. 6 ADuC816 Machine Cycle Time is nominally defined as 12/Core_CLK. Specifications subject to change without notice. tCKR tCHK tCKL tCKF tCK Figure 1. XTAL1 Input DVDD – 0.5V 0.2DVDD + 0.9V TEST POINTS 0.2DVDD – 0.1V VLOAD – 0.1V VLOAD VLOAD + 0.1V 0.45V TIMING REFERENCE POINTS VLOAD – 0.1V VLOAD VLOAD + 0.1V Figure 2. Timing Waveform Characteristics –8– REV. REV. A 0 ADuC816 Parameter EXTERNAL PROGRAM MEMORY tLHLL ALE Pulsewidth tAVLL Address Valid to ALE Low tLLAX Address Hold after ALE Low tLLIV ALE Low to Valid Instruction In tLLPL ALE Low to PSEN Low tPLPH PSEN Pulsewidth tPLIV PSEN Low to Valid Instruction In tPXIX Input Instruction Hold after PSEN tPXIZ Input Instruction Float after PSEN tAVIV Address to Valid Instruction In tPLAZ PSEN Low to Address Float tPHAX Address Hold after PSEN High 12.58 MHz Core_Clk Min Max Variable Core_Clk Min Max 119 39 49 2tCORE – 40 tCORE – 40 tCORE – 30 218 4tCORE – 100 49 193 tCORE – 30 3tCORE – 45 133 3tCORE – 105 0 0 54 292 25 tCORE – 25 5tCORE – 105 25 0 0 CORE_CLK tLHLL ALE (O) tAVLL tPLPH tLLPL tLLIV tPLIV PSEN (O) tLLAX PORT 0 (I/O) tPXIZ tPLAZ tPXIX PCL (OUT) INSTRUCTION (IN) tAVIV tPHAX PORT 2 (O) PCH Figure 3. External Program Memory Read Cycle REV. REV. A 0 –9– Unit Figure ns ns ns ns ns ns ns ns ns ns ns ns 3 3 3 3 3 3 3 3 3 3 3 3 ADuC816 12.58 MHz Core_Clk Min Max Parameter EXTERNAL DATA MEMORY READ CYCLE tRLRH RD Pulsewidth tAVLL Address Valid after ALE Low tLLAX Address Hold after ALE Low tRLDV RD Low to Valid Data In tRHDX Data and Address Hold after RD tRHDZ Data Float after RD tLLDV ALE Low to Valid Data In tAVDV Address to Valid Data In tLLWL ALE Low to RD Low tAVWL Address Valid to RD Low tRLAZ RD Low to Address Float tWHLH RD High to ALE High Variable Core_Clk Min Max 377 39 44 6tCORE – 100 tCORE – 40 tCORE – 35 232 5tCORE – 165 0 0 89 486 550 288 188 188 3tCORE – 50 4tCORE – 130 0 119 39 tCORE – 40 2tCORE – 70 8tCORE – 150 9tCORE – 165 3tCORE + 50 0 tCORE + 40 Unit Figure ns ns ns ns ns ns ns ns ns ns ns ns 4 4 4 4 4 4 4 4 4 4 4 4 CORE_CLK ALE (O) tWHLH PSEN (O) tLLDV tLLWL tRLRH RD (O) tAVWL tRLDV tAVLL tLLAX tRHDX tRHDZ tRLAZ PORT 0 (I/O) A0 – A7 (OUT) DATA (IN) tAVDV PORT 2 (O) A16 – A23 A8 – A15 Figure 4. External Data Memory Read Cycle –10– REV. REV. A 0 ADuC816 Parameter 12.58 MHz Core_Clk Min Max EXTERNAL DATA MEMORY WRITE CYCLE tWLWH WR Pulsewidth tAVLL Address Valid after ALE Low tLLAX Address Hold after ALE Low tLLWL ALE Low to WR Low tAVWL Address Valid to WR Low tQVWX Data Valid to WR Transition tQVWH Data Setup before WR tWHQX Data and Address Hold after WR tWHLH WR High to ALE High 377 39 44 188 188 29 406 29 39 288 119 Variable Core_Clk Min Max 6tCORE – 100 tCORE – 40 tCORE – 35 3tCORE – 50 4tCORE – 130 tCORE – 50 7tCORE – 150 tCORE – 50 tCORE – 40 3tCORE + 50 tCORE + 40 CORE_CLK ALE (O) tWHLH PSEN (O) tLLWL tWLWH WR (O) tAVWL tAVLL tLLAX PORT 0 (O) A0 – A7 PORT 2 (O) A16 – A23 tQVWX tWHQX tQVWH DATA A8 – A15 Figure 5. External Data Memory Write Cycle REV. REV. A 0 –11– Unit Figure ns ns ns ns ns ns ns ns ns 5 5 5 5 5 5 5 5 5 ADuC816 Parameter 12.58 MHz Core_Clk Min Typ Max UART TIMING (Shift Register Mode) tXLXL Serial Port Clock Cycle Time tQVXH Output Data Setup to Clock tDVXH Input Data Setup to Clock tXHDX Input Data Hold after Clock tXHQX Output Data Hold after Clock 662 292 0 42 Min Variable Core_Clk Typ Max 0.95 2tCORE 10tCORE – 133 2tCORE + 133 0 2tCORE – 117 Unit Figure μs ns ns ns ns 6 6 6 6 ALE (O) tXLXL TXD (OUTPUT CLOCK) 67 01 SET RI OR SET TI tQVXH tXHQX RXD (OUTPUT DATA) MSB BIT 6 BIT 1 tDVXH RXD (INPUT DATA) MSB tXHDX BIT 6 BIT 1 LSB Figure 6. UART Timing in Shift Register Mode –12– REV.A0 REV. ADuC816 Parameter Min Max Unit Figure μs μs μs μs μs μs μs μs 7 7 7 7 7 7 7 7 ns ns ns 7 7 7 2 I C-COMPATIBLE INTERFACE TIMING tL SCLOCK Low Pulsewidth tH SCLOCK High Pulsewidth tSHD Start Condition Hold Time tDSU Data Setup Time tDHD Data Hold Time tRSU Setup Time for Repeated Start tPSU Stop Condition Setup Time tBUF Bus Free Time between a STOP Condition and a START Condition tR Rise Time of Both SCLOCK and SDATA tF Fall Time of Both SCLOCK and SDATA tSUP* Pulsewidth of Spike Suppressed 4.7 4.0 0.6 100 0.9 0.6 0.6 1.3 300 300 50 *Input filtering on both the SCLOCK and SDATA inputs suppresses noise spikes less than 50 ns. tBUF tSUP SDATA (I/O) LSB MSB tDSU tPSU tDSU 2-7 8 PS tL –13– tF tR tRSU 1 9 tSUP Figure 7. I 2C-Compatible Interface Timing REV. 0 REV. A MSB tDHD tH 1 START STOP CONDITION CONDITION ACK tDHD tSHD SCLK (I) tR S(R) REPEATED START tF ADuC816 Parameter Min SPI MASTER MODE TIMING (CPHA = 1) SCLOCK Low Pulsewidth* tSL tSH SCLOCK High Pulsewidth* tDAV Data Output Valid after SCLOCK Edge tDSU Data Input Setup Time before SCLOCK Edge tDHD Data Input Hold Time after SCLOCK Edge tDF Data Output Fall Time tDR Data Output Rise Time tSR SCLOCK Rise Time tSF SCLOCK Fall Time Typ Max 630 630 50 100 100 10 10 10 10 25 25 25 25 Unit Figure ns ns ns ns ns ns ns ns ns 8 8 8 8 8 8 8 8 8 *Characterized under the following conditions: a. Core clock divider bits CD2, CD1, and CD0 bits in PLLCON SFR set to 0, 1, and 1 respectively, i.e., core clock frequency = 1.57 MHz and b. SPI bit-rate selection bits SPR1 and SPR0 bits in SPICON SFR set to 0 and 0 respectively. SCLOCK (CPOL = 0) tSH tSL tSR SCLOCK (CPOL = 1) tDAV tDF tSF tDR MOSI BITS 6 – 1 MSB MISO BITS 6 – 1 MSB IN tDSU LSB LSB IN tDHD Figure 8. SPI Master Mode Timing (CPHA = 1) –14– REV. REV. 0 A ADuC816 Parameter Min SPI MASTER MODE TIMING (CPHA = 0) tSL SCLOCK Low Pulsewidth* tSH SCLOCK High Pulsewidth* tDAV Data Output Valid after SCLOCK Edge tDOSU Data Output Setup before SCLOCK Edge tDSU Data Input Setup Time before SCLOCK Edge tDHD Data Input Hold Time after SCLOCK Edge tDF Data Output Fall Time tDR Data Output Rise Time tSR SCLOCK Rise Time tSF SCLOCK Fall Time Typ Max 630 630 50 150 100 100 10 10 10 10 25 25 25 25 Unit Figure ns ns ns ns ns ns ns ns ns ns 9 9 9 9 9 9 9 9 9 9 *Characterized under the following conditions: a. Core clock divider bits CD2, CD1 and CD0 bits in PLLCON SFR set to 0, 1, and 1 respectively, i.e., core clock frequency = 1.57 MHz and b. SPI bit-rate selection bits SPR1 and SPR0 bits in SPICON SFR set to 0 and 0 respectively. SCLOCK (CPOL = 0) tSH tSL tSR SCLOCK (CPOL = 1) tSF tDAV tDOSU MOSI MISO tDF MSB MSB IN tDSU tDR BITS 6 – 1 BITS 6 – 1 LSB LSB IN tDHD Figure 9. SPI Master Mode Timing (CPHA = 0) REV. A REV. 0 –15– ADuC816 Parameter Min SPI SLAVE MODE TIMING (CPHA = 1) SS to SCLOCK Edge tSS tSL SCLOCK Low Pulsewidth tSH SCLOCK High Pulsewidth tDAV Data Output Valid after SCLOCK Edge tDSU Data Input Setup Time before SCLOCK Edge tDHD Data Input Hold Time after SCLOCK Edge tDF Data Output Fall Time tDR Data Output Rise Time tSR SCLOCK Rise Time tSF SCLOCK Fall Time tSFS SS High after SCLOCK Edge Typ Max 0 330 330 50 100 100 10 10 10 10 25 25 25 25 0 Unit Figure ns ns ns ns ns ns ns ns ns ns ns 10 10 10 10 10 10 10 10 10 10 10 SS tSFS tSS SCLOCK (CPOL = 0) tDF tSL tSH tSR tSF SCLOCK (CPOL = 1) tDAV tDF MISO MOSI BITS 6 – 1 MSB BITS 6 – 1 MSB IN tDSU tDR LSB LSB IN tDHD Figure 10. SPI Slave Mode Timing (CPHA = 1) –16– REV. A REV. 0 ADuC816 Parameter Min SPI SLAVE MODE TIMING (CPHA = 0) SS to SCLOCK Edge tSS tSL SCLOCK Low Pulsewidth tSH SCLOCK High Pulsewidth tDAV Data Output Valid after SCLOCK Edge tDSU Data Input Setup Time before SCLOCK Edge tDHD Data Input Hold Time after SCLOCK Edge tDF Data Output Fall Time tDR Data Output Rise Time tSR SCLOCK Rise Time tSF SCLOCK Fall Time tSSR SS to SCLOCK Edge tDOSS Data Output Valid after SS Edge tSFS SS High after SCLOCK Edge Typ Max 0 330 330 50 100 100 10 10 10 10 25 25 25 25 50 20 0 SS tSFS tSS SCLOCK (CPOL = 0) tSH tSL tSF tSR SCLOCK (CPOL = 1) tDAV tDOSS tDF MSB MISO MOSI MSB IN tDSU tDR BITS 6 – 1 BITS 6 – 1 LSB LSB IN tDHD Figure 11. SPI Slave Mode Timing (CPHA = 0) REV. A REV. 0 –17– Unit Figure ns ns ns ns ns ns ns ns ns ns ns ns ns 11 11 11 11 11 11 11 11 11 11 11 11 11 ADuC816 ABSOLUTE MAXIMUM RATINGS (TA = 25°C unless otherwise noted) Parameter AVDD to AGND AVDD to DGND DVDD to AGND DVDD to DGND AGND to DGND1 AVDD to DVDD Analog Input Voltage to AGND2 Reference Input Voltage to AGND AIN/REFIN Current (Indefinite) Digital Input Voltage to DGND Digital Output Voltage to DGND Operating Temperature Range Storage Temperature Range Junction Temperature șJA Thermal Impedance (MQFP) șJA Thermal Impedance (LFCSP Base Floating) Lead Temperature, Soldering Vapor Phase (60 sec) Infrared (15 sec) 1 2 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 listed in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Ratings −0.3 V to +7 V −0.3 V to +7 V −0.3 V to +7 V −0.3 V to +7 V −0.3 V to +0.3 V −2 V to +5 V −0.3 V to AVDD +0.3 V −0.3 V to AVDD +0.3 V 30 mA −0.3 V to DVDD +0.3 V −0.3 V to DVDD +0.3 V −40°C to +85°C −65°C to +150°C 150°C 90°C/W 52°C/W 215°C 220°C AGND and DGND are shorted internally on the ADuC816. Applies to P1.2 to P1.7 pins operating in analog or digital input modes. ESD CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although this product features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. –18– REV. A ADuC816 PIN FUNCTION DESCRIPTIONS 52 40 1 39 56 PIN 1 1 43 42 PIN 1 INDICATOR ADuC816 ADuC816 TOP VIEW (Not to Scale) TOP VIEW (Not to Scale) 14 29 26 00436-001 14 NOTES 1. THE EXPOSED PADDLE MUST BE LEFT UNCONNECTED. 56-Lead MQFP 00436-002 28 15 27 13 56-Lead LFCSP PIN FUNCTION DESCRIPTIONS Pin No. 52-Lead MQFP 1, 2 Pin No. 56-Lead CSP 56, 1 Mnemonic P1.0/P1.1 Type1 I/O P1.0/T2 I/O P1.1/T2EX I/O 3–4, 2–3, P1.2–P1.7 I 9–12 11–14 P1.2/DAC/IEXC1 I/O P1.3/AIN5/IEXC2 I/O P1.4/AIN1 P1.5/AIN2 P1.6/AIN3 P1.7/AIN4/DAC I I I I/O Description P1.0 and P1.1 can function as digital inputs or digital outputs and have a pull-up configuration as described for Port 3. P1.0 and P1.1 have an increased current drive sink capability of 10 mA. P1.0 and P1.1 also have various secondary functions as described below. P1.0 can be used to provide a clock input to Timer 2. When enabled, Counter 2 is incremented in response to a negative transition on the T2 input pin. P1.1 can also be used to provide a control input to Timer 2.When enabled, a negative transition on the T2EX input pin will cause a Timer 2 capture or reload event. Port 1.2 to Port 1.7 have no digital output driver; they can function as a digital input for which 0 must be written to the port bit. As a digital input, these pins must be driven high or low externally. These pins also have the following analog functionality: The voltage output from the DAC or one or both current sources (200 μA or 2 × 200 μA) can be configured to appear at this pin. Auxiliary ADC input or one or both current sources can be configured at this pin. Primary ADC, Positive Analog Input Primary ADC, Negative Analog Input Auxiliary ADC Input or Muxed Primary ADC, Positive Analog Input Auxiliary ADC Input or Muxed Primary ADC, Negative Analog Input. The voltage output from the DAC can also be configured to appear at this pin. Analog Supply Voltage, 3 V or 5 V Analog Ground. Ground reference pin for the analog circuitry. Reference Input, Negative Terminal Reference Input, Positive Terminal Slave Select Input for the SPI Interface. A weak pull-up is present on this pin. 5 6 7 8 13 4, 5 6, 7, 8 9 10 15 AVDD AGND REFIN(–) REFIN(+) SS S S I I I 14 15 16 17 MISO RESET I/O I 16–19, 22–25 18–21, 24–27 P3.0–P3.7 P3.0/RXD I/O I/O P3.1/TXD P3.2/INT0 I/O I/O P3.3/INT1 P3.4/T0 P3.5/T1 P3.6/WR I/O External Interrupt 1.This pin can also be used as a gate control input to Timer 1. I/O I/O I/O P3.7/RD I/O Timer/Counter 0 External Input. Timer/Counter 1 External Input External Data Memory Write Strobe. Latches the data byte from Port 0 into an external data memory. External Data Memory Read Strobe. Enables the data from an external data memory to Port 0. REV. A Master Input/Slave Output for the SPI Interface. A weak pull-up is present on this input pin Reset Input. A high level on this pin for 16 core clock cycles while the oscillator is running resets the device. There is an internal weak pull-down and a Schmitt trigger input stage on this pin. P3.0–P3.7 are bidirectional port pins with internal pull-up resistors. Port 3 pins that have 1s written to them are pulled high by the internal pull-up resistors, and in that state can be used as inputs. As inputs, Port 3 pins being pulled externally low will source current because of the internal pull-up resistors.When driving a 0-to-1 output transition, a strong pull-up is active for two core clock periods of the instruction cycle. Port 3 pins also have various secondary functions including: Receiver Data for UART Serial Port Transmitter Data for UART Serial Port External Interrupt 0.This pin can also be used as a gate control input to Timer 0. –19– ADuC816 Pin No. 52-Lead MQFP 20, 34, 48 21, 35, 47 26 Pin No. 56-Lead CSP 22, 36, 51, 23, 37, 38, 50 27 Mnemonic DVDD DGND SCLOCK Type1 S S I/O MOSI/SDATA I/O 28–31 36–39 30–33 39–42 P2.0–P2.7 (A8–A15) (A16–A23) I/O 32 33 34 35 XTAL1 XTAL2 I O 40 43 EA I/O 41 44 PSEN O 42 45 ALE O 43–46 49–52 46–49 52–55 P0.0–P0.7 (AD0–AD3) I/O 1 Description Digital Supply, 3 V or 5 V Digital Ground. Ground reference point for the digital circuitry. Serial Interface Clock for either the I2C or SPI Interface. As an input, this pin is a Schmitt-triggered input, and a weak internal pull-up is present on this pin unless it is outputting logic low. This pin can also be directly controlled in software as a digital output pin. Serial Data I/O for the I2C Interface or Master Output/Slave Input for the SPI Interface. A weak internal pull-up is present on this pin unless it is outputting logic low. This pin can also be directly controlled in software as a digital output pin. Port 2 is a bidirectional port with internal pull-up resistors. Port 2 pins that have 1s written to them are pulled high by the internal pull-up resistors, and in that state can be used as inputs. As inputs, Port 2 pins being pulled externally low will source current because of the internal pull-up resistors. Port 2 emits the high order address bytes during fetches from external program memory and middle and high order address bytes during accesses to the 24-bit external data memory space. Input to the Crystal Oscillator Inverter Output from the Crystal Oscillator Inverter. (See the ADuC816 Hardware Design Considerations section for description.) External Access Enable, Logic Input. When held high, this input enables the device to fetch code from internal program memory locations 0000h to F7FFh.When held low, this input enables the device to fetch all instructions from external program memory. To determine the mode of code execution, i.e., internal or external, the EA pin is sampled at the end of an external RESET assertion or as part of a device power cycle. EA may also be used as an external emulation I/O pin, and therefore the voltage level at this pin must not be changed during normal mode operation as it may cause an emulation interrupt that will halt code execution. Program Store Enable, Logic Output. This output is a control signal that enables the external program memory to the bus during external fetch operations. It is active every six oscillator periods except during external data memory accesses. This pin remains high during internal program execution. PSEN can also be used to enable Serial Download mode when pulled low through a resistor at the end of an external RESET assertion or as part of a device power cycle. Address Latch Enable, Logic Output. This output is used to latch the low byte (and page byte for 24-bit data address space accesses) of the address to external memory during external code or data memory access cycles. It is activated every six oscillator periods except during an external data memory access. It can be disabled by setting the PCON.4 bit in the PCON SFR. These pins are part of Port 0, which is an 8-bit, open-drain, bidirectional I/O port. Port 0 pins that have 1s written to them float and in that state can be used (AD4–AD7)as high impedance inputs. An external pull-up resistor will be required on P0 outputs to force a valid logic high level externally. Port 0 is also the multiplexed low order address and data bus during accesses to external program or data memory. In this application, it uses strong internal pull-ups when emitting 1s. I = Input, O = Output, S = Supply. –20– REV. A ADuC816 Figure 12. 52-MQFP Block Diagram REV. A –21– ADuC816 MEMORY ORGANIZATION DATA MEMORY SPACE READ/WRITE As with all 8051-compatible devices, the ADuC816 has separate address spaces for Program and Data memory as shown in Figure 13 and Figure 14. 9FH FFFFFFH (PAGE 159) 640 BYTES FLASH/EE DATA MEMORY ACCESSED INDIRECTLY VIA SFR CONTROL REGISTERS If the user applies power or resets the device while the EA pin is pulled low, the part will execute code from the external program space, otherwise the part defaults to code execution from its internal 8 Kbyte Flash/EE program memory. This internal code space can be downloaded via the UART serial port while the device is in-circuit. 00H (PAGE 0) EXTERNAL DATA MEMORY SPACE (24-BIT ADDRESS SPACE) INTERNAL DATA MEMORY SPACE PROGRAM MEMORY SPACE READ ONLY FFFFH FFH ACCESSIBLE BY INDIRECT ADDRESSING ONLY UPPER 128 EXTERNAL PROGRAM MEMORY SPACE 80H 7FH LOWER 128 00H 2000H FFH SPECIAL FUNCTION REGISTERS ACCESSIBLE BY DIRECT ADDRESSING ONLY 80H ACCESSIBLE BY DIRECT AND INDIRECT ADDRESSING 000000H Figure 14. Data Memory Map EA = 1 INTERNAL 8 KBYTE FLASH/EE PROGRAM MEMORY 1FFFH EA = 0 EXTERNAL PROGRAM MEMORY SPACE 0000H Figure 13. Program Memory Map The data memory address space consists of internal and external memory space. The internal memory space is divided into four physically separate and distinct blocks, namely the lower 128 bytes of RAM, the upper 128 bytes of RAM, the 128 bytes of special function register (SFR) area, and a 640-byte Flash/EE Data memory. While the upper 128 bytes of RAM, and the SFR area share the same address locations, they are accessed through different address modes. The lower 128 bytes of internal data memory are mapped as shown in Figure 15. The lowest 32 bytes are grouped into four banks of eight registers addressed as R0 through R7. The next 16 bytes (128 bits), locations 20Hex through 2FHex above the register banks, form a block of directly addressable bit locations at bit addresses 00H through 7FH. The stack can be located anywhere in the internal memory address space, and the stack depth can be expanded up to 256 bytes. The lower 128 bytes of data memory can be accessed through direct or indirect addressing, the upper 128 bytes of RAM can be accessed through indirect addressing, and the SFR area is accessed through direct addressing. 7FH GENERAL-PURPOSE AREA 30H 2FH BANKS BIT-ADDRESSABLE (BIT ADDRESSES) SELECTED VIA 20H BITS IN PSW 1FH 11 18H 17H Also, as shown in Figure 13, the additional 640 Bytes of Flash/EE Data Memory are available to the user and can be accessed indirectly via a group of control registers mapped into the Special Function Register (SFR) area. Access to the Flash/ EE Data Memory is discussed in detail later as part of the Flash/ EE Memory section in this data sheet. 10 10H 0FH 01 FOUR BANKS OF EIGHT REGISTERS R0 R7 08H 07H 00 RESET VALUE OF STACK POINTER 00H The external data memory area can be expanded up to 16 MBytes. This is an enhancement of the 64 KByte external data memory space available on standard 8051-compatible cores. Figure 15. Lower 128 Bytes of Internal Data Memory The external data memory is discussed in more detail in the ADuC816 Hardware Design Considerations section. –22– REV. A 0 REV. ADuC816 Reset initializes the stack pointer to location 07 hex and increments it once to start from locations 08 hex which is also the first register (R0) of register bank 1. Thus, if one is going to use more than one register bank, the stack pointer should be initialized to an area of RAM not used for data storage. The SFR space is mapped to the upper 128 bytes of internal data memory space and 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 ADuC816 via the SFR area is shown in Figure 16. A complete SFR map is shown in Figure 17. Program Status Word SFR The PSW register is the Program Status Word which contains several bits reflecting the current status of the CPU as detailed in Table I. SFR Address Power ON Default Value Bit Addressable CY AC F0 D0H 00H Yes RS1 RS0 OV F1 P Table I. PSW SFR Bit Designations 640-BYTE ELECTRICALLY REPROGRAMMABLE NONVOLATILE FLASH/EE DATA MEMORY 8 KBYTE ELECTRICALLY REPROGRAMMABLE NONVOLATILE FLASH/EE PROGRAM MEMORY 8051COMPATIBLE CORE 128-BYTE SPECIAL FUNCTION REGISTER AREA 256 BYTES RAM DUAL SIGMA-DELTA ADCs OTHER ON-CHIP PERIPHERALS TEMPERATURE SENSOR CURRENT SOURCES 12-BIT DAC SERIAL I/O WDT PSM TIC PLL Figure 16. Programming Model OVERVIEW OF MCU-RELATED SFRS Accumulator SFR ACC is the Accumulator register and is used for math operations including addition, subtraction, integer multiplication and division, and Boolean bit manipulations. The mnemonics for accumulatorspecific instructions refer to the Accumulator as A. Bit Name Description 7 6 5 4 3 CY AC F0 RS1 RS0 2 1 0 OV F1 P Carry Flag Auxiliary Carry Flag General-Purpose Flag Register Bank Select Bits RS1 RS0 Selected Bank 0 0 0 0 1 1 1 0 2 1 1 3 Overflow Flag General-Purpose Flag Parity Bit Power Control SFR The Power Control (PCON) register contains bits for powersaving options and general-purpose status flags as shown in Table II. SFR Address Power ON Default Value Bit Addressable SMOD B SFR The B register is used with the ACC for multiplication and division operations. For other instructions it can be treated as a general-purpose scratchpad register. Stack Pointer SFR The SP register is the stack pointer and is used to hold an internal RAM address that is called the “top of the stack.” The SP register is incremented before data is stored during PUSH and CALL executions. While the Stack may reside anywhere in on-chip RAM, the SP register is initialized to 07H after a reset. This causes the stack to begin at location 08H. Data Pointer The Data Pointer is made up of three 8-bit registers, named DPP (page byte), DPH (high byte) and DPL (low byte). These are used to provide memory addresses for internal and external code access and external data access. It may be manipulated as a 16-bit register (DPTR = DPH, DPL), although INC DPTR instructions will automatically carry over to DPP, or as three independent 8-bit registers (DPP, DPH, DPL). REV. REV. A 0 SERIPD 87H 00H No INT0PD ALEOFF GF1 GF 0 PD IDL Table II. PCON SFR Bit Designations Bit Name Description 7 6 SMOD SERIPD 5 INT0PD 4 3 2 1 0 ALEOFF GF1 GF0 PD IDL Double UART Baud Rate I2C/SPI Power-Down Interrupt Enable INT0 Power-Down Interrupt Enable Disable ALE Output General-Purpose Flag Bit General-Purpose Flag Bit Power-Down Mode Enable Idle Mode Enable –23– ADuC816 SPECIAL FUNCTION REGISTERS Figure 17 shows a full SFR memory map and SFR contents on RESET; NOT USED indicates unoccupied SFR locations. Unoccupied locations in the SFR address space are not implemented; i.e., no register exists at this location. If an unoccupied location is read, an unspecified value is returned. SFR locations reserved for future use are shaded (RESERVED) and should not be accessed by user software. All registers except the program counter and the four generalpurpose register banks, reside in the SFR area. The SFR registers include control, configuration, and data registers that provide an interface between the CPU and all on-chip peripherals. ISPI WCOL SPE SPIM CPOL CPHA SPR1 SPR0 FFH 0 FEH 0 FDH 0 FCH 0 FBH 0 FAH 1 F9H 0 F8H 0 F7H 0 F6H 0 F5H 0 F4H 0 F3H 0 F2H 0 F1H 0 F0H 0 SPICON DACL DACH DACCON RESERVED RESERVED BITS F8H RESERVED RESERVED FBH 04H 00H FCH 00H FDH 00H B MDO MDE MCO MDI I2CM I2CRS I2CTX SPIDAT RESERVED RESERVED BITS F0H I2CI BITS 0 EEH 0 EDH 0 ECH 0 EBH 0 EAH 0 E9H 0 E8H 0 E7H 0 E6H 0 E5H 0 E4H 0 E3H 0 E2H 0 E1H 0 E0H 0 GN0M* 0 D9H 0 D8H 0 RDY0 0 CY D7H CAL 0 DDH AC 0 TF2 CFH RDY1 DEH D6H CEH C7H 0 C6H BFH 0 BEH PRE3 WR C4H 0 BCH B6H 1 B5H AFH 0 AEH A7H 1 A6H 9FH 0 9EH 0 97H 1 96H 8FH 0 87H 1 OV EXEN2 WDIR TR2 PT1 PX1 0 WDWR 0 C0H PT0 TXD ACH 0 ABH 0 AAH 0 A9H 0 A8H 0 1 A5H 1 A4H 1 A3H 1 A2H 1 A1H 1 A0H 1 9DH 0 9CH 0 9BH 0 9AH 0 99H 1 95H 1 94H 1 93H 1 1 91H 8EH 0 8DH 0 8CH 0 8BH 0 8AH 0 89H 0 88H 0 86H 1 85H 1 84H 1 83H 1 1 81H 1 80H 1 EX1 ET0 SM1 SM2 REN TB8 RB8 1 T2EX TF1 TR1 TF0 TR0 IE1 92H IT1 IE0 0 OF1H* ADC0H E4H 00H ADC1L E5H 80H ADC1H PSMCON RESERVED 00H DBH 00H ADC1CON 00H D1H D2H D3H 00H 07H RCAP2L DCH 00H SF DDH DFH 00H ICON 00H RCAP2H D4H 45H TL2 D5H DEH PLLCON C8H WDCON BITS 00H CBH 00H CCH 00H CDH 00H CHIPID EADRL RESERVED RESERVED RESERVED RESERVED 10H C0H 03H TH2 RESERVED RESERVED CAH 00H D7H 00H RESERVED BITS C2H RESERVED C6H 16H ECON EDATA1 EDATA2 00H EDATA3 EDATA4 RESERVED RESERVED B8H 00H B9H BITS BCH 00H NOT USED B0H 00H BDH 00H BEH 00H BFH 00H NOT USED NOT USED NOT USED RESERVED RESERVED NOT USED FFH IEIP2 BITS RESERVED RESERVED A8H 00H A9H FFH A1H RESERVED RESERVED RESERVED RESERVED A0H TIMECON HTHSEC SEC MIN HOUR INTVAL BITS NOT USED A0H 00H SBUF A2H 00H I2CDAT A3H 00H 98H 00H 99H 00H 9AH 00H A4H 00H A5H 00H A6H 00H I2CDAT BITS 1 BITS NOT USED 90H 9BH NOT USED NOT USED NOT USED NOT USED NOT USED NOT USED NOT USED NOT USED 00H TCON IT0 NOT USED NOT USED FFH TMOD TL0 TL1 TH0 TH1 BITS RESERVED RESERVED 88H 00H 89H FFH 81H P0 82H 59H P1 T2 1 90H 80H ADC0CON SCON R1 0 98H E3H ADCMODE IE EX0 T1 OF1L* EDH RESERVED D0H P2 SM0 9AH P3 0 ET1 00H ADC0M DAH 00H BITS RXD 1 B0H OF0H* ECH BITS 0 0 ADH ES 1 B1H 53H RESERVED D8H IP PX0 0 B8H EBH RESERVED RESERVED E2H 00H BITS 0 B4H ET2 1 B2H CAP2 55H OF0M* T2CON 1 EADC 1 B3H C1H B9H INT0 0 0 C8H WDE 0 BAH INT1 0 D0H CNT2 0 E0H 00H GN1H* RESERVED BITS PSW P D1H 0 C9H WDS 0 C2H 0 BBH T0 0 0 CAH 1 C3H PS FI 0 D2H 0 CBH PRE0 0 T1 1 EA CCH PT2 0 BDH RS0 GN1L* RESERVED RESERVED EAH 00H ADCSTAT ERR1 0 DAH 0 D3H TCLK 0 PRE1 0 C5H PADC B7H D4H ERR0 0 DBH RSI 0 RCLK 0 CDH PRE2 RD DCH F0 0 D5H EXF2 0 NOXREF 0 GN0H* RESERVED E8H ACC DFH RESERVED RESERVED RESERVED F7H I2CCON EFH NOT USED 00H 00H 8AH 07H 82H SP 00H DPL 8BH 00H DPH 8CH 00H 8DH 00H DPP BITS PCON RESERVED RESERVED 80H 00H 83H 00H 84H 00H 87H 00H *CALIBRATION COEFFICIENTS ARE PRECONFIGURED AT POWER-UP TO FACTORY-CALIBRATED VALUES. SFR MAP KEY: THESE BITS ARE CONTAINED IN THIS BYTE. BIT MNEMONIC BIT BIT ADDRESS DEFAULT BIT VALUE IE0 89H TCON IT0 0 88H 0 88H 00H MNEMONIC DEFAULT VALUE SFR ADDRESS SFR NOTE: SFRs WHOSE ADDRESSES END IN 0H OR 8H ARE BIT-ADDRESSABLE. Figure 17. Special Function Register Locations and Reset Values –24– REV. REV. 0 A ADuC816 SFR INTERFACE TO THE PRIMARY AND AUXILIARY ADCS Both ADCs are controlled and configured via a number of SFRs that are mentioned here and described in more detail in the following pages. ICON: Current Source Control Register. Allows user control of the various on-chip current source options. ADC0H/M*: Primary ADC 16-bit conversion result held in these two 8-bit registers. ADCSTAT: ADC Status Register. Holds general status of the Primary and Auxiliary ADCs. ADC1H/L: Auxiliary ADC 16-bit conversion result held in these two 8-bit registers. ADCMODE: ADC Mode Register. Controls general modes of operation for Primary and Auxiliary ADCs. OF0H/M*: Primary ADC 16-bit Offset Calibration Coefficient held in these two 8-bit registers. ADC0CON: Primary ADC Control Register. Controls specific configuration of Primary ADC. OF1H/L: Auxiliary ADC 16-bit Offset Calibration Coefficient held in these two 8-bit registers. ADC1CON: Auxiliary ADC Control Register. Controls specific configuration of Auxiliary ADC. GN0H/M*: Primary ADC 16-bit Gain Calibration Coefficient held in these two 8-bit registers. SF: Sinc Filter Register. Configures the decimation factor for the Sinc3 filter and thus the Primary and Auxiliary ADC update rates. GN1H/L: Auxiliary ADC 16-bit Gain Calibration Coefficient held in these two 8-bit registers. *To maintain code compatibility with the ADuC824, it is the low-byte SFR associated with these register groups that is omitted on the ADuC816. ADCSTAT (ADC Status Register) This SFR reflects the status of both ADCs including data ready, calibration and various (ADC-related) error and warning conditions including reference detect and conversion overflow/underflow flags. SFR Address Power-On Default Value Bit Addressable RDY0 RDY1 D8H 00H Yes CAL NOXREF ERR0 ERR 1 --- --- Table III. ADCSTAT SFR Bit Designations Bit Name Description 7 RDY0 6 RDY1 5 CAL 4 NOXREF 3 ERR0 2 ERR1 1 0 ----- Ready Bit for Primary ADC. Set by hardware on completion of ADC conversion or calibration cycle. Cleared directly by the user or indirectly by write to the mode bits to start another Primary ADC conversion or calibration. The Primary ADC is inhibited from writing further results to its data or calibration registers until the RDY0 bit is cleared. Ready Bit for Auxiliary ADC. Same definition as RDY0 referred to the Auxiliary ADC. Calibration Status Bit. Set by hardware on completion of calibration. Cleared indirectly by a write to the mode bits to start another ADC conversion or calibration. No External Reference Bit (only active if Primary or Auxiliary ADC is active). Set to indicate that one or both of the REFIN pins is floating or the applied voltage is below a specified threshold. When Set conversion results are clamped to all ones,if using ext. reference. Cleared to indicate valid VREF. Primary ADC Error Bit. Set by hardware to indicate that the result written to the Primary ADC data registers has been clamped to all zeros or all ones. After a calibration this bit also flags error conditions that caused the calibration registers not to be written. Cleared by a write to the mode bits to initiate a conversion or calibration. Auxiliary ADC Error Bit. Same definition as ERR0 referred to the Auxiliary ADC. Reserved for Future Use. Reserved for Future Use. REV. REV. A 0 –25– ADuC816 ADCMODE (ADC Mode Register) Used to control the operational mode of both ADCs. SFR Address Power-On Default Value Bit Addressable --- --- D1H 00H No ADC0EN ADC1EN --- MD2 MD1 MD0 Table IV. ADCMODE SFR Bit Designations Bit Name Description 7 6 5 ----ADC0EN 4 ADC1EN 3 2 1 0 --MD2 MD1 MD0 Reserved for Future Use. Reserved for Future Use. Primary ADC Enable. Set by the user to enable the Primary ADC and place it in the mode selected in MD2-MD0 below Cleared by the user to place the Primary ADC in power-down mode. Auxiliary ADC Enable. Set by the user to enable the Auxiliary ADC and place it in the mode selected in MD2-MD0 below Cleared by the user to place the Auxiliary ADC in power-down mode. Reserved for Future Use. Primary and Auxiliary ADC Mode bits. These bits select the operational mode of the enabled ADC as follows: MD2 MD1 MD0 0 0 0 Power-Down Mode (Power-On Default) 0 0 1 Idle Mode In Idle Mode the ADC filter and modulator are held in a reset state although the modulator clocks are still provided. 0 1 0 Single Conversion Mode In Single Conversion Mode, a single conversion is performed on the enabled ADC. On completion of the conversion, the ADC data registers (ADC0H/M and/or ADC1H/L) are updated, the relevant flags in the ADCSTAT SFR are written, and power-down is re-entered with the MD2–MD0 accordingly being written to 000. 0 1 1 Continuous Conversion In continuous conversion mode the ADC data registers are regularly updated at the selected update rate (see SF register) 1 0 0 Internal Zero-Scale Calibration Internal short automatically connected to the enabled ADC(s) 1 0 1 Internal Full-Scale Calibration Internal or External VREF (as determined by XREF0 and XREF1 bits in ADC0/1CON) is automatically connected to the ADC input for this calibration. 1 1 0 System Zero-Scale Calibration User should connect system zero-scale input to the ADC input pins as selected by CH1/CH0 and ACH1/ACH0 bits in the ADC0/1CON register. 1 1 1 System Full-Scale Calibration User should connect system full-scale input to the ADC input pins as selected by CH1/CH0 and ACH1/ACH0 bits in the ADC0/1CON register. NOTES 1. Any change to the MD bits will immediately reset both ADCs. A write to the MD2–0 bits with no change is also treated as a reset. (See exception to this in Note 3 below.) 2. If ADC0CON is written when AD0EN = 1, or if AD0EN is changed from 0 to 1, then both ADCs are also immediately reset. In other words, the Primary ADC is given priority over the Auxiliary ADC and any change requested on the primary ADC is immediately responded to. 3. On the other hand, if ADC1CON is written or if ADC1EN is changed from 0 to 1, only the Auxiliary ADC is reset. For example, if the Primary ADC is continuously converting when the Auxiliary ADC change or enable occurs, the primary ADC continues undisturbed. Rather than allow the Auxiliary ADC to operate with a phase difference from the primary ADC, the Auxiliary ADC will fall into step with the outputs of the primary ADC. The result is that the first conversion time for the Auxiliary ADC will be delayed up to three outputs while the Auxiliary ADC update rate is synchronized to the Primary ADC. 4. Once ADCMODE has been written with a calibration mode, the RDY0/1 bits (ADCSTAT) are immediately reset and the calibration commences. On completion, the appropriate calibration registers are written, the relevant bits in ADCSTAT are written, and the MD2–0 bits are reset to 000 to indicate the ADC is back in power-down mode. 5. Any calibration request of the Auxiliary ADC while the temperature sensor is selected will fail to complete. Although the RDY1 bit will be set at the end of the calibration cycle, no update of the calibration SFRs will take place and the ERR1 bit will be set. 6. Calibrations are performed at maximum SF (see SF SFR) value guaranteeing optimum calibration operation. –26– REV. REV. 0 A ADuC816 ADC0CON (Primary ADC Control Register) Used to configure the Primary ADC for range, channel selection, external Ref enable, and unipolar or bipolar coding. SFR Address Power-On Default Value Bit Addressable --- XREF0 D2H 07H No CH1 CH0 UNI0 RN2 RN1 RN0 Table V. ADC0CON SFR Bit Designations Bit Name Description 7 6 --XREF0 5 4 CH1 CH0 3 UNI0 2 1 0 RN2 RN1 RN0 Reserved for Future Use. Primary ADC External Reference Select Bit. Set by user to enable the Primary ADC to use the external reference via REFIN(+)/REFIN(–). Cleared by user to enable the Primary ADC to use the internal bandgap reference (VREF = 1.25 V). Primary ADC Channel Selection Bits. Written by the user to select the differential input pairs used by the Primary ADC as follows: CH1 CH0 Positive Input Negative Input 0 0 AIN1 AIN2 0 1 AIN3 AIN4 1 0 AIN2 AIN2 (Internal Short) 1 1 AIN3 AIN2 Primary ADC Unipolar Bit. Set by user to enable unipolar coding, i.e., zero differential input will result in 000000 hex output. Cleared by user to enable bipolar coding, zero differential input will result in 800000 hex output. Primary ADC Range Bits. Written by the user to select the Primary ADC input range as follows: RN2 RN1 RN0 Selected Primary ADC Input Range (VREF = 2.5 V) 0 0 0 ± 20 mV 0 0 1 ± 40 mV 0 1 0 ± 80 mV 0 1 1 ± 160 mV 1 0 0 ± 320 mV 1 0 1 ± 640 mV 1 1 0 ± 1.28 V 1 1 1 ± 2.56 V REV. A REV. 0 –27– ADuC816 ADC1CON (Auxiliary ADC Control Register) Used to configure the Auxiliary ADC for channel selection, external Ref enable and unipolar or bipolar coding. It should be noted that the Auxiliary ADC only operates on a fixed input range of ± VREF. SFR Address Power-On Default Value Bit Addressable --- D3H 00H No XREF1 ACH1 ACH0 UNI1 --- --- --- Table VI. ADC1CON SFR Bit Designations Bit Name Description 7 6 --XREF1 5 4 ACH1 ACH0 3 UNI1 2 1 0 ------- Reserved for Future Use. Auxiliary ADC External Reference Bit. Set by user to enable the Auxiliary ADC to use the external reference via REFIN(+)/REFIN(–). Cleared by user to enable the Auxiliary ADC to use the internal bandgap reference. Auxiliary ADC Channel Selection Bits. Written by the user to select the single-ended input pins used to drive the Auxiliary ADC as follows: ACH1 ACH0 Positive Input Negative Input 0 0 AIN3 AGND 0 1 AIN4 AGND 1 0 Temp Sensor* AGND (Temp. Sensor routed to the ADC input) 1 1 AIN5 AGND Auxiliary ADC Unipolar Bit. Set by user to enable unipolar coding, i.e., zero input will result in 0000 hex output. Cleared by user to enable bipolar coding, zero input will result in 8000 hex output. Reserved for Future Use. Reserved for Future Use. Reserved for Future Use. *NOTES 1. When the temperature sensor is selected, user code must select internal reference via XREF1 bit above and clear the UNI1 bit (ADC1CON.3) to select bipolar coding. 2. The temperature sensor is factory calibrated to yield conversion results 8000H at 0 °C. 3. A +1°C change in temperature will result in a +1 LSB change in the ADC1H register ADC conversion result. SF (Sinc Filter Register) The number in this register sets the decimation factor and thus the output update rate for the Primary and Auxiliary ADCs. This SFR cannot be written by user software while either ADC is active. The update rate applies to both Primary and Auxiliary ADCs and is calculated as follows: f ADC = Where: fADC = fMOD = SF = 1 1 · · f MOD 3 8.SF ADC Output Update Rate Modulator Clock Frequency = 32.768 kHz Decimal Value of SF Register The allowable range for SF is 0Dhex to FFhex. Examples of SF values and corresponding conversion update rate (fADC) and conversion time (tADC) are shown in Table VII, the power-on default value for the SF register is 45 hex, resulting in a default ADC update rate of just under 20 Hz. Both ADC inputs are chopped to minimize offset errors, which means that the settling time for a single conversion or the time to a first conversion result in continuous conversion mode is 2 × tADC. As mentioned earlier, all calibration cycles will be carried out automatically with a maximum, i.e., FFhex, SF value to ensure optimum calibration performance. Once a calibration cycle has completed, the value in the SF register will be that programmed by user software. Table VII. SF SFR Bit Designations SF(dec) SF(hex) fADC(Hz) tADC(ms) 13 69 255 0D 45 FF 105.3 19.79 5.35 9.52 50.34 186.77 –28– REV. A0 REV. ADuC816 ICON (Current Sources Control Register) Used to control and configure the various excitation and burnout current source options available on-chip. SFR Address Power-On Default Value Bit Addressable --- BO D5H 00H No ADC1IC ADC0IC I2PIN I1PIN I2EN I1EN Table VIII. ICON SFR Bit Designations Bit Name Description 7 6 --BO 5 ADC1IC 4 ADC0IC 3 I2PIN* 2 I1PIN* 1 I2EN 0 I1EN Reserved for Future Use. Burnout Current Enable Bit. Set by user to enable both transducer burnout current sources in the primary ADC signal paths. Cleared by user to disable both transducer burnout current sources. Auxiliary ADC Current Correction Bit. Set by user to allow scaling of the Auxiliary ADC by an internal current source calibration word. Primary ADC Current Correction Bit. Set by user to allow scaling of the Primary ADC by an internal current source calibration word. Current Source-2 Pin Select Bit. Set by user to enable current source-2 (200 μA) to external Pin 3 (P1.2/DAC/IEXC1). Cleared by user to enable current source-2 (200 μA) to external Pin 4 (P1.3/AIN5/IEXC2). Current Source-1 Pin Select Bit. Set by user to enable current source-1 (200 μA) to external Pin 4 (P1.3/AIN5/IEXC2). Cleared by user to enable current source-1 (200 μA) to external Pin 3 (P1.2/DAC/IEXC1). Current Source-2 Enable Bit. Set by user to turn on excitation current source-2 (200 μA). Cleared by user to turn off excitation current source-2 (200 μA). Current Source-1 Enable Bit. Set by user to turn on excitation current source-1 (200 μA). Cleared by user to turn off excitation current source-1 (200 μA). *Both current sources can be enabled to the same external pin, yielding a 400 μA current source. ADC0H/ADC0M (Primary ADC Conversion Result Registers) These two 8-bit registers hold the 16-bit conversion result from the Primary ADC. SFR Address Power-On Default Value Bit Addressable ADC0H ADC0M 00H No High Data Byte Middle Data Byte Both Registers Both Registers DBH DAH ADC1H/ADC1L (Auxiliary ADC Conversion Result Registers) These two 8-bit registers hold the 16-bit conversion result from the Auxiliary ADC. SFR Address Power-On Default Value Bit Addressable REV. A REV. 0 ADC1H ADC1L 00H No High Data Byte Low Data Byte Both Registers Both Registers –29– DDH DCH ADuC816 OF0H/OF0M (Primary ADC Offset Calibration Registers 1) These two 8-bit registers hold the 16-bit offset calibration coefficient for the Primary ADC. These registers are configured at poweron with a factory default value of 8000Hex. However, these bytes will be automatically overwritten if an internal or system zero-scale calibration is initiated by the user via MD2–0 bits in the ADCMODE register. SFR Address Power-On Default Value Bit Addressable OF0H OF0M 8000H No Primary ADC Offset Coefficient High Byte Primary ADC Offset Coefficient Middle Byte OF0H and OF0M Respectively Both Registers E3H E2H OF1H/OF1L (Auxiliary ADC Offset Calibration Registers 1) These two 8-bit registers hold the 16-bit offset calibration coefficient for the Auxiliary ADC. These registers are configured at power-on with a factory default value of 8000Hex. However, these bytes will be automatically overwritten if an internal or system zero-scale calibration is initiated by the user via the MD2–0 bits in the ADCMODE register. SFR Address Power-On Default Value Bit Addressable OF1H OF1L 8000H No Auxiliary ADC Offset Coefficient High Byte Auxiliary ADC Offset Coefficient Low Byte OF1H and OF1L Respectively Both Registers E5H E4H GN0H/GN0M (Primary ADC Gain Calibration Registers 1) These two 8-bit registers hold the 16-bit gain calibration coefficient for the Primary ADC. These registers are configured at power-on with a factory-calculated internal full-scale calibration coefficient. Every device will have an individual coefficient. However, these bytes will be automatically overwritten if an internal or system full-scale calibration is initiated by the user via MD2–0 bits in the ADCMODE register. SFR Address Power-On Default Value Bit Addressable GN0H GN0M No Primary ADC Gain Coefficient High Byte Primary ADC Gain Coefficient Middle Byte Configured at factory final test, see notes above. Both Registers EBH EAH GN1H/GN1L (Auxiliary ADC Gain Calibration Registers 1) These two 8-bit registers hold the 16-bit gain calibration coefficient for the Auxiliary ADC. These registers are configured at poweron with a factory calculated internal full-scale calibration coefficient. Every device will have an individual coefficient. However, these bytes will be automatically overwritten if an internal or system full-scale calibration is initiated by the user via MD2–0 bits in the ADCMODE register. SFR Address Power-On Default Value Bit Addressable GN1H GN1L No Auxiliary ADC Gain Coefficient High Byte Auxiliary ADC Gain Coefficient Low Byte Configured at factory final test, see notes above. Both Registers EDH ECH NOTE 1 These registers can be overwritten by user software only if Mode bits MD0–2 (ADCMODE SFR) are zero. –30– REV. 0 REV. A ADuC816 PRIMARY AND AUXILIARY ADC CIRCUIT DESCRIPTION OVERVIEW the analog inputs if required. On-chip burnout currents can also be turned on. These currents can be used to check that a transducer on the selected channel is still operational before attempting to take measurements. The ADuC816 incorporates two independent sigma-delta ADCs (Primary and Auxiliary) with on-chip digital filtering intended for the measurement of wide dynamic range, low frequency signals such as those in weigh-scale, strain-gauge, pressure transducer or temperature measurement applications. Primary ADC This ADC is intended to convert the primary sensor input. The input is buffered and can be programmed for one of 8 input ranges from ± 20 mV to ± 2.56 V being driven from one of three differential input channel options AIN1/2, AIN3/4, or AIN3/2. The input channel is internally buffered allowing the part to handle significant source impedances on the analog input, allowing R/C filtering (for noise rejection or RFI reduction) to be placed on PROGRAMMABLE GAIN AMPLIFIER ANALOG INPUT CHOPPING BURNOUT CURRENTS TWO 100nA BURNOUT CURRENTS ALLOW THE USER TO EASILY DETECT IF A TRANSDUCER HAS BURNED OUT OR GONE OPEN-CIRCUIT THE INPUTS ARE ALTERNATELY REVERSED THROUGH THE CONVERSION CYCLE. CHOPPING YIELDS EXCELLENT ADC OFFSET AND OFFSET DRIFT PERFORMANCE THE PROGRAMMABLE GAIN AMPLIFIER ALLOWS EIGHT UNIPOLAR AND EIGHT BIPOLAR INPUT RANGES FROM 20mV TO 2.56V (EXT VREF = +2.5V) SEE PAGE 34 The ADC employs a sigma-delta conversion technique to realize up to 16 bits of no missing codes performance. The sigma-delta modulator converts the sampled input signal into a digital pulse train whose duty cycle contains the digital information. A Sinc3 programmable low-pass filter is then employed to decimate the modulator output data stream to give a valid data conversion result at programmable output rates from 5.35 Hz (186.77 ms) to 105.03 Hz (9.52 ms). A Chopping scheme is also employed to minimize ADC offset errors. A block diagram of the Primary ADC is shown in Figure 18. DIFFERENTIAL REFERENCE THE EXTERNAL REFERENCE INPUT TO THE ADuC816 IS DIFFERENTIAL AND FACILITATES RATIOMETRIC OPERATION. THE EXTERNAL REFERENCE VOLTAGE IS SELECTED VIA THE XREF0 BIT IN ADC0CON. REFERENCE DETECT CIRCUITRY TESTS FOR OPEN OR SHORTED REFERENCES INPUTS SEE PAGE 36 SIGMA-DELTA ADC OUTPUT AVERAGE THE SIGMA-DELTA ARCHITECTURE ENSURES 16 BITS NO MISSING CODES. THE ENTIRE SIGMA-DELTA ADC IS CHOPPED TO REMOVE DRIFT ERROR AS PART OF THE CHOPPING IMPLEMENTATION, EACH DATA WORD OUTPUT FROM THE FILTER IS SUMMED AND AVERAGED WITH ITS PREDECESSOR TO NULL ADC CHANNEL OFFSET ERRORS SEE PAGE 35 SEE PAGE 35 SEE PAGE 36 SEE PAGE 29 AND 34 REFIN(–) REFIN(+) AVDD SIGMA-DELTA A/D CONVERTER AIN1 BUFFER AIN2 MUX PGA SIGMADELTA MODULATOR PROGRAMMABLE DIGITAL FILTER OUTPUT AVERAGE OUTPUT SCALING DIGTAL OUTPUT RESULT WRITTEN TO ADC0H/M SFRs AIN3 CHOP AIN4 CHOP AGND OUTPUT SCALING ANALOG MULTIPLEXER A DIFFERENTIAL MULTIPLEXER ALLOWS SELECTION OF THREE FULLY DIFFERENTIAL PAIR OPTIONS AND ADDITIONAL INTERNAL SHORT OPTION (AIN2–AIN2).THE MULTIPLEXER IS CONTROLLED VIA THE CHANNEL SELECTION BITS IN ADC0CON SEE PAGES 27 AND 33 BUFFER AMPLIFIER THE BUFFER AMPLIFIER PRESENTS A HIGH IMPEDANCE INPUT STAGE FOR THE ANALOG INPUTS, ALLOWING SIGNIFICANT EXTERNAL SOURCE IMPEDANCES SEE PAGE 33 PROGRAMMABLE DIGITAL FILTER SIGMA-DELTA MODULATOR THE MODULATOR PROVIDES A HIGH-FREQUENCY 1-BIT DATA STREAM (THE OUTPUT OF WHICH IS ALSO CHOPPED) TO THE DIGITAL FILTER, THE DUTY CYCLE OF WHICH REPRESENTS THE SAMPLED ANALOG INPUT VOLTAGE THE SINC3 FILTER REMOVES QUANTIZATION NOISE INTRODUCED BY THE MODULATOR. THE UPDATE RATE AND BANDWIDTH OF THIS FILTER ARE PROGRAMMABLE VIA THE SF SFR SEE PAGE 35 Figure 18. Primary ADC Block Diagram REV. 0 REV. A –31– SEE PAGE 35 THE OUPUT WORD FROM THE DIGITAL FILTER IS SCALED BY THE CALIBRATION COEFFICIENTS BEFORE BEING PROVIDED AS THE CONVERSION RESULT SEE PAGE 37 ADuC816 Auxiliary ADC The Auxiliary ADC is intended to convert supplementary inputs such as those from a cold junction diode or thermistor. This ADC is not buffered and has a fixed input range of 0 V to 2.5 V (assuming an external 2.5 V reference). The single-ended inputs can be driven from AIN3, AIN4 or AIN5 pins or directly from the on-chip temperature sensor voltage. A block diagram of the Auxiliary ADC is shown in Figure 19. DIFFERENTIAL REFERENCE ANALOG INPUT CHOPPING THE INPUTS ARE ALTERNATELY REVERSED THROUGH THE CONVERSION CYCLE. CHOPPING YIELDS EXCELLENT ADC OFFSET AND OFFSET DRIFT PERFORMANCE THE EXTERNAL REFERENCE INPUT TO THE ADuC816 IS DIFFERENTIAL AND FACILITATES RATIOMETRIC OPERATION. THE EXTERNAL REFERENCE VOLTAGE IS SELECTED VIA THE XREF1 BIT IN ADC1CON. REFERENCE DETECT CIRCUITRY TESTS FOR OPEN OR SHORTED REFERENcES INPUTS SIGMA-DELTA ADC OUTPUT AVERAGE THE SIGMA-DELTA ARCHITECTURE ENSURES 16 BITS NO MISSING CODES. THE ENTIRE SIGMA-DELTA ADC IS CHOPPED TO REMOVE DRIFT ERRORS SEE PAGE 35 AS PART OF THE CHOPPING IMPLEMENTATION EACH DATA WORD OUTPUT FROM THE FILTER IS SUMMED AND AVERAGED WITH ITS PREDECESSOR TO NULL ADC CHANNEL OFFSET ERRORS SEE PAGE 35 SEE PAGE 36 SEE PAGE 36 REFIN(–) REFIN(+) SIGMA-DELTA A/D CONVERTER AIN3 AIN4 AIN5 ON-CHIP TEMPERATURE SENSOR SIGMADELTA MODULATOR MU MUX PROGRAMMABLE DIGITAL FILTER OUTPUT AVERAGE OUTPUT SCALING DIGTAL OUTPUT RESULT WRITTEN TO ADC1H/L SFRs X CHOP CHOP OUTPUT SCALING ANALOG MULTIPLEXER A DIFFERENTIAL MULTIPLEXER ALLOWS SELECTION OF THREE EXTERNAL SINGLE ENDED INPUTS OR THE ON-CHIP TEMP. SENSOR. THE MULTIPLEXER IS CONTROLLED VIA THE CHANNEL SELECTION BITS IN ADC1CON SEE PAGE 28 AND 33 PROGRAMMABLE DIGITAL FILTER SIGMA-DELTA MODULATOR THE MODULATOR PROVIDES A HIGH FREQUENCY 1-BIT DATA STREAM (THE OUTPUT OF WHICH IS ALSO CHOPPED) TO THE DIGITAL FILTER, THE DUTY CYCLE OF WHICH REPRESENTS THE SAMPLED ANALOG INPUT VOLTAGE THE SINC3 FILTER REMOVES QUANTIZATION NOISE INTRODUCED BY THE MODULATOR. THE UPDATE RATE AND BANDWIDTH OF THIS FILTER ARE PROGRAMMABLE VIA THE SF SFR THE OUPUT WORD FROM THE DIGITAL FILTER IS SCALED BY THE CALIBRATION COEFFICIENTS BEFORE BEING PROVIDED AS THE CONVERSION RESULT SEE PAGE 37 SEE PAGE 35 SEE PAGE 35 Figure 19. Auxiliary ADC Block Diagram –32– REV. REV. A 0 ADuC816 are generated at a differential input voltage of 0 V. The output update rate is selected via the SF7–SF0 bits in the Sinc Filter (SF) SFR. It is important to note that the peak-to-peak resolution figures represent the resolution for which there will be no code flicker within a six-sigma limit. PRIMARY AND AUXILIARY ADC NOISE PERFORMANCE Tables IX, X and XI below show the output rms noise in μV and output peak-to-peak resolution in bits (rounded to the nearest 0.5 LSB) for some typical output update rates on both the Primary and Auxiliary ADCs. The numbers are typical and Table IX. Primary ADC, Typical Output RMS Noise (V) Typical Output RMS Noise vs. Input Range and Update Rate; Output RMS Noise in V SF Word Data Update Rate (Hz) 20 mV 40 mV 80 mV Input Range 160 mV 320 mV 640 mV 1.28 V 2.56 V 13 69 255 105.3 19.79 5.35 1.50 0.60 0.35 1.50 0.65 0.35 1.60 0.65 0.37 1.75 0.65 0.37 3.50 0.65 0.37 4.50 0.95 0.51 6.70 1.40 0.82 11.75 2.30 1.25 Table X. Primary ADC, Peak-to-Peak Resolution (Bits) Peak-to-Peak Resolution vs. Input Range and Update Rate; Peak-to-Peak Resolution in Bits SF Word Data Update Rate (Hz) 20 mV 40 mV 80 mV Input Range 160 mV 320 mV 640 mV 1.28 V 2.56 V 13 69 255 105.3 19.79 5.35 12 13 14 13 14 15 14 15 16 15 16 161 15 161 161 15.5 161 161 16 161 161 16 161 161 NOTE 1 Peak-to-peak resolution at these range/update rate settings is limited only by the number of bits available from the ADC. Effective resolution at these range/update rate settings is greater than 16 bits as indicated by the rms noise table shown in Table IX. Table XI. Auxiliary ADC Typical Output RMS Noise vs. Update Rate 1 Output RMS Noise in V Peak-to-Peak Resolution vs. Update Rate 1 Peak-to-Peak Resolution in Bits SF Word Data Update Rate (Hz) Input Range 2.5 V SF Word Data Update Rate (Hz) Input Range 2.5 V 13 69 255 105.3 19.79 5.35 10.75 2.00 1.15 13 69 255 105.3 19.79 5.35 162 16 16 NOTE 1 ADC converting in bipolar mode. NOTES 1 ADC converting in bipolar mode. 2 In unipolar mode peak-to-peak resolution at 105 Hz is 15 bits. Analog Input Channels Primary and Auxiliary ADC Inputs The primary ADC has four associated analog input pins (labelled AIN1 to AIN4) which can be configured as two fully differential input channels. Channel selection bits in the ADC0CON SFR detailed in Table V allow three combinations of differential pair selection as well as an additional shorted input option (AIN2–AIN2). The output of the primary ADC multiplexer feeds into a high impedance input stage of the buffer amplifier. As a result, the primary ADC inputs can handle significant source impedances and are tailored for direct connection to external resistive-type sensors like strain gauges or Resistance Temperature Detectors (RTDs). The auxiliary ADC has three external input pins (labelled AIN3 to AIN5) as well as an internal connection to the internal on-chip temperature sensor. All inputs to the auxiliary ADC are singleended inputs referenced to the AGND on the part. Channel selection bits in the ADC1CON SFR detailed previously in Table VI allow selection of one of four inputs. The auxiliary ADC, however, is unbuffered resulting in higher analog input current on the auxiliary ADC. It should be noted that this unbuffered input path provides a dynamic load to the driving source. Therefore, resistor/capacitor combinations on the input pins can cause dc gain errors depending on the output impedance of the source that is driving the ADC inputs. Two input multiplexers switch the selected input channel to the on-chip buffer amplifier in the case of the primary ADC and directly to the sigma-delta modulator input in the case of the auxiliary ADC. When the analog input channel is switched, the settling time of the part must elapse before a new valid word is available from the ADC. Analog Input Ranges REV. A REV. 0 The absolute input voltage range on the primary ADC is restricted to between AGND + 100 mV to AVDD – 100 mV. Care must be taken in setting up the common-mode voltage and input voltage range so that these limits are not exceeded, otherwise there will be a degradation in linearity performance. –33– ADuC816 The absolute input voltage range on the auxiliary ADC is restricted to between AGND – 30 mV to AVDD + 30 mV. The slightly negative absolute input voltage limit does allow the possibility of monitoring small signal bipolar signals using the single-ended auxiliary ADC front end. Programmable Gain Amplifier The output from the buffer on the primary ADC is applied to the input of the on-chip programmable gain amplifier (PGA). The PGA can be programmed through eight different unipolar input ranges and bipolar ranges. The PGA gain range is programmed via the range bits in the ADC0CON SFR. With the external reference select bit set in the ADC0CON SFR and an external 2.5 V reference, the unipolar ranges are 0 mV to +20 mV, 0 mV to 40 mV, 0 mV to 80 mV, 0 mV to 160 mV, 0 mV to 320 mV, 0 mV to 640 mV and 0 V to 1.28 V and 0 to 2.56 V while the bipolar ranges are ± 20 mV, ± 40 mV, ± 80 mV, ± 160 mV, ±320 mV, ±640 mV, ±1.28 V and ±2.56 V. These are the nominal ranges that should appear at the input to the on-chip PGA. An ADC range matching specification of 0.5 LSB (typ) across all ranges means that calibration need only be carried out at a single gain range and does not have to be repeated when the PGA gain range is changed. The auxiliary ADC does not incorporate a PGA and is configured for a fixed single input range of 0 to VREF. Bipolar/Unipolar Inputs The analog inputs on the ADuC816 can accept either unipolar or bipolar input voltage ranges. Bipolar input ranges do not imply that the part can handle negative voltages with respect to system AGND. Burnout Currents The primary ADC on the ADuC816 contains two 100 nA constant current generators, one sourcing current from AVDD to AIN(+), and one sinking from AIN(–) to AGND. The currents are switched to the selected analog input pair. Both currents are either on or off, depending on the Burnout Current Enable (BO) bit in the ICON SFR (see Table VIII). These currents can be used to verify that an external transducer is still operational before attempting to take measurements on that channel. Once the burnout currents are turned on, they will flow in the external transducer circuit, and a measurement of the input voltage on the analog input channel can be taken. If the resultant voltage measured is full-scale, this indicates that the transducer has gone open-circuit. If the voltage measured is 0 V, it indicates that the transducer has short circuited. For normal operation, these burnout currents are turned off by writing a 0 to the BO bit in the ICON SFR. The current sources work over the normal absolute input voltage range specifications. Excitation Currents The ADuC816 also contains two identical, 200 μA constant current sources. Both source current from AVDD to Pin 3 (IEXC1) or Pin 4 (IEXC2) These current sources are controlled via bits in the ICON SFR shown in Table VIII. They can be configured to source 200 μA individually to both pins or a combination of both currents, i.e., 400 μA to either of the selected pins. These current sources can be used to excite external resistive bridge or RTD sensors. Reference Input Unipolar and bipolar signals on the AIN(+) input on the primary ADC are referenced to the voltage on the respective AIN(–) input. For example, if AIN(–) is 2.5 V and the primary ADC is configured for an analog input range of 0 mV to +20 mV, the input voltage range on the AIN(+) input is 2.5 V to 2.52 V. If AIN(–) is 2.5 V and the ADuC816 is configured for an analog input range of 1.28 V, the analog input range on the AIN(+) input is 1.22 V to 3.78 V (i.e., 2.5 V ± 1.28 V). As mentioned earlier, the auxiliary ADC input is a single-ended input with respect to the system AGND. In this context a bipolar signal on the auxiliary ADC can only span 30 mV negative with respect to AGND before violating the voltage input limits for this ADC. Bipolar or unipolar options are chosen by programming the Primary and Auxiliary Unipolar enable bits in the ADC0CON and ADC1CON SFRs respectively. This programs the relevant ADC for either unipolar or bipolar operation. Programming for either unipolar or bipolar operation does not change any of the input signal conditioning; it simply changes the data output coding and the points on the transfer function where calibrations occur. When an ADC is configured for unipolar operation, the output coding is natural (straight) binary with a zero differential input voltage resulting in a code of 000 . . . 000, a midscale voltage resulting in a code of 100 . . . 000, and a full-scale input voltage resulting in a code of 111 . . . 111. When an ADC is configured for bipolar operation, the coding is offset binary with a negative full-scale voltage resulting in a code of 000 . . . 000, a zero differential voltage resulting in a code of 100 . . . 000, and a positive full-scale voltage resulting in a code of 111 . . . 111. The ADuC816’s reference inputs, REFIN(+) and REFIN(–), provide a differential reference input capability. The commonmode range for these differential inputs is from AGND to AVDD. The nominal reference voltage, VREF (REFIN(+) – REFIN(–)), for specified operation is 2.5 V with the primary and auxiliary reference enable bits set in the respective ADC0CON and/or ADC1CON SFRs. The part is also functional (although not specified for performance) when the XREF0 or XREF1 bits are “0,” which enables the on-chip internal bandgap reference. In this mode, the ADCs will see the internal reference of 1.25 V, therefore halving all input ranges. As a result of using the internal reference voltage, a noticeable degradation in peak-to-peak resolution will result. Therefore, for best performance, operation with an external reference is strongly recommended. In applications where the excitation (voltage or current) for the transducer on the analog input also drives the reference voltage for the part, the effect of the low-frequency noise in the excitation source will be removed as the application is ratiometric. If the ADuC816 is not used in a ratiometric application, a low noise reference should be used. Recommended reference voltage sources for the ADuC816 include the AD780, REF43, and REF192. It should also be noted that the reference inputs provide a high impedance, dynamic load. Because the input impedance of each reference input is dynamic, resistor/capacitor combinations on these inputs can cause dc gain errors depending on the output impedance of the source that is driving the reference inputs. Reference voltage sources, like those recommended above (e.g., AD780) will typically have low output impedances and therefore decoupling capacitors on the REFIN(+) input would be recom- –34– REV. A 0 REV. ADuC816 mended. Deriving the reference input voltage across an external resistor, as shown in Figure 52, will mean that the reference input sees a significant external source impedance. External decoupling on the REFIN(+) and REFIN(–) pins would not be recommended in this type of circuit configuration. Reference Detect The ADuC816 includes on-chip circuitry to detect if the part has a valid reference for conversions or calibrations. If the voltage between the external REFIN(+) and REFIN(–) pins goes below 0.3 V or either the REFIN(+) or REFIN(–) inputs is open circuit, the ADuC816 detects that it no longer has a valid reference. In this case, the NOXREF bit of the ADCSTAT SFR is set to a 1. If the ADuC816 is performing normal conversions and the NOXREF bit becomes active, the conversion results revert to all 1s. Therefore, it is not necessary to continuously monitor the status of the NOXREF bit when performing conversions. It is only necessary to verify its status if the conversion result read from the ADC Data Register is all 1s. If the ADuC816 is performing either an offset or gain calibration and the NOXREF bit becomes active, the updating of the respective calibration registers is inhibited to avoid loading incorrect coefficients to these registers, and the appropriate ERR0 or ERR1 bits in the ADCSTAT SFR are set. If the user is concerned about verifying that a valid reference is in place every time a calibration is performed, the status of the ERR0 or ERR1 bit should be checked at the end of the calibration cycle. frequency. In this manner, the 1-bit output of the comparator is translated into a band-limited, low noise output from the ADuC816 ADCs. The ADuC816 filter is a low-pass, Sinc3 or (sinx/x)3 filter whose primary function is to remove the quantization noise introduced at the modulator. The cutoff frequency and decimated output data rate of the filter are programmable via the SF (Sinc Filter) SFR as described in Table VII. Figure 21 shows the frequency response of the ADC channel at the default SF word of 69 dec or 45 hex, yielding an overall output update rate of just under 20 Hz. It should be noted that this frequency response allows frequency components higher than the ADC Nyquist frequency to pass through the ADC, in some cases without significant attenuation. These components may, therefore, be aliased and appear in-band after the sampling process. It should also be noted that rejection of mains-related frequency components, i.e., 50 Hz and 60 Hz, is seen to be at level of >65 dB at 50 Hz and >100 dB at 60 Hz. This confirms the data sheet specifications for 50 Hz/60 Hz Normal Mode Rejection (NMR) at a 20 Hz update rate. 0 –10 –20 –30 Sigma-Delta Modulator –40 GAIN – dB A sigma-delta ADC generally consists of two main blocks, an analog modulator and a digital filter. In the case of the ADuC816 ADCs, the analog modulators consist of a difference amplifier, an integrator block, a comparator, and a feedback DAC as illustrated in Figure 20. –50 –60 –70 –80 –90 ANALOG INPUT DIFFERENCE AMP COMPARATOR INTEGRATOR –100 HIGHFREQUENCY BITSTREAM TO DIGITAL FILTER –110 –120 DAC In operation, the analog signal sample is fed to the difference amplifier along with the output of the feedback DAC. The difference between these two signals is integrated and fed to the comparator. The output of the comparator provides the input to the feedback DAC so the system functions as a negative feedback loop that tries to minimize the difference signal. The digital data that represents the analog input voltage is contained in the duty cycle of the pulse train appearing at the output of the comparator. This duty cycle data can be recovered as a data word using a subsequent digital filter stage. The sampling frequency of the modulator loop is many times higher than the bandwidth of the input signal. The integrator in the modulator shapes the quantization noise (which results from the analog-to-digital conversion) so that the noise is pushed toward one-half of the modulator frequency. 20 30 50 70 40 60 FREQUENCY – Hz 80 90 100 110 The response of the filter, however, will change with SF word as can be seen in Figure 22, which shows >90 dB NMR at 50 Hz and >70 dB NMR at 60 Hz when SF = 255 dec. 0 –10 –20 –30 –40 –50 –60 –70 –80 –90 –100 –110 –120 0 Digital Filter The output of the sigma-delta modulator feeds directly into the digital filter. The digital filter then band-limits the response to a frequency significantly lower than one-half of the modulator REV. A REV. 0 10 Figure 21. Filter Response, SF = 69 dec GAIN – dB Figure 20. Sigma-Delta Modulator Simplified Block Diagram 0 10 20 30 50 40 60 FREQUENCY – Hz 70 80 90 Figure 22. Filter Response, SF = 255 dec –35– 100 ADuC816 Figures 23 and 24 show the NMR for 50 Hz and 60 Hz across the full range of SF word, i.e., SF = 13 dec to SF = 255 dec. 0 –10 –20 –30 GAIN – dB –40 –50 –60 –70 –80 –90 –100 –110 –120 10 30 50 70 90 110 130 150 170 190 210 230 250 SF – Decimal Figure 23. 50 Hz Normal Mode Rejection vs. SF 0 –10 –20 –30 GAIN – dB –40 –50 –60 –70 –80 –90 –100 –110 –120 10 30 50 70 90 110 130 150 170 190 210 230 250 SF – Decimal Figure 24. 60 Hz Normal Mode Rejection vs. SF ADC Chopping Both ADCs on the ADuC816 implement a chopping scheme whereby the ADC repeatability reverses its inputs. The decimated digital output words from the Sinc3 filters therefore have a positive offset and negative offset term included. As a result, a final summing stage is included in each ADC so that each output word from the filter is summed and averaged with the previous filter output to produce a new valid output result to be written to the ADC data SFRs. In this way, while the ADC throughput or update rate is as discussed earlier and illustrated in Table VII, the full settling time through the ADC (or the time to a first conversion result), will actually be given by 2 × tADC. The chopping scheme incorporated in the ADuC816 ADC results in excellent dc offset and offset drift specifications and is extremely beneficial in applications where drift, noise rejection, and optimum EMI rejection are important factors. Calibration The ADuC816 provides four calibration modes that can be programmed via the mode bits in the ADCMODE SFR detailed in Table IV. In fact, every ADuC816 has already been factory calibrated. The resultant Offset and Gain calibration coefficients for both the primary and auxiliary ADCs are stored on-chip in manufacturing-specific Flash/EE memory locations. At poweron, these factory calibration coefficients are automatically downloaded to the calibration registers in the ADuC816 SFR space. Each ADC (primary and auxiliary) has dedicated calibration SFRs, these have been described earlier as part of the general ADC SFR description. However, the factory calibration values in the ADC calibration SFRs will be overwritten if any one of the four calibration options are initiated and that ADC is enabled via the ADC enable bits in ADCMODE. Even though an internal offset calibration mode is described below, it should be recognized that both ADCs are chopped. This chopping scheme inherently minimizes offset and means that an internal offset calibration should never be required. Also, because factory 5 V/25°C gain calibration coefficients are automatically present at power-on, an internal full-scale calibration will only be required if the part is being operated at 3 V or at temperatures significantly different from 25°C. The ADuC816 offers “internal” or “system” calibration facilities. For full calibration to occur on the selected ADC, the calibration logic must record the modulator output for two different input conditions. These are “zero-scale” and “full-scale” points. These points are derived by performing a conversion on the different input voltages provided to the input of the modulator during calibration. The result of the “zero-scale” calibration conversion is stored in the Offset Calibration Registers for the appropriate ADC. The result of the “full-scale” calibration conversion is stored in the Gain Calibration Registers for the appropriate ADC. With these readings, the calibration logic can calculate the offset and the gain slope for the input-to-output transfer function of the converter. During an “internal” zero-scale or full-scale calibration, the respective “zero” input and “full-scale” input are automatically connected to the ADC input pins internally to the device. A “system” calibration, however, expects the system zero-scale and system full-scale voltages to be applied to the external ADC pins before the calibration mode is initiated. In this way external ADC errors are taken into account and minimized as a result of system calibration. It should also be noted that to optimize calibration accuracy, all ADuC816 ADC calibrations are carried out automatically at the slowest update rate. Internally in the ADuC816, the coefficients are normalized before being used to scale the words coming out of the digital filter. The offset calibration coefficient is subtracted from the result prior to the multiplication by the gain coefficient. All ADuC816 ADC specifications will only apply after a zero-scale and full-scale calibration at the operating point (supply voltage/temperature) of interest. From an operational point of view, a calibration should be treated like another ADC conversion. A zero-scale calibration (if required) should always be carried out before a full-scale calibration. System software should monitor the relevant ADC RDY0/1 bit in the ADCSTAT SFR to determine end of calibration via a polling sequence or interrupt driven routine. –36– REV. 0 A REV. ADuC816 NONVOLATILE FLASH/EE MEMORY Flash/EE Memory Overview The ADuC816 incorporates Flash/EE memory technology on-chip to provide the user with nonvolatile, in-circuit reprogrammable, code and data memory space. Flash/EE memory is a relatively recent type of nonvolatile memory technology and is based on a single transistor cell architecture. This technology is basically an outgrowth of EPROM technology and was developed through the late 1980s. Flash/EE memory takes the flexible in-circuit reprogrammable features of EEPROM and combines them with the space efficient/density features of EPROM (see Figure 25). Because Flash/EE technology is based on a single transistor cell architecture, a Flash memory array, like EPROM, can be implemented to achieve the space efficiencies or memory densities required by a given design. Like EEPROM, Flash memory can be programmed in-system at a byte level, although it must first be erased; the erase being performed in page blocks. Thus, Flash memory is often and more correctly referred to as Flash/EE memory. EPROM TECHNOLOGY EEPROM TECHNOLOGY SPACE EFFICIENT/ DENSITY IN-CIRCUIT REPROGRAMMABLE FLASH/EE MEMORY TECHNOLOGY Figure 25. Flash/EE Memory Development Overall, Flash/EE memory represents a step closer to the ideal memory device that includes nonvolatility, in-circuit programmability, high density and low cost. Incorporated in the ADuC816, Flash/EE memory technology allows the user to update program code space in-circuit, without the need to replace one-time programmable (OTP) devices at remote operating nodes. ADuC816 Flash/EE Memory Reliability The Flash/EE Program and Data Memory arrays on the ADuC816 are fully qualified for two key Flash/EE memory characteristics, namely Flash/EE Memory Cycling Endurance and Flash/EE Memory Data Retention. Endurance quantifies the ability of the Flash/EE memory to be cycled through many Program, Read, and Erase cycles. In real terms, a single endurance cycle is composed of four independent, sequential events. These events are defined as: a. initial page erase sequence b. read/verify sequence c. byte program sequence d. second read/verify sequence A single Flash/EE Memory Endurance Cycle In reliability qualification, every byte in both the program and data Flash/EE memory is cycled from 00 hex to FFhex until a first fail is recorded signifying the endurance limit of the on-chip Flash/EE memory. As indicated in the specification pages of this data sheet, the ADuC816 Flash/EE Memory Endurance qualification has been carried out in accordance with JEDEC Specification A117 over the industrial temperature range of –40°C, +25°C, and +85°C. The results allow the specification of a minimum endurance figure over supply and temperature of 100,000 cycles, with an endurance figure of 700,000 cycles being typical of operation at 25°C. Retention quantifies the ability of the Flash/EE memory to retain its programmed data over time. Again, the ADuC816 has been qualified in accordance with the formal JEDEC Retention Lifetime Specification (A117) at a specific junction temperature (TJ = 55°C). As part of this qualification procedure, the Flash/EE memory is cycled to its specified endurance limit described above, before data retention is characterized. This means that the Flash/ EE memory is guaranteed to retain its data for its full specified retention lifetime every time the Flash/EE memory is reprogrammed. It should also be noted that retention lifetime, based on an activation energy of 0.6 eV, will derate with TJ as shown in Figure 26. Flash/EE Memory and the ADuC816 The ADuC816 provides two arrays of Flash/EE memory for user applications. 8K bytes of Flash/EE Program space are provided on-chip to facilitate code execution without any external discrete ROM device requirements. The program memory can be programmed using conventional third party memory programmers. This array can also be programmed in-circuit, using the serial download mode provided. 300 RETENTION – Years 250 A 640-Byte Flash/EE Data Memory space is also provided on-chip. This may be used as a general-purpose nonvolatile scratchpad area. User access to this area is via a group of six SFRs. This space can be programmed at a byte level, although it must first be erased in 4-byte pages. 200 ADI SPECIFICATION 100 YEARS MIN. AT TJ = 55C 150 100 50 0 40 50 60 70 90 80 TJ JUNCTION TEMPERATURE – C 100 110 Figure 26. Flash/EE Memory Data Retention REV. A REV. 0 –37– ADuC816 Using the Flash/EE Program Memory 5V The 8 Kbyte Flash/EE Program Memory array is mapped into the lower 8 Kbytes of the 64 Kbytes program space addressable by the ADuC816, and is used to hold user code in typical applications. VDD P0 GND PROGRAM DATA (D0–D7) ADuC816 PROGRAM MODE (SEE TABLE XII) The program memory Flash/EE memory arrays can be programmed in one of two modes, namely: COMMAND ENABLE P3.0 NEGATIVE EDGE Serial Downloading (In-Circuit Programming) As part of its factory boot code, the ADuC816 facilitates serial code download via the standard UART serial port. Serial download mode is automatically entered on power-up if the external pin, PSEN, is pulled low through an external resistor as shown in Figure 27. Once in this mode, the user can download code to the program memory array while the device is sited in its target application hardware. A PC serial download executable is provided as part of the ADuC816 QuickStart development system. The Serial Download protocol is detailed in a MicroConverter Applications Note uC004 available from the ADI MicroConverter Website at www.analog.com/microconverter. ENTRY SEQUENCE P1 P3 P2 P3.6 ALE PSEN GND PROGRAM ADDRESS (A0–A13) (P2.0 = A0) (P1.7 = A13) WRITE ENABLE STROBE RESET VDD Figure 28. Flash/EE Memory Parallel Programming Table XII. Flash/EE Memory Parallel Programming Modes 0.7 0.6 Port 3 Pins 0.5 0.4 0.3 0.2 0.1 X X X X 0 0 0 X X X X 0 0 1 X X X X X X X X X X X X X X X 1 0 1 0 X 0 0 0 0 1 1 1 1 1 0 0 0 1 1 0 X X X X 1 0 1 All Other Codes Programming Mode Erase Flash/EE Program, Data, and Security Modes Read Device Signature/ID Program Code Byte Program Data Byte Read Code Byte Read Data Byte Program Security Modes Read/Verify Security Modes Redundant Flash/EE Program Memory Security PULL PSEN LOW DURING RESET TO CONFIGURE THE ADuC816 FOR SERIAL DOWNLOAD MODE ADuC816 PSEN 1k The ADuC816 facilitates three modes of Flash/EE program memory security. These modes can be independently activated, restricting access to the internal code space. These security modes can be enabled as part of the user interface available on all ADuC816 serial or parallel programming tools referenced on the MicroConverter web page at www.analog.com/microconverter. The security modes available on the ADuC816 are described as follows: Lock Mode Figure 27. Flash/EE Memory Serial Download Mode Programming Parallel Programming The parallel programming mode is fully compatible with conventional third party Flash or EEPROM device programmers. A block diagram of the external pin configuration required to support parallel programming is shown in Figure 28. In this mode, Ports 0, 1, and 2 operate as the external data and address bus interface, ALE operates as the Write Enable strobe, and Port 3 is used as a general configuration port that configures the device for various program and erase operations during parallel programming. The high voltage (12 V) supply required for Flash/EE programming is generated using on-chip charge pumps to supply the high voltage program lines. This mode locks code in memory, disabling parallel programming of the program memory although reading the memory in parallel mode is still allowed. This mode is deactivated by initiating a “code-erase” command in serial download or parallel programming modes. Secure Mode This mode locks code in memory, disabling parallel programming (program and verify/read commands) as well as disabling the execution of a “MOVC” instruction from external memory, which is attempting to read the op codes from internal memory. This mode is deactivated by initiating a “code-erase” command in serial download or parallel programming modes. –38– REV. A REV. 0 ADuC816 Serial Safe Mode FUNCTION: HOLDS THE 4-BYTE PAGE DATA FUNCTION: HOLDS THE 8-BIT PAGE ADDRESS POINTER This mode disables serial download capability on the device. If Serial Safe mode is activated and an attempt is made to reset the part into serial download mode, i.e., RESET asserted and deasserted with PSEN low, the part will interpret the serial download reset as a normal reset only. It will, therefore, not enter serial download mode but only execute a normal reset sequence. Serial Safe mode can only be disabled by initiating a code-erase command in parallel programming mode. 9FH BYTE 1 BYTE 2 BYTE 3 BYTE 4 EADRL EDATA1 (BYTE 1) EDATA2 (BYTE 2) EDATA3 (BYTE 3) EDATA4 (BYTE 4) Using the Flash/EE Data Memory The user Flash/EE data memory array consists of 640 bytes that are configured into 160 (00H to 9FH) 4-byte pages as shown in Figure 29. 9FH BYTE 1 BYTE 2 BYTE 3 00H BYTE 1 BYTE 2 BYTE 3 BYTE 4 ECON COMMAND INTERPRETER LOGIC BYTE 4 FUNCTION: RECEIVES COMMAND DATA ECON FUNCTION: INTERPRETS THE FLASH COMMAND WORD Figure 30. Flash/EE Data Memory Control and Configuration ECON—Flash/EE Memory Control SFR 00H BYTE 1 BYTE 2 BYTE 3 This SFR acts as a command interpreter and may be written with one of five command modes to enable various read, program and erase cycles as detailed in Table XIII: BYTE 4 Figure 29. Flash/EE Data Memory Configuration As with other ADuC816 user-peripheral circuits, the interface to this memory space is via a group of registers mapped in the SFR space. A group of four data registers (EDATA1–4) are used to hold 4-byte page data just accessed. EADRL is used to hold the 8-bit address of the page to be accessed. Finally, ECON is an 8bit control register that may be written with one of five Flash/EE memory access commands to trigger various read, write, erase, and verify functions. These registers can be summarized as follows: ECON: EADRL: SFR Address: Function: Default: SFR Address: Function: Default: B9H Controls access to 640 Bytes Flash/EE Data Space. 00H C6H Holds the Flash/EE Data Page Address. (640 Bytes => 160 Page Addresses.) 00H Table XIII. ECON–Flash/EE Memory Control Register Command Modes Command Byte 01H 02H 03H 04H EDATA 1–4: SFR Address: Function: Default : BCH to BFH respectively Holds Flash/EE Data memory page write or page read data bytes. EDATA1–2 –> 00H EDATA3–4 –> 00H A block diagram of the SFR interface to the Flash/EE Data Memory array is shown in Figure 30. 05H 06H 07H to FFH REV. A REV. 0 –39– Command Mode READ COMMAND. Results in four bytes being read into EDATA1–4 from memory page address contained in EADRL. PROGRAM COMMAND. Results in four bytes (EDATA1–4) being written to memory page address in EADRL. This write command assumes the designated “write” page has been pre-erased. RESERVED FOR INTERNAL USE. 03H should not be written to the ECON SFR. VERIFY COMMAND. Allows the user to verify if data in EDATA1–4 is contained in page address designated by EADRL. A subsequent read of the ECON SFR will result in a “zero” being read if the verification is valid, a nonzero value will be read to indicate an invalid verification. ERASE COMMAND. Results in an erase of the 4-byte page designated in EADRL. ERASE-ALL COMMAND. Results in erase of the full Flash/EE Data memory 160-page (640 bytes) array. RESERVED COMMANDS. Commands reserved for future use. ADuC816 Flash/EE Memory Timing Erase-All The typical program/erase times for the Flash/EE Data Memory are: Although the 640-byte User Flash/EE array is shipped from the factory pre-erased, i.e., Byte locations set to FFH, it is nonetheless good programming practice to include an erase-all routine as part of any configuration/setup code running on the ADuC816. An “ERASE-ALL” command consists of writing “06H” to the ECON SFR, which initiates an erase of all 640 byte locations in the Flash/EE array. This command coded in 8051 assembly would appear as: Erase Full Array (640 Bytes) – 2 ms Erase Single Page (4 Bytes) – 2 ms Program Page (4 Bytes) – 250 μs Read Page (4 Bytes) – Within Single Instruction Cycle Using the Flash/EE Memory Interface As with all Flash/EE memory architectures, the array can be programmed in-system at a byte level, although it must be erased first; the erasure being performed in page blocks (4-byte pages in this case). MOV ECON, #06H ; Erase all Command ; 2 ms Duration Program a Byte A typical access to the Flash/EE Data array will involve setting up the page address to be accessed in the EADRL SFR, configuring the EDATA1–4 with data to be programmed to the array (the EDATA SFRs will not be written for read accesses) and finally, writing the ECON command word which initiates one of the six modes shown in Table XIII. In general terms, a byte in the Flash/EE array can only be programmed if it has previously been erased. To be more specific, a byte can only be programmed if it already holds the value FFH. Because of the Flash/EE architecture, this erasure must happen at a page level; therefore, a minimum of four bytes (1 page) will be erased when an erase command is initiated. It should be noted that a given mode of operation is initiated as soon as the command word is written to the ECON SFR. The core microcontroller operation on the ADuC816 is idled until the requested Program/Read or Erase mode is completed. A more specific example of the Program-Byte process is shown below. In this example the user writes F3H into the second byte on Page 03H of the Flash/EE Data Memory space while preserving the other three bytes already in this page. As the user is only required to modify one of the page bytes, the full page must be first read so that this page can then be erased without the existing data being lost. In practice, this means that even though the Flash/EE memory mode of operation is typically initiated with a two-machine cycle MOV instruction (to write to the ECON SFR), the next instruction will not be executed until the Flash/EE operation is complete (250 μs or 2 ms later). This means that the core will not respond to Interrupt requests until the Flash/EE operation is complete, although the core peripheral functions like Counter/Timers will continue to count and time as configured throughout this period. This example, coded in 8051 assembly, would appear as: MOV MOV MOV MOV MOV –40– EADRL,#03H ECON,#01H EDATA2,#0F3H ECON,#05H ECON,#02H ; ; ; ; ; Set Page Address Pointer Read Page Write New Byte Erase Page Write Page (Program Flash/EE) REV. REV. A 0 ADuC816 USER INTERFACE TO OTHER ON-CHIP ADuC816 PERIPHERALS The following section gives a brief overview of the various peripherals also available on-chip. A summary of the SFRs used to control and configure these peripherals is also given. DAC The ADuC816 incorporates a 12-bit, voltage output DAC on-chip. It has a rail-to-rail voltage output buffer capable of DACCON DAC Control Register SFR Address Power-On Default Value Bit Addressable FDH 00H No --- --- --- driving 10 kΩ/100 pF. It has two selectable ranges, 0 V to VREF (the internal bandgap 2.5 V reference) and 0 V to AVDD. It can operate in 12-bit or 8-bit mode. The DAC has a control register, DACCON, and two data registers, DACH/L. The DAC output can be programmed to appear at Pin 3 or Pin 12. It should be noted that in 12-bit mode, the DAC voltage output will be updated as soon as the DACL data SFR has been written; therefore, the DAC data registers should be updated as DACH first followed by DACL.5 DACPIN DAC8 DACRN DACCLR DACEN Table XIV. DACCON SFR Bit Designations Bit Name Description 7 6 5 4 ------DACPIN 3 DAC8 2 DACRN 1 DACCLR 0 DACEN Reserved for Future Use. Reserved for Future Use. Reserved for Future Use. DAC Output Pin Select. Set by the user to direct the DAC output to Pin 12 (P1.7/AIN4/DAC). Cleared by user to direct the DAC output to Pin 3 (P1.2/DAC/IEXC1). DAC 8-bit Mode Bit. Set by user to enable 8-bit DAC operation. In this mode the 8-bits in DACL SFR are routed to the 8 MSBs of the DAC and the 4 LSBs of the DAC are set to zero. Cleared by user to operate the DAC in its normal 12-bit mode of operation. DAC Output Range Bit. Set by user to configure DAC range of 0 – AVDD. Cleared by user to configure DAC range of 0 – 2.5 V. DAC Clear Bit. Set to “1” by user to enable normal DAC operation. Cleared to “0” by user to reset DAC data registers DACl/H to zero. DAC Enable Bit. Set to “1” by user to enable normal DAC operation. Cleared to “0” by user to power-down the DAC. DACH/L DAC Data Registers Function SFR Address DAC Data Registers, written by user to update the DAC output. DACL (DAC Data Low Byte) –>FBH DACH (DAC Data High Byte) –>FCH 00H –>Both Registers No –>Both Registers Power-On Default Value Bit Addressable The 12-bit DAC data should be written into DACH/L right-justified such that DACL contains the lower eight bits, and the lower nibble of DACH contains the upper four bits. REV. 0 A REV. –41– ADuC816 On-Chip PLL The ADuC816 is intended for use with a 32.768 kHz watch crystal. A PLL locks onto a multiple (384) of this to provide a stable 12.582912 MHz clock for the system. The core can operate at this frequency or at binary submultiples of it to allow power saving in cases where maximum core performance is not PLLCON PLL Control Register SFR Address Power-On Default Value Bit Addressable D7H 03H No OSC_PD LOCK required. The default core clock is the PLL clock divided by 8 or 1.572864 MHz. The ADC clocks are also derived from the PLL clock, with the modulator rate being the same as the crystal oscillator frequency. The above choice of frequencies ensures that the modulators and the core will be synchronous, regardless of the core clock rate. The PLL control register is PLLCON. LTEA --- FINT CD2 CD1 CD0 Table XV. PLLCON SFR Bit Designations Bit Name Description 7 OSC_PD 6 LOCK 5 4 3 --LTEA FINT 2 1 0 CD2 CD1 CD0 Oscillator Power-Down Bit. Set by user to halt the 32 kHz oscillator in power-down mode. Cleared by user to enable the 32 kHz oscillator in power-down mode. This feature allows the TIC to continue counting even in power-down mode. PLL Lock Bit. This is a read only bit. Set automatically at power-on to indicate the PLL loop is correctly tracking the crystal clock. If the external crystal becomes subsequently disconnected the PLL will rail and the core will halt. Cleared automatically at power-on to indicate the PLL is not correctly tracking the crystal clock. This may be due to the absence of a crystal clock or an external crystal at power-on. In this mode, the PLL output can be 12.58 MHz ± 20%. Reserved for future use; should be written with “0.” Reading this bit returns the state of the external EA pin latched at reset or power-on. Fast Interrupt Response Bit. Set by user enabling the response to any interrupt to be executed at the fastest core clock frequency, regardless of the configuration of the CD2–0 bits (see below). Once user code has returned from an interrupt, the core resumes code execution at the core clock selected by the CD2–0 bits. Cleared by user to disable the fast interrupt response feature. CPU (Core Clock) Divider Bits. This number determines the frequency at which the microcontroller core will operate. CD2 CD1 CD0 Core Clock Frequency (MHz) 0 0 0 12.582912 0 0 1 6.291456 0 1 0 3.145728 0 1 1 1.572864 (Default Core Clock Frequency) 1 0 0 0.786432 1 0 1 0.393216 1 1 0 0.196608 1 1 1 0.098304 –42– REV. REV. 0 A ADuC816 overflow will clock the interval counter. When this counter is equal to the time interval value loaded in the INTVAL SFR, the TII bit (TIMECON.2) is set and generates an interrupt if enabled (See IEIP2 SFR description under Interrupt System later in this data sheet.) If the ADuC816 is in power-down mode, again with TIC interrupt enabled, the TII bit will wake up the device and resume code execution by vectoring directly to the TIC interrupt service vector address at 0053 hex. The TIC-related SFRs are described in Table XVI. Note also that the timebase SFRs can be written initially with the current time, the TIC can then be controlled and accessed by user software. In effect, this facilitates the implementation of a real-time clock. A block diagram of the TIC is shown in Figure 31. Time Interval Counter (TIC) A time interval counter is provided on-chip for counting longer intervals than the standard 8051-compatible timers are capable of. The TIC is capable of timeout intervals ranging from 1/128th second to 255 hours. Furthermore, this counter is clocked by the crystal oscillator rather than the PLL and thus has the ability to remain active in power-down mode and time long power-down intervals. This has obvious applications for remote battery-powered sensors where regular widely spaced readings are required. Six SFRs are associated with the time interval counter, TIMECON being its control register. Depending on the configuration of the IT0 and IT1 bits in TIMECON, the selected time counter register TCEN 32.768kHz EXTERNAL CRYSTAL ITS0, 1 8-BIT PRESCALER HUNDREDTHS COUNTER HTHSEC INTERVAL TIMEBASE SELECTION MUX SECOND COUNTER SEC MINUTE COUNTER MIN HOUR COUNTER HOUR 8-BIT INTERVAL COUNTER INTERVAL TIMEOUT TIME INTERVAL COUNTER INTERRUPT COMPARE COUNT = INTVAL? TIME INTERVAL INTVAL Figure 31. TIC, Simplified Block Diagram REV. A REV. 0 –43– TIEN ADuC816 TIMECON TIC CONTROL REGISTER SFR Address Power-On Default Value Bit Addressable A1H 00H No --- --- ITS1 ITS0 STI TI I TIEN TCEN Table XVI. TIMECON SFR Bit Designations Bit Name Description 7 6 5 4 ----ITS1 ITS0 3 STI 2 TII 1 TIEN 0 TCEN Reserved for Future Use. Reserved for Future Use. For future product code compatibility this bit should be written as a ‘1.’ Interval Timebase Selection Bits. Written by user to determine the interval counter update rate. ITS1 ITS0 Interval Timebase 0 0 1/128 Second 0 1 Seconds 1 0 Minutes 1 1 Hours Single Time Interval Bit. Set by user to generate a single interval timeout. If set, a timeout will clear the TIEN bit. Cleared by user to allow the interval counter to be automatically reloaded and start counting again at each interval timeout. TIC Interrupt Bit. Set when the 8-bit Interval Counter matches the value in the INTVAL SFR. Cleared by user software. Time Interval Enable Bit. Set by user to enable the 8-bit time interval counter. Cleared by user to disable and clear the contents of the interval counter. Time Clock Enable Bit. Set by user to enable the time clock to the time interval counters. Cleared by user to disable the clock to the time interval counters and clear the time interval SFRs. The time registers (HTHSEC, SEC, MIN and HOUR) can be written while TCEN is low. –44– REV. A REV. 0 ADuC816 INTVAL User Time Interval Select Register Function SFR Address Power-On Default Value Bit Addressable Valid Value User code writes the required time interval to this register. When the 8-bit interval counter is equal to the time interval value loaded in the INTVAL SFR, the TII bit (TIMECON.2) bit is set and generates an interrupt if enabled. (See IEIP2 SFR description under Interrupt System later in this data sheet.) A6H 00H No 0 to 255 decimal HTHSEC Hundredths Seconds Time Register Function This register is incremented in (1/128) second intervals once TCEN in TIMECON is active. The HTHSEC SFR counts from 0 to 127 before rolling over to increment the SEC time register. A2H 00H No 0 to 127 decimal SFR Address Power-On Default Value Bit Addressable Valid Value SEC Seconds Time Register Function SFR Address Power-On Default Value Bit Addressable Valid Value This register is incremented in 1-second intervals once TCEN in TIMECON is active. The SEC SFR counts from 0 to 59 before rolling over to increment the MIN time register. A3H 00H No 0 to 59 decimal MIN Minutes Time Register Function This register is incremented in 1-minute intervals once TCEN in TIMECON is active. The MIN counts from 0 to 59 before rolling over to increment the HOUR time register. A4H 00H No 0 to 59 decimal SFR Address Power-On Default Value Bit Addressable Valid Value HOUR Hours Time Register Function This register is incremented in 1-hour intervals once TCEN in TIMECON is active. The HOUR SFR counts from 0 to 23 before rolling over to 0. A5H 00H No 0 to 23 decimal SFR Address Power-On Default Value Bit Addressable Valid Value REV. REV. 0 A –45– ADuC816 Watchdog Timer The purpose of the watchdog timer is to generate a device reset or interrupt within a reasonable amount of time if the ADuC816 enters an erroneous state, possibly due to a programming error, electrical noise, or RFI. The Watchdog function can be disabled by clearing the WDE (Watchdog Enable) bit in the Watchdog Control (WDCON) SFR. When enabled; the watchdog circuit will generate a system reset or interrupt (WDS) if the user program fails to set the watchdog (WDE) bit within a predetermined amount of time (see PRE3–0 bits in WDCON). The watchdog timer itself is a 16-bit counter that is clocked at 32.768 kHz. The watchdog time-out interval can be adjusted via the PRE3–0 bits in WDCON. Full Control and Status of the watchdog timer function can be controlled via the watchdog timer control SFR (WDCON). The WDCON SFR can only be written by user software if the double write sequence described in WDWR below is initiated on every write access to the WDCON SFR. WDCON Watchdog Timer Control Register SFR Address Power-On Default Value Bit Addressable C0H 10H Yes PRE3 PRE2 PRE1 PRE0 WDIR WDS WDE WDWR Table XVII. WDCON SFR Bit Designations Bit Name Description 7 6 5 4 PRE3 PRE2 PRE1 PRE0 3 WDIR 2 WDS 1 WDE 0 WDWR Watchdog Timer Prescale Bits. The Watchdog timeout period is given by the equation: tWD = (2PRE × (29/fPLL)) (0 ≤ PRE ≤ 7; fPLL = 32.768 kHz) PRE3 PRE2 PRE1 PRE0Timout Period (ms) Action 0 0 0 0 15.6 Reset or Interrupt 0 0 0 1 31.2 Reset or Interrupt 0 0 1 0 62.5 Reset or Interrupt 0 0 1 1 125 Reset or Interrupt 0 1 0 0 250 Reset or Interrupt 0 1 0 1 500 Reset or Interrupt 0 1 1 0 1000 Reset or Interrupt 0 1 1 1 2000 Reset or Interrupt 1 0 0 0 0.0 Immediate Reset PRE3–0 > 1001 Reserved Watchdog Interrupt Response Enable Bit. If this bit is set by the user, the watchdog will generate an interrupt response instead of a system reset when the watchdog timeout period has expired. This interrupt is not disabled by the CLR EA instruction and it is also a fixed, high-priority interrupt. If the watchdog is not being used to monitor the system, it can alternatively be used as a timer. The prescaler is used to set the timeout period in which an interrupt will be generated. (See also Note 1, Table XXXIV in the Interrupt System section.) Watchdog Status Bit. Set by the Watchdog Controller to indicate that a watchdog timeout has occurred. Cleared by writing a “0” or by an external hardware reset. It is not cleared by a watchdog reset. Watchdog Enable Bit. Set by user to enable the watchdog and clear its counters. If this bit is not set by the user within the watchdog timeout period, the watchdog will generate a reset or interrupt, depending on WDIR. Cleared under the following conditions, User writes “0,” Watchdog Reset (WDIR = “0”); Hardware Reset; PSM Interrupt. Watchdog Write Enable Bit. To write data into the WDCON SFR involves a double instruction sequence. The WDWR bit must be set and the very next instruction must be a write instruction to the WDCON SFR. e.g., CLR EA ; disable interrupts while writing to WDT SETB WDWR ; allow write to WDCON MOV WDCON, #72h ; enable WDT for 2.0s timeout SET B EA ; enable interrupts again (if rqd) –46– REV. A 0 ADuC816 Power Supply Monitor As its name suggests, the Power Supply Monitor, once enabled, monitors both supplies (AVDD or DVDD) on the ADuC816. It will indicate when any of the supply pins drop below one of four user-selectable voltage trip points from 2.63 V to 4.63 V. For correct operation of the Power Supply Monitor function, AVDD must be equal to or greater than 2.7 V. Monitor function is controlled via the PSMCON SFR. If enabled via the IEIP2 SFR, the monitor will interrupt the core using the PSMI bit in the PSMCON SFR. This bit will not be cleared until the failing power supply has returned above the trip point for at least 250 ms. This monitor function allows the user to save working registers to avoid possible data loss due to the low supply condition, and also ensures that normal code execution will not resume until a safe supply level has been well established. The supply monitor is also protected against spurious glitches triggering the interrupt circuit. PSMCON Power Supply Monitor Control Register SFR Address Power-On Default Value Bit Addressable DFH DEH No CMPD CMPA PSMI TPD1 TPD0 TPA1 TPA0 PSMEN Table XVIII. PSMCON SFR Bit Designations Bit Name Description 7 CMPD 6 CMPA 5 PSMI 4 3 TPD1 TPD0 2 1 TPA1 TPA0 0 PSMEN DVDD Comparator Bit. This is a read-only bit and directly reflects the state of the DVDD comparator. Read “1” indicates the DVDD supply is above its selected trip point. Read “0” indicates the DVDD supply is below its selected trip point. AVDD Comparator Bit. This is a read-only bit and directly reflects the state of the AVDD comparator. Read “1” indicates the AVDD supply is above its selected trip point. Read “0” indicates the AVDD supply is below its selected trip point. Power Supply Monitor Interrupt Bit. This bit will be set high by the MicroConverter if either CMPA or CMPD are low, indicating low analog or digital supply. The PSMI bit can be used to interrupt the processor. Once CMPD and/or CMPA return (and remain) high, a 250 ms counter is started. When this counter times out, the PSMI interrupt is cleared. PSMI can also be written by the user. However, if either comparator output is low, it is not possible for the user to clear PSMI. DVDD Trip Point Selection Bits. These bits select the DVDD trip-point voltage as follows: TPD1 TPD0 Selected DVDD Trip Point (V) 0 0 4.63 0 1 3.08 1 0 2.93 1 1 2.63 AVDD Trip Point Selection Bits. These bits select the AVDD trip-point voltage as follows: TPA1 TPA0 Selected AVDD Trip Point (V) 0 0 4.63 0 1 3.08 1 0 2.93 1 1 2.63 Power Supply Monitor Enable Bit. Set to “1” by the user to enable the Power Supply Monitor Circuit. Cleared to “0” by the user to disable the Power Supply Monitor Circuit. REV. REV. A 0 –47– ADuC816 SERIAL PERIPHERAL INTERFACE The ADuC816 integrates a complete hardware Serial Peripheral Interface (SPI) interface on-chip. SPI is an industry standard synchronous serial interface that allows eight bits of data to be synchronously transmitted and received simultaneously, i.e., full duplex. It should be noted that the SPI physical interface is shared with the I2C interface and therefore the user can only enable one or the other interface at any given time (see SPE in SPICON below). The system can be configured for Master or Slave operation and typically consists of four pins, namely: MISO (Master In, Slave Out Data I/O Pin), Pin 14 The MISO (master in slave out) pin is configured as an input line in master mode and 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), Pin 27 The MOSI (master out slave in) pin is configured as an output line in master mode and 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. SCLOCK (Serial Clock I/O Pin), Pin 26 The master clock (SCLOCK) is used to synchronize the data being transmitted and received through the MOSI and MISO data lines. A single data bit is transmitted and received in SPICON: SPI Control Register SFR Address Power-On Default Value Bit Addressable F8H 04H Yes ISPI WCOL SPE each SCLOCK period. Therefore, a byte is transmitted/received after eight SCLOCK periods. The SCLOCK pin is configured as an output in master mode and as an input in slave mode. In master mode the bit-rate, polarity and phase of the clock are controlled by the CPOL, CPHA, SPR0 and SPR1 bits in the SPICON SFR (see Table XIX below). In slave mode the SPICON register will have to be configured with the phase and polarity (CPHA and CPOL) of the expected input clock. In both master and slave mode the data is transmitted on one edge of the SCLOCK signal and sampled on the other. It is important therefore that the CPHA and CPOL are configured the same for the master and slave devices. SS (Slave Select Input Pin), Pin 13 The Slave Select (SS) input pin is only used when the ADuC816 is configured in slave mode to enable the SPI peripheral. This line is active low. Data is only received or transmitted in slave mode when the SS pin is low, allowing the ADuC816 to be used in single master, multislave SPI configurations. If CPHA = 1 then the SS input may be permanently pulled low. With CPHA = 0 then the SS input must be driven low before the first bit in a byte wide transmission or reception and return high again after the last bit in that byte wide transmission or reception. In SPI Slave Mode, the logic level on the external SS pin (Pin 13), can be read via the SPR0 bit in the SPICON SFR. The following SFR registers are used to control the SPI interface. SPIM CPOL CPHA SPR1 SPR0 Table XIX. SPICON SFR Bit Designations Bit Name Description 7 ISPI 6 WCOL 5 SPE 4 SPIM 3 CPOL 2 CPHA SPI Interrupt Bit. Set by MicroConverter at the end of each SPI transfer. Cleared directly by user code or indirectly by reading the SPIDAT SFR Write Collision Error Bit. Set by MicroConverter if SPIDAT is written to while an SPI transfer is in progress. Cleared by user code. SPI Interface Enable Bit. Set by user to enable the SPI interface. Cleared by user to enable the I2C interface. SPI Master/Slave Mode Select Bit. Set by user to enable Master Mode operation (SCLOCK is an output). Cleared by user to enable Slave Mode operation (SCLOCK is an input). Clock Polarity Select Bit. Set by user if SCLOCK idles high. Cleared by user if SCLOCK idles low. Clock Phase Select Bit. Set by user if leading SCLOCK edge is to transmit data. Cleared by user if trailing SCLOCK edge is to transmit data. –48– REV. 0 REV. A ADuC816 Table XIX. SPICON SFR Bit Designations (continued) Bit Name Description 1 0 SPR1 SPR0 SPI Bit-Rate Select Bits. These bits select the SCLOCK rate (bit-rate) in Master Mode as follows: SPR1 SPR0 Selected Bit Rate 0 0 fCORE/2 0 1 fCORE/4 1 0 fCORE/8 1 1 fCORE/16 In SPI Slave Mode, i.e., SPIM = 0, the logic level on the external SS pin (Pin 13), can be read via the SPR0 bit. NOTE The CPOL and CPHA bits should both contain the same values for master and slave devices. SPIDAT SPI Data Register Function The SPIDAT SFR is written by the user to transmit data over the SPI interface or read by user code to read data just received by the SPI interface. F7H 00H No SFR Address Power-On Default Value Bit Addressable Using the SPI Interface SPI Interface—Master Mode Depending on the configuration of the bits in the SPICON SFR shown in Table XIX, the ADuC816 SPI interface will transmit or receive data in a number of possible modes. Figure 32 shows all possible ADuC816 SPI configurations and the timing relationships and synchronization between the signals involved. Also shown in this figure is the SPI interrupt bit (ISPI) and how it is triggered at the end of each byte-wide communication. In master mode, the SCLOCK pin is always an output and generates a burst of eight clocks whenever user code writes to the SPIDAT register. The SCLOCK bit rate is determined by SPR0 and SPR1 in SPICON. It should also be noted that the SS pin is not used in master mode. If the ADuC816 needs to assert the SS pin on an external slave device, a Port digital output pin should be used. SCLOCK (CPOL = 1) SCLOCK (CPOL = 0) SS SAMPLE INPUT (CPHA = 1) DATA OUTPUT ? MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB SPI Interface—Slave Mode In slave mode the SCLOCK is an input. The SS pin must also be driven low externally during the byte communication. ISPI FLAG SAMPLE INPUT DATA OUTPUT MSB BIT 6 BIT 5 BIT 4 BIT 3 BIT 2 BIT 1 LSB ? (CPHA = 0) ISPI FLAG Figure 32. SPI Timing, All Modes REV. A REV. 0 In master mode a byte transmission or reception is initiated by a write to SPIDAT. Eight clock periods are generated via the SCLOCK pin and the SPIDAT byte being transmitted via MOSI. With each SCLOCK period a data bit is also sampled via MISO. After eight clocks, the transmitted byte will have been completely transmitted and the input byte will be waiting in the input shift register. The ISPI flag will be set automatically and an interrupt will occur if enabled. The value in the shift register will be latched into SPIDAT. Transmission is also initiated by a write to SPIDAT. In slave mode, a data bit is transmitted via MISO and a data bit is received via MOSI through each input SCLOCK period. After eight clocks, the transmitted byte will have been completely transmitted and the input byte will be waiting in the input shift register. The ISPI flag will be set automatically and an interrupt will occur if enabled. The value in the shift register will be latched into SPIDAT only when the transmission/reception of a byte has been completed. The end of transmission occurs after the eighth clock has been received, if CPHA = 1 or when SS returns high if CPHA = 0. –49– ADuC816 I2C-COMPATIBLE INTERFACE The ADuC816 supports a 2-wire serial interface mode which is I2C compatible. The I2C-compatible interface shares its pins with the on-chip SPI interface and therefore the user can only enable one or the other interface at any given time (see SPE in SDATA (Pin 27) SCLOCK (Pin 26) SPICON previously). An Application Note describing the operation of this interface as implemented is available from the MicroConverter Website at www.analog.com/microconverter. This interface can be configured as a Software Master or Hardware Slave, and uses two pins in the interface. Serial Data I/O Pin Serial Clock Three SFRs are used to control the I2C-compatible interface. These are described below: I2C Control Register E8H 00H Yes I2CCON: SFR Address Power-On Default Value Bit Addressable MDO MDE MCO MDI I2CM I2CRS I2CTX I2CI Table XX. I2CCON SFR Bit Designations Bit Name Description 7 MDO 6 MDE 5 MCO 4 MDI 3 I2CM 2 I2CRS 1 I2CTX 0 I2CI I2C Software Master Data Output Bit (MASTER MODE ONLY). This data bit is used to implement a master I2C transmitter interface in software. Data written to this bit will be output on the SDATA pin if the data output enable (MDE) bit is set. I2C Software Master Data Output Enable Bit (MASTER MODE ONLY). Set by user to enable the SDATA pin as an output (Tx). Cleared by the user to enable SDATA pin as an input (Rx). I2C Software Master Clock Output Bit (MASTER MODE ONLY). This data bit is used to implement a master I2C transmitter interface in software. Data written to this bit will be outputted on the SCLOCK pin. I2C Software Master Data Input Bit (MASTER MODE ONLY). This data bit is used to implement a master I2C receiver interface in software. Data on the SDATA pin is latched into this bit on SCLOCK if the Data Output Enable (MDE) bit is ‘0.’ I2C Master/Slave Mode Bit. Set by user to enable I2C software master mode. Cleared by user to enable I2C hardware slave mode. I2C Reset Bit (SLAVE MODE ONLY). Set by user to reset the I2C interface. Cleared by user code for normal I2C operation. I2C Direction Transfer Bit (SLAVE MODE ONLY). Set by the MicroConverter if the interface is transmitting. Cleared by the MicroConverter if the interface is receiving. I2C Interrupt Bit (SLAVE MODE ONLY). Set by the MicroConverter after a byte has been transmitted or received. Cleared automatically when user code reads the I2CDAT SFR (see I2CDAT below). I2CADD I2C Address Register I2CDAT I2C Data Register Function Holds the I2C peripheral address for the part. It may be overwritten by user code. Technical Note uC001 at www.analog.com/microconverter describes the format of the I2C standard 7-bit address in detail. 9BH 55H No Function The I2CDAT SFR is written by the user to transmit data over the I2C interface or read by user code to read data just received by the I2C interface Accessing I2CDAT automatically clears any pending I2C interrupt and the I2CI bit in the I2CCON SFR. User software should only access I2CDAT once per interrupt cycle. 9AH 00H No SFR Address Power-On Default Value Bit Addressable SFR Address Power-On Default Value Bit Addressable –50– REV. REV. 0 A ADuC816 8051-COMPATIBLE ON-CHIP PERIPHERALS This section gives a brief overview of the various secondary peripheral circuits are also available to the user on-chip. These remaining functions are fully 8051-compatible and are controlled via standard 8051 SFR bit definitions. Parallel I/O Ports 0–3 The ADuC816 uses four input/output ports to exchange data with external devices. In addition to performing general-purpose I/O, some ports are capable of external memory operations; others are multiplexed with an alternate function for the peripheral features on the device. In general, when a peripheral is enabled, that pin may not be used as a general purpose I/O pin. Port 0 is an 8-bit open drain bidirectional I/O port that is directly controlled via the Port 0 SFR (SFR address = 80 hex). Port 0 pins that have 1s written to them via the Port 0 SFR will be configured as open drain and will therefore float. In that state, Port 0 pins can be used as high impedance inputs. An external pull-up resistor will be required on Port 0 outputs to force a valid logic high level externally. Port 0 is also the multiplexed low-order address and data bus during accesses to external program or data memory. In this application it uses strong internal pull-ups when emitting 1s. Port 1 is also an 8-bit port directly controlled via the P1 SFR (SFR address = 90 hex). The Port 1 pins are divided into two distinct pin groupings. P1.0 and P1.1 pins on Port 1 are bidirectional digital I/O pins with internal pull-ups. If P1.0 and P1.1 have 1s written to them via the P1 SFR, these pins are pulled high by the internal pull-up resistors. In this state they can also be used as inputs; as input pins being externally pulled low, they will source current because of the internal pull-ups. With 0s written to them, both these pins will drive a logic low output voltage (VOL) and will be capable of sinking 10 mA compared to the standard 1.6 mA sink capability on the other port pins. These pins also have various secondary functions described in Table XXI. Table XXI. Port 1, Alternate Pin Functions Pin Alternate Function P1.0 P1.1 T2 (Timer/Counter 2 External Input) T2EX (Timer/Counter 2 Capture/Reload Trigger) The remaining Port 1 pins (P1.2–P1.7) can only be configured as Analog Input (ADC), Analog Output (DAC) or Digital Input pins. By (power-on) default these pins are configured as Analog Inputs, i.e., “1” written in the corresponding Port 1 register bit. To configure any of these pins as digital inputs, the user should write a “0” to these port bits to configure the corresponding pin as a high impedance digital input. Port 2 is a bidirectional port with internal pull-up resistors directly controlled via the P2 SFR (SFR address = A0 hex). Port 2 pins that have 1s written to them are pulled high by the internal pull-up resistors and, in that state, they can be used as inputs. As inputs, Port 2 pins being pulled externally low will source current because of the internal pull-up resistors. Port 2 emits the high order REV. REV. A 0 address bytes during fetches from external program memory and middle and high order address bytes during accesses to the 16-bit external data memory space. Port 3 is a bidirectional port with internal pull-ups directly controlled via the P2 SFR (SFR address = B0 hex). Port 3 pins that have 1s written to them are pulled high by the internal pullups and in that state they can be used as inputs. As inputs, Port 3 pins being pulled externally low will source current because of the internal pull-ups. Port 3 pins also have various secondary functions described in Table XXII. Table XXII. Port 3, Alternate Pin Functions Pin Alternate Function P3.0 RXD (UART Input Pin) (or Serial Data I/O in Mode 0) TXD (UART Output Pin) (or Serial Clock Output in Mode 0) INT0 (External Interrupt 0) INT1 (External Interrupt 1) T0 (Timer/Counter 0 External Input) T1 (Timer/Counter 1 External Input) WR (External Data Memory Write Strobe) RD (External Data Memory Read Strobe) P3.1 P3.2 P3.3 P3.4 P3.5 P3.6 P3.7 The alternate functions of P1.0, P1.1, and Port 3 pins can only be activated if the corresponding bit latch in the P1 and P3 SFRs contains a 1. Otherwise, the port pin is stuck at 0. Timers/Counters The ADuC816 has three 16-bit Timer/Counters: Timer 0, Timer 1, and Timer 2. The Timer/Counter hardware has been included on-chip to relieve the processor core of the overhead inherent in implementing timer/counter functionality in software. Each Timer/Counter consists of two 8-bit registers THx and TLx (x = 0, 1 and 2). All three can be configured to operate either as timers or event counters. In “Timer” function, the TLx register is incremented every machine cycle. Thus one can think of it as counting machine cycles. Since a machine cycle consists of 12 core clock periods, the maximum count rate is 1/12 of the core clock frequency. In “Counter” function, the TLx register is incremented by a 1-to-0 transition at its corresponding external input pin, T0, T1, or T2. In this function, the external input is sampled during S5P2 of every machine cycle. When the samples show a high in one cycle and a low in the next cycle, the count is incremented. The new count value appears in the register during S3P1 of the cycle following the one in which the transition was detected. Since it takes two machine cycles (16 core clock periods) to recognize a 1-to-0 transition, the maximum count rate is 1/16 of 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. Remember that the core clock frequency is programmed via the CD0–2 selection bits in the PLLCON SFR. –51– ADuC816 User configuration and control of all Timer operating modes is achieved via three SFRs namely: TMOD, TCON: T2CON: Control and configuration for Timers 0 and 1. Control and configuration for Timer 2. TMOD Timer/Counter 0 and 1 Mode Register SFR Address Power-On Default Value Bit Addressable 89H 00H No C/T Gate M1 M0 Gate C/T M1 M0 Table XXIII. TMOD SFR Bit Designations Bit Name Description 7 Gate 6 C/T 5 4 M1 M0 3 Gate 2 C/T 1 0 M1 M0 Timer 1 Gating Control. Set by software to enable timer/counter 1 only while INT1 pin is high and TR1 control bit is set. Cleared by software to enable timer 1 whenever TR1 control bit is set. Timer 1 Timer or Counter Select Bit. Set by software to select counter operation (input from T1 pin). Cleared by software to select timer operation (input from internal system clock). Timer 1 Mode Select Bit 1 (Used with M0 Bit). Timer 1 Mode Select Bit 0. M1 M0 0 0 TH1 operates as an 8-bit timer/counter. TL1 serves as 5-bit prescaler. 0 1 16-Bit Timer/Counter. TH1 and TL1 are cascaded; there is no prescaler. 1 0 8-Bit Auto-Reload Timer/Counter. TH1 holds a value which is to be reloaded into TL1 each time it overflows. 1 1 Timer/Counter 1 Stopped. Timer 0 Gating Control. Set by software to enable timer/counter 0 only while INT0 pin is high and TR0 control bit is set. Cleared by software to enable Timer 0 whenever TR0 control bit is set. Timer 0 Timer or Counter Select Bit. Set by software to select counter operation (input from T0 pin). Cleared by software to select timer operation (input from internal system clock). Timer 0 Mode Select Bit 1. Timer 0 Mode Select Bit 0. M1 M0 0 0 TH0 operates as an 8-bit timer/counter. TL0 serves as 5-bit prescaler. 0 1 16-Bit Timer/Counter. TH0 and TL0 are cascaded; there is no prescaler 1 0 8-Bit Auto-Reload Timer/Counter. TH0 holds a value which is to be reloaded into TL0 each time it overflows. 1 1 TL0 is an 8-bit timer/counter controlled by the standard timer 0 control bits. TH0 is an 8-bit timer only, controlled by Timer 1 control bits. –52– REV. A 0 REV. ADuC816 TCON: Timer/Counter 0 and 1 Control Register SFR Address Power-On Default Value Bit Addressable TF1 TR1 88H 00H Yes TF0 IE11 TR0 IT11 IE01 IT01 NOTE 1 These bits are not used in the control of timer/counter 0 and 1, but are used instead in the control and monitoring of the external INT0 and INT1 interrupt pins. Table XXIV. TCON SFR Bit Designations Bit Name Description 7 TF1 6 TR1 5 TF0 4 TR0 3 IE1 2 IT1 1 IE0 0 IT0 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 user to turn on timer/counter 1. Cleared by 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 user to turn on timer/counter 0. Cleared by user to turn off timer/counter 0. External Interrupt 1 (INT1) Flag. Set by hardware by a falling edge or zero level being applied to external interrupt pin INT1, depending on bit IT1 state. Cleared by hardware when the 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 (i.e., 1-to-0 transition). Cleared by software to specify level-sensitive detection (i.e., zero level). External Interrupt 0 (INT0) Flag. Set by hardware by a falling edge or zero level being applied to external interrupt pin INT0, depending on bit IT0 state. 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 (i.e., 1-to-0 transition). Cleared by software to specify level-sensitive detection (i.e., zero level). Timer/Counter 0 and 1 Data Registers Each timer consists of two 8-bit registers. These can be used as independent registers or combined to be a single 16-bit register depending on the timer mode configuration. TH0 and TL0 Timer 0 high byte and low byte. SFR Address = 8Chex, 8Ahex respectively. TH1 and TL1 Timer 1 high byte and low byte. SFR Address = 8Dhex, 8Bhex respectively. REV. A 0 REV. –53– ADuC816 TIMER/COUNTER 0 AND 1 OPERATING MODES Mode 2 (8-Bit Timer/Counter with Autoreload) The following paragraphs describe the operating modes for timer/ counters 0 and 1. Unless otherwise noted, it should be assumed that these modes of operation are the same for timer 0 as for timer 1. Mode 2 configures the timer register as an 8-bit counter (TL0) with automatic reload, as shown in Figure 35. 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. Mode 0 (13-Bit Timer/Counter) Mode 0 configures an 8-bit timer/counter with a divide-by-32 prescaler. Figure 33 shows mode 0 operation. CORE CLK* 12 C/T = 0 CORE CLK* TL0 (8 BITS) 12 C/T = 0 TF0 C/T = 1 TL0 TH0 (5 BITS) (8 BITS) P3.4/T0 CONTROL C/T = 1 INTERRUPT TR0 P3.4/T0 CONTROL TR0 INTERRUPT TF0 RELOAD TH0 (8 BITS) GATE P3.2/INT0 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. GATE P3.2/INT0 Figure 35. Timer/Counter 0, Mode 2 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. Mode 3 (Two 8-Bit Timer/Counters) Figure 33. Timer/Counter 0, Mode 0 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. The overflow flag, TF0, can then be used to request an interrupt. The counted input is enabled to the timer when TR0 = 1 and either Gate = 0 or INT0 = 1. Setting Gate = 1 allows the timer to be controlled by external input INT0, to facilitate pulsewidth measurements. TR0 is a control bit in the special function register TCON; Gate is in TMOD. The 13-bit register consists of all eight bits of TH0 and the lower five bits of TL0. The upper three bits of TL0 are indeterminate and should be ignored. Setting the run flag (TR0) does not clear the registers. Mode 1 (16-Bit Timer/Counter) 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 36. TL0 uses the timer 0 control bits: C/T, Gate, TR0, INT0, and TF0. TH0 is locked into a timer function (counting machine cycles) and takes over the use of TR1 and TF1 from timer 1. Thus, TH0 now 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 can still be used by the serial interface as a Baud Rate Generator. In fact, it can be used, in any application not requiring an interrupt from timer 1 itself. Mode 1 is the same as Mode 0, except that the timer register is running with all 16 bits. Mode 1 is shown in Figure 34. CORE CLK* CORE CLK/12 12 C/T = 0 CORE CLK* TL0 (8 BITS) 12 C/T = 0 C/T = 1 TL0 TH0 (8 BITS) (8 BITS) P3.4/T0 TR0 CONTROL INTERRUPT TF0 C/T = 1 P3.4/T0 CONTROL TR0 INTERRUPT INTERRUPT GATE TF0 TF1 P3.2/INT0 CORE CLK/12 GATE P3.2/INT0 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. TR1 TH0 (8 BITS) CONTROL *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. Figure 34. Timer/Counter 0, Mode 1 Figure 36. Timer/Counter 0, Mode 3 –54– REV. A REV. 0 ADuC816 T2CON Timer/Counter 2 Control Register SFR Address Power-On Default Value Bit Addressable C8H 00H Yes TF2 EXF2 RCLK TCLK EXEN2 TR 2 CNT2 CAP2 Table XXV. T2CON SFR Bit Designations Bit Name Description 7 TF2 6 EXF2 5 RCLK 4 TCLK 3 EXEN2 2 TR2 1 CNT2 0 CAP2 Timer 2 Overflow Flag. Set by hardware on a timer 2 overflow. TF2 will not be set when either RCLK or TCLK = 1. Cleared by user software. Timer 2 External Flag. Set by hardware when either a capture or reload is caused by a negative transition on T2EX and EXEN2 = 1. Cleared by user user software. Receive Clock Enable Bit. Set by user to enable the serial port to use timer 2 overflow pulses for its receive clock in serial port Modes 1 and 3. Cleared by user to enable timer 1 overflow to be used for the receive clock. Transmit Clock Enable Bit. Set by user to enable the serial port to use timer 2 overflow pulses for its transmit clock in serial port Modes 1 and 3. Cleared by user to enable timer 1 overflow to be used for the transmit clock. Timer 2 External Enable Flag. Set by 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 user for Timer 2 to ignore events at T2EX. Timer 2 Start/Stop Control Bit. Set by user to start timer 2. Cleared by user to stop timer 2. Timer 2 Timer or Counter Function Select Bit. Set by user to select counter function (input from external T2 pin). Cleared by user to select timer function (input from on-chip core clock). Timer 2 Capture/Reload Select Bit. Set by user to enable captures on negative transitions at T2EX if EXEN2 = 1. Cleared by user to enable auto-reloads 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. Timer/Counter 2 Data Registers Timer/Counter 2 also has two pairs of 8-bit data registers associated with it. These are used as both timer data registers and timer capture/reload registers. TH2 and TL2 Timer 2, data high byte and low byte. SFR Address = CDhex, CChex respectively. RCAP2H and RCAP2L Timer 2, Capture/Reload byte and low byte. SFR Address = CBhex, CAhex respectively. REV. 0 REV. A –55– ADuC816 Timer/Counter 2 Operating Modes 16-Bit Capture Mode The following paragraphs describe the operating modes for timer/ counter 2. The operating modes are selected by bits in the T2CON SFR as shown in Table XXVI. In the “Capture” mode, there are again two options, which are selected by bit EXEN2 in T2CON. If EXEN2 = 0, then Timer 2 is a 16-bit timer or counter which, upon overflowing, sets bit TF2, the Timer 2 overflow bit, which can be used to generate an interrupt. If EXEN2 = 1, then Timer 2 still performs the above, but a l-to-0 transition on external input T2EX causes the current value in the Timer 2 registers, TL2 and TH2, to be captured into registers RCAP2L and RCAP2H, respectively. In addition, the transition at T2EX causes bit EXF2 in T2CON to be set, and EXF2, like TF2, can generate an interrupt. The Capture Mode is illustrated in Figure 38. Table XXVI. TIMECON SFR Bit Designations RCLK (or) TCLK CAP2 TR2 MODE 0 0 1 X 0 1 X X 1 1 1 0 16-Bit Autoreload 16-Bit Capture Baud Rate OFF 16-Bit Autoreload Mode In “Autoreload” mode, there are two options, which are selected by bit EXEN2 in T2CON. If EXEN2 = 0, then when Timer 2 rolls over it not only sets TF2 but also causes the Timer 2 registers to be reloaded with the 16-bit value in registers RCAP2L and RCAP2H, which are preset by software. If EXEN2 = 1, then Timer 2 still performs the above, but with the added feature that a 1-to-0 transition at external input T2EX will also trigger the 16-bit reload and set EXF2. The autoreload mode is illustrated in Figure 37 below. CORE CLK* 12 The baud rate generator mode is selected by RCLK = 1 and/or TCLK = 1. In either case if Timer 2 is being used to generate the baud rate, the TF2 interrupt flag will not occur. Hence Timer 2 interrupts will not occur so they do not have to be disabled. In this mode the EXF2 flag, however, can still cause interrupts and this can be used as a third external interrupt. Baud rate generation will be described as part of the UART serial port operation in the following pages. C/T2 = 0 TL2 (8 BITS) TH2 (8 BITS) RCAP2L RCAP2H C/T2 = 1 T2 PIN CONTROL TR2 RELOAD TRANSITION DETECTOR TF2 TIMER INTERRUPT T2EX PIN EXF2 CONTROL EXEN2 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. Figure 37. Timer/Counter 2, 16-Bit Autoreload Mode CORE CLK* 12 C/T2 = 0 TL2 (8 BITS) TH2 (8 BITS) TF2 C/T2 = 1 T2 PIN CONTROL TR2 TIMER INTERRUPT CAPTURE TRANSITION DETECTOR RCAP2L RCAP2H T2EX PIN EXF2 CONTROL EXEN2 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. Figure 38. Timer/Counter 2, 16-Bit Capture Mode –56– REV. REV. 0 A ADuC816 UART SERIAL INTERFACE The serial port is full duplex, meaning it can transmit and receive simultaneously. It is also receive-buffered, meaning it can commence reception of a second byte before a previously received byte has been read from the receive register. However, if the first byte still has not been read by the time reception of the second byte is complete, the first byte will be lost. The physical interface to the serial data network is via Pins RXD(P3.0) and TXD(P3.1) while the SFR interface to the UART is comprised of the following registers. SBUF The serial port receive and transmit registers are both accessed through the SBUF SFR (SFR address = 99 hex). Writing to SBUF loads the transmit register and reading SBUF accesses a physically separate receive register. SCON UART Serial Port Control Register SFR Address Power-On Default Value Bit Addressable 98H 00H Yes SM0 SM1 SM2 REN TB8 RB8 TI RI Table XXVII. SCON SFR Bit Designations Bit Name Description 7 6 SM0 SM1 5 SM2 4 REN 3 TB8 2 RB8 1 TI 0 RI UART Serial Mode Select Bits. These bits select the Serial Port operating mode as follows: SM0 SM1 Selected Operating Mode 0 0 Mode 0: Shift Register, fixed baud rate (Core_Clk/2) 0 1 Mode 1: 8-bit UART, variable baud rate 1 0 Mode 2: 9-bit UART, fixed baud rate (Core_Clk/64) or (Core_Clk/32) 1 1 Mode 3: 9-bit UART, variable baud rate Multiprocessor Communication Enable Bit. Enables multiprocessor communication in Modes 2 and 3. In Mode 0, SM2 should be cleared. In Mode 1, if SM2 is set, RI will not be activated if a valid stop bit was not received. If SM2 is cleared, RI will be set as soon as the byte of data has been received. In Modes 2 or 3, if SM2 is set, RI will not be activated if the received ninth data bit in RB8 is 0. If SM2 is cleared, RI will be set as soon as the byte of data has been 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 will be the ninth data bit that will be transmitted in Modes 2 and 3. Serial port Receiver Bit 9. The ninth data bit received in Modes 2 and 3 is latched into RB8. For Mode 1 the stop bit is latched into RB8. Serial Port Transmit Interrupt Flag. Set by hardware at the end of the eighth bit in Mode 0, or at the beginning of the stop bit in Modes 1, 2, and 3. TI must be cleared by user software. Serial Port Receive Interrupt Flag. Set by hardware at the end of the eighth bit in mode 0, or halfway through the stop bit in Modes 1, 2, and 3. RI must be cleared by software. REV. A REV. 0 –57– ADuC816 Mode 0: 8-Bit Shift Register Mode Mode 2: 9-Bit UART with Fixed Baud Rate Mode 0 is selected by clearing both the SM0 and SM1 bits in the SFR SCON. Serial data enters and exits through RXD. TXD outputs the shift clock. Eight data bits are transmitted or received. Transmission is initiated by any instruction that writes to SBUF. The data is shifted out of the RXD line. The eight bits are transmitted with the least-significant bit (LSB) first, as shown in Figure 39. 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 Core_Clk/64 by default, although by setting the SMOD bit in PCON, the frequency can be doubled to Core_Clk/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, although it can be used for anything, including a ninth data bit if required. MACHINE CYCLE 1 MACHINE CYCLE 2 MACHINE CYCLE 7 S1 S2 S3 S4 S5 S6 S1 S2 S3 S4 MACHINE CYCLE 8 To transmit, the eight data bits must be written into SBUF. The ninth bit must be written to TB8 in SCON. When transmission is initiated the eight data bits (from SBUF) are loaded onto the transmit shift register (LSB first). The contents of TB8 are loaded into the ninth bit position of the transmit shift register. The transmission will start at the next valid baud rate clock. The TI flag is set as soon as the stop bit appears on TXD. S4 S5 S6 S1 S2 S3 S4 S5 S6 CORE CLK ALE RXD (DATA OUT) DATA BIT 0 DATA BIT 1 DATA BIT 6 DATA BIT 7 TXD (SHIFT CLOCK) Figure 39. UART Serial Port Transmission, Mode 0 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. 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. When all eight bits have been clocked in, the following events occur: The eight bits in the receive shift register are latched into SBUF The ninth data bit is latched into RB8 in SCON The Receiver interrupt flag (RI) is set 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 10 bits are transmitted on TXD or received on RXD. The baud rate is set by the Timer 1 or Timer 2 overflow rate, or a combination of the two (one for transmission and the other for reception). Transmission is initiated by writing to SBUF. The “write to SBUF” signal also loads a 1 (stop bit) 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 40. START BIT TXD STOP BIT D0 D1 D2 D3 D4 D5 D6 D7 if, and only if, the following conditions are met at the time the final shift pulse is generated: RI = 0, and Either SM2 = 0, or SM2 = 1 and the received stop bit = 1. If either of these conditions is not met, the received frame is irretrievably lost, and RI is not set. Mode 3: 9-Bit UART with Variable Baud Rate Mode 3 is selected by setting both SM0 and SM1. In this mode the 8051 UART serial port operates in 9-bit mode with a variable baud rate determined by either Timer 1 or Timer 2. The operation of the 9-bit UART is the same as for Mode 2 but the baud rate can be varied as for Mode 1. In all four modes, transmission is initiated by any instruction that uses SBUF as a destination register. Reception is initiated in Mode 0 by the condition RI = 0 and REN = 1. Reception is initiated in the other modes by the incoming start bit if REN = 1. TI (SCON.1) SET INTERRUPT i.e., READY FOR MORE DATA Figure 40. UART Serial Port Transmission, Mode 0 Reception is initiated when a 1-to-0 transition is detected on RXD. Assuming a valid start bit was detected, character reception continues. The start bit is skipped and the eight data bits are clocked into the serial port shift register. When all eight bits have been clocked in, the following events occur: UART Serial Port Baud Rate Generation Mode 0 Baud Rate Generation The baud rate in Mode 0 is fixed: Mode 0 Baud Rate = (Core Clock Frequency1/12) The eight bits in the receive shift register are latched into SBUF NOTE 1 In these descriptions Core Clock Frequency refers to the core clock frequency selected via the CD0–2 bits in the PLLCON SFR. The ninth bit (Stop bit) is clocked into RB8 in SCON Mode 2 Baud Rate Generation The Receiver interrupt flag (RI) is set if, and only if, the following conditions are met at the time the final shift pulse is generated: RI = 0, and Either SM2 = 0, or SM2 = 1 and the received stop bit = 1. If either of these conditions is not met, the received frame is irretrievably lost, and RI is not set. The baud rate in Mode 2 depends on the value of the SMOD bit in the PCON SFR. If SMOD = 0, the baud rate is 1/64 of the core clock. If SMOD = 1, the baud rate is 1/32 of the core clock: Mode 2 Baud Rate = (2SMOD/64) × (Core Clock Frequency) Modes 1 and 3 Baud Rate Generation The baud rates in Modes 1 and 3 are determined by the overflow rate in Timer 1 or Timer 2, or both (one for transmit and the other for receive). –58– REV. A 0 REV. ADuC816 Timer 1 Generated Baud Rates Modes 1 and 3 Baud Rate = (1/16) × (Timer 2 Overflow Rate) When Timer 1 is used as the baud rate generator, the baud rates in Modes 1 and 3 are determined by the Timer 1 overflow rate and the value of SMOD as follows: Therefore, when Timer 2 is used to generate baud rates, the timer increments every two clock cycles and not every core machine cycle as before. Hence, it increments six times faster than Timer 1, and therefore baud rates six times faster are possible. Because Timer 2 has 16-bit autoreload capability, very low baud rates are still possible. Modes 1 and 3 Baud Rate = (2SMOD/32) × (Timer 1 Overflow Rate) The Timer 1 interrupt should be disabled in this application. The Timer itself can be configured for either timer or counter operation, and in any of its three running modes. In the most typical application, it is configured for timer operation, in the autoreload mode (high nibble of TMOD = 0100Binary). In that case, the baud rate is given by the formula: Timer 2 is selected as the baud rate generator by setting the TCLK and/or RCLK in T2CON. The baud rates for transmit and receive can be simultaneously different. Setting RCLK and/or TCLK puts Timer 2 into its baud rate generator mode as shown in Figure 41. In this case, the baud rate is given by the formula: Modes 1 and 3 Baud Rate = (2SMOD/32) × (Core Clock/(12 × [256-TH1])) A very low baud rate can also be achieved with Timer 1 by leaving the Timer 1 interrupt enabled, and configuring the timer to run as a 16-bit timer (high nibble of TMOD = 0100Binary), and using the Timer 1 interrupt to do a 16-bit software reload. Table XXVIII below, shows some commonly-used baud rates and how they might be calculated from a core clock frequency of 1.5728 MHz and 12.58 MHz. Generally speaking, a 5% error is tolerable using asynchronous (start/stop) communications. Table XXVIII. Commonly-Used Baud Rates, Timer 1 Ideal Baud Core CLK SMOD Value TH1-Reload Value Actual Baud % Error 9600 2400 1200 1200 12.58 12.58 12.58 1.57 1 1 1 1 –7 (F9h) –27 (E5h) –55 (C9h) –7 (F9h) 9362 2427 1192 1170 2.5 1.1 0.7 2.5 Modes 1 and 3 Baud Rate = (Core Clk)/(32 × [65536 – (RCAP2H, RCAP2L)]) Table XXIX shows some commonly used baud rates and how they might be calculated from a core clock frequency of 1.5728 MHz and 12.5829 MHz. Table XXIX. Commonly Used Baud Rates, Timer 2 Ideal Baud Core CLK RCAP2H Value RCAP2L Value Actual Baud % Error 19200 9600 2400 1200 9600 2400 1200 12.58 12.58 12.58 12.58 1.57 1.57 1.57 –1 (FFh) –1 (FFh) –1 (FFh) –2 (FEh) –1 (FFh) –1 (FFh) –1 (FFh) –20 (ECh) –41 (D7h) –164 (5Ch) –72 (B8h) –5 (FBh) –20 (ECh) –41 (D7h) 19661 9591 2398 1199 9830 2457 1199 2.4 0.1 0.1 0.1 2.4 2.4 0.1 Timer 2 Generated Baud Rates Baud rates can also be generated 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/received. Because Timer 2 has a 16-bit autoreload mode a wider range of baud rates is possible using Timer 2. TIMER 1 OVERFLOW 2 NOTE: OSC. FREQ. IS DIVIDED BY 2, NOT 12. 0 CORE CLK* 2 SMOD C/T2 = 0 TL2 (8 BITS) T2 PIN 1 CONTROL TH2 (8 BITS) TIMER 2 OVERFLOW 1 0 RCLK C/T2 = 1 16 1 TR2 TCLK RELOAD 16 RCAP2L RCAP2H NOTE AVAILABILITY OF ADDITIONAL EXTERNAL INTERRUPT EXF 2 T2EX PIN TRANSITION DETECTOR TIMER 2 INTERRUPT CONTROL EXEN2 *THE CORE CLOCK IS THE OUTPUT OF THE PLL AS DESCRIBED ON PAGE 42. Figure 41. Timer 2, UART Baud Rates REV. A REV. 0 RX CLOCK 0 –59– TX CLOCK ADuC816 INTERRUPT SYSTEM The ADuC816 provides a total of twelve interrupt sources with two priority levels. The control and configuration of the interrupt system is carried out through three Interrupt-related SFRs. IE: IP: IEIP2: Interrupt Enable Register. Interrupt Priority Register. Secondary Interrupt Priority-Interrupt Register. IE: Interrupt Enable Register SFR Address Power-On Default Value Bit Addressable A8H 00H Yes EA EADC ET2 ES ET1 EX1 ET0 EX0 Table XXX. IE SFR Bit Designations Bit Name Description 7 6 5 4 3 2 1 0 EA EADC ET2 ES ET1 EX1 ET0 EX0 Written by User to Enable “1” or Disable “0” All Interrupt Sources Written by User to Enable “1” or Disable “0” ADC Interrupt Written by User to Enable “1” or Disable “0” Timer 2 Interrupt Written by User to Enable “1” or Disable “0” UART Serial Port Interrupt Written by User to Enable “1” or Disable “0” Timer 1 Interrupt Written by User to Enable “1” or Disable “0” External Interrupt 1 Written by User to Enable “1” or Disable “0” Timer 0 Interrupt Written by User to Enable “1” or Disable “0” External Interrupt 0 IP: Interrupt Priority Register SFR Address Power-On Default Value Bit Addressable B8H 00H Yes --- PADC PT2 PS PT1 PX1 PT0 PX0 Table XXXI. IP SFR Bit Designations Bit Name Description 7 6 5 4 3 2 1 0 --PADC PT2 PS PT1 PX1 PT0 PX0 Reserved for Future Use. Written by User to Select ADC Interrupt Priority (“1” = High; “0” = Low) Written by User to Select Timer 2 Interrupt Priority (“1” = High; “0” = Low) Written by User to Select UART Serial Port Interrupt Priority (“1” = High; “0” = Low) Written by User to Select Timer 1 Interrupt Priority (“1” = High; “0” = Low) Written by User to Select External Interrupt 1 Priority (“1” = High; “0” = Low) Written by User to Select Timer 0 Interrupt Priority (“1” = High; “0” = Low) Written by User to Select External Interrupt 0 Priority (“1” = High; “0” = Low) –60– REV. REV. A 0 ADuC816 IEIP2: Secondary Interrupt Enable and Priority Register SFR Address Power-On Default Value Bit Addressable A9H A0H No --- PTI PPSM PSI --- ETI EPSM ESI Table XXXII. IEIP2 SFR Bit Designations Bit Name Description 7 6 5 4 3 2 1 0 --PTI PPSM PSI --ETI EPSM ESI Reserved for Future Use. Written by User to Select TIC Interrupt Priority (“1” = High; “0” = Low). Written by User to Select Power Supply Monitor Interrupt Priority (“1” = High; “0” = Low). Written by User to Select SPI/I2C Serial Port Interrupt Priority (“1” = High; “0” = Low). Reserved, This Bit Must Be “0.” Written by User to Enable “1” or Disable “0” TIC Interrupt. Written by User to Enable “1” or Disable “0” Power Supply Monitor Interrupt. Written by User to Enable “1” or Disable “0” SPI/I2C Serial Port Interrupt. Table XXXIV. Interrupt Vector Addresses Interrupt Priority The Interrupt Enable registers are written by the user to enable individual interrupt sources, while the Interrupt Priority registers allow the user to select one of two priority levels for each interrupt. An interrupt of a high priority may interrupt the service routine of a low priority interrupt, and if two interrupts of different priority occur at the same time, the higher level interrupt will be 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 as shown in Table XXXIII. Table XXXIII. Priority within an Interrupt Level Source Priority Description PSMI WDS IE0 RDY0/RDY1 TF0 IE1 TF1 I2CI + ISPI RI + TI TF2 + EXF2 TII 1 (Highest) 2 3 4 5 6 7 8 9 10 11 (Lowest) Power Supply Monitor Interrupt Watchdog Interrupt External Interrupt 0 ADC Interrupt Timer/Counter 0 Interrupt External Interrupt 1 Timer/Counter 1 Interrupt I2C/SPI Interrupt Serial Interrupt Timer/Counter 2 Interrupt Time Interval Counter Interrupt Source Vector Address IE0 TF0 IE1 TF1 RI + TI TF2 + EXF2 RDY0/RDY1 (ADC) II2C + ISPI PSMI TII WDS (WDIR = 1)* 0003 Hex 000B Hex 0013 Hex 001B Hex 0023 Hex 002B Hex 0033 Hex 003B Hex 0043 Hex 0053 Hex 005B Hex *The watchdog can be configured to generate an interrupt instead of a reset when it times out. This is used for logging errors or to examine the internal status of the microcontroller core to understand, from a software debug point of view, why a watchdog timeout occurred. The watchdog interrupt is slightly different from the normal interrupts in that its priority level is always set to 1 and it is not possible to disable the interrupt via the global disable bit (EA) in the IE SFR. This is done to ensure that the interrupt will always be responded to if a watch dog timeout occurs. The watchdog will only produce an interrupt if the watchdog timeout is greater than zero. Interrupt Vectors When an interrupt occurs the program counter is pushed onto the stack and the corresponding interrupt vector address is loaded into the program counter. The interrupt vector addresses are shown in Table XXXIV. REV. A REV. 0 –61– ADuC816 ADuC816 HARDWARE DESIGN CONSIDERATIONS This section outlines some of the key hardware design considerations that must be addressed when integrating the ADuC816 into any hardware system. Clock Oscillator time that the low byte of the program counter is valid on P0, the signal ALE (Address Latch Enable) clocks this byte into an address latch. Meanwhile, Port 2 (P2) emits the high byte of the program counter (PCH), then PSEN strobes the EPROM and the code byte is read into the ADuC816. As described earlier, the core clock frequency for the ADuC816 is generated from an on-chip PLL that locks onto a multiple (384 times) of 32.768 kHz. The latter is generated from an internal clock oscillator. To use the internal clock oscillator, connect a 32.768 kHz parallel resonant crystal between XTAL1 and XTAL2 pins (32 and 33) as shown in Figure 42. ADuC816 P0 LATCH ADuC816 XTAL1 12pF XTAL2 12pF A0–A7 ALE As shown in the typical external crystal connection diagram in Figure 42, two internal 12 pF capacitors are provided on-chip. These are connected internally, directly to the XTAL1 and XTAL2 pins and the total input capacitances at both pins is detailed in the specification section of this data sheet. The value of the total load capacitance required for the external crystal should be the value recommended by the crystal manufacturer for use with that specific crystal. In many cases, because of the on-chip capacitors, additional external load capacitors will not be required. 32.768kHz EPROM D0–D7 (INSTRUCTION) TO INTERNAL PLL Figure 42. External Parallel Resonant Crystal Connections External Memory Interface In addition to its internal program and data memories, the ADuC816 can access up to 64 Kbytes of external program memory (ROM/PROM/etc.) and up to 16 Mbytes of external data memory (SRAM). A8–A15 P2 OE PSEN Figure 43. External Program Memory Interface Note that program memory addresses are always 16 bits wide, even in cases where the actual amount of program memory used is less than 64 Kbytes. External program execution sacrifices two of the 8-bit ports (P0 and P2) to the function of addressing the program memory. While executing from external program memory, Ports 0 and 2 can be used simultaneously for read/write access to external data memory, but not for general-purpose I/O. Though both external program memory and external data memory are accessed by some of the same pins, the two are completely independent of each other from a software point of view. For example, the chip can read/write external data memory while executing from external program memory. Figure 44 shows a hardware configuration for accessing up to 64 Kbytes of external RAM. This interface is standard to any 8051 compatible MCU. To select from which code space (internal or external program memory) to begin executing instructions, tie the EA (external access) pin high or low, respectively. When EA is high (pulled up to VDD), user program execution will start at address 0 of the internal 8 Kbytes Flash/EE code space. When EA is low (tied to ground) user program execution will start at address 0 of the external code space. In either case, addresses above 1FFF hex (8K) are mapped to the external space. ADuC816 SRAM D0–D7 (DATA) P0 LATCH A0–A7 ALE P2 Note that a second very important function of the EA pin is described in the Single Pin Emulation Mode section of this data sheet. External program memory (if used) must be connected to the ADuC816 as illustrated in Figure 43. Note that 16 I/O lines (Ports 0 and 2) are dedicated to bus functions during external program memory fetches. Port 0 (P0) serves as a multiplexed address/data bus. It emits the low byte of the program counter (PCL) as an address, and then goes into a float state awaiting the arrival of the code byte from the program memory. During the A8–A15 RD OE WR WE Figure 44. External Data Memory Interface (64 K Address Space) If access to more than 64 Kbytes of RAM is desired, a feature unique to the ADuC816 allows addressing up to 16 Mbytes of external RAM simply by adding an additional latch as illustrated in Figure 45. –62– REV. A 0 ADuC816 ADuC816 SRAM 20 D0–D7 (DATA) P0 34 DVDD 48 LATCH A0–A7 ALE POR (ACTIVE HIGH) 15 RESET A8–A15 P2 LATCH Figure 47. External Active High POR Circuit A16–A23 RD OE WR WE Some active-low POR chips, such as the ADM809 can be used with a manual push-button as an additional reset source as illustrated by the dashed line connection in Figure 48. Figure 45. External Data Memory Interface (16 M Bytes Address Space) Detailed timing diagrams of external program and data memory read and write access can be found in the timing specification sections of this data sheet. Power-On Reset Operation External POR (power-on reset) circuitry must be implemented to drive the RESET pin of the ADuC816. The circuit must hold the RESET pin asserted (high) whenever the power supply (DVDD) is below 2.5 V. Furthermore, VDD must remain above 2.5 V for at least 10 ms before the RESET signal is deasserted (low) by which time the power supply must have reached at least a 2.7 V level. The external POR circuit must be operational down to 1.2 V or less. The timing diagram of Figure 46 illustrates this functionality under three separate events: powerup, brownout, and power-down. Notice that when RESET is asserted (high) it tracks the voltage on DVDD. 34 DVDD 48 POR (ACTIVE LOW) 15 RESET OPTIONAL MANUAL RESET PUSH-BUTTON Figure 48. External Active Low POR Circuit Power Supplies The ADuC816’s operational power supply voltage range is 2.7 V to 5.25 V. Although the guaranteed data sheet specifications are given only for power supplies within 2.7 V to 3.6 V or +5% of the nominal 5 V level, the chip will function equally well at any power supply level between 2.7 V and 5.25 V. Separate analog and digital power supply pins (AVDD and DVDD respectively) allow AVDD to be kept relatively free of noisy digital signals often present on the system DVDD line. In this mode the part can also operate with split supplies; that is, using different voltage supply levels for each supply. For example, this means that the system can be designed to operate with a DVDD voltage level of 3 V while the AVDD level can be at 5 V or vice-versa if required. A typical split supply configuration is shown in Figure 49. DVDD ANALOG SUPPLY DIGITAL SUPPLY + – 10ms MIN 20 1k 2.5V MIN 10ms MIN ADuC816 POWER SUPPLY In either implementation, Port 0 (P0) serves as a multiplexed address/data bus. It emits the low byte of the data pointer (DPL) as an address, which is latched by a pulse of ALE prior to data being placed on the bus by the ADuC816 (write operation) or the SRAM (read operation). Port 2 (P2) provides the data pointer page byte (DPP) to be latched by ALE, followed by the data pointer high byte (DPH). If no latch is connected to P2, DPP is ignored by the SRAM, and the 8051 standard of 64 Kbyte external data memory access is maintained. 1.2V MAX ADuC816 POWER SUPPLY 1.2V MAX 10F 10F + – ADuC816 20 34 DVDD AVDD 5 0.1F 48 0.1F RESET 21 35 DGND AGND 6 47 Figure 46. External POR Timing The best way to implement an external POR function to meet the above requirements involves the use of a dedicated POR chip, such as the ADM809/ADM810 SOT-23 packaged PORs from Analog Devices. Recommended connection diagrams for both active-high ADM810 and active-low ADM809 PORs are shown in Figure 47 and Figure 48, respectively. REV. A REV. 0 –63– Figure 49. External Dual Supply Connections ADuC816 As an alternative to providing two separate power supplies, AVDD quiet by placing a small series resistor and/or ferrite bead between it and DVDD, and then decoupling AVDD separately to ground. An example of this configuration is shown in Figure 50. With this configuration other analog circuitry (such as op amps, voltage reference, etc.) can be powered from the AVDD supply line as well. DIGITAL SUPPLY + – 10F BEAD 1.6 10F ADuC816 20 34 DVDD AVDD 5 Asserting the RESET Pin (15) 0.1F Returns to normal mode all registers are set to their default state and program execution starts at the reset vector once the Reset pin is deasserted. 48 0.1F 21 35 47 In power-down mode, both the PLL and the clock to the core are stopped. The on-chip oscillator can be halted or can continue to oscillate depending on the state of the oscillator power-down bit (OSC_PD) in the PLLCON SFR. The TIC, being driven directly from the oscillator, can also be enabled during powerdown. All other on-chip peripherals however, are shut down. Port pins retain their logic levels in this mode, but the DAC output goes to a high-impedance state (three-state) while ALE and PSEN outputs are held low. During full power-down mode, the ADuC816 consumes a total of 5 μA typically. There are five ways of terminating power-down mode: DGND AGND 6 Cycling Power All registers are set to their default state and program execution starts at the reset vector. Figure 50. External Single Supply Connections Notice that in both Figure 49 and Figure 50, a large value (10 μF) reservoir capacitor sits on DVDD and a separate 10 μF capacitor sits on AVDD. Also, local small-value (0.1 μF) capacitors are located at each VDD pin of the chip. As per standard design practice, be sure to include all of these capacitors, and ensure the smaller capacitors are closest to each AVDD pin with trace lengths as short as possible. Connect the ground terminal of each of these capacitors directly to the underlying ground plane. Finally, it should also be noticed that, at all times, the analog and digital ground pins on the ADuC816 should be referenced to the same system ground reference point. Power Consumption The “CORE” values given represent the current drawn by DVDD, while the rest (“ADC” and “DAC”) are pulled by the AVDD pin and can be disabled in software when not in use. The other on-chip peripherals (watchdog timer, power supply monitor, etc.) consume negligible current and are therefore lumped in with the “CORE” operating current here. Of course, the user must add any currents sourced by the parallel and serial I/O pins, and that sourced by the DAC, in order to determine the total current needed at the ADuC816’s supply pins. Also, current draw from the DVDD supply will increase by approximately 5 mA during Flash/EE erase and program cycles Power-Saving Modes Setting the Idle and Power-Down Mode bits, PCON.0 and PCON.1 respectively, in the PCON SFR described in Table II, allows the chip to be switched from normal mode into idle mode, and also into full power-down mode. In idle mode, the oscillator continues to run, but the core clock generated from the PLL is halted. The on-chip peripherals continue to receive the clock, and remain functional. The CPU status is preserved with the stack pointer, program counter, and all other internal registers maintain their data during idle mode. Port pins and DAC output pins also retain their states, and ALE and PSEN outputs go high in this mode. The chip will recover from idle mode upon receiving any enabled interrupt, or on receiving a hardware reset. Time Interval Counter (TIC) Interrupt Power-down mode is terminated and the CPU services the TIC interrupt, the RETI at the end of the TIC Interrupt Service Routine will return the core to the instruction after that which enabled power down. I2C or SPI Interrupt Power-down mode is terminated and the CPU services the I2C/ SPI interrupt. The RETI at the end of the ISR will return the core to the instruction after that which enabled power down. It should be noted that the I2C/SPI power down interrupt enable bit (SERIPD) in the PCON SFR must first be set to allow this mode of operation. INT0 Interrupt Power-down mode is terminated and the CPU services the INT0 interrupt. The RETI at the end of the ISR will return the core to the instruction after that which enabled power-down. It should be noted that the INT0 power-down interrupt enable bit (INT0PD) in the PCON SFR must first be set to allow this mode of operation. Grounding and Board Layout Recommendations As with all high resolution data converters, special attention must be paid to grounding and PC board layout of ADuC816-based designs in order to achieve optimum performance from the ADCs and DAC. Although the ADuC816 has separate pins for analog and digital ground (AGND and DGND), the user must not tie these to two separate ground planes unless the two ground planes are connected together very close to the ADuC816, as illustrated in the simplified example of Figure 51a. In systems where digital and analog ground planes are connected together somewhere else (at the system’s power supply for example), they cannot be connected again near the ADuC816 since a ground loop would result. In these cases, tie the ADuC816’s AGND and DGND pins all to the analog ground plane, as illustrated in Figure 51b. In systems with only one ground plane, ensure that the digital and analog components are physically separated onto separate halves of the board such that digital return currents do not flow near analog circuitry and vice versa. The ADuC816 can then be placed between the digital and analog sections, as illustrated in Figure 51c. –64– REV. A REV. 0 ADuC816 OTHER HARDWARE CONSIDERATIONS A PLACE DIGITAL COMPONENTS HERE PLACE ANALOG COMPONENTS HERE AGND B DGND PLACE ANALOG COMPONENTS HERE PLACE DIGITAL COMPONENTS HERE AGND DGND To facilitate in-circuit programming, plus in-circuit debug and emulation options, users will want to implement some simple connection points in their hardware that will allow easy access to download, debug, and emulation modes. In-Circuit Serial Download Access Nearly all ADuC816 designs will want to take advantage of the in-circuit reprogrammability of the chip. This is accomplished by a connection to the ADuC816’s UART, which requires an external RS-232 chip for level translation if downloading code from a PC. Basic configuration of an RS-232 connection is illustrated in Figure 52 with a simple ADM202-based circuit. If users would rather not design an RS-232 chip onto a board, refer to the application note “uC006–A 4-Wire UART-to-PC Interface”1 for a simple (and zero-cost-per-board) method of gaining in-circuit serial download access to the ADuC816. NOTE 1 Application note uC006 is available at www.analog.com/microconverter C PLACE ANALOG COMPONENTS HERE PLACE DIGITAL COMPONENTS HERE GND Figure 51. System Grounding Schemes In all of these scenarios, and in more complicated real-life applications, keep in mind the flow of current from the supplies and back to ground. Make sure the return paths for all currents are as close as possible to the paths the currents took to reach their destinations. For example, do not power components on the analog side of Figure 51b with DVDD since that would force return currents from DVDD to flow through AGND. Also, try to avoid digital currents flowing under analog circuitry, which could happen if the user placed a noisy digital chip on the left half of the board in Figure 51c. Whenever possible, avoid large discontinuities in the ground plane(s) (such as are formed by a long trace on the same layer), since they force return signals to travel a longer path. And of course, make all connections to the ground plane directly, with little or no trace separating the pin from its via to ground. If the user plans to connect fast logic signals (rise/fall time < 5 ns) to any of the ADuC816’s digital inputs, add a series resistor to each relevant line to keep rise and fall times longer than 5 ns at the ADuC816 input pins. A value of 100 Ω or 200 Ω is usually sufficient to prevent high-speed signals from coupling capacitively into the ADuC816 and affecting the accuracy of ADC conversions. ADuC816 System Self-Identification In some hardware designs it may be an advantage for the software running on the ADuC816 target to identify the host MicroConverter. For example, code running on the ADuC816 may be used at future date to run on an ADuC816 MicroConverter host and the code may be required to operate differently. The CHIPID SFR is a read-only register located at SFR address C2 hex. The top nibble of this byte is set to “1” to designate an ADuC824 host. For an ADuC824 host, the CHIPID SFR will contain the value “0” in the upper nibble. REV. A REV. 0 In addition to the basic UART connections, users will also need a way to trigger the chip into download mode. This is accomplished via a 1 kΩ pull-down resistor that can be jumpered onto the PSEN pin, as shown in Figure 52. To get the ADuC816 into download mode, simply connect this jumper and powercycle the device (or manually reset the device, if a manual reset button is available) and it will be ready to receive a new program serially. With the jumper removed, the device will come up in normal mode (and run the program) whenever power is cycled or RESET is toggled. Note that PSEN is normally an output (as described in the External Memory Interface section) and it is sampled as an input only on the falling edge of RESET (i.e., at power-up or upon an external manual reset). Note also that if any external circuitry unintentionally pulls PSEN low during power-up or reset events, it could cause the chip to enter download mode and therefore fail to begin user code execution as it should. To prevent this, ensure that no external signals are capable of pulling the PSEN pin low, except for the external PSEN jumper itself. Embedded Serial Port Debugger From a hardware perspective, entry to serial port debug mode is identical to the serial download entry sequence described above. In fact, both serial download and serial port debug modes can be thought of as essentially one mode of operation used in two different ways. Note that the serial port debugger is fully contained on the ADuC816 device, (unlike “ROM monitor” type debuggers) and therefore no external memory is needed to enable in-system debug sessions. Single-Pin Emulation Mode Also built into the ADuC816 is a dedicated controller for single-pin in-circuit emulation (ICE) using standard production ADuC816 devices. In this mode, emulation access is gained by connection to a single pin, the EA pin. Normally, this pin is hardwired either high or low to select execution from internal or external program memory space, as described earlier. To enable single-pin emulation mode, however, users will need to pull the EA pin high through a 1 kΩ resistor as shown in Figure 52. The emulator will then connect to the 2-pin header also shown in Figure 52. To be compatible with the standard connector that –65– ADuC816 DOWNLOAD/DEBUG ENABLE JUMPER (NORMALLY OPEN) DVDD 1k DVDD 49 48 47 46 45 44 43 42 41 40 EA 50 PSEN 51 DVDD 52 DGND 1k 39 38 P1.2IEXC1/DAC 37 AVDD 36 AVDD 200A/400A EXCITATION CURRENT DGND AGND ADuC816 REFIN– VREF + VREF – AIN + DVDD 35 DVDD 34 XTAL2 33 XTAL1 32 REFIN+ R1 5.6k 2-PIN HEADER FOR EMULATION ACCESS (NORMALLY OPEN) P1.4/AIN1 31 P1.5/AIN2 30 32.766kHz DGND DVDD R2 510 TXD RESET AIN – RXD 29 RTD 28 27 DVDD ADM810 VCC NOT CONNECTED IN THIS EXAMPLE RST DVDD GND ADM202 C1+ V+ DVDD 9-PIN D-SUB FEMALE VCC GND 1 C1– T1OUT 2 C2+ R1IN 3 C2– R1OUT 4 V– T1IN 5 T2OUT T2IN 6 R2OUT 7 R2IN 8 9 Figure 52. Typical System Configuration comes with the single-pin emulator available from Accutron Limited (www.accutron.com), use a 2-pin 0.1-inch pitch “Friction Lock” header from Molex (www.molex.com) such as their part number 22-27-2021. Be sure to observe the polarity of this header. As represented in Figure 52, when the Friction Lock tab is at the right, the ground pin should be the lower of the two pins (when viewed from the top). Enhanced-Hooks Emulation Mode ADuC816 also supports enhanced-hooks emulation mode. An enhanced-hooks-based emulator is available from Metalink Corporation (www.metaice.com). No special hardware support for these emulators needs to be designed onto the board since these are “pod-style” emulators where users must replace the chip on their board with a header device that the emulator pod plugs into. The only hardware concern is then one of determining if adequate space is available for the emulator pod to fit into the system enclosure. Typical System Configuration A typical ADuC816 configuration is shown in Figure 52. It summarizes some of the hardware considerations discussed in the previous paragraphs. Figure 52 also includes connections for a typical analog measurement application of the ADuC816, namely an interface to an RTD (Resistive Temperature Device). The arrangement shown is commonly referred to as a 4-wire RTD configuration. Here, the on-chip excitation current sources are enabled to excite the sensor. An external differential reference voltage is generated by the current sourced through resistor R1. This current also flows directly through the RTD, which generates a differential voltage directly proportional to temperature. This differential voltage is routed directly to the positive and negative inputs of the primary ADC (AIN1, AIN2 respectively). A second external resistor, R2, is used to ensure that absolute analog input voltage on the negative input to the primary ADC stays within that specified for the ADuC816, i.e., AGND + 100 mV. –66– REV. A 0 REV. ADuC816 It should also be noted that variations in the excitation current do not affect the measurement system, as the input voltage from the RTD and reference voltage across R1 vary ratiometrically with the excitation current. Resistor R1 must, however, have a low temperature coefficient to avoid errors in the reference voltage over temperature. Download—In-Circuit Serial Downloader QUICKSTART DEVELOPMENT SYSTEM DeBug—In-Circuit Debugger The QuickStart Development System is a full featured, low cost development tool suite supporting the ADuC816. The system consists of the following PC-based (Windows-compatible) hardware and software development tools. Hardware: ADuC816 Evaluation Board, Plug-In Power Supply and Serial Port Cable Code Development: 8051 Assembler C Compiler (2 Kcode Limited) Code Functionality: ADSIM, Windows MicroConverter Code Simulator In-Circuit Code Download: Serial Downloader In-Circuit Debugger: Serial Port Debugger Misc. Other: CD-ROM Documentation and Two Additional Prototype Devices Figures 53 shows the typical components of a QuickStart Development System while Figure 54 shows a typical debug session. A brief description of some of the software tools’ components in the QuickStart Development System is given below. The Serial Downloader is a software program that allows the user to serially download an assembled program (Intel Hex format file) to the on-chip program FLASH memory via the serial COM1 port on a standard PC. An Application Note (uC004) detailing this serial download protocol is available from www.analog.com/ microconverter. The Debugger is a Windows application that allows the user to debug code execution on silicon using the MicroConverter UART serial port. The debugger provides access to all on-chip peripherals during a typical debug session as well as single-step and break-point code execution control. ADSIM—Windows Simulator The Simulator is a Windows application that fully simulates all the MicroConverter functionality including ADC and DAC peripherals. The simulator provides an easy-to-use, intuitive, interface to the MicroConverter functionality and integrates many standard debug features; including multiple breakpoints, single stepping; and code execution trace capability. This tool can be used both as a tutorial guide to the part as well as an efficient way to prove code functionality before moving to a hardware platform. The QuickStart development tool-suite software is freely available at the Analog Devices MicroConverter Website www.analog.com/microconverter. Figure 54. Typical Debug Session Figure 53. Components of the QuickStart Development System REV. 0 REV. A –67– ADuC816 OUTLINE DIMENSIONS 1.03 0.88 0.73 14.15 13.90 SQ 13.65 2.45 MAX 39 27 40 SEATING PLANE 26 7.80 REF TOP VIEW 2.10 2.00 1.95 10.20 10.00 SQ 9.80 (PINS DOWN) 10° 6° 2° 0.23 0.11 VIEW A PIN 1 52 7° 0° 0.25 MIN 14 1 13 0.10 COPLANARITY 0.38 0.22 LEAD WIDTH 0.65 BSC LEAD PITCH VIEW A ROTATED 90° CCW COMPLIANT TO JEDEC STANDARDS MO-112-AC-1 Figure 55. 52-Lead Metric Quad Flat Package [MQFP] (S-52-2) Dimensions shown in millimeters 8.00 BSC SQ 0.30 0.23 0.18 0.60 MAX 0.60 MAX PIN 1 INDICATOR TOP VIEW PIN 1 INDICATOR 56 43 42 1 6.25 6.10 SQ 5.95 EXPOSED PAD (BOTTOM VIEW) 7.75 BSC SQ 0.50 0.40 0.30 29 28 15 14 0.25 MIN 0.80 MAX 0.65 TYP 12° MAX SEATING PLANE 0.50 BSC 0.05 MAX 0.02 NOM COPLANARITY 0.08 0.20 REF FOR PROPER CONNECTION OF THE EXPOSED PAD, REFER TO THE PIN FUNCTION DESCRIPTIONS SECTION OF THIS DATA SHEET. 030509-A 1.00 0.85 0.80 6.50 REF COMPLIANT TO JEDEC STANDARDS MO-220-VLLD-2 Figure 56. 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 8 mm × 8 mm Body, Very Thin Quad (CP-56-1) Dimensions shown in millimeters ORDERING GUIDE Model1 ADuC816BSZ ADuC816BSZ-REEL ADuC816BCPZ ADuC816BCPZ-REEL 1 Temperature Range –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C Package Description 52-Lead Metric Quad Flat Package [MQFP] 52-Lead Metric Quad Flat Package [MQFP] 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ] Package Option S-52-2 S-52-2 CP-56-1 CP-56-1 Ordering Quantity 1,000 1,000 Z = RoHS Compliant Part. ©2001–2010 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D00436-0-1/10(A) –68– REV. A