Datasheet ADE9078 (Analog Devices) - 4
| Hersteller | Analog Devices |
| Beschreibung | High Performance, Polyphase Energy Metering AFE |
| Seiten / Seite | 107 / 4 — ADE9078. Data Sheet. SPECIFICATIONS. Table 1.1. Parameter. Min. Typ. Max. … |
| Dateiformat / Größe | PDF / 1.9 Mb |
| Dokumentensprache | Englisch |
ADE9078. Data Sheet. SPECIFICATIONS. Table 1.1. Parameter. Min. Typ. Max. Unit. Test Conditions/Comments
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ADE9078 Data Sheet SPECIFICATIONS
VDD = 2.7 V to 3.63 V, GND = AGND = DGND = 0 V, on-chip reference, CLKIN = 12.288 MHz crystal (XTAL), TMIN to TMAX = −40°C to +85°C for minimum and maximum specifications, TA = 25°C (typical) for typical specifications.
Table 1.1 Parameter Min Typ Max Unit Test Conditions/Comments
ACCURACY Measurement error per phase Total Active Energy 0.1 % Over a dynamic range of 5000 to 1, 10 sec accumulation; gain compensation only 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation; gain compensation only Total Reactive Energy 0.1 % Over a dynamic range of 5000 to 1, 10 sec accumulation; gain compensation only 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation; gain compensation only Total Apparent Energy 0.1 % Over a dynamic range of 1000 to 1, 2 sec accumulation 0.5 % Over a dynamic range of 5000 to 1, 10 sec accumulation Fundamental Reactive 0.1 % Over a dynamic range of 5000 to 1, 2 sec accumulation 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation IRMS, VRMS 0.1 % Over a dynamic range of 1000 to 1 0.5 % Over a dynamic range of 5000 to 1 Active Power, VAR 0.2 % Over a dynamic range of 5000 to 1, 1 sec accumulation Power Factor (PF) ±0.001 Over a dynamic range of 5000 to 1 64-Point per Line Cycle 0.1 % An FFT is performed to receive the magni- Resampled Data tude response; this error is the worst case error in the fundamental magnitude caused by resampling algorithm distortion; input signal is 50 Hz fundamental on voltage channel and fundamental with ninth har- monic at half of full scale on current channel 0.3 % An FFT is performed to receive the magni- tude response; this error is the magnitude error of ninth harmonic caused by the resampling algorithm distortion input signal is 50 Hz fundamental with ninth harmonic at half of ful scale on current channel −72 dB Amplitude of highest spur; input signal is 50 Hz fundamental and ninth harmonic at half of full scale on the current channel 3 % An FFT is performed to receive the magni- tude response; this error is the magnitude error of 31st harmonic caused by resampling algorithm distortion; input signal is 50 Hz fundamental with 31st harmonic at half of full scale on the current channel −38 dB Amplitude of highest spur; input signal is 50 Hz fundamental and 31st harmonic at half of full scale on the current channel Line Period Measurement 0.001 Hz Resolution at 50 Hz Current to Current, Voltage to 0.036 Degrees Resolution at 50 Hz; voltage and current Voltage, and Voltage to at 1/10th of full scale Current Angle Measurement PSM1 IRMS 0.2 % Accuracy achieved 40 ms after entering PSM1 mode at 600:1 Rev. 0 | Page 4 of 107 Document Outline FEATURES APPLICATIONS GENERAL DESCRIPTION FUNCTIONAL BLOCK DIAGRAM TABLE OF CONTENTS REVISION HISTORY SPECIFICATIONS TIMING CHARACTERISTICS ABSOLUTE MAXIMUM RATINGS THERMAL RESISTANCE ESD CAUTION PIN CONFIGURATION AND FUNCTION DESCRIPTIONS TYPICAL PERFORMANCE CHARACTERISTICS TOTAL ENERGY LINEARITY OVER SUPPLY AND TEMPERATURE FUNDAMENTAL ENERGY LINEARITY WITH FIFTH HARMONIC OVER SUPPLY AND TEMPERATURE TOTAL ENERGY ERROR OVER FREQUENCY RMS LINEARITY OVER TEMPERATURE AND RMS ERROR OVER FREQUENCY ENERGY LINEARITY REPEATABILITY TOTAL ENERGY AND RMS LINEARITY WITH INTEGRATOR ON TOTAL ENERGY ERROR OVER FREQUENCY WITH INTEGRATOR ON TEST CIRCUIT TERMINOLOGY THEORY OF OPERATION ADC Overview Analog Input Configuration Fully Differential Inputs Interfacing to Current and Voltage Sensors Internal RF Immunity Filter Modes of Operation Output Data Rates and Format Voltage Reference CRYSTAL OSCILLATOR/EXTERNAL CLOCK Crystal Selection Load Capacitor Calculation Load Capacitor Calculation Example POWER MANAGEMENT Power Modes Power-On Sequence Brownout Detection Reset Changing to PSM2 or PSM3 MEASUREMENTS (NORMAL MODE) Current Channel Current Channel Measurement Update Rates ADC_REDIRECT Multiplexer Current Channel Gain, xIGAIN IB Calculation Using ICONSEL High-Pass Filter Digital Integrator Phase Compensation Multipoint Gain and Phase Calibration Multipoint Gain and Phase Single-Point Gain and Phase Voltage Channel Voltage Channel Measurements Voltage Channel Gain Energy Measurements Overview Per Phase Energy Measurements Update Rate Power-Based and Filter-Based RMS Measurement Algorithms Filter-Based Total RMS Neutral Current RMS, RMS of Sum of Instantaneous Currents Total Active Power Total Reactive Power Total Apparent Power Fundamental Reactive Power Power Factor Energy Accumulation Signed Energy Accumulation Modes Total Active Energy Accumulation Modes Reactive Energy Accumulation Modes No Load Detection No Load Indications Energy Accumulation Details Internal Energy Register Overflow Rate User Energy Register Update Rate, EGYRDY Reloading or Accumulating User Energy Register User Energy Register Overflow Rate Accessing the User Energy Registers Read User Energy Register with Reset User Energy Register Use Models Digital to Frequency Conversion—CFx Output Energy and Phase Selection Configuring the Maximum CF Pulse Output Frequency Configuring the CF Pulse Width CFx Pulse Sign Clearing the CFx Accumulator Disabling the CFx Pulse Output and CFx Interrupt MEASUREMENTS (PSM1) Overview IRMS, VRMS, and Active Power VAR PSM1 Startup Flow from PSM2 and PSM3 PSM1 Startup Flow from PSM0 Power Accumulation Power Accumulation Details Accessing the User Power Registers Power Sign Detection Zero-Crossing Detection Combined Voltage Zero Crossing Zero-Crossing Output Rates Zero-Crossing Timeout Line Period Calculation Angle Measurement Phase Sequence Error Detection 4-Wire Wye and 4-Wire Delta 3-Wire Delta Peak Detection MEASUREMENTS (PSM2) Overview Low Power Comparator KEY FEATURES FLEXIBLE WAVEFORM BUFFER WITH RESAMPLING MULTIPOINT PHASE/GAIN CALIBRATION RMS OF SUM OF INSTANTANEOUS CURRENTS MEASUREMENT TAMPER MODES POWER FACTOR ZERO-CROSSING TIMEOUT DETECTION LINE PERIOD MEASUREMENT ANGLE MEASUREMENT PHASE SEQUENCE ERROR DETECTION QUICK START APPLICATIONS INFORMATION NON-BLONDEL COMPLIANT METERS APPLYING THE ADE9078 TO A 4-WIRE WYE SERVICE APPLYING THE ADE9078 TO A 3-WIRE DELTA SERVICE APPLYING THE ADE9078 TO A NON-BLONDEL COMPLIANT, 4-WIRE WYE SERVICE APPLYING THE ADE9078 TO A NON-BLONDEL COMPLIANT, 4-WIRE DELTA SERVICE SERVICE TYPE SUMMARY ACCESSING ON-CHIP DATA SPI PROTOCOL OVERVIEW SPI WRITE SPI READ SPI BURST READ SPI PROTOCOL CRC CRC Algorithm ADDITIONAL COMMUNICATION VERIFICATION REGISTERS CRC OF CONFIGURATION REGISTERS CONFIGURATION LOCK WAVEFORM BUFFER FIXED DATA RATE WAVEFORMS Waveform Buffer Filling Indication—Fixed Data Rate Samples FIXED DATA RATE WAVEFORMS FILLING AND TRIGGER-BASED MODES Stop When Buffer Is Full Mode Continuous Fill Mode Stop Filling on Trigger Center Capture Around Trigger Save Event Address and Keep Filling RESAMPLED WAVEFORMS CONFIGURING THE WAVEFORM BUFFER BURST READ WAVEFORM BUFFER SAMPLES FROM SPI Example 1: Fixed Data Rate Data, Seven Channel Samples Example 2: Resampled Data, Phase C (I and V Samples) Example 3: Fixed Data Rate Data, Single Address Read Mode Example 4: Resampled Data, Single Address Read Mode SPI CRC when Reading the Waveform Buffer SPI Last Data Register when Reading the Waveform Buffer INTERRUPTS/EVENTS INTERRUPTS (IRQ0\ AND IRQ1\) EVENT\ STATUS BITS IN ADDITIONAL REGISTERS No Load TROUBLESHOOTING SPI DOES NOT WORK PSM2_CFG REGISTER VALUE IS NOT RETAINED WHEN GOING FROM PSM2 OR PSM3 TO PSM0 REGISTER INFORMATION REGISTER DETAILS OUTLINE DIMENSIONS ORDERING GUIDE
ADE9078 Data Sheet SPECIFICATIONS
VDD = 2.7 V to 3.63 V, GND = AGND = DGND = 0 V, on-chip reference, CLKIN = 12.288 MHz crystal (XTAL), TMIN to TMAX = −40°C to +85°C for minimum and maximum specifications, TA = 25°C (typical) for typical specifications.
Table 1.1 Parameter Min Typ Max Unit Test Conditions/Comments
ACCURACY Measurement error per phase Total Active Energy 0.1 % Over a dynamic range of 5000 to 1, 10 sec accumulation; gain compensation only 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation; gain compensation only Total Reactive Energy 0.1 % Over a dynamic range of 5000 to 1, 10 sec accumulation; gain compensation only 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation; gain compensation only Total Apparent Energy 0.1 % Over a dynamic range of 1000 to 1, 2 sec accumulation 0.5 % Over a dynamic range of 5000 to 1, 10 sec accumulation Fundamental Reactive 0.1 % Over a dynamic range of 5000 to 1, 2 sec accumulation 0.2 % Over a dynamic range of 10,000 to 1, 20 sec accumulation IRMS, VRMS 0.1 % Over a dynamic range of 1000 to 1 0.5 % Over a dynamic range of 5000 to 1 Active Power, VAR 0.2 % Over a dynamic range of 5000 to 1, 1 sec accumulation Power Factor (PF) ±0.001 Over a dynamic range of 5000 to 1 64-Point per Line Cycle 0.1 % An FFT is performed to receive the magni- Resampled Data tude response; this error is the worst case error in the fundamental magnitude caused by resampling algorithm distortion; input signal is 50 Hz fundamental on voltage channel and fundamental with ninth har- monic at half of full scale on current channel 0.3 % An FFT is performed to receive the magni- tude response; this error is the magnitude error of ninth harmonic caused by the resampling algorithm distortion input signal is 50 Hz fundamental with ninth harmonic at half of ful scale on current channel −72 dB Amplitude of highest spur; input signal is 50 Hz fundamental and ninth harmonic at half of full scale on the current channel 3 % An FFT is performed to receive the magni- tude response; this error is the magnitude error of 31st harmonic caused by resampling algorithm distortion; input signal is 50 Hz fundamental with 31st harmonic at half of full scale on the current channel −38 dB Amplitude of highest spur; input signal is 50 Hz fundamental and 31st harmonic at half of full scale on the current channel Line Period Measurement 0.001 Hz Resolution at 50 Hz Current to Current, Voltage to 0.036 Degrees Resolution at 50 Hz; voltage and current Voltage, and Voltage to at 1/10th of full scale Current Angle Measurement PSM1 IRMS 0.2 % Accuracy achieved 40 ms after entering PSM1 mode at 600:1 Rev. 0 | Page 4 of 107 Document Outline FEATURES APPLICATIONS GENERAL DESCRIPTION FUNCTIONAL BLOCK DIAGRAM TABLE OF CONTENTS REVISION HISTORY SPECIFICATIONS TIMING CHARACTERISTICS ABSOLUTE MAXIMUM RATINGS THERMAL RESISTANCE ESD CAUTION PIN CONFIGURATION AND FUNCTION DESCRIPTIONS TYPICAL PERFORMANCE CHARACTERISTICS TOTAL ENERGY LINEARITY OVER SUPPLY AND TEMPERATURE FUNDAMENTAL ENERGY LINEARITY WITH FIFTH HARMONIC OVER SUPPLY AND TEMPERATURE TOTAL ENERGY ERROR OVER FREQUENCY RMS LINEARITY OVER TEMPERATURE AND RMS ERROR OVER FREQUENCY ENERGY LINEARITY REPEATABILITY TOTAL ENERGY AND RMS LINEARITY WITH INTEGRATOR ON TOTAL ENERGY ERROR OVER FREQUENCY WITH INTEGRATOR ON TEST CIRCUIT TERMINOLOGY THEORY OF OPERATION ADC Overview Analog Input Configuration Fully Differential Inputs Interfacing to Current and Voltage Sensors Internal RF Immunity Filter Modes of Operation Output Data Rates and Format Voltage Reference CRYSTAL OSCILLATOR/EXTERNAL CLOCK Crystal Selection Load Capacitor Calculation Load Capacitor Calculation Example POWER MANAGEMENT Power Modes Power-On Sequence Brownout Detection Reset Changing to PSM2 or PSM3 MEASUREMENTS (NORMAL MODE) Current Channel Current Channel Measurement Update Rates ADC_REDIRECT Multiplexer Current Channel Gain, xIGAIN IB Calculation Using ICONSEL High-Pass Filter Digital Integrator Phase Compensation Multipoint Gain and Phase Calibration Multipoint Gain and Phase Single-Point Gain and Phase Voltage Channel Voltage Channel Measurements Voltage Channel Gain Energy Measurements Overview Per Phase Energy Measurements Update Rate Power-Based and Filter-Based RMS Measurement Algorithms Filter-Based Total RMS Neutral Current RMS, RMS of Sum of Instantaneous Currents Total Active Power Total Reactive Power Total Apparent Power Fundamental Reactive Power Power Factor Energy Accumulation Signed Energy Accumulation Modes Total Active Energy Accumulation Modes Reactive Energy Accumulation Modes No Load Detection No Load Indications Energy Accumulation Details Internal Energy Register Overflow Rate User Energy Register Update Rate, EGYRDY Reloading or Accumulating User Energy Register User Energy Register Overflow Rate Accessing the User Energy Registers Read User Energy Register with Reset User Energy Register Use Models Digital to Frequency Conversion—CFx Output Energy and Phase Selection Configuring the Maximum CF Pulse Output Frequency Configuring the CF Pulse Width CFx Pulse Sign Clearing the CFx Accumulator Disabling the CFx Pulse Output and CFx Interrupt MEASUREMENTS (PSM1) Overview IRMS, VRMS, and Active Power VAR PSM1 Startup Flow from PSM2 and PSM3 PSM1 Startup Flow from PSM0 Power Accumulation Power Accumulation Details Accessing the User Power Registers Power Sign Detection Zero-Crossing Detection Combined Voltage Zero Crossing Zero-Crossing Output Rates Zero-Crossing Timeout Line Period Calculation Angle Measurement Phase Sequence Error Detection 4-Wire Wye and 4-Wire Delta 3-Wire Delta Peak Detection MEASUREMENTS (PSM2) Overview Low Power Comparator KEY FEATURES FLEXIBLE WAVEFORM BUFFER WITH RESAMPLING MULTIPOINT PHASE/GAIN CALIBRATION RMS OF SUM OF INSTANTANEOUS CURRENTS MEASUREMENT TAMPER MODES POWER FACTOR ZERO-CROSSING TIMEOUT DETECTION LINE PERIOD MEASUREMENT ANGLE MEASUREMENT PHASE SEQUENCE ERROR DETECTION QUICK START APPLICATIONS INFORMATION NON-BLONDEL COMPLIANT METERS APPLYING THE ADE9078 TO A 4-WIRE WYE SERVICE APPLYING THE ADE9078 TO A 3-WIRE DELTA SERVICE APPLYING THE ADE9078 TO A NON-BLONDEL COMPLIANT, 4-WIRE WYE SERVICE APPLYING THE ADE9078 TO A NON-BLONDEL COMPLIANT, 4-WIRE DELTA SERVICE SERVICE TYPE SUMMARY ACCESSING ON-CHIP DATA SPI PROTOCOL OVERVIEW SPI WRITE SPI READ SPI BURST READ SPI PROTOCOL CRC CRC Algorithm ADDITIONAL COMMUNICATION VERIFICATION REGISTERS CRC OF CONFIGURATION REGISTERS CONFIGURATION LOCK WAVEFORM BUFFER FIXED DATA RATE WAVEFORMS Waveform Buffer Filling Indication—Fixed Data Rate Samples FIXED DATA RATE WAVEFORMS FILLING AND TRIGGER-BASED MODES Stop When Buffer Is Full Mode Continuous Fill Mode Stop Filling on Trigger Center Capture Around Trigger Save Event Address and Keep Filling RESAMPLED WAVEFORMS CONFIGURING THE WAVEFORM BUFFER BURST READ WAVEFORM BUFFER SAMPLES FROM SPI Example 1: Fixed Data Rate Data, Seven Channel Samples Example 2: Resampled Data, Phase C (I and V Samples) Example 3: Fixed Data Rate Data, Single Address Read Mode Example 4: Resampled Data, Single Address Read Mode SPI CRC when Reading the Waveform Buffer SPI Last Data Register when Reading the Waveform Buffer INTERRUPTS/EVENTS INTERRUPTS (IRQ0\ AND IRQ1\) EVENT\ STATUS BITS IN ADDITIONAL REGISTERS No Load TROUBLESHOOTING SPI DOES NOT WORK PSM2_CFG REGISTER VALUE IS NOT RETAINED WHEN GOING FROM PSM2 OR PSM3 TO PSM0 REGISTER INFORMATION REGISTER DETAILS OUTLINE DIMENSIONS ORDERING GUIDE