Digital Power Factor Correction Controller with Accurate AC Power Metering ADP1048W Data Sheet FEATURES GENERAL DESCRIPTION Qualified for automotive applications Flexible digital power factor correction (PFC) controller Interleaved and bridgeless operation True rms ac power metering Enhanced dynamic response Optimized light load efficiency performance Output voltage adjustment Frequency reduction Inrush current control Switching frequency spread spectrum for improved EMI External frequency synchronization PMBus compliant Programmable ac line fault detection and protection Programmable output fault detection and protection Extensive fault protection for high reliability systems Frequency range from 30 kHz to 400 kHz 8 kB EEPROM Programming via easy-to-use graphical user interface (GUI) The ADP1048W is a digital power factor correction (PFC) controller that provides accurate input power metering capability and inrush current control for ac/dc systems. The device is designed for single phase PFC applications, especially interleaved and bridgeless PFC applications. APPLICATIONS The digital PFC function is based on a conventional boost PFC with multiplication of the output voltage feedback combined with the input current and voltage to provide optimum harmonic correction and power factor for ac/dc systems. All signals are converted into the digital domain to provide maximum flexibility; all key parameters can be reported and adjusted via the PMBus™ interface. The ADP1048W allows users to optimize system performance, maximize efficiency across the load range, and reduce design time to market. The ADP1048W provides accurate rms measurement of input voltage, current, and power. This information can be reported to the microcontroller of the power supply via the PMBus interface. 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Technical Support www.analog.com ADP1048W Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 Frequency Dithering (Spread Spectrum) ................................ 30 Applications ....................................................................................... 1 PWM Frequency Synchronization ........................................... 30 General Description ......................................................................... 1 Smart Output Voltage (Load Line) .......................................... 30 Revision History ............................................................................... 4 Smart Switching Frequency ...................................................... 31 Typical Applications Circuit ....................................................... 5 Current Loop Filter for Light Load .......................................... 31 Specifications..................................................................................... 6 Phase Shedding ........................................................................... 31 Absolute Maximum Ratings ............................................................ 9 Current Loop Feedforward ....................................................... 31 Thermal Resistance ...................................................................... 9 Bridgeless Boost Operation....................................................... 32 ESD Caution .................................................................................. 9 Power Supply System Calibration and Trim ............................... 33 Pin Configuration and Function Descriptions ........................... 10 Output Voltage (VFB) Calibration and Trim ......................... 33 Functional Block Diagram ............................................................ 11 Input Voltage (VAC) Gain and Offset Trim............................ 33 Controller Architecture ................................................................. 12 Current Sense Gain and Offset Trim ....................................... 33 Current Sense .............................................................................. 12 Input Power Gain and Offset Trim .......................................... 33 RMS Input Overcurrent Protection ......................................... 12 PMBus Digital Communication ................................................... 34 Fast Overcurrent Protection (ILIM Pin) ................................. 12 Features ........................................................................................ 34 Current Balancing ...................................................................... 14 Overview ..................................................................................... 34 Voltage Sense ............................................................................... 14 PMBus Address .......................................................................... 34 Overvoltage Protection .............................................................. 15 Data Transfer............................................................................... 35 Power Factor Correction Control Loop ...................................... 17 General Call Support ................................................................. 36 Digital Compensation Filters .................................................... 17 Fast Mode .................................................................................... 36 Pulse-Width Modulation........................................................... 18 Fault Conditions ......................................................................... 36 Duty Cycle Minimum/Maximum Limits ................................ 18 Timeout Condition .................................................................... 36 Switching Frequency Programming ........................................ 19 Data Transmission Faults .......................................................... 37 Line Fault Protections and Soft Start Sequencing ...................... 20 Data Content Faults ................................................................... 37 PSON Operation ........................................................................ 20 EEPROM ......................................................................................... 38 AC Line Detection ...................................................................... 20 Overview ..................................................................................... 38 Soft Start Procedure ................................................................... 22 Page Erase Operation ................................................................. 38 Line Fault Protections ................................................................ 22 Read Operation (Byte Read and Block Read) ........................ 38 Advanced Input Power Metering.................................................. 24 Write Operation (Byte Write and Block Write) ..................... 39 Power Supply System and Fault Monitoring ............................... 25 EEPROM Password .................................................................... 39 Flag Conventions ........................................................................ 25 Downloading EEPROM Settings to Internal Registers ......... 39 Manufacturer-Specific Flags ..................................................... 25 Saving Register Settings into EEPROM .................................. 40 Standard PMBus Flags ............................................................... 26 EEPROM CRC Checksum ........................................................ 40 PMBus Fault Flag Response ...................................................... 27 Software GUI .................................................................................. 41 Manufacturer-Specific Flag Response ..................................... 28 Standard PMBus Commands Supported by the ADP1048W .. 42 Monitoring Functions ................................................................ 29 Manufacturer-Specific PMBus Commands ................................ 43 First Error Fault .......................................................................... 29 Detailed Register Descriptions ..................................................... 45 Overtemperature Protection (OTP) ........................................ 29 OPERATION Register ............................................................... 45 AC_OK and PGOOD Signals ................................................... 29 ON_OFF_CONFIG Register .................................................... 45 Advanced Features.......................................................................... 30 CLEAR_FAULTS Command .................................................... 45 Rev. 0 | Page 2 of 82 Data Sheet ADP1048W WRITE_PROTECT Register .....................................................45 RESTORE_DEFAULT_ALL Command ..................................45 EEPROM_DATA_00 Through EEPROM_DATA_15 Commands................................................................................... 56 STORE_USER_ALL Command................................................45 EEPROM_CRC_CHKSUM Register ....................................... 56 RESTORE_USER_ALL Command ..........................................46 EEPROM_NUM_RD_BYTES Register ................................... 56 CAPABILITY Register ...............................................................46 EEPROM_ADDR_OFFSET Register ....................................... 56 VOUT_MODE Register .............................................................46 EEPROM_PAGE_ERASE Register ........................................... 57 VOUT_COMMAND Register ..................................................46 EEPROM_PASSWORD Register .............................................. 57 VOUT_SCALE_LOOP Register ...............................................46 TRIM_PASSWORD Register .................................................... 57 VOUT_SCALE_MONITOR Register ......................................46 EEPROM_INFO Command ..................................................... 57 VIN_ON Register........................................................................47 CS_FAST_OCP_RESPONSE Register ..................................... 57 VIN_OFF Register ......................................................................47 OVP_FAST_OVP_RESPONSE Register ................................. 58 VOUT_OV_FAULT_LIMIT Register ......................................47 OLP_RESPONSE Register ......................................................... 58 VOUT_OV_FAULT_RESPONSE Register .............................47 VDD3P3_RESPONSE Register ................................................. 58 VOUT_OV_WARN_LIMIT Register ......................................48 VCORE_RESPONSE Register................................................... 59 VOUT_UV_WARN_LIMIT Register ......................................48 PGOOD_AC_OK_DEBOUNCE_SET Register ..................... 59 VOUT_UV_FAULT_LIMIT Register ......................................48 PSON_SET Register ................................................................... 60 VOUT_UV_FAULT_RESPONSE Register .............................49 FLAG_FAULT_ID Register ....................................................... 60 OT_FAULT_RESPONSE Register ............................................49 SOFTSTART_FLAGS_BLANK1 Register ............................... 60 VIN_OV_FAULT_LIMIT Register...........................................50 SOFTSTART_FLAGS_BLANK2 Register ............................... 61 VIN_OV_FAULT_RESPONSE Register ..................................50 PGOOD_FLAGS_LIST Register............................................... 61 VIN_UV_WARN_LIMIT Register...........................................51 AC_OK_FLAGS_LIST Register ................................................ 61 VIN_UV_FAULT_LIMIT Register ..........................................51 PWM and PWM2 Timing Registers ........................................ 61 VIN_UV_FAULT_RESPONSE Register ..................................52 PWM_SET Register .................................................................... 63 IIN_OC_FAULT_LIMIT Register ............................................52 PWM_LIMIT Register ............................................................... 63 IIN_OC_FAULT_RESPONSE Register ...................................53 RTD ADC Offset Trim Setting (MSB) Register ...................... 63 IIN_OC_WARN_LIMIT Register ............................................53 RTD ADC Offset Trim Setting (LSB) Register ....................... 63 PIN_OP_WARN_LIMIT Register ............................................54 RTD ADC Gain Trim Setting Register .................................... 63 STATUS_BYTE Register ............................................................54 OT_FAULT_LIMIT Register ..................................................... 64 STATUS_WORD Register .........................................................54 OT_WARN_LIMIT Register ..................................................... 64 STATUS_VOUT Register...........................................................54 Switching Frequency Setting Register ...................................... 65 STATUS_INPUT Register .........................................................55 Low Power Switching Frequency Setting Register ................. 66 STATUS_TEMPERATURE Register ........................................55 Frequency Dithering Set Register ............................................. 67 READ_VIN Register...................................................................55 Frequency Synchronization Set Register ................................. 68 READ_IIN Register ....................................................................55 Voltage Loop Filter Gain Register............................................. 68 READ_VOUT Register ..............................................................55 Voltage Loop Filter Zero Register ............................................. 68 READ_PIN Register ...................................................................56 Fast Voltage Loop Filter Gain Register..................................... 68 PMBUS_REVISION Register ....................................................56 Fast Voltage Loop Filter Zero Register ..................................... 68 MFR_ID Register ........................................................................56 Fast Voltage Loop Enable Register............................................ 68 MFR_MODEL Register ..............................................................56 VAC_THRESHOLD_SET Register .......................................... 69 MFR_REVISION Register .........................................................56 VAC_THRESHOLD_READ Register ...................................... 69 MIN_AC_PERIOD_SET Register ............................................ 69 Rev. 0 | Page 3 of 82 ADP1048W Data Sheet MAX_AC_PERIOD_SET Register .......................................... 69 Smart VOUT High Line (VOH2) Register ............................. 76 Current Loop Filter Gain for Low Line Input Register ......... 70 Smart VOUT Upper Limit (VOH) Register ........................... 76 Current Loop Filter Zero for Low Line Input Register ......... 70 Smart VOUT Super High Line Register .................................. 76 Current Loop Filter Gain for High Line Input Register ........ 70 SYNC Delay Register ................................................................. 76 Current Loop Filter Zero for High Line Input Register ........ 70 SMART_VOUT_SUPER_HIGH_LINE_HYS Register ........ 76 Soft Start Set Register ................................................................. 70 POWER_HYS Register .............................................................. 77 Inrush Set Register ..................................................................... 71 Advanced Feature Enable Register........................................... 77 FAST_OVP_FAULT_RISE Register ......................................... 71 VOUT_OV_FAULT_HYS Register ......................................... 77 FAST_OVP_FAULT_FALL Register ........................................ 71 VIN_UV_FAULT_HYS Register.............................................. 77 FAST OVP Debounce Time Setting Register ......................... 71 VAC ADC Offset Trim Register ............................................... 77 Low Power Mode Operation Threshold Register .................. 72 CS ADC Offset Trim for 500 mV Range Register ................. 78 Power Metering Offset Trim for Low Line Input Register .... 72 CS ADC Gain Trim for High (750 mV) Range Register....... 78 Power Metering Gain Trim for Low Line Input Register ...... 72 CS ADC Offset Trim for High (750 mV) Range Register .... 78 High Line Limit Register ........................................................... 72 Latched Flag Registers ............................................................... 78 Low Line Limit Register ............................................................ 72 PWM Value Register .................................................................. 79 ILIM_TRIM Register ................................................................. 72 VAC_LINE_PERIOD Register ................................................. 79 Voltage Loop Output Register .................................................. 72 Read Temperature ADC Register ............................................. 79 Exponent Register ...................................................................... 73 Power Metering Offset Trim for High Line Input Register .. 79 Read Update Rate Register ........................................................ 73 Power Metering Gain Trim for High Line Input Register .... 79 VIN Scale Monitor Register ...................................................... 73 Current Loop Filter Gain for Low Line Input and Light Load Register ........................................................................................ 79 IIN_GSENSE Register ............................................................... 73 CS Fast OCP Blank Register ..................................................... 74 CS Fast OCP Setting Register ................................................... 74 Temperature Hysteresis Register .............................................. 74 VAC ADC Gain Trim Register ................................................. 75 Current Loop Filter Zero for Low Line Input and Light Load Register ........................................................................................ 80 Current Loop Filter Gain for High Line Input and Light Load Register ........................................................................................ 80 VFB ADC Gain Trim Register .................................................. 75 Current Loop Filter Zero for High Line Input and Light Load Register ........................................................................................ 80 CS ADC Gain Trim for 500 mV Range Register .................... 75 Smart VOUT Power Reading Register .................................... 80 IBAL Gain Register .................................................................... 75 IBAL Configuration Register .................................................... 80 Smart VOUT Low Power Threshold (P1) Register ............... 75 Debug Flag Registers.................................................................. 80 Smart VOUT High Power Threshold (P2) Register .............. 75 Outline Dimensions ....................................................................... 82 Smart VOUT Low Line (VOL1) Register................................ 76 Ordering Guide .......................................................................... 82 Smart VOUT Low Line (VOL2) Register................................ 76 Automotive Products ................................................................. 82 Smart VOUT High Line (VOH1) Register ............................. 76 REVISION HISTORY 8/14—Revision 0: Initial Version Rev. 0 | Page 4 of 82 Data Sheet ADP1048W circuitry: independent overvoltage protection (OVP) and overcurrent protection (OCP), ground continuity monitoring, and ac sensing. Internal overtemperature protection (OTP) is provided whereby the external temperature can be recorded via an external sensing device. The combination of a flexible, digitally controlled PFC engine and accurate input power metering facilitates the adoption of intelligent power management systems that are capable of making decisions to improve end-user system efficiency. The device supports additional efficiency improvements through programmable frequency reduction at light load and the capability to reduce the output voltage at light load. The internal 8 kB EEPROM stores all programmed values and allows standalone control without a microcontroller. All parametric reporting and adjustments can be programmed via an easy-to-use GUI. No complex programming is required. The ADP1048W provides enhanced integrated features and functions; the inrush current and soft start control functions provide significant component count reduction with easy design optimization. The ADP1048W operates from a single 3.3 V supply. The device is available in a 24-lead QSOP package that is specified over an ambient temperature range of −40°C to +125°C. The device is designed for high reliability, redundant power supply applications, and has extensive and robust protection TYPICAL APPLICATIONS CIRCUIT VREC VOUT RELAY BULK CAPACITOR AC INPUT 3.3V 1 AGND VDD 24 2 VAC RES 23 3 VFB RTD 22 4 OVP ADD 21 5 PGND SDA 20 6 ILIM SCL 19 7 IBAL 8 CS– INRUSH 17 9 PMBus CS+ PGOOD 16 10 DGND AC_OK 15 11 PSON PWM2 14 12 VCORE PWM 13 ADP1048W Figure 1. Typical Interleaved Application, ADP1048W Rev. 0 | Page 5 of 82 12535-102 SYNC 18 ADP1048W Data Sheet SPECIFICATIONS VDD = 3.3 V, TA = −40°C to +125°C, unless otherwise noted. Table 1. Parameter POWER SUPPLY Operating Supply Voltage Supply Current Supply Current for Programming Shutdown Current POWER-ON RESET Power-On Reset Undervoltage Lockout Overvoltage Lockout VCORE PIN Output Voltage Range PWM OUTPUTS Output Low Voltage Output High Voltage Rise Time Fall Time VAC ADC Input Voltage Range Leakage Current Equivalent Resolution Voltage Sense Measurement Accuracy Symbol VDD IDD IDD_PK IDD_SD UVLO OVLO VPWMOL VPWMOH Test Conditions/Comments Current Source High Input Low Input Max Unit 3.05 3.3 17 3.6 40 V mA IDD + 8 100 mA µA VDD rising VDD falling 1.8 2.75 3.7 2.85 3.9 3.02 2.98 4.1 V V V Temperature = 25°C PWM, PWM2 pins Sink current = 10 mA Source current = 10 mA 2.26 2.45 2.65 V 0.4 V V VDD − 0.6 CLOAD = 50 pF CLOAD = 50 pF 4 4 0 ns ns 1.6 5 V μA Bits +1.3 +1.99 % FSR % FSR 1.6 V Bits −1.2 −1.72 +1.2 +1.72 % FSR % FSR 0 0 750 500 mV mV Bits +1.7 +2.06 % FSR % FSR 11 From 3% to 97% of input voltage range −1.3 −1.99 0 11 From 3% to 97% of input voltage range VDD = 3.3 V VDD varies from 3.0 V to 3.6 V CURRENT SENSE ADC High Input Voltage Range Low Input Voltage Range Equivalent Resolution Current Sense Measurement Accuracy Typ Normal operation (PSON high) and no load on PWM output During EEPROM programming (50 ms) VDD = 3.3 V VDD varies from 3.0 V to 3.6 V VFB ADC Input Voltage Range Equivalent Resolution Voltage Sense Measurement Accuracy Min 11 From 5% to 95% of input voltage range VDD = 3.3 V VDD varies from 3.0 V to 3.6 V 10 kΩ level shifting resistor, VCS+ − VCS− = 0 V −1.7 −2.06 74 84 Rev. 0 | Page 6 of 82 μA μA Data Sheet Parameter RTD PIN Input Voltage Range Current Source Accuracy Equivalent Resolution Voltage Sense Measurement Accuracy ADP1048W Symbol Min 0 9 Typ 10 13 Max Unit 0.8 11 V μA Bits +1.52 +1.97 % FSR % FSR 0.8 From 3% to 97% of input voltage range VDD = 3.3 V VDD varies from 3.0 V to 3.6 V Interleaved operation mode IBAL PIN Input Voltage Range Equivalent Resolution Channel Mismatch SWITCHING FREQUENCY Frequency Range Accuracy OSCILLATOR, CLOCK, AND PLL Oscillator Frequency Digital Clock Frequency PLL Frequency RES PIN Temperature Stability PGOOD, AC_OK PINS Output Low Voltage FAST OVERCURRENT PROTECTION Fast OCP Threshold Positive Signal Negative Signal Current Source Accuracy Propagation Delay RMS OVERCURRENT PROTECTION RMS Accuracy Propagation Delay FAST OVERVOLTAGE PROTECTION Fast OVP Threshold Rising Falling OVP Threshold Minimum Step Accuracy Propagation Delay (Latency) Blanking Time ACCURATE OVERVOLTAGE PROTECTION Accuracy Propagation Delay OPEN-LOOP PROTECTION VFB Error Threshold Propagation Delay Debounce Time Common-Mode Input Range Test Conditions/Comments −1.52 −1.97 0 DC input and acquiring time window on each channel is 526 µs −5 +5 V Bits % FSR Programmable 30 −3.85 400 +3.85 kHz % 11 1.516 1.56 200 200 1.62 MHz MHz MHz −120 0 +120 ppm/°C 0.8 V 1550 523 mV mV % ns 1455 452 1500 500 ±4.4 From threshold trip to PWM disabled VDD = 3.3 V AC line frequency = 50 Hz Fully programmable from 1 V to 1.5 V Register 0xFE2F, Bits[6:0] Register 0xFE30, Bits[6:0] 140 −1.7 +1.7 % ms 1.5 1.5 V V mV LSB ns µs 12 1 1 3.9 −4 Does not include blanking/debounce Blanking after threshold reprogramming VDD = 3.3 V AC line frequency = 50 Hz ∆VFB 10 −1.2 +1.2 % ms ±242 mV ns µs V 12 ±33 −0.2 Rev. 0 | Page 7 of 82 +4 120 ±111 200 10 +1.6 ADP1048W Parameter SDA, SCL PINS Input Low Voltage Input High Voltage Output Low Voltage Pull-Up Current Leakage Current SERIAL BUS TIMING Clock Frequency Glitch Immunity Bus Free Time Start Condition Hold Time Start Condition Setup Time Stop Condition Setup Time Data Hold Time Data Setup Time SCL Low Timeout SCL Low Time SCL High Time Clock Low Extend Time SCL, SDA Rise Time SCL, SDA Fall Time EEPROM RELIABILITY Endurance Endurance Data Retention Data Retention Data Sheet Symbol Test Conditions/Comments VDD = 3.3 V Min Typ Max Unit 0.8 V V V µA µA 2.2 0.4 350 +5 100 −5 10 tSW tBUF tHD;STA tSU;STA tSU;STO tHD;DAT For readback For write tSU;DAT tTIMEOUT tLOW tHIGH tLOW;SEXT tR tF 1.3 0.6 0.6 0.6 125 300 100 25 1.3 0.6 20 20 Temperature = 85°C Temperature = 125°C Temperature = 85°C Temperature = 125°C Rev. 0 | Page 8 of 82 10,000 1,000 20 10 100 400 50 35 25 300 300 kHz ns µs µs µs µs ns ns ns ms µs µs ms ns ns Cycles Cycles Years Years Data Sheet ADP1048W ABSOLUTE MAXIMUM RATINGS THERMAL RESISTANCE Table 2. Parameter Supply Voltage (Continuous), VDD Digital Core Supply Voltage, VCORE Digital Pins Analog Pins AGND to DGND Operating Temperature Range Storage Temperature Range Maximum Junction Temperature Peak Solder Reflow Temperature SnPb Assemblies (10 sec to 30 sec) RoHS-Compliant Assemblies (20 sec to 40 sec) ESD Charged Device Model ESD Human Body Model Rating 3.8 V 2.7 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to +0.3 V −40°C to +125°C −65°C to +150°C 150°C θJA is specified for the worst-case conditions, that is, a device soldered in a circuit board for surface-mount packages. Table 3. Thermal Resistance Package Type 24-Lead QSOP (RQ-24) ESD CAUTION 240°C 260°C 1 kV 3.5 kV Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Rev. 0 | Page 9 of 82 θJA 44.4 θJC 6.4 Unit °C/W ADP1048W Data Sheet AGND 1 24 VDD VAC 2 23 RES VFB 3 22 RTD OVP 4 21 ADD PGND 5 ADP1048W 20 SDA ILIM 6 TOP VIEW (Not to Scale) 19 SCL IBAL 7 18 SYNC CS– 8 17 INRUSH CS+ 9 16 PGOOD DGND 10 15 AC_OK PSON 11 14 PWM2 VCORE 12 13 PWM 12535-002 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS Figure 2. Pin Configuration Table 4. Pin Function Descriptions Pin No. 1 2 3 Mnemonic AGND VAC VFB 4 5 OVP PGND 6 7 8 ILIM IBAL CS− 9 CS+ 10 11 DGND PSON 12 13 14 15 16 17 18 19 20 21 22 23 24 VCORE PWM PWM2 AC_OK PGOOD INRUSH SYNC SCL SDA ADD RTD RES VDD Description Analog Ground. AGND must be connected directly to DGND. Input Line Voltage Sense. The VAC signal is referred to PGND. Feedback Voltage Sense. The VFB signal is referred to PGND. VFB is the feedback signal for PFC power circuit regulation. It is used as the analog voltage input to the VFB ADC. Overvoltage Protection. The OVP signal is referred to PGND. This signal is used for redundant overvoltage protection. Power Ground. PGND is the connection for the ground line of the power rail. There must be a low impedance path between PGND and AGND. Fast Current Limiting. This pin is referred to PGND. Current Balancing Input for Interleaved Operation. The IBAL input is referred to PGND. Differential Current Sense Negative Input. The CS− signal is used for current measurement, monitoring, and protection. A 0.1%, 10 kΩ resistor must be used to connect to this circuit. Differential Current Sense Positive Input. The CS+ signal is used for current measurement, monitoring, and protection. A 0.1%, 10 kΩ resistor must be used to connect to this circuit. Digital Ground. DGND must be connected directly to AGND. Power Supply Enable Signal. The PSON signal is used to enable/disable the PFC controller. The PSON signal is referred to DGND. Output of 2.5 V Regulator. Connect a 100 nF capacitor from VCORE to DGND. PWM Output for PFC Regulation. The PWM signal is referred to AGND. Interleaved PWM Output. The PWM2 signal is referred to AGND. Open-Drain Output. User-configurable signal from a combination of flags. The AC_OK signal is referred to AGND. Open-Drain Output. User-configurable signal from a combination of flags. The PGOOD signal is referred to AGND. Inrush Current Control Signal to an External Inrush Driver. This pin is referred to AGND. Allows parallel PFC controllers to synchronize to reduce interference. This pin is referred to DGND. I2C Serial Clock Input. The SCL signal is referred to DGND. I2C Serial Data Input and Output (Open-Drain). The SDA signal is referred to DGND. Address Select Input. Connect a resistor from ADD to AGND (see the PMBus Address section). Thermistor Input. A thermistor is placed from RTD to AGND. The RTD signal is referred to AGND. Internal Voltage Reference. Connect a 0.1%, 50 kΩ resistor from RES to AGND. Positive Supply Input. The range is from 3.0 V to 3.6 V. The VDD signal is referred to AGND. Rev. 0 | Page 10 of 82 Data Sheet ADP1048W FUNCTIONAL BLOCK DIAGRAM IBAL CS– CS+ ILIM VAC PGND VFB OVP PGND + – ADP1048W DAC ADC ADC IBAL CS OCP ADC ADC VAC VFB OLP PGND OVP INRUSH PGOOD PWM PWM ENGINE PWM2 DIGITAL CORE 8kB EEPROM AC_OK VDD I 2C INTERFACE UVLO LDO ADC OSC SYNC VCORE PSON VREF SCL SDA ADD RTD AGND DGND Figure 3. Functional Block Diagram Rev. 0 | Page 11 of 82 12535-001 RES ADP1048W Data Sheet CONTROLLER ARCHITECTURE The ADP1048W integrates the following functions: The output of the Σ-Δ ADC is used for the following purposes: • • • • Power factor correction control loop (see the Power Factor Correction Control Loop section) Advanced input power metering (see the Advanced Input Power Metering section) PMBus digital communication (see the PMBus Digital Communication section) This section describes the internal architecture of the chip. • The output is decimated at the switching frequency for the control loop. The effective number of bits (ENOB) is >7 when the current loop bandwidth is 10 kHz; the ENOB is >10 when the current loop bandwidth is 1 kHz. The 11-bit result is calculated and updated at each half line cycle for high accuracy ac line current and input power monitoring and for overcurrent protection (accurate OCP). RMS INPUT OVERCURRENT PROTECTION CURRENT SENSE Current sensing is used for the control, protection, and monitoring of the PFC stage. For normal operation, the power factor correction control loop requires inductor current information. The typical implementation uses a sense resistor on the input bus. A combination of two current transformers in series with the power switch and the boost diode can be used to reconstruct the inductor current and minimize losses in the resistive shunt, but, in general, a good quality shunt resistor provides much better accuracy in measuring input current and input power. The inputs to the current sense ADC are differential. A pair of matched current sources is provided to level shift the negative signal across the current sense element in the input range of the current sense ADC (see Figure 4). The ADP1048W provides rms overcurrent protection (OCP). RMS OCP (or accurate OCP) is distinct from the instantaneous pulse-by-pulse fast overcurrent protection and is based on the rms value of the input ac current. The measured value is compared to the limit set in the IIN_OC_FAULT_LIMIT register (Register 0x5B) at the end of each half cycle of the ac line. If the limit is exceeded, the action programmed in the IIN_OC_FAULT_RESPONSE register (Register 0x5C) is triggered. In addition, an input current warning limit can be programmed in the IIN_OC_WARN_LIMIT register (Register 0x5D). This warning limit has no action attached to it, but it sets flags in the STATUS_BYTE register (Register 0x78, Bit 0), the STATUS_WORD register (Register 0x79, Bit 13), and the STATUS_INPUT register (Register 0x7C, Bit 1). FAST OVERCURRENT PROTECTION (ILIM PIN) IL 10kΩ A dedicated current limiting pin (ILIM) is provided to protect the decice from pulse-by-pulse overcurrent events. When the threshold is crossed, the PWM pulse is terminated. This action is independent of any programming of the fast OCP flag. The next switching cycle resumes normally. Additional actions can be programmed (see Table 5). 10kΩ CS– CS+ + ADC The OCP comparator on the ILIM pin can accept positive or negative signals; the pin is referred to PGND (power ground) and has programmable level shifting current sources (see Table 5). These sources can be changed during normal operation to adapt to the level at which the overcurrent protection is triggered. 11-BIT VDD ADP1048W 12535-005 – Figure 4. Current Sense Configuration The current sense can be calibrated digitally to remove any errors due to external components (see the Current Sense Gain and Offset Trim section). This calibration can be performed in the production environment; the settings are saved in the EEPROM of the ADP1048W. The OCP comparator also features programmable blanking and debounce times (see Table 5). If OCP is triggered, the PWM signal is terminated and operation resumes at the next switching cycle unless a different action is specified for the fast OCP response in Register 0xFE00. Rev. 0 | Page 12 of 82 Data Sheet ADP1048W IL ILIM PGND 60µA TO 120µA OCP PGND 20µA TO 80µA 500mV OCP 1500mV VDD VDD ADP1048W ADP1048W 12535-006 ILIM IM Figure 5. Fast Overcurrent Protection Schemes 500mV 1500mV LEVEL SHIFTING 10k × 120µA = 1.2V 0mV 0mV 12535-007 LEVEL SHIFTING 10k × 80µA = 0.8V Figure 6. Level Shifting and Threshold for OCP Table 5. Programmable Options for Fast Overcurrent Protection Parameter Debounce Time Blanking Time Values or Options 40 ns, 80 ns, 120 ns, 240 ns 40 ns, 80 ns, 120 ns, 160 ns, 200 ns, 400 ns, 600 ns, 800 ns Propagation Delay 140 ns typical Threshold Value and Polarity Level Shifting Current Sources 500 mV (negative); 1500 mV (positive) 60 μA, 80 μA, 100 μA, 120 μA (negative) 20 μA, 40 μA, 60 μA, 80 μA (positive) Ignore (still terminates the PWM pulse); allow n switching cycles, then shut down and soft start; allow n switching cycles, then shut down and wait for PSON signal Actions for Fast OCP Rev. 0 | Page 13 of 82 Comments Register 0xFE3D, Bits[4:3] Blanking from the leading edge; Register 0xFE3D, Bits[2:0] Fixed value; does not include blanking or debounce Fixed values Register 0xFE3E, Bits[7:5] n = 1, 2, 4, 8; Register 0xFE00, Bits[7:6] ADP1048W Data Sheet CURRENT BALANCING The ADP1048W has a dedicated circuit to maintain current balance in each interleaved phase when operating in interleaved PFC topology. This ensures that each interleaved phase provides equal power regardless of the tolerance of the inductor and the boost switch driving circuitry. The input is through the IBAL pin specifically provided for the ADP1048W. The current balancing circuit monitors the current flowing in both switches of the interleaved PFC topology and stores this information. It compensates the PWM signals, ensuring equal current flow to balance the current between interleaved phases. Several switching cycles are required for the circuit to operate effectively. The current balance settings are programmed in Register 0xFE43 and Register 0xFE95. The voltage sense can be calibrated digitally to remove any errors due to external components (see the Output Voltage (VFB) Calibration and Trim section). This calibration can be performed in the production environment; the settings are saved in the EEPROM of the ADP1048W. Input Voltage Sensing (VAC Pin) The VAC pin is used for the monitoring and protection of the rectified power supply input voltage. The sense point on the power rail requires an external resistor divider to bring the signal within the operating input range of the ADC (0 V to 1.6 V). This scaled-down signal is fed into a high speed Σ-Δ ADC. The output of the Σ-Δ ADC goes to the digital filter and is used for the following purposes: • • Output Voltage Sensing (VFB Pin) PGND IBAL The VFB pin is used for the control, monitoring, and protection of the output voltage. This voltage is the main feedback loop for the power supply control loop. The sense point on the power rail requires an external resistor divider to bring the signal within the operating input range of the ADC (0 V to 1.6 V). This scaleddown signal is fed into a high speed Σ-Δ ADC. 0° TO 180° ADC + K – ADC 180° TO 360° PWM OUTPUT OF PFC CURRENT LOOP PWM The output of the Σ-Δ ADC goes to the digital filter and is used for the following purposes: 12535-008 ADP1048W PWM2 • Figure 7. Current Balancing (IBAL) VOLTAGE SENSE Voltage sensing is used for the control, protection, and monitoring of the PFC stage. Input and output voltages are sensed using dedicated ADCs and references (see Figure 8). VREC VAC PGND + – VOUT + – ADC + – OLP OVP 11-BIT ADP1048W 12535-009 7-BIT 11-BIT The 11-bit result is used at each half line cycle for the normal control loop to control the value of the output voltage. The 10-bit, 1.5 kHz update rate is used for the fast voltage control loop to control the value of the output voltage during large transients. To reduce the current distortion from the output voltage feedback, a prefilter is implemented before the voltage loop filter. The prefilter detects the zero-crossing point of the input voltage to identify the half input line cycle. The prefilter then performs an averaging function for the sampled VFB signal during this half line cycle. In this way, the fundamental frequency of the output bulk voltage ripple and its harmonics are significantly attenuated. OVP VFB • DAC ADC The output is decimated at the switching frequency for the control loop. The effective number of bits (ENOB) is >7 when the current loop bandwidth is 10 kHz; the ENOB is >10 when the current loop bandwidth is 1 kHz. The 11-bit result is calculated and updated at each half line cycle for high accuracy input voltage and power monitoring. Figure 8. Typical Voltage Sense Configuration Rev. 0 | Page 14 of 82 Data Sheet ADP1048W OVERVOLTAGE PROTECTION Fast Overvoltage Protection (OVP Pin) The ADP1048W has two OVP circuits: an ADC-based comparator and a fast comparator. A fast OVP mode is implemented using a programmable comparator on the OVP pin. Fast OVP is used for overvoltage protection of the bulk capacitors and to provide open-loop protection. The sense point on the power rail requires an external resistor divider to match the divider applied to VFB. This separate divider introduces a level of redundancy in sensing the output voltage to improve system reliability. Accurate Overvoltage Protection (VFB Pin) Overvoltage protection (OVP) is implemented using the information available on the output of the VFB ADC. The information from the VFB ADC is averaged over one half the ac line frequency; therefore, the response of this OVP is relatively slow. The threshold for the accurate OVP is fully programmable using the VOUT_OV_FAULT_LIMIT register (Register 0x40). The programmed value is the dc average voltage. When the accurate OVP threshold is crossed, the accurate OVP flag is set. The response to this flag can be programmed for one of several actions using the VOUT_OV_FAULT_RESPONSE register (Register 0x41). If the disable PWM option is selected, a voltage hysteresis can be programmed for the accurate OVP threshold using Register 0xFE50. If the voltage divider on the VFB pin is damaged or drifts in value, the OVP pin can still detect an overvoltage condition and take the appropriate programmed action. The fast OVP signal is fed into a comparator with a programmable threshold to set the trip point for overvoltage. The threshold is set using a DAC. Table 6. Programmable Options for Fast Overvoltage Protection (Fast OVP) Parameter Debounce Time Values or Options 120 ns, 240 ns, 480 ns, 640 ns Blanking Time 10 μs (fixed) Propagation Delay Threshold Rising Threshold Falling Actions for Fast OVP 120 ns max (fixed) 1 V to 1.5 V 1 V to 1.5 V Immediate shutdown and wait for PSON; disable PWM until the flag is cleared; shut down and soft start; ignore (do nothing) Rev. 0 | Page 15 of 82 Comments Minimum duration of pulse to be considered; programmable using Register 0xFE31, Bits[1:0] Duration of time while the comparator is blanked and the threshold changes from rising to falling Does not include blanking or debounce Programmable using Register 0xFE2F, Bits[6:0] Programmable using Register 0xFE30, Bits[6:0] Register 0xFE01, Bits[7:6] ADP1048W Data Sheet Figure 9 shows an example of the output voltage and the OVP thresholds set. The rising and falling thresholds, FAST_OVP_ FAULT_RISE and FAST_OVP_FAULT_FALL, respectively, are used for fast OVP protection. FAST_OVP_FAULT_RISE corresponds to OVPUP, which is the trip point for overvoltage protection (see Figure 10). FAST_OVP_FAULT_FALL corresponds to OVPDOWN, which is the reset point for the fast OVP. When the rising threshold is triggered, the programmed action is applied and the threshold is switched to the programmed falling threshold (if the programmed falling threshold is different from the rising threshold). A blanking time is applied when the thresholds are switched to avoid spurious signals (see the timing diagram in Figure 10). A programmable debounce time is applied to the OVP signal as well to avoid false triggering. ADC INPUT RANGE = 1.6V 1.6V VOUT_OV_FAULT_LIMIT = 450V (REG 0x40) FAST_OVP__FAULT_RISE = 435V (REG 0xFE2F) VOUT_OV_WARN_LIMIT = 420V (REG 0x42) FAST OVP PROGRAMMING RANGE FAST_OVP_FAULT_FALL = 400V (REG 0xFE30) 1.0V VOUT_COMMAND = 385V (REG 0x21) ADC FULL RANGE 0.5V VOUT_UV_FAULT_LIMIT = 200V (REG 0x44) 12535-020 The rising and falling thresholds are programmable from 1 V to 1.5 V (at the OVP pin) using Register 0xFE2F and Register 0xFE30, respectively. Open-Loop Protection Open-loop protection detects differences between the OVP and VFB pins. Identical resistor dividers are applied to these pins; therefore, if a voltage difference is present, it means that one or more resistors in the dividers have the wrong values or are not connected. In this case, it is usually recommended that the user shut down the system to prevent damage. The open-loop protection detects a difference in voltage in excess of ~100 mV, which equates to approximately 6.6% of the full-scale range. Figure 9. Output Voltage Levels OUTPUT VOLTAGE OVP PIN OVPUP OVPDOWN DEBOUNCE 10µs TIME 12535-021 A debounce time of 10 μs is added to avoid false triggering. If filtering capacitors are applied to the OVP and VFB pins, care must be taken to make sure that the time constant difference does not exceed 10 μs. OVPFLAG Figure 10. OVP Thresholds and Timing Table 7. Programmable Options for Open-Loop Protection (OLP) Parameter Debounce Time Propagation Delay Actions for OLP Values or Options 10 μs (fixed) 200 ns (fixed) Immediate shutdown and wait for PSON; disable PWM until the flag is cleared; shut down and soft start; ignore (do nothing) Rev. 0 | Page 16 of 82 Comments Minimum duration of pulse to be considered Does not include debounce Register 0xFE02, Bits[7:6] Data Sheet ADP1048W POWER FACTOR CORRECTION CONTROL LOOP The frequency gains and zero locations can all be programmed individually to tailor the loop response to the application. It is recommended that the Analog Devices, Inc., GUI software be used to program the filter (see the Software GUI section). The GUI displays the filter response in Bode plot format and can be used to calculate all stability criteria for the power supply. The ADP1048W implements the average current mode power factor correction control loop using a traditional multiplier approach. The implementation of the loop is digital, and all the signals are converted from analog to digital before they are processed by the control loop. Σ-Δ ADCs are used to achieve high performance, cost-effective implementation. Each ADC has its own dedicated voltage reference. Optimized Compensation Filters DIGITAL COMPENSATION FILTERS Instead of a single programmable compensation filter, the ADP1048W offers the following filter presets so that the dynamic response of the control loop can be tailored to optimize different operating conditions. The ADP1048W is a digital PFC controller with ac power monitoring. It is implemented in the digital domain using a dedicated state machine, which allows the user to program the loop response specifically, with no need for external loop compensation. • • • The detailed control loop configuration is illustrated in Figure 11. VREF is the digital reference voltage setting; VFB is the sensed feedback voltage of the output. The difference between VREF and VFB is processed first by the voltage loop filter (HV). Its output, VEA, is then multiplied by the instantaneous rectified input voltage, VAC, and divided by the square of the rms value of VAC. The result, IREF, is used as the reference signal for the current. The output of the current loop filter (HI) is the duty cycle command. The mathematical expression is I REF = Low line current filter High line current filter Fast voltage compensation filter The ADP1048W can be configured to switch automatically between the high and low line filters when the rms value of the ac line crosses the programmed threshold between the high and low lines. (The high line threshold is programmed in Register 0xFE35; the low line threshold is programmed in Register 0xFE36.) The ADP1048W checks for the value of the rms input voltage at each half line cycle. When a transition between the high and low line threshold is detected, the device waits for four full line cycles before switching to the correct filter at the zero crossing of the input line cycle. This is done to avoid spurious transitions due to a missing or distorted voltage line cycle. VEA × VAC 2 VAC _ RMS Both the voltage loop and current loop digital compensating filters, HV(z) and HI(z), are programmable. The filter transfer function in the digital domain is During soft start, one of four combinations of filters can be used, depending on whether the fast loop mode is enabled and whether the high line or low line is detected for soft start (see Table 8). z − a 256 H(z) = k × b × (z − 1) where: a is the filter zero. b is the filter gain. k is related to the switching frequency. VAC – VREF + IL V2AC_RMS HV (z) IREF VEA – + DUTY CYCLE HI (z) 12535-010 VFB Figure 11. Control Loop Digital Filters Table 8. Summary of the PFC Digital Compensation Filters for Soft Start Line Filter High Line Low Line Normal Compensation Filter High line current filter, normal voltage filter Low line current filter, normal voltage filter Rev. 0 | Page 17 of 82 Fast Voltage Compensation Filter High line current filter, fast voltage filter Low line current filter, fast voltage filter ADP1048W Data Sheet Fast Loop Mode VFB During transients, a fast loop mode is enabled to allow for faster loop responses. Typical timing can be seen in Figure 12. The fast loop mode has separate settings and can be programmed to respond quickly to load transients. The user can disable the fast loop mode if it is not required by the application. VFB ERROR FAST LOOP VFB FAST ERROR VREC ILOAD 12535-012 NORMAL FILTER @ 100Hz FAST FILTER @ 1.5kHz Figure 13. Fast Loop Operation PROGRAMMABLE RANGE VOUT 12535-011 PROGRAMMABLE DELAY (0 TO 7 HALF LINE CYCLES) FAST LOOP Figure 12. Fast Loop for Transient Response Improvement When fast loop mode is enabled and the feedback output voltage is out of range from the desired reference value (programmable band of 1.5%, 3%, 6%, or 12%, set in Register 0xFE24), the ADP1048W enters fast loop mode. To ensure a smooth transition, the ADP1048W switches from the regular filter to the fast loop filter at the zero crossing of the rectified input voltage. When the output voltage returns to regulation within the programmed band, the controller switches back (after a programmable delay of 0 to 7 half line cycles) to the normal loop at the next zero crossing of the rectified input voltage. If the output voltage does not return to regulation within the programmed band after a fixed time of 630 ms, the control loop automatically switches back to the normal loop. In the normal compensation loop, the sampling frequency of the output voltage is the same as the ripple oscillation frequency (which is commonly 100 Hz or 120 Hz). During fast loop operation, the feedback voltage is sampled at 1.5 kHz, and the fast filter is applied to regulate the output voltage. The output voltage is averaged and decimated at 1.5 kHz (see Figure 13). Based on the requirements of the application, the user can enable or disable the fast loop mode by programming Register 0xFE24. It is recommended that fast loop mode be enabled for the ADP1048W during large load transients. The fast loop mode settings are also used during soft start, even when the fast loop is disabled. PULSE-WIDTH MODULATION The ADP1048W can implement either leading edge or trailing edge modulation. Trailing edge modulation is the more popular modulation scheme. Using trailing edge modulation, the rms ripple current in the bulk capacitors can be reduced when used with downstream converter synchronization. It is recommended that the Analog Devices, Inc., GUI software be used to program PWM (see the Software GUI section). DUTY CYCLE MINIMUM/MAXIMUM LIMITS The ADP1048W allows the user to program the minimum off time and the minimum on time for the PWM outputs separately, thereby allowing the minimum and maximum duty cycles to be set. The minimum off time represents the minimum time that the PWM is low during each switching cycle. It can be programmed from 40 ns to 1.2 μs in steps of 80 ns using Register 0xFE15, Bits[3:0]. In this way, the maximum duty cycle can be clamped between 96% and 99.8% at the minimum frequency and between 48.8% and 96.8% at the maximum frequency. The minimum on time is the smallest PWM pulse that the modulator generates on the PWM output. It can be programmed from 0 ns to 1200 ns in steps of 80 ns using Register 0xFE15, Bits[7:4]. Rev. 0 | Page 18 of 82 Data Sheet ADP1048W SWITCHING FREQUENCY PROGRAMMING The switching frequency of the PWM outputs can be programmed from 30 kHz to 400 kHz using Register 0xFE1B, Bits[5:0] (see Table 9). Table 9. Switching Frequency Settings from 30 kHz to 400 kHz (Register 0xFE1B, Bits[5:0]) Frequency Setting (Decimal) 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Frequency (kHz) 30.05 32.55 35.51 39.06 43.40 48.83 52.06 55.80 60.10 65.10 71.02 78.13 86.81 97.66 100.81 104.17 Frequency Setting (Decimal) 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 Frequency (kHz) 107.76 111.61 115.74 120.19 125.00 130.21 135.87 142.05 148.81 156.25 164.47 173.61 183.82 195.31 198.41 201.61 Frequency Setting (Decimal) 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 Rev. 0 | Page 19 of 82 Frequency (kHz) 204.92 208.33 211.86 215.52 219.30 223.21 227.27 231.48 235.85 240.38 245.10 250.00 255.10 260.42 265.96 271.74 Frequency Setting (Decimal) 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 Frequency (kHz) 277.78 284.09 290.70 297.62 304.88 312.50 320.51 328.95 337.84 347.22 357.14 367.65 378.79 390.63 403.23 403.23 ADP1048W Data Sheet LINE FAULT PROTECTIONS AND SOFT START SEQUENCING PSON OPERATION AC Line Period and Zero Crossing To comply with PMBus standards, the PFC circuit controlled by the ADP1048W can be turned on and off by the hardware PSON pin and/or the software PSON command. The setting of Bit 2 in Register 0x02 determines whether the PSON pin and/or the PSON command is used. If the PSON pin is used, the pin can be configured to be either active high or active low (see Table 18). The input ac line period is measured every half period of the ac line cycle and is reported in the VAC_LINE_PERIOD register (Register 0xFE85). During the first 40 ms, the ac line period is measured between two consecutive falling crossings of the threshold value, which is set in the VAC_THRESHOLD_SET register (Register 0xFE25, Bits[6:0]). The ac line period is then measured between two consecutive falling crossings and compared to the average value of the input line voltage, which is calculated during each half line period. The VAC average reading can be found in the VAC_ THRESHOLD_READ register (Register 0xFE26, Bits[6:0]). AC LINE DETECTION The ADP1048W is capable of detecting several parameters of the ac line input voltage and taking the appropriate programmed actions when necessary. The detection is a combination of time and voltage measurements and is implemented via the VAC pin, which detects the rectified ac input voltage. This allows early detection of ac line faults and early warning for the host system, thereby increasing reliability. If the measured period is larger than MAX_AC_PERIOD_SET or smaller than MIN_AC_PERIOD_SET, the default, MAX_AC_ PERIOD_SET, is used as the value of the period. As shown in Figure 14, the two consecutive crossing points, B and C, are used to determine the zero-crossing point of the ac line. The middle point between B and C is calculated as the zero-crossing point. Five main parameters are related to ac line detection. VAC_LINE_PERIOD (Register 0xFE85) VAC_THRESHOLD_SET (Register 0xFE25) VAC_THRESHOLD_READ (Register 0xFE26) MIN_AC_PERIOD_SET (Register 0xFE27) MAX_AC_PERIOD_SET (Register 0xFE28) VAC THRESHOLD (REG 0xFE25) This information is used by the control loop, as well as the power metering block. A B HALF AC LINE PERIOD Figure 14. AC Line Period Detection Rev. 0 | Page 20 of 82 C VAC AVERAGE (REG 0xFE26) 12535-013 • • • • • Data Sheet ADP1048W AC Line Value Detection To operate, the controller must detect the ac line value. At startup, the controller waits for the PSON signal (hardware PSON, software PSON, or both, depending on how the device is programmed). VIN_OFF (REG 0x36) TIMER 1/4 TIMER 1/4 VIN_LOW FLAG (REG 0x7C[3]) VIN_ON (REG 0x35) Figure 16. AC Line Early Fault Detection VAC 12535-014 BROWN_OUT FLAG (REG 0xFE80[2]) Figure 15. VAC Detection for Startup The start-up value for the ac line used by the controller to initiate the start-up procedure is stored in the VIN_ON register (Register 0x35). This value is the minimum rms value of the ac line required for the system to start up. The controller measures the value of VAC at every half line cycle and compares it with VIN_ON. If VAC is larger than the value in the VIN_ON register, the soft start procedure is initiated and the BROWN_OUT flag is reset. AC Line Early Fault Detection After the VIN_ON limit is crossed and the system starts up, the controller constantly monitors the condition of the ac line (see Figure 16). To provide early detection of ac line faults, the instantaneous value of VAC is compared to the VIN_OFF value in Register 0x36. If VAC remains below the VIN_OFF threshold for a time longer than the programmed period, the VIN_LOW flag is set in Register 0x7C. The programmed period can be either a fraction of the detected ac line period (one-quarter or one-half) or it can be an absolute time (2 ms or 4 ms); the value is set in Register 0xFE2E. The controller does not take any action, but the VIN_LOW signal can be used to set the AC_OK signal and to trigger immediate actions in the power system. The VIN_OFF threshold is intended solely to provide early warning of problems on the ac line; it is not used to shut down the power supply. The VIN_UV_FAULT_LIMIT register (Register 0x59) is used for that purpose. ADC INPUT RANGE = 1.6V VIN_OV_FAULT_LIMIT = 270VAC (REG 0x55) VACMAX = 265VAC HIGH LINE LIMIT (VACTH) = 180V (REG 0xFE35) HYSTERESIS ZONE LOW LINE LIMIT (VACTH) = 150V (REG 0xFE36) VACMIN = 90VAC VIN_ON = 85VAC (REG 0x35) VIN_UV_WARN_LIMIT = 80VAC (REG 0x58) Figure 17. Input Voltage Limits Rev. 0 | Page 21 of 82 12535-016 VIN_OFF = 70VAC (REG 0x36) VIN_UV_FAULT_LIMIT = 70VAC (REG 0x59) 12535-015 When the PSON signal is present, the controller looks for the ac line period and value (see Figure 15). VAC ADP1048W Data Sheet SOFT START PROCEDURE The PSON signal is used to enable or disable the PFC stage. After PSON is asserted, the ADP1048W starts monitoring VAC and, if the ac line conditions are met, they initiate the soft start procedure, as shown in Figure 18. Startup is gated by the rms value of the ac line voltage measured on one half period of the ac line frequency. When VAC is above the VIN_ON value, the BROWN_OUT flag is reset and the soft start sequence is initiated. At the same time, the inrush delay time and soft start delay time timers begin. Both of these timers can be programmed to count 0 to 7 line cycles (or 0 to 14 half line cycles in steps of 2). After the inrush delay time programmed in Register 0xFE2E, Bits[2:0], the INRUSH flag is reset and the inrush signal (Pin 17) is asserted, closing the inrush current relay. (Note that the INRUSH flag is active low.) The inrush signal is set at the zero crossing of the ac voltage, if this crossing is detected. This setting allows zero voltage turn-on if a solid-state switch is used (zero voltage turn-on is not relevant with mechanical relays). After the soft start delay time (programmed in Register 0xFE2D, Bits[5:3]), the output voltage is ramped up according to the soft start time programmed in Register 0xFE2D, Bits[2:0]. When output voltage regulation is reached and all flags are OK, the POWER_GOOD# flag is reset and the PGOOD signal (Pin 16) is set to Logic Level 1. (Note that the POWER_GOOD# flag is active low.) The soft start time can be programmed to one of eight values: 112 ms, 168 ms, 224 ms, 280 ms, 392 ms, 504 ms, 616 ms, or 728 ms (set in Register 0xFE2D, Bits[2:0]). The soft start delay time (Register 0xFE2D, Bits[5:3]) can be programmed from 0 to 7 full line cycles in increments of 1 (that is, two of the rectified half line cycles). The inrush delay time (Register 0xFE2E, Bits[2:0]) can be programmed from 0 to 7 full line cycles in increments of 1 (that is, two of the rectified half line cycles). If no zero crossings are detected, the programmed maximum ac line period, MAX_AC_PERIOD_SET (Register 0xFE28), is used. LINE FAULT PROTECTIONS Line faults occur when the ac line is not behaving correctly and include anomalies such as a missing ac line cycle (can be partial), brownout, or high distortion levels. When a line fault occurs, the ADP1048W can be programmed to react according to the situation. Some of the flags can be blanked during soft start so that the programmed action of the flag does not take place if the flag is set during the soft start period (see Register 0xFE08 and Register 0xFE09). VIN_ON (REG 0x35) VIN_OFF (REG 0x36) VAC VIN_LOW FLAG (REG 0x7C[3]) BROWN_OUT FLAG (REG 0xFE80[2]) INRUSH PIN INRUSH DELAY TIME = 2 (REG 0xFE2E[2:0]) SOFT START DELAY TIME = 3 (REG 0xFE2D[5:3]) SOFT START TIME (REG 0xFE2D[2:0]) Figure 18. Soft Start and Inrush Current Control Timing Rev. 0 | Page 22 of 82 12535-017 VOUT Data Sheet ADP1048W Missing AC Line Cycles PSON Delay Figure 19 shows examples of the typical missing ac line cycles fault. The VIN_LOW flag is set when the instantaneous voltage is below VIN_OFF for more than a quarter or half line cycle (depending on how it is programmed). This flag can be used as an early warning to the system via the AC_OK pin when more than a half cycle is missing. The BROWN_OUT flag is also set; this flag does not cause a shutdown. The PSON start delay is programmable using Register 0xFE06, Bits[3:2]. Four options are available: 0 ms, 50 ms, 250 ms, and 1000 ms. If any other flag that is programmed for shut down is set (in this example, VOUT_UV_FAULT), the power supply shuts down, the INRUSH pin is asserted, and the controller prepares for the next soft start cycle. If the BROWN_OUT flag is cleared before VOUT drops below the VOUT_UV_FAULT_LIMIT value (Register 0x44), operation resumes in normal mode (or fast loop mode if enabled); otherwise, if VOUT drops below VOUT_UV_FAULT_LIMIT, the INRUSH pin is reset and a new soft start cycle is started. Brownout Conditions Brownout is another typical line fault condition in which the line drops below the minimum specified operating level. This level can be set with VIN_UV_FAULT_LIMIT (Register 0x59). This flag can be programmed according to the standard PMBus flag response. For example, it can be programmed to shut down and restart after a certain delay. During brownout, there are other conditions that can occur, such as input overcurrent or output undervoltage. Each of these faults can be programmed to shut down or disable the output, based on the response action. VIN_ON (REG 0x35) VAC VIN_OFF (REG 0x36) VIN_LOW FLAG (REG 0x7C[3]) BROWN_OUT FLAG (REG 0xFE80[2]) INRUSH DELAY TIME (REG 0xFE2E[2:0]) INRUSH PIN SOFT START TIME (REG 0xFE2D[2:0]) 12535-018 VOUT VOUT_UV_FAULT_LIMIT (REG 0x44) Figure 19. Line Fault (Missing Cycles) Timing Diagram VAC VIN_ON (REG 0x35) VIN_UV_FAULT_LIMIT (REG 0x59) BROWN_OUT FLAG (REG 0xFE80[2]) VIN_UV_FAULT FLAG (1 CYCLE DEBOUNCE) SHUTDOWN 12535-019 INRUSH PIN Figure 20. Brownout Timing Diagram (VIN_UV_FAULT_RESPONSE Register Programmed to Shut Down After a One-Cycle Debounce) Rev. 0 | Page 23 of 82 ADP1048W Data Sheet ADVANCED INPUT POWER METERING is written to the READ_PIN register (Register 0x97) and is available to be read back through the interface until it is overwritten by the next averaged value at the end of the next averaging period. The ADP1048W monitors and communicates critical information, including input and output voltage, input and output current, temperature, and efficiency. The device also monitors and communicates OVP, UVP, OCP, OTP, and openloop protection functions. An I2C interface reads all these values and flags and programs their thresholds. The on-chip EEPROM can be used to store all of the settings for the thresholds. For this reason, the polling frequency used to read average power through the PMBus interface must be equal to or higher than the averaging window to maintain data integrity. The averaging window is programmable over a wide range of times to accommodate different situations. True rms values are calculated at the end of each half ac line cycle by integrating the instantaneous values across each line cycle. These values have a resolution of 11 bits and are used to calculate the average, but are not available to be read through the PMBus interface. Input voltage, input current, output voltage, and input power are reported in linear format in the following registers: • • • • VAC ADC PGND CS+ ADC CS– RMS AVG RMS AVG RMS AVG 1 2 AC SYNC VIN PIN IIN 3 0 LINE CYCLES TO 4096 LINE CYCLES 12535-022 The averaging window is programmable from zero full line cycles to 4096 full line cycles using Register 0xFE3A. At the end of each averaging period, the new value for average power Input voltage: READ_VIN (Register 0x88) Input current: READ_IIN (Register 0x89) Output voltage: READ_VOUT (Register 0x8B) Input power: READ_PIN (Register 0x97) Figure 21. Block Diagram of Power Monitoring Table 10. Data Format and Range for VIN, IIN, PIN, and VOUT Metering Data VIN IIN PIN VOUT Mantissa (Bits) 11 11 11 11 Exponent (N) −3 to −1 −10 to −5 −4 to +3 −3 to 0 Minimum Range 256 V 2A 256 W 256 V Rev. 0 | Page 24 of 82 Minimum LSB 0.125 V 0.976 mA 125 mW 0.125 V Maximum Range 1024 V 64 A 32.8 kW 2048 V Maximum LSB 0.5 V 0.03125 A 16 W 1V Data Sheet ADP1048W POWER SUPPLY SYSTEM AND FAULT MONITORING The ADP1048W has extensive system and fault monitoring capabilities. The system monitoring functions include voltage, current, power, and temperature readings. The fault conditions include out of limit for current, voltage, power, and temperature. The limits for the fault conditions are programmable. An extensive set of flags is set when certain thresholds or limits are exceeded. These flags are described in Table 11 and Table 12. FLAG CONVENTIONS A flag indicates a fault condition; therefore, a flag is set (equal to 1, or high) when the fault or bad condition occurs. Good flags, such as POWER_GOOD# and AC_OK, are active low flags. For example, POWER_GOOD# = 1 indicates a problem. Note that the signals relative to a flag are active high. For example, if the POWER_GOOD# flag is set to 1, the PGOOD pin is at Logic Level 0 because the POWER_GOOD# flag is inverted at the pin to provide active high signals. MANUFACTURER-SPECIFIC FLAGS The manufacturer-specific flags are flags that are not covered by the PMBus specification. Some flags simply indicate a condition (typically, warning flags). The response to some of the flags is individually programmable (typically, fault flags). There is also a set of latched fault registers. These registers contain the same flags, but the flags remain set to allow users to detect an intermittent fault. Reading a latched register resets the flags in that register. The latched fault registers are Register 0xFE80, Register 0xFE81, and Register 0xFE82. Table 11. Summary of Manufacturer-Specific Flags Bit Name MAX_MODULATION MIN_MODULATION OLP Address 0xFE80[7] 0xFE80[6] 0xFE80[5] Description (1 = Flag Set) The maximum modulation limit is reached. The minimum modulation limit is reached. Signals a difference of more than ~100 mV between the VFB and OVP signals (one of the two voltage dividers is probably disconnected or malfunctioning). The threshold set for the comparator on the OVP pin has been crossed. The controller is not able to detect the ac line period; the maximum value of the period is used and this flag is set. VAC is lower than the value stored in VIN_ON (Register 0x35). The system is in soft start sequence; fast loop filter is in use. INRUSH control relay is off. FAST_OVP AC_PERIOD 0xFE80[4] 0xFE80[3] BROWN_OUT SOFT_START INRUSH 0xFE80[2] 0xFE80[1] 0xFE80[0] EEPROM_UNLOCKED EEPROM_CRC I2C_ADDRESS 0xFE81[6] 0xFE81[5] 0xFE81[4] LOW_LINE FAST_OCP SYNC_LOCK AC_OK 0xFE81[3] 0xFE81[2] 0xFE81[1] 0xFE81[0] LOW_POWER 0xFE82[5] FAST_LOOP 0xFE82[4] EEPROM is unlocked and its contents can be written. The downloaded contents of the EEPROM are incorrect. The resistor on the ADD pin has a value that can cause an error in the address assignment (the address falls too close to the threshold between two addresses). The input voltage is higher than the high line threshold. The threshold set for the comparator on the ILIM pin has been crossed. External synchronization frequency is locked. The output of the AC_OK pin is low. (This flag is a programmable combination of other internal flags and refers to the condition of the input voltage.) The input power has dropped below the threshold for low power mode operation. The fast loop compensation filter is in use. VCORE_OV VDD_3.3V_OV VDD_3.3V_UV 0xFE82[3] 0xFE82[2] 0xFE82[1] An overvoltage condition is present on the VCORE rail. An overvoltage condition is present on the VDD rail. An undervoltage condition is present on the VDD rail. Rev. 0 | Page 25 of 82 Action Programmable Programmable Can set AC_OK flag INRUSH pin (can also set AC_OK flag) Programmable Programmable AC_OK pin Programmable Can set POWER_GOOD# flag Programmable Programmable Shutdown ADP1048W Data Sheet STANDARD PMBus FLAGS Figure 22 shows the bits in the six standard PMBus fault response registers: Register 0x41, Register 0x45, Register 0x50, Register 0x56, Register 0x5A, and Register 0x5C. All six PMBus fault response registers follow the same format. For more information, see the PMBus Fault Flag Response section. When the corresponding bit of a standard PMBus flag is set in the STATUS_WORD or STATUS_BYTE register, the programmed action takes place as shown in Figure 22. RESPONSE (BITS[7:6]) RETRY SETTING (BITS[5:3]) DELAY TIME (BITS[2:0]) 00 = DO NOTHING FAULT CLEARED RETRY SETTING (BITS[5:3]) 000 = NO RETRIES (OFF) 001 TO 110 = TRY 1 TO 6 TIMES 111 = RETRY FOREVER DELAY TIME (BITS[2:0]) SHUT DOWN IF FLAG STILL ACTIVE 01 = SHUT DOWN (AFTER DEBOUNCE) 10 = IMMEDIATE SHUTDOWN OUTPUT DISABLED FAULT NOT CLEARED FLAGS ARE IGNORED IF BLANKED SOFT START 12535-023 11 = DISABLE OUTPUT 10 01 = S = HU CO T NT DO IN W U N E T TH HE EN N R RE ET TR RY Y NORMAL OPERATION Figure 22. Standard PMBus Fault Response Table 12. Summary of Standard PMBus Flags Implemented on the ADP1048W Name STATUS_BYTE (0x78) PSON_OFF Address Description 0x78[6] VOUT_OV 0x78[5] VIN_UV TEMPERATURE CML NONE_OF_THE_ABOVE STATUS_WORD (0x79) VOUT 0x78[3] 0x78[2] 0x78[1] 0x78[0] Power supply on signal: this flag indicates that the PSON signal (hardware or software) is inactive. General output overvoltage fault. This flag is a combination (OR) of any output overvoltage flag: Register 0x7A[7] and Register 0xFE80[4] (FAST_OVP). General input undervoltage fault (same data as in Register 0x7C[4]). Temperature fault or warning. Communications, memory, or logic fault. A fault or warning not listed in Register 0x78[7:1]. INPUT 0x79[13] MFR 0x79[12] POWER_GOOD# 0x79[11] UNKNOWN 0x79[8] 0x79[15] Action Any fault or warning on the output voltage (overvoltage, undervoltage, fast OVP, or accurate OVP). Input voltage, input current, or input power fault or warning (same data as in Register 0x7C, Bits[7:0]). Manufacturer-specific fault or warning (same data as in Register 0xFE80, Register 0xFE81, and Register 0xFE82). Power good. This flag is a programmable combination of other internal flags and refers to the condition of the output voltage. This flag sets the PGOOD pin. The POWER_GOOD# flag is an inverted version of the PGOOD pin. A fault or warning not listed in Bits[15:1]. Rev. 0 | Page 26 of 82 Programmable Programmable Programmable PGOOD pin Data Sheet ADP1048W Name STATUS_VOUT (0x7A) VOUT_OV_FAULT VOUT_OV_WARN VOUT_UV_WARN VOUT_UV_FAULT STATUS_INPUT (0x7C) VIN_OV_FAULT VIN_UV_WARN VIN_UV_FAULT VIN_LOW IIN_OC_FAULT Address Description Action 0x7A[7] 0x7A[6] 0x7A[5] 0x7A[4] The output voltage is above the VOUT_OV_FAULT_LIMIT. The output voltage is above the VOUT_OV_WARN_LIMIT. The output voltage is below the VOUT_UV_WARN_LIMIT. The output voltage is below the VOUT_UV_FAULT_LIMIT. Programmable 0x7C[7] 0x7C[5] 0x7C[4] 0x7C[3] 0x7C[2] Programmable IIN_OC_WARN 0x7C[1] PIN_OP_WARN STATUS_TEMPERATURE (0x7D) OT_FAULT OT_WARN 0x7C[0] The input voltage on VAC is larger than the value in VIN_OV_FAULT_LIMIT. The input voltage on VAC is smaller than the value in VIN_UV_WARN_LIMIT. The input voltage on VAC is smaller than the value in VIN_UV_FAULT_LIMIT. VAC is lower than VIN_OFF. This signal shuts down the power supply. The input current measured on the CS ADC is larger than the value in IIN_OC_FAULT_LIMIT. The input current measured on the CS ADC is larger than the value in IIN_OC_WARN_LIMIT. Input overpower warning. 0x7D[7] 0x7D[6] The measured temperature is above the value set in OT_FAULT_LIMIT. The measured temperature is above the value set in OT_WARN_LIMIT. Programmable Programmable Programmable Can set AC_OK flag Programmable Can set AC_OK flag PMBus FAULT FLAG RESPONSE Concurrent Faults All standard PMBus fault response registers follow the same format. The six standard PMBus fault response registers are When multiple faults occur at the same time, the state machine executes the response that has the highest priority. Flag priority is determined by the response of the faults as determined by Bits[7:6]. The higher the number in these two bits, the higher the priority. • • • • • • VOUT_OV_FAULT_RESPONSE (Register 0x41) VOUT_UV_FAULT_RESPONSE (Register 0x45) OT_FAULT_RESPONSE (Register 0x50) VIN_OV_FAULT_RESPONSE (Register 0x56) VIN_UV_FAULT_RESPONSE (Register 0x5A) IIN_OC_FAULT_RESPONSE (Register 0x5C) The standard PMBus fault response registers are composed of eight bits: Bits[7:6] define the response type, Bits[5:3] define the retry settings, and Bits[2:0] contain the delay information. Bits[7:6] define the response type as follows: • • • Bits[7:6] = 00 (ignore). When the corresponding fault flag is set, no action is taken and the power supply continues to operate normally. Bits[7:6] = 01 or 10 (shutdown and retry). When the corresponding fault flag is set, the system shuts down and then retries for the number of times programmed in Bits[5:3]. The difference between the 01 and 10 options is that when Bits[7:6] = 01, a debounce (programmed in Bits[2:0]) is applied to the flag. Bits[7:6] = 11 (disable output). When the corresponding fault flag is set, the system does not enter a shutdown/soft start sequence. Instead, the output is disabled indefinitely until the flag is cleared. Care must be taken when selecting this option because it may cause the system to stall in an endless loop. For example, if OVP is programmed to disable the output (Bits[7:6] = 11) and OCP is programmed to shut down and retry after a delay (Bits[7:6] = 01), and both faults occur at the same time, the OVP action is executed first. If the OVP condition is cleared and the OCP flag is still set, the programmed action for OCP is executed. If two or more faults occur at the same time and all the faults have the same response priority, the fault with the smallest retry setting takes priority. For example, if one fault has a retry setting programmed to 011 and the other has a retry setting of 001, the lower number of retries is executed. Rev. 0 | Page 27 of 82 ADP1048W Data Sheet MANUFACTURER-SPECIFIC FLAG RESPONSE Four different actions can be programmed for this flag. Manufacturer-specific flags follow a different response from the standard PMBus flags because these flags are much faster and, in some cases, operate on a pulse-by-pulse basis. • • 00 (ignore, do nothing). No action is taken. 01 (shut down and soft start). The power supply is shut down, and a soft start sequence is initiated after the delay programmed in the VOUT_OV_FAULT_RESPONSE register (Register 0x41, Bits[2:0]). 10 (immediate shutdown and wait for PSON). The power supply is shut down until the PSON signal is received. 11 (disable the PWM until the flag is cleared). The PWM is disabled until the flag is cleared; no soft start is done. FAST OCP Flag Response (Register 0xFE00) The fast OCP flag responds to an overcurrent condition that occurs on the comparator connected to the ILIM pin. This comparator performs a pulse-by-pulse current limiting function (see the Fast Overcurrent Protection (ILIM Pin) section). Four different actions can be programmed for this flag using Bits[7:6]. Regardless of the programmed flag response, the PWM pulse is always terminated when the threshold programmed for the comparator is crossed. • • • 00 (ignore, do nothing). No action is taken. The PWM pulses are still terminated as long as the OCP condition persists. 01 (shut down and soft start). The power supply is shut down, and a soft start sequence is initiated after the delay that is programmed in the IIN_OC_FAULT_RESPONSE register (Register 0x5C, Bits[2:0]). 10 (shutdown and wait for PSON). After the number of switching cycles programmed in Bits[5:4], the power supply is shut down until the PSON signal is received. 11 (disable the PWM until the flag is cleared). After the number of switching cycles programmed in Bits[5:4], the PWM is disabled until the flag is cleared; no soft start is initiated. FAST OVP Flag Response (Register 0xFE01) The fast OVP flag responds to an overvoltage condition on the programmable comparator connected to the OVP pin. This comparator constantly monitors the output voltage and its operation (see the Fast Overvoltage Protection (OVP Pin) section). • OLP Flag Response (Register 0xFE02) The OLP flag responds to differences between the OVP and VFB pins. Open-loop protection detects a difference in voltage in excess of ~100 mV, which equates to approximately 6.6% of the full-scale range (see the Open-Loop Protection section). Four different actions can be programmed for this flag. • • 00 (ignore, do nothing). No action is taken. 01 (shut down and soft start). The power supply is shut down, and a soft start sequence is initiated after the delay programmed in the VOUT_OV_FAULT_RESPONSE register (Register 0x41, Bits[2:0]). 10 (immediate shutdown and wait for PSON). The power supply is shut down until the PSON signal is received. 11 (disable the PWM until the flag is cleared). The PWM is disabled until the flag is cleared; no soft start is done. • • VDD and VCORE OV Flag Response (Register 0xFE03 and Register 0xFE04) These two flags respond to an overvoltage condition on the VDD (3.3 V) and VCORE (2.5 V) rails. These rails must be properly decoupled and filtered to guarantee proper operation of the digital controller. The controller can be programmed to ignore the flags or to shut down and restart. A debounce time of 2.56 μs or 660 μs can be set. The controller can also be instructed to reload the contents of the EEPROM upon restart or to resume operation without reloading the EEPROM contents. Reloading the contents of the EEPROM to RAM prevents device malfunction if the RAM contents have been corrupted during the overvoltage condition. ILIM FAST OCP BLANKING AND DEBOUNCE TERMINATE PWM PULSE TIMEOUT 1 TO 8 TIMES Figure 23. Fast OCP Flag Rev. 0 | Page 28 of 82 FLAG SET, PROGRAMMED ACTIONS 12535-024 • • Data Sheet ADP1048W MONITORING FUNCTIONS OVERTEMPERATURE PROTECTION (OTP) Voltage, current, power, and temperature measurements are taken by the ADP1048W. These values are stored in the following registers and can be read through the PMBus interface. If the temperature sensed at the RTD pin exceeds the programmable fault threshold, the OTP flag is set, and the power supply can be programmed to shut down. A PTC or NTC thermistor can be used. • • • • • To set the fault and warning thresholds for OTP, program Register 0xFE19 and Register 0xFE1A, respectively. To set the temperature hysteresis for the fault and warning thresholds, program Register 0xFE3F. The response to an OTP fault flag is programmable in Register 0x50. Input voltage measurement (Register 0x88) Output voltage measurement (Register 0x8B) Input current measurement (Register 0x89) Input power measurement (Register 0x97) Temperature measurement (Register 0xFE86) AC_OK AND PGOOD SIGNALS The ADP1048W provides a FLAG_FAULT_ID register (Register 0xFE07) that records the first fault that causes a system shutdown. For example, if the overtemperature (OT) fault causes the system to shut down, the OT_FAULT flag (0011) is stored in the FLAG_ FAULT_ID register (Register 0xFE07, Bits[3:0]). In addition, the flag ID of the fault that occurred before the fault that caused the system shutdown is included in Bits[7:4] of Register 0xFE07. The contents of this register are stored until read by the user. The flag ID is also saved in EEPROM when the shutdown occurs. In this way, it is possible to determine the cause of a shutdown in case of system failure. The ADP1048W has two digital status pins: AC_OK and PGOOD. Both signals represent an OR function for a programmable list of internal flags. Users can blank some of these flags to tailor the AC_OK and PGOOD signals to their needs using Register 0xFE0B and Register 0xFE0A, respectively. When the signals on the AC_OK and PGOOD pins are set, the corresponding internal flag is also set. The programmable delay block acts like a debounce. That is, the signal must be active for at least the duration of the programmed delay before the flag is set. The debounce times for the AC_OK and PGOOD pins can be programmed separately in Register 0xFE05. PGOOD_FLAGS_LIST (PROGRAMMABLE LIST OF FLAGS) REG 0xFE0A PROGRAMMABLE DELAY BLOCK PGOOD AC_OK_FLAGS_LIST (PROGRAMMABLE LIST OF FLAGS) REG 0xFE0B PROGRAMMABLE DELAY BLOCK AC_OK 12535-025 FIRST ERROR FAULT Figure 24. AC_OK and PGOOD Signals Table 13. Flags Available to Program the AC_OK and PGOOD Pins AC_OK_FLAGS_LIST (Register 0xFE0B)1 VIN_LOW (always checked) VIN_UV_FAULT (Bit 7) VIN_UV_WARN (Bit 6) IIN_OC_FAULT (Bit 5) IIN_OC_WARN (Bit 4) FAST_OCP (Bit 3) AC_LINE_PERIOD (Bit 2) BROWN_OUT (Bit 1) INRUSH (Bit 0) 1 PGOOD_FLAGS_LIST (Register 0xFE0A)1 VOUT_OV_FAULT (always checked) VOUT_UV_FAULT (Bit 7) VOUT_OV_WARN (Bit 6) FAST_OVP (Bit 5) OLP (Bit 4) FAST_OCP (Bit 3) IIN_OC_FAULT (Bit 2) OT_FAULT (Bit 1) FAST_LOOP (Bit 0) To blank one or more flags so that the AC_OK or PGOOD pin ignores it, set the corresponding bit to 1 in Register 0xFE0A or Register 0xFE0B. Rev. 0 | Page 29 of 82 ADP1048W Data Sheet ADVANCED FEATURES The advanced features of the ADP1048W include PWM FREQUENCY SYNCHRONIZATION Frequency dithering for EMI noise minimization PWM frequency synchronization with external source Smart output voltage: real-time efficiency optimization by changing the output voltage based on ac line and output power Smart switching frequency: real-time efficiency optimization by changing the switching frequency Current loop filter for light load: real-time THD optimization at light load conditions Phase shedding: real-time efficiency optimization by shutting down one phase Current loop feedforward: power factor and THD optimization at light load conditions Bridgeless boost operation The device can synchronize the internal PWM clock with an external clock frequency; the external source must be within the minimum and maximum synchronization range programmed in the device. To enable PWM frequency synchronization, set Register 0xFE4F, Bit 1, to 1. All advanced features other than bridgeless boost operation are enabled by setting the appropriate bit in Register 0xFE4F. The device synchronizes to the external clock frequency as follows: FREQUENCY DITHERING (SPREAD SPECTRUM) The PWM signal can be altered digitally to optimize for EMI reduction (see Figure 25). For a wider but lower EMI spectrum, the switching frequency varies with the rectified line voltage. The switching cycle changes linearly with time from 87.5% to 112.5% of the nominal value, resulting in a frequency variation of 114% to 89% of the nominal value. To enable frequency dithering, set Register 0xFE4F, Bit 0, to 1. To configure the dithering period, program Register 0xFE1D. VREC The capture range for the SYNC period is 87.5% to 112.5% of the programmed switching period. The switching frequency synchronized to the SYNC pin is limited by the frequency set in Register 0xFE1B. The maximum range for the synchronized frequency is from 89% to 114% of the programmed switching frequency. The delay between the external SYNC signal and the start of the internal switching cycle can be programmed using Register 0xFE4C. 1. 2. 3. The device attempts to determine the external clock period, averaging it over seven cycles (frequency capture mode). After the period of the SYNC signal is determined, the internal PWM clock is adjusted until the phase is also aligned. At that point, internal and external clocks are synchronized (phase capture mode). Each internal switching cycle is terminated after the SYNC rising edge is detected (pulse-by-pulse synchronization). If the external SYNC signal is lost at any time or if the period exceeds the minimum/maximum limit, the internal clock goes back to the maximum period set in Register 0xFE1B. During the soft start phase, the SYNC pin is ignored and the clock frequency is not synchronized. Interleaved operation of a multiphase PFC circuit is realized by using the SYNC pin of several ADP1048W controllers. The frequency synchronization feature is optional. When enabled, the switching frequency can be programmed to 1, 1/2, 1/3, or 1/4 of the SYNC frequency using Register 0xFE1E. TIME SWITCHING CYCLE SMART OUTPUT VOLTAGE (LOAD LINE) 112.5% t SW To achieve higher efficiency, the output voltage can be programmed according to the load power and input voltage condition (see Figure 26). To enable the smart output voltage feature, set Register 0xFE4F, Bit 2, to 1. tSW 87.5% t SW OUTPUT VOLTAGE TIME SUPER HIGH LINE VOH SWITCHING FREQUENCY VOH2 114% f SW VOH1 fSW 89% f SW VOL2 HIGH LINE LOW LINE VOL1 1/f DITHER 2/f DITHER 12535-026 POWER TIME Figure 25. Switching Frequency Dithering Control Rev. 0 | Page 30 of 82 P1 P2 100% Figure 26. Smart Output Voltage Control (Load Line) 12535-027 Data Sheet ADP1048W When the rms value of the input voltage is higher than the super high line input (for example, 250 V), the load line is flat, that is, the output voltage remains at VOH, which is independent of the power. To avoid output voltage oscillation when the input voltage is around the super high line level, voltage hysteresis can be programmed using Register 0xFE4D. It is recommended that at least 16 V of hysteresis be programmed. CURRENT LOOP FILTER FOR LIGHT LOAD To achieve low THD under light load conditions, the ADP1048W offers current loop filter presets for light load operation under both high line input and low line input (see Figure 28). To enable the current loop filter for light load feature, set Register 0xFE4F, Bit 5, to 1. AC LINE HIGH LINE LIGHT LOAD When the rms value of the input voltage is lower than the super high line input but higher than the high line threshold, there is a load line between P1 and P2 in terms of power. The output voltage varies between VOH1 and VOH2 as a linear function of the output power when the output power falls within the range between P1 and P2. The power levels of P1 and P2 are programmable using Register 0xFE44 and Register 0xFE45, respectively. When the power is below P1, the output voltage remains unchanged at VOH1. When the power is higher than P2, the output voltage remains unchanged at VOH2. The bottom load line in Figure 26 applies when the rms value of the input voltage is lower than the low line threshold. The output voltage varies between VOL1 and VOL2 as a linear function of the output power when the output power falls within the range between P1 and P2. When the power is below P1, the output voltage remains unchanged at VOL1. When the power is higher than P2, the output voltage remains unchanged at VOL2. The user can program values for VOH, VOH2, VOH1, VOL2, and VOL1 using Register 0xFE4A, Register 0xFE49, Register 0xFE48, Register 0xFE47, and Register 0xFE46, respectively. SMART SWITCHING FREQUENCY For higher efficiency, the switching frequency of the ADP1048W can be programmed according to the load power condition (see Figure 27). To enable the smart switching frequency feature, set Register 0xFE4F, Bit 3, to 1. SWITCHING FREQUENCY HIGH LINE HIGH/LOW LINE THRESHOLD LOW LINE LIGHT LOAD LIGHT LOAD LOW LINE POWER THRESHOLD INPUT POWER 12535-029 Three load lines address super high line, high line, and low line input voltage conditions. Figure 28. Current Loop Filter at Light Load Condition When the input power drops below the low power threshold, PTH (set in Register 0xFE32), the current loop filter switches to the light load filter after four full line cycles. When the input power goes above PTH plus the programmed hysteresis, the current loop filter switches back to the normal mode filter immediately. This applies to both high line and low line input. PHASE SHEDDING To achieve high efficiency at light load, the ADP1048W can shut down one PWM output under light load conditions. When the input power drops below the low power threshold, PTH (set in Register 0xFE32), one PWM output is disabled. When the input power goes above the low power threshold plus power hysteresis (set in Register 0xFE4E), the PWM resumes operation. To enable phase shedding for the ADP1048W, set Register 0xFE4F, Bit 4, to 1. CURRENT LOOP FEEDFORWARD fS Current loop feedforward is implemented in the ADP1048W to improve the power factor and reduce THD under light load conditions (see Figure 29). To enable current loop feedforward, set Register 0xFE4F, Bit 6, to 1. FULL POWER Figure 27. Smart Switching Frequency Control IL The smart switching frequency feature uses two different switching frequencies for heavy load and light load conditions. When the output power is lower than the low power threshold, PTH, the PFC circuit switches at the fSL frequency. When the output power is higher than PTH plus power hysteresis, the circuit switches at the normal set frequency, fS. Hysteresis can be programmed in Register 0xFE4E. The user can program the values for fSL and PTH in Register 0xFE1C and Register 0xFE32, respectively. Rev. 0 | Page 31 of 82 IREF + – HI (z) DUTY CYCLE + + VAC –VREF Figure 29. Current Loop Feedforward 12535-030 POWER PTH 12535-028 fSL ADP1048W Data Sheet BRIDGELESS BOOST OPERATION During the positive ac line phase, only one boost stage is effectively working. The second one is passive, and the current flows in Q2 from the source to the drain. Turning the Q2 FET fully on during this phase allows conduction losses in Q2 to be minimized. The bridgeless boost configuration allows removal of the conduction losses caused by the input bridge of the PFC converter. In this configuration, it is necessary to drive the two power MOSFETs separately to achieve the highest efficiency. The ADP1048W can provide such signals. The IBAL pin is used to detect the ac line phase and zero crossings. Note that the maximum rating on the IBAL pin is VDD + 0.3 V; therefore, a clamp circuit must be connected to the IBAL pin. When the ac line phase becomes negative, the roles of Q1 and Q2 are reversed, and Q2 actively switches while Q1 is always on. The phase information is detected from the ac line via the IBAL pin. During the soft start phase, both FETs are switching as a precautionary measure; the same happens when the phase information on the IBAL pin becomes corrupted or inaccurate. AC INPUT T3 VOUT RELAY T1 T2 BULK CAPACITOR VREC Q1 Q2 3.3V 1 AGND VDD 24 2 VAC RES 23 3 VFB RTD 22 4 OVP ADD 21 5 PGND SDA 20 6 ILIM SCL 19 7 IBAL 8 CS– INRUSH 17 9 PMBus CS+ PGOOD 16 10 DGND AC_OK 15 11 PSON PWM2 14 12 VCORE PWM 13 12535-031 T1 + T2 + T3 SYNC 18 ADP1048W Figure 30. Schematic of Bridgeless PFC Circuit VAC IBAL PIN 12535-032 PWM PWM2 Figure 31. Bridgeless Boost Operation Rev. 0 | Page 32 of 82 Data Sheet ADP1048W POWER SUPPLY SYSTEM CALIBRATION AND TRIM The ADP1048W allows the entire power supply to be calibrated and trimmed digitally in the production environment. The device can calibrate items including the output voltage, input voltage, input current, and input power, and it can trim for tolerance errors introduced by sense resistors, current transformers, and resistor dividers, as well as for its own internal circuitry. The device comes factory trimmed at 90% of the input range at a 3.3 V supply, but it can be re-trimmed by the user to compensate for the errors introduced by external components. With the exception of the gain and offset trim registers for input power, the trim registers must be unlocked for write access. To unlock the trim registers, write to the TRIM_PASSWORD register (Register 0xD6). 2. For VAC offset trim, adjust the value in Register 0xFE53. CURRENT SENSE GAIN AND OFFSET TRIM The current sense can be calibrated digitally to remove any errors due to external components. 1. 2. OUTPUT VOLTAGE (VFB) CALIBRATION AND TRIM The voltage sense inputs are optimized for sensing signals at 90% of the input range and cannot sense signals greater than 1.6 V. In a high voltage system, a resistor divider is required to reduce the high voltage signal to below 1.6 V. It is recommended that the high voltage signal be reduced to 1 V for best performance. The resistor divider can introduce errors, which must be trimmed out as follows: 1. Turn on the power supply with no load attached. The output voltage is divided down by the feedback resistor divider to supply 1 V across the VFB and AGND pins. 2. 3. Use a calibrated multimeter to perform the output voltage reading. Adjust the VFB ADC gain trim register (Register 0xFE41) until the power supply outputs the exact value in the READ_VOUT register (Register 0x8B). INPUT VOLTAGE (VAC) GAIN AND OFFSET TRIM The input voltage sense point on the power rail requires an external resistor divider to bring the signal within the operating input range of the VAC ADC (0 V to 1.6 V). The resistor divider can introduce errors, which must be trimmed out as follows: 1. Apply the maximum line voltage value to the input of the power supply. The VAC resistor divider divides this voltage down at the VAC pin. The VAC resistor divider is programmed in linear format using the VIN scale monitor register (Register 0xFE3B). Adjust the VAC ADC gain trim register (Register 0xFE40) until the VAC value (Register 0x88, READ_VIN) equals the input voltage reading from a calibrated multimeter. This step trims for errors in the resistor divider network. Apply the maximum load to the output with the low line input voltage. To match the input current reading at the maximum nominal input current, adjust the CS ADC gain trim register until the CS value (Register 0x89, READ_IIN) equals the measured result of the input current from calibrated equipment. If the 500 mV input range is used, adjust Register 0xFE42. If the 750 mV range is used, adjust Register 0xFE7E. For CS offset trim, adjust the values in Register 0xFE54 (500 mV input range) or Register 0xFE7F (750 mV input range). INPUT POWER GAIN AND OFFSET TRIM The input power trim has separate trim registers for high line and low line input. 1. 2. 3. 4. Apply the maximum load to the output with the low line input voltage. Adjust the power metering gain trim for low line input register (Register 0xFE34) until the input power value in the READ_PIN register (Register 0x97) equals the measured result of the input power from calibrated equipment. Apply the maximum load to the output with the high line input voltage. Adjust the power metering gain trim for high line input register (Register 0xFE8F) until the input power value in the READ_PIN register (Register 0x97) equals the measured result of the input power from the calibrated equipment. For input power offset trim, adjust the values in Register 0xFE33 (for low line input) and Register 0xFE8E (for high line input). Rev. 0 | Page 33 of 82 ADP1048W Data Sheet PMBus DIGITAL COMMUNICATION The PMBus slave allows a device to interface to a PMBuscompliant master device as specified by the PMBus Power System Management Protocol Specification (Revision 1.1, February 5, 2007). The PMBus slave is a 2-wire interface that can be used to communicate with other PMBus-compliant devices and is compatible in a multimaster, multislave bus configuration. FEATURES The function of the PMBus slave is to decode the command sent from the master device and respond as requested. Communication is established using an I2C-like 2-wire interface with a clock line (SCL) and data line (SDA). The PMBus slave is designed to externally move chunks of 8-bit data (bytes) while maintaining compliance with the PMBus protocol. The PMBus protocol is based on the SMBus Specification (Version 2.0, August 2000). The SMBus specification is, in turn, based on the Philips I2C Bus Specification (Version 2.1, January 2000). The PMBus incorporates the following features: • • • • • • • Slave operation on multiple device systems 7-bit addressing 100 kHz and 400 kHz data rates General call address support Support for clock low extension Separate multiple byte receive and transmit FIFO Extensive fault monitoring When communicating with the master device, it is possible for illegal or corrupted data to be received by the PMBus slave device. In this case, the PMBus slave device responds to the invalid command or data as defined by the PMBus specification, and indicates to the master device that an error or fault condition has occurred. This method of handshaking can be used as a first level of defense against programming of the slave device that can potentially damage the chip or system. The PMBus specification defines a set of generic PMBus commands that is recommended for a power management system. However, each PMBus device manufacturer can choose to implement and support certain commands as it deems fit for its system. In addition, the PMBus device manufacturer can choose to implement manufacturer-specific commands whose functions are not included in the generic PMBus command set. The list of standard PMBus and manufacturer-specific commands can be found in the Standard PMBus Commands Supported by the ADP1048Wsection and the Manufacturer-Specific PMBus Command section. PMBus ADDRESS Control of the ADP1048W is implemented via the I2C interface. The ADP1048W is connected to the bus as a slave device under the control of a master device. The PMBus address of the ADP1048W is set by connecting an external resistor from the ADD pin to ground. Table 14 lists the recommended resistor values and associated PMBus addresses. Eight different addresses can be used. OVERVIEW The PMBus slave module is a 2-wire interface that can be used to communicate with other PMBus-compliant devices. Its transfer protocol is based on the Philips I2C transfer mechanism. The ADP1048W is always configured as a slave device in the overall system. The ADP1048W communicates with the master device using one data pin (SDA) and one clock pin (SCL). Because the ADP1048W is a slave device, it cannot generate the clock signal. However, it is capable of clock-stretching the SCL line to put the master device in a wait state when it is not ready to respond to the master request. Communication is initiated when the master device sends a command to the PMBus slave device. Commands can be read or write commands, in which case, data is transferred between the devices in a byte wide format. Commands can also be send commands, in which case, the command is executed by the slave device upon receiving the stop bit. The stop bit is the last bit in a complete data transfer, as defined in the PMBus/I2C communication protocol. During communication, the master and slave devices send acknowledge (A) or no acknowledge (A) bits as a method of handshaking between devices. See the PMBus specification for a more detailed description of the communication protocol. Table 14. PMBus Address Settings Address 0x58 0x59 0x5A 0x5B 0x5C 0x5D 0x5E 0x5F ADD Pin Resistor Value (kΩ) 10 (or connect directly to AGND) 30 50 69 89 109 128 148 (or connect directly to VDD) If an incorrect resistor value is used and the resulting I2C address is close to a threshold between two addresses, the I2C_ADDRESS flag is set (Bit 4 of Register 0xFE81). The recommended resistor values in Table 14 can vary by ±2 kΩ. Therefore, it is recommended that 1% tolerance resistors be used on the ADD pin. The device responds to the standard PMBus broadcast address (general call) of 0x00. Rev. 0 | Page 34 of 82 Data Sheet ADP1048W DATA TRANSFER “A” represents the ACK (acknowledge) bit. The ACK bit is typically active low (Logic 0) if the transmitted byte is successfully received by a device. However, when the receiving device is the bus master, the acknowledge bit for the last byte read is a Logic 1, indicated by A. Format Overview The PMBus slave follows the transfer protocol of the SMBus specification, which is based on the fundamental transfer protocol format of the Philips I2C Bus Specification, dated January 2000. Data transfers are byte wide, lower byte first. Each byte is transmitted serially, most significant bit (MSB) first. A typical transfer is diagrammed in Figure 32. See the SMBus and I2C specifications for an in-depth discussion of the transfer protocols. 7-BIT SLAVE ADDRESS W A 8-BIT DATA A Data transfer using the PMBus slave is established using PMBus commands. The PMBus specification requires that all PMBus commands start with a slave address with the RW bit cleared (set to 0), followed by the command code. All PMBus commands supported by the ADP1048W follow one of the protocol types shown in Figure 33 through Figure 39. P 09696-135 S Command Overview MASTER TO SLAVE SLAVE TO MASTER The PMBus slave module also supports manufacturer-specific extended commands. These commands follow the same protocol as the standard PMBus commands. However, the command code consists of the following two bytes: Figure 32. Basic Data Transfer Figure 32 through Figure 39 use the following abbreviations: S = start condition Sr = repeated start condition P = stop condition R = read bit W = write bit A = acknowledge bit (0) A = acknowledge bit (1) • • The command code extension, 0xFE The extended command code, 0x00 to 0xFF Using the manufacturer-specific extended commands, the PMBus device manufacturer can add an additional 256 manufacturer-specific commands to its PMBus command set. SLAVE ADDRESS W A COMMAND CODE A P 12535-136 S MASTER TO SLAVE SLAVE TO MASTER Figure 33. Send Byte Protocol W A COMMAND CODE A DATA BYTE A P 12535-137 SLAVE ADDRESS S MASTER TO SLAVE SLAVE TO MASTER Figure 34. Write Byte Protocol W COMMAND CODE A DATA BYTE LOW A A DATA BYTE HIGH A P 12535-138 SLAVE ADDRESS S MASTER TO SLAVE SLAVE TO MASTER Figure 35. Write Word Protocol W A COMMAND CODE A Sr SLAVE ADDRESS R A DATA BYTE A P 12535-139 SLAVE ADDRESS S MASTER TO SLAVE SLAVE TO MASTER Figure 36. Read Byte Protocol SLAVE ADDRESS W A COMMAND CODE A Sr SLAVE ADDRESS R A DATA BYTE LOW A DATA BYTE HIGH A P 12535-140 S MASTER TO SLAVE SLAVE TO MASTER Figure 37. Read Word Protocol SLAVE ADDRESS W A COMMAND CODE A BYTE COUNT =N A DATA BYTE 1 A DATA BYTE N A P 12535-141 S MASTER TO SLAVE SLAVE TO MASTER Figure 38. Block Write Protocol Rev. 0 | Page 35 of 82 ADP1048W SLAVE ADDRESS W A COMMAND CODE A Sr SLAVE ADDRESS R A BYTE COUNT =N A DATA BYTE 1 A DATA BYTE N A P 12535-142 S Data Sheet MASTER TO SLAVE SLAVE TO MASTER Figure 39. Block Read Protocol Clock Generation and Stretching FAST MODE The ADP1048W is always a PMBus slave device in the overall system; therefore, the device never needs to generate the clock, which is done by the master device in the system. However, the PMBus slave device is capable of clock stretching to put the master in a wait state. By stretching the SCL signal during the low period, the slave device communicates to the master device that it is not ready and that the master device must wait. Fast mode (400 kHz) uses essentially the same mechanics as the standard mode of operation; the electrical specifications and timing are most affected. The PMBus slave is capable of communicating with a master device operating in standard mode (100 kHz) or fast mode. Conditions where the PMBus slave device stretches the SCL line low include the following: • • • The master device is transmitting at a higher baud rate than the slave device. The receive buffer of the slave device is full and must be read before continuing. This prevents a data overflow condition. The slave device is not ready to send data that the master has requested. Note that the slave device can stretch the SCL line only during the low period. Also, whereas the I2C specification allows indefinite stretching of the SCL line, the PMBus specification limits the maximum time that the SCL line can be stretched, or held low, to 25 ms, after which the device must release the communication lines and reset its state machine. GENERAL CALL SUPPORT The PMBus slave is capable of decoding and acknowledging a general call address. The PMBus device responds to both its own address and the general call address (0x00). The general call address enables all devices on the PMBus to be written to simultaneously. FAULT CONDITIONS The PMBus protocol provides a comprehensive set of fault conditions that must be monitored and reported. These fault conditions can be grouped into two major categories: communication faults and monitoring faults. Communication faults are error conditions associated with the data transfer mechanism of the PMBus protocol. Monitoring faults are error conditions associated with the operation of the PMBus device, such as output overvoltage protection, and are specific to each PMBus device. These fault conditions are described in the Power Supply System and Fault Monitoring section. TIMEOUT CONDITION A timeout condition occurs if any single SCL clock pulse is held low for longer than the tTIMEOUT of 25 ms (min). Upon detecting the timeout condition, the PMBus slave device has 10 ms to abort the transfer, release the bus lines, and be ready to accept a new start condition. The device initiating the timeout is required to hold the SCL clock line low for at least tTIMEOUT MAX = 35 ms, guaranteeing that the slave device is given enough time to reset its communication protocol. Note that all PMBus commands must start with the slave address with the R/W bit cleared (set to 0), followed by the command code. This is also true when using the general call address to communicate with the PMBus slave device. Rev. 0 | Page 36 of 82 Data Sheet ADP1048W DATA TRANSMISSION FAULTS DATA CONTENT FAULTS Data transmission faults occur when two communicating devices violate the PMBus communication protocol, as specified in the PMBus specification. See the PMBus specification for more information about each fault condition. Data content faults occur when data transmission is successful, but the PMBus slave device cannot process the data that is received from the master device. Corrupted Data, PEC (Item 10.8.1) All PMBus commands start with a slave address with the R/W bit cleared (set to 0), followed by the command code. If a host starts a PMBus transaction with R/W set in the address phase (equivalent to an I2C read), the PMBus slave considers this a data content fault and responds as follows: Parity error checking. Not supported. Sending Too Few Bits (Item 10.8.2) Transmission is interrupted by a start or stop condition before a complete byte (eight bits) has been sent. Not supported; any transmitted data is ignored. Reading Too Few Bits (Item 10.8.3) Transmission is interrupted by a start or stop condition before a complete byte (eight bits) has been read. Not supported; any received data is ignored. Improperly Set Read Bit in the Address Byte (Item 10.9.1) • • • • ACKs the address byte NACKs the command and data bytes Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE register Host Sends or Reads Too Few Bytes (Item 10.8.4) Invalid or Unsupported Command Code (Item 10.9.2) If a host ends a packet with a stop condition before the required bytes are sent/received, it is assumed that the host intended to stop the transfer. Therefore, the PMBus does not consider this to be an error and takes no action, except to flush any remaining bytes in the transmit FIFO. If an invalid or unsupported command code is sent to the PMBus slave, the code is considered to be a data content fault, and the PMBus slave responds as follows: Host Sends Too Many Bytes (Item 10.8.5) • • • NACKs the illegal/unsupported command byte and data bytes Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE register If a host sends more bytes than are expected for the corresponding command, the PMBus slave considers this a data transmission fault and responds as follows: Reserved Bits (Item 10.9.5) • • • Write to Read-Only Commands NACKs all unexpected bytes as they are received Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE register Accesses to reserved bits are not a fault. Writes to reserved bits are ignored, and reads from reserved bits return 0. Host Reads Too Many Bytes (Item 10.8.6) If a host performs a write to a read-only command, the PMBus slave considers this a data content fault and responds as follows: If a host reads more bytes than are expected for the corresponding command, the PMBus slave considers this a data transmission fault and responds as follows: • • • • • Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE register Device Busy (Item 10.8.7) The PMBus slave device is too busy to respond to a request from the master device. Not supported. NACKs all unexpected data bytes as they are received Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE register Note that this is the same error described in the Host Sends Too Many Bytes (Item 10.8.5) section. Read from Write-Only Commands If a host performs a read from a write-only command, the PMBus slave considers this a data content fault and responds as follows: • • Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE register Note that this is the same error described in the Host Reads Too Many Bytes (Item 10.8.6) section. Rev. 0 | Page 37 of 82 ADP1048W Data Sheet EEPROM The ADP1048W has a built-in EEPROM controller that is used to communicate with the embedded 8K × 8-byte EEPROM. The EEPROM, also called Flash®EE, is partitioned into two major blocks: the INFO block and the main block. The INFO block contains 128 8-bit bytes, and the main block contains 8K 8-bit bytes. The main block is further partitioned into 16 pages, each page containing 512 bytes. OVERVIEW The EEPROM controller provides an interface between the ADP1048W core logic and the built-in Flash/EE. The user can control data access to and from the EEPROM through this controller interface. Separate PMBus commands are available for the read, write, and erase operations to the EEPROM. Communication is initiated by the master device sending a command to the PMBus slave device to access data from or send data to the EEPROM. Read, write, and erase commands are supported. Data is transferred between devices in a byte wide format. Using a read command, data is received from the EEPROM and transmitted to the master device. Using a write command, data is received from the master device and stored in the EEPROM through the EEPROM controller. The EEPROM allows erasing of whole pages only; therefore, to change the data of any single byte in a page, the entire page must first be erased (set high) for that byte to be writable. Subsequent writes to any bytes in that page are allowed as long as that byte has not been written to a low previously. READ OPERATION (BYTE READ AND BLOCK READ) Read from Page 0 and Page 1 Page 0 and Page 1 of the main block are reserved for storing the default settings and user settings, respectively, and are meant to prevent third-party access to this data. To read from Page 0 or Page 1, the user must first unlock the EEPROM (see the Unlock EEPROM section). After they are unlocked, Page 0 and Page 1 are readable using the EEPROM_DATA_xx commands, as described in the Read from Page 2 to Page 15 section. Note that when the EEPROM is locked, a read from Page 0 and Page 1 returns invalid data. Read from Page 2 to Page 15 PAGE ERASE OPERATION Data in Page 2 to Page 15 is always readable, even with the EEPROM locked. The data in the EEPROM main block can be read one byte at a time or in multiple bytes in series using the EEPROM_DATA_xx commands (Command Code 0xB0 to Command Code 0xBF). The main block consists of 16 equivalent pages of 512 bytes each, numbered Page 0 to Page 15. Page 0 and Page 1 of the main block are reserved for storing the default settings and user settings, respectively. The user cannot perform a page erase operation to Page 0 or Page 1. Before executing this command, the user must program the number of bytes to read using the EEPROM_NUM_RD_BYTES command (Register 0xD2). Also, the user can program the offset from the page boundary where the first read byte is returned using the EEPROM_ADDR_OFFSET command (Register 0xD3). Main Block Page Erase (Page 2 to Page 15) In the following example, three bytes from Page 4 are read from EEPROM, starting from the fifth byte of that page. W A COMMAND CODE A DATA BYTE A MASTER TO SLAVE SLAVE TO MASTER A W 0xD2 A 0x03 A P MASTER TO SLAVE SLAVE TO MASTER 2. Set address offset = 5. SLAVE ADDRESS S P SLAVE ADDRESS W A 0xD3 A 0x00 A A 0x05 P MASTER TO SLAVE SLAVE TO MASTER 3. Figure 40. Example Erase Command In this example, Command Code = 0xD4 and Data Byte = 0x0A. Read three bytes from Page 4. S SLAVE ADDRESS W BYTE COUNT = 0x03 Note that it is important to wait at least 35 ms for the page erase operation to complete before executing the next PMBus command. MASTER TO SLAVE SLAVE TO MASTER A A 0xB4 DATA BYTE 1 A A Sr ... SLAVE ADDRESS DATA BYTE 3 R A A P 12535-145 SLAVE ADDRESS S 12535-137 S Set number of return bytes = 3. 12535-144 Page 2 to Page 15 of the main block can be individually erased using the EEPROM_PAGE_ERASE command (Register 0xD4). For example, to perform a page erase of Page 10, execute the following command: 1. 12535-143 To erase any page from Page 2 to Page 15 of the main block, the EEPROM must first be unlocked for access. For instructions on how to unlock the EEPROM, see the Unlock EEPROM section. Note that the block read command can read a maximum of 256 bytes for any single transaction. Rev. 0 | Page 38 of 82 Data Sheet ADP1048W WRITE OPERATION (BYTE WRITE AND BLOCK WRITE) On power-up, Page 0 and Page 1 are also protected from read access, and the EEPROM must first be unlocked to read these pages. Before performing a write to Page 2 through Page 15 of the main block, the user must first unlock the EEPROM (see the Unlock EEPROM section). Unlock EEPROM To unlock the EEPROM, perform two consecutive writes with the correct password (default = 0x0) using the EEPROM_ PASSWORD command (Register 0xD5). The EEPROM_ UNLOCKED flag (Bit 6 of Register 0xFE81) is set to indicate that the EEPROM is unlocked for write access. Write to Page 0 and Page 1 Page 0 and Page 1 of the main block are reserved for storing the default settings and user settings, respectively. The user cannot perform a direct write operation to Page 0 or Page 1 using the EEPROM_DATA_xx commands. If the user writes to Page 0, Page 1 returns a no acknowledge. To program the register contents of Page 1 of the main block, it is recommended that the STORE_USER_ALL command be used (Command Code 0x15). See the Save Register Settings to the User Scratch Pad section. Lock EEPROM To lock the EEPROM, write any byte other than the correct password using the EEPROM_PASSWORD command (Register 0xD5). The EEPROM unlock flag is cleared to indicate that the EEPROM is locked from write access. Write to Page 2 Through Page 15 Change EEPROM Password The data in the EEPROM main block can be programmed (written to) one byte at a time or in multiple bytes in series using the EEPROM_DATA_xx commands (Command Code 0xB0 to Command Code 0xBF). Before executing this command, the user can program the offset from the page boundary where the first byte is written using the EEPROM_ADDR_OFFSET command (Register 0xD3). To change the EEPROM password, the EEPROM must first be unlocked. To change the EEPROM password, first write the correct password using the EEPROM_PASSWORD command (Register 0xD5). Immediately write the new password using the EEPROM_PASSWORD command. The password is now changed to the new password. DOWNLOADING EEPROM SETTINGS TO INTERNAL REGISTERS If the targeted page has not yet been erased, the user can erase the page as described in the Main Block Page Erase (Page 2 to Page 15) section. Download User Settings to Registers The user settings are stored in Page 1 of the EEPROM main block. These settings are downloaded from the EEPROM into the registers under the following conditions: In the following example, four bytes are written to Page 9, starting from the 256th byte of that page. S Set address offset = 256. SLAVE ADDRESS W A • A 0xD3 A 0x01 A 0x00 P 12535-146 1. MASTER TO SLAVE SLAVE TO MASTER S Write four bytes to Page 9. SLAVE ADDRESS W DATA BYTE 1 A 0xB9 A ... A DATA BYTE 4 BYTE COUNT = 4 A A Download Factory Settings to Registers P 12535-147 2. • On power-up. The user settings are automatically downloaded into the internal registers, powering up the device in a state previously saved by the user. On execution of the RESTORE_USER_ALL command (Command Code 0x16). This command allows the user to force a download of the user settings from the EEPROM main block, Page 1, into the internal registers. MASTER TO SLAVE SLAVE TO MASTER Note that the block write command can write a maximum of 256 bytes for any single transaction. EEPROM PASSWORD On power-up, the EEPROM is locked and protected from accidental writes or erases. Only reads from Page 2 to Page 15 are allowed when the EEPROM is locked. Before any data can be written (programmed) to the EEPROM, the EEPROM must be unlocked for write access. After it is unlocked, the EEPROM is opened for reading, writing, and erasing. The factory default settings are stored in Page 0 of the EEPROM main block. The factory settings can be downloaded from the EEPROM into the internal registers using the RESTORE_ DEFAULT_ALL command (Command Code 0x12). When this command is executed, the EEPROM password is also reset to the factory default setting of 0xFF. Rev. 0 | Page 39 of 82 ADP1048W Data Sheet SAVING REGISTER SETTINGS INTO EEPROM EEPROM CRC CHECKSUM The register settings cannot be saved to the factory scratch pad located in Page 0 of the EEPROM main block. This is to prevent the user from accidentally overriding the factory trim settings and default register settings. As a simple method of checking that the values downloaded from EEPROM and the internal registers are consistent, a CRC checksum is implemented. • Save Register Settings to the User Scratch Pad The register settings can be saved to the user scratch pad located in Page 1 of the EEPROM main block using the STORE_USER_ALL command (Command Code 0x15). Before this command can be executed, the EEPROM must first be unlocked for writing (see the Unlock EEPROM section). After the register settings are saved to the user scratch pad, any subsequent power cycle automatically downloads the latest stored user information from the EEPROM into the internal registers. Note that execution of the STORE_USER_ALL command automatically performs a page erase to Page 1 of the EEPROM main block, after which the registers are stored in EEPROM. Therefore, it is important to wait at least 35 ms for the operation to complete before executing the next PMBus command. • When the data from the internal registers is saved to the EEPROM (Page 1 of the main block), the total number of 1s from all the registers is counted and written into the EEPROM as the last byte of information. This is called the CRC checksum. When the data is downloaded from the EEPROM into the internal registers, a similar counter that sums all 1s from the values loaded into the registers is saved. This value is compared with the CRC checksum from the previous upload operation. If the values match, the download operation was successful. If the values differ, the EEPROM download operation failed, and the EEPROM_CRC fault flag is set (Register 0xFE81, Bit 5). To read the EEPROM CRC checksum value, execute the EEPROM_CRC_CHKSUM command (Register 0xD1). This command returns the CRC checksum accumulated in the counter during the download operation. Note that the CRC checksum is an 8-bit cyclical accumulator that wraps around to 0 when 255 is reached. Rev. 0 | Page 40 of 82 Data Sheet ADP1048W SOFTWARE GUI A free software GUI is available for programming and configuring the ADP1048W. The GUI is designed to be intuitive and dramatically reduces power supply design and development time. displaying the status of all readings, monitoring, and flags on the ADP1048W. For more information about the GUI, contact Analog Devices for the latest software and a user guide. 12535-044 The software includes filter design and power supply PWM topology windows. The GUI is also an information center, Figure 41. The ADP1048W GUI Main Window Rev. 0 | Page 41 of 82 ADP1048W Data Sheet STANDARD PMBus COMMANDS SUPPORTED BY THE ADP1048W Table 15 lists the standard PMBus commands that are implemented on the ADP1048W. Many of these commands are implemented in registers, which share the same hexadecimal value as the PMBus command code. Table 15. Standard PMBus Commands Command Code 0x01 0x02 0x03 0x10 0x12 0x15 0x16 0x19 0x20 0x21 0x29 0x2A 0x35 0x36 0x40 0x41 0x42 0x43 0x44 0x45 0x50 0x55 0x56 0x58 0x59 0x5A 0x5B 0x5C 0x5D 0x6B 0x78 0x79 0x7A Command Name OPERATION ON_OFF_CONFIG CLEAR_FAULTS WRITE_PROTECT RESTORE_DEFAULT_ALL STORE_USER_ALL RESTORE_USER_ALL CAPABILITY VOUT_MODE VOUT_COMMAND VOUT_SCALE_LOOP VOUT_SCALE_MONITOR VIN_ON VIN_OFF VOUT_OV_FAULT_LIMIT VOUT_OV_FAULT_RESPONSE VOUT_OV_WARN_LIMIT VOUT_UV_WARN_LIMIT VOUT_UV_FAULT_LIMIT VOUT_UV_FAULT_RESPONSE OT_FAULT_RESPONSE VIN_OV_FAULT_LIMIT VIN_OV_FAULT_RESPONSE VIN_UV_WARN_LIMIT VIN_UV_FAULT_LIMIT VIN_UV_FAULT_RESPONSE IIN_OC_FAULT_LIMIT IIN_OC_FAULT_RESPONSE IIN_OC_WARN_LIMIT PIN_OP_WARN_LIMIT STATUS_BYTE STATUS_WORD STATUS_VOUT Command Code 0x7C 0x7D 0x88 0x89 0x8B 0x97 0x98 0x99 0x9A 0x9B 0xB0 0xB1 0xB2 0xB3 0xB4 0xB5 0xB6 0xB7 0xB8 0xB9 0xBA 0xBB 0xBC 0xBD 0xBE 0xBF 0xD1 0xD2 0xD3 0xD4 0xD5 0xD6 0xF1 Rev. 0 | Page 42 of 82 Command Name STATUS_INPUT STATUS_TEMPERATURE READ_VIN READ_IIN READ_VOUT READ_PIN PMBUS_REVISION MFR_ID MFR_MODEL MFR_REVISION EEPROM_DATA_00 EEPROM_DATA_01 EEPROM_DATA_02 EEPROM_DATA_03 EEPROM_DATA_04 EEPROM_DATA_05 EEPROM_DATA_06 EEPROM_DATA_07 EEPROM_DATA_08 EEPROM_DATA_09 EEPROM_DATA_10 EEPROM_DATA_11 EEPROM_DATA_12 EEPROM_DATA_13 EEPROM_DATA_14 EEPROM_DATA_15 EEPROM_CRC_CHKSUM EEPROM_NUM_RD_BYTES EEPROM_ADDR_OFFSET EEPROM_PAGE_ERASE EEPROM_PASSWORD TRIM_PASSWORD EEPROM_INFO Data Sheet ADP1048W MANUFACTURER-SPECIFIC PMBus COMMANDS Table 16 lists the manufacturer-specific PMBus commands that are implemented on the ADP1048W. These commands are implemented in registers, which share the same hexadecimal value as the PMBus command code. Table 16. Manufacturer-Specific Commands Command Code 0xFE00 0xFE01 0xFE02 0xFE03 0xFE04 0xFE05 0xFE06 0xFE07 0xFE08 0xFE09 0xFE0A 0xFE0B 0xFE0C 0xFE0D 0xFE0E 0xFE0F 0xFE10 0xFE11 0xFE12 0xFE13 0xFE14 0xFE15 0xFE16 0xFE17 0xFE18 0xFE19 0xFE1A 0xFE1B 0xFE1C 0xFE1D 0xFE1E 0xFE20 0xFE21 0xFE22 0xFE23 0xFE24 0xFE25 0xFE26 0xFE27 0xFE28 0xFE29 0xFE2A 0xFE2B 0xFE2C 0xFE2D 0xFE2E Command Name CS_FAST_OCP_RESPONSE OVP_FAST_OVP_RESPONSE OLP_RESPONSE VDD3P3_RESPONSE VCORE_RESPONSE PGOOD_AC_OK_DEBOUNCE_SET PSON_SET FLAG_FAULT_ID SOFTSTART_FLAGS_BLANK1 SOFTSTART_FLAGS_BLANK2 PGOOD_FLAGS_LIST AC_OK_FLAGS_LIST PWM rising edge timing (PWM pin) PWM rising edge setting (PWM pin) PWM falling edge timing (PWM pin) PWM falling edge setting (PWM pin) PWM2 rising edge timing (PWM2 pin) PWM2 rising edge setting (PWM2 pin) PWM2 falling edge timing (PWM2 pin) PWM2 falling edge setting (PWM2 pin) PWM_SET PWM_LIMIT RTD ADC offset trim setting (MSB) RTD ADC offset trim setting (LSB) RTD ADC gain trim setting OT_FAULT_LIMIT OT_WARN_LIMIT Switching frequency setting Low power switching frequency setting Frequency dithering set Frequency synchronization set Voltage loop filter gain Voltage loop filter zero Fast voltage loop filter gain Fast voltage loop filter zero Fast voltage loop enable VAC_THRESHOLD_SET VAC_THRESHOLD_READ MIN_AC_PERIOD_SET MAX_AC_PERIOD_SET Current loop filter gain for low line input Current loop filter zero for low line input Current loop filter gain for high line input Current loop filter zero for high line input Soft start set Inrush set Command Code 0xFE2F 0xFE30 0xFE31 0xFE32 0xFE33 0xFE34 0xFE35 0xFE36 0xFE37 0xFE38 0xFE39 0xFE3A 0xFE3B 0xFE3C 0xFE3D 0xFE3E 0xFE3F 0xFE40 0xFE41 0xFE42 0xFE43 0xFE44 0xFE45 0xFE46 0xFE47 0xFE48 0xFE49 0xFE4A 0xFE4B 0xFE4C 0xFE4D 0xFE4E 0xFE4F 0xFE50 0xFE51 0xFE53 0xFE54 0xFE7E 0xFE7F 0xFE80 0xFE81 0xFE82 0xFE84 0xFE85 0xFE86 0xFE8E Rev. 0 | Page 43 of 82 Command Name FAST_OVP_FAULT_RISE FAST_OVP_FAULT_FALL Fast OVP debounce time setting Low power mode operation threshold Power metering offset trim for low line input Power metering gain trim for low line input High line limit Low line limit ILIM_TRIM Voltage loop output Exponent Read update rate VIN scale monitor IIN_GSENSE CS fast OCP blank CS fast OCP setting Temperature hysteresis VAC ADC gain trim VFB ADC gain trim CS ADC gain trim for 500 mV range IBAL gain Smart VOUT low power threshold (P1) Smart VOUT high power threshold (P2) Smart VOUT low line (VOL1) Smart VOUT low line (VOL2) Smart VOUT high line (VOH1) Smart VOUT high line (VOH2) Smart VOUT upper limit (VOH) Smart VOUT super high line SYNC delay SMART_VOUT_SUPER_HIGH_LINE_HYS POWER_HYS Advanced feature enable VOUT_OV_FAULT_HYS VIN_UV_FAULT_HYS VAC ADC offset trim CS ADC offset trim for 500 mV range CS ADC gain trim for high (750 mV) range CS ADC offset trim for high (750 mV) range Latched Flag 0 Latched Flag 1 Latched Flag 2 PWM value VAC_LINE_PERIOD Read temperature ADC Power metering offset trim for high line input ADP1048W Command Code 0xFE8F 0xFE90 0xFE91 0xFE92 0xFE93 Data Sheet Command Name Power metering gain trim for high line input Current loop filter gain for low line input and light load Current loop filter zero for low line input and light load Current loop filter gain for high line input and light load Current loop filter zero for high line input and light load Command Code 0xFE94 0xFE95 0xFE96 0xFE97 0xFE98 0xFE99 0xFE9A 0xFE9B Rev. 0 | Page 44 of 82 Command Name Smart VOUT power reading IBAL configuration Debug Flag 0 Debug Flag 1 Debug Flag 2 Debug Flag 3 Debug Flag 4 Debug Flag 5 Data Sheet ADP1048W DETAILED REGISTER DESCRIPTIONS OPERATION REGISTER Table 17. Register 0x01—OPERATION Bits 7 Bit Name Enable R/W R/W 6 [5:4] [3:2] RSVD Margin control Margin fault response RSVD R R R [1:0] R Description This bit determines the device response to the OPERATION command. 0 = immediate off (no sequencing). 1 = device on. Always reads as 0. These bits set the output voltage margin level and are hardcoded to a value of 00. These bits set the device response to an output OVP/UVP warning or fault after the output is margined. These bits are hardcoded to a value of 01. Reserved. ON_OFF_CONFIG REGISTER Table 18. Register 0x02—ON_OFF_CONFIG Bits [7:5] 4 Bit Name RSVD Power-up control R/W R R/W 3 Command enable R/W 2 Pin enable R/W 1 Control pin polarity R/W 0 Power-down delay R Description Reserved. Set the device power-up response. 0 = device powers up when power is present. 1 = device powers up only when commanded by the control pin (PSON) and the OPERATION command. Control how the device responds to the OPERATION command. 0 = ignore the OPERATION command. 1 = the OPERATION command must be set to 1 to enable the device (in addition to setting Bit 2). Control how the device responds to the value of the control pin (PSON). 0 = ignore the control pin (PSON). 1 = the control pin must be asserted to enable the device (in addition to setting Bit 3). Set the polarity of the control pin (PSON). 0 = active low. 1 = active high. Actions to take on power-down. This bit always reads as 1 (turn off the output and stop energy transfer to the output as fast as possible). CLEAR_FAULTS COMMAND Code 0x03, send byte, no data. This command clears all fault bits in all registers simultaneously. WRITE_PROTECT REGISTER Table 19. Register 0x10—WRITE_PROTECT Bits 7 6 Bit Name Write Protect 1 Write Protect 2 R/W R/W R/W 5 Write Protect 3 R/W [4:0] RSVD R Description Setting this bit disables writes to all commands except for WRITE_PROTECT. Setting this bit disables writes to all commands except for WRITE_PROTECT, OPERATION, and EEPROM_PAGE_ERASE. Setting this bit disables writes to all commands except for WRITE_PROTECT, OPERATION, EEPROM_PAGE_ERASE, ON_OFF_CONFIG, and VOUT_COMMAND. Reserved. RESTORE_DEFAULT_ALL COMMAND Code 0x12, send byte, no data. This command downloads the factory default parameters from EEPROM into operating memory. STORE_USER_ALL COMMAND Code 0x15, send byte, no data. This command copies the entire contents of operating memory into EEPROM (Page 1 of the main block). Rev. 0 | Page 45 of 82 ADP1048W Data Sheet RESTORE_USER_ALL COMMAND Code 0x16, send byte, no data. This command downloads the stored user settings from EEPROM into operating memory. CAPABILITY REGISTER This register allows host systems to determine the capabilities of the PMBus device. Table 20. Register 0x19—CAPABILITY Bits 7 [6:5] Bit Name Packet error checking Maximum bus speed R/W R R 4 [3:0] SMBALERT# RSVD R R Description Always reads as 0. Packet error checking (PEC) is not supported. Return the device PMBus speed capability. These bits are hardcoded to a value of 01 (use the 400 kHz maximum bus speed). Always reads as 0. SMBALERT# pin and SMBus alert response protocol not supported. Reserved. VOUT_MODE REGISTER This register sets and reads the format (linear, VID, direct) and exponents for VOUT related commands. Table 21. Register 0x20—VOUT_MODE Bits [7:5] [4:3] [2:0] Bit Name Mode RSVD Exponent R/W R R R/W Description Return the output voltage data format. This bit is hardcoded to use linear format. Reserved. Specify the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent is in twos complement format. VOUT_COMMAND REGISTER This register sets VOUT to the configured value. Table 22. Register 0x21—VOUT_COMMAND Bits [15:12] [11:0] Bit Name RSVD Mantissa R/W R R/W Description Reserved. Always reads as 0000. Mantissa (Y[11:0]) used in VOUT linear mode format (X = Y × 2N). VOUT_SCALE_LOOP REGISTER This register sets the K factor = VADCVOUT. Table 23. Register 0x29—VOUT_SCALE_LOOP Bits [15:11] 10 [9:0] Bit Name Exponent RSVD Mantissa R/W R/W R R/W Description Write the exponent (N) in twos complement format for K = Y × 2N. Always reads as 0. Mantissa (Y[9:0]) used in K linear mode format (K = Y × 2N). VOUT_SCALE_MONITOR REGISTER This register sets the Kr factor = VOUTVADC. Table 24. Register 0x2A—VOUT_SCALE_MONITOR Bits [15:14] [13:11] 10 [9:0] Bit Name RSVD Exponent RSVD Mantissa R/W R R/W R R/W Description Reserved. Write the exponent (N) in twos complement format for Kr = Y × 2N. Always reads as 0. Mantissa (Y[9:0]) used in Kr linear mode format (Kr = Y × 2N). Rev. 0 | Page 46 of 82 Data Sheet ADP1048W VIN_ON REGISTER This register sets the value of the input voltage to start power conversion. Table 25. Register 0x35—VIN_ON Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). VIN_OFF REGISTER This register sets the value of the input voltage to stop power conversion. Table 26. Register 0x36—VIN_OFF Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). VOUT_OV_FAULT_LIMIT REGISTER This register sets the accurate overvoltage threshold measured at the PFC output that causes an overvoltage fault condition. Table 27. Register 0x40—VOUT_OV_FAULT_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent (N) is set in the VOUT_MODE register (Register 0x20, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VOUT linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VOUT linear mode format (X = Y × 2N). VOUT_OV_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an output overvoltage fault condition. Table 28. Register 0x41—VOUT_OV_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W Description These bits determine the device response to an output overvoltage fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Rev. 0 | Page 47 of 82 ADP1048W Data Sheet Bits [5:3] Bit Name Retry setting R/W R/W [2:0] Delay times R/W Description Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-offpower-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms VOUT_OV_WARN_LIMIT REGISTER This register sets the accurate overvoltage threshold measured at the PFC output that causes an overvoltage warning condition. Table 29. Register 0x42—VOUT_OV_WARN_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent (N) is set in the VOUT_MODE register (Register 0x20, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VOUT linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VOUT linear mode format (X = Y × 2N). VOUT_UV_WARN_LIMIT REGISTER This register sets the undervoltage threshold measured at the PFC output that causes an undervoltage warning condition. Table 30. Register 0x43—VOUT_UV_WARN_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent (N) is set in the VOUT_MODE register (Register 0x20, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VOUT linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VOUT linear mode format (X = Y × 2N). VOUT_UV_FAULT_LIMIT REGISTER This register sets the undervoltage threshold measured at the PFC output that causes an undervoltage fault condition. Table 31. Register 0x44—VOUT_UV_FAULT_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent (N) is set in the VOUT_MODE register (Register 0x20, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VOUT linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VOUT linear mode format (X = Y × 2N). Rev. 0 | Page 48 of 82 Data Sheet ADP1048W VOUT_UV_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an output undervoltage fault condition. Table 32. Register 0x45—VOUT_UV_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:3] Retry setting R/W [2:0] Delay times R/W Description These bits determine the device response to an output undervoltage fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-off/power-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms OT_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an overtemperature fault condition. Table 33. Register 0x50—OT_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W Description These bits determine the device response to an overtemperature fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Rev. 0 | Page 49 of 82 ADP1048W Data Sheet Bits [5:3] Bit Name Retry setting R/W R/W [2:0] Delay times R/W Description Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-off/power-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms VIN_OV_FAULT_LIMIT REGISTER This register sets the overvoltage threshold measured at the PFC input that causes an overvoltage fault condition. Table 34. Register 0x55—VIN_OV_FAULT_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). VIN_OV_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an input overvoltage fault condition. Table 35. Register 0x56—VIN_OV_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W Description These bits determine the device response to an input overvoltage fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Rev. 0 | Page 50 of 82 Data Sheet ADP1048W Bits [5:3] Bit Name Retry setting R/W R/W [2:0] Delay times R/W Description Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-off/power-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms VIN_UV_WARN_LIMIT REGISTER This register sets the undervoltage threshold measured at the PFC input that causes an undervoltage warning condition. Table 36. Register 0x58—VIN_UV_WARN_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). VIN_UV_FAULT_LIMIT REGISTER This register sets the undervoltage threshold measured at the PFC input that causes an undervoltage fault condition. Table 37. Register 0x59—VIN_UV_FAULT_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). Rev. 0 | Page 51 of 82 ADP1048W Data Sheet VIN_UV_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an input undervoltage fault condition. Table 38. Register 0x5A—VIN_UV_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:3] Retry setting R/W [2:0] Delay times R/W Description These bits determine the device response to an input undervoltage fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-off/power-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms IIN_OC_FAULT_LIMIT REGISTER This register sets the accurate overcurrent threshold measured at the PFC input that causes an overcurrent fault condition. Table 39. Register 0x5B—IIN_OC_FAULT_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in current linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[10:6]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in current linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in current linear mode format (X = Y × 2N). Rev. 0 | Page 52 of 82 Data Sheet ADP1048W IIN_OC_FAULT_RESPONSE REGISTER This register instructs the device on actions to take due to an input overcurrent fault condition. Table 40. Register 0x5C—IIN_OC_FAULT_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:3] Retry setting R/W [2:0] Delay times R/W Description These bits determine the device response to an input overcurrent fault condition. Bit 7 Bit 6 Response 0 0 Do nothing. 0 1 Continue operation for the time specified by Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 1 0 Shut down, disable the output, and retry the number of times specified by the retry setting (Bits[5:3]). 1 1 Disable the output and wait for the fault to clear. After the fault is cleared, reenable the output. Number of retry attempts following a fault condition. If the fault persists after the programmed number of attempts, the output is disabled and remains off until the fault is cleared. A fault condition can be cleared by a reset, a power-off/power-on sequence, or a loss of bias power. The time between restart attempts is specified by Delay Time 2 (Bits[2:0]). Bit 5 Bit 4 Bit 3 Number of Retries 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 Infinite Delay Time 1 is the delay before the device disables the output after a fault condition is detected. Delay Time 2 is the time between restart attempts. Bit 2 Bit 1 Bit 0 Delay Time 1 Delay Time 2 0 0 0 10 ms 252 ms 0 0 1 20 ms 558 ms 0 1 0 40 ms 924 ms 0 1 1 80 ms 1260 ms 1 0 0 160 ms 1596 ms 1 0 1 320 ms 1932 ms 1 1 0 640 ms 2268 ms 1 1 1 1280 ms 2604 ms IIN_OC_WARN_LIMIT REGISTER This register sets the accurate overcurrent threshold measured at the PFC input that causes an overcurrent warning condition. Table 41. Register 0x5D—IIN_OC_WARN_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in current linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[10:6]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in current linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in current linear mode format (X = Y × 2N). Rev. 0 | Page 53 of 82 ADP1048W Data Sheet PIN_OP_WARN_LIMIT REGISTER This register sets the upper input power (W) threshold that causes an input overpower warning condition. Table 42. Register 0x6B—PIN_OP_WARN_LIMIT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R/W R/W Description Return the exponent (N) used in power linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in power linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in power linear mode format (X = Y × 2N). STATUS_BYTE REGISTER This register returns the lower byte of the STATUS_WORD register. A value of 1 in this register indicates that a fault has occurred. Table 43. Register 0x78—STATUS_BYTE Bits 7 6 5 4 3 2 1 0 Bit Name BUSY PSON_OFF VOUT_OV IOUT_OC VIN_UV TEMPERATURE CML NONE_OF_THE_ABOVE R/W R R R R R R R R Description 1 = device was busy and unable to respond. 1 = device is not providing power to the output. 1 = output overvoltage fault. 1 = output overcurrent fault. 1 = input undervoltage fault. 1 = temperature fault or warning. 1 = communications, memory, or logic fault. 1 = fault or warning not listed in Bits[7:1]. STATUS_WORD REGISTER A value of 1 in this register indicates that a fault has occurred. Table 44. Register 0x79—STATUS_WORD Bits 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Bit Name VOUT IOUTPOUT INPUT MFR POWER_GOOD# FANS OTHER UNKNOWN BUSY PSON_OFF VOUT_OV IOUT_OC VIN_UV TEMPERATURE CML NONE_OF_THE_ABOVE R/W R R R R R R R R R R R R R R R R Description 1 = output voltage fault or warning. 1 = output current or output power fault or warning. 1 = input voltage, input current, or input power fault or warning. 1 = manufacturer-specific fault or warning. 1 = POWER_GOOD is negated. 1 = fan or airflow fault or warning. Always reads as 0. 1 = fault or warning not listed in Bits[15:1]. 1 = device was busy and unable to respond. 1 = device is not providing power to the output. 1 = output overvoltage fault. 1 = output overcurrent fault. 1 = input undervoltage fault. 1 = temperature fault or warning. 1 = communications, memory, or logic fault. 1 = fault or warning not listed in Bits[7:1]. STATUS_VOUT REGISTER A value of 1 in this register indicates that a fault has occurred. Table 45. Register 0x7A—STATUS_VOUT Bits 7 6 5 4 Bit Name VOUT_OV_FAULT VOUT_OV_WARN VOUT_UV_WARN VOUT_UV_FAULT R/W R R R R Description 1 = output overvoltage fault. 1 = output overvoltage warning. 1 = output undervoltage warning. 1 = output undervoltage fault. Rev. 0 | Page 54 of 82 Data Sheet ADP1048W STATUS_INPUT REGISTER A value of 1 in this register indicates that a fault has occurred. Table 46. Register 0x7C—STATUS_INPUT Bits 7 5 4 3 2 1 0 Bit Name VIN_OV_FAULT VIN_UV_WARN VIN_UV_FAULT VIN_LOW IIN_OC_FAULT IIN_OC_WARN PIN_OP_WARN R/W R R R R R R R Description 1 = input overvoltage fault. 1 = input undervoltage warning. 1 = input undervoltage fault. 1 = device is off due to insufficient input voltage; that is, input voltage is below the turn-off threshold. 1 = input overcurrent fault. 1 = input overcurrent warning. 1 = input overpower warning. STATUS_TEMPERATURE REGISTER A value of 1 in this register indicates that a fault has occurred. Table 47. Register 0x7D—STATUS_TEMPERATURE Bits 7 6 [5:0] Bit Name OT_FAULT OT_WARN RSVD R/W R R R Description 1 = overtemperature fault. 1 = overtemperature warning. Reserved. READ_VIN REGISTER This register returns the input voltage (V) in VIN linear mode format (X = Y × 2N). Table 48. Register 0x88—READ_VIN Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R R Description Return the exponent (N) used in VIN linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[5:3]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VIN linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VIN linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[5:3]). READ_IIN REGISTER This register returns the input current (A) in current linear mode format (X = Y × 2N). Table 49. Register 0x89—READ_IIN Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R R Description Return the exponent (N) used in current linear mode format (X = Y × 2N). The exponent is set in the exponent register (Register 0xFE39, Bits[10:6]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in current linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in current linear mode format (X = Y × 2N). READ_VOUT REGISTER This register returns the output voltage (V) in VIN linear mode format (X = Y × 2N). Table 50. Register 0x8B—READ_VOUT Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R R Description Return the exponent (N) used in VOUT linear mode format (X = Y × 2N). The exponent (N) is set in the VOUT_MODE register (Register 0x20, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in VOUT linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in VOUT linear mode format (X = Y × 2N). Rev. 0 | Page 55 of 82 ADP1048W Data Sheet READ_PIN REGISTER This register returns the input power (W) in power linear mode format (X = Y × 2N). Table 51. Register 0x97—READ_PIN Bits [15:11] Bit Name Exponent R/W R [10:8] [7:0] High bits Low byte R R Description Return the exponent (N) used in power linear mode format (X = Y × 2N). The exponent (N) is set in the exponent register (Register 0xFE39, Bits[2:0]). The exponent is in twos complement format. Mantissa high bits (Y[10:8]) used in power linear mode format (X = Y × 2N). Mantissa low byte (Y[7:0]) used in power linear mode format (X = Y × 2N). PMBUS_REVISION REGISTER Table 52. Register 0x98—PMBUS_REVISION Bits [7:0] Bit Name Revision R/W R Description Return the revision of PMBus that the device is compliant with. MFR_ID REGISTER Table 53. Register 0x99—MFR_ID Bits [7:0] Bit Name MFR_ID R/W R Description Return the manufacturer ID. MFR_MODEL REGISTER Table 54. Register 0x9A—MFR_MODEL Bits [7:0] Bit Name Model R/W R Description Return the manufacturer model number. MFR_REVISION REGISTER Table 55. Register 0x9B—MFR_REVISION Bits [7:0] Bit Name Revision R/W R Description Return the manufacturer revision number. EEPROM_DATA_00 Through EEPROM_DATA_15 COMMANDS Code 0xB0 through Code 0xBF, read/write block. The EEPROM_DATA_00 through EEPROM_DATA_15 commands are used to read data from the EEPROM and write data to the EEPROM. EEPROM_DATA_00 reads from and writes to Page 0 of the EEPROM main block; EEPROM_DATA_01 reads from and writes to Page 1 of the EEPROM main block, and so on. EEPROM_CRC_CHKSUM REGISTER Table 56. Register 0xD1—EEPROM_CRC_CHKSUM Bits [7:0] Bit Name CRC checksum R/W R Description Return the CRC checksum value from the EEPROM download operation. EEPROM_NUM_RD_BYTES REGISTER Table 57. Register 0xD2—EEPROM_NUM_RD_BYTES Bits [7:0] Bit Name Number of read bytes returned R/W R/W Description These bits set the number of read bytes returned when using the EEPROM_DATA_xx commands. EEPROM_ADDR_OFFSET REGISTER Table 58. Register 0xD3—EEPROM_ADDR_OFFSET Bits [15:0] Bit Name Address offset R/W R/W Description These bits set the address offset of the current EEPROM page. Rev. 0 | Page 56 of 82 Data Sheet ADP1048W EEPROM_PAGE_ERASE REGISTER Table 59. Register 0xD4—EEPROM_PAGE_ERASE Bits [7:0] Bit Name Page erase R/W W Description Perform a page erase on the selected EEPROM page. (Wait 35 ms after each page erase operation.) EEPROM must first be unlocked. Page 0 and Page 1 erase are allowed only in manufacturing test mode. EEPROM_PASSWORD REGISTER Table 60. Register 0xD5—EEPROM_PASSWORD Bits [7:0] Bit Name EEPROM password R/W W Description Write the password to this register to unlock EEPROM and/or to change the EEPROM password. TRIM_PASSWORD REGISTER Table 61. Register 0xD6—TRIM_PASSWORD Bits [7:0] Bit Name Trim password R/W W Description Write the password to this register to unlock the trim registers for write access. Write the trim password twice (default 0x00) to unlock the register; write any other value to exit. EEPROM_INFO COMMAND Code 0xF1, block readwrite. This command reads the manufacturer data from the EEPROM. CS_FAST_OCP_RESPONSE REGISTER This register instructs the device on actions to take due to a fast overcurrent protection condition. Table 62. Register 0xFE00—CS_FAST_OCP_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:4] N-time R/W [3:0] RSVD R Description These bits determine the device response to a fast overcurrent protection condition. Bit 7 Bit 6 Response 0 0 Ignore (still terminate the PWM pulse). 0 1 Allow the number of switching cycles specified in Bits[5:4], then shut down and soft start (use the soft start delay time specified in Register 0x5C, Bits[2:0]). 1 0 Allow the number of switching cycles specified in Bits[5:4] (terminating the PWM pulse each time), then shut down and wait for the PSON signal to soft start. 1 1 Disable the PWM output after the number of switching cycles specified in Bits[5:4] and wait for the flag to be cleared. These bits determine the number of switching cycles allowed before the device disables the PWM output after a fast overcurrent condition is detected. Bit 5 Bit 4 Number of Switching Cycles 0 0 1 0 1 2 1 0 4 1 1 8 Reserved. Rev. 0 | Page 57 of 82 ADP1048W Data Sheet OVP_FAST_OVP_RESPONSE REGISTER This register instructs the device on actions to take due to a fast overvoltage fault condition. Table 63. Register 0xFE01—OVP_FAST_OVP_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:0] RSVD R Description These bits determine the device response to a fast overvoltage condition. Bit 7 Bit 6 Response 0 0 Ignore (do nothing; PWM continues). 0 1 Shut down and soft start. 1 0 Shut down immediately and wait for the PSON signal. 1 1 Disable the PWM output until the unlatched flag is cleared. Reserved. OLP_RESPONSE REGISTER This register instructs the device on actions to take due to an open-loop fault condition. Table 64. Register 0xFE02—OLP_RESPONSE Bits [7:6] Bit Name Response R/W R/W [5:0] RSVD R Description These bits determine the device response to an open-loop fault condition. Bit 7 Bit 6 Response 0 0 Ignore (do nothing; PWM continues). 0 1 Shut down and soft start. 1 0 Shut down immediately and wait for the PSON signal. 1 1 Disable the PWM output until the unlatched flag is cleared. Reserved. VDD3P3_RESPONSE REGISTER This register instructs the device on actions to take due to a VDD overvoltage fault condition. Table 65. Register 0xFE03—VDD3P3_RESPONSE Bits 7 6 Bit Name RSVD Save first flag ID to EEPROM R/W R R/W [5:3] 2 Retry wait time Reload EEPROM R/W R/W 1 Debounce time R/W 0 Ignore VDD OV R/W Description Reserved. 1 = save the first flag ID to EEPROM when the device shuts down. 0 = do not save the first flag ID to EEPROM when the device shuts down. These bits determine the retry wait time before the next soft start. Each LSB = 588 ms. 1 = reload the contents of EEPROM. 0 = do not reload the contents of EEPROM. 1 = 2.56 μs. 0 = 660 μs. 1 = ignore the VDD 3.3 V overvoltage fault. 0 = do not ignore the VDD 3.3 V overvoltage fault. Rev. 0 | Page 58 of 82 Data Sheet ADP1048W VCORE_RESPONSE REGISTER This register instructs the device on actions to take due to a VCORE overvoltage fault condition. Table 66. Register 0xFE04—VCORE_RESPONSE Bits 7 6 Bit Name RSVD Save first flag ID to EEPROM R/W R R/W [5:3] 2 Retry wait time Reload EEPROM R/W R/W 1 Debounce time R/W 0 Ignore VCORE OV R/W Description Reserved. 1 = save the first flag ID to EEPROM when the device shuts down. 0 = do not save the first flag ID to EEPROM when the device shuts down. These bits determine the retry wait time before the next soft start. Each LSB = 588 ms. 1 = reload the contents of EEPROM. 0 = do not reload the contents of EEPROM. 1 = 2.56 μs. 0 = 660 μs. 1 = ignore the VCORE overvoltage fault. 0 = do not ignore the VCORE overvoltage fault. PGOOD_AC_OK_DEBOUNCE_SET REGISTER This register sets the debounce times for the PGOOD and AC_OK pins. Table 67. Register 0xFE05—PGOOD_AC_OK_DEBOUNCE_SET Bits [7:6] Bit Name Debounce time, AC_OK pin (low to high) R/W R/W [5:4] Debounce time, AC_OK pin (high to low) R/W [3:2] Debounce time, PGOOD pin (low to high) R/W [1:0] Debounce time, PGOOD pin (high to low) R/W Description Debounce from low to high for the AC_OK pin. Bit 7 Bit 6 Time 0 0 0 ms 0 1 200 ms 1 0 320 ms 1 1 600 ms Debounce from high to low for the AC_OK pin. Bit 5 Bit 4 Time 0 0 0 ms 0 1 200 ms 1 0 320 ms 1 1 600 ms Debounce from low to high for the PGOOD pin. Bit 3 Bit 2 Time 0 0 0 ms 0 1 200 ms 1 0 320 ms 1 1 600 ms Debounce from high to low for the PGOOD pin. Bit 1 Bit 0 Time 0 0 0 ms 0 1 200 ms 1 0 320 ms 1 1 600 ms Rev. 0 | Page 59 of 82 ADP1048W Data Sheet PSON_SET REGISTER This register sets the delay time for PSON and PSOFF. Table 68. Register 0xFE06—PSON_SET Bits [7:4] [3:2] Bit Name RSVD PSON delay R/W R R/W [1:0] PSOFF delay R/W Description Reserved. These bits specify the time from when the PSON signal is active to when soft start begins. Delay Time Bit 3 Bit 2 Min Typ Max 0 0 0 ms 0 ms 0 ms 0 1 40 ms 50 ms 82 ms 1 0 209 ms 250 ms 252 ms 1 1 964 ms 1000 ms 1007 ms These bits specify the time from when the PSON signal is cleared to when the device is turned off. Delay Time Bit 1 Bit 0 Min Typ Max 0 0 0 ms 0 ms 0 ms 0 1 40 ms 50 ms 82 ms 1 0 209 ms 250 ms 252 ms 1 1 964 ms 1000 ms 1007 ms FLAG_FAULT_ID REGISTER This register records the first fault ID that caused the system to shut down. Table 69. Register 0xFE07—FLAG_FAULT_ID Bits [7:4] [3:0] Bit Name Previous fault flag ID Fault flag ID R/W R R Description Return the flag fault ID value of the fault that occurred just before the flag that caused the shutdown (identified in Bits[3:0]). Return the flag fault ID value of the fault that caused the shutdown. Bit 3 Bit 2 Bit 1 Bit 0 Fault 0 0 0 1 VOUT_OV_FAULT 0 0 1 0 VOUT_UV_FAULT 0 0 1 1 OT_FAULT 0 1 0 0 VIN_OV_FAULT 0 1 0 1 VIN_UV_FAULT 0 1 1 0 IIN_OC_FAULT 0 1 1 1 OLP_FAULT 1 0 0 0 FAST_OVP_FAULT 1 0 0 1 FAST_OCP_FAULT 1 0 1 0 VDD_33V_OV_FAULT 1 0 1 1 VCORE_25V_OV_FAULT SOFTSTART_FLAGS_BLANK1 REGISTER This register blanks the specified flags during soft start (1 = blank, 0 = don’t blank). Table 70. Register 0xFE08—SOFTSTART_FLAGS_BLANK1 Bits 7 6 5 4 3 2 1 0 Bit Name BLANK_FAST_OVP BLANK_OLP BLANK_IIN_OC BLANK_VIN_OFF BLANK_VIN_OV BLANK_OT BLANK_VOUT_UV BLANK_VOUT_OV R/W R/W R/W R/W R/W R/W R/W R/W R/W Description 1 = ignore fast OVP flag. 1 = ignore OLP flag. 1 = ignore IIN_OC_FAULT flag. 1 = ignore VIN_OFF flag. 1 = ignore VIN_OV flag. 1 = ignore OT flag. 1 = ignore VOUT_UV flag. 1 = ignore VOUT_OV flag. Rev. 0 | Page 60 of 82 Data Sheet ADP1048W SOFTSTART_FLAGS_BLANK2 REGISTER This register blanks the specified flag during soft start (1 = blank, 0 = don’t blank). Table 71. Register 0xFE09—SOFTSTART_FLAGS_BLANK2 Bits 0 Bit Name BLANK_FAST_OCP R/W R/W Description 1 = ignore fast OCP flag. PGOOD_FLAGS_LIST REGISTER This register specifies the flags that are checked to determine the PGOOD pin voltage (1 = ignore flag, 0 = check flag). Table 72. Register 0xFE0A—PGOOD_FLAGS_LIST Bits 7 6 5 4 3 2 1 0 Bit Name VOUT_UV_FAULT VOUT_OV_WARN FAST_OVP OLP FAST_OCP IIN_OC_FAULT OT_FAULT FAST_LOOP R/W R/W R/W R/W R/W R/W R/W R/W R/W Description 1 = ignore VOUT_UV_FAULT flag. 1 = ignore VOUT_OV_WARN flag. 1 = ignore FAST_OVP flag. 1 = ignore OLP flag. 1 = ignore FAST_OCP flag. 1 = ignore IIN_OC_FAULT flag. 1 = ignore OT_FAULT flag. 1 = ignore FAST_LOOP flag. AC_OK_FLAGS_LIST REGISTER This register specifies the flags that are checked to determine the AC_OK pin voltage (1 = ignore flag, 0 = check flag). Table 73. Register 0xFE0B—AC_OK_FLAGS_LIST Bits 7 6 5 4 3 2 1 0 Bit Name VIN_UV_FAULT VIN_UV_WARN IIN_OC_FAULT IIN_OC_WARN FAST_OCP AC_LINE_PERIOD BROWN_OUT INRUSH R/W R/W R/W R/W R/W R/W R/W R/W R/W Description 1 = ignore VIN_UV_FAULT flag. 1 = ignore VIN_UV_WARN flag. 1 = ignore IIN_OC_FAULT flag. 1 = ignore IIN_OC_WARN flag. 1 = ignore FAST_OCP flag. 1 = ignore AC_LINE_PERIOD flag. 1 = ignore BROWN_OUT flag. 1 = ignore INRUSH flag. PWM AND PWM2 TIMING REGISTERS Register 0xFE0C through Register 0xFE13 configure the rising and falling edges of the PWM outputs. Table 74. Register 0xFE0C—PWM Rising Edge Timing (PWM Pin) Bits [7:0] Bit Name t1 R/W R/W Description This register contains the eight MSBs of the 10-bit t1 time. Table 75. Register 0xFE0D—PWM Rising Edge Setting (PWM Pin) Bits [7:4] [3:2] Bit Name RSVD t1 R/W R R/W 1 Modulate enable R/W 0 t1 sign R/W Description Reserved. These bits contain the two LSBs of the 10-bit t1 time. This value is always used with the eight bits of Register 0xFE0C, which contains the eight MSBs of the t1 time. 1 = PWM modulation acts on the t1 edge. 0 = no PWM modulation of the t1 edge. 1 = positive sign. Increase of PWM modulation moves t1 right. 0 = negative sign. Increase of PWM modulation moves t1 left. Rev. 0 | Page 61 of 82 ADP1048W Data Sheet Table 76. Register 0xFE0E—PWM Falling Edge Timing (PWM Pin) Bits [7:0] Bit Name t2 R/W R/W Description This register contains the eight MSBs of the 10-bit t2 time. Table 77. Register 0xFE0F—PWM Falling Edge Setting (PWM Pin) Bits [7:4] [3:2] Bit Name RSVD t2 R/W R R/W 1 Modulate enable R/W 0 t2 sign R/W Description Reserved. These bits contain the two LSBs of the 10-bit t2 time. This value is always used with the eight bits of Register 0xFE0E, which contains the eight MSBs of the t2 time. 1 = PWM modulation acts on the t2 edge. 0 = no PWM modulation of the t2 edge. 1 = positive sign. Increase of PWM modulation moves t2 right. 0 = negative sign. Increase of PWM modulation moves t2 left. Table 78. Register 0xFE10—PWM2 Rising Edge Timing (PWM2 Pin) Bits [7:0] Bit Name t1 R/W R/W Description This register contains the eight MSBs of the 10-bit t1 time. Table 79. Register 0xFE11—PWM2 Rising Edge Setting (PWM2 Pin) Bits [7:4] [3:2] Bit Name RSVD t1 R/W R R/W 1 Modulate enable R/W 0 t1 sign R/W Description Reserved. These bits contain the two LSBs of the 10-bit t1 time. This value is always used with the eight bits of Register 0xFE10, which contains the eight MSBs of the t1 time. 1 = PWM modulation acts on the t1 edge. 0 = no PWM modulation of the t1 edge. 1 = positive sign. Increase of PWM modulation moves t1 right. 0 = negative sign. Increase of PWM modulation moves t1 left. Table 80. Register 0xFE12—PWM2 Falling Edge Timing (PWM2 Pin) Bits [7:0] Bit Name t2 R/W R/W Description This register contains the eight MSBs of the 10-bit t2 time. Table 81. Register 0xFE13—PWM2 Falling Edge Setting (PWM2 Pin) Bits [7:4] [3:2] Bit Name RSVD t2 R/W R R/W 1 Modulate enable R/W 0 t2 sign R/W Description Reserved. These bits contain the two LSBs of the 10-bit t2 time. This value is always used with the eight bits of Register 0xFE12, which contains the eight MSBs of the t2 time. 1 = PWM modulation acts on the t2 edge. 0 = no PWM modulation of the t2 edge. 1 = positive sign. Increase of PWM modulation moves t2 right. 0 = negative sign. Increase of PWM modulation moves t2 left. Rev. 0 | Page 62 of 82 Data Sheet ADP1048W PWM_SET REGISTER Table 82. Register 0xFE14—PWM_SET Bits [7:5] 4 Bit Name RSVD operation R/W R R/W 3 PWM resolution R/W 2 PWM enable R/W 1 PWM2 enable R/W 0 Go button R/W Description Reserved. 1 = bridgeless PFC operation. 0 = interleaved PFC operation. 1 = 5 ns. 0 = 40 ns. 1 = disable the PWM output. 0 = enable the PWM output. 1 = disable the PWM2 output. 0 = enable the PWM2 output. The PWM settings are updated during the transition of this bit from low to high. PWM_LIMIT REGISTER Table 83. Register 0xFE15—PWM_LIMIT Bits [7:4] [3:0] Bit Name Limit minimum on time Limit minimum off time R/W R/W R/W Description These bits set the minimum on time for the PWM outputs in steps of 80 ns: 0000 = 0 ns and 1111 = 1200 ns. These bits set the minimum off time for the PWM outputs: 0000 = 40 ns, 0001 = 80 ns, 1111 = 1200 ns. RTD ADC OFFSET TRIM SETTING (MSB) REGISTER This register must be unlocked for write access; see Table 61. Table 84. Register 0xFE16—RTD ADC Offset Trim Setting (MSB) Bits [7:2] 1 Bit Name RSVD Trim polarity R/W R/W R/W 0 RTD ADC offset trim R/W Description Reserved. 1 = negative offset trim is introduced. 0 = positive offset trim is introduced. This bit is the MSB of the 9-bit value that sets the amount of offset trim applied to the RTD ADC reading. The LSBs are specified in Register 0xFE17. RTD ADC OFFSET TRIM SETTING (LSB) REGISTER This register must be unlocked for write access; see Table 61. Table 85. Register 0xFE17—RTD ADC Offset Trim Setting (LSB) Bits [7:0] Bit Name RTD ADC offset trim R/W R/W Description These eight bits are the LSBs of the 9-bit value that sets the amount of offset trim applied to the RTD ADC reading. The MSB is specified in Register 0xFE16, Bit 0. RTD ADC GAIN TRIM SETTING REGISTER This register must be unlocked for write access; see Table 61. Table 86. Register 0xFE18—RTD ADC Gain Trim Setting Bits 7 Bit Name Gain polarity R/W R/W [6:0] RTD ADC gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This value sets the amount of gain trim that is applied to the RTD sensing gain. Rev. 0 | Page 63 of 82 ADP1048W Data Sheet OT_FAULT_LIMIT REGISTER This register sets the overtemperature fault threshold. The debounce time of the overtemperature fault flag is 100 ms. Table 87. Register 0xFE19—OT_FAULT_LIMIT Bits [7:0] Bit Name OT fault threshold R/W R/W Description Overtemperature fault threshold. This register, adding 0 as the MSB, results in a 9-bit threshold value. This 9-bit value is compared to the nine MSBs of the RTD ADC reading. If the RTD ADC reading is lower than the threshold set by these bits, the overtemperature fault flag is set. These eight bits provide 256 threshold settings from 0 mV to 800 mV (one LSB = 800 mV/256 = 3.125 mV). However, the lowest allowed value is 9.375 mV (0x03), and the highest allowed value is 781.25 mV (0xFA). Bit 7 Bit 6 … Bit 3 Bit 2 Bit 1 Bit 0 OTP Threshold (mV) 0 0 … 0 0 1 1 9.375 0 0 … 0 1 0 0 12.5 0 0 … 0 1 0 1 15.875 … … … … … … … … 1 1 … 1 0 0 1 778.125 1 1 … 1 0 1 0 781.25 OT_WARN_LIMIT REGISTER This register sets the overtemperature warning threshold. The debounce time of the overtemperature warning flag is 100 ms. Table 88. Register 0xFE1A—OT_WARN_LIMIT Bits [7:0] Bit Name OT warning threshold R/W R/W Description Overtemperature warning threshold. This register, adding 0 as the MSB, results in a 9-bit threshold value. This 9-bit value is compared to the nine MSBs of the RTD ADC reading. If the RTD ADC reading is lower than the threshold set by these bits, the overtemperature warning flag is set. These eight bits provide 256 threshold settings from 0 mV to 800 mV (one LSB = 800 mV/256 = 3.125 mV). However, the lowest allowed value is 9.375 mV (0x03), and the highest allowed value is 781.25 mV (0xFA). Bit 7 Bit 6 … Bit 3 Bit 2 Bit 1 Bit 0 OTP Threshold (mV) 0 0 … 0 0 1 1 9.375 0 0 … 0 1 0 0 12.5 0 0 … 0 1 0 1 15.875 … … … … … … … … 1 1 … 1 0 0 1 778.125 1 1 … 1 0 1 0 781.25 Rev. 0 | Page 64 of 82 Data Sheet ADP1048W SWITCHING FREQUENCY SETTING REGISTER Table 89. Register 0xFE1B—Switching Frequency Setting Bits [7:6] [5:0] Bit Name RSVD Switching frequency R/W R R/W Description Reserved. This register sets the switching frequency of the PWM outputs. Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 1 0 0 0 0 0 1 1 0 0 0 1 0 0 0 0 0 1 0 1 0 0 0 1 1 0 0 0 0 1 1 1 0 0 1 0 0 0 0 0 1 0 0 1 0 0 1 0 1 0 0 0 1 0 1 1 0 0 1 1 0 0 0 0 1 1 0 1 0 0 1 1 1 0 0 0 1 1 1 1 0 1 0 0 0 0 0 1 0 0 0 1 0 1 0 0 1 0 0 1 0 0 1 1 0 1 0 1 0 0 0 1 0 1 0 1 0 1 0 1 1 0 0 1 0 1 1 1 0 1 1 0 0 0 0 1 1 0 0 1 0 1 1 0 1 0 0 1 1 0 1 1 0 1 1 1 0 0 0 1 1 1 0 1 0 1 1 1 1 0 0 1 1 1 1 1 1 0 0 0 0 0 1 0 0 0 0 1 1 0 0 0 1 0 1 0 0 0 1 1 1 0 0 1 0 0 1 0 0 1 0 1 1 0 0 1 1 0 1 0 0 1 1 1 1 0 1 0 0 0 1 0 1 0 0 1 1 0 1 0 1 0 1 0 1 0 1 1 1 0 1 1 0 0 1 0 1 1 0 1 1 0 1 1 1 0 Rev. 0 | Page 65 of 82 Frequency (kHz) 30.05 32.55 35.51 39.06 43.40 48.83 52.06 55.80 60.10 65.10 71.02 78.13 86.81 97.66 100.81 104.17 107.76 111.61 115.74 120.19 125.00 130.21 135.87 142.05 148.81 156.25 164.47 173.61 183.82 195.31 198.41 201.61 204.92 208.33 211.86 215.52 219.30 223.21 227.27 231.48 235.85 240.38 245.10 250.00 255.10 260.42 265.96 ADP1048W Bits [5:0] Bit Name Switching frequency Data Sheet R/W R/W Description Bit 5 Bit 4 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Bit 3 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 Bit 2 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 Bit 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 Bit 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 Frequency (kHz) 271.74 277.78 284.09 290.70 297.62 304.88 312.50 320.51 328.95 337.84 347.22 357.14 367.65 378.79 390.63 403.23 403.23 LOW POWER SWITCHING FREQUENCY SETTING REGISTER This register sets the PFC switching frequency when the PFC is running under low power mode and the smart switching frequency operation is enabled. Table 90. Register 0xFE1C—Low Power Switching Frequency Setting Bits [7:6] [5:0] Bit Name RSVD Switching frequency R/W R R/W Description Reserved. This register sets the switching frequency when the power is lower than the low power threshold set in Register 0xFE32 and the smart switching frequency is enabled. Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Frequency (kHz) 0 0 0 0 0 0 30.05 0 0 0 0 0 1 32.55 0 0 0 0 1 0 35.51 0 0 0 0 1 1 39.06 0 0 0 1 0 0 43.40 0 0 0 1 0 1 48.83 0 0 0 1 1 0 52.06 0 0 0 1 1 1 55.80 0 0 1 0 0 0 60.10 0 0 1 0 0 1 65.10 0 0 1 0 1 0 71.02 0 0 1 0 1 1 78.13 0 0 1 1 0 0 86.81 0 0 1 1 0 1 97.66 0 0 1 1 1 0 100.81 0 0 1 1 1 1 104.17 0 1 0 0 0 0 107.76 0 1 0 0 0 1 111.61 0 1 0 0 1 0 115.74 0 1 0 0 1 1 120.19 0 1 0 1 0 0 125.00 0 1 0 1 0 1 130.21 0 1 0 1 1 0 135.87 0 1 0 1 1 1 142.05 Rev. 0 | Page 66 of 82 Data Sheet Bits [5:0] Bit Name Switching frequency ADP1048W R/W R/W Description Bit 5 Bit 4 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Bit 3 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 Bit 2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 Bit 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 Bit 0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 Frequency (kHz) 148.81 156.25 164.47 173.61 183.82 195.31 198.41 201.61 204.92 208.33 211.86 215.52 219.30 223.21 227.27 231.48 235.85 240.38 245.10 250.00 255.10 260.42 265.96 271.74 277.78 284.09 290.70 297.62 304.88 312.50 320.51 328.95 337.84 347.22 357.14 367.65 378.79 390.63 403.23 403.23 FREQUENCY DITHERING SET REGISTER Table 91. Register 0xFE1D—Frequency Dithering Set Bits 7 [6:0] Bit Name RSVD Dithering period R/W R R/W Description Reserved. Sets the period for updating the switching frequency. Each LSB corresponds to 40 μs. Rev. 0 | Page 67 of 82 ADP1048W Data Sheet FREQUENCY SYNCHRONIZATION SET REGISTER Table 92. Register 0xFE1E—Frequency Synchronization Set Bits [7:2] [1:0] Bit Name RSVD Frequency division R/W R/W R/W Description Reserved. Sets the frequency division between the switching frequency and the external SYNC clock (fSWfSYNC_EXT). Bit 1 Bit 0 Frequency Division 0 0 1 0 1 12 1 0 13 1 1 14 VOLTAGE LOOP FILTER GAIN REGISTER Table 93. Register 0xFE20—Voltage Loop Filter Gain Bits [7:0] Bit Name Voltage loop filter gain R/W R/W Description Determines the digital filter gain of the PFC voltage loop. VOLTAGE LOOP FILTER ZERO REGISTER Table 94. Register 0xFE21—Voltage Loop Filter Zero Bits [7:0] Bit Name Voltage loop filter zero R/W R/W Description Determines the position of the digital filter zero of the PFC voltage loop. FAST VOLTAGE LOOP FILTER GAIN REGISTER Table 95. Register 0xFE22—Fast Voltage Loop Filter Gain Bits [7:0] Bit Name Fast voltage loop filter gain R/W R/W Description Determines the digital filter gain of the PFC fast voltage loop. FAST VOLTAGE LOOP FILTER ZERO REGISTER Table 96. Register 0xFE23—Fast Voltage Loop Filter Zero Bits [7:0] Bit Name Fast voltage loop filter zero R/W R/W Description Determines the position of the digital filter zero of the PFC fast voltage loop. FAST VOLTAGE LOOP ENABLE REGISTER Table 97. Register 0xFE24—Fast Voltage Loop Enable Bits 7 Bit Name Enable fast loop for line transient R/W R/W [6:5] Regulation band limit R/W Description Enables fast loop mode immediately after the overshoot becomes larger than the regulation band plus 3%. 1 = enable fast loop mode. 0 = disable fast loop mode. Sets the threshold of the regulation band limit for switching from the normal filter to the fast loop filter. Bit 6 Bit 5 Threshold 0 0 ±1.5625% 0 1 ±3.125% 1 0 ±6.25% 1 1 ±12.5% Rev. 0 | Page 68 of 82 Data Sheet ADP1048W Bits [4:2] Bit Name Delay time R/W R/W 1 Enable fast loop during soft start R/W 0 Enable fast loop R/W Description Delay time before switching from the fast loop filter back to the normal filter after the output voltage is within the regulation band (Bits[6:5]). Bit 4 Bit 3 Bit 2 Number of Half AC Line Cycles 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 7 Enables the fast loop filter during soft start. 1 = fast loop filter is used during soft start. 0 = normal filter is used during soft start. Enables the fast loop filter with a delay. The threshold is programmed in Bits[6:5]. 1 = enable fast loop filter. 0 = disable fast loop filter. VAC_THRESHOLD_SET REGISTER This register sets the input voltage threshold for input ac line period measurement and zero-crossing detection. Table 98. Register 0xFE25—VAC_THRESHOLD_SET Bits 7 Bit Name Enable automatic threshold R/W R/W Description 1 = enable automatic threshold. [6:0] Threshold voltage R/W 0 = disable automatic threshold. These bits set the threshold voltage to detect the ac line frequency and period if Bit 7 is set to 0. VAC_THRESHOLD_READ REGISTER Table 99. Register 0xFE26—VAC_THRESHOLD_READ Bits 7 [6:0] Bit Name RSVD VAC average reading R/W R R Description Reserved. Return the reading of the threshold voltage to detect the ac line frequency and period if the automatic threshold is enabled in Register 0xFE25, Bit 7. MIN_AC_PERIOD_SET REGISTER Table 100. Register 0xFE27—MIN_AC_PERIOD_SET Bits [7:0] Bit Name Minimum ac line period R/W R/W Description These bits set the minimum ac line period of the input voltage. Each LSB corresponds to 163.84 μs resolution. MAX_AC_PERIOD_SET REGISTER Table 101. Register 0xFE28—MAX_AC_PERIOD_SET Bits [7:0] Bit Name Maximum ac line period R/W R/W Description These bits set the maximum ac line period of the input voltage. Each LSB corresponds to 163.84 μs resolution. Rev. 0 | Page 69 of 82 ADP1048W Data Sheet CURRENT LOOP FILTER GAIN FOR LOW LINE INPUT REGISTER Table 102. Register 0xFE29—Current Loop Filter Gain for Low Line Input Bits [7:0] Bit Name Current loop filter gain for low line R/W R/W Description These bits set the current loop digital filter gain of the PFC current loop under the low line input voltage. CURRENT LOOP FILTER ZERO FOR LOW LINE INPUT REGISTER Table 103. Register 0xFE2A—Current Loop Filter Zero for Low Line Input Bits [7:0] Bit Name Current loop filter zero for low line R/W R/W Description These bits set the current loop digital filter zero of the PFC current loop under the low line input voltage. CURRENT LOOP FILTER GAIN FOR HIGH LINE INPUT REGISTER Table 104. Register 0xFE2B—Current Loop Filter Gain for High Line Input Bits [7:0] Bit Name Current loop filter gain for high line R/W R/W Description These bits set the current loop digital filter gain of the PFC current loop under the high line input voltage. CURRENT LOOP FILTER ZERO FOR HIGH LINE INPUT REGISTER Table 105. Register 0xFE2C—Current Loop Filter Zero for High Line Input Bits [7:0] Bit Name Current loop filter zero for high line R/W R/W Description These bits set the current loop digital filter zero of the PFC current loop under the high line input voltage. SOFT START SET REGISTER Table 106. Register 0xFE2D—Soft Start Set Bits [7:6] [5:3] Bit Name RSVD Soft start delay time R/W R R/W [2:0] Soft start time R/W Description Reserved. These bits set the delay time between the inrush signal and the beginning of the soft start. Bit 5 Bit 4 Bit 3 Number of Full AC Line Cycles 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 7 These bits set the soft start time. Bit 2 Bit 1 Bit 0 Time 0 0 0 112 ms 0 0 1 168 ms 0 1 0 224 ms 0 1 1 280 ms 1 0 0 392 ms 1 0 1 504 ms 1 1 0 616 ms 1 1 1 728 ms Rev. 0 | Page 70 of 82 Data Sheet ADP1048W INRUSH SET REGISTER Table 107. Register 0xFE2E—Inrush Set Bits [7:5] [4:3] Bit Name RSVD Timer R/W R R/W [2:0] Inrush delay time R/W Description Reserved. These bits set the timer for the VIN_LOW flag measurement. Bit 4 Bit 3 Timer 0 0 Quarter line cycle 0 1 Half line cycle 1 0 2 ms 1 1 4 ms These bits set the inrush signal delay time after the BROWN_OUT flag goes low. Bit 2 Bit 1 Bit 0 Number of Full AC Line Cycles 0 0 0 0 0 0 1 1 0 1 0 2 0 1 1 3 1 0 0 4 1 0 1 5 1 1 0 6 1 1 1 7 FAST_OVP_FAULT_RISE REGISTER Table 108. Register 0xFE2F—FAST_OVP_FAULT_RISE Bits 7 [6:0] Bit Name RSVD Fast OVP rise threshold R/W R R/W Description Reserved. These bits set the rising threshold for the analog comparator at the OVP pin input as follows: OVP threshold = (Code × 0.5/127) + 1. This threshold is programmable from 1 V to 1.5 V. Each LSB increments the threshold by 3.9 mV. A value of 0x00 corresponds to a 1 V threshold; a value of 0x7F corresponds to a 1.5 V threshold. FAST_OVP_FAULT_FALL REGISTER Table 109. Register 0xFE30—FAST_OVP_FAULT_FALL Bits 7 [6:0] Bit Name RSVD Fast OVP fall threshold R/W R R/W Description Reserved. These bits set the falling threshold for the analog comparator at the OVP pin input as follows: OVP threshold = (Code × 0.5/127) + 1. This threshold is programmable from 1 V to 1.5 V. Each LSB increments the threshold by 3.9 mV. A value of 0x00 corresponds to a 1 V threshold; a value of 0x7F corresponds to a 1.5 V threshold. FAST OVP DEBOUNCE TIME SETTING REGISTER Table 110. Register 0xFE31—Fast OVP Debounce Time Setting Bits [7:2] [1:0] Bit Name RSVD OVP debounce time R/W R R/W Description Reserved. These bits set the fast OVP debounce time. Bit 1 Bit 0 Time 0 0 120 ns 0 1 240 ns 1 0 480 ns 1 1 640 ns Rev. 0 | Page 71 of 82 ADP1048W Data Sheet LOW POWER MODE OPERATION THRESHOLD REGISTER Table 111. Register 0xFE32—Low Power Mode Operation Threshold Bits [7:0] Bit Name Low power threshold R/W R/W Description These bits set the threshold value (PTH) for low power mode detection. When the input power is lower than this value, the PFC enters low power mode. POWER METERING OFFSET TRIM FOR LOW LINE INPUT REGISTER Table 112. Register 0xFE33—Power Metering Offset Trim for Low Line Input Bits 7 Bit Name Offset trim polarity R/W R/W [6:0] Power meter offset trim R/W Description 1 = negative offset trim is introduced. 0 = positive offset trim is introduced. This value calibrates the power meter offset at the low line input voltage. Each LSB corresponds to 0.0625/128 of the full input power. POWER METERING GAIN TRIM FOR LOW LINE INPUT REGISTER Table 113. Register 0xFE34—Power Metering Gain Trim for Low Line Input Bits 7 Bit Name Gain trim polarity R/W R/W [6:0] Power meter gain trim R/W Description 1 = negative gain trim is introduced. 0 = positive gain trim is introduced. This value calibrates the power meter gain at the low line input voltage. Each LSB corresponds to 0.0625/128 of the input power. HIGH LINE LIMIT REGISTER Table 114. Register 0xFE35—High Line Limit Bits [7:0] Bit Name VAC high line threshold R/W R/W Description When the input voltage is higher than this value, the current loop filter for high line input is used. LOW LINE LIMIT REGISTER Table 115. Register 0xFE36—Low Line Limit Bits [7:0] Bit Name VAC low line threshold R/W R/W Description When the input voltage is lower than this value, the current loop filter for low line input is used. ILIM_TRIM REGISTER This register must be unlocked for write access; see Table 61. Table 116. Register 0xFE37—ILIM_TRIM Bits [7:5] 4 Bit Name RSVD Trim current direction R/W R R/W [3:0] ILIM trim R/W Description Reserved. 1 = source trim current (ILIM + ILIM_TRIM). 0 = sink trim current (ILIM − ILIM_TRIM). These bits set the trim current. Each LSB corresponds to ILIM/64. VOLTAGE LOOP OUTPUT REGISTER Table 117. Register 0xFE38—Voltage Loop Output Bits [7:0] Bit Name Voltage loop output R/W R Description Return the output of the voltage control loop. Rev. 0 | Page 72 of 82 Data Sheet ADP1048W EXPONENT REGISTER This register reads and writes exponents (N) for PIN, VIN, and IIN. Table 118. Register 0xFE39—Exponent Bits [15:11] [10:6] [5:3] [2:0] Bit Name RSVD Input current exponent Input voltage exponent Input power exponent R/W R R/W R/W R/W Description Reserved. Sets the exponent for the input current. The exponent is in twos complement format. Sets the exponent for the input voltage. The exponent is in twos complement format. Sets the exponent for the input power. The exponent is in twos complement format. READ UPDATE RATE REGISTER Table 119. Register 0xFE3A—Read Update Rate Bits [7:3] [2:0] Bit Name RSVD Averaging window R/W R R/W Description Reserved. These bits set the averaging window for the power current and voltage readings; rms values from one half ac line cycle are averaged over the programmed number of half ac line cycles. Bit 2 Bit 1 Bit 0 Number of Half AC Line Cycles 0 0 0 0 0 0 1 16 0 1 0 64 0 1 1 128 1 0 0 512 1 0 1 1024 1 1 0 4096 1 1 1 8192 VIN SCALE MONITOR REGISTER Table 120. Register 0xFE3B—VIN Scale Monitor Bits [15:14] [13:11] 10 [9:0] Bit Name RSVD Exponent RSVD Mantissa R/W R R/W R R/W Description Reserved. Write the exponent (N) in twos complement format (KVIN = Y × 2N). Reserved. Mantissa (Y[9:0]) used in KVIN linear mode format (KVIN = Y × 2N). IIN_GSENSE REGISTER Table 121. Register 0xFE3C—IIN_GSENSE Bits [15:11] 10 [9:0] Bit Name Exponent RSVD Mantissa R/W R/W R R/W Description Write the exponent (N) in twos complement format (IIN_GSENSE = Y × 2N). Reserved. Mantissa (Y[9:0]) used in IIN linear mode format (IIN_GSENSE = Y × 2N). Rev. 0 | Page 73 of 82 ADP1048W Data Sheet CS FAST OCP BLANK REGISTER Table 122. Register 0xFE3D—CS Fast OCP Blank Bits [7:5] [4:3] Bit Name RSVD CS OCP debounce time R/W R R/W [2:0] Leading edge blanking time R/W Description Reserved. These bits set the CS OCP debounce time. This value is the minimum time that the CS signal must be constantly above the ILIM threshold (set in Register 0xFE3E, Bits[7:5]). When the CS OCP debounce time is exceeded, all PWM outputs are disabled for the remainder of the switching cycle. Bit 4 Bit 3 Fast OCP Debounce Time 0 0 40 ns 0 1 80 ns 1 0 120 ns 1 1 240 ns These bits determine the leading edge blanking time. During this time, the OCP comparator output is ignored. Bit 2 Bit 1 Bit 0 Leading Edge Blanking Time 0 0 0 40 ns 0 0 1 80 ns 0 1 0 120 ns 0 1 1 160 ns 1 0 0 200 ns 1 0 1 400 ns 1 1 0 600 ns 1 1 1 800 ns CS FAST OCP SETTING REGISTER Table 123. Register 0xFE3E—CS Fast OCP Setting Bits [7:5] Bit Name ILIM absolute value R/W R/W [4:2] 1 RSVD CS_RANGE_SELECT R R/W 0 SEL_RESVI_REF R/W Description These bits determine the ILIM absolute value. Bit 7 = 0 is positive sensing, and Bit 7 = 1 is negative sensing. Bit 7 Bit 6 Bit 5 ILIM Current Value 0 0 0 20 μA 0 0 1 40 μA 0 1 0 60 μA 0 1 1 80 μA 1 0 0 60 μA 1 0 1 80 μA 1 1 0 100 μA 1 1 1 120 μA Reserved. CS ADC input range. 0 = 750 mV. 1 = 500 mV. This bit sets the reference current for the CS+ and CS− common-mode level shift. 1 = select the RES VI reference current (changing RRES changes this current). 0 = select the band gap generated reference current. TEMPERATURE HYSTERESIS REGISTER Table 124. Register 0xFE3F—Temperature Hysteresis Bits [7:0] Bit Name Temperature hysteresis R/W R/W Description These bits set the temperature (RTD) measurement hysteresis. The OT_FAULT flag is reset when the RTD ADC value is higher than the temperature fault limit plus hysteresis. The OT_WARN flag is reset when the RTD ADC value is higher than the temperature warning limit plus hysteresis. Rev. 0 | Page 74 of 82 Data Sheet ADP1048W VAC ADC GAIN TRIM REGISTER This register must be unlocked for write access; see Table 61. Table 125. Register 0xFE40—VAC ADC Gain Trim Bits 7 Bit Name Gain polarity R/W R/W [6:0] VAC ADC gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This value calibrates the VAC voltage sense gain. VFB ADC GAIN TRIM REGISTER This register must be unlocked for write access; see Table 61. Table 126. Register 0xFE41—VFB ADC Gain Trim Bits 7 Bit Name Gain polarity R/W R/W [6:0] VFB ADC gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This value calibrates the output voltage sense gain. CS ADC GAIN TRIM FOR 500 mV RANGE REGISTER This register must be unlocked for write access; see Table 61. Table 127. Register 0xFE42—CS ADC Gain Trim for 500 mV Range Bits 7 Bit Name Gain polarity R/W R/W [6:0] CS ADC gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This value calibrates the CS current sense gain. IBAL GAIN REGISTER Table 128. Register 0xFE43—IBAL Gain Bits 7 Bit Name IBAL enable R/W R/W [6:0] IBAL gain R/W Description 1 = enable current balancing. 0 = disable current balancing and reset the IBAL integrator. The gain can be set from 0 to 127. SMART VOUT LOW POWER THRESHOLD (P1) REGISTER Table 129. Register 0xFE44—Smart VOUT Low Power Threshold (P1) Bits [15:13] [12:0] Bit Name RSVD P1 R/W R R/W Description Reserved. These bits set the threshold value for low power mode operation when the smart output voltage function is enabled. When the input power is lower than this value, the output voltage is VOL1 for low line input and VOH1 for high line input. SMART VOUT HIGH POWER THRESHOLD (P2) REGISTER Table 130. Register 0xFE45—Smart VOUT High Power Threshold (P2) Bits [15:13] [12:0] Bit Name RSVD P2 R/W R R/W Description Reserved. These bits set the threshold value for high power mode operation when the smart output voltage function is enabled. When the input power is higher than this value, the output voltage is VOL2 for low line input and VOH2 for high line input. Rev. 0 | Page 75 of 82 ADP1048W Data Sheet SMART VOUT LOW LINE (VOL1) REGISTER Table 131. Register 0xFE46—Smart VOUT Low Line (VOL1) Bits [15:11] [10:0] Bit Name RSVD VOL1 R/W R R/W Description Reserved. These bits set the output voltage under low power mode operation with low line input. SMART VOUT LOW LINE (VOL2) REGISTER Table 132. Register 0xFE47—Smart VOUT Low Line (VOL2) Bits [15:11] [10:0] Bit Name RSVD VOL2 R/W R R/W Description Reserved. These bits set the output voltage under high power mode operation with low line input. SMART VOUT HIGH LINE (VOH1) REGISTER Table 133. Register 0xFE48—Smart VOUT High Line (VOH1) Bits [15:11] [10:0] Bit Name RSVD VOH1 R/W R R/W Description Reserved. These bits set the output voltage under low power mode operation with high line input. SMART VOUT HIGH LINE (VOH2) REGISTER Table 134. Register 0xFE49—Smart VOUT High Line (VOH2) Bits [15:11] [10:0] Bit Name RSVD VOH2 R/W R R/W Description Reserved. These bits set the output voltage under high power mode operation with high line input. SMART VOUT UPPER LIMIT (VOH) REGISTER Table 135. Register 0xFE4A—Smart VOUT Upper Limit (VOH) Bits [15:11] [10:0] Bit Name RSVD VOH R/W R R/W Description Reserved. These bits set the output voltage when the VAC input voltage is higher than the value set in Register 0xFE4B. SMART VOUT SUPER HIGH LINE REGISTER Table 136. Register 0xFE4B—Smart VOUT Super High Line Bits [15:11] [10:0] Bit Name RSVD Super high line voltage R/W R R/W Description Reserved. These bits set the input voltage value as a super high line limit. SYNC DELAY REGISTER Table 137. Register 0xFE4C—SYNC Delay Bits [15:0] Bit Name tSYNC_DELAY R/W R/W Description These bits set the additional delay between the external synchronization reference clock signal and the rising edge of PWM. Each LSB corresponds to 40 ns resolution. SMART_VOUT_SUPER_HIGH_LINE_HYS REGISTER Table 138. Register 0xFE4D—SMART_VOUT_SUPER_HIGH_LINE_HYS Bits [7:0] Bit Name Super high line voltage hysteresis R/W R/W Description These bits set the voltage hysteresis of the super high line voltage for the smart output voltage function. The output voltage is VOH2 if the input voltage is lower than the super high line voltage minus the voltage hysteresis. Rev. 0 | Page 76 of 82 Data Sheet ADP1048W POWER_HYS REGISTER Table 139. Register 0xFE4E—POWER_HYS Bits [7:0] Bit Name Power hysteresis R/W R/W Description These bits set the power hysteresis for low power mode operation. The PFC exits the low power mode if the input power is higher than the low power threshold plus the power hysteresis. ADVANCED FEATURE ENABLE REGISTER Table 140. Register 0xFE4F—Advanced Feature Enable Bits 7 6 Bit Name RSVD Enable current loop feedforward R/W R R/W Description Reserved. 1 = current loop feedforward is enabled. 5 Enable light load current loop filter R/W 0 = current loop feedforward is disabled. 1 = light load current loop filter is enabled. 4 Enable phase shedding R/W 3 Enable smart switching frequency R/W 0 = light load current loop filter is disabled. 1 = phase shedding is enabled. 0 = phase shedding is disabled. 1 = smart switching frequency is enabled. 2 Enable smart output voltage R/W 0 = smart switching frequency is disabled. 1 = smart output voltage is enabled. 1 Enable PWM synchronization R/W 0 = smart output voltage is disabled. 1 = PWM frequency synchronization is enabled. 0 Enable frequency dithering R/W 0 = PWM frequency synchronization is disabled. 1 = frequency dithering is enabled. 0 = frequency dithering is disabled. VOUT_OV_FAULT_HYS REGISTER Table 141. Register 0xFE50—VOUT_OV_FAULT_HYS Bits [7:0] Bit Name VOUT OV fault hysteresis R/W R/W Description This register determines the mantissa hysteresis for the VOUT_OV_FAULT_LIMIT condition. This hysteresis applies only when the disable output option is selected as the VOUT_OV_FAULT_ RESPONSE (Register 0x41, Bits[7:6]). The PFC output is reenabled when the output voltage is lower than VOUT_OV_FAULT_LIMIT minus this hysteresis. VIN_UV_FAULT_HYS REGISTER Table 142. Register 0xFE51—VIN_UV_FAULT_HYS Bits [7:0] Bit Name VIN UV fault hysteresis R/W R/W Description This register determines the mantissa hysteresis for the VIN_UV_FAULT_LIMIT condition. This hysteresis applies only when the disable output option is selected as the VIN_UV_FAULT_ RESPONSE (Register 0x5A, Bits[7:6]). The PFC output is reenabled when the input voltage is higher than VIN_UV_FAULT_LIMIT plus this hysteresis. VAC ADC OFFSET TRIM REGISTER This register must be unlocked for write access; see Table 61. Table 143. Register 0xFE53—VAC ADC Offset Trim Bits [7:0] Bit Name VAC ADC offset trim R/W R/W Description This register calibrates the VAC ADC offset (the offset is always subtracted from the ADC output). Rev. 0 | Page 77 of 82 ADP1048W Data Sheet CS ADC OFFSET TRIM FOR 500 mV RANGE REGISTER This register must be unlocked for write access; see Table 61. Table 144. Register 0xFE54—CS ADC Offset Trim for 500 mV Range Bits [7:0] Bit Name CS ADC offset trim R/W R/W Description This register calibrates the CS current sense offset (the offset is always subtracted from the ADC output). CS ADC GAIN TRIM FOR HIGH (750 mV) RANGE REGISTER This register must be unlocked for write access; see Table 61. Table 145. Register 0xFE7E—CS ADC Gain Trim for High (750 mV) Range Bits 7 Bit Name Gain polarity R/W R/W [6:0] CS ADC gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This register calibrates the CS current sense gain. CS ADC OFFSET TRIM FOR HIGH (750 mV) RANGE REGISTER This register must be unlocked for write access; see Table 61. Table 146. Register 0xFE7F—CS ADC Offset Trim for High (750 mV) Range Bits [7:0] Bit Name CS ADC offset trim R/W R/W Description This register calibrates the CS current sense offset (the offset is always subtracted from the ADC output). LATCHED FLAG REGISTERS The bits in the latched flag registers remain set (latched) to allow users to detect an intermittent fault. Reading a latched flag register resets the flags in that register. Table 147. Register 0xFE80—Latched Flag 0 Bits 7 6 5 4 3 Bit Name MAX_MODULATION MIN_MODULATION OLP FAST_OVP AC_PERIOD R/W R R R R R 2 1 0 BROWN_OUT SOFT_START INRUSH R R R Description 1 = maximum modulation limit is reached. 1 = minimum modulation limit is reached. 1 = one of the two voltage dividers is probably disconnected or malfunctioning. 1 = the threshold set for the comparator on the OVP pin has been crossed. 1 = controller is not able to detect the ac line period; the maximum value of the period is used and this flag is set. 1 = VAC is lower than the value stored in VIN_ON (Register 0x35). 1 = system is in soft start sequence; fast loop filter is in use. 1 = INRUSH control relay is off. Table 148. Register 0xFE81—Latched Flag 1 Bits 7 6 5 4 Bit Name RSVD EEPROM_UNLOCKED EEPROM_CRC I2C_ADDRESS R/W R R R R 3 2 1 0 LOW_LINE FAST_OCP SYNC_LOCK AC_OK R R R R Description Reserved. 1 = EEPROM is unlocked and its contents can be written. 1 = downloaded EEPROM contents are incorrect. 1 = the resistor on the ADD pin has a value that can cause an error in the address assignment (the address falls too close to the threshold between two addresses). 1 = input voltage is higher than the high line threshold. 1 = the threshold set for the comparator on the ILIM pin has been crossed. 1 = external synchronization frequency is locked. This flag is a programmable combination of other internal flags and refers to the condition of the input voltage. A value of 1 means that the output of the AC_OK pin is low. Rev. 0 | Page 78 of 82 Data Sheet ADP1048W Table 149. Register 0xFE82—Latched Flag 2 Bits [7:6] 5 4 3 2 1 0 Bit Name RSVD LOW_POWER FAST_LOOP VCORE_OV VDD_3.3V_OV VDD_3.3V_UV RSVD R/W R R R R R R R Description Reserved. 1 = input power has dropped below the threshold for low power mode operation. 1 = fast loop compensation filter is in use. 1 = an overvoltage condition is present on the VCORE rail. 1 = an overvoltage condition is present on the VDD rail. 1 = an undervoltage condition is present on the VDD rail. Reserved. PWM VALUE REGISTER Table 150. Register 0xFE84—PWM Value Bits [7:0] Bit Name PWM value R/W R Description Return the eight MSBs of the PWM value (10 bits). VAC_LINE_PERIOD REGISTER Table 151. Register 0xFE85—VAC_LINE_PERIOD Bits [7:0] Bit Name VAC line period R/W R Description Return the measured period on the VAC pin signal. Each LSB corresponds to 163.84 μs. READ TEMPERATURE ADC REGISTER Table 152. Register 0xFE86—Read Temperature ADC Bits [15:0] Bit Name RTD temperature R/W R Description Return the measured temperature in ADC 13-bit format. POWER METERING OFFSET TRIM FOR HIGH LINE INPUT REGISTER Table 153. Register 0xFE8E—Power Metering Offset Trim for High Line Input Bits 7 Bit Name Offset trim polarity R/W R/W [6:0] Power meter offset trim R/W Description 1 = negative offset trim is introduced. 0 = positive offset trim is introduced. This value calibrates the power meter offset at the high line input voltage. Each LSB corresponds to 0.0625/128 of the full input power. POWER METERING GAIN TRIM FOR HIGH LINE INPUT REGISTER Table 154. Register 0xFE8F—Power Metering Gain Trim for High Line Input Bits 7 Bit Name Gain trim polarity R/W R/W [6:0] Power meter gain trim R/W Description 1 = negative gain trim is introduced. 0 = positive gain trim is introduced. This value calibrates the power meter gain at the high line input voltage. Each LSB corresponds to 0.0625/128 of the input power. CURRENT LOOP FILTER GAIN FOR LOW LINE INPUT AND LIGHT LOAD REGISTER Table 155. Register 0xFE90—Current Loop Filter Gain for Low Line Input and Light Load Bits [7:0] Bit Name Current loop filter gain for low line and light load R/W R/W Description These bits set the current loop digital filter gain of the PFC current loop under the low line input voltage at a light load condition if Bit 5 of Register 0xFE4F is set to 1. Rev. 0 | Page 79 of 82 ADP1048W Data Sheet CURRENT LOOP FILTER ZERO FOR LOW LINE INPUT AND LIGHT LOAD REGISTER Table 156. Register 0xFE91—Current Loop Filter Zero for Low Line Input and Light Load Bits [7:0] Bit Name Current loop filter zero for low line and light load R/W R/W Description These bits set the current loop digital filter zero of the PFC current loop under the low line input voltage at a light load condition if Bit 5 of Register 0xFE4F is set to 1. CURRENT LOOP FILTER GAIN FOR HIGH LINE INPUT AND LIGHT LOAD REGISTER Table 157. Register 0xFE92—Current Loop Filter Gain for High Line Input and Light Load Bits [7:0] Bit Name Current loop filter gain for high line and light load R/W R/W Description These bits set the current loop digital filter gain of the PFC current loop under the high line input voltage at a light load condition if Bit 5 of Register 0xFE4F is set to 1. CURRENT LOOP FILTER ZERO FOR HIGH LINE INPUT AND LIGHT LOAD REGISTER Table 158. Register 0xFE93—Current Loop Filter Zero for High Line Input and Light Load Bits [7:0] Bit Name Current loop filter zero for high line and light load R/W R/W Description These bits set the current loop digital filter zero of the PFC current loop under the high line input voltage at a light load condition if Bit 5 of Register 0xFE4F is set to 1. SMART VOUT POWER READING REGISTER Table 159. Register 0xFE94—Smart VOUT Power Reading Bits [15:0] Bit Name Power reading R/W R Description Return the average power reading for smart output voltage (averaged over 16 full line cycles). IBAL CONFIGURATION REGISTER Table 160. Register 0xFE95—IBAL Configuration Bits 7 Bit Name IBAL disconnect R/W R/W 6 IBAL at load transient R/W [5:4] 3 RSVD IBAL at low power mode R R/W [2:0] RSVD R Description 1 = disconnect the output of the current balance block from the PWM outputs. 0 = connect the output of the current balance block to the PWM outputs. 0 = disable current balancing when the fast loop is triggered. 1 = enable current balancing when the fast loop is triggered. It is recommended that this bit be set to 0. Reserved. 1 = disable current balancing under low power mode if the output of the current balancing block reaches the limit. 0 = enable current balancing under low power mode even if the output of the current balancing block reaches the limit. It is recommended that this bit be set to 1. Reserved. DEBUG FLAG REGISTERS Table 161. Register 0xFE96—Debug Flag 0 Bits 7 6 5 4 3 2 1 Bit Name OT_WARN OT_FAULT TEMPERATURE UNKNOWN MFR_FAULT PSON PGOOD R/W R R R R R R R 0 AC_OK R Description 1 = measured temperature is above the value of OT_WARN_LIMIT. 1 = measured temperature is above the value of OT_FAULT_LIMIT. 1 = temperature fault or warning. 1 = fault or warning not listed in Register 0x79, Bits[15:1]. 1 = manufacturer-specific fault or warning (Register 0xFE80, Register 0xFE81, Register 0xFE82). 1 = PSON signal (hardware or software) is inactive. Power good. This flag is a programmable combination of other internal flags and refers to the condition of the output voltage. A value of 1 means that the output of the PGOOD pin is low. This flag is a programmable combination of other internal flags and refers to the condition of the input voltage. A value of 1 means that the output of the AC_OK pin is low. Rev. 0 | Page 80 of 82 Data Sheet ADP1048W Table 162. Register 0xFE97—Debug Flag 1 Bits 7 6 5 Bit Name EEPROM_UNLOCKED EEPROM_CRC I2C_ADDRESS R/W R R R 4 3 2 1 0 FAST_LOOP MAX_MODULATION MIN_MODULATION SOFT_START SYNC_LOCK R R R R R Description 1 = EEPROM is unlocked and its contents can be written. 1 = downloaded EEPROM contents are incorrect. 1 = the resistor on the ADD pin has a value that can cause an error in the address assignment (the address falls too close to the threshold between two addresses). 1 = fast loop compensation filter is in use. 1 = maximum modulation limit is reached. 1 = minimum modulation limit is reached. 1 = system is in soft start sequence; fast loop filter is in use. 1 = external synchronization frequency is locked. Table 163. Register 0xFE98—Debug Flag 2 Bits 7 6 5 4 3 2 1 0 Bit Name VIN_UV VIN_LOW VIN_UV_FAULT VIN_UV_WARN LOW_LINE BROWN_OUT CML VDD_3.3V_OV R/W R R R R R R R R Description 1 = general input undervoltage fault (same as Register 0x7C, Bit 4). 1 = VAC is lower than VIN_OFF (Register 0x36). This signal shuts down the power supply. 1 = input voltage on VAC is smaller than the value in VIN_UV_FAULT_LIMIT (Register 0x59). 1 = input voltage on VAC is smaller than the value in VIN_UV_WARN_LIMIT (Register 0x58). 1 = input voltage is higher than the high line threshold. 1 = VAC is lower than the value stored in VIN_ON (Register 0x35). 1 = communications, memory, or logic fault. 1 = an overvoltage condition is present on the VDD rail. Table 164. Register 0xFE99—Debug Flag 3 Bits 7 6 5 4 Bit Name VIN_OV_FAULT VCORE_OV PIN_OP_WARN AC_PERIOD R/W R R R R 3 IIN_OC_WARN R 2 IIN_OC_FAULT R 1 0 FAST_OCP INPUT R R Description 1 = input voltage on VAC is larger than the value in VIN_OV_FAULT_LIMIT (Register 0x55). 1 = an overvoltage condition is present on the VCORE rail. 1 = input overpower warning. 1 = controller is not able to detect the ac line period; the maximum value of the period is used and this flag is set. 1 = input current measured on the CS ADC is larger than the value in IIN_OC_WARN_LIMIT (Register 0x5D). 1 = input current measured on the CS ADC is larger than the value in IIN_OC_FAULT_LIMIT (Register 0x5B). 1 = the threshold set for the comparator on the ILIM pin has been crossed. 1 = input voltage, input current, or input power fault or warning. Table 165. Register 0xFE9A—Debug Flag 4 Bits 7 6 5 4 3 2 1 Bit Name OLP FAST_OVP VOUT_UV_FAULT VOUT_UV_WARN VOUT_OV_WARN VOUT_OV_FAULT VOUT_OV R/W R R R R R R R 0 VOUT R Description 1 = one of the two voltage dividers is probably disconnected or malfunctioning. 1 = the threshold set for the comparator on the OVP pin has been crossed. 1 = output voltage is below the VOUT_UV_FAULT_LIMIT (Register 0x44). 1 = output voltage is below the VOUT_UV_WARN_LIMIT (Register 0x43). 1 = output voltage is above the VOUT_OV_WARN_LIMIT (Register 0x42). 1 = output voltage is above the VOUT_OV_FAULT_LIMIT (Register 0x40). General output overvoltage fault: this flag is a combination (OR) of any output overvoltage flag (Register 0x7A, Bit 7 and Register 0xFE80, Bit 4 (FAST_OVP)). 1 = any fault on output voltage (overvoltage, undervoltage, fast OVP, or accurate OVP). Table 166. Register 0xFE9B—Debug Flag 5 Bits [7:3] 2 1 0 Bit Name RSVD LOW_POWER VDD_3.3V_UV INRUSH R/W R R R R Description Reserved. 1 = input power has dropped below the threshold for low power mode operation. 1 = an undervoltage condition is present on the VDD rail. 1 = INRUSH control relay is off. Rev. 0 | Page 81 of 82 ADP1048W Data Sheet OUTLINE DIMENSIONS 0.345 (8.76) 0.341 (8.66) 0.337 (8.55) 13 1 12 0.010 (0.25) 0.006 (0.15) 0.069 (1.75) 0.053 (1.35) 0.065 (1.65) 0.049 (1.25) 0.010 (0.25) 0.004 (0.10) COPLANARITY 0.004 (0.10) 0.158 (4.01) 0.154 (3.91) 0.150 (3.81) 0.244 (6.20) 0.236 (5.99) 0.228 (5.79) 0.025 (0.64) BSC SEATING PLANE 0.012 (0.30) 0.008 (0.20) 8° 0° 0.050 (1.27) 0.016 (0.41) COMPLIANT TO JEDEC STANDARDS MO-137-AE CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS (IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN. 0.020 (0.51) 0.010 (0.25) 0.041 (1.04) REF 01-03-2008-A 24 Figure 42. 24-Lead Shrink Small Outline Package [QSOP] (RQ-24) Dimensions shown in inches and (millimeters) ORDERING GUIDE Model1, 2 ADP1048WARQZ-R7 ADP1048-600-EVALZ ADP1048DC1-EVALZ ADP-I2C-USB-Z 1 2 Temperature Range −40°C to +125°C Package Description 24-Lead Shrink Small Outline Package [QSOP] ADP1048W 600 W Evaluation Board ADP1048W Daughter Card USB to I2C Adapter Package Option RQ-24 Z = RoHS Compliant Part. W = Qualified for Automotive Applications. AUTOMOTIVE PRODUCTS The ADP1048W models are available with controlled manufacturing to support the quality and reliability requirements of automotive applications. Note that these automotive models may have specifications that differ from the commercial models; therefore, designers should review the Specifications section of this data sheet carefully. Only the automotive grade products shown are available for use in automotive applications. Contact your local Analog Devices account representative for specific product ordering information and to obtain the specific Automotive Reliability reports for these models. I2C refers to a communications protocol originally developed by Philips Semiconductors (now NXP Semiconductors). ©2014 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D12535-0-8/14(0) Rev. 0 | Page 82 of 82