Data Sheet Digital Controller for Isolated Power Supply Applications ADP1046 FEATURES GENERAL DESCRIPTION Integrates all typical PWM controller functions 7 PWM control signals Digital control loop Integrated programmable loop filters Programmable voltage line feedforward Dedicated soft start filter Programmable dead time for improved efficiency Remote and local voltage sense Primary and secondary side current sense Synchronous rectifier control Current sharing OrFET control I2C interface Extensive fault detection and protection Extensive programming and telemetry Fast digital calibration User accessible EEPROM The ADP1046 is a flexible, digital secondary side controller designed for ac-to-dc and isolated dc-to-dc secondary side applications. The ADP1046 is pin-compatible with the ADP1043A and offers several enhancements and new features, including voltage feedforward, improved loop response, and programmable dead time control to maximize efficiency. The ADP1046 is optimized for minimal component count, maximum flexibility, and minimum design time. Features include local and remote voltage sense, primary and secondary side current sense, digital pulse-width modulation (PWM) generation, current sharing, and redundant OrFET control. The control loop digital filter and compensation terms are integrated and can be programmed over the I2C interface. Programmable protection features include overcurrent protection (OCP), overvoltage protection (OVP), undervoltage lockout (UVLO), and overtemperature protection (OTP). The built-in EEPROM provides extensive programming of the integrated loop filter, PWM signal timing, inrush current, and soft start timing and sequencing. Reliability is improved through a built-in checksum and programmable protection circuits. APPLICATIONS AC-to-DC power supplies Isolated dc-to-dc power supplies Redundant power supply systems Server, storage, network, and communications infrastructure A comprehensive GUI is provided for easy design of loop filter characteristics and programming of the safety features. The industry-standard I2C bus provides access to the many monitoring and system test functions. The ADP1046 is available in a 32-lead LFCSP and operates from a single 3.3 V supply. TYPICAL APPLICATION CIRCUIT DC INPUT LOAD DRIVER DRIVER SR1 SR2 ACSNS CS2– CS2+ PGND VS1 GATE VS2 CS1 DRIVER iCoupler OUTA OUTB ADP1046 OUTC OUTD OUTAUX RES ADD RTD VCORE FLAGIN PSON PGOOD2 PGOOD1 SDA SCL VS3+ VS3– SHAREo SHAREi VDD DGND AGND MICROCONTROLLER 10045-001 VDD Figure 1. Rev. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.461.3113 ©2012 Analog Devices, Inc. All rights reserved. ADP1046 Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 Power Readings .......................................................................... 28 Applications....................................................................................... 1 Power Monitoring Accuracy..................................................... 28 General Description ......................................................................... 1 First Flag Fault ID and Value Registers ................................... 28 Typical Application Circuit ............................................................. 1 External Flag Input (FLAGIN Pin) .......................................... 28 Revision History ............................................................................... 3 Temperature Readings (RTD Pin) ........................................... 28 Functional Block Diagram .............................................................. 4 Overtemperature Protection (OTP) ........................................ 29 Specifications..................................................................................... 5 Overcurrent Protection (OCP) ................................................ 29 Absolute Maximum Ratings.......................................................... 10 Constant Current Mode ............................................................ 30 Thermal Resistance .................................................................... 10 Overvoltage Protection (OVP)................................................. 30 Soldering...................................................................................... 10 Undervoltage Protection (UVP) .............................................. 31 ESD Caution................................................................................ 10 AC Sense (ACSNS)..................................................................... 31 Pin Configuration and Function Descriptions........................... 11 Volt-Second Balance .................................................................. 32 Typical Performance Characteristics ........................................... 13 Digital Load Line and Slew Rate .............................................. 32 Theory of Operation ...................................................................... 15 Power Supply Calibration and Trim ............................................ 33 Current Sense.............................................................................. 15 CS1 Trim...................................................................................... 33 Voltage Sense and Control Loop .............................................. 16 CS2 Trim...................................................................................... 33 ADCs............................................................................................ 16 Voltage Calibration and Trim ................................................... 34 VS1 Operation (VS1) ................................................................. 16 Output Voltage Setting (VS3+, VS3− Trim) ........................... 34 VS2 Operation (VS2) ................................................................. 17 VS1 Trim...................................................................................... 34 VS3 Operation (VS3+, VS3−) ................................................... 17 VS2 Trim...................................................................................... 34 Voltage Line Feedforward and ACSNS.................................... 17 RTD/OTP Trim .......................................................................... 34 Digital Filter ................................................................................ 17 ACSNS Calibration and Trim................................................... 35 PWM and Sync Rect Outputs (OUTA, OUTB, OUTC, OUTD, OUTAUX, SR1, SR2) ................................................... 18 Layout Guidelines........................................................................... 36 Synchronous Rectification ........................................................ 19 VS3+ and VS3−........................................................................... 36 SR (Synchronous Rectifier) Delay............................................ 19 VDD ............................................................................................. 36 Adaptive Dead Time Control.................................................... 19 SDA and SCL .............................................................................. 36 Light Load Mode ........................................................................ 19 CS1 ............................................................................................... 36 Modulation Limit ....................................................................... 19 Exposed Pad................................................................................ 36 Soft Start ...................................................................................... 20 VCORE ........................................................................................ 36 OrFET Control (GATE) ............................................................ 22 RES ............................................................................................... 36 VDD ............................................................................................. 24 RTD .............................................................................................. 36 CS2+ and CS2−........................................................................... 36 VDD/VCORE OVLO ................................................................ 24 AGND, DGND, and PGND...................................................... 36 Power Good................................................................................. 24 I C Interface Communication ...................................................... 37 Current Sharing (Share) ............................................................ 25 Features........................................................................................ 37 Power Supply System and Fault Monitoring............................... 27 Overview ..................................................................................... 37 Flags.............................................................................................. 27 I2C Address.................................................................................. 37 Monitoring Functions................................................................ 27 Data Transfer............................................................................... 37 Voltage Readings ........................................................................ 27 General Call Support ................................................................. 39 Current Readings........................................................................ 27 10-Bit Addressing....................................................................... 39 2 Rev. 0 | Page 2 of 96 Data Sheet ADP1046 Fast Mode .....................................................................................39 ID Registers..................................................................................63 Repeated Start Condition...........................................................39 PWM and Synchronous Rectifier Timing Registers ..............64 Electrical Specifications..............................................................39 Digital Filter Programming Registers ......................................74 Fault Conditions..........................................................................39 Adaptive Dead Time Registers..................................................76 Timeout Condition .....................................................................39 Soft Start Filter Programming Registers ..................................80 Data Transmission Faults...........................................................39 Extended Functions Registers ...................................................81 Data Content Faults ....................................................................39 EEPROM Registers .....................................................................84 EEPROM ..........................................................................................41 Resonant Mode Operation.............................................................87 Overview ......................................................................................41 Resonant Mode Enable...............................................................87 Page Erase Operation .................................................................41 PWM Timing in Resonant Mode .............................................87 Read Operation (Byte Read and Block Read) .........................41 Synchronous Rectification in Resonant Mode........................87 Write Operation (Byte Write and Block Write) ......................42 Adjusting the Timing of the PWM Outputs ...........................88 EEPROM Password.....................................................................42 Frequency Limit Setting.............................................................88 Downloading EEPROM Settings to Internal Registers..........42 Feedback Control in Resonant Mode.......................................88 Saving Register Settings to the EEPROM ................................43 Soft Start in Resonant Mode......................................................88 EEPROM CRC Checksum.........................................................43 Light Load Operation (Burst Mode) ........................................88 Software GUI ...................................................................................44 OUTAUX in Resonant Mode ....................................................88 Register Listing ................................................................................45 Protections in Resonant Mode..................................................88 Detailed Register Descriptions ......................................................49 Resonant Mode Register Descriptions.....................................89 Fault Registers..............................................................................49 Outline Dimensions........................................................................93 Value Registers.............................................................................52 Ordering Guide ...........................................................................93 Current Sense and Current Limit Registers ............................55 Voltage Sense Registers ..............................................................60 REVISION HISTORY 3/12—Revision 0: Initial Version Rev. 0 | Page 3 of 96 ADP1046 Data Sheet The ADP1046 is a secondary side controller for switch mode power supplies (SMPS). It is designed for use in isolated redundant applications. The ADP1046 integrates the typical functions that are needed to control a power supply, such as The PWM block generates up to seven programmable PWM outputs for control of FET drivers and synchronous rectification FET drivers. This programmability allows many traditional and unique switching topologies to be realized. • • • • • • • • • A current share bus interface is provided for paralleling multiple power supplies. The ADP1046 also has hot-swap OrFET sense and control for N + 1 redundant power supplies. Output voltage sense and feedback Voltage line feedforward control Digital loop filter compensation PWM generation Current sharing Current, voltage, and temperature sense OrFET control Housekeeping and I2C interface Calibration and trimming Conventional power supply housekeeping features, such as remote and local voltage sense and primary and secondary side current sense, are included. An extensive set of protections is offered, including overvoltage protection (OVP), overcurrent protection (OCP), overtemperature protection (OTP), undervoltage protection (UVP), ground continuity monitoring (voltage continuity), and ac sense. The main function of controlling the output voltage is performed using the feedback ADCs, the digital loop filter, and the PWM block. All these features are programmable through the I2C bus interface. This bus interface is also used to calibrate the power supply. Other information that is useful for power monitoring, such as input current, output current, and fault flags, is also available through the I2C bus interface. The feedback ADCs use a multipath approach (patent pending). The ADP1046 combines a high speed, low resolution (fast and coarse) ADC with a low speed, high resolution (slow and accurate) ADC. Loop compensation is implemented using the digital filter. This proportional, integral, derivative (PID) filter is implemented in the digital domain to allow easy programming of filter characteristics, which is of great value in customizing and debugging designs. The internal EEPROM can store all programmed values and allows standalone control without a microcontroller. A free, downloadable GUI is available and provides all the necessary software to program the ADP1046. To obtain the latest software and a user guide, visit http://www.analog.com/digitalpower. The ADP1046 operates from a single 3.3 V supply and is specified from −40°C to +125°C. GATE VS2 PGND VS1 ACSNS CS2+ CS2– FUNCTIONAL BLOCK DIAGRAM 0.45V ADP1046 + – V_OVP 1.2V VREF – + CS1 ADC ADC ADC ADC ADC ADC SR1 VS3+ VS3– SR2 SHAREo OUTA OUTB PWM ENGINE SHAREi OUTC OUTD OUTAUX VDD PWM DIGITAL CORE UVLO 8kB EEPROM PGOOD1 I2C INTERFACE PGOOD2 ADC FLAGIN LDO DGND PSON OSC SCL AGND SDA ADD RTD Figure 2. ADP1046 Simplified Block Diagram Rev. 0 | Page 4 of 96 10045-002 VCORE RES Data Sheet ADP1046 SPECIFICATIONS VDD = 3.0 V to 3.6 V, TA = −40°C to +125°C, unless otherwise noted. FSR = full-scale range. Table 1. Parameter SUPPLY Supply Voltage Supply Current Symbol Test Conditions/Comments Min Typ Max Unit VDD IDD 4.7 μF capacitor connected to AGND Normal operation (PSON is high or low) During EEPROM programming (40 ms) Shutdown (VDD below UVLO) 3.0 3.3 20 IDD + 8 100 3.6 V mA mA μA 2.75 3.0 2.97 4.1 V V mV V μs μs POWER-ON RESET Power-On Reset UVLO UVLO Hysteresis OVLO OVLO Debounce VCORE PIN Output Voltage OSCILLATOR AND PLL PLL Frequency OUTA, OUTB, OUTC, OUTD, OUTAUX, SR1, SR2, GATE PINS Output Low Voltage Output High Voltage Rise Time Fall Time VS1, VS2, VS3 LOW SPEED ADCs Input Voltage Range Usable Input Voltage Range ADC Clock Frequency Register Update Rate Voltage Sense Measurement Accuracy VDD rising VDD falling VOL VOH VIN 3.8 When set to 2 μs When set to 500 μs 0.33 μF capacitor connected to DGND TA = 25°C 2.85 40 4.0 2.0 500 2.4 2.5 2.7 V RES = 10 kΩ (±0.1%) 190 200 210 MHz 0.4 V V ns ns 1.6 V 1.4 V MHz ms +3.0 +48 +2.0 +32 +1.0 +16 65 1.0 % FSR mV % FSR mV % FSR mV ppm/°C μA Bits +0.25 +200 % FSR mV Source current = 10 mA Source current = 10 mA CLOAD = 50 pF CLOAD = 50 pF Differential voltage from VS1, VS2 to PGND, and from VS3+ to VS3− 1 Factory trimmed at 1.0 V 900 mV to 1.1 V VS2 and VS3 OVP Threshold Accuracy 0 1.56 10 10% to 90% of usable input voltage range VS1 OVP Threshold Accuracy VS2 and VS3 OVP Speed 3.5 1.5 0 0% to 100% of usable input voltage range Temperature Coefficient Leakage Current Voltage Sense Measurement Resolution Common-Mode Voltage Offset Voltage Differential from VS3− to PGND VS1 Accurate OVP Speed VDD − 0.4 −3.0 −48 −2.0 −32 −1.0 −16 12 −0.25 −200 Register 0x32[1:0] = 00; equivalent resolution is 7 bits Relative to nominal voltage (1 V) on VS1 Register 0x33[1:0] = 00; equivalent resolution is 7 bits Relative to nominal voltage (1 V) on VS2 and VS3 Rev. 0 | Page 5 of 96 80 −2.0 μs +2.0 % FSR μs +2.0 % FSR 80 −2.0 ADP1046 Parameter VS3 HIGH SPEED ADC Equivalent Sampling Frequency Equivalent Resolution Dynamic Range VS1 FAST OVP COMPARATOR Threshold Accuracy Propagation Delay Data Sheet Symbol Max Unit fSW kHz fSW = 390.6 kHz 6 ±30 Bits mV Factory trimmed at 1.2 V Does not include debounce time (Register 0x0A[7] = 1) 1 40 0.4 From ACSNS threshold to SRx rising edge (resonant mode only) VACSNS 0 0 Equivalent resolution is 11 bits Factory trimmed at 1.0 V 0% to 100% of usable input voltage range 10% to 90% of usable input voltage range 900 mV to 1.1 V VIN 1.25 % ns +2.0 % FSR ns 0.5 V ns 80 Does not include debounce time (Register 0x0B[3] = 1) PWM and resonant mode 0.45 160 1.56 1 100 MHz V V Hz 10 μs −5.0 −2.0 −1.0 −16 0 0 1 1.6 1.4 +3.0 +2.0 +1.0 +16 1.0 % FSR % FSR % FSR mV μA 1.4 1.3 V V MHz ms +3.0 +41.4 +3.0 +42 +1.0 % FSR mV % FSR mV % FSR Bits 1.21 100 +2.0 +28 5.24 1.0 V ns % FSR mV ms μA 1.56 10 Factory trimmed at 0.7 V; tested under dc input conditions 10% to 50% of usable input voltage range 0% to 100% of usable input voltage range 40% to 60% of usable input voltage range Current Sense Measurement Resolution CS1 Fast OCP Threshold CS1 Fast OCP Speed CS1 Accurate OCP DC Accuracy Typ −2.0 AC SENSE COMPARATOR Input Voltage Threshold Propagation Delay Leakage Current CURRENT SENSE 1 (CS1 PIN) Input Voltage Range Usable Input Voltage Range ADC Clock Frequency Register Update Rate Current Sense Measurement Accuracy Min fSAMP VS1 UVP DIGITAL COMPARATOR VS1 UVP Accuracy Propagation Delay ADC Clock Frequency Input Voltage Range Usable Input Voltage Range Sampling Frequency for I2C Reporting Sampling Period for Feedforward Measurement Accuracy Test Conditions/Comments −3.0 −41.4 −6.0 −84 −1.0 12 1.18 10% to 90% of usable input voltage range CS1 Accurate OCP Speed Leakage Current 1.2 80 −2.0 −28 2.62 Rev. 0 | Page 6 of 96 Data Sheet Parameter CURRENT SENSE 2 (CS2+, CS2− PINS) Input Voltage Range Usable Input Voltage Range ADC Clock Frequency Temperature Coefficient 120 mV Range 60 mV Range Current Sense Measurement 120 mV Setting 60 mV Setting Current Sense Measurement Accuracy 120 mV Setting 60 mV Setting Leakage Current Current Sense Measurement Resolution CS2 Accurate OCP Speed Current Sink (High Side) Current Source (Low Side) Common-Mode Voltage at the CS2+ and CS2− Pins OrFET PROTECTION (CS2+, CS2−) Fast OrFET Accuracy Fast OrFET Speed RTD TEMPERATURE SENSE ADC Clock Frequency Input Voltage Range Usable Input Voltage Range Source Current Source Current Fine Setting RTD ADC Register Update Rate Resolution ADP1046 Symbol Test Conditions/Comments Min VIN Differential voltage from CS2+ to CS2−, LSB = 29.297 μV 0 Typ Max Unit 120 mV 110 mV MHz 78 70 156 140 ppm/°C ppm/°C ppm/°C ppm/°C −2.1 −2.52 −4.2 −5.04 +2.1 +2.52 +4.2 +5.04 % FSR mV % FSR mV −0.9 −1.08 −1.8 −2.16 +0.9 +1.08 +1.8 +2.16 1.0 % FSR mV % FSR mV μA Bits 2.62 2 200 1.0 5.24 1.4 ms mA μA V −3.00 −6.21 −9.43 −12.64 −15.86 −19.07 −22.29 −25.50 110 −9.5 −12.71 −16.18 −19.39 −22.71 −25.92 −29.29 −32.50 150 mV mV mV mV mV mV mV mV ns 1.6 1.3 47.65 MHz V V μA 0 1.56 0 mV to 100 mV 0 mV to 50 mV 0 mV to 50 mV 0 mV to 25 mV 0 mV to 110 mV 0 mV to 55 mV With 0.01% level shifting resistors 0 mV to 100 mV, VDD = 3.3 V 0 mV to 55 mV, VDD = 3.3 V 12 To achieve CS2 measurement accuracy 0.8 Low-side and high-side current sensing −3 mV setting −6 mV setting −9 mV setting −12 mV setting −15 mV setting −18 mV setting −21 mV setting −24 mV setting Debounce = 40 ns +3.5 +0.29 −2.68 −5.89 −9.01 −12.22 −15.29 −18.50 1.56 RTD to AGND Factory trimmed to 46 μA (Register 0x11 set to 0xE6) Current source set to 10 μA Current source set to 20 μA Current source set to 30 μA Current source set to 40 μA See Register 0x11[5:0] 0 0 44.35 9.25 18.35 28.45 38.45 46 10.1 20.1 30.2 40.3 160 10 12 Rev. 0 | Page 7 of 96 10.75 21.85 31.95 41.95 μA μA μA μA nA ms Bits ADP1046 Parameter Measurement Accuracy Data Sheet Symbol Test Conditions/Comments Factory trimmed at 1 V 0 mV to 160 mV 0% to 100% of usable input voltage range Temperature Readings According to Internal Linearization Scheme T = 85°C with 100 kΩ||16.5 kΩ T = 100°C with 100 kΩ||16.5 kΩ Leakage Current GATE PIN Output Low Voltage Output High Voltage SDA/SCL PINS Input Low Voltage Input High Voltage Output Low Voltage Leakage Current SERIAL BUS TIMING Clock Operating Frequency Bus-Free Time Start Hold Time Typ −0.5 −8 −3.0 −42 RTD source set to 46 μA (Register 0x11 set to 0xE6); NTC R0 = 100 kΩ, 1%, beta = 4250, 1%; REXT = 16.5 kΩ, 1% 25°C to 100°C 100°C to 125°C OTP Threshold Accuracy Comparator Speed OTP Threshold Hysteresis PGOOD1, PGOOD2, SHAREo PINS (OPEN DRAIN) Output Low Voltage PSON, FLAGIN, SHAREi PINS (DIGITAL INPUTS) Input Low Voltage Input High Voltage FLAGIN Propagation Delay Min −0.9 −14.4 −0.5 −8 Max Unit +0.5 +8 +3.0 +42 % FSR mV % FSR mV 7 5 °C °C +0.25 +4 +1.1 +17.6 % FSR mV % FSR mV ms mV 0.4 V 0.4 V V ns 1.0 μA 0.4 V V 0.4 V V V μA 10.5 16 VOL VIL VIH VDD − 0.4 200 Does not include debounce time (Register 0x0A[3] = 1); flag action set to disable PSU VOL VOH VDD − 0.4 VDD = 3.3 V VIL VIH VOL VDD − 0.4 0.4 1.0 See Figure 3 tBUF tHD;STA Start Setup Time Stop Setup Time SDA Setup Time SDA Hold Time tSU;STA tSU;STO tSU;DAT tHD;DAT SCL Low Timeout SCL Low Period SCL High Period Clock Low Extend Time SCL, SDA Fall Time SCL, SDA Rise Time tTIMEOUT tLOW tHIGH tLO;SEXT tF tR Between stop and start conditions Hold time after (repeated) start condition; after this period, the first clock is generated Repeated start condition setup time For readback For write 10 1.3 0.6 0.6 0.6 100 125 300 25 1.3 0.6 20 20 Rev. 0 | Page 8 of 96 100 400 35 25 300 300 kHz μs μs μs μs ns ns ns ms μs μs ms ns ns Data Sheet ADP1046 Parameter EEPROM RELIABILITY Endurance 1 Symbol Data Retention 2 1 2 Test Conditions/Comments Min TJ = 85°C TJ = 125°C TJ = 85°C TJ = 125°C 10,000 1000 20 10 Typ Max Unit Cycles Cycles Years Years Endurance is qualified as per JEDEC Standard 22, Method A117, and is measured at −40°C, +25°C, +85°C, and +125°C. Endurance conditions are subject to change pending EEPROM qualification. Retention lifetime equivalent at junction temperature (TJ) = 85°C as per JEDEC Standard 22, Method A117. The derated retention lifetime equivalent at junction temperature TJ = 125°C is 2.87 years and is subject to change pending EEPROM qualification. Timing Diagram tR tF tHD;STA tLOW SCL SDA tHD;DAT tHIGH tSU;STA tSU;DAT tSU;STO tBUF P S S Figure 3. Serial Bus Timing Diagram Rev. 0 | Page 9 of 96 P 10045-103 tHD;STA ADP1046 Data Sheet ABSOLUTE MAXIMUM RATINGS THERMAL RESISTANCE Table 2. Parameter Supply Voltage (Continuous), VDD Digital Pins: OUTA, OUTB, OUTC, OUTD, OUTAUX, SR1, SR2, GATE, PGOOD1, PGOOD2 VS3− to PGND, AGND, DGND VS1, VS2, VS3+ RTD, ADD CS1, CS2+, CS2− FLAGIN, PSON SDA, SCL SHAREo, SHAREi Operating Temperature Range Storage Temperature Range 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 4.2 V −0.3 V to VDD + 0.3 V −0.3 V to +0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 0.3 V −0.3 V to VDD + 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 32-Lead LFCSP θJA 44.4 θJC 6.4 Unit °C/W SOLDERING It is important to follow the correct guidelines when laying out the PCB footprint for the ADP1046 and when soldering the part onto the PCB. For detailed information about these guidelines, see the AN-772 Application Note. ESD CAUTION 240°C 260°C 1.5 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 10 of 96 Data Sheet ADP1046 32 31 30 29 28 27 26 25 VS3+ VS3– RES ADD RTD VDD VCORE DGND PIN CONFIGURATION AND FUNCTION DESCRIPTIONS 1 2 3 4 5 6 7 8 PIN 1 INDICATOR ADP1046 TOP VIEW (Not to Scale) 24 23 22 21 20 19 18 17 SHAREi SHAREo PGOOD1 PGOOD2 FLAGIN PSON SDA SCL NOTES 1. THE ADP1046 HAS AN EXPOSED THERMAL PAD ON THE UNDERSIDE OF THE PACKAGE. FOR INCREASED RELIABILITY OF THE SOLDER JOINTS AND MAXIMUM THERMAL CAPABILITY, IT IS RECOMMENDED THAT THE PAD BE SOLDERED TO THE PCB AGND PLANE. 10045-003 SR1 SR2 OUTA OUTB OUTC OUTD OUTAUX GATE 9 10 11 12 13 14 15 16 VS2 AGND VS1 CS2– CS2+ ACSNS CS1 PGND Figure 4. Pin Configuration Table 4. Pin Function Descriptions Pin No. 1 Mnemonic VS2 2 3 AGND VS1 4 CS2− 5 CS2+ 6 ACSNS 7 CS1 8 PGND 9 SR1 10 SR2 11 12 OUTA OUTB Description Power Supply Output Voltage Sense Input. This signal is referenced to PGND and is the input to a low frequency Σ-Δ ADC. Nominal voltage at this pin should be 1 V. The resistor divider on this input must have a tolerance specification of 0.5% or better to allow for trimming. Analog Ground. This pin is the ground for the analog circuitry and the return for the VDD pin of the ADP1046. Local Output Voltage Sense Input. This signal is referenced to PGND. Nominal voltage at this pin should be 1 V. The resistor divider on this input must have a tolerance specification of 0.5% or better to allow for trimming. Inverting Differential Current Sense Input. Nominal voltage at this pin should be 1 V for best operation. When using low-side current sensing, place a 5 kΩ resistor between the sense resistor and this pin. When using highside current sensing in a 12 V application, place a 5.5 kΩ resistor between the sense resistor and this pin. When using high-side current sensing with a voltage other than 12 V, use this formula to calculate the resistor value: R = (VOUT − 1)/2 mA. A 0.1% resistor must be used to connect this circuit. If this pin is not used, connect it to PGND and set CS2± to high-side current sense mode (set Bit 2 of Register 0x27). It is recommended that a 500 pF to 1000 pF capacitor be connected either across the resistor or from this pin to AGND. Noninverting Differential Current Sense Input. Nominal voltage at this pin should be 1 V for best operation. When using low-side current sensing, place a 5 kΩ resistor between the sense resistor and this pin. When using high-side current sensing in a 12 V application, place a 5.5 kΩ resistor between the sense resistor and this pin. When using high-side current sensing with a voltage other than 12 V, use this formula to calculate the resistor value: R = (VOUT − 1)/2 mA. A 0.1% resistor must be used to connect this circuit. If this pin is not used, connect it to PGND and set CS2± to high-side current sense mode (set Bit 2 of Register 0x27). It is recommended that a 500 pF to 1000 pF capacitor be connected either across the resistor or from this pin to AGND. AC Sense Input. This input is connected upstream of the main output inductor through a resistor divider network. The nominal voltage for this circuit is 0.45 V. This pin is also connected to the voltage feedforward ADC (nominal voltage 1 V). This signal is referenced to PGND. Primary Side Current Sense Input. This pin is connected to the primary side current sensing ADC and to the fast OCP comparator. This signal is referenced to PGND. The resistors on this input must have a tolerance specification of 0.5% or better to allow for trimming. If this pin is not used, connect it to PGND. Power Ground. This pin is the ground connection for the main power rail of the power supply and is the reference for all voltage and current sensing other than CS2± and VS3±. Star connect to AGND. Synchronous Rectifier Output. This PWM output connects to the input of a FET driver. This pin can be disabled when not in use. This signal is referenced to AGND. Synchronous Rectifier Output. This PWM output connects to the input of a FET driver. This pin can be disabled when not in use. This signal is referenced to AGND. PWM Output for Primary Side Switch. This pin can be disabled when not in use. This signal is referenced to AGND. PWM Output for Primary Side Switch. This pin can be disabled when not in use. This signal is referenced to AGND. Rev. 0 | Page 11 of 96 ADP1046 Pin No. 13 14 15 16 17 18 19 Mnemonic OUTC OUTD OUTAUX GATE SCL SDA PSON 20 21 FLAGIN PGOOD2 22 PGOOD1 23 SHAREo 24 SHAREi 25 26 DGND VCORE 27 VDD 28 RTD 29 ADD 30 RES 31 VS3− 32 VS3+ EP Data Sheet Description PWM Output for Primary Side Switch. This pin can be disabled when not in use. This signal is referenced to AGND. PWM Output for Primary Side Switch. This pin can be disabled when not in use. This signal is referenced to AGND. Auxiliary PWM Output. This pin can be disabled when not in use. This signal is referenced to AGND. OrFET Gate Drive Output. This signal is referenced to AGND. If this pin is not used, leave it floating. I2C Serial Clock Input. This signal is referenced to AGND. I2C Serial Data Input and Output (Open Drain). This signal is referenced to AGND. Power Supply On Input. This signal is referenced to AGND. This pin is the hardware PSON control signal. It is recommended that a 1 nF capacitor be connected from the PSON pin to AGND for noise debouncing and decoupling. Flag Input. An external signal can be input at this pin to generate a flag condition. Power-Good Output (Open Drain). This signal is referenced to AGND. This pin is controlled by the PGOOD2 flag. This pin is set by a programmable combination of internal flags. If this pin is not used, connect it to AGND. Power-Good Output (Open Drain). This signal is referenced to AGND. This pin is controlled by the PGOOD1 flag. This pin is set by a programmable combination of internal flags. If this pin is not used, connect it to AGND. Share Bus Output Voltage Pin. Connect this pin to 3.3 V through a pull-up resistor (typically 2.2 kΩ). When configured for a digital share bus, this pin is a digital output. This signal is referenced to AGND. If this pin is not used, connect it to AGND. Share Bus Feedback Pin. Connect this pin to the SHAREo pin. This signal is referenced to AGND. If this pin is not used, connect it to AGND. Digital Ground. This pin is the ground reference for the digital circuitry of the ADP1046. Star connect to AGND. Output of the 2.5 V Regulator. Connect a decoupling capacitor of at least 330 nF (1 μF maximum) from this pin to DGND as close to the IC as possible to minimize PCB trace length. It is recommended that the VCORE pin not be used as a reference or to generate other logic levels using resistive dividers. Positive Supply Input. This signal is referenced to AGND. Connect a 4.7 μF decoupling capacitor from this pin to AGND as close to the IC as possible to minimize PCB trace length. Thermistor Input. Place a thermistor (100 kΩ, 1%, beta = 4250, 1%) in parallel with a 16.5 kΩ, 1% resistor. This pin is referenced to AGND. If this pin is not used, connect it to AGND. Address Select Input. This pin is used to program the I2C address. Connect a resistor from ADD to AGND. This signal is referenced to AGND. Resistor Input. This pin sets up the internal voltage reference for the ADP1046. Connect a 10 kΩ, ±0.1% resistor from RES to AGND. This signal is referenced to AGND. Inverting Remote Voltage Sense Input. There should be a low ohmic connection to AGND. The resistor divider on this input must have a tolerance specification of 0.5% or better to allow for trimming. Connect a 0.1 μF capacitor from VS3− to AGND. Noninverting Remote Voltage Sense Input. This signal is referenced to VS3−, and the nominal input voltage at this pin is 1 V. The resistor divider on this input must have a tolerance specification of 0.5% or better to allow for trimming. This pin is the input to the high frequency Δ-Σ ADC. Exposed Pad. The ADP1046 has an exposed thermal pad on the underside of the package. For increased reliability of the solder joints and maximum thermal capability, it is recommended that the pad be soldered to the PCB AGND plane. Rev. 0 | Page 12 of 96 Data Sheet ADP1046 TYPICAL PERFORMANCE CHARACTERISTICS 2.5 2.5 1.5 1.5 1.0 MAX 0.5 0 –0.5 MIN –1.0 MEAN –1.5 1.0 0.5 MAX 0 –0.5 MIN –1.0 MIN SPEC MIN SPEC –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) Figure 5. VS1 ADC Accuracy vs. Temperature (from 10% to 90% of FSR) –2.5 –60 –40 –20 0 2.5 1.5 CS2 ADC ACCURACY (%FSR) 1.5 0 MIN –1.0 MEAN –1.5 100 120 140 1.0 MAX 0.5 0 –0.5 MIN MEAN –1.0 –1.5 MIN SPEC –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) –2.5 –60 Figure 6. VS2 ADC Accuracy vs. Temperature (from 10% to 90% of FSR) MIN SPEC –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 10045-404 –2.5 –60 80 –2.0 –2.0 10045-401 VS2 ADC ACCURACY (%FSR) 2.0 –0.5 60 MAX SPEC MAX SPEC 0.5 40 Figure 8. CS1 ADC Accuracy vs. Temperature (from 10% to 90% of FSR) 2.0 MAX 20 TEMPERATURE (°C) 2.5 1.0 MEAN –1.5 –2.0 –2.0 –2.5 –60 MAX SPEC 10045-403 CS1 ADC ACCURACY (%FSR) 2.0 10045-400 VS1 ADC ACCURACY (%FSR) MAX SPEC 2.0 Figure 9. CS2 ADC Accuracy vs. Temperature (from 10% to 90% of FSR) 1.24 2.5 MAX SPEC CS1 FAST OCP THRESHOLD (V) 1.5 1.0 MAX 0.5 0 –0.5 MIN –1.0 MEAN –1.5 1.22 MAX 1.21 1.20 MEAN 1.19 1.18 MIN 1.17 –2.0 MIN SPEC MIN SPEC –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 140 Figure 7. VS3 ADC Accuracy vs. Temperature (from 10% to 90% of FSR) Rev. 0 | Page 13 of 96 1.16 –60 –40 –20 0 20 40 60 80 100 120 TEMPERATURE (°C) Figure 10. CS1 Fast OCP Threshold vs. Temperature 140 10045-405 –2.5 –60 MAX SPEC 1.23 10045-402 VS3 ADC ACCURACY (%FSR) 2.0 ADP1046 Data Sheet 4 2.5 2.0 3 RTD ADC ACCURACY (%FSR) 1.5 1.0 MAX 0.5 0 –0.5 MIN –1.0 MEAN –1.5 MAX 1 0 –1 MEAN MIN –2 MIN SPEC –40 –20 0 20 40 MIN SPEC 60 TEMPERATURE (°C) 80 100 120 140 –4 –60 Figure 11. ACSNS ADC Accuracy vs. Temperature (from 10% to 90% of FSR) –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 140 10045-408 –2.5 –60 2 –3 –2.0 10045-406 ACSNS ADC ACCURACY (%FSR) MAX SPEC MAX SPEC Figure 12. RTD ADC Accuracy vs. Temperature (from 10% to 90% of FSR) Rev. 0 | Page 14 of 96 Data Sheet ADP1046 THEORY OF OPERATION When using low-side current sensing, the current sources are 200 μA; therefore, the required resistor value is 1 V/200 μA = 5 kΩ. When using high-side current sensing, the current sources are 2 mA; therefore, the resistor value required is (VOUT − 1 V)/2 mA. In the case of VOUT = 12 V, the required resistor value is 5.5 kΩ. CURRENT SENSE The ADP1046 has two current sense inputs: CS1 and CS2±. These inputs sense, protect, and control the primary input current, secondary output current, and the share bus information. They can be calibrated to reduce errors due to external components. CS1 Operation (CS1) CS1 is typically used for the monitoring and protection of the primary side current, which is commonly sensed using a current transformer (CT). The input signal at the CS1 pin is fed into an ADC for current monitoring. The range of the ADC is 0 V to 1.4 V. The input signal is also fed into a comparator for pulse-by-pulse OCP protection. The typical configuration for the CS1 current sense is shown in Figure 13. VIN OUTC When not in use, the CS2+ and CS2− inputs should both be connected directly to PGND, and CS2± should be set to highside current sense mode (Register 0x27[2] = 1). The CS2 ADC is used to measure the CS2 current; the reading is averaged every 2.62 ms in an asynchronous fashion. This averaged reading is used to make fault decisions, such as the CS2 OCP fault. The ADP1046 also writes the 12-bit CS2 reading every 10 ms to Register 0x18. I OUTB 12V OUTD 1V I = 10A 1kΩ 10Ω CS1 ADC 5.5kΩ 5.5kΩ CS2+ CS2– 12 BITS I = 100mA VREF FAST OCP ADC 1V 10045-010 1:100 2mA 12 BITS 2mA 10045-011 OUTA Typical configurations are shown in Figure 14 and Figure 15. Various thresholds and limits can be set for CS2±, such as OCP. These thresholds and limits are described in the Current Sense and Current Limit Registers section. Figure 13. Current Sense 1 (CS1) Operation The CS1 ADC is used to measure the average value of the primary current; the reading is averaged every 2.62 ms in an asynchronous fashion to make fault decisions. The ADP1046 also writes the 12-bit CS1 reading every 10 ms to Register 0x13. The fast OCP comparator is used to limit the instantaneous primary current within each switching cycle and has a nominal threshold of 1.2 V. Various thresholds and limits can be set for CS1, as described in the Current Sense and Current Limit Registers section. Figure 14. High-Side Resistive Current Sense I 5kΩ 5kΩ CS2– CS2+ ADC 1V 12 BITS CS2+ and CS2− are differential inputs used for the monitoring and protection of the secondary side current. The full-scale range of the CS2 ADC is programmable to 60 mV or 120 mV. The differential inputs are fed into an ADC through a pair of external resistors that provide the necessary level shifting. The device pins, CS2+ and CS2−, are internally regulated to approximately 1 V by internal current sources. Rev. 0 | Page 15 of 96 200µA 200µA 10045-012 CS2 Operation (CS2+, CS2−) Figure 15. Low-Side Resistive Current Sense (Recommended) ADP1046 Data Sheet For voltage monitoring, the VS1, VS2, and VS3 voltage value registers (Register 0x15, Register 0x16, and Register 0x17, respectively) are updated every 10 ms. The ADP1046 stores every ADC sample for 10 ms and then outputs the average value at the end of the 10 ms period. Therefore, if these registers are read at least every 10 ms, a true average value is read. FREQUENCY The low frequency ADC runs at approximately 1.56 MHz. For a specified bandwidth, the equivalent resolution can be calculated as follows: ln(1.56 MHz/BW)/ln2 = N bits For example, at a bandwidth of 95 Hz, the equivalent resolution/noise is ln(1.5 MHz/95)/ln2 = 14 bits At a bandwidth of 1.5 kHz, the equivalent resolution/noise is The control loop of the ADP1046 features a patented multipath architecture. The output voltage is converted simultaneously by two ADCs: a high accuracy ADC and a high speed ADC. The complete signal is reconstructed and processed in the digital filter to provide a high performance, cost competitive solution. 12V ln(1.56 MHz/1.5 kHz)/ln2 = 10 bits The high frequency ADC has a clock of 25 MHz. It is comb filtered and outputs at the switching frequency (fSW) into the digital filter. The equivalent resolution at some sample frequencies is listed in Table 5. 12V Table 5. Equivalent Resolutions for High Frequency ADC at Various Switching Frequencies LOAD 11kΩ 1V 11kΩ VS1 PGND fSW (kHz) 48.8 97.7 195.3 390.6 1V 1kΩ 1kΩ VS2 11kΩ VS3+ VS3– VS1 ADC VS2 ADC VS3 ADC 12 BITS 12 BITS 12 BITS Σ-∆ ADC NOISE Figure 17. Noise Performance for Nyquist Rate and Σ-Δ ADCs The ADP1046 uses two separate sensing points: VS1 and VS3±, depending on the condition of the OrFET. When the OrFET is turned off, the control loop is regulated via VS1; when the OrFET is turned on, the control loop is regulated via the differential sensing on VS3±. This sensing mechanism effectively performs a local and remote voltage sense. 12V NYQUIST ADC NOISE 10045-014 Multiple voltage sense inputs on the ADP1046 are used for the monitoring, control, and protection of the power supply output. This information is available through the I2C interface. All voltage sense points can be calibrated digitally to minimize errors due to external components. This calibration can be performed in the production environment, and the settings can be stored in the EEPROM of the ADP1046 (see the Power Supply Calibration and Trim section for more information). Σ-Δ ADCs also differ from Nyquist rate ADCs in that the quantization noise is not uniform across the frequency spectrum. At lower frequencies, the noise is lower, and at higher frequencies, the noise is higher (see Figure 17). MAGNITUDE VOLTAGE SENSE AND CONTROL LOOP 1V 1kΩ High Frequency ADC Resolution 9 bits 8 bits 7 bits 6 bits The HF ADC has a range of ±30 mV. Using a base switching frequency (fSW) of 100 kHz (8-bit HF ADC resolution), when fSW increases to 200 kHz (7-bit HF ADC resolution), the quantization noise is 0.9375 mV (1 LSB). Increasing fSW to 400 kHz increases the quantization noise to 3.75 mV (1 LSB = 2 × 30 mV/26 = 0.9375 mV). HF VS3 ADC 10045-013 DIGITAL FILTER Figure 16. Voltage Sense Configuration ADCs Two kinds of Σ-Δ ADCs are used in the feedback loop of the ADP1046: a low frequency (LF) ADC that runs at 1.56 MHz and a high frequency (HF) ADC that runs at 25 MHz. Σ-Δ ADCs have a resolution of one bit and operate differently from traditional flash ADCs. The equivalent resolution obtainable depends on how long the output bit stream of the Σ-Δ is sampled. VS1 OPERATION (VS1) VS1 is used for the monitoring and protection of the power supply voltage at the output of the LC stage, upstream of the OrFET. The VS1 sense point on the power rail needs an external resistor divider to bring the nominal input voltage to 1 V at the VS1 pin (see Figure 16). The resistor divider is necessary because the VS1 ADC input range is 0 V to 1.6 V (12-bit reading). This divideddown signal is internally fed into a low speed Σ-Δ ADC. The output of the VS1 ADC goes to the digital filter and is also updated in Register 0x15 every 10 ms. The VS1 signal is referenced to PGND. When the OrFET is turned off, the power supply is regulated from the VS1 sense point instead of the VS3± sense point. Rev. 0 | Page 16 of 96 Data Sheet ADP1046 The feedforward scheme modifies the modulation value based on the ACSNS voltage. When the ACSNS input is 1 V, the line feedforward has no effect. For example, if the digital filter output remains unchanged and the ACSNS voltage changes to 50% of its original value (still higher than 0.5 V), the modulation of the falling edge of OUTx doubles and vice versa (see Figure 19). The voltage line feedforward function is optional and is programmable using Register 0x75. VS2 OPERATION (VS2) VS2 is used in conjunction with VS1 to control the OrFET gate drive turn-on. The VS2 sense point on the power rail needs an external resistor divider to bring the nominal common-mode signal to 1 V at the VS2 pin (see Figure 16). The resistor divider is necessary because the VS2 ADC input range is 0 V to 1.6 V. This divided-down signal is internally fed into the VS2 ADC. The output of the VS2 ADC goes to the VS2 voltage value register (Register 0x16). The VS2 signal is never used for the control loop but is used to control the turn-on and turn-off of the OrFET (see the OrFET Control (GATE) section) as well as the voltage continuity flag. If the OrFET function of the ADP1046 is not used, it is recommended that the VS2 input be connected directly to PGND. The VS2 value is updated in Register 0x16 every 10 ms. ACSNS DIGITAL FILTER OUTPUT tMODULATION VS3± is used for the monitoring and protection of the remote load voltage. VS3± is a fully differential input that is the main feedback sense point for the power supply control loop. The VS3± sense point on the power rail needs an external resistor divider to bring the nominal common-mode signal to 1 V at the VS3± pins (see Figure 16). The resistor divider is necessary because the VS3 ADC input range is 0 V to 1.6 V. This divideddown signal is internally fed into a high frequency (HF) ADC. The output of the VS3 ADC goes to the digital filter and is also updated in Register 0x17 every 10 ms. The HF ADC is also the high frequency feedback loop for the power supply. tS The ACSNS level comparator is also connected on the same pin and flags an ACSNS fault when the voltage on the pin is below 0.45 V within each switching period. The ACSNS level comparator is used to detect whether the node is switching. DIGITAL FILTER The loop response of the power supply can be changed using the internal programmable digital filter. A Type 3 filter architecture has been implemented. To tailor the loop response to the specific application, the low frequency gain, zero location, pole location, and high frequency gain can all be set individually (see the Digital Filter Programming Registers section). It is recommended that the Analog Devices, Inc., software GUI be used to program the filter. The software GUI displays the filter response in Bode plot format and can be used to calculate all stability criteria for the power supply. The ADP1046 supports voltage line feedforward control to improve line transient performance. The ACSNS value is used to divide the output of the digital filter, and the result is fed into the PWM engine. The input voltage signal can be sensed at the secondary winding of the isolation transformer and must be filtered by an RCD network to eliminate the voltage spike at the switch node (see Figure 18). FROM SECONDARY WINDING R From the sensed voltage to the duty cycle, the transfer function of the filter in z-domain is as follows: PROGRAMMABLE ACTION (REG 0x0D[3:0]) d z H(z) 202.24 m z 1 ACSNS GAIN TRIM (REG 0x5E) ACSNS ADC 0V TO 1.6V R1 Vx R2 ACSNS FEEDFORWARD ADC 1/x FEEDFORWARD GAIN (REG 0x75[1:0]) 10045-015 0.6V TO 1.6V DIGITAL FILTER tS Figure 19. Feedforward Control on Modulation VOLTAGE LINE FEEDFORWARD AND ACSNS 0.45V tMODULATION OUTx DPWM ENGINE Figure 18. Feedforward Configuration The ACSNS voltage must be set to 1 V when the nominal input voltage is applied. The ACSNS ADC sampling period is 10 μs; therefore, the decision to modify the PWM outputs based on input voltage is performed at this rate. c z b 7.68 z a where: a = filter_pole_register_value/256. b = filter_zero_register_value/256. c = high_frequency_gain_register_value. d = low_frequency_gain_register_value. m = 1 when 48.8 kHz ≤ fSW < 97.7 kHz. m = 2 when 97.7 kHz ≤ fSW < 195.3 kHz. m = 4 when 195.3 kHz ≤ fSW < 390.6 kHz. m = 8 when 390.6 kHz ≤ fSW. where fSW is the switching frequency. Rev. 0 | Page 17 of 96 10045-016 VS3 OPERATION (VS3+, VS3−) ADP1046 Data Sheet To transfer the z-domain value to the s-domain, plug the following bilinear transformation equation into the H(z) equation: 2 f SW s 2 f SW s The digital filter introduces an extra phase delay element into the control loop. The digital filter circuit sends the duty cycle information to the PWM circuit at the beginning of each switching cycle (unlike an analog controller, which makes decisions on the duty cycle information continuously). Therefore, the extra phase delay for phase margin, Φ, introduced by the filter block is Φ = 360 × (fC/fSW) where: fC is the crossover frequency. fSW is the switching frequency. The PWM and SR outputs are used for control of the primary side drivers and the synchronous rectifier drivers. These outputs can be used for several control topologies such as full-bridge, phase-shifted ZVS configurations and interleaved, two switch forward converter configurations. Delays between rising and falling edges can be individually programmed. Special care must be taken to avoid shootthrough and cross-conduction. It is recommended that the Analog Devices software GUI be used to program these outputs. Figure 20 shows an example configuration to drive a full-bridge, phase-shifted topology with synchronous rectification. VIN At one-tenth the switching frequency, the phase delay is 36°. The GUI incorporates this phase delay into its calculations. Note that the GUI does not account for other delays such as gate driver and propagation delays. OUTA OUTC OUTB OUTD SR1 Two sets of registers allow for two distinct filter responses. The main filter, called the normal mode filter, is controlled by programming Register 0x60 to Register 0x63. The light load mode filter is controlled by programming Register 0x64 to Register 0x67. The ADP1046 uses the light load mode filter only when the output current measured on CS2± is below the load current threshold (programmed using Register 0x3B[2:0]). The Analog Devices software GUI allows the user to program the light load mode filter in the same manner as the normal mode filter. It is recommended that the GUI be used for this purpose. In addition, during the soft start process, a soft start filter can be used in combination with the normal mode filter and the light load mode filter. The soft start filter is programmed using Register 0x71 to Register 0x74. For more information, see the Soft Start section. Filter Transitions To avoid output voltage glitches and provide a seamless transition from one filter to another, the ADP1046 supports programmable filter transitions. This feature allows a gradual transition from one filter to another. Filter transitions are programmed using Register 0x7A[2:0]. SR2 DRIVER SR1 DRIVER ISOLATOR SR2 OUTA OUTB OUTC OUTD Figure 20. PWM Pin Assignment for Full-Bridge, Phase-Shifted Topology with Synchronous Rectification The PWM and SR outputs are all synchronized with each other. Therefore, when reprogramming more than one of these outputs, it is important to first update all the registers and then latch the information into the ADP1046 at the same time. During reprogramming, the outputs are temporarily disabled. A special instruction is sent to the ADP1046 to ensure that new timing information is programmed simultaneously. This is done by setting Bit 1 in Register 0x7F. It is recommended that PWM outputs be disabled when not in use. OUTAUX is an additional PWM output pin. OUTAUX allows an extra PWM signal to be generated at a different frequency from the other six PWM outputs. This signal can be used to drive an extra power converter stage, such as a buck controller located in front of a full-bridge converter. OUTAUX can also be used as a clock reference signal. For more information about the various programmable switching frequencies and PWM timings, see the PWM and Synchronous Rectifier Timing Registers section (Register 0x3F to Register 0x5C). Rev. 0 | Page 18 of 96 10045-117 z(s) PWM AND SYNC RECT OUTPUTS (OUTA, OUTB, OUTC, OUTD, OUTAUX, SR1, SR2) Data Sheet ADP1046 SR1 and SR2 are recommended for use as the PWM control signals when using synchronous rectification. These PWM signals can be configured much like the other PWM outputs. An optional soft start can be applied to the synchronous rectifier PWM outputs. The SR soft start can be programmed using Register 0x54[1:0]. When SR soft start is disabled (Register 0x54[0] = 0), the SR signals are turned on to their full PWM duty cycle values immediately. When SR soft start is enabled (Register 0x54[0] = 1), the SR signals ramp up from zero duty cycle to the desired duty cycle in steps of 40 ns per switching cycle. The advantage of ramping the SR signals is to minimize the output voltage step that occurs when the SR FETs are turned on without a soft start. The advantage of turning the SR signals completely on immediately is that they can help to minimize the voltage transient caused by a load step. Using Register 0x54[1], the SR soft start can be programmed to occur only once (the first time that the SR signals are enabled) or every time that the SR signals are enabled, for example, when the system enters or exits light load mode. When programming the ADP1046 to use SR soft start, ensure correct operation of this function by setting the falling edge of SR1 (t10) to a lower value than the rising edge of SR1 (t9) and by setting the falling edge of SR2 (t12) to a lower value than the rising edge of SR2 (t11). SR soft start can also be disabled by setting Register 0x0F[7] = 1. SR (SYNCHRONOUS RECTIFIER) DELAY The ADP1046 is well suited for dc-to-dc converters in isolated topologies. Every time a PWM signal crosses the isolation barrier an additional propagation delay is added due to the isolating components. The ADP1046 allows programming of an adjustable delay (0 ns to 315 ns in steps of 5 ns) using Register 0x79[5:0]. This delay moves both SR1 and SR2 later in time to compensate for the added delay due to the isolating components (see Figure 56). In this way, the edges of all PWM outputs can be aligned, and the SR delay can be applied separately as a constant dead time. ADAPTIVE DEAD TIME CONTROL A set of registers called the adaptive dead time (ADT) registers (Register 0x68 to Register 0x70) allows the dead time between PWM edges to be adapted on the fly. The ADP1046 uses the ADT only when the modulation is below the dead time (primary current) threshold programmed in Register 0x68. The Analog Devices software GUI allows the user to easily program the dead time values, and it is recommended that the GUI be used for this purpose. This offset can be positive or negative and is relative to the nominal edge position. When the CS1 current is between zero and the current threshold, the amount of dead time is linearly adjusted in steps of 5 ns. The averaging period of the CS1 current and the speed of the dead time adjustment can also be programmed in Register 0x70 to accommodate faster or slower adjustment. For example, if the CS1 threshold is set to 2 A, t1 has a nominal rising edge of 100 ns. If the ADT setting for t1 is 40 ns at no load, t1 moves to 140 ns when the current is 0 A and to 120 ns when the current is 1 A. Similarly, ADT can be applied in the negative direction. LIGHT LOAD MODE The ADP1046 can be configured to disable PWM outputs under light load conditions based on the value of CS2. Register 0x3B and Register 0x7D are used to program the light load mode thresholds for turn-off and turn-on of SR1, SR2, and other PWM outputs. Below the light load threshold programmed in Register 0x3B, the SR outputs are disabled; the user can also program any of the other PWM outputs to shut down below this threshold. Light load mode allows the ADP1046 to be used with interleaved topologies that incorporate automatic phase shedding at light load. To prevent the system from oscillating between light load and normal modes due to the thresholds being programmed too close to each other, a programmable debounce is provided in Register 0x7D[5:4]. This debounce prevents the part from changing state within the programmed interval. The speed of the SR enable is programmable from 37.5 μs to 300 μs in four discrete steps using Register 0x7D[3:2]. This ensures that, in case of a load step, the SR signals (and any other PWM outputs that are temporarily disabled) can be turned on quickly enough to prevent damage to the FETs that they are controlling. The light load mode digital filter is also used during light load mode. MODULATION LIMIT The modulation limit register (Register 0x2E) can be programmed to apply a maximum duty cycle modulation limit to any PWM signal, thus limiting the modulation range of any PWM output. When modulation is enabled, the maximum modulation limit is applied to all PWM outputs collectively. As shown in Figure 21, this limit is the maximum time variation for the modulated edges from the default timing, following the configured modulation direction. There is no minimum duty cycle limit setting. Therefore, the user must set the rising edges and falling edges based on the case with the least modulation. tMODULATION_LIMIT OUTx Before ADT is configured, the primary current threshold must be programmed. Each individual PWM rising and falling edge (t1 to t14) can then be programmed to have a specific dead time offset at no load (zero current). Rev. 0 | Page 19 of 96 tRX 10045-118 SYNCHRONOUS RECTIFICATION tFX Figure 21. Modulation Limit Settings ADP1046 Data Sheet Fault Condition During Soft Start Each LSB in Register 0x2E corresponds to a different time step size, depending on the switching frequency (see Table 46). The modulated edges cannot extend beyond one switching cycle. 10045-119 The GUI provided with the ADP1046 is recommended for programming this feature (see Figure 22). Figure 22. Setting Modulation Limits (Modulation Range Shown by Arrows) The turning on and off of the ADP1046 is controlled by the hardware PSON pin and/or the software PSON register, depending on the configured settings in Register 0x2C. When the user turns on the power supply (enables PSON), the following soft start procedure occurs (see Figure 23). 2. 3. 4. 5. 6. 7. 8. Digital Compensation Filters During Soft Start The ADP1046 has a dedicated soft start filter (SSF) that can be used to fine-tune and optimize the dynamic response during the output voltage ramp-up. SOFT START 1. If a fault condition occurs during soft start, the controller responds as programmed unless the flag is blanked. Flag blanking during soft start is programmed in Register 0x0F. The UVP and ACSNS flags are always blanked during soft start. The OTP, FLAGIN, OVP, and OCP fault flags can be blanked during soft start by setting the appropriate bits in Register 0x0F. The PSON signal is enabled at Time t0. If the part is programmed to be always on (Register 0x2C[7:6] = 00), PSON is enabled as soon as VCORE is above UVLO. The ADP1046 waits for the programmed PS_ON delay (set in Register 0x2C[4:3]). The soft start begins to ramp up the internal digital reference. The total duration of the soft start ramp is programmable from 5 ms to 100 ms using Register 0x5F[7:5]. If the soft start from precharge function is enabled (Register 0x5F[4] = 1), the soft start ramp starts from the value of the output voltage sensed on VS1 or VS3± (depending on the OrFET status), and the soft start ramp time is reduced proportionally. If the soft start from precharge function is disabled, the soft start ramp time is the programmed value in Register 0x5F[7:5]. When the power supply voltage exceeds the VS1 undervoltage protection (UVP) limit (set in Register 0x34[6:0]), the UVP flag is reset. The OrFET is turned on as soon as the OrFET enable threshold is met. (The OrFET enable threshold is programmed in Register 0x30[6:5].) The regulation point is switched from VS1 to VS3±. If no other fault conditions are present, the PGOODx signals wait for the programmed debounce time (set in Register 0x2D[7:4]) and are then enabled. The soft start flag must be unmasked in Register 0x7B and Register 0x7C (Bit 7 must be set to 0). If no OrFET is used, the power supply must be configured to regulate using VS3 at all times (Register 0x33[2] = 1). VS2 can be used as a secondary OVP mechanism. Before it ramps up the internal reference after the PSON signal is enabled, the ADP1046 evaluates whether the OrFET should be turned on or off by looking at the difference between VS1 and VS2. This step is done to determine whether the regulation point should be VS1 or VS3± (see Figure 23). • • If the regulation point is VS1, the soft start filter is used by default during the ramp-up. At the end of the soft start ramp, the part switches to the normal mode filter (NMF). If the regulation point is VS3±, the part starts the ramp using the normal mode filter (NMF). In both cases, after the voltage reaches 12.5% of the nominal output voltage value, the load current is evaluated. • • If the load current is below the light load mode threshold, the part switches to the light load mode filter (LLF). If the load current is above the light load mode threshold, the normal mode filter is used until the end of the soft start ramp, even if the system subsequently enters light load mode based on a change to the load current. Register 0x2C can be programmed to configure the use of the different filters during soft start as follows: • • Rev. 0 | Page 20 of 96 Force soft start filter (Bit 0). This option forces the part to use the soft start filter even when the regulation point is VS3. In some cases, this option allows better fine-tuning of the ramp-up voltage. This option can also be selected when an OrFET is not used. Disable light load mode during soft start (Bit 1). This option prevents the use of the light load mode filter during soft start, even if the light load condition is met. The light load mode filter is available for use after the end of the soft start ramp. Data Sheet ADP1046 t0 PS_ON DELAY (REG 0x2C[4:3]) RAMP TIME (REG 0x5F[7:5]) PGOOD DEBOUNCE (REG 0x2D) PSON VS3 UVP VS1 (VS1 – VS2) VOLTAGE OrFET ENABLE OrFET GATE LOOP CONTROLLED FROM VS1 LOOP CONTROLLED FROM VS3 UVP FLAG 10045-120 PGOOD1 Figure 23. Soft Start Timing Diagram RAMP TIME (REG 0x5F[7:5]) PSON 12.5% REF VOUT LIGHT LOAD FILTER (LLF) NORMAL MODE FILTER (NMF) OR SOFT START FILTER (SSF) LLF OR NMF BASED ON LOAD NORMAL MODE FILTER (NMF) OR SOFT START FILTER (SSF) LLF OR NMF BASED ON LOAD 10045-121 NORMAL MODE FILTER (NMF) OR SOFT START FILTER (SSF) Figure 24. Filter Sequencing at Startup Rev. 0 | Page 21 of 96 ADP1046 Data Sheet • ORFET CONTROL (GATE) The GATE control signal drives an external OrFET. The OrFET is used in redundant systems to protect against power flow into the power supply from another supply’s output terminals. This ensures that power flows only out of the power supply and that the unit can be hot-swapped. • The GATE pin is a totem-pole output and does not require a pull-up resistor. The GATE pin polarity can be programmed via Register 0x2D[1] to be active high or active low. The GATE output is CMOS level (0 V to 3.3 V). An external driver is required to turn the OrFET on or off. OrFET programmable comparator. If the reverse voltage present on CS2± exceeds the analog comparator threshold programmed in Register 0x30[4:2], the OrFET is turned off. This comparator can be disabled using Register 0x30[0]. GATE signal disable. When Register 0x5D[0] = 1, the GATE signal is disabled and has no effect on the VSx feedback point. OrFET GATE Control and Regulation Points The GATE signal is enabled when the threshold configured in Register 0x30[6:5]) is met. The GATE signal controls a very important function of output voltage regulation: the control loop sensing point. OrFET Turn-On • The turn-on process for the OrFET is controlled by the voltage difference between VS1 and VS2. For this reason, the VS1 and VS2 readings must be correctly calibrated for the OrFET function to perform properly. • When the GATE signal is disabled, the OrFET is turned off and the voltage regulation sensing point is VS1. When the GATE signal is enabled, the OrFET is turned on and the voltage regulation sensing point is VS3±. The OrFET turn-on circuit detects the voltage difference between VS1 and VS2 (see Figure 25). When the forward voltage drop from VS1 to VS2 is greater than the programmable OrFET enable threshold set in Register 0x30[6:5], the OrFET is enabled. The OrFET enable threshold can be set to 0%, −0.5%, −1%, or −2% of the nominal output voltage. • OrFET Turn-Off In light load mode, follow this procedure: The OrFET can be turned off by three methods: • In normal operating mode, follow this procedure: • Fault flag. Any flag in a fault configuration register (Register 0x08 to Register 0x0D) can be programmed with an action to turn off the OrFET. The OrFET is kept off for as long as the flag is set. • When 12 V < VOUT < OVP, use the fast OrFET control circuit to turn off the OrFET. When VOUT > OVP, use load OVP to turn off the OrFET. When 12 V < VOUT < OVP, use ACSNS to turn off the OrFET. When VOUT > OVP, use load OVP to turn off the OrFET. In a 12 V application, when an internal short circuit occurs, use CS1 OCP or VS1 UVP to shut down the unit and restart it. 12V VOUT RSENSE DRIVER 11kΩ 1kΩ 1kΩ CS2– CS2+ 11kΩ VS1 VS2 GATE DEBOUNCE OrFET ENABLE THRESHOLD FAST OrFET FAST OrFET FAST OrFET COMPARATOR DEBOUNCE BYPASS OrFET S ENABLE R Q GATE DISABLE OrFET DISABLE FAST OrFET THRESHOLD FLAGS Figure 25. OrFET Control Circuit Internal Detailed Diagram Rev. 0 | Page 22 of 96 10045-122 • Recommended Setup for a 12 V Application Data Sheet ADP1046 Short Circuit OrFET Operation Examples Hot Plug into a Live Bus A new PSU is plugged into a live 12 V bus (yellow). The internal voltage, VS1 (red), is ramped up before the OrFET is turned on. After the OrFET is turned on (green), current in the new PSU begins to flow to the load (blue). The turn-on voltage threshold between the new PSU and the bus is programmable. VS3 VS1 When one of the output rectifiers fails, the bus voltage can collapse if the OrFET is not promptly turned off. The fast OrFET comparator is used to protect the system from this fault event. Figure 28 shows a short circuit applied to the output capacitors before the OrFET. After the fast OrFET threshold for CS2± (blue) is triggered, the OrFET (green) is turned off. Figure 28 also shows the operation when the short circuit is removed. The internal regulation point, VS1 (red), returns to 12 V, and the OrFET (green) is reenabled. The PSU again begins to contribute current to the load (blue). VS3 OrFET 4 OrFET 4 CS2 3 CS2 3 CH1 2.00V CH2 2.00V CH3 2.00A CH4 10.0V M10.0ms A CH4 100mV 10045-017 2 VS1 Runaway Master CH1 2.00V CH2 2.00V CH3 2.00A CH4 10.0V A rogue PSU on the bus (yellow) has a fault condition, causing the bus voltage to increase above the OVP threshold. The good PSU turns off the OrFET (green) and regulates its internal voltage, VS1 (red). When the rogue power supply fault condition is removed, the bus voltage decreases. The OrFET of the good PSU is immediately turned on, and the good PSU resumes regulating from VS3±. VS3 VS1 M200.0ms A CH4 7.5mV 10045-019 Figure 26. Hot Plug into a Live Bus (Yellow Is Bus Voltage; Red Is VS1 Voltage; Green Is OrFET Control Signal; Blue Is Load Current) Figure 28. Internal Short Circuit (Yellow Is Bus Voltage; Red Is VS1 Voltage; Green Is OrFET Control Signal; Blue Is Load Current) Light Load Mode Operation PSU 1 increases its voltage at light load from 12 V to 12.1 V (yellow). Both PSU 1 and PSU 2 are CCM; therefore PSU 1 sources current and PSU 2 sinks current (blue). In PSU 2, the OrFET control turns off the OrFET to prevent reverse current from flowing. Note that the OrFET voltage (green) is solid during this transition because PSU 1 and PSU 2 are in CCM mode. VS3 VS1 4 OrFET 4 OrFET CS2 3 A CH4 0mV 3 CS2 Figure 27. Runaway Master (Yellow Is Bus Voltage; Red Is VS1 Voltage; Green Is OrFET Control Signal; Blue Is Load Current) CH1 2.00V CH2 2.00V CH3 2.00A CH4 10.0V M5.0ms A CH4 8.3mV 10045-020 M50.0ms 10045-018 CH1 2.00V CH2 2.00V CH3 2.00A CH4 10.0V Figure 29. Light Load Mode (Yellow Is Bus Voltage; Red Is VS1 Voltage; Green Is OrFET Control Signal; Blue Is Load Current) Rev. 0 | Page 23 of 96 ADP1046 Data Sheet VDD POWER GOOD When VDD is applied, a certain time elapses before the part is capable of regulating the power supply. When VDD rises above the power-on reset and UVLO levels, it takes approximately 20 μs for VCORE to reach its operational point of 2.5 V. The EEPROM contents are then downloaded to the registers. The download takes an additional 25 μs (approximately). After the EEPROM download, the ADP1046 is ready for operation. The ADP1046 has two open-drain power-good pins. The PGOOD1 pin is driven low when a PGOOD1 fault condition is present; the PGOOD2 pin is driven low when a PGOOD2 fault condition is present. The PGOOD1 and PGOOD2 pins and flags can be programmed to respond to the following flags: If the ADP1046 is programmed to power up at this time (PSON is enabled), the soft start ramp begins. Otherwise, the part waits for the PSON signal. The proper amount of decoupling capacitance must be placed between VDD and AGND, as close as possible to the device to minimize the trace length. It is recommended that the VCORE pin not be used as a reference or to generate other logic levels using resistive dividers. VDD/VCORE OVLO The ADP1046 has built-in overvoltage protection (OVP) on its supply rails. When the VDD or VCORE voltage rises above the OVLO threshold, the response can be programmed using Register 0x0E[7:5]. It is recommended that when a VDD/ VCORE OVP fault occurs, the response be set to download the EEPROM before restarting the part (set Register 0x0E[6] = 1). • • • • • • • • Soft start CS1 fast OCP CS1 accurate OCP CS2 accurate OCP UVP Local OVP (fast and accurate) Load OVP OrFET (GATE pin) The masking of these flags is programmed in Register 0x7B (for PGOOD1) and Register 0x7C (for PGOOD2). When a flag is masked, it does not set PGOOD1 or PGOOD2. The following additional flags can also set the PGOOD2 pin either unconditionally or based on the flag response, as programmed in Register 0x2D[3] (see Figure 30 and Table 45). • • • • • Voltage continuity OrFET disable ACSNS External flag (FLAGIN pin) OTP These additional flags can be programmed in Register 0x2D[3] to always set PGOOD2 or to set PGOOD2 only if the flag action is not set to “ignore” in the fault configuration register for that flag (see Table 12 and Table 13). -SOFT START -CS1 FAST OCP -CS1 ACCURATE OCP -CS2 ACCURATE OCP -UVP -LOCAL OVP (FAST AND ACCURATE) -LOAD OVP -OrFET (GATE PIN) ADDITIONAL FLAGS -VOLTAGE CONTINUITY -OrFET DISABLE -ACSNS -FLAGIN -OTP MASKED BY REG 0x7B DEBOUNCE (REG 0x2D[7:6]) PGOOD1 (FLAG AND PIN) MASKED BY REG 0x7C DEBOUNCE (REG 0x2D[5:4]) PGOOD2 (FLAG AND PIN) IF REG 0x2D[3] = 0, THE ADDITIONAL FLAGS ALWAYS AFFECT PGOOD2, REGARDLESS OF THE PROGRAMMED ACTION. IF REG 0x2D[3] = 1, THE ADDITIONAL FLAGS AFFECT PGOOD2 ONLY IF THEY ARE NOT SET TO BE IGNORED. Figure 30. PGOOD1, PGOOD2 Programming Rev. 0 | Page 24 of 96 10045-127 MAIN FLAGS Data Sheet ADP1046 During the next cycle, the slave increases its current output contribution by increasing its output voltage. This cycle continues until the slave outputs the same current as the master, within a programmable tolerance range. Figure 31 shows the configuration of the digital share bus. CURRENT SHARING (SHARE) The ADP1046 supports both analog current sharing and digital current sharing. The ADP1046 can use either the CS1 current information or the CS2 current information for current sharing (this setting is programmed in Register 0x29[3]). VDD Analog Current Sharing Analog current sharing uses the internal current sensing circuitry to provide a current reading to an external current error amplifier. Therefore, an additional differential current amplifier is not necessary. SHAREi CURRENT SENSE INFO The current reading from CS1 or CS2 can be output to the SHAREo pin in the form of a digital bit stream, which is the output of the current sense ADC (see Figure 32). The bit stream is proportional to the current delivered by this unit to the load. By filtering this digital bit stream using an external RC filter, the current information is turned into an analog voltage that is proportional to the current delivered by this unit to the load. This voltage can be compared to the share bus voltage. If the unit is not supplying enough current, an error signal can be applied to the VS3± feedback point. This signal causes the unit to increase its output voltage and, in turn, its current contribution to the load. SHAREo DIGITAL WORD POWER SUPPLY A SHARE BUS SHAREi SHAREo DIGITAL WORD 10045-023 CURRENT SENSE INFO POWER SUPPLY B Figure 31. Digital Current Share Configuration Digital Share Bus The digital share bus is based on a single-wire communication bus principle; that is, the clock and data signals are contained together. The digital share bus scheme is similar in principle to the traditional analog share bus scheme. The difference is that instead of using a voltage on the share bus to represent current, a digital word is used. When two or more ADP1046 devices are connected, they synchronize their share bus timing. This synchronization is performed by the start bit at the beginning of a communications frame. If a new ADP1046 is hot-swapped onto an existing digital share bus, the device waits to begin sharing until the next frame. The new ADP1046 monitors the share bus until it sees a stop bit, which designates the end of a share frame. It then performs synchronization with the other ADP1046 devices during the next start bit. The digital share bus frame is shown in Figure 33. The ADP1046 outputs a digital word onto the share bus. The digital word is a function of the current that the power supply is providing (the higher the current, the larger the digital word). The power supply with the highest current controls the bus (master). A power supply that is putting out less current (slave) sees that another supply is providing more power to the load than it is. CURRENT CS2– VOLTAGE CURRENT SENSE ADC BIT STREAM SHARE BUS SHAREo BIT STREAM LPF 10045-222 CS2+ Figure 32. Analog Current Share Configuration PREVIOUS FRAME START BIT 0 8-BIT DATA 2 STOP BITS (IDLE) FRAME Figure 33. Digital Current Share Frame Timing Diagram Rev. 0 | Page 25 of 96 START BIT 0 NEXT FRAME 10045-024 2 STOP BITS (IDLE) ADP1046 Data Sheet Figure 34 shows the possible signals on the share bus. Round 1 In Round 1, every supply first places its MSB on the bus. If a supply senses that its MSB is the same as the value on the bus, it continues to Round 2. If a supply senses that its MSB is less than the value on the bus, it means that this supply must be a slave. LOGIC 1 LOGIC 0 t0 10045-025 t1 NEXT BIT tBIT If two units have the same MSB, they both continue to Round 2 because either of them may be the master. Figure 34. Share Bus High, Low, and Idle Bits The length of a bit (tBIT) is fixed at 10 μs. A Logic 1 is defined as a high-to-low transition at the start of the bit and a low-to-high transition at 75% of tBIT. A Logic 0 is defined as a high-to-low transition at the start of the bit and a low-to-high transition at 25% of tBIT. Round 2 In Round 2, all supplies that are still communicating on the bus place their second MSB on the share bus. If a supply senses that its MSB is less than the value on the bus, it means that this supply must be a slave and it stops communicating on the share bus. The bus is idle when it is high during the whole period of tBIT. All other activity on the bus is illegal. Glitches up to tGLITCH (200 ns) are ignored. Round 3 to Round 8 The same algorithm is repeated for up to eight rounds to allow supplies to compare their digital words and, in this way, to determine whether each unit is the master or a slave. The digital word that represents the current information is eight bits long. The ADP1046 takes the eight MSBs of the CS1 or CS2 reading (the current share signal specified in Register 0x29[3]) and uses this reading as the digital word. When read, the share bus value at any given time is equal to the CS1 or CS2 current reading (see Figure 35). Digital Share Bus Configuration The digital share bus can be configured in various ways. The bandwidth of the share bus loop is programmable in Register 0x29[2:0]. The extent to which a slave tries to match the current of the master is programmable in Register 0x2A[3:0]. The primary side or the secondary side current can be used as the current share signal by programming Register 0x29[3]. Digital Share Bus Scheme Each power supply compares the digital word that it is outputting with the digital words of all the other supplies on the bus. PSU A VDD 0x4A SHAREi MASTER CS2+ IOUT = 35A 1mΩ CS2– + 35mV – CURRENT SENSE ADC 12 BITS 1195 DEC 0x4AB DIGITAL FILTER ÷16 8 BITS 74 DEC 0x4A SHARE BUS 8-BIT WORD 0xB5 SHAREo DIGITAL WORD 0x4A 8-BIT WORD 1 LSB = 29.3µV 35mV/29.3µV = 1195 Figure 35. How the Share Bus Generates the Digital Word to Place on the Digital Share Bus Rev. 0 | Page 26 of 96 10045-026 IDLE PREVIOUS BIT When a supply becomes a slave, it stops communicating on the share bus because it knows that it is not the master. The supply then increases its output voltage in an attempt to share more current. Data Sheet ADP1046 POWER SUPPLY SYSTEM AND FAULT MONITORING The ADP1046 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 values for current, voltage, power, and temperature. The limits for the fault conditions are programmable. The ADP1046 has an extensive set of flags that are set when certain programmed thresholds or limits are exceeded. These thresholds and limits are described in the Fault Registers section. FLAGS The ADP1046 has an extensive set of flags that are set when certain limits, conditions, and thresholds are exceeded. The real-time status of these flags can be read in Register 0x00 to Register 0x03. The response to these flags is individually programmable. Flags can be ignored or used to trigger actions such as turning off certain PWM outputs or the OrFET gate. Flags can also be used to turn off the power supply. The ADP1046 can be programmed to respond when these flags are reset. For more information, see the Fault Registers section. The ADP1046 also has a set of latched fault registers (Register 0x04 to Register 0x07). The latched fault registers have the same flags as Register 0x00 to Register 0x03, but the flags in the latched registers remain set so that intermittent faults can be detected. Reading a latched fault register resets all the flags in that register. MONITORING FUNCTIONS The ADP1046 monitors and reports several signals, including voltages, currents, power, and temperature. All these values are stored in separate registers and can be read through the I2C interface. For more information, see the Value Registers section. In a 12 V system, this equates to VOUT = (390.625 μV × 2560) × (11 kΩ + 1 kΩ)/1 kΩ CURRENT READINGS CS1 Pin CS1 has an input range of 1.4 V. The ADC performs a 12-bit reading conversion of this value, which means that the LSB size is 1.4 V/4096 = 341.8 μV. When there is exactly 1 V on the CS1 pin, the value in the CS1 value register (Register 0x13[15:4]) reads 2926. The equation to calculate the ADC code at a specified CS1 input voltage (Vx) is given by the following formula: ADC Code = Vx/1.4 × 4096 For example, when there is 1 V on the CS1 input pin, ADC Code = 1 V/1.4 × 4096 ADC Code = 2926 CS2+, CS2− Pins The full-scale (FS) range for the CS2 ADC can be set to 60 mV or 120 mV using Register 0x27[5]. The CS2 ADC has an input range of 120 mV. The resolution is 12 bits, which means that the LSB size is 120 mV/4096 = 29.30 μV. The user is limited to an input range of 110 mV. The equation to calculate the ADC code at a specified voltage (VX) is given by the following formula: ADC Code = Vx/(120 mV) × 4096 For example, when there is 50 mV on the input of the ADC, ADC Code = 50 mV/120 mV × 4096 VOLTAGE READINGS The VS1, VS2, and VS3 ADCs have an input range of 1.6 V. The outputs of the ADCs are 12-bit values, which means that the LSB size is 1.6 V/4096 = 390.625 μV. The user is limited to an input range of 1.4 V, which means that the ADC output code is limited to 1.4 V/390.6 μV = 3584. The equation to calculate the ADC code at a specified voltage (Vx) at the pin is given by the following formula: ADC Code = Vx/1.6 × 4096 ADC Code = 1707 Therefore, to convert the CS2 register value to a real current, use the following formula: IOUT = (CS2_ADC_CODE/4096) × (FS/RSENSE) where: CS2_ADC_CODE is the value in Register 0x18[15:4]. FS is the full-scale voltage drop (60 mV or 120 mV). RSENSE is the sense resistor value. For example, if CS2_ADC_CODE = 1520, RSENSE = 10 mΩ, and FS = 120 mV, the real current is calculated as follows: For example, when there is 1 V on the input of the ADC, ADC Code = 1 V/1.6 × 4096 IOUT = (1520/4096) × (120 mV/10 mΩ) ADC Code = 2560 In a 12 V application, the 12 V reading is divided down using a resistor divider network to provide 1 V at the sense pin. Therefore, to convert the register value to a real voltage, use the following formula: VOUT = (LSB × 2560) × ((R1 + R2)/R2) Rev. 0 | Page 27 of 96 IOUT = 4.453 A ADP1046 Data Sheet The output of the RTD ADC is linearly proportional to the voltage on the RTD pin. However, thermistors exhibit a nonlinear function of resistance vs. temperature. Therefore, the user must perform postprocessing on the RTD ADC reading to accurately read the temperature. POWER READINGS The output power value register (Register 0x19) is the product of the VS3 voltage value and the CS2 current value. Therefore, a combination of the formulas in the Voltage Readings section and the CS2+, CS2− Pins section is used to calculate the power reading in watts. This register is a 16-bit word. It multiplies two 12-bit numbers and discards the eight LSBs. By connecting an external resistor (REXT) in parallel with the NTC thermistor (TH), a constant current can be used to achieve linearization (see Figure 36). POUT = VOUT × IOUT For example, DAC POWER MONITORING ACCURACY RTD REXT The ADP1046 power monitoring accuracy is specified relative to the full-scale range of the signal that it is measuring. ADC TH Figure 36. Temperature Measurement Using Thermistor FIRST FLAG FAULT ID AND VALUE REGISTERS An internal, precision current source of 10 μA, 20 μA, 30 μA, or 40 μA can be selected in Register 0x11. This current source can be trimmed by means of an internal DAC to compensate for thermistor accuracy (see the RTD/OTP Trim section). The user can select the output current source using Bits[7:6] of Register 0x11. When the ADP1046 registers several fault conditions, it stores the value of the first fault in a dedicated register. For example, if the overtemperature (OTP) fault is registered followed by an OVP fault, the OTP flag is stored in the first flag ID register (Register 0x10). This register gives the user more information for fault diagnosis than a simple flag. The contents of this register are latched, meaning that they are stored until read by the user. The contents are also reset by toggling PSON. If a flag is set to be ignored, it does not appear in the first flag register. The ADP1046 implements a linearization scheme based on a preselected combination of external components and current selection for best performance when measuring linearized temperatures in degrees Celsius in the industrial range. EXTERNAL FLAG INPUT (FLAGIN PIN) For more information about the required thermistor and selecting and trimming the precision current sources, see the Temperature Linearization Scheme section. The FLAGIN pin can be used to send an external fault signal into the ADP1046. Register 0x0A[3:0] can be used to program the FLAGIN flag to trigger an action. Optionally, the user can process the RTD reading and perform postprocessing in the form of a lookup table or polynomial equation to match the specific NTC thermistor used. With the internal current source set to 46 μA, the equation to calculate the ADC code at a specified NTC thermistor value (Rx) is given by the following formula: TEMPERATURE READINGS (RTD PIN) The RTD pin is set up for use with an external negative temperature coefficient (NTC) thermistor. The RTD pin has an internal programmable current source. An ADC monitors the voltage on the RTD pin. ADC CODE = 46 μA × Rx/1.6 × 4096 The RTD temperature value register, Register 0x1A, is updated every 10 ms. The ADP1046 stores every ADC sample for 10 ms and then outputs the average value at the end of the 10 ms period. For example, at 60°C, the NTC thermistor at the RTD pin is 21.82 kΩ. The RTD ADC has an input range of 1.6 V and a resolution of 12 bits, which means that the LSB size is 1.6 V/4096 = 390.625 μV. The user is limited to an input range of 1.3 V, which means that the maximum ADC output code is limited to 1.3 V/390.6 μV = 3328. RTD_ADC_CODE = 46 μA × 21.82 kΩ/1.6 × 4096 = 2570 10µA/20µA/30µA/40µA 100kΩ NTC 16.5kΩ RTD ADC RTD TEMPERATURE VALUE REGISTER REG 0x1A[15:4] OTP FLAG SIGNAL CONDITIONING RTD TEMPERATURE VALUE IN °C REG 0x1B[7:0] FLAGS OTP THRESHOLD REG 0x2F[7:0] Figure 37. RTD Pin Internal Details Rev. 0 | Page 28 of 96 10045-027 RTD 10045-134 POUT = 12 V × 4.453 A = 53.436 W Data Sheet ADP1046 Temperature Linearization Scheme OVERCURRENT PROTECTION (OCP) The ADP1046 implements a linearization scheme based on a preselected combination of thermistor (100 kΩ, 1%), external resistor (16.5 kΩ, 1%), and the 46 μA current source for best performance when linearizing measured temperatures in the industrial range. The ADP1046 has several OCP functions. CS1 and CS2± have separate OCP circuits to provide both primary and secondary side protection. CS1 OCP CS1 has two protection circuits: CS1 fast OCP and CS1 accurate OCP (see Figure 38). The required NTC thermistor should have a resistance of 100 kΩ, 1%, such as the NCP15WF104F03RC (beta = 4250, 1%). It is recommended that 1% tolerance be used for both the resistor and beta values. CS1 Fast OCP CS1 fast OCP is an analog comparator. When the voltage at the CS1 pin exceeds the (fixed) 1.2 V threshold, the CS1 fast OCP flag is set. A programmable blanking time can be set to ignore the leading edge current spike at the beginning of the current signal (leading edge blanking). Reading the Linearized Temperature Reading Register 0x1B (updated every 10 ms) returns the current temperature according to an internal linearization scheme. See Table 1 for the specified accuracy of these measurements. The temperature reading result is represented in 8-bit decimal format in °C; therefore, the temperature range for this reading is from 0°C to 255°C. A debounce time can be programmed to improve the noise immunity of the OCP circuit. When the CS1 fast OCP comparator is set, the OUTA, OUTB, OUTC, and OUTD PWM outputs are immediately disabled for the remainder of the switching cycle. These outputs are reenabled at the start of the next switching cycle. This function cannot be bypassed. OVERTEMPERATURE PROTECTION (OTP) If the temperature sensed at the RTD pin exceeds the threshold programmed in Register 0x2F, the OTP flag is set. The response to the OTP flag is programmable using Register 0x0B[7:4]. CS1 Accurate OCP CS1 accurate OCP is used for more precise control of overcurrent protection. With CS1 accurate OCP, the reading at the output of the CS1 ADC (Register 0x13) is compared to a programmable OCP limit. The CS1 accurate OCP value can be programmed from 0 to 31 decimal using Register 0x22[4:0]. If the CS1 reading exceeds the CS1 accurate OCP limit, the CS1 accurate OCP flag is set. The CS1 ADC is asynchronously sampled, and the readings are averaged every 2.62 ms to make a fault decision. The flag response is programmed in Register 0x08. An RTD trim is required to make accurate temperature readings at the lower end of the RTD ADC range to account for tolerances in the NTC thermistor and the external resistor. This trim results in a more accurate measurement for determining the OTP threshold (see the RTD/OTP Trim section). VIN OUTC OUTB OUTD CS1 CS1 ADC ASYNCHRONOUS 2.62ms AVERAGING 12 CS1 ACCURATE OCP FLAG CS1 FAST OCP FLAG CS1 ACCURATE OCP SETTING REG 0x22[4:0] FLAGS SHUTDOWN OUTA OUTB CS1 FAST OCP BYPASS 1.2V FAST OCP COMPARATOR REG 0x27[4] CS1 FAST OCP BLANKING CS1 FAST OCP DEBOUNCE CYCLE TIMEOUT CYCLE-BY-CYCLE SHUTDOWN REG 0x22[7:5] REG 0x27[7:6] REG 0x27[1:0] OUTC PWM OUTD SR1 SR2 OUTAUX FLAGIN Figure 38. CS1 OCP Detailed Internal Schematic Rev. 0 | Page 29 of 96 10045-135 OUTA ADP1046 Data Sheet 5kΩ 5kΩ CS2+ ADC 1V 200µA 12 ASYNCHRONOUS 2.62ms AVERAGING PROGRAMMABLE DEBOUNCE AND ACTION (REG 0x0E AND REG 0x09) CS2 ACCURATE OCP SETTING REG 0x26 200µA 10045-136 CS2– Figure 39. CS2 OCP Detailed Internal Schematic CS2 OCP The constant current control loop is relatively low bandwidth because the current is averaged over a 328 μs period. The output voltage changes at a maximum rate of 1.18 V/sec at the VS3± pins; therefore, the instantaneous value of the current can exceed the constant current limit for a very short period of time, depending upon the transient. CS2 has one OCP protection circuit: CS2 accurate OCP (see Figure 39). The reading at the output of the CS2 ADC (Register 0x18) is compared to a programmable OCP threshold. The CS2 OCP threshold can be programmed using Register 0x26[7:0]. If the CS2 reading exceeds the CS2 OCP threshold, the CS2 accurate OCP flag is set. The CS2 ADC is asynchronously sampled, and the readings are averaged every 2.62 ms to make a fault decision. The flag response is programmed in Register 0x09. As the output voltage falls, the UVP flag (Register 0x0B[3:0]) can be used to program a shutdown action. OVERVOLTAGE PROTECTION (OVP) CONSTANT CURRENT MODE The ADP1046 has three separate OVP circuits. If the output voltage at the VS1 pin, VS2 pin, or VS3± pins exceeds the programmable threshold for that pin, the appropriate OVP flag is set. The flag response is programmed in Register 0x09[3:0] for the VS2 and VS3 OVP flags or in Register 0x0A[7:4] for the VS1 OVP flag. The ADP1046 can be configured to operate in constant current mode. The threshold to enter constant current mode operation is 3% current below the CS2 accurate OCP setting (see Figure 40). Below this current, the part operates in constant voltage mode, using the output voltage as the feedback signal for closed-loop operation. VS1 has two OVP circuits: a fast comparator (fast OVP) and an ADC based comparator (accurate OVP). VS2 and VS3 share an accurate OVP circuit. VOUT VOUT NOMINAL 0.97 × OCP OCP IOUT Figure 40. Constant Current Mode (VOUT vs. IOUT) 10045-137 The OVP circuits can be programmed for different OVP thresholds. See Register 0x32 and Register 0x33 for more information. The sampling time for the ADC based comparators is 80 μs. Additional debounce in steps of 80 μs can be added using Bits[1:0] of Register 0x32 and Register 0x33. The fast OVP comparator also has a programmable threshold and debounce time. These values are programmed in Register 0x37. When the ADP1046 reaches the constant current mode threshold, a flag is set in Register 0x02[4] and in Register 0x06[4] (real-time and latched flag registers, respectively). When this flag is set, the CS2 current reading is used to control the output voltage regulation point. The output voltage is ramped down linearly as the load increases to ensure that the current remains constant. Rev. 0 | Page 30 of 96 Data Sheet ADP1046 UNDERVOLTAGE PROTECTION (UVP) If the voltage sensed at the VS1 pin falls below the programmable UVP threshold, the UVP flag is set. The UVP threshold is programmed in Register 0x34; the GUI can also be used, as shown in Figure 41. The response to the UVP flag is programmable in Register 0x0B[3:0]. Undervoltage protection and the UVP flag are disabled during soft start. The equation to calculate the ADC code is given by the following formula: ADC Code = Vx/1.6 × 4096 where Vx is the voltage at the ACSNS pin. For example, when there is 1 V on the input of the ADC ADC Code = 1 V/1.6 × 4096 ADC Code = 2560 VSENSE = (Vx) × (R1 + R2)/R2 AC SENSE (ACSNS) The ACSNS circuit performs multiple monitoring and control functions. Two ADCs and a fast comparator are connected to this pin. The fast ADC is used for the voltage feedforward function (see the Voltage Line Feedforward and ACSNS section). This ADC has an equivalent resolution of 11 bits at 10 μs. The slow ADC is used to report the input voltage. This ADC has a resolution of 12 bits at 10 ms. The fast comparator is used to monitor whether a switching waveform is present at the output of the synchronous rectifier stage (or rectifier diodes). The pick-off point upstream of the output inductor is connected to the ACSNS pin through an external RCD divider network. where VSENSE is the filtered secondary voltage. The primary input voltage can be calculated by multiplying VSENSE by the turns ratio (N1/N2) as follows: VPRIMARY = Vx × (R1 + R2)/R2 × (N1/N2) The ACSNS comparator threshold is set at 0.45 V. If the average voltage on the ACSNS pin falls below this threshold, the ACSNS flag is set in Register 0x03[2] and in Register 0x07[2] (real-time and latched flag registers, respectively), and the programmed action for the flag is executed. When operating in resonant mode, the ACSNS comparator is used for the timing of the synchronous rectifiers and, therefore, the additional features of the ADC cannot be used. For more information, see the Resonant Mode Operation section. 10045-138 The output of the ACSNS slow ADC is a 12-bit value reported in Register 0x14. The gain of this ADC can be adjusted using Register 0x5E[6:0] to compensate for divider errors and the voltage spike. Figure 41. Voltage Sense Window in Simulation Mode (ADP1046 GUI) Rev. 0 | Page 31 of 96 ADP1046 Data Sheet The circuit monitors the current flowing in both legs of the fullbridge topology and stores this information. It compensates the selected PWM signals to ensure equal current flow in both legs of the full-bridge topology. The input is through the CS1 pin. Several switching cycles are required for the circuit to operate effectively. The maximum amount of modulation applied to each edge of the selected PWM outputs is programmable to ±80 ns or ±160 ns in Register 0x28[2]. The volt-second balance settings are programmed in Register 0x28 and in Register 0x76 through Register 0x78. It is recommended that the Analog Devices software GUI be used to program these settings. ROUT = 0.1 × 12 V × 10 mΩ/(120 mV × 23) = 12.5 mΩ This feature can be used for advanced current sharing techniques. By default, the load line is disabled. The load line is introduced digitally by modifying the value of the digital reference based on the CS2 reading. Figure 42 and Figure 43 show the load line as a percentage of VOUT vs. the RSENSE voltage drop. 100 99 98 97 96 95 94 SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING 93 92 The compensation of the PWM drive signals is performed on the edges of two selected outputs. The SR1 and SR2 edges can also be independently set to modulate due to the volt-second balance circuit to maintain the timing relation to the primary side signals. 91 90 0 10 20 7 6 5 4 3 2 1 0 30 40 50 60 70 80 90 100 110 120 RSENSE VOLTAGE DROP (mV) 10045-030 The ADP1046 has a dedicated circuit to maintain volt-second balance in the main transformer when operating in full-bridge topology. This circuit eliminates the need for a dc blocking capacitor. In interleaved topologies, volt-second balance can also be used for current balancing to ensure that each interleaved phase contributes equal power. For example, if VOUT_NOM = 12 V, CS2 RSENSE = 10 mΩ, CS2 Range = 120 mV, and LOAD_SET[2:0] = 3, VOUT (%) VOLT-SECOND BALANCE Figure 42. Load Line Settings with 120 mV CS2 Range 100 DIGITAL LOAD LINE AND SLEW RATE 96 The load line value (Register 0x36[2:0]) controls the slope of the load line. The amount of output resistance introduced can be calculated as follows: 94 SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING 92 90 88 ROUT = 0.1 × VOUT_NOM × CS2 RSENSE/(CS2 Range × 2LOAD_SET[2:0]) 0 5 10 7 6 5 4 3 2 1 0 15 20 25 30 35 40 45 50 55 RSENSE VOLTAGE DROP (mV) where: VOUT_NOM is the nominal output voltage when VS3 = 1 V. CS2 RSENSE is the sense resistor value. CS2 Range is 120 mV or 60 mV. LOAD_SET[2:0] is the value of Bits[2:0] in Register 0x36 (0 to 7 decimal). Figure 43. Load Line Settings with 60 mV CS2 Range Rev. 0 | Page 32 of 96 60 10045-031 The slew rate (Register 0x36[6:4]) determines how quickly the output voltage is adjusted in response to a change in the digital reference. Eight different settings are available. 98 VOUT (%) The ADP1046 can optionally introduce a digital load line into the power supply. This option is programmed in the load line impedance register (Register 0x36). Two parameters can be configured independently: slew rate and load line value. Data Sheet ADP1046 POWER SUPPLY CALIBRATION AND TRIM The ADP1046 allows the entire power supply to be calibrated and trimmed digitally in the production environment. It can calibrate items such as output voltage and trim for tolerance errors introduced by sense resistors and resistor dividers, as well as its own internal circuitry. The part is factory trimmed, but it can be retrimmed by the user to compensate for the errors introduced by external components. The ADP1046 GUI allows the user to automatically revert the trim settings to their factory default values. To unlock the trim registers for write access, write to the TRIM_PASSWORD register (Register 0x89). Write the trim password twice (the factory default password is 0xFF). The ADP1046 allows the user enough trim capability to trim for external components with a tolerance of 0.5% or better. If the ADP1046 is not trimmed in the production environment, it is recommended that components with a tolerance of 0.1% or better be used for the inputs to CS1, CS2, VS1, VS2, and VS3 to meet data sheet specifications. CS1 TRIM Using a DC Signal A known voltage (Vx) is applied at the CS1 pin. The CS1 ADC should output a digital code equal to Vx/1.4 × 4096. The CS1 gain trim register (Register 0x21) is adjusted until the CS1 ADC value in Register 0x13[15:4] reads the correct digital code. Using an AC Signal A known current (Ix) is applied to the PSU input. This current passes through a current transformer, a diode rectifier, and an external resistor (RCS1) to convert the current information to a voltage (Vx). This voltage is fed into the CS1 pin. The voltage (Vx) is calculated as follows: It is important to perform the CS2 offset trim as described in the following steps: 1. 2. 3. 4. 5. 6. 7. Set high-side or low-side current sensing using Register 0x27[2]. Set the nominal full-scale sense resistor voltage drop in Register 0x27[5] to 1 for the 120 mV range or to 0 for the 60 mV range. Apply no-load current across the sense resistor. Set the CS2 gain trim value to 0 (Register 0x23 = 0). Set the CS2 digital offset trim value to 0 (Register 0x25 = 0). Adjust the CS2 analog offset trim value in Register 0x24[6:0]. For the 120 mV range, adjust Register 0x24 until the CS2 value in Register 0x18[15:4] reads as close to 100 decimal (0x64) as possible; this value must be greater than 50 (0x32). For the 60 mV range, adjust Register 0x24 until the CS2 value in Register 0x18[15:4] reads as close to 200 decimal (0xC8) as possible; this value must be greater than 100 (0x64). Adjust the CS2 digital offset trim value in Register 0x25 until the CS2 value in Register 0x18[15:4] reads 0. The offset trim is now completed, and the ADC code reads 0 if there is a no-load current across the sense resistor. CS2 Gain Trim After performing the offset trim, perform the gain trim to remove any mismatch that is introduced by the sense resistor tolerance. The ADP1046 can trim for sense resistors with a tolerance of 1% or better. 1. 2. Apply a known load current (IOUT) across the sense resistor. Adjust the CS2 gain trim value in Register 0x23[5:0] until the CS2 value in Register 0x18[15:4] reads the value calculated by the following formula: CS2 Value = IOUT × RSENSE/FS × 4096 Vx = Ix × (N1/N2) × RCS1 where N1/N2 is the turns ratio of the current transformer. The CS1 ADC outputs a digital code equal to Vx/1.4 × 4096. The CS1 gain trim register (Register 0x21) is adjusted until the CS1 ADC value in Register 0x13[15:4] reads the correct digital code. CS2 TRIM The CS2 trim must compensate for offset and gain errors. The offset error requires both an analog trim and a digital trim. This error includes the mismatch of the level shifting resistors to the inputs of the CS2± differential amplifier and the tolerance of the current sense element. where: FS is the full-scale voltage drop (120 mV or 60 mV). RSENSE is the sense resistor value. If CS2 is programmed to the 120 mV range and IOUT = 10 A, RSENSE = 10 mΩ, and FS = 120 mV, CS2 Value = (10 A × 10 mΩ)/120 mV × 4096 CS2 Value = 3413 decimal If CS2 is programmed to the 60 mV range and IOUT = 5 A, RSENSE = 5 mΩ, and FS = 60 mV, CS2 Value = (5 A × 5 mΩ)/60 mV × 4096 CS2 Value = 1707 decimal CS2 Offset Trim Offset errors can be introduced by the external level shifting resistors and the internal current sources. It is best to use two 0.1% matched resistors or matched resistors within the same package. The CS2 circuit is now trimmed. The OCP limits and settings should be configured after the current sense trim is performed. Rev. 0 | Page 33 of 96 ADP1046 Data Sheet VOLTAGE CALIBRATION AND TRIM Trimming the Current Source The voltage sense inputs are optimized for sensing signals at 1 V (the usable input range is 1.4 V). In a 12 V system, a 12:1 resistor divider is required to reduce the 12 V signal to below 1.4 V. It is recommended that the output voltage of the power supply be reduced to 1 V at this pin for best performance. The tolerance of the resistor divider introduces errors that need to be trimmed. The ADP1046 has enough trim range to trim out errors introduced by resistors with a tolerance of 0.5% or better. Bits[7:6] of Register 0x11 set the value of the current source to 10 μA, 20 μA, 30 μA, or 40 μA. Bits[5:0] of Register 0x11 can be used to fine-tune the current value. By fine-tuning the internal current source, component tolerance can be compensated for and errors can be minimized. One LSB in Bits[5:0] = 160 nA. A decimal value of 1 adds 160 nA to the current source set by Bits[7:6]; a decimal value of 63 adds 63 × 160 nA = 10.08 μA to the current source set by Bits[7:6]. The VS1, VS2, and VS3 ADCs produce a digital code equal to VSx/1.6 × 4096. The ADCs output a digital word of 2560 decimal (0xA00) in Bits[15:4] of Register 0x15, Register 0x16, and Register 0x17 when there is exactly 1 V at their inputs. To program a value for the current source, select the nearest possible option (10 μA, 20 μA, 30 μA, or 40 μA) using Register 0x11[7:6]. Then use Register 0x11[5:0] to achieve the finer step size. OUTPUT VOLTAGE SETTING (VS3+, VS3− TRIM) For example, to use a value of 46 μA as the current source, follow these steps: The VS3± inputs require a gain trim. Set the output regulation point to 100% of the nominal value (Register 0x31 = 0xA0). Enable the power supply with no-load current. The power supply output voltage is divided down by the VS3 resistor divider to give 1 V across the VS3+ and VS3− differential input pins. The VS3 trim register (Register 0x3A) is adjusted until the output voltage is at the desired value. This step should be performed before any other trim routine. The VS3 voltage value in Register 0x17[15:4] reads 2560 decimal (0xA00). VS1 TRIM The VS1 input requires a gain trim. Enable the power supply with no-load current. It is recommended that the VS1 voltage be divided down by the VS1 resistor divider to give 1 V at the VS1 pin. The VS1 trim register (Register 0x38) is adjusted until the VS1 value in Register 0x15[15:4] reads 2560 decimal (0xA00). VS2 TRIM The VS2 input requires a gain trim. Enable the power supply with no-load current. It is recommended that the VS2 voltage be divided down by the VS2 resistor divider to give 1 V at the VS2 pin. The VS2 trim register (Register 0x39) is adjusted until the VS2 value in Register 0x16[15:4] reads 2560 decimal (0xA00). RTD/OTP TRIM The RTD input requires two trims: one for the current source and one for the ADC. To use the internal linearization scheme, additional trimming procedures are required. 1. 2. 3. Place a known resistor (Rx) from RTD to AGND. Set Register 0x11[7:6] to 11 (40 μA). Increase the value of Register 0x11[5:0] one LSB at a time until the voltage at the RTD pin is VRTD = 46 μA × Rx. The current source is now calibrated and is set to the factory default value. Trimming the ADC Due to the nonlinear nature of the thermistor, two trimming options can be used. Using the Internal Linearization Scheme The first option uses the internal linearization scheme with 46 μA RTD current, which provides an accurate reading in °C read in Register 0x1B in decimal format. A 100 kΩ, 1% NTC thermistor with beta = 4250, 1% (such as the NCP15WF104F03RC) in parallel with an external resistor of 16.5 kΩ, 1%, should be used with the ADP1046. With this NTC thermistor and resistor combination, the ADP1046 default current source trim is set to 46 μA to achieve the best possible accuracy over temperatures ranging from 85°C to 125°C. If an external microcontroller is used, the RTD ADC code in Register 0x1A can be fed into the microcontroller and a different linearization scheme can be implemented in terms of a best-fit polynomial for the selected NTC characteristics. Rev. 0 | Page 34 of 96 Data Sheet ADP1046 Using the OTP Value The second option does not use the linearization scheme. Instead, the user programs an RTD current and sets the OTP threshold in millivolts. Due to the nonlinear nature of the NTC thermistor, it is best to use a resistor in parallel with the NTC thermistor to aid in the linearization of the voltage seen at the RTD pin. This procedure trims out the errors/tolerances in the NTC thermistor and the external resistor. Calculation of the parallel resistor can be done by knowing the NTC resistance characteristic across various temperatures. To use this procedure, the temperatures and equivalent resistances of the NTC thermistor and parallel resistor combination must be known. T2 TEMPERATURE 10045-300 T1 Figure 44. RTD Pin Voltage, ADC Code, and Temperature The following procedure should be used: 1. 2. 3. 4. 5. 6. The ACSNS slow ADC requires a gain trim. Enable the power supply with full load current at the nominal input voltage. The secondary peak reverse voltage on the output rectifiers is filtered by an external RCD circuit (see Figure 18). The ACSNS gain trim register (Register 0x5E) is adjusted until this calculated voltage is equal to the desired primary input voltage. V2 RTD PIN VOLTAGE The ACSNS feedforward ADC (see Figure 18) is used for voltage line feedforward and cannot be trimmed by the user. where: Vx is the voltage at the ACSNS pin. N1/N2 is the turns ratio. RTD PIN VOLTAGE V1 ACSNS CALIBRATION AND TRIM VPRIMARY = Vx × (R1 + R2)/R2 × (N1/N2) V1 V2 This procedure achieves the most accurate OTP because it takes into account the part-to-part variations of the ADP1046 and the tolerances of the thermistor being used. To trim the ACSNS ADC, the user can reverse-calculate the primary voltage as follows: In Figure 44, T2 is the OTP threshold that sets the OTP flag, and T1 is the temperature at which the OTP flag is cleared. ADC CODE The ADC is now trimmed and is linear between the two temperatures of interest. Adjust the desired RTD current source, IRTD, as described in the Trimming the Current Source section. Set the temperature to the OTP threshold. Adjust the offset trim registers (Register 0x1C and Register 0x20) until the reading in Register 0x1A is the same as V2 (in mV). Set the OTP threshold (Register 0x2F) to the value of V2. Set the temperature to the hysteresis point where the OTP flag is cleared. Adjust the temperature gain trim register (Register 0x2B) until the correct voltage is seen in Register 0x1A. Another way to trim the ACSNS ADC uses the average secondary voltage. With known values for the nominal input voltage, transformer turns ratio, and resistor dividers at the ACSNS pin, the ACSNS gain trim register (Register 0x5E) is adjusted to give code 2560 decimal (0xA00). ADC Code = Vx/1.6 × 4096 where Vx is the voltage at the ACSNS pin. The resistors in Figure 18 are sized such that the first time constant, RC, is long enough to prevent overcharging of the capacitor (roughly 200 ns in a typical application), whereas the second time constant, (R1 + R2) × C, is long enough to keep the average voltage constant during the rectifier off time. Rev. 0 | Page 35 of 96 ADP1046 Data Sheet LAYOUT GUIDELINES This section explains best practices that should be followed to ensure optimal performance of the ADP1046. In general, all components should be placed as close to the ADP1046 as possible. All signals should be referenced to their respective grounds. CS1 Run the traces from the current sense transformer to the ADP1046 in parallel to each other. The traces should also be kept close together and as far from the switch nodes as possible. EXPOSED PAD CS2+ AND CS2− The routing of the traces from the sense resistor to the ADP1046 should be laid out in parallel to each other. The traces should also be kept close together and as far from the switch nodes as possible. VS3+ AND VS3− The routing of the traces from the remote voltage sense point to the ADP1046 should be laid out in parallel to each other. The traces should also be kept close together and as far from the switch nodes as possible. Place a 100 nF capacitor from VS3− to AGND to reduce common-mode noise. The exposed pad underneath the ADP1046 should be soldered to the PCB AGND plane. VCORE Place a 330 nF decoupling capacitor from this pin to DGND as close to the part as possible. RES Place a 10 kΩ, ±0.1% resistor from this pin to AGND as close to the part as possible. RTD Route a single trace to the ADP1046 from the thermistor using a dedicated trace to AGND. Place the thermistor close to the hottest part of the power supply. VDD Place decoupling capacitors as close to the part as possible. A 4.7 μF capacitor from VDD to AGND is recommended. AGND, DGND, AND PGND SDA AND SCL The routing of the traces should be laid out in parallel to each other. The traces should also be kept close together and as far from the switch nodes as possible. Create an AGND ground plane and make a single-point (star) connection to the power supply system ground. Connect DGND to AGND with a very short trace using a star connection. Connect PGND to AGND using a star connection. Rev. 0 | Page 36 of 96 Data Sheet ADP1046 I2C INTERFACE COMMUNICATION The ADP1046 I2C slave is a 2-wire interface that can be used to communicate with other I2C-compliant master devices and is compatible in a multimaster, multislave bus configuration. FEATURES The function of the I2C slave is to decode the command sent from the master device and respond as requested. Communication is established using a 2-wire interface with a clock line (SCL) and data line (SDA). The I2C slave is designed to externally move chunks of 8-bit data (bytes) while maintaining compliance with the I2C protocol, based on the Philips I2C Bus Specification, Version 2.1, dated January 2000. The I2C protocol incorporates the following features: Slave operation on multiple device systems 7-bit addressing 100 kB/sec and 400 kB/sec data rates General call address support Support for clock low extension (clock stretching) Separate multiple byte receive and transmit FIFO Extensive communication fault monitoring The I2C address of the ADP1046 is set by connecting an external resistor from the ADD pin to AGND. Table 6 lists the recommended resistor values and the associated I2C addresses. Seven different addresses can be used. The recommended resistor values in Table 6 must be 1% tolerance resistors. Table 6. Recommended Resistor Values for I2C Addresses I2C Address 0x50 0x51 0x52 0x53 0x54 0x55 0x57 Resistor Value (kΩ) 10 (or connect the ADD pin directly to AGND) 28.7 48.7 68.1 88.7 109 200 (or connect the ADD pin directly to VDD) DATA TRANSFER Format Overview OVERVIEW The I2C slave module is a 2-wire interface that can be used to communicate with other I2C-compliant master devices. Its transfer protocol is based on the Philips I2C transfer mechanism. The ADP1046 is always configured as a slave device in the overall system. The ADP1046 communicates with the master device using one data pin (SDA) and one clock pin (SCL). Because the ADP1046 is a slave device, it cannot generate the clock signal. However, it is capable of stretching the SCL line to put the master device in a wait state when it is not ready to respond to the master’s request. Communication is initiated when the master device sends a command to the I2C 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 I2C communication protocol. During communication, the master and slave devices send acknowledge (A) or no acknowledge (NA) bits as a method of handshaking between devices. Refer to the Philips I2C Bus Specification, Version 2.1, dated January 2000, for a more detailed description of the communication protocol. The I2C slave follows the transfer protocol of the Philips I2C Bus Specification. Data transfers are byte-wide, lower byte first. Each byte is transmitted serially, most significant bit (MSB) first. A typical transfer is shown in Figure 45. S 7-BIT SLAVE ADDRESS W A 8-BIT DATA A ... P 10045-140 • • • • • • • I2C ADDRESS = MASTER-TO-SLAVE = SLAVE-TO-MASTER Figure 45. Basic Data Transfer Figure 45 to Figure 52 use the following abbreviations: • • • • • • • S = start condition Sr = repeated start condition P = stop condition R = read bit W = write bit A = acknowledge bit (0) NA = no acknowledge bit (1) Refer to the I2C specification for an in-depth discussion of the transfer protocols. Rev. 0 | Page 37 of 96 Data transfer using the I2C slave is established using commands. All commands start with a slave address with the R/W bit cleared (set to 0), followed by the command code (register address). All commands supported by the ADP1046 follow one of the protocol types shown in Figure 46 to Figure 52. 7-BIT SLAVE ADDRESS W A COMMAND CODE A P = MASTER-TO-SLAVE = SLAVE-TO-MASTER 7-BIT SLAVE ADDRESS COMMAND CODE A DATA BYTE A A P = MASTER-TO-SLAVE = SLAVE-TO-MASTER W COMMAND CODE A A DATA BYTE LOW DATA BYTE HIGH A A P 10045-143 7-BIT SLAVE ADDRESS Figure 47. Write Byte Protocol S = MASTER-TO-SLAVE = SLAVE-TO-MASTER W COMMAND CODE A NA Sr P COMMAND CODE A Sr DATA BYTE HIGH NA R A DATA BYTE N A NA P Conditions where the I2C 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 FIFO 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 ADP1046 limits the maximum time that the SCL line can be stretched, or held low. For more information about the maximum time, see the Timeout Condition section. Start and Stop Conditions P 10045-145 DATA BYTE LOW A 7-BIT SLAVE ADDRESS 7-BIT SLAVE ADDRESS Figure 49. Read Byte Protocol A ... R The ADP1046 is always a slave 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 I2C 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. = SLAVE-TO-MASTER W A Sr Figure 52. Block Read Protocol A = MASTER-TO-SLAVE S DATA BYTE 1 A = SLAVE-TO-MASTER R 10045-144 DATA BYTE A 7-BIT SLAVE ADDRESS 7-BIT SLAVE ADDRESS Figure 48. Write Word Protocol S A COMMAND CODE Clock Generation and Stretching 10045-142 W A = MASTER-TO-SLAVE Figure 46. Send Byte Protocol S W BYTE COUNT = N 10045-141 S S 10045-147 Command Overview 7-BIT SLAVE ADDRESS Data Sheet 7-BIT SLAVE ADDRESS ADP1046 = MASTER-TO-SLAVE = SLAVE-TO-MASTER Start and stop conditions involve serial data transitions while the serial clock is at a logic high level. The I2C slave device monitors the SDA and SCL lines to detect the start and stop conditions and transition its internal state machine accordingly. Typical start and stop conditions are shown in Figure 53. Figure 50. Read Word Protocol SCL S 7-BIT SLAVE ADDRESS W A COMMAND CODE A BYTE COUNT = N A START A ... DATA BYTE N A P 10045-146 DATA BYTE 1 = MASTER-TO-SLAVE = SLAVE-TO-MASTER STOP Figure 53. Start and Stop Transitions Figure 51. Block Write Protocol Rev. 0 | Page 38 of 96 10045-148 SDA Data Sheet ADP1046 GENERAL CALL SUPPORT DATA TRANSMISSION FAULTS The ADP1046 is capable of decoding and acknowledging a general call address. The general call address is supported for send, write, and read commands that use Address 0x00 as the slave address. The I2C slave responds to both its own address and to the general call address (0x00). Data transmission faults occur when two communicating devices violate the I2C communication protocol. Note that all commands start with a 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 I2C slave device. 10-BIT ADDRESSING The ADP1046 does not support 10-bit addressing as defined in the I2C specification. FAST MODE Fast mode (400 kB/sec) uses essentially the same mechanics as the standard mode of operation; the electrical specifications and timing are most affected. The I2C slave is capable of communicating with a master device operating in standard mode (100 kB/sec) or fast mode. REPEATED START CONDITION In general, a repeated start condition is the absence of a stop condition between two transfers. The two transfers can be of any direction type, for example, a transmit followed by a receive or a receive followed by a transmit. However, the ADP1046 I2C communication protocol uses the repeated start condition only when performing a read access (read byte, read word, and block read). Other uses of the repeated start condition are not allowed. ELECTRICAL SPECIFICATIONS All logic complies with the electrical specifications outlined in the Philips I2C Bus Specification, Version 2.1, dated January 2000. FAULT CONDITIONS The I2C protocol provides a very comprehensive set of fault conditions that are monitored during communication. These communication faults are error conditions associated with the data transfer mechanism of the I2C protocol and are explained in the following sections. TIMEOUT CONDITION A timeout condition occurs if any single SCL clock pulse is held low for longer than the tTIMEOUT, MIN of 25 ms. Upon detecting the timeout condition, the I2C 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 a minimum of tTIMEOUT, MAX = 35 ms, guaranteeing that the slave device is given enough time to reset its communication protocol. Sending Too Few Bits 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 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. Host Sends or Reads Too Few Bytes 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 I2C slave does not consider this to be an error and takes no action, except to flush any remaining bytes in the transmit FIFO. Host Sends Too Many Bytes If a host sends more bytes than are expected for the corresponding command, the I2C slave considers this a data transmission fault and responds as follows: NACKs all unexpected bytes as they are received Flushes and ignores the received command and data Host Reads Too Many Bytes If a host reads more bytes than are expected for the corresponding command, the I2C slave considers this a data transmission fault and sends all 1s (0xFF) as long as the host continues to request data. Device Busy The I2C slave device is too busy to respond to a request from the master device. Typically SCL clock stretching is involved until the device is free to communicate. DATA CONTENT FAULTS Data content faults occur when data transmission is successful, but the I2C slave device cannot process the data that is received from the master device. Improperly Set Read Bit in the Address Byte All I2C commands start with a slave address with the R/W bit cleared (set to 0), followed by the command code. If a host starts an I2C transaction with R/W set in the address phase (equivalent to an I2C read), the I2C slave considers this a data content fault and responds as follows: Rev. 0 | Page 39 of 96 ACKs the address byte NACKs the command and data bytes Sends all 1s (0xFF) as long as the host continues to request data ADP1046 Data Sheet Invalid or Unsupported Command Code Write to Read-Only Commands If an invalid or unsupported command code is sent to the I2C slave, the I2C slave considers this a data content fault and responds as follows: If a host performs a write to a read-only command, the I2C slave considers this a data content fault and responds as follows: • • NACKs the illegal/unsupported command byte and data bytes Flushes and ignores the received command and data • • NACKs all unexpected data bytes as they are received Flushes and ignores the received command and data Note that this is the same error described in the Host Sends Too Many Bytes section. Reserved Bits Read from Write-Only Commands Accesses to reserved bits are not a fault. Writes to reserved bits are ignored, and reads from reserved bits return undefined data. If a host performs a read from a write-only command, the I2C slave considers this a data content fault and send all 1s (0xFF) as long as the host continues to request data. Note that this is the same error described in the Host Reads Too Many Bytes section. Rev. 0 | Page 40 of 96 Data Sheet ADP1046 EEPROM 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 logic low previously. The ADP1046 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 (for internal use only), and the main block contains 8K 8-bit bytes. The main block is further partitioned into 16 pages, each page containing 512 bytes. READ OPERATION (BYTE READ AND BLOCK READ) Read from Main Block, Page 0 and Page 1 Communication is initiated by the master device sending a command to the I2C slave device to access data from or send data to the EEPROM. Using read and write commands, 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. Send commands are also supported, 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 I2C communication protocol. For a complete description of the I2C protocol, see the Philips I2C Bus Specification, Version 2.1, dated January 2000. PAGE ERASE OPERATION 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 on Page 0 or Page 1. Page 2 and Page 3 are reserved for internal use, and their contents should not be erased. Only Page 4 to Page 15 of the main block should be used to store data. To erase any page from Page 4 to Page 15, the EEPROM must first be unlocked for access. For instructions on how to unlock the EEPROM, see the Unlock the EEPROM section. COMMAND CODE A DATA BYTE A In the following example, three bytes from Page 4 are read from the EEPROM, starting from the fifth byte of that page. Set the number of return bytes = 3. 1. S 7-BIT SLAVE ADDRESS W A 0x86 A 0x03 A P A 0x00 A 0x05 A P 7-BIT SLAVE ADDRESS R A NA P = MASTER-TO-SLAVE = SLAVE-TO-MASTER 2. Set address offset = 5. S 7-BIT SLAVE ADDRESS W A 0x85 = SLAVE-TO-MASTER Read three bytes from Page 4. S 7-BIT SLAVE ADDRESS W A 0x8F A Sr P = MASTER-TO-SLAVE BYTE COUNT = 0x03 = SLAVE-TO-MASTER A DATA BYTE 1 A ... DATA BYTE 3 = MASTER-TO-SLAVE Figure 54. Example Erase Command = SLAVE-TO-MASTER In this example, command code = 0x87 and data byte = 0x0A. Note that it is necessary to wait at least 35 ms for the page erase operation to complete before executing the next I2C command. Note that the block read command can read a maximum of 256 bytes for any single transaction (set the number of return bytes = 0). Rev. 0 | Page 41 of 96 10045-203 A Before executing this command, the user must program the number of bytes to read using the EEPROM_NUM_RD_BYTES command (Register 0x86). The user can also program the offset from the page boundary where the first read byte is returned using the EEPROM_ADDR_OFFSET command (Register 0x85). 10045-200 W Data in Page 2 to Page 15 of the main block 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 (Register 0x8B to Register 0x9A). 3. For example, to perform a page erase of Page 10, execute the following command: 7-BIT SLAVE ADDRESS Read from Main Block, Page 2 to Page 15 = MASTER-TO-SLAVE Page 4 to Page 15 of the main block can be individually erased using the EEPROM_PAGE_ERASE command (Register 0x87). S Page 0 and Page 1 of the main block are reserved for storing the default settings and user settings, respectively, and are intended 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 the EEPROM section). After the EEPROM is unlocked, Page 0 and Page 1 are readable using the EEPROM_DATA_xx commands, as described in the Read from Main Block, Page 2 to Page 15 section. Note that when the EEPROM is locked, a read from Page 0 or Page 1 returns invalid data. 10045-201 The EEPROM controller provides an interface between the ADP1046 core logic and the built-in Flash/EE. The user can control data access to and from the EEPROM through this controller interface. Different I2C commands are available for the different operations to the EEPROM. 10045-202 OVERVIEW ADP1046 Data Sheet WRITE OPERATION (BYTE WRITE AND BLOCK WRITE) EEPROM PASSWORD Write to Main Block, 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_00 and EEPROM_DATA_01 commands. A user write to Page 0 or 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 (Register 0x82). See the Save Register Settings to User Settings section. Write to Main Block, Page 2 and Page 3 Page 2 and Page 3 of the main block are reserved for internal use and their contents should not be written to. Only Page 4 to Page 15 should be used to store data. Change the EEPROM Password Data in Page 4 to Page 15 of 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 (Register 0x8B to Register 0x9A). 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 0x85). If the targeted page has not yet been erased, the user can erase the page as described in the Page Erase Operation section. In the following example, four bytes are written to Page 9, starting from the 256th byte of that page. 0x85 A 0x01 A 0x00 A P 10045-204 W A = MASTER-TO-SLAVE = SLAVE-TO-MASTER DOWNLOADING EEPROM SETTINGS TO INTERNAL REGISTERS 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: Write four bytes to Page 9. S 7-BIT SLAVE ADDRESS DATA BYTE 1 W A A 0x94 ... A DATA BYTE 4 BYTE COUNT = 4 A A P = MASTER-TO-SLAVE = SLAVE-TO-MASTER Note that the block write command can write a maximum of 256 bytes for any single transaction (set the byte count = 0). On power-up. The user settings are automatically downloaded into the internal registers, powering the part up in a state previously saved by the user. On execution of the RESTORE_USER_ALL command (Register 0x83). This command allows the user to force a download of the user settings from Page 1 of the EEPROM main block into the internal registers. Download Factory Default Settings to Registers 10045-205 2. To change the EEPROM password, first write the correct password using the EEPROM_PASSWORD command (Register 0x88). Immediately write the new password using the same command. The password is now changed to the new password. Set address offset = 256. 7-BIT SLAVE ADDRESS To unlock the EEPROM, perform two consecutive writes with the correct password (default = 0xFF) using the EEPROM_ PASSWORD command (Register 0x88). The EEPROM unlocked flag (Bit 0 of Register 0x03) is set to indicate that the EEPROM is unlocked for write access. To lock the EEPROM, write any byte other than the correct password using the EEPROM_PASSWORD command (Register 0x88). The EEPROM unlocked flag (Bit 0 of Register 0x03) is cleared to indicate that the EEPROM is locked from write access. Before performing a write to Page 4 through Page 15 of the main block, the user must first unlock the EEPROM (see the Unlock the EEPROM section). S Unlock the EEPROM Lock the EEPROM Write to Main Block, Page 4 to Page 15 1. On power-up, the EEPROM is locked and protected from accidental writes or erases. Only reads from Page 2 to Page 15 of the main block 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 default settings can be downloaded from the EEPROM into the internal registers using the RESTORE_ DEFAULT_ALL command (Register 0x81). When this command is executed, the EEPROM password is also reset to the factory default setting of 0xFF. Rev. 0 | Page 42 of 96 Data Sheet ADP1046 SAVING REGISTER SETTINGS TO THE EEPROM EEPROM CRC CHECKSUM The register settings cannot be saved to the factory default settings 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 the EEPROM are consistent with the internal registers, a CRC checksum is implemented. Save Register Settings to User Settings The register settings can be saved to the user settings located in Page 1 of the EEPROM main block using the STORE_USER_ALL command (Register 0x82). Before this command can be executed, the EEPROM must first be unlocked for writing (see the Unlock the EEPROM section). After the register settings are saved to the user settings, 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 register settings are stored in the EEPROM. Therefore, it is important to wait at least 40 ms for the operation to complete before executing the next I2C 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 (Bit 1 of Register 0x03). To read the EEPROM CRC checksum value, execute the EEPROM_CRC_CHKSUM command (Register 0x84). 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 43 of 96 ADP1046 Data Sheet SOFTWARE GUI A free software GUI is available for programming and configuring the ADP1046. The GUI is designed to be intuitive to power supply designers and dramatically reduces power supply design and development time. For more information about the GUI, contact Analog Devices for the latest software and a user guide. Evaluation boards are also available by contacting Analog Devices. 10045-407 The software includes filter design and power supply PWM topology windows. The GUI is also an information center, displaying the status of all readings, monitoring, and flags on the ADP1046. Figure 55. ADP1046 GUI Rev. 0 | Page 44 of 96 Data Sheet ADP1046 REGISTER LISTING Table 7. Register List Address Register Name Fault Registers 0x00 Fault Register 1 0x01 Fault Register 2 0x02 Fault Register 3 0x03 Fault Register 4 0x04 Latched Fault Register 1 0x05 Latched Fault Register 2 0x06 Latched Fault Register 3 0x07 Latched Fault Register 4 0x08 Fault Configuration Register 1 0x09 Fault Configuration Register 2 0x0A Fault Configuration Register 3 0x0B Fault Configuration Register 4 0x0C Fault Configuration Register 5 0x0D Fault Configuration Register 6 0x0E Flag configuration 0x0F Soft start blank fault flags Value Registers 0x10 First flag ID 0x11 RTD current source 0x12 HF ADC reading 0x13 CS1 value (input current) 0x14 ACSNS value 0x15 VS1 voltage value 0x16 VS2 voltage value 0x17 VS3 voltage value (output voltage) 0x18 CS2 value (output current) 0x19 CS2 × VS3 value (output power) 0x1A RTD temperature value 0x1B Read temperature 0x1C RTD offset trim (MSB) 0x1D Share bus value 0x1E Modulation value 0x1F Line impedance value 0x20 RTD offset trim (LSBs) Current Sense and Current Limit Registers 0x21 CS1 gain trim 0x22 CS1 accurate OCP limit 0x23 CS2 gain trim 0x24 CS2 analog offset trim 0x25 CS2 digital offset trim 0x26 CS2 accurate OCP limit 0x27 CS1/CS2 fast OCP settings 0x28 Volt-second balance settings 0x29 Share bus bandwidth 0x2A Share bus setting 0x2B Temperature gain trim 0x2C PSON/soft start 0x2D PGOOD debounce and pin polarity settings 0x2E Modulation limit Rev. 0 | Page 45 of 96 ADP1046 Data Sheet Address Register Name 0x2F OTP threshold 0x30 OrFET Voltage Sense Registers 0x31 VS3 voltage setting (remote voltage) 0x32 VS1 overvoltage limit (OVP) 0x33 VS2 and VS3 overvoltage limit (OVP) 0x34 VS1 undervoltage limit (UVP) 0x35 Line impedance limit 0x36 Load line impedance 0x37 Fast OVP comparator 0x38 VS1 trim 0x39 VS2 trim 0x3A VS3 trim 0x3B Light load mode disable settings ID Registers 0x3C Silicon revision ID 0x3D Manufacturer ID 0x3E Device ID PWM and Synchronous Rectification Timing Registers 0x3F OUTAUX switching frequency setting 0x40 PWM switching frequency setting and PWM switching frequency setting in resonant mode 0x41 OUTA rising edge timing (OUTA pin) and OUTA rising edge dead time in resonant mode 0x42 OUTA rising edge setting (OUTA pin) and lowest switching frequency limit setting in resonant mode 0x43 OUTA falling edge timing (OUTA pin) and OUTA falling edge dead time in resonant mode 0x44 OUTA falling edge setting (OUTA pin) and lowest switching frequency limit setting in resonant mode 0x45 OUTB rising edge timing (OUTB pin) and OUTB rising edge dead time in resonant mode 0x46 OUTB rising edge setting (OUTB pin) and highest switching frequency limit setting in resonant mode 0x47 OUTB falling edge timing (OUTB pin) and OUTB falling edge dead time in resonant mode 0x48 OUTB falling edge setting (OUTB pin) and highest switching frequency limit setting in resonant mode 0x49 OUTC rising edge timing (OUTC pin) and OUTC rising edge dead time in resonant mode 0x4A OUTC rising edge setting (OUTC pin) and burst mode operation in resonant mode 0x4B OUTC falling edge timing (OUTC pin) and OUTC falling edge dead time in resonant mode 0x4C OUTC falling edge setting (OUTC pin) 0x4D OUTD rising edge timing (OUTD pin) and OUTD rising edge dead time in resonant mode 0x4E OUTD rising edge setting (OUTD pin) 0x4F OUTD falling edge timing (OUTD pin) and OUTD falling edge dead time in resonant mode 0x50 OUTD falling edge setting (OUTD pin) 0x51 SR1 rising edge timing (SR1 pin) and SR1 rising edge dead time in resonant mode 0x52 SR1 rising edge setting (SR1 pin) 0x53 SR1 falling edge timing (SR1 pin) and SR1 falling edge dead time in resonant mode 0x54 SR1 falling edge setting (SR1 pin) 0x55 SR2 rising edge timing (SR2 pin) and SR2 rising edge dead time in resonant mode 0x56 SR2 rising edge setting (SR2 pin) 0x57 SR2 falling edge timing (SR2 pin) and SR2 falling edge dead time in resonant mode 0x58 SR2 falling edge setting (SR2 pin) 0x59 OUTAUX rising edge timing (OUTAUX pin) 0x5A OUTAUX rising edge setting (OUTAUX pin) 0x5B OUTAUX falling edge timing (OUTAUX pin) 0x5C OUTAUX falling edge setting (OUTAUX pin) 0x5D OUTx and SRx pin disable settings 0x5E ACSNS gain trim Rev. 0 | Page 46 of 96 Data Sheet ADP1046 Address Register Name Digital Filter Programming Registers 0x5F Soft start and output voltage slew rate settings 0x60 Normal mode digital filter LF gain setting 0x61 Normal mode digital filter zero setting 0x62 Normal mode digital filter pole setting 0x63 Normal mode digital filter HF gain setting 0x64 Light load mode digital filter LF gain setting 0x65 Light load mode digital filter zero setting 0x66 Light load mode digital filter pole setting 0x67 Light load mode digital filter HF gain setting Adaptive Dead Time Registers 0x68 Adaptive dead time threshold 0x69 Dead Time 1 0x6A Dead Time 2 0x6B Dead Time 3 0x6C Dead Time 4 0x6D Dead Time 5 0x6E Dead Time 6 0x6F Dead Time 7 0x70 Dead time configuration Soft Start Filter Programming Registers 0x71 Soft start digital filter LF gain setting 0x72 Soft start digital filter zero setting 0x73 Soft start digital filter pole setting 0x74 Soft start digital filter HF gain setting Extended Functions Registers 0x75 Voltage line feedforward 0x76 Volt-second balance settings (OUTA and OUTB pins) 0x77 Volt-second balance settings (OUTC and OUTD pins) 0x78 Volt-second balance settings (SR1 and SR2 pins) 0x79 SR delay compensation 0x7A Filter transitions 0x7B PGOOD1 flag masking 0x7C PGOOD2 flag masking 0x7D Light load mode threshold settings 0x7E Reserved 0x7F GO byte 0x80 Reserved EEPROM Registers 0x81 RESTORE_DEFAULT_ALL 0x82 STORE_USER_ALL 0x83 RESTORE_USER_ALL 0x84 EEPROM_CRC_CHKSUM 0x85 EEPROM_ADDR_OFFSET 0x86 EEPROM_NUM_RD_BYTES 0x87 EEPROM_PAGE_ERASE 0x88 EEPROM_PASSWORD 0x89 TRIM_PASSWORD 0x8A EEPROM_INFO 0x8B EEPROM_DATA_00 0x8C EEPROM_DATA_01 0x8D EEPROM_DATA_02 0x8E EEPROM_DATA_03 0x8F EEPROM_DATA_04 Rev. 0 | Page 47 of 96 ADP1046 Address 0x90 0x91 0x92 0x93 0x94 0x95 0x96 0x97 0x98 0x99 0x9A Data Sheet Register Name 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 Rev. 0 | Page 48 of 96 Data Sheet ADP1046 DETAILED REGISTER DESCRIPTIONS FAULT REGISTERS Register 0x04 to Register 0x07 are latched fault registers. In these registers, flags are not reset when the fault disappears. Flags are cleared only by a register read (provided that the fault no longer persists). Note that latched bits are clocked on a low-to-high transition only. Also note that these register bits are cleared when read via the I2C interface unless the fault is still present. It is recommended that the latched fault register be read again after the faults disappear to ensure that the register is reset. Table 8. Register 0x00—Fault Register 1 and Register 0x04—Latched Fault Register 1 (1 = Fault, 0 = Normal Operation) Bits 7 Bit Name Power supply R/W R 6 5 OrFET PGOOD1 fault R R 4 PGOOD2 fault R 3 SR off R 2 CS1 fast OCP R 1 0 CS1 accurate OCP CS2 accurate OCP R R Description 1 = power supply is off. All PWM outputs are disabled. This bit stays high until the power supply is restarted. 1 = OrFET control signal at the GATE pin (Pin 16) is off. 1 = Power-Good 1 fault. At least one of the following flags has been set: soft start flag, CS1 fast OCP, CS1 accurate OCP, CS2 accurate OCP, UVP, local OVP, load OVP, or OrFET (GATE). These flags can be masked using Register 0x7B. 1 = Power-Good 2 fault. At least one of the following flags has been set: soft start flag, CS1 fast OCP, CS1 accurate OCP, CS2 accurate OCP, UVP, local OVP, load OVP, or OrFET (GATE pin). These flags can be masked using Register 0x7C. The following flags can also set PGOOD2, either unconditionally or based on the flag response, as defined in Register 0x2D[3] (see Table 45): voltage continuity, OrFET disable, ACSNS, external flag (FLAGIN pin), and OTP. SR1 and SR2 synchronous rectifiers are disabled. This flag is set when one of the following cases is true: SR1 and SR2 are disabled by the user. The load current has fallen below the threshold in Register 0x3B. Register A flag has been set that is configured to disable the synchronous rectifiers. CS1 current is above its fast overcurrent protection limit. There is a 1.2 V threshold on the CS1 pin. Fast OCP is a comparator. CS1 current is above its accurate overcurrent protection limit. CS2 current is above its accurate overcurrent protection limit. 0x08 to 0x0D Action None 0x30 0x2D None 0x2D None None 0x5D 0x3B Programmable 0x22 0x26 Programmable Programmable Table 9. Register 0x01—Fault Register 2 and Register 0x05—Latched Fault Register 2 (1 = Fault, 0 = Normal Operation) Bits 7 Bit Name Voltage continuity R/W R 6 5 R R 4 3 2 UVP CS2 reverse current VDD UV VCORE OV VDD OV R R R 1 0 Load OVP Local OVP R R Description Voltage differential between VS1 and VS2 pins or between VS2 and VS3± pins is outside limits. Either (VS1 − VS2) > 50 mV or (VS2 − VS3) > 50 mV at the pins. VS1 is below its undervoltage limit. Reverse voltage across the CS2± pins is above limit. This is the OrFET reverse voltage. VDD is below limit. 2.5 V VCORE is above limit. VDD is above limit. The I2C interface stays functional, but a PSON toggle is required to restart the power supply. VS2 or VS3± is above its overvoltage limit. VS1 is above its overvoltage limit. Rev. 0 | Page 49 of 96 Register Action Programmable 0x34 0x30 Programmable Programmable 0x0E Immediate shutdown Immediate shutdown Programmable 0x33 0x32 Programmable Programmable ADP1046 Data Sheet Table 10. Register 0x02—Fault Register 3 and Register 0x06—Latched Fault Register 3 (1 = Fault, 0 = Normal Operation) Bits 7 6 5 4 Bit Name OTP Fast OVP Share bus Constant current R/W R R R R 3 2 1 0 Soft start Line impedance Soft start filter External flag R R R R Description Temperature is above OTP limit. Fast OVP threshold was exceeded. Current share is outside regulation limit. Power supply is operating in constant current mode (constant current mode is enabled). The reference is being ramped. Line impedance between VS2 and VS3± is above limit. The soft start filter is in use. The external flag pin (FLAGIN) is set. Register 0x2F 0x37 0x2A 0x27 Action Programmable Programmable Programmable None 0x35 0x5F None None None Programmable Table 11. Register 0x03—Fault Register 4 and Register 0x07—Latched Fault Register 4 (1 = Fault, 0 = Normal Operation) Bits 7 6 5 4 3 2 1 0 Bit Name Volt-second balance Modulation Reserved Light load mode Adaptive dead time ACSNS CRC fault EEPROM unlocked R/W R R R R R R R R Description Volt-second balance is at its maximum or minimum limit. Modulation is at its maximum or minimum limit. Reserved. The system is in light load mode. Adaptive dead time in use and affecting PWM edges. The ac sense (comparator) amplitude is not correct. The EEPROM contents downloaded are incorrect. The EEPROM is unlocked. Register 0x2E 0x3B Action None None None None None Programmable Immediate shutdown None Table 12. Register 0x08 to Register 0x0D—Fault Configuration Registers Register Name Fault Configuration Register 1 Address 0x08 Fault Configuration Register 2 0x09 Fault Configuration Register 3 0x0A Fault Configuration Register 4 0x0B Fault Configuration Register 5 0x0C Fault Configuration Register 6 0x0D Bits [7:4] [3:0] [7:4] [3:0] [7:4] [3:0] [7:4] [3:0] [7:4] [3:0] [7:4] [3:0] Flag CS1 fast OCP CS1 accurate OCP CS2 accurate OCP Load OVP (VS2 or VS3) Local accurate OVP (VS1) and fast OVP (VS1) External flag input (FLAGIN) OTP UVP CS2 reverse voltage Voltage continuity Share bus ACSNS Rev. 0 | Page 50 of 96 Shutdown Debounce See Register 0x27 in Table 39 See Register 0x0E in Table 14 See Register 0x0E in Table 14 2 ms 2 ms See Register 0x37 in Table 55 10 ms 100 ms 10 ms 10 ms 100 ms 100 ms 10 ms Data Sheet ADP1046 Register 0x08 to Register 0x0D allow the user to program the response when each flag is set. Table 13. Register 0x08 to Register 0x0D—Fault Configuration Register Bit Descriptions Bits 7 Bit Name Timing R/W R/W [6:4] Action R/W 3 [2:0] Timing Action R/W R/W Description This bit specifies when the flag is set. 0 = after debounce. 1 = immediately. These bits specify the action that the part takes in response to the flag. Bit 6 Bit 5 Bit 4 Action 0 0 0 Ignore flag completely 0 0 1 Disable SR1 and SR2 0 1 0 Disable OrFET 0 1 1 Disable the power supply and reenable it after the power supply reenable time set in Register 0x0E[1:0] 1 0 0 Disable OUTAUX 1 0 1 Disable all PWM outputs except OUTAUX 1 1 0 Disable SR1, SR2, and OrFET 1 1 1 Disable the power supply and keep it disabled; PSON signal is necessary to restart Same as Bit 7. Same as Bits[6:4]. Table 14. Register 0x0E—Flag Configuration Register Bits 7 6 5 [4:2] [1:0] Bit Name VDD OV/VCORE OV flags ignore VDD OV/VCORE OV restart R/W R/W Description Setting this bit to 1 means that the VDD OV and VCORE OV flags are ignored. R/W VDD OV/VCORE OV debounce Accurate OCP debounce for CS1 and CS2 R/W Power supply reenable time R/W This bit specifies whether the part downloads the EEPROM contents before it restarts. 1 = if the part shuts down, it downloads the EEPROM contents again before restarting. 0 = if the part shuts down, it does not download the EEPROM contents again before restarting. Setting this bit to 1 means that there is a 500 μs debounce before the part shuts down. Setting this bit to 0 means that there is a 2 μs debounce before the part shuts down. When an accurate OCP flag is set, there is a debounce time before the flag action is performed. These bits set the flag debounce time. The ADC sampling rate adds a variable latency from 2.62 ms to 5.24 ms to this debounce time. Bit 4 Bit 3 Bit 2 Debounce 0 0 0 2.6 ms 0 0 1 9.8 ms 0 1 0 130 ms 0 1 1 260 ms 1 0 0 600 ms 1 0 1 1.3 sec 1 1 0 2 sec 1 1 1 2.6 sec These bits specify the time delay before restarting the power supply after a shutdown. SR1, SR2, and OrFET are reenabled immediately. Bit 1 Bit 0 Time (sec) 0 0 0.5 0 1 1 1 0 2 1 1 4 R/W Rev. 0 | Page 51 of 96 ADP1046 Data Sheet Register 0x0F allows the user to program the ADP1046 to ignore the specified flags until the end of the soft start ramp time. The UVP and ACSNS flags are always active during soft start. Table 15. Register 0x0F—Soft Start Blank Fault Flags Register Bits 7 Bit Name Blank SR R/W R/W 6 5 4 Blank OTP Blank FLAGIN Blank local OVP (accurate and fast) Blank load OVP Blank CS2 accurate OCP Blank CS1 accurate OCP Blank CS1 fast OCP R/W R/W R/W 3 2 1 0 R/W R/W R/W R/W Description Setting this bit means that the SR1 and SR2 PWM outputs are not enabled until the end of the soft start ramp time. Setting this bit means that the OTP flag is ignored until the end of the soft start ramp time. Setting this bit means that the FLAGIN flag is ignored until the end of the soft start ramp time. Setting this bit means that the local OVP flag is ignored until the end of the soft start ramp time. Setting this bit means that the load OVP flag is ignored until the end of the soft start ramp time. Setting this bit means that the CS2 accurate OCP flag is ignored until the end of the soft start ramp time. Setting this bit means that the CS1 accurate OCP flag is ignored until the end of the soft start ramp time. Setting this bit means that the CS1 fast OCP flag is ignored until the end of the soft start ramp time. VALUE REGISTERS Table 16. Register 0x10—First Flag ID Bits [7:4] [3:0] Bit Name Reserved First flag ID R/W R R Description Reserved. These bits record the flag that was set first. Restarting the power supply resets this register. Reading this register also resets the register. Bit 3 Bit 2 Bit 1 Bit 0 Fault Register Flag 0 0 0 0 None No flag 0 0 0 1 Register 0x01, Bit 3 VCORE OV 0 0 1 0 Register 0x01, Bit 2 VDD OV 0 0 1 1 Register 0x03, Bit 1 EEPROM CRC fault 0 1 0 0 Register 0x00, Bit 2 CS1 fast OCP 0 1 0 1 Register 0x00, Bit 1 CS1 accurate OCP 0 1 1 0 Register 0x00, Bit 0 CS2 accurate OCP 0 1 1 1 Register 0x01, Bit 1 Load OVP 1 0 0 0 Register 0x01, Bit 0 Local OVP (fast and accurate) 1 0 0 1 Register 0x02, Bit 0 FLAGIN 1 0 1 0 Register 0x02, Bit 7 OTP 1 0 1 1 Register 0x01, Bit 6 UVP 1 1 0 0 Register 0x01, Bit 5 CS2 reverse voltage 1 1 0 1 Register 0x01, Bit 7 Voltage continuity 1 1 1 0 Register 0x02, Bit 5 Share bus 1 1 1 1 Register 0x03, Bit 2 ACSNS Table 17. Register 0x11—RTD Current Source Bits [7:6] Bit Name RTD current setting R/W R/W [5:0] Current trim R/W Description These bits set the size of the current source on the RTD pin. Bit 7 Bit 6 Current Source (μA) 0 0 10 0 1 20 1 0 30 1 1 40 These six bits are used to trim the current source on the RTD pin. Each LSB corresponds to 160 nA, independent of the RTD current setting selected in Register 0x11[7:6]. Rev. 0 | Page 52 of 96 Data Sheet ADP1046 Table 18. Register 0x12—HF ADC Reading Bits [7:0] Bit Name HF ADC reading R/W R Description This register contains the reading from the high frequency ADC. Table 19. Register 0x13—CS1 Value (Input Current) Bits [15:4] Bit Name Input current value R/W R [3:0] Reserved R Description This register contains the 12-bit input current information. This value is derived from a voltage measurement at the CS1 input. To read the input current information, this register must be read using two consecutive read operations. The eight bits of the first read return the eight MSBs of the input current information. The top four bits of the second read return the four LSBs of the input current information. The range of the CS1 input pin is from 0 V to 1.4 V. This value has 12 bits of resolution, which results in an LSB size of 342 μV. At 0 V input, the value in this register is 0 (0x000). At 1 V input, the value in this register is 2926 (0xB6E). Reserved. Table 20. Register 0x14—ACSNS Value Bits [15:4] [3:0] Bit Name ACSNS voltage value Reserved R/W R R Description This register contains the 12-bit ACSNS slow ADC voltage information. Reserved. Table 21. Register 0x15—VS1 Voltage Value Bits [15:4] Bit Name VS1 voltage value R/W R [3:0] Reserved R Description This register contains the 12-bit local output voltage information. This voltage is measured at the VS1 pin. To read the VS1 voltage information, this register must be read using two consecutive read operations. The eight bits of the first read return the eight MSBs of the local output voltage information. The top four bits of the second read return the four LSBs of the local output voltage information. The range of the VS1 input pin is from 0 V to 1.6 V. This value has 12 bits of resolution, which results in an LSB size of 390.625 μV. At 0 V input, the value in this register is 0 (0x000). The recommended nominal voltage at this pin is 1 V. At 1 V input, these bits read 2560 (0xA00). Reserved. Table 22. Register 0x16—VS2 Voltage Value Bits [15:4] Bit Name VS2 voltage value R/W R [3:0] Reserved R Description This register contains the 12-bit load output voltage information. This voltage is measured at the VS2 pin. To read the load VS2 voltage information, this register must be read using two consecutive read operations. The eight bits of the first read return the eight MSBs of the load output voltage information. The top four bits of the second read return the four LSBs of the load output voltage information. The range of the VS2 input pin is from 0 V to 1.6 V. This value has 12 bits of resolution, which results in an LSB size of 390.625 μV. At 0 V input, the value in this register is 0 (0x000). The recommended nominal voltage at this pin is 1 V. At 1 V input, these bits read 2560 (0xA00). Reserved. Table 23. Register 0x17—VS3 Voltage Value (Output Voltage) Bits [15:4] Bit Name VS3 voltage value R/W R [3:0] Reserved R Description This register contains the 12-bit remote output voltage information. This value is the differential voltage between the VS3+ and VS3− pins. To read the remote output voltage information, this register must be read using two consecutive read operations. The eight bits of the first read return the eight MSBs of the remote output voltage information. The top four bits of the second read return the four LSBs of the remote output voltage information. The range of the VS3± input pins is from 0 V to 1.6 V. This value has 12 bits of resolution, which results in an LSB size of 390.625 μV. At 0 V input, the value in this register is 0 (0x000). The recommended nominal voltage at this pin is 1 V. At 1 V input, these bits read 2560 (0xA00). Reserved. Rev. 0 | Page 53 of 96 ADP1046 Data Sheet Table 24. Register 0x18—CS2 Value (Output Current) Bits [15:4] Bit Name Output current value R/W R [3:0] Reserved R Description This register contains the 12-bit output current information. This value is the voltage drop across the sense resistor. To obtain the current value, the user must divide the value of this register by the sense resistor value (see the CS2+, CS2− Pins section). The CS2± pins have a full-scale input range of 120 mV or 60 mV (set in Register 0x27[5]). This value has 12 bits of resolution; the LSB step size depends on the input range value. When the CS2 input range is set to 120 mV, the LSB step size is 29.30 μV. For example, at a 30 mV input signal on CS2, the value in this register is 30 mV/29.30 μV = 1024 (0x400). When the CS2 input range is set to 60 mV, the LSB step size is 14.65 μV. For example, at a 30 mV input signal on CS2, the value in this register is 30 mV/14.65 μV = 2048 (0x800). Reserved. Table 25. Register 0x19—CS2 × VS3 Value (Output Power) Bits [15:0] Bit Name Output power value R/W R Description This register contains the 16-bit output power information. This value is the product of the remote output voltage value (VS3) and the output current reading (CS2). See the Power Readings section for the formulas needed to convert this digital reading into power information. Table 26. Register 0x1A—RTD Temperature Value Bits [15:4] Bit Name Temperature value R/W R [3:0] Reserved R Description This register contains the 12-bit output temperature information, as determined from the RTD pin. The range of the RTD pin is from 0 V to 1.6 V. This value has 12 bits of resolution, which results in an LSB size of 390.625 μV. At 0 V input, the value in this register is 0 (0x000). The recommended nominal voltage at this pin is 1 V. At 1 V input, these bits read 2560 (0xA00). Reserved. Table 27. Register 0x1B—Read Temperature Bits [7:0] Bit Name Read temperature R/W R/W Description This register returns an 8-bit temperature in °C (unsigned decimal format). For this feature to function correctly, the external thermistor must be 100 kΩ with a 16.5 kΩ, 1% resistor in parallel, and the selected current source must be trimmed to 46 μA by selecting 40 μA in Register 0x11[7:6] and using the current trim (fine-trim) bits in Register 0x11[5:0]. Table 28. Register 0x1C—RTD Offset Trim (MSB) Bits [7:2] 1 Bit Name Reserved Trim polarity R/W R R/W 0 RTD offset trim (MSB) R/W Description Reserved. Setting this bit to 1 means that negative offset is introduced. Setting this bit to 0 means that positive offset is introduced. This bit is the MSB of the RTD offset trim. Together with Register 0x20 (the LSBs), this bit sets the amount of offset trim that is applied to the RTD ADC reading. Table 29. Register 0x1D—Share Bus Value Bits [7:0] Bit Name Share bus value R/W R Description This register contains the 8-bit share bus voltage information. If the power supply is the master, this register outputs 0. Table 30. Register 0x1E—Modulation Value Bits [7:0] Bit Name Modulation value R/W R Description This register contains the 8-bit modulation information. It outputs the amount of modulation from 0% to 100% that is being placed on the modulating edges. Table 31. Register 0x1F—Line Impedance Value Bits [7:0] Bit Name Line impedance value R/W R Description This register contains the 8-bit line impedance information. This value is (VS2 − VS3)/CS2. Rev. 0 | Page 54 of 96 Data Sheet ADP1046 Table 32. Register 0x20—RTD Offset Trim (LSBs) Bits [7:0] Bit Name RTD offset trim (LSBs) R/W R/W Description These eight bits, together with Register 0x1C[0] (the MSB), set the amount of offset trim that is applied to the RTD ADC reading. CURRENT SENSE AND CURRENT LIMIT REGISTERS Table 33. Register 0x21—CS1 Gain Trim Bits 7 Bit Name Gain polarity R/W R/W [6:0] CS1 gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This value calibrates the primary side current sense gain. See the CS1 Trim section for more information. Table 34. Register 0x22—CS1 Accurate OCP Limit Bits [7:5] Bit Name CS1 fast OCP blanking R/W R/W [4:0] CS1 accurate OCP R/W Description These bits determine the blanking time for CS1 before fast OCP is enabled. This time is measured from the start of a switching cycle. If using OUTAUX, the time is synchronized with the rising edge of OUTAUX. Bit 7 Bit 6 Bit 5 Delay (ns) 0 0 0 0 0 0 1 40 0 1 0 80 0 1 1 120 1 0 0 200 1 0 1 400 1 1 0 600 1 1 1 800 These bits set the CS1 accurate OCP threshold. The digital word that is output from the CS1 ADC is compared with this threshold. If the CS1 ADC reading (Register 0x13) is greater than the OCP threshold set by these bits, the CS1 accurate OCP flag is set. This value should be programmed only after the CS1 trim has been performed. The range of these bits is from 0 to 31, that is, 0 V to 1.4 V in 43.75 mV steps. The following equation gives the CS1 accurate OCP threshold: CS1_OCP_Threshold = (CS1_OCP_Limit × 1.4 V/32) + 16 × 1.4/212 Table 35. Register 0x23—CS2 Gain Trim Bits [7:6] 5 Bit Name Reserved Gain polarity R/W R/W R/W [4:0] CS2 gain trim R/W Description Reserved. 1 = negative gain is introduced. 0 = positive gain is introduced. This register calibrates the secondary side (CS2) current sense gain. It calibrates for errors in the sense resistor. See the CS2 Trim section for more information. Table 36. Register 0x24—CS2 Analog Offset Trim Bits 7 6 Bit Name Reserved Offset polarity R/W R/W R/W [5:0] CS2 offset trim R/W Description Reserved. 1 = negative offset is introduced. 0 = positive offset is introduced. This register calibrates the secondary side (CS2) current sense common-mode error. It calibrates for errors in the resistor divider network. See the CS2 Trim section for more information. Rev. 0 | Page 55 of 96 ADP1046 Data Sheet Table 37. Register 0x25—CS2 Digital Offset Trim Bits [7:0] Bit Name CS2 digital offset trim R/W R/W Description This register contains the CS2 digital trim level. This value is used to calibrate the CS2 value that is read in Register 0x18. See the CS2 Trim section for more information. Table 38. Register 0x26—CS2 Accurate OCP Limit Bits [7:0] Bit Name CS2 accurate OCP R/W R/W Description This register sets the CS2 accurate OCP current level. This 8-bit number is compared to the CS2 value register (Register 0x18). When the CS2 value register is greater than the value in this register, the CS2 accurate OCP flag is set. The following equation gives the CS2 accurate OCP threshold: CS2_OCP_Threshold = CS2_OCP_Limit × (ADC_Range)/256 + 16 × (ADC_Range)/212 Table 39. Register 0x27—CS1/CS2 Fast OCP Settings Bits [7:6] Bit Name CS1 fast OCP debounce R/W R/W 5 CS2 nominal voltage drop R/W 4 3 CS1 fast OCP bypass Constant current mode R/W R/W 2 CS2 current sensing R/W [1:0] CS1 fast OCP timeout R/W Description These bits set the CS1 fast OCP debounce value. This is the minimum time that the CS1 signal must be constantly above the fast OCP limit before the PWM outputs are shut down. When this happens, all PWM outputs are disabled for the remainder of the switching cycle. Bit 7 Bit 6 Debounce (ns) 0 0 0 0 1 40 1 0 80 1 1 120 These bits set the nominal full-scale voltage drop across the sense resistor. See the CS2 Trim section for more information. These bits set the LSB step size of the CS2 ADC. Bit 5 ADC Range (mV) LSB Step Size (μV) 0 60 14.65 1 120 29.30 Setting this bit to 1 means that the FLAGIN pin is used for CS1 fast OCP instead of the CS1 pin. When this bit is set, constant current mode is enabled to 97% of the CS2 accurate OCP limit. 1 = constant current mode enabled. 0 = constant current mode disabled. This bit is set high if high-side current sensing is used. This bit is set low if low-side current sensing is used. See the CS2 Trim section for more information. If the CS1 fast OCP comparator is set, all PWM outputs that are on at that time are immediately disabled for the remainder of the switching cycle. The PWM outputs resume normal operation at the beginning of the next switching cycle. These bits set the number of consecutive switching cycles for the comparator before the CS1 fast OCP response is activated. Bit 1 Bit 0 Number of Switching Cycles 0 0 1 0 1 62 1 0 188 1 1 440 Table 40. Register 0x28—Volt-Second Balance Settings Bits 7 6 5 4 3 Bit Name Reserved Volt-second balance enable Volt-second balance leading edge blanking R/W R/W R/W Volt-second disable during soft start 50% blanking of each phase R/W R/W R/W Description Reserved. Setting this bit enables volt-second balance for the main transformer (used for full-bridge configurations). For more information, see the Volt-Second Balance section. Setting this bit means that CS1 is blanked for volt-second balance calculations at the rising edge of the PWM outputs that are selected for volt-second balance. The blanking value is the same value configured for CS1 fast OCP blanking in Register 0x22[7:5]. 0 = do not blank volt-second balance control during soft start. 1 = blank volt-second balance control during soft start. Setting this bit limits the sampling period for the current on CS1 to less than 50% of a half cycle. Rev. 0 | Page 56 of 96 Data Sheet ADP1046 Bits 2 Bit Name Volt-second balance modulation R/W R/W [1:0] Volt-second balance gain setting R/W Description This bit specifies the maximum amount of modulation from volt-second balance. 0 = ±80 ns maximum. 1 = ±160 ns maximum. These bits set the gain of the volt-second balance circuit. The gain can be changed by a factor of 64. When these bits are set to 00, it takes approximately 700 ms to achieve volt-second balance. When these bits are set to 11, it takes approximately 10 ms to achieve volt-second balance. Bit 1 Bit 0 Volt-Second Balance Gain 0 0 1 0 1 4 1 0 16 1 1 64 Table 41. Register 0x29—Share Bus Bandwidth Bits [7:5] 4 Bit Name Reserved Bit stream R/W R/W R/W 3 Current share select R/W [2:0] Share bus bandwidth R/W Description Reserved. 1 = the current sense ADC reading is output on the SHAREo pin. This bit stream can be used for analog current sharing. 0 = the digital share bus signal is output on the SHAREo pin. This signal can be used for digital current sharing. 1 = CS1 reading used for current share. 0 = CS2 reading used for current share. These bits determine the amount of bandwidth dedicated to the share bus. The value 000 is the lowest possible bandwidth, and the value 111 is the highest possible bandwidth. Table 42. Register 0x2A—Share Bus Setting Bits [7:4] [3:0] Bit Name Number of bits dropped by master Bit difference between master and slave R/W R/W Description These bits determine how much a master device reduces its output voltage to maintain current sharing. These bits determine how closely a slave tries to match the current of the master device. The higher the setting, the larger the voltage difference that satisfies the current sharing criteria. R/W Table 43. Register 0x2B—Temperature Gain Trim Bits 7 Bit Name Gain polarity R/W R/W [6:0] Gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. This register calibrates the RTD ADC gain. It calibrates for errors in the ADC. Table 44. Register 0x2C—PSON/Soft Start Bits [7:6] Bit Name PS_ON setting R/W R/W 5 PS_ON R/W [4:3] PS_ON delay R/W Description These bits determine which signal is used by the ADP1046 as the PS_ON control. Bit 7 Bit 6 PS_ON Setting 0 0 The ADP1046 is always on. 0 1 Hardware PSON pin is used to enable or disable the power supply. 1 0 Software PS_ON bit (Bit 5) is used to enable or disable the power supply. 1 1 Both the software PS_ON bit and the hardware PSON pin must be enabled before the ADP1046 is enabled. Software PS_ON bit. 0 = power supply off. 1 = power supply on. These bits set the time from when the PS_ON control signal is set to when the soft start begins. Bit 4 Bit 3 Typical Delay (sec) 0 0 0 0 1 0.5 1 0 1 1 1 2 Rev. 0 | Page 57 of 96 ADP1046 Data Sheet Bits 2 1 Bit Name Reserved Disable light load during soft start R/W R/W R/W 0 Force soft start filter R/W Description Set this bit to zero for normal operation. 0 = allow switching to light load mode filter during soft start. 1 = never switch to light load mode filter during soft start. 0 = use normal mode filter or soft start filter, depending on the OrFET status. If regulating from VS3 (OrFET on), the normal mode filter is used. If regulating from VS1 (OrFET off ), the soft start filter is used. 1 = use soft start filter as the initial filter regardless of OrFET status. Table 45. Register 0x2D—PGOOD Debounce and Pin Polarity Settings Bits [7:6] Bit Name PGOOD1 turn-on debounce R/W R/W [5:4] PGOOD2 turn-on debounce R/W 3 PGOOD2 flags R/W 2 1 0 FLAGIN polarity GATE polarity PSON polarity R/W R/W R/W Description These bits set the debounce time before the PGOOD1 pin and flag are set. This debounce time starts at the end of the soft start ramp and can vary by ±50 ms. The turn-off of PGOOD1 is always immediate (no debounce). Bit 7 Bit 6 Typical Debounce Time (ms) 0 0 350 0 1 150 1 0 550 1 1 0 These bits set the debounce time before the PGOOD2 pin and flag are set. This debounce time starts at the end of the soft start ramp and can vary by ±50 ms. The turn-off of PGOOD2 is always immediate (no debounce). Bit 5 Bit 4 Typical Delay Time (ms) 0 0 350 0 1 150 1 0 550 1 1 0 The following flags can also set the PGOOD2 pin: voltage continuity, OrFET disable, ACSNS, FLAGIN, and OTP. This bit specifies whether these flags unconditionally set PGOOD2 or whether these flags set PGOOD2 only if the flag action is not set to ignore (Bits[6:4] = 000) in the appropriate fault configuration register (see Table 12 and Table 13). 0 = voltage continuity, OrFET disable, ACSNS, FLAGIN, and OTP flags always set the PGOOD2 pin. 1 = voltage continuity, OrFET disable, ACSNS, FLAGIN, and OTP flags set the PGOOD2 pin only if the flag action is not set to “ignore.” This bit sets the polarity of the FLAGIN input pin: 1 = inverted (low = 0 V = on). This bit sets the polarity of the OrFET GATE control pin: 1 = inverted (low = 0 V = on). This bit sets the polarity of the PSON input pin: 1 = inverted (low = 0 V = on). Table 46. Register 0x2E—Modulation Limit Bits 7 [6:0] Bit Name Full-bridge mode Modulation limits R/W R/W R/W Description Enable this bit when operating in full-bridge mode. It affects the modulation high limit. This value sets the minimum/maximum modulation limits relative to the nominal edge value. The resolution depends on the switching frequency range. Switching Frequency Range Resolution Corresponding to LSB 48.8 kHz to 86.8 kHz 160 ns 97.7 kHz to 183.8 kHz 80 ns 195 kHz to 378.8 kHz 40 ns 390.6 kHz to 625.0 kHz 20 ns Rev. 0 | Page 58 of 96 Data Sheet ADP1046 Table 47. Register 0x2F—OTP Threshold Bits [7:0] Bit Name OTP threshold R/W R/W Description This register, adding 0 as the MSB, results in a 9-bit OTP 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 OTP flag is set. This 8-bit register provides 256 threshold settings from 0 mV to 800 mV. One LSB equates to 800 mV/256 = 3.125 mV. Some of the threshold settings at the high and low ends of the range are not allowed. The OTP flag has a hysteresis of 16 mV. … Bit 7 Bit 6 Bit 3 Bit 2 Bit 1 Bit 0 OTP Limit (mV) 0 0 … 0 0 0 0 0 0 0 … 0 0 0 1 3.125 0 0 … 0 0 1 0 6.25 0 0 … 0 0 1 1 9.375 0 0 … 0 1 0 0 12.5 0 0 … 0 1 0 1 15.625 … … … … … … … … 1 1 … 1 0 0 1 778.125 1 1 … 1 0 1 0 781.25 … … … … … … … 1 1 … 1 1 1 1 796.875 Table 48. Register 0x30—OrFET Bits 7 Bit Name OrFET enable delay OrFET enable threshold R/W R/W [4:2] Fast OrFET threshold R/W 1 Fast OrFET debounce R/W 0 Fast OrFET bypass R/W [6:5] R/W Description 0 = delay of 328 μs, equivalent to 9 bits of (VS1 − VS2) data. 1 = delay of 164 μs, equivalent to 8 bits of (VS1 − VS2) data. These bits program the voltage difference between VS1 and VS2 before the OrFET is enabled. The VS1 and VS2 input pins are used to control the OrFET enable function. ADC Full-Scale Voltage Difference from VS1 to VS2 Bit 6 Bit 5 VOUT = 48 V (mV) Range (%) VOUT = 12 V (mV) 0 0 −2 −384 −1504 0 1 −1 −192 −752 1 0 −0.5 −96 −376 1 1 0 0 0 These bits program the threshold voltage difference between CS2+ and CS2− at which the OrFET is disabled. The CS2+ and CS2− input pins are used to control this function. The internal circuit is an analog comparator. Bit 4 Bit 3 Bit 2 Voltage Difference from CS2+ to CS2− (mV) 0 0 0 −3 0 0 1 −6 0 1 0 −9 0 1 1 −12 1 0 0 −15 1 0 1 −18 1 1 0 −21 1 1 1 −24 These bits determine the debounce on the fast OrFET control before it disables the OrFET. 0 = 40 ns. 1 = 200 ns. Set this bit to completely bypass fast OrFET control. The action programmed for the OrFET flag is executed, unless the flag is programmed to be ignored. Rev. 0 | Page 59 of 96 ADP1046 Data Sheet VOLTAGE SENSE REGISTERS Table 49. Register 0x31—VS3 Voltage Setting (Remote Voltage) Bits [7:0] Bit Name VS3 voltage setting R/W R/W Description This register is used to set the output voltage (voltage differential at the VS3+ and VS3− pins). This value is programmable from 0% to 150% of the nominal voltage. Each LSB corresponds to a 0.6% increase. Setting this register to a value of 0xA0 gives an output voltage setting of 100% of the nominal voltage. This is the default value that is stored in this register when the part is shipped from the factory. Updating the VS3 voltage setting is a two-stage process. The user must first change the value in this register; this information is stored in a shadow register. To latch the new VS3 voltage setting into the state machine, the user must set the voltage reference GO bit (Register 0x7F[0]). After that, the voltage changes with a limited slew rate (programmed in Register 0x5F[2:0]). Table 50. Register 0x32—VS1 Overvoltage Limit (OVP) Bits [7:3] Bit Name VS1 OVP setting R/W R/W 2 [1:0] Reserved OVP sampling R/W R/W Description Local overvoltage limit. This limit is programmable from 111.25% to 150% of the nominal VS1 voltage; 0x00 corresponds to 111.2%. Each LSB results in an increase of 1.25%. The VS1 OVP threshold is calculated as follows: VS1_OVP_Threshold = [(89 + VS1_OVP_Setting)/128] × 1.6 V For example, if the VS1 OVP setting is 10, then VS1_OVP_Threshold = [(89 + 10)/128] × 1.6 V = 1.2375 V Setting these bits to 0 gives an OVP limit of 111.25% of the nominal VS1 voltage. Setting these bits to 7 gives an OVP limit of 120% of the nominal VS1 voltage. Setting these bits to 15 gives an OVP limit of 130% of the nominal VS1 voltage. Setting these bits to 31 gives an OVP limit of 150% of the nominal VS1 voltage. Reserved. The OVP flag is set if the average voltage during the OVP sampling period is greater than the OVP threshold. This OVP flag sampling period is 80 μs. The number of samples can be increased using these bits. If the number of samples is increased, the average voltage must be greater than the OVP threshold for each of those cycles. For example, if this value is set to two cycles, the average voltage must be greater than the OVP threshold for both cycles. Bit 1 Bit 0 Additional Sampling (μs) 0 0 0 (one sample sets the OVP flag) 0 1 80 (two samples set the OVP flag) 1 0 160 (three samples set the OVP flag) 1 1 240 (four samples set the OVP flag) Table 51. Register 0x33—VS2 and VS3 Overvoltage Limit (OVP) Bits [7:3] Bit Name VS2 and VS3 OVP setting R/W R/W 2 Regulating point R/W Description Local overvoltage limit. This limit is programmable from 111.25% to 150% of the nominal VSx voltage; 0x00 corresponds to 111.2%. Each LSB results in an increase of 1.25%. The VSx OVP threshold is calculated as follows: VSx_OVP_Threshold = [(89 + VSx_OVP_Setting)/128] × 1.6 V For example, if the VS2 OVP setting is 10, then VS2_OVP_Threshold = [(89 + 10)/128] × 1.6 V = 1.2375 V Setting these bits to 0 gives an OVP limit of 111.25% of the nominal VSx voltage. Setting these bits to 7 gives an OVP limit of 120% of the nominal VSx voltage. Setting these bits to 15 gives an OVP limit of 130% of the nominal VSx voltage. Setting these bits to 31 gives an OVP limit of 150% of the nominal VSx voltage. When this bit is set, the ADP1046 regulates from the VS3 node at all times. When this bit is not set, the ADP1046 uses the VS1 voltage as the regulating point during soft start and when the OrFET is disabled. Rev. 0 | Page 60 of 96 Data Sheet Bits [1:0] Bit Name OVP sampling ADP1046 R/W R/W Description The OVP flag is set if the average voltage during the OVP sampling period is greater than the OVP threshold. This OVP flag sampling period is 80 μs. The number of samples can be increased using these bits. If the number of samples is increased, the average voltage must be greater than the OVP threshold for each of those cycles. For example, if this value is set to two cycles, the average voltage must be greater than the OVP threshold for both cycles. Bit 1 Bit 0 Additional Sampling (μs) 0 0 0 (one sample sets the OVP flag) 0 1 80 (two samples set the OVP flag) 1 0 160 (three samples set the OVP flag) 1 1 240 (four samples set the OVP flag) Table 52. Register 0x34—VS1 Undervoltage Limit (UVP) Bits 7 Bit Name End of cycle shutdown R/W R/W [6:0] VS1 UVP setting R/W Description This bit is valid only when the OUTAUX pin is used for regulation. When any flag shuts down the power supply, the OUTAUX PWM is immediately shut down. This bit specifies when the other PWM outputs are shut down. 1 = all other PWM outputs are shut down at the end of the switching cycle. 0 = all other PWM outputs are immediately shut down. These bits set the UVP limit to one of 128 settings. The UVP limit can be programmed from 0% to 158.75% of the nominal VS1 voltage. Each LSB increases the voltage by 158.75%/128 = 1.25%. In reality, there are 81 usable settings, which program the UVP threshold from 0% to 100% of the nominal VS1 voltage. The VS1 UVP threshold is calculated as follows: VS1_UVP_Threshold = [(VS1_UVP_Setting + 1)/128] × 1.6 V − 12.5 mV For example, if the VS1 UVP setting is 60, then VS1_UVP_Threshold = [(60 + 1)/128] × 1.6 V − 12.5 mV = 750 mV Setting these bits to 0 gives a UVP limit of 0% of the nominal VS1 voltage. Setting these bits to 72 (0x48) gives a UVP limit of 90% of the nominal VS1 voltage. Setting these bits to 76 (0x4C) gives a UVP limit of 95% of the nominal VS1 voltage. Setting these bits to 80 (0x50) gives a UVP limit of 100% of the nominal VS1 voltage. Setting these bits to 127 (0x7F) gives a UVP limit of 158.75% of the nominal VS1 voltage. Table 53. Register 0x35—Line Impedance Limit Bits [7:0] Bit Name Line impedance limit R/W R/W Description This value sets the threshold at which the line impedance flag is enabled. This 8-bit value is compared with the line impedance value (Register 0x1F). If the line impedance value exceeds this value, the line impedance flag is set (Register 0x02, Bit 2). Table 54. Register 0x36—Load Line Impedance Bits 7 [6:4] Bit Name Load line enable Slew rate R/W R/W R/W 3 Reserved R/W Description Set this bit to enable the load line. These bits set the load line slew rate limit, which determines the maximum slew rate for changing the reference when adjusting the output load line value. Bit 6 Bit 5 Bit 4 Maximum Slew Rate Duration 0 0 0 200 mV/ms 0 0 1 100 mV/ms 0 1 0 50 mV/ms 0 1 1 25 mV/ms 1 0 0 12.5 mV/ms 1 0 1 6.25 mV/ms 1 1 0 3.125 mV/ms 1 1 1 1.5625 mV/ms (4 LSB/ms) Reserved. Rev. 0 | Page 61 of 96 ADP1046 Bits [2:0] Bit Name Load line setting Data Sheet R/W R/W Description These bits specify how much the output voltage decreases from nominal at full load. The amount of output resistance introduced can be calculated as follows (these bits specify the value of N): ROUT = 0.1 × VOUT_NOM × CS2 RSENSE/(CS2 Range × 2N). For more information, see the Digital Load Line and Slew Rate section. Bit 2 Bit 1 Bit 0 Impedance Setting 0 0 0 Setting 0 0 0 1 Setting 1 0 1 0 Setting 2 0 1 1 Setting 3 1 0 0 Setting 4 1 0 1 Setting 5 1 1 0 Setting 6 1 1 1 Setting 7 Table 55. Register 0x37—Fast OVP Comparator Bits [7:6] Bit Name Fast OVP debounce R/W R/W [5:0] Fast OVP threshold R/W Description These bits set the fast OVP debounce time. Debounce Time (μs) Bit 7 Bit 6 Min Typ Max 0 0 0 0 0 0 1 0.64 0.96 1.28 1 0 1.92 2.24 2.56 1 1 7.98 8 8.32 These bits set the threshold for the fast OVP analog comparator. This threshold is programmable from 0.8 V to 1.6 V. Setting this value to 0x00 corresponds to a 0.8 V threshold. Setting this value to 0x3F corresponds to a 1.6 V threshold. Each LSB increments the threshold by 12.5 mV. The fast OVP threshold can be set using the following formula: Fast_OVP_Threshold = (Bits[5:0] × 0.8 V/63) + 0.8 V Table 56. Register 0x38—VS1 Trim Bits 7 Bit Name Trim polarity R/W R/W [6:0] VS1 trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. These bits set the amount of gain trim that is applied to the VS1 ADC reading. This register trims the voltage at the VS1 pin for external resistor tolerances. When there is 1 V on the VS1 pin, this register is trimmed until the VS1 voltage value (Register 0x15[15:4]) reads 2560 (0xA00). Table 57. Register 0x39—VS2 Trim Bits 7 Bit Name Trim polarity R/W R/W [6:0] VS2 trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. These bits set the amount of gain trim that is applied to the VS2 ADC reading. This register trims the voltage at the VS2 pin for external resistor tolerances. When there is 1 V on the VS2 pin, this register is trimmed until the VS2 voltage value (Register 0x16[15:4]) reads 2560 (0xA00). Table 58. Register 0x3A—VS3 Trim Bits 7 Bit Name Trim polarity R/W R/W [6:0] VS3 trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. These bits set the amount of gain trim that is applied to the VS3 ADC reading. This register trims the voltage at the VS3 pins for external resistor tolerances. When there is 1 V on each VS3 pin, this register is trimmed until the VS3 voltage value (Register 0x17[15:4]) reads 2560 (0xA00). The VS3 trim must be performed before the load OVP and load UVP trims are performed. Rev. 0 | Page 62 of 96 Data Sheet ADP1046 Table 59. Register 0x3B—Light Load Mode Disable Settings Bits 7 Bit Name Disable OUTAUX R/W R/W 6 Disable OUTD R/W 5 Disable OUTC R/W 4 Disable OUTB R/W 3 Disable OUTA R/W [2:0] Light load SR disable R/W Description Setting this bit means that OUTAUX is also disabled if the load current falls below the light load SR disable threshold. Setting this bit means that OUTD is also disabled if the load current falls below the light load SR disable threshold. Setting this bit means that OUTC is also disabled if the load current falls below the light load SR disable threshold. Setting this bit means that OUTB is also disabled if the load current falls below the light load SR disable threshold. Setting this bit means that OUTA is also disabled if the load current falls below the light load SR disable threshold. These bits set the load current limit on the CS2 ADC below which the synchronous rectifier outputs (SR1 and SR2) are disabled. This value also determines the point at which the power supply goes into light load mode and the light load mode filter is used. This value is programmable as a percentage of the CS2 ADC full scale (either 60 mV or 120 mV). The hysteresis and the averaging speed are programmable in Register 0x7D. Light Load Threshold as % of Full Scale Bit 2 Bit 1 Bit 0 37.5 μs 75 μs 150 μs 300 μs 0 0 0 0% 0% 0% 0% 0 0 1 7.81% 3.91% 1.95% 0.98% 0 1 0 15.63% 7.81% 3.91% 1.95% 0 1 1 23.44% 11.72% 5.86% 2.93% 1 0 0 31.25% 15.63% 7.81% 3.91% 1 0 1 39.06% 19.53% 9.77% 4.88% 1 1 0 46.88% 23.44% 11.72% 5.86% 1 1 1 54.69% 27.34% 13.67% 6.84% ID REGISTERS Table 60. Register 0x3C—Silicon Revision ID Bits [7:0] Bit Name Silicon revision R/W R Description This register contains the manufacturer’s silicon revision code for the device. This value is used by the manufacturer for tracking purposes. Table 61. Register 0x3D—Manufacturer ID (Power-On Default: 0x41) Bits [7:0] Bit Name Manufacturer ID code R/W R Description This register contains the manufacturer’s ID code for the device. It is used by the manufacturer for test purposes and should not be read from in normal operation. This value is hardwired to 0x41 to represent the Analog Devices ID code. Table 62. Register 0x3E—Device ID (Power-On Default: 0x46) Bits [7:0] Bit Name Device ID code R/W R Description This register contains the ID code for the device. This value is hardwired to 0x46 to represent the ADP1046. Rev. 0 | Page 63 of 96 ADP1046 Data Sheet PWM AND SYNCHRONOUS RECTIFIER TIMING REGISTERS Figure 56 and Table 63 to Table 93 describe the implementation and programming of the seven PWM signals that are output from the ADP1046. In general, it is recommended that t1 be set to 0 and that t1 be set as the reference point for the other signals. t2 PWM1 (OUTA) t1 t4 PWM2 (OUTB) t3 t5 PWM3 (OUTC) t6 t8 PWM4 (OUTD) t7 t10 SYNC RECT 1 (SR1) t9 SYNC RECT 2 (SR2) t12 t11 t13 t14 tPERIOD tPERIOD 10045-035 PWM5 (OUTAUX) Figure 56. PWM Timing Diagram Table 63. Register 0x3F—OUTAUX Switching Frequency Setting Bits 7 Bit Name Pulse skipping R/W R/W 6 Pulse skipping zero PWM Switching frequency R/W [5:0] R/W Description Setting this bit enables pulse skipping mode. If the ADP1046 requires a duty cycle lower than the modulation low limit, pulse skipping is enabled. 0 = pulse skipping drives all modulated PWM outputs to 0 V. 1 = sets all modulated edges to t = 0 (the crossing rule set in Register 0x52[0] applies). This register sets the switching frequency of the OUTAUX signal. Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Frequency (kHz) 0 0 0 0 0 0 48.83 0 0 0 0 0 1 50.40 52.08 0 0 0 0 1 0 0 0 0 0 1 1 53.88 0 0 0 1 0 0 55.80 0 0 0 1 0 1 57.87 0 0 0 1 1 0 60.1 0 0 0 1 1 1 62.5 0 0 1 0 0 0 65.1 0 0 1 0 0 1 67.93 0 0 1 0 1 0 71.02 0 0 1 0 1 1 74.4 0 0 1 1 0 0 78.13 0 0 1 1 0 1 82.24 0 0 1 1 1 0 86.81 0 0 1 1 1 1 91.91 0 1 0 0 0 0 97.66 0 1 0 0 0 1 100.81 0 1 0 0 1 0 104.17 Rev. 0 | Page 64 of 96 Data Sheet Bits [5:0] Bit Name Switching frequency ADP1046 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 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 Bit 3 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 0 0 0 0 0 0 0 Bit 2 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 Rev. 0 | Page 65 of 96 Bit 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 Bit 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 Frequency (kHz) 107.76 111.61 115.74 120.19 125.0 130.21 135.87 142.05 148.81 156.25 164.47 173.61 183.82 195.31 201.61 208.33 215.52 223.21 231.48 240.38 250 260.42 271.42 284.09 297.62 312.5 328.95 347.22 367.65 390.63 416.67 446.43 480.77 520.83 568.18 625 ADP1046 Data Sheet Table 64. Register 0x40—PWM Switching Frequency Setting Bits [7:6] [5:0] Bit Name Reserved Switching frequency R/W R/W R/W Description Reserved. This register sets the switching frequency of all the PWM pins other than the OUTAUX pin. Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Frequency (kHz) 0 0 0 0 0 0 48.83 0 0 0 0 0 1 50.40 0 0 0 0 1 0 52.08 0 0 0 0 1 1 53.88 0 0 0 1 0 0 55.80 0 0 0 1 0 1 57.87 0 0 0 1 1 0 60.1 0 0 0 1 1 1 62.5 0 0 1 0 0 0 65.1 0 0 1 0 0 1 67.93 0 0 1 0 1 0 71.02 0 0 1 0 1 1 74.4 0 0 1 1 0 0 78.13 0 0 1 1 0 1 82.24 0 0 1 1 1 0 86.81 0 0 1 1 1 1 91.91 0 1 0 0 0 0 97.66 0 1 0 0 0 1 100.81 0 1 0 0 1 0 104.17 0 1 0 0 1 1 107.76 0 1 0 1 0 0 111.61 0 1 0 1 0 1 115.74 0 1 0 1 1 0 120.19 0 1 0 1 1 1 125.0 0 1 1 0 0 0 130.21 0 1 1 0 0 1 135.87 0 1 1 0 1 0 142.05 0 1 1 0 1 1 148.81 0 1 1 1 0 0 156.25 0 1 1 1 0 1 164.47 0 1 1 1 1 0 173.61 0 1 1 1 1 1 183.82 1 0 0 0 0 0 195.31 1 0 0 0 0 1 201.61 1 0 0 0 1 0 208.33 1 0 0 0 1 1 215.52 1 0 0 1 0 0 223.21 1 0 0 1 0 1 231.48 1 0 0 1 1 0 240.38 1 0 0 1 1 1 250 1 0 1 0 0 0 260.42 1 0 1 0 0 1 271.42 1 0 1 0 1 0 284.09 1 0 1 0 1 1 297.62 1 0 1 1 0 0 312.5 1 0 1 1 0 1 328.95 1 0 1 1 1 0 347.22 1 0 1 1 1 1 367.65 1 1 0 0 0 0 390.63 Rev. 0 | Page 66 of 96 Data Sheet Bits [5:0] Bit Name Switching frequency ADP1046 R/W R/W Description Bit 5 Bit 4 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Bit 3 0 0 0 0 0 0 1 Bit 2 0 0 0 1 1 1 1 Bit 1 0 1 1 0 0 1 1 Bit 0 1 0 1 0 1 0 1 Frequency (kHz) 416.67 446.43 480.77 520.83 568.18 625 Resonant mode Table 65. Register 0x41—OUTA Rising Edge Timing (OUTA Pin) Bits [7:0] Bit Name t1 R/W R/W Description This register contains the eight MSBs of the 12-bit t1 time. This value is always used with the top four bits of Register 0x42, which contains the four LSBs of the t1 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 66. Register 0x42—OUTA Rising Edge Setting (OUTA Pin) Bits [7:4] Bit Name t1 R/W R/W 3 Modulate enable R/W 2 t1 sign R/W 1 0 Reserved Volt-second balance source selection R/W R/W Description These bits contain the four LSBs of the 12-bit t1 time. This value is always used with the eight bits of Register 0x41, which contains the eight MSBs of the t1 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t1 edge. 0 = no PWM modulation of the t1 edge. 1 = negative sign. Increase of PWM modulation moves t1 right. 0 = positive sign. Increase of PWM modulation moves t1 left. Reserved. If this bit is set to 1, the OUTA rising edge is selected as the start of the integration period for volt-second balance. Table 67. Register 0x43—OUTA Falling Edge Timing (OUTA Pin) Bits [7:0] Bit Name t2 R/W R/W Description This register contains the eight MSBs of the 12-bit t2 time. This value is always used with the top four bits of Register 0x44, which contains the four LSBs of the t2 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 68. Register 0x44—OUTA Falling Edge Setting (OUTA Pin) Bits [7:4] Bit Name t2 R/W R/W 3 Modulate enable R/W 2 t2 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t2 time. This value is always used with the eight bits of Register 0x43, which contains the eight MSBs of the t2 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t2 edge. 0 = no PWM modulation of the t2 edge. 1 = negative sign. Increase of PWM modulation moves t2 right. 0 = positive sign. Increase of PWM modulation moves t2 left. Reserved. Rev. 0 | Page 67 of 96 ADP1046 Data Sheet Table 69. Register 0x45—OUTB Rising Edge Timing (OUTB Pin) Bits [7:0] Bit Name t3 R/W R/W Description This register contains the eight MSBs of the 12-bit t3 time. This value is always used with the top four bits of Register 0x46, which contains the four LSBs of the t3 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 70. Register 0x46—OUTB Rising Edge Setting (OUTB Pin) Bits [7:4] Bit Name t3 R/W R/W 3 Modulate enable R/W 2 t3 sign R/W 1 0 Reserved Volt-second balance source selection R/W R/W Description These bits contain the four LSBs of the 12-bit t3 time. This value is always used with the eight bits of Register 0x45, which contains the eight MSBs of the t3 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t3 edge. 0 = no PWM modulation of the t3 edge. 1 = negative sign. Increase of PWM modulation moves t3 right. 0 = positive sign. Increase of PWM modulation moves t3 left. Reserved. If this bit is set to 1, the OUTB rising edge is selected as the start of the integration period for volt-second balance. Table 71. Register 0x47—OUTB Falling Edge Timing (OUTB Pin) Bits [7:0] Bit Name t4 R/W R/W Description This register contains the eight MSBs of the 12-bit t4 time. This value is always used with the top four bits of Register 0x48, which contains the four LSBs of the t4 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 72. Register 0x48—OUTB Falling Edge Setting (OUTB Pin) Bits [7:4] Bit Name t4 R/W R/W 3 Modulate enable R/W 2 t4 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t4 time. This value is always used with the eight bits of Register 0x47, which contains the eight MSBs of the t4 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t4 edge. 0 = no PWM modulation of the t4 edge. 1 = negative sign. Increase of PWM modulation moves t4 right. 0 = positive sign. Increase of PWM modulation moves t4 left. Reserved. Table 73. Register 0x49—OUTC Rising Edge Timing (OUTC Pin) Bits [7:0] Bit Name t5 R/W R/W Description This register contains the eight MSBs of the 12-bit t5 time. This value is always used with the top four bits of Register 0x4A, which contains the four LSBs of the t5 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Rev. 0 | Page 68 of 96 Data Sheet ADP1046 Table 74. Register 0x4A—OUTC Rising Edge Setting (OUTC Pin) Bits [7:4] Bit Name t5 R/W R/W 3 Modulate enable R/W 2 t5 sign R/W 1 0 Reserved Volt-second balance source selection R/W R/W Description These bits contain the four LSBs of the 12-bit t5 time. This value is always used with the eight bits of Register 0x49, which contains the eight MSBs of the t5 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t5 edge. 0 = no PWM modulation of the t5 edge. 1 = negative sign. Increase of PWM modulation moves t5 right. 0 = positive sign. Increase of PWM modulation moves t5 left. Reserved. If this bit is set to 1, the OUTC rising edge is selected as the start of the integration period for volt-second balance. Table 75. Register 0x4B—OUTC Falling Edge Timing (OUTC Pin) Bits [7:0] Bit Name t6 R/W R/W Description This register contains the eight MSBs of the 12-bit t6 time. This value is always used with the top four bits of Register 0x4C, which contains the four LSBs of the t6 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 76. Register 0x4C—OUTC Falling Edge Setting (OUTC Pin) Bits [7:4] Bit Name t6 R/W R/W 3 Modulate enable R/W 2 t6 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t6 time. This value is always used with the eight bits of Register 0x4B, which contains the eight MSBs of the t6 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t6 edge. 0 = no PWM modulation of the t6 edge. 1 = negative sign. Increase of PWM modulation moves t6 right. 0 = positive sign. Increase of PWM modulation moves t6 left. Reserved. Table 77. Register 0x4D—OUTD Rising Edge Timing (OUTD Pin) Bits [7:0] Bit Name t7 R/W R/W Description This register contains the eight MSBs of the 12-bit t7 time. This value is always used with the top four bits of Register 0x4E, which contains the four LSBs of the t7 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Rev. 0 | Page 69 of 96 ADP1046 Data Sheet Table 78. Register 0x4E—OUTD Rising Edge Setting (OUTD Pin) Bits [7:4] Bit Name t7 R/W R/W 3 Modulate enable R/W 2 t7 sign R/W 1 0 Reserved Volt-second balance source selection R/W R/W Description These bits contain the four LSBs of the 12-bit t7 time. This value is always used with the eight bits of Register 0x4D, which contains the eight MSBs of the t7 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t7 edge. 0 = no PWM modulation of the t7 edge. 1 = negative sign. Increase of PWM modulation moves t7 right. 0 = positive sign. Increase of PWM modulation moves t7 left. Reserved. If this bit is set to 1, the OUTD rising edge is selected as the start of the integration period for volt-second balance. Table 79. Register 0x4F—OUTD Falling Edge Timing (OUTD Pin) Bits [7:0] Bit Name t8 R/W R/W Description This register contains the eight MSBs of the 12-bit t8 time. This value is always used with the top four bits of Register 0x50, which contains the four LSBs of the t8 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 80. Register 0x50—OUTD Falling Edge Setting (OUTD Pin) Bits [7:4] Bit Name t8 R/W R/W 3 Modulate enable R/W 2 t8 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t8 time. This value is always used with the eight bits of Register 0x4F, which contains the eight MSBs of the t8 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t8 edge. 0 = no PWM modulation of the t8 edge. 1 = negative sign. Increase of PWM modulation moves t8 right. 0 = positive sign. Increase of PWM modulation moves t8 left. Reserved. Table 81. Register 0x51—SR1 Rising Edge Timing (SR1 Pin) Bits [7:0] Bit Name t9 R/W R/W Description This register contains the eight MSBs of the 12-bit t9 time. This value is always used with the top four bits of Register 0x52, which contains the four LSBs of the t9 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. It is recommended that the SR1 rising edge not be set between 80 ns and 115 ns when using the SR soft start. Rev. 0 | Page 70 of 96 Data Sheet ADP1046 Table 82. Register 0x52—SR1 Rising Edge Setting (SR1 Pin) Bits [7:4] Bit Name t9 R/W R/W 3 Modulate enable R/W 2 t9 sign R/W 1 0 Reserved SR soft start edge control R/W R/W Description These bits contain the four LSBs of the 12-bit t9 time. This value is always used with the eight bits of Register 0x51, which contains the eight MSBs of the t9 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. It is recommended that the SR1 rising edge not be set between 80 ns and 115 ns when using the SR soft start. 1 = PWM modulation acts on the t9 edge. 0 = no PWM modulation of the t9 edge. 1 = negative sign. Increase of PWM modulation moves t9 right. 0 = positive sign. Increase of PWM modulation moves t9 left. Reserved. 0 = always allow SR edge crossing. 1 = allow SR edge crossing only during SR soft start (recommended). Table 83. Register 0x53—SR1 Falling Edge Timing (SR1 Pin) Bits [7:0] Bit Name t10 R/W R/W Description This register contains the eight MSBs of the 12-bit t10 time. This value is always used with the top four bits of Register 0x54, which contains the four LSBs of the t10 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 84. Register 0x54—SR1 Falling Edge Setting (SR1 Pin) Bits [7:4] Bit Name t10 R/W R/W 3 Modulate enable R/W 2 t10 sign R/W 1 SR soft start setting R/W 0 SR soft start enable R/W Description These bits contain the four LSBs of the 12-bit t10 time. This value is always used with the eight bits of Register 0x53, which contains the eight MSBs of the t10 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t10 edge. 0 = no PWM modulation of the t10 edge. 1 = negative sign. Increase of PWM modulation moves t10 right. 0 = positive sign. Increase of PWM modulation moves t10 left. 1 = SR signals perform a soft start every time that they are enabled. 0 = SR signals perform a soft start only the first time that they are enabled. Setting this bit enables the soft start function for the SR signals. Table 85. Register 0x55—SR2 Rising Edge Timing (SR2 Pin) Bits [7:0] Bit Name t11 R/W R/W Description This register contains the eight MSBs of the 12-bit t11 time. This value is always used with the top four bits of Register 0x56, which contains the four LSBs of the t11 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. It is recommended that the SR2 rising edge not be set between 80 ns and 115 ns when using the SR soft start. Rev. 0 | Page 71 of 96 ADP1046 Data Sheet Table 86. Register 0x56—SR2 Rising Edge Setting (SR2 Pin) Bits [7:4] Bit Name t11 R/W R/W 3 Modulate enable R/W 2 t11 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t11 time. This value is always used with the eight bits of Register 0x55, which contains the eight MSBs of the t11 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. It is recommended that the SR2 rising edge not be set between 80 ns and 115 ns when using the SR soft start. 1 = PWM modulation acts on the t11 edge. 0 = no PWM modulation of the t11 edge. 1 = negative sign. Increase of PWM modulation moves t11 right. 0 = positive sign. Increase of PWM modulation moves t11 left. Reserved. Table 87. Register 0x57—SR2 Falling Edge Timing (SR2 Pin) Bits [7:0] Bit Name t12 R/W R/W Description This register contains the eight MSBs of the 12-bit t12 time. This value is always used with the top four bits of Register 0x58, which contains the four LSBs of the t12 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Table 88. Register 0x58—SR2 Falling Edge Setting (SR2 Pin) Bits [7:4] Bit Name t12 R/W R/W 3 Modulate enable R/W 2 t12 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t12 time. This value is always used with the eight bits of Register 0x57, which contains the eight MSBs of the t12 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. 1 = PWM modulation acts on the t12 edge. 0 = no PWM modulation of the t12 edge. 1 = negative sign. Increase of PWM modulation moves t12 right. 0 = positive sign. Increase of PWM modulation moves t12 left. Reserved. Table 89. Register 0x59—OUTAUX Rising Edge Timing (OUTAUX Pin) Bits [7:0] Bit Name t13 R/W R/W Description This register contains the eight MSBs of the 12-bit t13 time. This value is always used with the top four bits of Register 0x5A, which contains the four LSBs of the t13 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Depending on the switching frequency and the OUTAUX frequency, there is a constant lag/lead time between this edge and the other edges (t1 to t12); therefore, OUTAUX is not synchronized to the other PWM outputs but can be made synchronous by adjusting the delay accordingly. If either the OUTAUX switching frequency (Register 0x3F) or the PWM switching frequency (Register 0x40) is changed after edge adjustment, the synchronization between OUTAUX and the PWM edges is no longer maintained. The OUTAUX delay must be adjusted again to synchronize the edges to the PWM edges for the new set of switching frequencies. Rev. 0 | Page 72 of 96 Data Sheet ADP1046 Table 90. Register 0x5A—OUTAUX Rising Edge Setting (OUTAUX Pin) Bits [7:4] Bit Name t13 R/W R/W 3 Modulate enable R/W 2 t13 sign R/W [1:0] Reserved R/W Description These bits contain the four LSBs of the 12-bit t13 time. This value is always used with the eight bits of Register 0x59, which contains the eight MSBs of the t13 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Depending on the switching frequency and the OUTAUX frequency, there is a constant lag/lead time between this edge and the other edges (t1 to t12); therefore, OUTAUX is not synchronized to the other PWM outputs but can be made synchronous by adjusting the delay accordingly. If either the OUTAUX switching frequency (Register 0x3F) or the PWM switching frequency (Register 0x40) is changed after edge adjustment, the synchronization between OUTAUX and the PWM edges is no longer maintained. The OUTAUX delay must be adjusted again to synchronize the edges to the PWM edges for the new set of switching frequencies. 1 = PWM modulation acts on the t13 edge. 0 = no PWM modulation of the t13 edge. 1 = negative sign. Increase of PWM modulation moves t13 right. 0 = positive sign. Increase of PWM modulation moves t13 left. Reserved. Table 91. Register 0x5B—OUTAUX Falling Edge Timing (OUTAUX Pin) Bits [7:0] Bit Name t14 R/W R/W Description This register contains the eight MSBs of the 12-bit t14 time. This value is always used with the top four bits of Register 0x5C, which contains the four LSBs of the t14 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Depending on the switching frequency and the OUTAUX frequency, there is a constant lag/lead time between this edge and the other edges (t1 to t12); therefore, OUTAUX is not synchronized to the other PWM outputs but can be made synchronous by adjusting the delay accordingly. If either the OUTAUX switching frequency (Register 0x3F) or the PWM switching frequency (Register 0x40) is changed after edge adjustment, the synchronization between OUTAUX and the PWM edges is no longer maintained. The OUTAUX delay must be adjusted again to synchronize the edges to the PWM edges for the new set of switching frequencies. Table 92. Register 0x5C—OUTAUX Falling Edge Setting (OUTAUX Pin) Bits [7:4] Bit Name t14 R/W R/W 3 Modulate enable R/W 2 t14 sign R/W 1 Regulate with OUTAUX R/W 0 Reserved R/W Description These bits contain the four LSBs of the 12-bit t14 time. This value is always used with the eight bits of Register 0x5B, which contains the eight MSBs of the t14 time. Each LSB corresponds to 5 ns resolution. The entire switching period is divided into 40 ns time steps. If the t_rise and t_fall of a PWM edge occur within the same 40 ns time step, the PWM output is 0 V. If the t_rise and t_fall occur in different 40 ns time steps, the PWM output is set to the programmed value. The absolute maximum pulse width is tPERIOD − 5 ns. Depending on the switching frequency and the OUTAUX frequency, there is a constant lag/lead time between this edge and the other edges (t1 to t12); therefore, OUTAUX is not synchronized to the other PWM outputs but can be made synchronous by adjusting the delay accordingly. If either the OUTAUX switching frequency (Register 0x3F) or the PWM switching frequency (Register 0x40) is changed after edge adjustment, the synchronization between OUTAUX and the PWM edges is no longer maintained. The OUTAUX delay must be adjusted again to synchronize the edges to the PWM edges for the new set of switching frequencies. 1 = PWM modulation acts on the t14 edge. 0 = no PWM modulation of the t14 edge. 1 = negative sign. Increase of PWM modulation moves t14 right. 0 = positive sign. Increase of PWM modulation moves t14 left. 1 = control loop PWM modulation is regulated by OUTAUX. When this bit is set, the CS1 blanking signal is synchronized with OUTAUX. 0 = control loop PWM modulation is regulated by OUTA, OUTB, OUTC, OUTD, SR1, and SR2 (normal mode). Reserved. Set this bit to 0 for normal operation. Rev. 0 | Page 73 of 96 ADP1046 Data Sheet Table 93. Register 0x5D—OUTx and SRx Pin Disable Settings Bits 7 6 5 4 3 2 1 0 Bit Name OUTAUX disable SR2 disable SR1 disable OUTD disable OUTC disable OUTB disable OUTA disable GATE disable R/W R/W R/W R/W R/W R/W R/W R/W R/W Description Setting this bit disables the OUTAUX output. Setting this bit disables the SR2 output. Setting this bit disables the SR1 output. Setting this bit disables the OUTD output. Setting this bit disables the OUTC output. Setting this bit disables the OUTB output. Setting this bit disables the OUTA output. Setting this bit disables the GATE output but does not affect the VSx feedback point. Table 94. Register 0x5E—ACSNS Gain Trim Bits 7 Bit Name Gain polarity R/W R/W [6:0] ACSNS gain trim R/W Description 1 = negative gain is introduced. 0 = positive gain is introduced. These bits set the gain trim for the ACSNS ADC. DIGITAL FILTER PROGRAMMING REGISTERS POLE 20dB HF GAIN RANGE 20dB LF GAIN RANGE Register 0x5F to Register 0x67 can be used to program the digital filters. It is recommended that the software GUI be used to program the digital filters. 500Hz 1kHz POLE LOCATION RANGE 5kHz 10kHz 10045-036 100Hz 20dB ZERO RANGE ZERO Figure 57. Digital Filter Programmability Table 95. Register 0x5F—Soft Start and Output Voltage Slew Rate Settings Bits [7:5] Bit Name Soft start ramp R/W R/W 4 Soft start from precharge R/W 3 Reserved R/W Description These bits determine the duration of the soft start ramp. Bit 7 Bit 6 Bit 5 Ramp Duration 0 0 0 5 ms 0 0 1 10 ms 0 1 0 15 ms 0 1 1 20 ms 1 0 0 40 ms 1 0 1 50 ms 1 1 0 80 ms 1 1 1 100 ms Setting this bit to 1 enables the soft start from precharge function. When this function is enabled, the soft start ramp starts from the value of the voltage detected on VS1 or VS3± (depending on the OrFET status). Reserved. Rev. 0 | Page 74 of 96 Data Sheet Bits [2:0] Bit Name Slew rate ADP1046 R/W R/W Description These bits specify the slew rate at the VS3± pins for the change in the voltage reference setting. Bit 2 Bit 1 Bit 0 Slew Rate 0 0 0 200 mV/ms 0 0 1 100 mV/ms 0 1 0 50 mV/ms 0 1 1 25 mV/ms 1 0 0 12.5 mV/ms 1 0 1 6.25 mV/ms 1 1 0 3.125 mV/ms 1 1 1 1.5625 mV/ms (4 LSB/ms) Table 96. Register 0x60—Normal Mode Digital Filter LF Gain Setting Bits [7:0] Bit Name LF gain setting R/W R/W Description This register determines the low frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Table 97. Register 0x61—Normal Mode Digital Filter Zero Setting Bits [7:0] Bit Name Zero setting R/W R/W Description This register determines the position of the final zero. See Figure 57. Table 98. Register 0x62—Normal Mode Digital Filter Pole Setting Bits [7:0] Bit Name Pole location R/W R/W Description This register determines the position of the final pole. See Figure 57. Table 99. Register 0x63—Normal Mode Digital Filter HF Gain Setting Bits [7:0] Bit Name HF gain setting R/W R/W Description This register determines the high frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Table 100. Register 0x64—Light Load Mode Digital Filter LF Gain Setting Bits [7:0] Bit Name LF gain setting R/W R/W Description This register determines the low frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Table 101. Register 0x65—Light Load Mode Digital Filter Zero Setting Bits [7:0] Bit Name Zero setting R/W R/W Description This register determines the position of the final zero. See Figure 57. Table 102. Register 0x66—Light Load Mode Digital Filter Pole Setting Bits [7:0] Bit Name Pole location R/W R/W Description This register determines the position of the final pole. See Figure 57. Table 103. Register 0x67—Light Load Mode Digital Filter HF Gain Setting Bits [7:0] Bit Name HF gain setting R/W R/W Description This register determines the high frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Rev. 0 | Page 75 of 96 ADP1046 Data Sheet ADAPTIVE DEAD TIME REGISTERS 10045-151 Register 0x68 to Register 0x70 can be used to program the adaptive dead time (ADT) feature. It is recommended that the software GUI be used to program the adaptive dead time edges. Figure 58. Adaptive Dead Time Window in the GUI Table 104. Register 0x68—Adaptive Dead Time Threshold Bits [7:0] Bit Name Adaptive dead time threshold R/W R/W Description This register sets the ADT threshold. This 8-bit number is compared to the eight MSBs of the CS1 value register (Register 0x13). When the current level measured on CS1 falls below this threshold, the edges of the PWM signals are affected as a linear function of the CS1 current, as programmed in Register 0x69 to Register 0x6F. When this register is programmed to 0x00, the ADT function is disabled. Table 105. Register 0x69—Dead Time 1 Bits 7 [6:4] Bit Name t1 polarity t1 offset R/W R/W R/W 3 [2:0] t2 polarity t2 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t1 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t2 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Rev. 0 | Page 76 of 96 Data Sheet ADP1046 Table 106. Register 0x6A—Dead Time 2 Bits 7 [6:4] Bit Name t3 polarity t3 offset R/W R/W R/W 3 [2:0] t4 polarity t4 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t3 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t4 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Table 107. Register 0x6B—Dead Time 3 Bits 7 [6:4] Bit Name t5 polarity t5 offset R/W R/W R/W 3 [2:0] t6 polarity t6 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t5 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t6 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Rev. 0 | Page 77 of 96 ADP1046 Data Sheet Table 108. Register 0x6C—Dead Time 4 Bits 7 [6:4] Bit Name t7 polarity t7 offset R/W R/W R/W 3 [2:0] t8 polarity t8 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t7 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t8 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Table 109. Register 0x6D—Dead Time 5 Bits 7 [6:4] Bit Name t9 polarity t9 offset R/W R/W R/W 3 [2:0] t10 polarity t10 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t9 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t10 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Rev. 0 | Page 78 of 96 Data Sheet ADP1046 Table 110. Register 0x6E—Dead Time 6 Bits 7 [6:4] Bit Name t11 polarity t11 offset R/W R/W R/W 3 [2:0] t12 polarity t12 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t11 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t12 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Table 111. Register 0x6F—Dead Time 7 Bits 7 [6:4] Bit Name t13 polarity t13 offset R/W R/W R/W 3 [2:0] t14 polarity t14 offset R/W R/W Description 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t13 offset from nominal timing at no load. Bit 6 Bit 5 Bit 4 Offset (ns) 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 0 = positive polarity; 1 = negative polarity. This value multiplied by Register 0x70[2:0] determines the t14 offset from nominal timing at no load. Bit 2 Bit 1 Bit 0 Offset (ns) 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 Rev. 0 | Page 79 of 96 ADP1046 Data Sheet Table 112. Register 0x70—Dead Time Configuration Bits [7:6] Bit Name Averaging period R/W R/W [5:3] Update rate R/W [2:0] Multiplier R/W Description These bits specify the averaging period for the CS1 current used to set the adaptive dead time. It is recommended that the averaging time be set to a value much greater than any transient condition. Bit 7 Bit 6 Averaging Period 0 0 2.5 ms 0 1 1.2 ms 1 0 600 μs 1 1 Reserved The ADT algorithm adjusts the dead time in steps of 5 ns. These bits are used to program the number of PWM switching cycles between each step. The number is calculated as 2N + 1 where N is the 3-bit value specified by these bits. If N = 6 (110), each PWM edge is adjusted by 5 ns every 26 + 1 = 65 switching cycles. These bits specify the programming step for Register 0x69 to Register 0x6F, Bits[6:4] and Bits[2:0]. Bit 2 Bit 1 Bit 0 Multiplier 0 0 0 5 0 0 1 10 0 1 0 15 0 1 1 20 1 0 0 25 1 0 1 30 1 1 0 35 1 1 1 40 SOFT START FILTER PROGRAMMING REGISTERS Table 113. Register 0x71—Soft Start Digital Filter LF Gain Setting Bits [7:0] Bit Name LF gain setting R/W R/W Description This register determines the low frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Table 114. Register 0x72—Soft Start Digital Filter Zero Setting Bits [7:0] Bit Name Zero setting R/W R/W Description This register determines the position of the final zero. See Figure 57. Table 115. Register 0x73—Soft Start Digital Filter Pole Setting Bits [7:0] Bit Name Pole location R/W R/W Description This register determines the position of the final pole. See Figure 57. Table 116. Register 0x74—Soft Start Digital Filter HF Gain Setting Bits [7:0] Bit Name HF gain setting R/W R/W Description This register determines the high frequency gain of the loop response. Programmable over a 20 dB range. Each LSB corresponds to a 0.3 dB increase. See Figure 57. Rev. 0 | Page 80 of 96 Data Sheet ADP1046 EXTENDED FUNCTIONS REGISTERS Table 117. Register 0x75—Voltage Line Feedforward Bits [7:4] 3 Bit Name Reserved Disable feedforward during soft start R/W R/W R/W 2 Feedforward enable R/W [1:0] Gain setting R/W Description Reserved. If voltage line feedforward is enabled, this bit disables it during the reference ramp-up (soft start). This operation is gated by the filter GO bit (Register 0x7F[3]). 0 = feedforward enabled during soft start (recommended setting). 1 = feedforward disabled during soft start. This bit enables the voltage line feedforward loop. This operation is gated by the filter GO bit (Register 0x7F[3]). 0 = feedforward disabled. 1 = feedforward enabled. These bits set the gain for the voltage feedforward function. Bit 1 Bit 0 Gain 0 0 1 0 1 0.875 1 0 0.75 1 1 0.5 Table 118. Register 0x76—Volt-Second Balance Settings (OUTA and OUTB Pins) Bits 7 6 Bit Name Modulate enable, t1 t1 sign R/W R/W R/W 5 4 Modulate enable, t2 t2 sign R/W R/W 3 2 Modulate enable, t3 t3 sign R/W R/W 1 0 Modulate enable, t4 t4 sign R/W R/W Description Setting this bit enables modulation from balance control on the OUTA rising edge, t1. 0 = positive sign. Increase of balance control modulation moves t1 right. 1 = negative sign. Increase of balance control modulation moves t1 left. Setting this bit enables modulation from balance control on the OUTA falling edge, t2. 0 = positive sign. Increase of balance control modulation moves t2 right. 1 = negative sign. Increase of balance control modulation moves t2 left. Setting this bit enables modulation from balance control on the OUTB rising edge, t3. 0 = positive sign. Increase of balance control modulation moves t3 right. 1 = negative sign. Increase of balance control modulation moves t3 left. Setting this bit enables modulation from balance control on the OUTB falling edge, t4. 0 = positive sign. Increase of balance control modulation moves t4 right. 1 = negative sign. Increase of balance control modulation moves t4 left. Table 119. Register 0x77—Volt-Second Balance Settings (OUTC and OUTD Pins) Bits 7 6 Bit Name Modulate enable, t5 t5 sign R/W R/W R/W 5 4 Modulate enable, t6 t6 sign R/W R/W 3 2 Modulate enable, t7 t7 sign R/W R/W 1 0 Modulate enable, t8 t8 sign R/W R/W Description Setting this bit enables modulation from balance control on the OUTC rising edge, t5. 0 = positive sign. Increase of balance control modulation moves t5 right. 1 = negative sign. Increase of balance control modulation moves t5 left. Setting this bit enables modulation from balance control on the OUTC falling edge, t6. 0 = positive sign. Increase of balance control modulation moves t6 right. 1 = negative sign. Increase of balance control modulation moves t6 left. Setting this bit enables modulation from balance control on the OUTD rising edge, t7. 0 = positive sign. Increase of balance control modulation moves t7 right. 1 = negative sign. Increase of balance control modulation moves t7 left. Setting this bit enables modulation from balance control on the OUTD falling edge, t8. 0 = positive sign. Increase of balance control modulation moves t8 right. 1 = negative sign. Increase of balance control modulation moves t8 left. Rev. 0 | Page 81 of 96 ADP1046 Data Sheet Table 120. Register 0x78—Volt-Second Balance Settings (SR1 and SR2 Pins) Bits 7 6 Bit Name Modulate enable, t9 t9 sign R/W R/W R/W 5 4 Modulate enable, t10 t10 sign R/W R/W 3 2 Modulate enable, t11 t11 sign R/W R/W 1 0 Modulate enable, t12 t12 sign R/W R/W Description Setting this bit enables modulation from balance control on the SR1 rising edge, t9. 0 = positive sign. Increase of balance control modulation moves t9 right. 1 = negative sign. Increase of balance control modulation moves t9 left. Setting this bit enables modulation from balance control on the SR1 falling edge, t10. 0 = positive sign. Increase of balance control modulation moves t10 right. 1 = negative sign. Increase of balance control modulation moves t10 left. Setting this bit enables modulation from balance control on the SR2 rising edge, t11. 0 = positive sign. Increase of balance control modulation moves t11 right. 1 = negative sign. Increase of balance control modulation moves t11 left. Setting this bit enables modulation from balance control on the SR2 falling edge, t12. 0 = positive sign. Increase of balance control modulation moves t12 right. 1 = negative sign. Increase of balance control modulation moves t12 left. Table 121. Register 0x79—SR Delay Compensation Bits [7:6] [5:0] Bit Name Reserved SR driver delay R/W R/W R/W Description Reserved. These bits specify the 6-bit representation of the SR delay in steps of 5 ns. 000000 = 0 ns. 111111 = 63 ns × 5 ns = 315 ns. Table 122. Register 0x7A—Filter Transitions Bits [7:6] [5:3] 2 Bit Name Reserved HF ADC configuration Enable soft transition R/W R/W R/W R/W [1:0] Transition speed R/W Description Reserved. Set these bits to 001 at all times for proper operation. Setting this bit enables a soft transition between filter settings to minimize output transients. All four parameters of each filter are linearly transitioned to the new value. These bits set the transition speed from one filter to another. The filter changes in 32 steps; each step is applied at the multiple of switching cycles (tSW) specified by these bits. Bit 1 Bit 0 Speed (tSW = One Switching Cycle) 0 0 32 tSW (total transition time = 32 × 32 tSW = 1024 × tSW) 0 1 8 tSW (total transition time = 8 × 32 tSW = 256 × tSW) 1 0 2 tSW (total transition time = 64 × tSW) 1 1 1 tSW (total transition time = 32 × tSW) Table 123. Register 0x7B—PGOOD1 Flag Masking Bits 7 Bit Name Soft start flag R/W R/W 6 5 4 3 2 CS1 fast OCP CS1 accurate OCP CS2 accurate OCP UVP Local OVP (fast and accurate) Load OVP OrFET R/W R/W R/W R/W R/W Description If set to 1, this flag is ignored by PGOOD1. This bit must be set to 0 to enable proper PGOOD1 debounce timing after the end of the soft start ramp. If set to 1, this flag is ignored by PGOOD1. If set to 1, this flag is ignored by PGOOD1. If set to 1, this flag is ignored by PGOOD1. If set to 1, this flag is ignored by PGOOD1. If set to 1, this flag is ignored by PGOOD1. R/W R/W If set to 1, this flag is ignored by PGOOD1. If set to 1, this flag is ignored by PGOOD1. 1 0 Rev. 0 | Page 82 of 96 Data Sheet ADP1046 Table 124. Register 0x7C—PGOOD2 Flag Masking Bits 7 Bit Name Soft start flag R/W R/W 6 5 4 3 2 CS1 fast OCP CS1 accurate OCP CS2 accurate OCP UVP Local OVP (fast and accurate) Load OVP OrFET R/W R/W R/W R/W R/W Description If set to 1, this flag is ignored by PGOOD2. This bit must be set to 0 to enable proper PGOOD2 debounce timing after the end of the soft start ramp. If set to 1, this flag is ignored by PGOOD2. If set to 1, this flag is ignored by PGOOD2. If set to 1, this flag is ignored by PGOOD2. If set to 1, this flag is ignored by PGOOD2. If set to 1, this flag is ignored by PGOOD2. R/W R/W If set to 1, this flag is ignored by PGOOD2. If set to 1, this flag is ignored by PGOOD2. 1 0 Table 125. Register 0x7D—Light Load Mode Threshold Settings Bits [7:6] [5:4] Bit Name Reserved Debounce R/W R/W R/W [3:2] Light load mode averaging speed R/W [1:0] Light load mode hysteresis R/W Description Reserved. After the SR outputs are turned on or off, any further transition of the thresholds is ignored for the amount of time programmed in these bits. This debounce is provided to avoid false transitions and improve noise immunity. The debounce time is calculated as a number of PWM switching cycles (tSW). For example, at 100 kHz, tSW = 10 μs, 64 × tSW = 640 μs. Bit 5 Bit 4 Debounce Time 0 0 0 tSW 0 1 64 tSW 1 0 128 tSW 1 1 256 tSW These bits set the averaging speed and resolution used for the light load mode threshold. Faster speed corresponds to lower resolution and, therefore, to lower accuracy of the threshold. Bit 3 Bit 2 Speed (Resolution) 0 0 37.5 μs (6 bits) 0 1 75 μs (7 bits) 1 0 150 μs (8 bits) 1 1 300 μs (9 bits) These bits set the amount of hysteresis applied to the light load mode threshold. The size of the LSB is affected by the speed and resolution selected in Bits[3:2]. If the CS2 ADC range of 120 mV is used with 8-bit resolution, the LSB size is 120 mV/28 = 469 μV. Bit 1 Bit 0 Hysteresis (LSB) 0 0 3 0 1 8 1 0 12 1 1 16 Table 126. Register 0x7F—GO Byte Bits [7:4] 3 Bit Name Reserved Filter GO R/W R/W W 2 Frequency GO W 1 PWM settings GO W 0 Voltage reference GO W Description Reserved. This bit latches all the filter registers: Register 0x60 to Register 0x67 and Register 0x71 to Register 0x75. This bit latches Register 0x3F and Register 0x40. This is to prevent the switching frequency settings from being temporarily incorrect. This bit latches Register 0x41 to Register 0x5C. This is to prevent the PWM settings from being temporarily incorrect. This bit latches Register 0x31. This is to prevent the reference setting from being temporarily incorrect. Rev. 0 | Page 83 of 96 ADP1046 Data Sheet EEPROM REGISTERS Refer to the I2C communication protocol specification for more information about how to write these commands to the ADP1046. Table 127. Register 0x81—RESTORE_DEFAULT_ALL Bits N/A Bit Name RESTORE_DEFAULT_ALL Type Send byte Description Download the factory default settings from EEPROM (Page 0 of the main block) into operating memory. The password is also reset to the default value (0xFF). Table 128. Register 0x82—STORE_USER_ALL Bits N/A Bit Name STORE_USER_ALL Type Send byte Description Copy the entire contents of operating memory (registers) into EEPROM (Page 1 of the main block). The EEPROM must first be unlocked. Table 129. Register 0x83—RESTORE_USER_ALL Bits N/A Bit Name RESTORE_USER_ALL Type Send byte Description Download the stored user settings from EEPROM (Page 1 of the main block) into operating memory. The EEPROM must first be unlocked. Table 130. Register 0x84—EEPROM_CRC_CHKSUM Bits [7:0] Bit Name EEPROM_CRC_CHKSUM Type R Description Return the CRC checksum value from the EEPROM download operation. Table 131. Register 0x85—EEPROM_ADDR_OFFSET Bits [15:0] Bit Name EEPROM_ADDR_OFFSET Type R/W Description Set the address offset of the current EEPROM page. Table 132. Register 0x86—EEPROM_NUM_RD_BYTES Bits [7:0] Bit Name EEPROM_NUM_RD_BYTES Type R/W Description Set the number of read bytes returned when using the EEPROM_DATA_xx command. Table 133. Register 0x87—EEPROM_PAGE_ERASE Bits [7:4] [3:0] Bit Name Reserved EEPROM_PAGE_ERASE Type R W Description Reserved. Perform a page erase on the selected EEPROM page (Page 4 to Page 15). Wait 35 ms after each page erase operation. The EEPROM must first be unlocked. Page 0 and Page 1 are reserved for storing the default settings and user settings, respectively. The user cannot perform a page erase of Page 0 or Page 1. Page 2 and Page 3 are reserved for internal use and their contents should not be erased. Table 134. Register 0x88—EEPROM_PASSWORD Bits [7:0] Bit Name EEPROM_PASSWORD Type W Description Write the password to this register two consecutive times to unlock the EEPROM and/or to change the EEPROM password. The factory default password is 0xFF. To lock the EEPROM, type any value other than the password to this register. Table 135. Register 0x89—TRIM_PASSWORD Bits [7:0] Bit Name TRIM_PASSWORD Type R/W Description Write the password to this register to unlock the trim registers for write access. Write the trim password twice to unlock the register; write any other value to exit. The trim password is the same as the EEPROM password. Rev. 0 | Page 84 of 96 Data Sheet ADP1046 Table 136. Register 0x8A—EEPROM_INFO Bits Variable Bit Name EEPROM_INFO Type Block read Description Block read from the EEPROM INFO block. Table 137. Register 0x8B—EEPROM_DATA_00 Bits Variable Bit Name EEPROM_DATA_00 Type Block read Description Block read from the EEPROM main block, Page 0. The EEPROM must first be unlocked. This page contains the factory default settings. Table 138. Register 0x8C—EEPROM_DATA_01 Bits Variable Bit Name EEPROM_DATA_01 Type Block read Description Block read from the EEPROM main block, Page 1. The EEPROM must first be unlocked. This page contains the user settings. Table 139. Register 0x8D—EEPROM_DATA_02 Bits Variable Bit Name EEPROM_DATA_02 Type Block read Description Block read from the EEPROM main block, Page 2. This page contains internal settings and should not be written to or erased. Table 140. Register 0x8E—EEPROM_DATA_03 Bits Variable Bit Name EEPROM_DATA_03 Type Block read Description Block read from the EEPROM main block, Page 3. This page contains internal settings and should not be written to or erased. Table 141. Register 0x8F—EEPROM_DATA_04 Bits Variable Bit Name EEPROM_DATA_04 Type Block read/ write Description Block read or write from the EEPROM main block, Page 4. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 142. Register 0x90—EEPROM_DATA_05 Bits Variable Bit Name EEPROM_DATA_05 Type Block read/ write Description Block read or write from the EEPROM main block, Page 5. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 143. Register 0x91—EEPROM_DATA_06 Bits Variable Bit Name EEPROM_DATA_06 Type Block read/ write Description Block read or write from the EEPROM main block, Page 6. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 144. Register 0x92—EEPROM_DATA_07 Bits Variable Bit Name EEPROM_DATA_07 Type Block read/ write Description Block read or write from the EEPROM main block, Page 7. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 145. Register 0x93—EEPROM_DATA_08 Bits Variable Bit Name EEPROM_DATA_08 Type Block read/ write Description Block read or write from the EEPROM main block, Page 8. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Rev. 0 | Page 85 of 96 ADP1046 Data Sheet Table 146. Register 0x94—EEPROM_DATA_09 Bits Variable Bit Name EEPROM_DATA_09 Type Block read/ write Description Block read or write from the EEPROM main block, Page 9. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 147. Register 0x95—EEPROM_DATA_10 Bits Variable Bit Name EEPROM_DATA_10 Type Block read/ write Description Block read or write from the EEPROM main block, Page 10. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 148. Register 0x96—EEPROM_DATA_11 Bits Variable Bit Name EEPROM_DATA_11 Type Block read/ write Description Block read or write from the EEPROM main block, Page 11. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 149. Register 0x97—EEPROM_DATA_12 Bits Variable Bit Name EEPROM_DATA_12 Type Block read/ write Description Block read or write from the EEPROM main block, Page 12. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 150. Register 0x98—EEPROM_DATA_13 Bits Variable Bit Name EEPROM_DATA_13 Type Block read/ write Description Block read or write from the EEPROM main block, Page 13. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 151. Register 0x99—EEPROM_DATA_14 Bits Variable Bit Name EEPROM_DATA_14 Type Block read/ write Description Block read or write from the EEPROM main block, Page 14. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Table 152. Register 0x9A—EEPROM_DATA_15 Bits Variable Bit Name EEPROM_DATA_15 Type Block read/ write Description Block read or write from the EEPROM main block, Page 15. To write to this page, the EEPROM must first be unlocked. This page is available to the user for storing data. Rev. 0 | Page 86 of 96 Data Sheet ADP1046 RESONANT MODE OPERATION The ADP1046 supports control of a resonant converter. Resonant converters are an alternative to traditional fixed frequency converters. They offer high switching frequency, small size, and high efficiency. Figure 59 illustrates a widely used series resonant converter. QA QC Control of the synchronous rectifiers in a resonant controller is a complicated issue. The ADP1046 ACSNS comparator can be used to control the SR signals. In resonant mode operation, the SR1 output is driven by the rising edge of the ACSNS comparator, and the SR2 output is driven by the falling edge of the comparator, as shown in Figure 61. SR2 CR LR IO IR SR1 QB CO RL VDS (SR2) 10045-037 QD SYNCHRONOUS RECTIFICATION IN RESONANT MODE ACSNS Figure 59. Series Resonant Converter RESONANT MODE ENABLE PWM1 (OUTA) ∆t1 ∆t2 ∆t10 ∆t11 tD ∆t12 tE 10045-040 SYNC RECT 2 (SR2) PWM TIMING IN RESONANT MODE With variable frequency control, OUTA and OUTB can only be high during the first half of the switching cycle (tA to tB), whereas OUTC and OUTD can only be high during the second half of the switching cycle (tB to tC), as shown in Figure 60. The frequency resolution of the control law is in steps of 10 ns. ∆t9 SYNC RECT 1 (SR1) tF Figure 61. SR1 and SR2 PWM Timing Diagram in Resonant Mode Following is an example of how the ADP1046 can be used in a series resonant topology and also achieve control of the synchronous rectifiers. The VDS voltage of SR2 (see Figure 61) can be used to control the SR signals. The ACSNS pin is connected to the divided-down SR2 VDS voltage. This provides the timing information for both synchronous rectifiers (see Figure 62). SR2 ∆t3 PWM2 (OUTB) CR ∆t4 IR ∆t5 PWM3 (OUTC) R1 ACSNS LR R2 IO SR1 CO RL ∆t6 10045-039 To enable the ADP1046 to control a resonant switching converter, Register 0x40 must be set to a value of 0x3F. In resonant mode, the PWM outputs have a fixed duty cycle with variable frequency. Figure 62. Resonant Synchronous Rectifier Control Circuit ∆t8 tPERIOD tA tB tPERIOD tC Figure 60. OUTA, OUTB, OUTC, and OUTD PWM Timing Diagram in Resonant Mode 10045-038 ∆t7 PWM4 (OUTD) After the timing information is obtained, SR1 is driven by the rising edge of the ACSNS comparator, and SR2 is driven by the falling edge of the comparator, as shown in Figure 61. In this way, it is possible to achieve synchronous rectification. Turn-on and turn-off delays can be programmed for the SR1 and SR2 signals individually. This example is not the only way to control the SR signals. If the user has another method to control the SR signals, this method can be used to connect to the ACSNS input instead of the VDS voltage of SR2. When the ADP1046 is used to control a resonant converter, it is recommended that SR soft start be disabled during soft start of the device (set Register 0x0F[7] = 1). Rev. 0 | Page 87 of 96 ADP1046 Data Sheet ADJUSTING THE TIMING OF THE PWM OUTPUTS SOFT START IN RESONANT MODE To accurately adjust the timing of the PWM outputs, the following registers can be used to set the dead time and delays of the PWM outputs: Register 0x41, Register 0x43, Register 0x45, Register 0x47, Register 0x49, Register 0x4B, Register 0x4D, Register 0x4F, Register 0x51, Register 0x53, Register 0x55, and Register 0x57. The resolution for adjusting the dead time is 5 ns. Refer to the Resonant Mode Register Descriptions section for more information. The software GUI for the ADP1046 can be used to set the frequency limit registers, as well as all other settings related to the resonant mode of operation. During soft start, the reference voltage of the ADP1046 ramps up. With the feedback loop closed, the switching frequency is reduced from the highest limit to a regulation value. The soft start timing settings and the filter settings are the same as those for the fixed frequency PWM mode (see the Soft Start section). FREQUENCY LIMIT SETTING The minimum frequency is set by Register 0x42 and the first four bits of Register 0x44. For example, Register 0x42 is set to 0xA0 (160 decimal) and Bits[7:4] of Register 0x44 are set to 0xF (15 decimal). LIGHT LOAD OPERATION (BURST MODE) To control the converter at very light load, the ADP1046 can operate in burst mode. Burst mode can be enabled or disabled using Bits[7:6] of Register 0x4A. When the desired switching frequency is higher than the burst mode threshold, the part enters burst mode. The threshold is determined by the maximum frequency and the burst mode offset setting. The threshold value used to enter burst mode is determined as follows: Threshold value for burst mode = ((Register 0x46 × 16) + Register 0x48[7:4]) + (Register 0x4A[5:0] × 2) The maximum switching cycle is (160 × 16 + 15) × 5 ns = 12.875 μs The threshold value used to exit burst mode is determined by the entrance value plus 0x10. The lowest switching frequency limit is 1/12.875 μs = 77.7 kHz The maximum frequency is set by Register 0x46 and by Bits[7:4] of Register 0x48. For example, Register 0x46 is set to 0x10 (16 decimal), Bits[7:4] of Register 0x48 are set to 0, and Bits[5:0] of Register 0x4A are set to 0x8 (8 decimal). For example, Register 0x46 is set to 0x10 (16 decimal) and Bits[7:4] of Register 0x48 are set to 0x9 (9 decimal). The minimum switching cycle is (16 × 16 + 0) × 5 ns = 1.28 μs The minimum switching cycle is The highest switching frequency limit is (16 × 16 + 9) × 5 ns = 1.325 μs 1/1.28 μs = 781 kHz The highest switching frequency limit is The threshold to enter burst mode is 1/1.325 μs = 755 kHz [(16 × 16 + 0) + (8 × 2)] × 5 ns = 1.36 μs FEEDBACK CONTROL IN RESONANT MODE In contrast to a traditional fixed frequency PWM converter, the output voltage of a resonant converter is regulated by changing the switching frequency. When the ADP1046 is operated in resonant mode, the switching frequency decreases when the sensed voltage is lower than the reference voltage. This makes the ADP1046 capable of controlling a resonant converter in zero-voltage switching (ZVS) mode. Although the switching frequency is variable, the high frequency feedback voltage sampling frequency (VS3± pins) is fixed at 400 kHz. The parameters of the feedback filter are based on this frequency. The method for calculating the filter parameters (gains, zeros, and poles) is the same as that for the fixed frequency PWM mode (see the Digital Filter section). When the desired switching frequency is higher than 1/1.36 μs = 735 kHz, the PWM outputs are shut down and the part enters burst mode. The threshold to exit burst mode is [(16 × 16 + 0) + (8 × 2) + 16] × 5 ns = 1.44 μs Therefore, when the desired switching frequency becomes lower than 1/1.44 μs = 694 kHz, the PWM signals are reenabled, and the part exits burst mode. OUTAUX IN RESONANT MODE In resonant mode, the OUTAUX pin cannot be used as a control signal. However, OUTAUX can be used as a fixed frequency PWM signal with a fixed duty cycle. PROTECTIONS IN RESONANT MODE All of the flags and protections that are available in resonant mode behave in the same manner as in fixed frequency PWM mode. Rev. 0 | Page 88 of 96 Data Sheet ADP1046 RESONANT MODE REGISTER DESCRIPTIONS Table 153. Register 0x40—PWM Switching Frequency Setting in Resonant Mode Bits [7:6] [5:0] Bit Name Reserved Switching frequency R/W R/W R/W Description Reserved. This register sets the switching frequency of the PWM pins and enables resonant mode. To enable resonant mode, set these bits to 0x3F (111111). Table 154. Register 0x41—OUTA Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt1 (rising edge dead time of OUTA) R/W R/W Description This register sets Δt1, which is the delay of the rising edge of OUTA from the start of the switching cycle, tA. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt1 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 155. Register 0x42—Lowest Switching Frequency Limit Setting (Maximum Switching Cycle in Resonant Mode) Bits [7:0] Bit Name Lowest frequency R/W R/W Description This register contains the eight MSBs of the 12-bit value of the lowest switching frequency (maximum switching cycle) limit. This value is always used with the top four bits of Register 0x44, which contain the four LSBs of the lowest switching frequency limit. Each LSB of the 12-bit value corresponds to 5 ns of resolution for the switching cycle. For example, if Register 0x42 is set to 0xA0 (160 decimal) and Bits[7:4] of Register 0x44 are set to 0xF (15 decimal), the maximum switching cycle is (160 × 16 + 15) × 5 ns = 12.875 μs, and the lowest switching frequency limit is 1/12.875 μs = 77.7 kHz. Table 156. Register 0x43—OUTA Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt2 (falling edge dead time of OUTA) R/W R/W Description This register sets Δt2, which is the difference between the falling edge of OUTA and the midpoint of the switching cycle, tB. Each LSB corresponds to 5 ns of resolution. When the register value is from 0x00 to 0x7F, the falling edge of OUTA is trailing tB. When the value is from 0x80 to 0xFF, the falling edge of OUTA is leading tB. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt2 0 0 0 0 0 0 0 0 0 ns 0 0 0 0 0 0 0 1 5 ns trailing … … … … … … … … … 0 1 1 1 1 1 1 1 635 ns trailing 1 0 0 0 0 0 0 0 640 ns leading … … … … … … … … … 1 1 1 1 1 1 1 1 5 ns leading Table 157. Register 0x44—Lowest Switching Frequency Limit Setting (Maximum Switching Cycle in Resonant Mode) Bits [7:4] Bit Name Lowest frequency R/W R/W [3:0] Reserved R/W Description This register contains the four LSBs of the 12-bit value of the lowest switching frequency (maximum switching cycle) limit. This value is always used with the eight bits of Register 0x42, which contain the eight MSBs of the lowest switching frequency limit. Each LSB of the 12-bit value corresponds to 5 ns of resolution for the switching cycle. For example, if Register 0x42 is set to 0xA0 (160 decimal) and Bits[7:4] of Register 0x44 are set to 0xF (15 decimal), the maximum switching cycle is (160 × 16 + 15) × 5 ns = 12.875 μs, and the lowest switching frequency limit is 1/12.875 μs = 77.7 kHz. Reserved. Rev. 0 | Page 89 of 96 ADP1046 Data Sheet Table 158. Register 0x45—OUTB Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt3 (rising edge dead time of OUTB) R/W R/W Description This register sets Δt3, which is the delay time of the rising edge of OUTB from the start of the switching cycle, tA. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt3 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 159. Register 0x46—Highest Switching Frequency Limit Setting (Minimum Switching Cycle in Resonant Mode) Bits [7:0] Bit Name Highest frequency R/W R/W Description This register contains the eight MSBs of the 12-bit value of the highest switching frequency (minimum switching cycle) limit. This value is always used with the top four bits of Register 0x48, which contain the four LSBs of the highest switching frequency limit. Each LSB of the 12-bit value corresponds to 5 ns of resolution for the switching cycle. For example, if Register 0x46 is set to 0x10 (16 decimal) and Bits[7:4] of Register 0x48 are set to 0x9 (9 decimal), the minimum switching cycle is (16 × 16 + 9) × 5 ns = 1.325 μs, and the highest switching frequency limit is 1/1.325 μs = 755 kHz. It is recommended that the maximum frequency be limited 1 MHz. Table 160. Register 0x47—OUTB Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt4 (falling edge dead time of OUTB) R/W R/W Description This register sets Δt4, which is the difference between the falling edge of OUTB and the midpoint of the switching cycle, tB. Each LSB corresponds to 5 ns of resolution. When the register value is from 0x00 to 0x7F, the falling edge of OUTB is trailing tB. When the value is from 0x80 to 0xFF, the falling edge of OUTB is leading tB. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt4 0 0 0 0 0 0 0 0 0 ns 0 0 0 0 0 0 0 1 5 ns trailing … … … … … … … … … 0 1 1 1 1 1 1 1 635 ns trailing 1 0 0 0 0 0 0 0 640 ns leading … … … … … … … … … 1 1 1 1 1 1 1 1 5 ns leading Table 161. Register 0x48—Highest Switching Frequency Limit Setting (Minimum Switching Cycle in Resonant Mode) Bits [7:4] Bit Name Highest frequency R/W R/W [3:0] Reserved R/W Description This register contains the four LSBs of the 12-bit value of the highest switching frequency (minimum switching cycle) limit. This value is always used with the eight bits of Register 0x46, which contain the eight MSBs of the highest switching frequency limit. Each LSB of the 12-bit value corresponds to 5 ns of resolution for the switching cycle. For example, if Register 0x46 is set to 0x10 (16 decimal) and Bits[7:4] of Register 0x48 are set to 0x9 (9 decimal), the minimum switching cycle is (16 × 16 + 9) × 5 ns = 1.325 μs, and the highest switching frequency limit is 1/1.325 μs = 755 kHz. Reserved. Rev. 0 | Page 90 of 96 Data Sheet ADP1046 Table 162. Register 0x49—OUTC Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt5 (rising edge dead time of OUTC) R/W R/W Description This register sets Δt5, which is the difference between the rising edge of OUTC and the midpoint of the switching cycle, tB. Each LSB corresponds to 5 ns of resolution. When the register value is from 0x00 to 0x7F, the rising edge of OUTC is trailing tB. When the value is from 0x80 to 0xFF, the rising edge of OUTC is leading tB. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt5 0 0 0 0 0 0 0 0 0 ns 0 0 0 0 0 0 0 1 5 ns trailing … … … … … … … … … 0 1 1 1 1 1 1 1 635 ns trailing 1 0 0 0 0 0 0 0 640 ns leading … … … … … … … … … 1 1 1 1 1 1 1 1 5 ns leading Table 163. Register 0x4A—Burst Mode Operation in Resonant Mode Bits [7:6] Bit Name Burst mode enable R/W R/W [5:0] Burst mode offset R/W Description These bits are used to enable or disable burst mode operation. Bit 7 Bit 6 Burst Mode 0 0 Disabled 0 1 Enabled for normal operation, but disabled during soft start 1 0 Disabled 1 1 Enabled for normal operation and during soft start These bits, along with the highest switching frequency limit, determine the threshold value for enabling burst mode operation. For information about how to set this value, see the Light Load Operation (Burst Mode) section. During burst mode, the PWM frequency is the maximum frequency limit set in Register 0x46. Table 164. Register 0x4B—OUTC Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt6 (falling edge dead time of OUTC) R/W R/W Description This register sets Δt6, which is the leading time of the falling edge of OUTC from the end of the switching cycle, tC. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt6 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 165. Register 0x4D—OUTD Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt7 (rising edge dead time of OUTD) R/W R/W Description This register sets Δt7, which is the difference between the rising edge of OUTD and the midpoint of the switching cycle, tB. Each LSB corresponds to 5 ns of resolution. When the register value is from 0x00 to 0x7F, the rising edge of OUTD is trailing tB. When the value is from 0x80 to 0xFF, the rising edge of OUTD is leading tB. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt7 0 0 0 0 0 0 0 0 0 ns 0 0 0 0 0 0 0 1 5 ns trailing … … … … … … … … … 0 1 1 1 1 1 1 1 635 ns trailing 1 0 0 0 0 0 0 0 640 ns leading … … … … … … … … … 1 1 1 1 1 1 1 1 5 ns leading Rev. 0 | Page 91 of 96 ADP1046 Data Sheet Table 166. Register 0x4F—OUTD Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt8 (falling edge dead time of OUTD) R/W R/W Description This register sets Δt8, which is the leading time of the falling edge of OUTD from the end of the switching cycle, tC. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt8 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 167. Register 0x51—SR1 Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt9 (rising edge dead time of SR1) R/W R/W Description This register sets Δt9, which is the delay time of the rising edge of SR1 from the ACSNS rising edge, tD. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt9 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 168. Register 0x53—SR1 Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt10 (falling edge dead time of SR1) R/W R/W Description This register sets Δt10, which is the leading time of the falling edge of SR1 from the ACSNS falling edge, tE. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt10 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 169. Register 0x55—SR2 Rising Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt11 (rising edge dead time of SR2) R/W R/W Description This register sets Δt11, which is the delay time of the rising edge of SR2 from the ACSNS falling edge, tE. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt11 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Table 170. Register 0x57—SR2 Falling Edge Dead Time in Resonant Mode Bits [7:0] Bit Name Δt12 (falling edge dead time of SR2) R/W R/W Description This register sets Δt12, which is the leading time of the falling edge of SR2 from the ACSNS rising edge, tF. Each LSB corresponds to 5 ns of resolution. Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Δt12 (ns) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 5 … … … … … … … … … 1 1 1 1 1 1 1 1 1275 Rev. 0 | Page 92 of 96 Data Sheet ADP1046 OUTLINE DIMENSIONS 0.30 0.25 0.18 32 25 1 24 0.50 BSC TOP VIEW 0.80 0.75 0.70 8 16 0.05 MAX 0.02 NOM COPLANARITY 0.08 0.20 REF SEATING PLANE 3.25 3.10 SQ 2.95 EXPOSED PAD 17 0.50 0.40 0.30 PIN 1 INDICATOR 9 BOTTOM VIEW 0.25 MIN FOR PROPER CONNECTION OF THE EXPOSED PAD, REFER TO THE PIN CONFIGURATION AND FUNCTION DESCRIPTIONS SECTION OF THIS DATA SHEET. COMPLIANT TO JEDEC STANDARDS MO-220-WHHD. 112408-A PIN 1 INDICATOR 5.10 5.00 SQ 4.90 Figure 63. 32-Lead Lead Frame Chip Scale Package [LFCSP_WQ] 5 mm × 5 mm Body, Very Very Thin Quad (CP-32-7) Dimensions shown in millimeters ORDERING GUIDE Model 1 ADP1046ACPZ-RL ADP1046ACPZ-R7 ADP1046-100-EVALZ ADP1046DC1-EVALZ ADP-I2C-USB-Z 1 Temperature Range −40°C to +125°C −40°C to +125°C Package Description 32-Lead Lead Frame Chip Scale Package [LFCSP_WQ] 32-Lead Lead Frame Chip Scale Package [LFCSP_WQ] ADP1046 100 W Evaluation Board ADP1046 Daughter Card USB to I2C Adapter Z = RoHS Compliant Part. Rev. 0 | Page 93 of 96 Package Option CP-32-7 CP-32-7 ADP1046 Data Sheet NOTES Rev. 0 | Page 94 of 96 Data Sheet ADP1046 NOTES Rev. 0 | Page 95 of 96 ADP1046 Data Sheet NOTES I2C refers to a communications protocol originally developed by Philips Semiconductors (now NXP Semiconductors). ©2012 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D10045-0-3/12(0) Rev. 0 | Page 96 of 96