Digital Controller for Isolated Power Supply with PMBus Interface ADP1050 Data Sheet FEATURES GENERAL DESCRIPTION Versatile digital voltage mode controller High speed input voltage feedforward control 4 pulse-width modulation (PWM) logic outputs with 625 ps resolution Switching frequency: 49 kHz to 625 kHz Frequency synchronization as slave device Pulse skipping power saving mode Prebias startup Conditional overvoltage protection Extensive fault detection and protection PMBus compliant Graphical user interface (GUI) for ease of programming On-board EEPROM for programming and data storage Available in a 20-lead, 4 mm × 4 mm LFCSP −40°C to +125°C operating temperature The ADP1050 is an advanced digital controller with a PMBus™ interface targeting high density, high efficiency dc-to-dc power conversion. This controller implements voltage mode control with high speed, input voltage feedforward operation for enhanced transient and noise performance. The ADP1050 has four programmable pulse-width modulation (PWM) outputs capable of controlling most high efficiency power supply topologies, with the added control of synchronous rectification (SR). The ADP1050 implements several features to enable a robust system of parallel and redundant operation for customers who require high availability. The device provides synchronization, prebias startup, and conditional overvoltage techniques to identify and safely shut down an erroneous power supply in parallel operation mode. The ADP1050 is based on flexible state machine architecture and is programmed using an intuitive graphical user interface (GUI). The easy to use GUI reduces design cycle time and results in a robust, hardware coded system loaded into the builtin EEPROM. The small size (4 mm × 4 mm) of the LFCSP package makes the ADP1050 ideal for ultracompact, isolated dc-to-dc power module or embedded power designs. APPLICATIONS High density, isolated dc-to-dc power supplies Intermediate bus converters High availability parallel power systems Server, storage, industrial, networking, and communications infrastructure TYPICAL APPLICATIONS CIRCUIT DC INPUT LOAD ADP3624 or ADP3654 SR1 SR2 VF OVP VS+ VS– CS1 ADuM3221 OUTA OUTB ADP1050 RES ADD RTD VCORE PG/ALT CTRL SDA SYNI/FLGI SCL VDD AGND 12039-006 PMBus Figure 1. Rev. A Document Feedback 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. 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Technical Support www.analog.com ADP1050* Product Page Quick Links Last Content Update: 11/01/2016 Comparable Parts Software and Systems Requirements View a parametric search of comparable parts • ADP1050/ADP1051/ADP1052 Software Evaluation Kits Reference Materials • ADP1050 Evaluation Board Technical Articles • Designing Digital Power Supplies With A State Machine Documentation Application Notes • AN-1306: ADP1050 and ADP1051 EEPROM Programming and Calibration in the Power Supply Manufacturing Environment Data Sheet • ADP1050: Digital Controller for Isolated Power Supply with PMBus Interface Data Sheet User Guides • UG-664: 240 W Evaluation Board Kit for the ADP1050, Digital Controller for Isolated Power Supply with PMBus Interface • UG-691: 150 W Eighth Brick Module for the ADP1050, Digital Controller for Isolated Power Supply with PMBus Interface Design Resources • • • • ADP1050 Material Declaration PCN-PDN Information Quality And Reliability Symbols and Footprints Discussions View all ADP1050 EngineerZone Discussions Sample and Buy Visit the product page to see pricing options Technical Support Submit a technical question or find your regional support number * This page was dynamically generated by Analog Devices, Inc. and inserted into this data sheet. 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ADP1050 Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 PMBus Protection Commands ................................................. 30 Applications ....................................................................................... 1 Manufacturer Specific Protection Commands....................... 32 General Description ......................................................................... 1 Manufacturer Specific Protection Responses ......................... 34 Typical Applications Circuit............................................................ 1 Power Supply Calibration and Trim ............................................ 35 Revision History ............................................................................... 3 IIN Trim (CS1 Trim).................................................................... 35 Specifications..................................................................................... 4 VOUT Trim (VS Trim) ................................................................. 35 Timing Diagram ........................................................................... 7 VIN Trim (VF Gain Trim) .......................................................... 35 Absolute Maximum Ratings............................................................ 8 RTD and OTP Trim ................................................................... 36 Thermal Resistance ...................................................................... 8 Layout Guidelines ........................................................................... 37 Soldering ........................................................................................ 8 CS1 Pin ........................................................................................ 37 ESD Caution .................................................................................. 8 VS+ and VS− Pins ...................................................................... 37 Pin Configuration and Function Descriptions ............................. 9 VDD Pin ...................................................................................... 37 Typical Performance Characteristics ........................................... 11 VCORE Pin ................................................................................. 37 Theory of Operation ...................................................................... 12 RES Pin ........................................................................................ 37 PWM Outputs (OUTA, OUTB, SR1, and SR2)...................... 13 SDA and SCL Pins ...................................................................... 37 Synchronous Rectification ........................................................ 13 Exposed Pad ................................................................................ 37 PWM Modulation Limit and 180° Phase Shift ....................... 14 RTD Pin ....................................................................................... 37 Frequency Synchronization ...................................................... 14 AGND Pin ................................................................................... 37 Output Voltage Sense and Adjustment .................................... 16 PMBus/I2C Communication ......................................................... 38 Digital Compensator .................................................................. 17 PMBus Features .......................................................................... 38 Closed-Loop Input Voltage Feedforward Control and VF Sense ...................................................................................... 18 Overview ..................................................................................... 38 Open-Loop Input Voltage Feedforward Operation ............... 19 Data Transfer............................................................................... 38 Open-Loop Operation ............................................................... 19 General Call Support ................................................................. 40 CS1 Current Sense (CS1 Pin).................................................... 20 10-Bit Addressing ....................................................................... 40 Soft Start and Shutdown ............................................................ 20 Fast Mode .................................................................................... 40 Volt-Second Balance Control.................................................... 22 Fault Conditions ......................................................................... 40 Pulse Skipping ............................................................................. 23 Timeout Conditions ................................................................... 40 Prebias Startup ............................................................................ 23 Data Transmission Faults .......................................................... 40 VDD and VCORE ...................................................................... 23 Data Content Faults ................................................................... 41 Chip Password ............................................................................ 24 EEPROM ......................................................................................... 42 Power Monitoring, Flags, and Fault Responses .......................... 25 EEPROM Features...................................................................... 42 Flags .............................................................................................. 25 EEPROM Overview ................................................................... 42 Voltage Readings ........................................................................ 28 EEPROM Password .................................................................... 42 Current Readings........................................................................ 28 Page Erase Operation ................................................................. 42 Power Readings........................................................................... 28 Read Operation (Byte Read and Block Read) ........................ 43 Duty Cycle Reading .................................................................... 28 Write Operation (Byte Write and Block Write) ..................... 43 Switching Frequency Reading .................................................. 28 Downloading EEPROM Settings to Internal Registers ......... 44 Temperature Reading ................................................................. 29 Saving Register Settings to the EEPROM ............................... 44 Temperature Linearization Scheme ......................................... 30 EEPROM CRC Checksum ........................................................ 44 PMBus/I2C Address ................................................................... 38 Rev. A | Page 2 of 92 Data Sheet ADP1050 GUI Software ...................................................................................45 Temperature Sense and Protection Setting Registers ............. 79 PMBus Command Set ....................................................................46 Digital Compensator and Modulation Setting Registers ....... 80 Manufacturer Specific Extended Command List .......................49 PWM Outputs Timing Registers .............................................. 83 PMBus Command Descriptions ...................................................51 Volt-Second Balance Control Registers ................................... 85 Basic PMBus Commands ...........................................................51 Duty Cycle Reading Setting Registers ...................................... 86 Manufacturer Specific Extended Commands Descriptions ......70 Other Register Settings............................................................... 86 Flag Configuration Registers .....................................................70 Manufacturer Specific Fault Flag Registers ............................. 89 Soft Start and Software Reset Registers ....................................72 Manufacturer Specific Value Reading Registers ..................... 91 Blanking and PGOOD Setting Registers ..................................73 Outline Dimensions ........................................................................ 92 Switching Frequency and Synchronization Registers ............75 Ordering Guide ........................................................................... 92 Current Sense and Limit Setting Registers ..............................76 Voltage Sense and Limit Setting Registers ...............................78 REVISION HISTORY 6/14—Rev. 0 to Rev. A Changes to Table 2 ............................................................................ 8 Changes to Pin 1, Table 4 ................................................................. 9 Changes to VOUT_COMMAND Section ...................................53 Change to Bit 7, Table 164 ..............................................................89 1/14—Revision 0: Initial Version Rev. A | Page 3 of 92 ADP1050 Data Sheet SPECIFICATIONS VDD = 3.0 V to 3.6 V, TJ = −40°C to +125°C, unless otherwise noted. FSR = full-scale range. Table 1. Parameter SUPPLY Supply Voltage Supply Current Symbol Min Typ Max Unit Test Conditions/Comments VDD IDD 3.0 3.3 28.5 IDD + 6 50 3.6 33 V mA mA μA 2.2 μF capacitor connected to AGND Normal operation; PWM pins unloaded During EEPROM programming Shutdown; VDD below undervoltage lockout (UVLO) threshold V V mV V μs μs VDD rising VDD falling POWER-ON RESET Power-On Reset UVLO Threshold UVLO Hysteresis OVLO Threshold OVLO Debounce VCORE PIN Output Voltage OSCILLATOR AND PLL PLL Frequency Digital PWM Resolution OUTA, OUTB, SR1, SR2 PINS Output Low Voltage Output High Voltage Rise Time Fall Time Output Source Current Output Sink Current VS+, VS− VOLTAGE SENSE PINS Input Voltage Range Leakage Current VS Accurate ADC Valid Input Voltage Range ADC Clock Frequency Register Update Rate Measurement Resolution Measurement Accuracy 2.75 3.7 VCORE VOL VOH tR tF IOL IOH VIN 2.85 35 3.9 2 500 3.0 2.97 4.1 VDD_OV flag debounce set to 2 μs VDD_OV flag debounce set to 500 μs 2.45 2.6 2.75 V 330 nF capacitor connected to AGND 190 200 625 210 MHz ps RES input = 10 kΩ (±0.1%) 0.4 IOH = 10 mA IOL = −10 mA CLOAD = 50 pF CLOAD = 50 pF 10 V V ns ns mA mA 1.6 1.0 V μA Differential voltage from VS+ to VS− 1.6 V MHz ms Bits +5 +80 +2 +32 +1.0 +16 70 +200 % FSR mV % FSR mV % FSR mV ppm/°C mV VDD − 0.4 3.5 1.5 −10 0 1 0 1.56 10 12 −5 −80 −2 −32 −1.0 −16 Temperature Coefficient Voltage Differential from VS− to AGND VS High Speed ADC Equivalent Sampling Frequency Equivalent Resolution Dynamic Range VS UVP Digital Comparator Threshold Accuracy Comparator Update Speed 100 −200 fSAMP fSW 6 ±25 −2 kHz Bits mV +2 82 Rev. A | Page 4 of 92 % FSR µs Factory trimmed at 1.0 V 0% to 100% of input voltage range 10% to 90% of input voltage range 900 mV to 1.1 V fSW = 390.5 kHz Regulation voltage = 0 mV to 1.6 V Triggers VOUT_UV_FAULT flag 10% to 90% of input voltage range Data Sheet Parameter OVP PIN Leakage Current OVP Comparator Voltage Range Threshold Accuracy Propagation Delay (Latency) VF VOLTAGE SENSE PIN Input Voltage Range Leakage Current General ADC Valid Input Voltage Range ADC Clock Frequency Register Update Rate Measurement Resolution Measurement Accuracy ADP1050 Symbol Min 0.75 −1.6 VIN 0 Typ +1 61 1 0 Max Unit 1.0 µA 1.5 +1.6 85 V % ns Differential voltage from OVP to VS− 0.75 V to 1.5 V voltage range Debounce time not included 1.6 1.0 V µA Voltage from VF to AGND 1.6 V MHz ms Bits % FSR mV % FSR mV 1.56 1.31 11 −2 −32 −5 −80 +2 +32 +5 +80 VF UVP Digital Comparator Threshold Accuracy Comparator Update Speed Feedforward ADC Input Voltage Range Resolution Sampling Period CS1 CURRENT SENSE PIN Input Voltage Range Source Current CS1 ADC Valid Input Voltage Range ADC Clock Frequency Register Update Rate Measurement Resolution Measurement Accuracy CS1 OCP Comparator Reference Accuracy Propagation Delay (Latency) CS31 Measurement and Digital Comparator Register Update Rate Comparator Speed Test Conditions/Comments Triggers VOUT_OV_FAULT flag 10% to 90% of input voltage range 0% to 100% of input voltage range Triggers VIN_LOW or VIN_UV_FAULT flag Based on VF general ADC parameter values 1.31 ms VIN 0.5 1 11 10 1.6 V Bits μs VIN 0 −1.2 1 1.6 −0.35 V µA 1.6 +2 +32 +5 +80 V MHz ms Bits % FSR mV % FSR mV 1.215 0.265 105 V V ns 0 1.56 10 12 −2 −32 −5 −80 1.185 0.235 1.2 0.25 65 10 10 Rev. A | Page 5 of 92 ms ms Voltage from CS1 to AGND 10% to 90% of input voltage range 0% to 100% of input voltage range Triggers internal CS1_OCP flag When set to 1.2 V When set to 0.25 V Debounce/blanking time not included Triggers CS3_OC_FAULT flag ADP1050 Parameter RTD TEMPERATURE SENSE PIN Input Voltage Range Source Current Register 0xFE2D = 0xE6 Register 0xFE2D = 0xB0 Register 0xFE2D = 0x80 Register 0xFE2D = 0x40 Register 0xFE2D = 0x00 RTD ADC Valid Input Voltage Range ADC Clock Frequency Register Update Rate Measurement Resolution Measurement Accuracy Data Sheet Symbol Min VIN 0 44.6 38.6 28.6 18.6 9.1 VIN 46 40 30 20 10 0 Max Unit Test Conditions/Comments 1.6 V Voltage from RTD to AGND Factory default setting 47.3 42 31.8 21.6 11 μA μA μA μA μA 1.6 V MHz ms Bits % FSR mV % FSR mV 1.56 10 12 OTP Digital Comparator Threshold Accuracy −0.3 −4.8 −2 −80 +0.45 +7.2 +2 +80 −0.9 −14.4 −0.5 −8 +0.25 +4 +1.1 +17.6 Comparator Update Speed Temperature Readings According to Internal Linearization Scheme PG/ALT (OPEN-DRAIN) PIN Output Low Level CTRL PIN Input Low Level Input High Level Leakage Current SYNI/FLGI PIN Input Low Level Input High Level Synchronization Range % of Internal Clock Period SYNI Positive Pulse Width Typ 10 VOL VIL VIH SYNI Negative Pulse Width 0.4 V Sink current = 10 mA 0.4 V V µA 0.4 110 V V % 360 ns 360 ns 280 ns Leakage Current SDA AND SCL PINS Input Low Voltage Input High Voltage Output Low Voltage Leakage Current 1.0 µA 0.8 V V V µA VDD − 0.8 −5 Rev. A | Page 6 of 92 T = 100°C with 100 kΩ||16.5 kΩ °C °C SYNI Period Drift VIL VIH VOL Triggers OT_FAULT flag T = 85°C with 100 kΩ||16.5 kΩ 7 5 VDD − 0.8 VDD − 0.8 90 0% to 100% of the input voltage range Source current is set to 46 µA (Register 0xFE2D = 0xE6); NTC R25 = 100 kΩ (1%); beta = 4250 (1%); REXT = 16.5 kΩ (1%) 25°C to 100°C 100°C to 125°C 1.0 VIL VIH tSYNC % FSR mV % FSR mV ms 2% to 20% of the input voltage range 0.4 +5 External clock applied on the SYNI/FLGI pin External clock applied on the SYNI/FLGI pin Period drift between two consecutive external clocks Sink current = 3 mA Data Sheet ADP1050 Parameter SERIAL BUS TIMING Clock Operating Frequency Glitch Immunity Bus Free Time Start Setup Time Start Hold Time Symbol Stop Setup Time SDA Setup Time SDA Hold Time SCL Low Timeout SCL Low Time SCL High Time SCL Low Extended Time SCL, SDA Rise Time SCL, SDA Fall Time EEPROM EEPROM Update Time Min Typ Max Unit 10 100 400 50 kHz ns µs µs µs tBUF tSU;STA tHD;STA 1.3 0.6 0.6 tSU;STO tSU;DAT tHD;DAT 0.6 100 125 300 25 0.6 0.6 tTIMEOUT tLOW tHIGH tLOW;SEXT tR tF 20 20 Reliability Endurance 2 Between stop and start conditions Repeated start condition setup time Hold time after repeated start condition; after this period, the first clock is generated 25 300 300 µs ns ns ns ms µs µs ms ns ns 40 ms Time from the update command to completion of the EEPROM update Cycles Cycles Years Years TJ = 85°C TJ = 125°C TJ = 85°C TJ = 125°C 35 10,000 1000 20 15 Data Retention 3 Test Conditions/Comments See Figure 2 For readback For write CS3 is an alternative output current reading that is calculated by the CS1 reading (representing input current), duty cycle, and the main transformer turns ratio. Endurance is qualified as per JEDEC Standard 22, Method A117, and is measured at −40°C, +25°C, +85°C, and +125°C. 3 Retention lifetime equivalent at junction temperature as per JEDEC Standard 22, Method A117. 1 2 TIMING DIAGRAM tR tF tHD;STA tLOW SCL tHIGH tHD;DAT tSU;STA tSU;DAT tSU;STO SDA tBUF P S S Figure 2. Serial Bus Timing Diagram Rev. A | Page 7 of 92 P 12039-002 tHD;STA ADP1050 Data Sheet ABSOLUTE MAXIMUM RATINGS THERMAL RESISTANCE Table 2. Parameter Supply Voltage (Continuous) VDD Digital Pins (OUTA, OUTB, SR1, SR2, PG/ALT, SDA, SCL) to AGND VS−, VS+, VF, OVP, RTD, ADD, CS1 to AGND SYNI/FLGI, CTRL Operating Temperature Range (TA) 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 VDD + 0.3 V −0.3 V to VDD + 0.3 V −40°C to +125°C −65°C to +150°C 150°C 240°C 260°C 1.25 kV 5.0 kV Stresses at or above those listed under Absolute Maximum Ratings may cause permanent damage to the product. This is a stress rating only; functional operation of the product at these or any other conditions above those indicated in the operational section of this specification is not implied. Operation beyond the maximum operating conditions for extended periods may affect product reliability. 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 20-Lead LFCSP θJA 37.05 θJC 1.53 Unit °C/W SOLDERING It is important to follow the correct guidelines when laying out the printed circuit board (PCB) footprint for the ADP1050 and for soldering the device onto the PCB. For detailed information about these guidelines, see the AN-772 Application Note, A Design and Manufacturing Guide for the Lead Frame Chip Scale Package (LFCSP). ESD CAUTION Rev. A | Page 8 of 92 Data Sheet ADP1050 20 19 18 17 16 RTD ADD RES AGND VDD PIN CONFIGURATION AND FUNCTION DESCRIPTIONS ADP1050 TOP VIEW (Not to Scale) 15 14 13 12 11 VCORE PG/ALT CTRL SDA SCL 12039-124 1 2 3 4 5 SR1 6 SR2 7 OUTA 8 OUTB 9 SYNI/FLGI 10 OVP VS– VS+ VF CS1 NOTES 1. THE ADP1050 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 EXPOSED PAD BE SOLDERED TO THE PCB AGND PLANE. Figure 3. Pin Configuration Table 4. Pin Function Descriptions Pin No. 1 2 Mnemonic OVP VS− 3 VS+ 4 VF 5 CS1 6 7 8 9 10 SR1 SR2 OUTA OUTB SYNI/FLGI 11 12 13 SCL SDA CTRL 14 PG/ALT 15 VCORE 16 VDD 17 AGND 18 RES 19 ADD Description Overvoltage Protection. This signal is used as redundant overvoltage protection. This signal is referred to AGND. Inverting Voltage Sense Input. This pin is the connection for the ground line of the power rail. Provide a low ohmic connection to AGND. To allow trimming, it is recommended that the resistor divider on this input have a tolerance specification of ≤0.5%. Noninverting Voltage Sense Input. This signal is referred to VS−. To allow trimming, it is recommended that the resistor divider on this input have a tolerance specification of ≤0.5%. Voltage Feedforward. Three optional functions can be implemented with this pin: feedforward, primary side input voltage sensing, and input voltage UVLO protection. The pin is connected upstream of the output inductor through a resistor divider network. The nominal voltage at this pin is 1 V. This signal is referred to AGND. Primary Side Current Sense Input. This pin is connected to the primary side current sensing ADC and to the cycleby-cycle current-limit comparator. This signal is referred to AGND. To allow trimming, it is recommended that the resistors on this input have a tolerance specification of ≤0.5%. If this pin is not used, connect it to AGND. PWM Logic Output Drive. This pin can be disabled when not in use. This signal is referred to AGND. PWM Logic Output Drive. This pin can be disabled when not in use. This signal is referred to AGND. PWM Logic Output Drive. This pin can be disabled when not in use. This signal is referred to AGND. PWM Logic Output Drive. This pin can be disabled when not in use. This signal is referred to AGND. Synchronization Signal Input (SYNI)/External Signal Input to Generate a Flag Condition (FLGI). If this pin is not used, connect it to AGND. I2C/PMBus Serial Clock Input and Output (Open Drain). This signal is referred to AGND. I2C/PMBus Serial Data Input and Output (Open Drain). This signal is referred to AGND. PMBus Control Signal. It is recommended that a 1 nF capacitor be connected from the CTRL pin to AGND for noise debounce and decoupling. This signal is referred to AGND. Power-Good Output (Open Drain)(PG)/Active Low SMBus ALERT Signal (ALT). Connect this pin to VDD using a pullup resistor (typically 2.2 kΩ). The power-good signal is referred to AGND. For information about the SMBus specification, see the PMBus Features section. Output of the 2.6 V Regulator. Connect a decoupling capacitor of at least 330 nF from this pin to AGND, as close as possible to the ADP1050 to minimize the PCB trace length. It is recommended that this pin not be used as a reference or to generate other logic levels using resistive dividers. Positive Supply Input. Voltage of 3.0 V to 3.6 V. This signal is referred to AGND. Connect a 2.2 μF decoupling capacitor from this pin to AGND, as close as possible to the ADP1050 to minimize the PCB trace length. Common Analog Ground. The internal analog circuitry ground and the digital circuitry ground are star connected to this pin through bonding wires. Resistor Input. This pin sets the internal reference for the internal PLL frequency. Connect a 10 kΩ resistor (±0.1%) from this pin to AGND. This signal is referred to AGND. Address Select Input. This pin is used to program the I2C/PMBus address. Connect a resistor from ADD to AGND. This signal is referred to AGND. Rev. A | Page 9 of 92 ADP1050 Pin No. 20 Mnemonic RTD EP Data Sheet Description Thermistor Input. Place a thermistor (R25 = 100 kΩ (1%), beta = 4250 (1%)) in parallel with a 16.5 kΩ (1%) resistor and a 1 nF filtering capacitor. This pin is referred to AGND. If this pin is not used, connect it to AGND. Exposed Pad. The ADP1050 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 exposed pad be soldered to the PCB AGND plane. Rev. A | Page 10 of 92 Data Sheet ADP1050 TYPICAL PERFORMANCE CHARACTERISTICS 2.5 2.5 MAX SPEC 1.5 1.0 MAX MEAN 0.5 0 –0.5 MIN –1.0 –1.5 0 20 40 60 80 100 120 140 –0.5 MIN –1.0 –1.5 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) Figure 7. RTD ADC Accuracy vs. Temperature (From 10% to 90% of FSR) 1.23 1.5 1.0 MAX 0.5 MEAN 0 –0.5 MIN –1.0 –1.5 MIN SPEC –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) Figure 5. VF ADC Accuracy vs. Temperature (From 10% to 90% of FSR) MAX SPEC 1.21 MAX MEAN 1.20 MIN 1.19 MIN SPEC 1.18 1.17 –60 12039-008 –2.0 1.22 –40 –20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 12039-012 CS1 OCP COMPARATOR REFERENCE (V) MAX SPEC 2.0 Figure 8. CS1 OCP Comparator Reference vs. Temperature (1.2 V Reference) 2.5 0.280 CS1 OCP COMPARATOR REFERENCE (V) MAX SPEC 2.0 1.5 1.0 MAX 0.5 MEAN 0 –0.5 MIN –1.0 –1.5 –2.0 MAX SPEC 0.265 MAX MEAN 0.250 MIN 0.235 MIN SPEC MIN SPEC –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 140 0.220 –60 12039-009 –40 Figure 6. CS1 ADC Accuracy vs. Temperature (From 10% to 90% of FSR) –40 –20 0 20 40 60 TEMPERATURE (°C) 80 100 120 140 12039-113 VF ADC ACCURACY (%FSR) MAX MEAN 0 –2.5 –60 2.5 CS1 ADC ACCURACY (%FSR) 0.5 12039-011 –20 12039-007 –40 Figure 4. VS ADC Accuracy vs. Temperature (From 10% to 90% of FSR) –2.5 –60 1.0 –2.0 MIN SPEC TEMPERATURE (°C) –2.5 –60 1.5 MIN SPEC –2.0 –2.5 –60 MAX SPEC 2.0 RTD ADC ACCURACY (%FSR) VS ADC ACCURACY (%FSR) 2.0 Figure 9. CS1 OCP Comparator Reference vs. Temperature (0.25 V Reference) Rev. A | Page 11 of 92 ADP1050 Data Sheet THEORY OF OPERATION up to four programmable PWM outputs for control of primary side FET drivers and synchronous rectification FET drivers. This programmability allows many generic and specific switching power supply topologies to be realized. The ADP1050 is designed as a flexible, easy to use, digital power supply controller. The ADP1050 integrates the typical functions that are needed to control a power supply, such as Output voltage sense and feedback Voltage feedforward control Digital loop filter compensation PWM generation Current, voltage, and temperature sense Housekeeping and I2C/PMBus interface Calibration and trimming Conventional power supply housekeeping features, such as input voltage sense, output voltage sense, primary side current sense, and secondary side current sense, are included. An extensive set of protections is included, such as overvoltage protection (OVP), overcurrent protection (OCP), overtemperature protection (OTP), and undervoltage protection (UVP). These features are programmable through the I2C/PMBus digital bus interface. This interface is also used for calibrations. Other information, such as input current, output current, and fault flags, is also available through this digital bus interface. The main function of controlling the output voltage is performed by the feedback ADCs, the digital loop compensator, and the digital PWM engine. The feedback ADCs feature a patented multipath architecture, with a high speed, low resolution (fast and coarse) ADC and a low speed, high resolution (slow and accurate) ADC. The ADC outputs are combined to form a high speed and high resolution feedback path. Loop compensation is implemented using the digital compensator. This proportional, integral, derivative (PID) compensator is implemented in the digital domain to allow easy programming of filter characteristics, which is of great value in customizing and debugging designs. The PWM engine generates The internal EEPROM can store all programmed values and allows standalone control without a microcontroller. A free, downloadable GUI is available that provides all the necessary software to program the ADP1050. To obtain the latest GUI software and a user guide, visit http://www.analog.com/digitalpower. The ADP1050 operates from a single 3.3 V power supply and is specified from −40°C to +125°C. VF 1.2V VS+ VS– 0.25V CS1 VREF ADC ADC ADC OVP OUTA OUTB DAC ADC PWM ENGINE RTD DIGITAL CORE ADD SR1 8kB EEPROM SR2 OSC RES PMBus AGND UVLO VDD LDO SYNI/FLGI SCL SDA CTRL PG/ALT Figure 10. Functional Block Diagram Rev. A | Page 12 of 92 VCORE 12039-013 • • • • • • • Data Sheet ADP1050 See the PWM Outputs Timing Registers section for additional information about the PWM timings. PWM OUTPUTS (OUTA, OUTB, SR1, AND SR2) The PWM outputs are used for control of the primary side drivers and the synchronous rectifier drivers. They can be used for several topologies, including hard-switched full bridge, half bridge, push pull, two-switch forward, active clamp forward, and interleaved buck. 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 ADP1050 GUI software be used to program these outputs. SYNCHRONOUS RECTIFICATION SR1 and SR2 are recommended for use as the PWM control signals when synchronous rectification is in use. These PWM signals can be configured much like the other PWM outputs. An optional soft start can be applied to the synchronous rectifier (SR) PWM outputs. The SR soft start can be programmed using Register 0xFE08[4:0]. Figure 11 shows an example configuration to drive an active clamp forward topology with synchronous rectification. The QA, QB, QSR1, and QSR2 switches are driven separately by the PWM outputs (OUTA, OUTB, SR1, and SR2). Figure 12 shows an example of the PWM settings in the GUI for the power stage shown in Figure 11. • • The PWM outputs are all synchronized with each other. Therefore, when reprogramming more than one of these outputs, it is important to first update all of the registers and then latch the information into the shadow registers at one time. During the reprogramming operation, the outputs are temporarily disabled. To ensure that the new PWM timings and the switching frequency setting are programmed simultaneously, a special instruction is sent to the ADP1050 by setting Register 0xFE61[2:1] (the go commands). It is recommended that the PWM outputs not in use be disabled via Register 0xFE53[5:4] and Register 0xFE53[1:0]. • DC INPUT When the SR soft start is disabled (Register 0xFE08[1:0] = 00), the SR signals are immediately turned on to their modulated PWM duty cycle values. When the SR soft start is enabled (Register 0xFE08[1:0] = 11), the SR1 and SR2 rising edges move left from the tRX + tMODU_LIMIT position to the tRX + tMODULATION position in steps that are set in Register 0xFE08[3:2]. tRX represents the rising edge timing of SR1 (tR5) and the rising edge timing of SR2 (tR6) (see Figure 58); tMODU_LIMIT represents the modulation limit defined in Register 0xFE3C (see Figure 57); tMODULATION represents the real-time modulation value. The SR soft start is still applicable even if the SR1 and SR2 outputs are not programmed to be modulated. When the SR soft start is enabled, the SR1 and SR2 rising edges move left from the tRX + tMODU_LIMIT position to the tRX position in steps that are set in Register 0xFE08[3:2]. QSR2 QSR1 DRIVER QA QB ISOLATED DRIVER SR2 OUTA OUTB 12039-120 SR1 12039-121 Figure 11. PWM Assignment for Active Clamp Forward Topology with Synchronous Rectification Figure 12. PWM Settings for Active Clamp Forward Topology with Synchronous Rectification Using the ADP1050 GUI Rev. A | Page 13 of 92 ADP1050 Data Sheet The advantage of the SR soft start is that it minimizes the output voltage undershoot that occurs when the SR FETs are turned on without a soft start. The advantage of turning the SRx signals completely on immediately is that they can help minimize the voltage transient caused during a load step. Using Register 0xFE08[4], the SR soft start can be programmed to occur only once (the first time that the SRx signals are enabled) or every time that the SRx signals are enabled. When programming the ADP1050 to use the SR soft start, ensure the correct operation of this function by setting the falling edge of SR1 (tF5) to a lower value than the rising edge of SR1 (tR5) and setting the falling edge of SR2 (tF6) to a lower value than the rising edge of SR2 (tR6). During the SR soft start, the rising edges of SRx move gradually from the right side (the tRX + tMODU_LIMIT position) to the left side to increase the duty cycle. The ADP1050 is well suited for dc-to-dc converters in isolated topologies. Every time a PWM signal crosses the isolation barrier, a propagation delay is added because of the isolating components. Using Register 0xFE3A[5:0], an adjustable delay (0 ns to 315 ns in steps of 5 ns) can be programmed to move both SR1 and SR2 later in time to compensate for the added propagation delay. In this way, all the PWM edges can be aligned (see Figure 58). The modulated edges cannot go beyond one switching cycle. To extend the modulation range for some applications, the 180° phase shift can be enabled, using Register 0xFE3B[5:4] and Register 0xFE3B[1:0]. When the 180° phase shift is disabled, the rising edge timing and the falling edge timing are referred to the start of the switching cycle (see tRX and tFX in Figure 13). When the 180° phase shift is enabled, the rising edge timing and the falling edge timing are referred to half of the switching cycle (see tRY and tFY in Figure 13, which are referred to tS/2). Therefore, when the 180° phase shift is disabled, the edges are always located between t0 and tS. When the 180° phase shift is enabled, the edges are located between tS/2 and 3tS/2. The 180° phase shift function can be used to extend the maximum duty cycle in a multiphase, interleaved converter. Figure 14 shows a dual phase, interleaved buck converter. The OUTB and SR1 PWM outputs can be programmed with a 180° phase shift with the OUTA and SR2 PWM outputs. The ADP1050 GUI is recommended for evaluating this feature. DC INPUT DRIVER LOAD PWM MODULATION LIMIT AND 180° PHASE SHIFT tRX tFX tMODU_LIMIT OUTY tFY tS/2 tS 3tS/2 12039-015 tRY t0 12039-118 SR1 SR2 OUTB Figure 14. Dual Phase, Interleaved Buck Converter Controlled by the ADP1050 FREQUENCY SYNCHRONIZATION The ADP1050 can be programmed as a slave device to use the SYNI/FLGI pin signal as the reference to synchronize the internal programmed PWM clock with an external clock. tMODU_LIMIT OUTX DRIVER OUTA The modulation limit register (Register 0xFE3C) can be programmed to apply a maximum modulation limit to any PWM signal, thus limiting the modulation range of any PWM output. If modulation is enabled, the maximum modulation limit is applied to all PWM outputs collectively. This limit, tMODU_LIMIT, is the maximum time variation for the modulated edges from the default timing, following the configured modulation direction (see Figure 13). There is no setting for the minimum duty cycle limit. Therefore, the user must set the rising edges and falling edges based on the case with the least modulation. Figure 13. Setting Modulation Limits Each least significant bit (LSB) in Register 0xFE3C corresponds to a different time step size, depending on the switching frequency (see Table 137). If the ADP1050 is to control a dual-ended topology (such as full bridge, half bridge, or push pull), enable the dual-ended topology mode using Register 0xFE13[6]. When dual-ended topology mode is enabled, the modulation limit in each half cycle is half of the modulation value programmed by Register 0xFE3C. The period of the external clock that is applied at the SYNI/FLGI pin must be in the range of 90% to 110% of the period of the internal programmed PWM clock. The minimum pulse width of the SYNI signal is 360 ns. From the rising edge of the SYNI signal to the start of the internal clock cycle, there is a 760 ns propagation delay. To realize interleaving control with different controllers, additional delay time can be programmed using Register 0xFE11. To achieve a smooth synchronization transition between asynchronous operation and synchronous operation, there is a phase capture range bit for synchronization in Register 0xFE12[6] for capturing the phase of the external clock signal. The ADP1050 detects the phase shift between the external clock signal and the internal clock signal when synchronization is enabled. When the phase shift falls within the phase capture range, synchronization begins. Rev. A | Page 14 of 92 Data Sheet ADP1050 The ADP1050 synchronizes to the external clock frequency as follows: 2. 3. 4. 5. After the synchronization function is enabled by Register 0xFE12[3] and Register 0xFE12[0], the ADP1050 starts to detect the period of the external clock signal applied at the SYNI/FLGI pin. If all periods of the most recent 64 consecutive cycles of the external clocks fall within 90% to 110% of the internal switching clock period, the ADP1050 uses the latest current cycle as the synchronization reference, and the period of the external clock is identified. This interval is t2 or t4, as shown in Figure 15. Otherwise, the ADP1050 discards this cycle and looks for the next cycle (frequency capture mode). After the external clock period is determined, the ADP1050 detects the phase shift between the external clock (plus the delay time set by Register 0xFE11) and the internal PWM signal. If the phase shift is within the phase capture range, the internal and external clocks are synchronized (phase capture mode). The PWM clock is synchronized with the external clock. Cycleby-cycle synchronization starts. If the external clock signal is lost at any time, or if the period exceeds the minimum limit (89% of the internal programmed frequency) or the maximum limit (114% of the internal programmed frequency), the ADP1050 takes the last valid external clock signal as the synchronization reference source. At the same time, the phase shift between the synchronization reference and the internal clock is detected. When the phase shift falls within the phase capture range, the PWM clock 6. Figure 15 shows the synchronization operation diagram. The internal frequency, fSW_INT, is the internal free-running frequency of the ADP1050. Before the synchronization is locked, the ADP1050 runs at fSW_INT. The external frequency, fSW_EXT, is the frequency of the external clock to which the ADP1050 must synchronize. After synchronization is locked, the ADP1050 runs at fSW_EXT. The ADP1050 does not allow the switching frequency to cross the boundaries of 97.5 kHz, 195.5 kHz, or 390.5 kHz on-the-fly. Ensure that the external clock does not cross these boundaries. Otherwise, the internal switching frequency cannot be set within ±10% of these boundaries. EXTERNAL CLOCK FREQUENCY (fSW_EXT ) INTERNAL CLOCK FREQUENCY (fSW_INT) OPERATING SWITCHING FREQUENCY fSW t1 t2 t3 t4 114% f SW_INT 110% f SW_INT fSW_INT 90% fSW_INT 89% fSW_INT UNIT ON UNIT OFF UNIT ON Figure 15. Synchronization Operation Rev. A | Page 15 of 92 TIME 12039-018 1. returns to the internal clock set by the internal oscillator. This interval is t1 or t3, as shown in Figure 15. This is the first synchronization unlock condition, called Synchronization Unlocked Mode 1, in which the switching frequency is out of range (range is 89% to approximately 114% of the internal programmed frequency). If the period of the external SYNI signal changes significantly (for example, if the period difference between contiguous cycles exceeds 280 ns), the ADP1050 takes the last valid external clock signal as the synchronization reference source. At the same time, the phase shift between the synchronization reference and the internal clock is detected. When the phase shift falls within the phase capture range, the PWM clock returns to the internal clock set by the internal oscillator. This is the second synchronization unlock condition, called Synchronization Unlocked Mode 2, in which the phase shift exceeds 280 ns. ADP1050 Data Sheet ±3.125% SYNI ENABLE REG 0xFE12[3] SYNI/FLGI SELECTION REG 0xFE12[0] 320ns DEBOUNCE SYNI MODE SYNI/FLGI FLGI MODE POLARITY REG 0xFE12[2] SYNI DELAY TIME SETTING REG 0xFE11 PHASE CAPTURE RANGE SELECTION REG 0xFE12[6] 0µs DEBOUNCE ±6.25% SYNC OPERATION AS SLAVE DEVICE FLAGIN FLAG RESPONSE REG 0xFE03[3:2] DEBOUNCE TIME REG 0xFE12[1] 12039-017 100µs DEBOUNCE 12039-122 Figure 16. Synchronization Configuration Figure 17. Edge Adjustment Reference During Synchronization OUTPUT VOLTAGE SENSE AND ADJUSTMENT The output voltage sense and adjustment function is used for control, monitoring, and undervoltage protection of the remote output voltage. VS− (Pin 2) and VS+ (Pin 3) are fully differential inputs. The voltage sense point can be calibrated digitally to remove any 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 ADP1050 (see the Power Supply Calibration and Trim section for more information). Voltage Feedback Sensing (VS+ and VS− Pins) The voltage sense point on the power rail requires an external resistor divider (R1 and R2 in Figure 18) to bring the nominal differential mode signal to 1 V between the VS+ and VS− pins (see Figure 18). This external resistor divider is necessary because the VS ADC input range of the ADP1050 is 0 V to 1.6 V. When R1 and R2 are known, the VOUT_SCALE_LOOP parameter can be calculated using the following equation: VOUT_SCALE_LOOP = R2/(R1 + R2) In a 12 V system with resistor dividers of 11 kΩ and 1 kΩ, VOUT_SCALE_LOOP can be calculated as follows: VOUT_SCALE_LOOP = 1 kΩ/(11 kΩ + 1 kΩ) = 0.08333 LOAD For voltage monitoring, the READ_VOUT output voltage command (Register 0x8B) is updated every 10 ms. The ADP1050 stores every ADC sample for 10 ms and then calculates the average value at the end of the 10 ms period. Therefore, if Register 0x8B is read at least every 10 ms, a true average value is obtained. The voltage information is available through the I2C/PMBus interface. The control loop of the ADP1050 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 compensator to provide a high performance and cost competitive solution. DIGITAL COMPENSATOR VOLTAGE SENSE REGISTERS VOUT_UV_FAULT FLAG Rev. A | Page 16 of 92 HIGH SPEED ADC ACCURATE ADC VS+ R1 VS– R2 VOUT_UV_FAULT_LIMIT Figure 18. Voltage Sense Configuration 12039-020 To ensure a constant dead time before and after synchronization, Register 0xFE6D and Register 0xFE6F can be set for edge adjustment referred to tS/2 or tS. For example, the falling edge of OUTA (tF1) is referred to the ½ × tS position, which means that the time difference between tF1 and ½ × tS is a constant during the synchronization transition. Figure 17 shows an example of the edge adjustment reference settings in a full bridge topology. Data Sheet ADP1050 Voltage Sense ADCs Output Voltage Adjustment Commands Two kinds of Σ-Δ ADCs are used in the ADP1050 feedback loop, as follows: In the ADP1050, the voltage data for commanding or reading the output voltage or related parameters is in linear data format. The linear format exponent is fixed at −10 decimal (see the VOUT_MODE command, Register 0x20, in Table 21). • • Low frequency (LF) ADC, running at 1.56 MHz High frequency (HF) ADC, running at 25 MHz The Σ-Δ ADCs have a resolution of one bit and operate differently from traditional flash ADCs. The equivalent resolution that is obtained depends on how long the output bit stream of the Σ-Δ ADC is filtered. NYQUIST ADC NOISE Σ-Δ ADC NOISE FREQUENCY VOUT_COMMAND command (Register 0x21, Table 22) VOUT_MARGIN_HIGH command (Register 0x25, Table 26) VOUT_MARGIN_LOW command (Register 0x26, Table 27) One of these three values is selected by the OPERATION command (Register 0x01, Table 13). The VOUT_MAX command (Register 0x24, Table 25) sets an upper limit on the output voltage that the ADP1050 can command, regardless of any other commands or combinations. DIGITAL COMPENSATOR Figure 19. ADC Noise Performance The low frequency ADC runs at approximately 1.56 MHz. For a specified bandwidth, the equivalent resolution is calculated as ln(1.56 MHz/BW)/ln(2) = N bits For example, at a bandwidth of 95 Hz, the equivalent resolution/ noise is ln(1.56 MHz/95 Hz)/ln(2) = 14 bits At a bandwidth of 1.5 kHz, the equivalent resolution/noise is ln(1.56 MHz/1.5 kHz)/ln(2) = 10 bits The high frequency ADC has a 25 MHz clock. It is comb filtered and outputs at the switching frequency into the digital compensator. See Table 5 for equivalent resolutions at selected sampling frequencies. Table 5. Equivalent Resolutions for High Frequency ADC at Selected Switching Frequencies fSW (kHz) 49 to 87 97.5 to 184 195.5 to 379 390.5 to 625 • • • During output voltage adjustment, use the VOUT_TRANSITION_ RATE command (Register 0x27, Table 28) to set the rate (in mV/µs) at which the VS± pins change voltage. 12039-021 MAGNITUDE The 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 decreases. At higher frequencies, the noise increases (see Figure 19). The following three basic commands are used for setting the output voltage: High Frequency ADC Resolution (Bits) 9 8 7 6 The high frequency ADC has a range of ±25 mV. Using a base switching frequency of 97.5 kHz at an 8-bit HF ADC resolution, the quantization noise is 0.195 mV (1 LSB = 2 × 25 mV/28 = 0.195 mV). When the switching frequency increases to 195.5 kHz at a 7-bit HF ADC resolution, the quantization noise is 0.391 mV (1 LSB = 2 × 25 mV/27 = 0.391 mV). Increasing the switching frequency to 390.5 kHz increases the quantization noise to 0.781 mV (1 LSB = 2 × 25 mV/26 = 0.781 mV). Use the internal programmable digital compensator to change the control loop of the power supply. A Type III digital compensator architecture has been implemented. This Type III compensator is reconstructed by a low frequency filter, with input from the low frequency ADC, and a high frequency filter, with input from the high frequency ADC. From the voltage sense ADC outputs to the digital compensator output, the transfer function of the digital compensator in z-domain is as follows: H (z ) = d z c z −b × + × 204.8 × m z − 1 12.8 z − a where: a = HF filter pole register value/256 (Register 0xFE32/256). b = HF filter zero registers value/256 (Register 0xFE31/256). c = HF filter gain register value (Register 0xFE33). d = LF filter gain register value (Register 0xFE30). m is the scale factor, as follows: m = 1 when 49 kHz ≤ fSW < 97.5 kHz m = 2 when 97.5 kHz ≤ fSW < 195.5 kHz m = 4 when 195.5 kHz ≤ fSW < 390.5 kHz m = 8 when 390.5 kHz ≤ fSW To tailor the loop response to the specific application, the low frequency gain (represented by d), the zero location of the HF filter (represented by b), the pole location of the HF filter (represented by a), and the high frequency gain (represented by c) can all be set up individually (see the Digital Compensator and Modulation Setting Registers section). Rev. A | Page 17 of 92 ADP1050 Data Sheet It is recommended that the ADP1050 GUI be used to program the compensator. The GUI displays the filter response, using a Bode plot in the s-domain, and calculates all stability criteria for the power supply. 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 FROM THE VIN SENSE CIRCUIT 2 f SW − s READ_VIN REG 0x88 The filter introduces an extra phase delay element into the control loop. The digital compensator circuit sends the information about the duty cycle to the digital PWM engine at the beginning of each switching cycle (unlike an analog controller, which makes decisions on the duty cycle information continuously). There is an additional delay for ADC sampling and decimation filtering. This extra phase delay for phase margin (Φ) is expressed as follows: Φ = 360 × fC/fSW Σ-Δ ADC VIN_UV_FAULT FLAG REG 0x7C[4] 0V TO 1.6V VIN_LOW FLAG REG 0x7C[3] R1 VF REG 0x35, REG 0x36 REG 0xFE29[5] 1/x DPWM ENGINE R2 FEEDFORWARD ADC 0.5V TO 1.6V DIGITAL COMPENSATOR 12039-022 where s is the s-domain value. Figure 20. Closed-Loop Input Voltage Feedforward Configuration where fC is the crossover frequency. fSW is the switching frequency. At one-tenth the switching frequency, the phase delay is 36°. The GUI incorporates this phase delay into its calculations. Note that the ADP1050 GUI does not account for other delays, such as gate driver and propagation delay. The main compensator, called the normal mode compensator, is programmed using Register 0xFE30 to Register 0xFE33. In addition, a dedicated filter is used during soft start. The filter is disabled at the end of the soft start routine, after which the voltage loop digital compensator is used. The soft start filter gain is a programmable value of 1, 2, 4, or 8, using Register 0xFE3D[1:0]. CLOSED-LOOP INPUT VOLTAGE FEEDFORWARD CONTROL AND VF SENSE The ADP1050 supports closed-loop input voltage feedforward control to improve input transient performance. The VF value is sensed by the feedforward ADC and is used to divide the output of the digital compensator. The result is fed into the digital PWM engine. The input voltage signal can be sensed at the center tap in the secondary windings of the isolation transformer and must be filtered by a residual current device (RCD) circuit network to eliminate the voltage spike at the switching node. Alternatively, the input voltage signal can be sensed from a winding of the auxiliary power transformer. If the digital compensator output remains unchanged and the VF voltage changes to 200% of its original value (still less than 1.6 V), the modulation of the OUTx edges that are configured for modulation is divided by 2 (see Figure 21). Register 0xFE3D[3:2] is used to program the optional input voltage feedforward function. The VF pin also has a low speed, high resolution Σ-Δ ADC. The ADC has an update rate of 800 Hz with 11-bit resolution. The ADC output value is stored in Register 0xFEAC and converted to the READ_VIN command (Register 0x88). This value provides information for the input voltage monitoring and flag functions. VF DIGITAL FILTER OUTPUT tMODULATION tMODULATION OUTx tS tS 12039-023 z(s) = As shown in Figure 20, the feedforward scheme modifies the modulation value, based on the VF voltage. When the VF input is 1 V, the line voltage feedforward has no effect. For example, if the digital compensator output remains unchanged and the VF voltage changes to 50% of its original value (still greater than 0.5 V), the modulation of the OUTx edges that are configured for modulation doubles. Figure 21. Closed-Loop Input Voltage Feedforward Changes Modulation Values The VF pin (Pin 4) voltage must be set to 1 V when the nominal input voltage is applied. The feedforward ADC sampling period is 10 μs. Therefore, the decision to modify the PWM outputs, based on the input voltage, is performed at this rate. Rev. A | Page 18 of 92 Data Sheet ADP1050 OPEN-LOOP INPUT VOLTAGE FEEDFORWARD OPERATION The ADP1050 can run in open-loop input voltage feedforward operation mode. In this mode, the input voltage is sensed as the feedforward signal for the generation of the PWM outputs. As shown in Figure 22, the digital compensator output is modified by a programmable modulation reference. The VF value, which represents the input voltage, is fed into the feedforward ADC to divide the modulation reference. The result of this division is then fed into the PWM engine. The duty cycle value is in inverse proportion to the input voltage. FROM THE VIN SENSE CIRCUIT READ_VIN REG 0x88 Σ-Δ ADC VIN_UV_FAULT FLAG REG 0x7C[4] 0V TO 1.6V REG 0xFE29[5] 1/x FEEDFORWARD ADC 0.5V TO 1.6V MODULATION REFERENCE REG 0xFE63 AND REG 0xFE64 DPWM ENGINE Figure 22. Open-Loop Feedforward Operation Use the following equations to derive the output voltage equation: D= V IN _ NOM The flag settings for open-loop feedforward operation are also similar to those of general closed-loop operation. Because the output voltage is not regulated in the same manner as in closed-loop operation, some settings, such as the VOUT setting, the digital compensator settings, and the constant current mode setting, are not functional. Other settings can be programmed in a manner that is similar to general closed-loop operation. OPEN-LOOP OPERATION VF REG 0x35, REG 0x36 12039-024 VIN_LOW FLAG REG 0x7C[3] The PWM settings for open-loop input voltage feedforward operation are similar to those of general closed-loop operation. The falling edge timings, rising edge timings, and modulation are set in the same manner as for closed-loop operation, by using Register 0xFE3E to Register 0xFE52. Register 0xFE09[4:3] sets the soft start speed of the modulation edges. Register 0xFE3D[6] enables open-loop feedforward operation. Register 0xFE3D[7] is used to enable the soft start procedure for open-loop feedforward operation. The ADP1050 can also run in open-loop operation mode. In this mode, the rising edges and falling edges of the PWM outputs are fixed during normal operation. Therefore, the output voltage varies with the input voltage. The topologies include full bridge, half bridge, and push pull converters. The PWM settings for open-loop operation are different from those of general closed-loop operation. 1. × (tREF × fSW) V IN and VOUT = 2. V IN × D 3. n The output voltage can then be derived by VOUT = V IN _ NOM × (t REF × f SW ) 4. n where: D is the duty cycle value. VIN_NOM is the nominal input voltage. VIN is the input voltage. VOUT is the output voltage. n is the turns ratio of the main transformer. tREF is the modulation reference, which is set by Register 0xFE63 and Register 0xFE64. fSW is the switching frequency. 5. Set the rising edge timings and falling edge timings using Register 0xFE3E to Register 0xFE4F. Typically, a duty cycle setting of ~50% is recommended for ease of zero voltage switching operation. A phase shift function of 180° is recommended to guarantee balanced PWM outputs. Program Register 0xFE3C to a value of 0x00, which sets the modulation limit to 0 µs. For soft start, apply negative modulation to the falling edges of the OUTA and OUTB outputs. The soft start of SR1 and SR2 is not recommended. Write 111111 to Register 0xFE67[5:4] and Register 0xFE67[1:0] to set all PWM channels to follow open-loop operation. Set Register 0xFE09[7] to enable the soft start procedure. The soft start speed is specified by Register 0xFE09[4:3]. Always set Register 0xFE09[2] = 1. The soft start ramp time is determined by tF2 − tR2. Because the output voltage is not regulated, some of the settings, such as the VOUT setting, digital compensator settings, and constant current control, are not functional. Other settings can be programmed to be similar to those of general closed-loop operation. In the equation to derive VOUT, the input voltage, VIN, is cancelled out. Therefore, the output voltage does not change when the input voltage changes. Register 0xFE63 and Register 0xFE64 set the modulation reference, based on the target output voltage and the nominal input voltage at which the VF pin voltage is 1 V (see Figure 22). Rev. A | Page 19 of 92 ADP1050 Data Sheet CS1 CURRENT SENSE (CS1 PIN) The CS1 current sense input (Pin 5) senses, protects, and controls the primary side input. CS1 can be calibrated to reduce errors due to the external components. Current Sense 1 (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 1.60 V. The input signal is also fed into an analog comparator for cycle-by-cycle current limiting and IIN overcurrent fast protection, with a reference of 0.25 V or 1.2 V set by Register 0xFE1B[6]. The typical configuration for the CS1 current sense is shown in Figure 23. VIN Various IIN overcurrent fast fault limits and response actions can be set for CS1. These are described in the Current Sense and Limit Setting Registers section. SOFT START AND SHUTDOWN On/Off Control The OPERATION command (Register 0x01) and the ON_OFF_ CONFIG command (Register 0x02) control the power-on and power-off behavior of the ADP1050. The OPERATION command turns the ADP1050 on and off in conjunction with input from the CTRL pin (Pin 13). The combination of the CTRL pin input and the serial bus commands required to turn the ADP1050 on and off is configured by the ON_OFF_CONFIG command. When the ADP1050 is commanded to turn on, the power supply on (PSON) signal is enabled, and the ADP1050 follows the soft start procedure to begin the power conversion. Soft Start CS1 ADC REFERENCE REG 0xFE1B[6] CYCLE-BY-CYCLE CURRENT LIMITING AND IIN FAST OCP 12039-025 12 BITS Figure 23. Current Sense 1 (CS1) Operation After VDD power-up and initialization, the PSON signal is enabled when the ADP1050 is commanded to turn on. The controller waits for a user specified turn-on delay (TON_DELAY, Register 0x60) before initiating output voltage soft start ramp. The soft start is then performed by actively regulating the output voltage and digitally ramping up the target voltage to the commanded voltage setpoint. The rise time of the voltage ramp is programmed, using the TON_ RISE command (Register 0x61) to minimize the inrush currents associated with the start-up voltage ramp. A nonzero prebiased voltage results in a longer turn-on delay and shorter rise time. The CS1 ADC is used to measure the average value of the primary side current. The ADC samples at a frequency of 1.56 MHz and reports a CS1 reading (12 bits) in the READ_IIN command (Register 0x89), with an asynchronously averaged rate of 10 ms, 52 ms, 105 ms, or 210 ms set by Register 0xFE65[1:0]. ON ALWAYS ON CTRL PIN IMMEDIATE OFF VOUT COMMAND OFF REG 0x02[1] VOUT MARGIN LOW REG 0x02[0] IMMEDIATE OFF OPERATION (SOFTWARE) ON/OFF OPERATION DELAY OFF VOUT MARGIN HIGH REG 0x02[4:2] REG 0x01[5:4] ON DELAY OFF 12039-029 REG 0x01[7:6] Figure 24. On/Off Control Diagram Rev. A | Page 20 of 92 Data Sheet ADP1050 TON_DELAY REG 0x60 t0 TON_RISE REG 0x61 t1 HF ADC SETTLING DEBOUNCE REG 0xFE3D[5:4] t2 PGOOD DEBOUNCE REG 0xFE0E[3:2] t3 t4 PSON SIGNAL VOUT SOFT_START_FILTER FLAG REG 0xFEA2[0] 12039-030 POWER_OFF FLAG REG 0x78[6] AND REG 0x79[6] PG/ALT PIN Figure 25. Soft Start Timing Diagram When the user turns on the power supply, the following soft start procedure is initiated (see Figure 25): 1. 2. 3. 4. 5. At t0, the PSON signal is enabled by using the OPERATION command, the ON_OFF_CONFIG command, and/or the CTRL pin. The ADP1050 verifies that the initial flags indicate no abnormalities. The ADP1050 waits for the programmed TON_DELAY time to ramp up the power stage voltage at t1. The soft start filter gain (set by Register 0xFE3D[1:0]) is used for closed-loop control. The soft start begins to ramp up the internal reference. The soft start ramp time is programmed using the TON_RISE command. At t2, the soft start ramp reaches the output voltage setpoint. The high frequency ADC starts to settle. Additional high frequency ADC settling debounce time can be programmed using Register 0xFE3D[5:4]. If the debounce time is used, the high frequency ADC is activated at t3. The period between t2 and t3 is the high frequency ADC settling debounce time. At t3, the control loop is switched from the soft start filter to the normal filter. If no faults are present, the PGOOD signal waits for the programmed clearing debounce time (Register 0xFE0E[3:2]) before the PG/ALT pin is pulled high at t4. If a fault condition occurs during the soft start ramp (the time set by the TON_RISE command, t1 to t2), the ADP1050 responds as programmed, unless the flag is blanked during soft start. The user can program which flags are active during the soft start. All flags are active at the end of the soft start ramp (t2). See the Flag Blanking During Soft Start section for more information. The SR1 and SR2 outputs and the volt-second balance functions can also be disabled during the soft start ramp. For more information, see the Synchronous Rectification section and the Volt-Second Balance Control section, respectively. Digital Filters During Soft Start A dedicated soft start filter is used during soft start. The soft start filter is a pure low frequency filter with a programmable gain. The filter is disabled at the end of the soft start routine (t2), and then the general digital compensator is used. The soft start filter gain is programmed using Register 0xFE3D[1:0]. The soft start filter is used during the ramp time of the voltage reference, until the VS high frequency ADC is settled. The user can program (using Register 0xFE3D[4]) whether a high frequency ADC debounce time is added. The high frequency ADC debounce time is the interval from when the high frequency ADC is settled to when the frequency filter takes action. The debounce time can be programmed at 5 ms or 10 ms using Register 0xFE3D[5]. During the time when the soft start filter is in use, the SOFT_ START_FILTER flag is set. It is recommended that a high frequency ADC debounce time not be used if the fast load transient occurs during soft start. Software Reset The software reset command allows the user to perform a software reset of the ADP1050. When a 1 is written to Register 0xFE06[0], the power supply is immediately turned off and then restarted with a soft start following a restart delay. The restart delay time can be programmed as 0 ms, 500 ms, 1 sec, or 2 sec (Register 0xFE07[1:0]). If both TON_DELAY and the restart delay are programmed with 0 ms, a write to Register 0xFE06[0] does nothing. Shutdown When the ADP1050 is commanded to turn off, the PSON signal is cleared. Depending on the setting of the OPERATION command, the ADP1050 shuts down immediately or waits for a user specified turn-off delay (TOFF_DELAY) prior to the shutdown action. If the ADP1050 is turned off because a fault condition occurs, the shutdown actions are programmed by the specific fault flag responses. See the Power Monitoring, Flags, and Fault Responses section for more information. The PGOOD flag setting debounce time can be programmed in Register 0xFE0E[1:0]). This debounce time is from when the PGOOD setting condition is met to when the PGOOD flag is set and the PG/ALT pin is pulled low. Rev. A | Page 21 of 92 ADP1050 Data Sheet Power-Good Signals VOLT-SECOND BALANCE CONTROL The ADP1050 has an open-drain, power-good pin, PG (PG/ALT, Pin 14). When the pin is logic high, the power is good. The ADP1050 also has a power-good flag, PGOOD, which is a negation of power good. When this flag is set, it indicates that the power is not good. The PG/ALT pin and the PGOOD flag can be programmed to respond to the flags from the following list: The ADP1050 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. The circuit monitors the current flowing in both legs of the full bridge topology and stores this information. It compensates the selected PWM signals to ensure equal current flow in the two legs of the full bridge topology. The CS1 pin is used as the input for this function. VIN_UV_FAULT IIN_OC_FAST_FAULT VOUT_OV_FAULT VOUT_UV_FAULT OT_FAULT OT_WARNING Register 0xFE0D is used to program the masking of these flags, which prevents them from setting the PGOOD flag and driving the PG/ALT pin low. Register 0xFE0E[1:0] is used to set the debounce time to drive the PG/ALT pin low and set the PGOOD flag (see Figure 26). The POWER_GOOD_ON command (Register 0x5E) sets the voltage limit that the output voltage must exceed before the POWER_GOOD flag (Register 0x79[11]) can be cleared. Similarly, the output voltage must fall below the POWER_GOOD_ OFF limit (Register 0x5F) for the POWER_GOOD flag to be set. The PG/ALT pin is always driven low and the PGOOD flag is always set when one of the POWER_OFF, SOFT_START_FILTER, CRC_FAULT, or POWER_GOOD flags is set. The debounce timings for setting and clearing the PGOOD flag can be programmed to 0 ms, 200 ms, 320 ms, or 600 ms in Register 0xFE0E[3:0]. VIN_UV_FAULT DEBOUNCE IIN_OC_FAST_FAULT DEBOUNCE VOUT_OV_FAULT DEBOUNCE VOUT_UV_FAULT DEBOUNCE OT_FAULT DEBOUNCE OT_WARNING DEBOUNCE 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, using Register 0xFE54[2]. The balance control gains are programmable via Register 0xFE54[1:0]. The compensation of the PWM drive signals is performed on the edges of two selected outputs, using Register 0xFE55 and Register 0xFE57. The direction of the modulation is also programmable in these registers. The volt-second balance control can be disabled during soft start using Register 0xFE0C[1]. There are also leading edge blanking functions at the sensed CS1 signal for more accurate control results. The blanking time follows the CS1 cycle-by-cycle current-limit blanking time (see the CS1 Current Sense section). To avoid the wrong compensation in light load condition, there is a CS1 threshold in Register 0xFE38 to enable volt-second balance. Below this threshold, volt-second balance is not enabled. PGOOD FLAG REG 0xFEA0[6] DEBOUNCE REG 0xFE0E[3:0] REG 0xFE0D REG 0xFE0F PG/ALT PIN POWER_OFF SOFT_START_FILTER 12039-031 CRC_FAULT POWER_GOOD Figure 26. PGOOD Programming Rev. A | Page 22 of 92 Data Sheet ADP1050 PULSE SKIPPING The pulse skipping function can reduce the switching loss under very light load current conditions while keeping the output voltage stable. Register 0xFE67[6] can be set to activate this function. As the output current falls, the supply enters discontinuous conduction mode (DCM). In DCM, the modulation value is a function of the load current. If a very light load current requires a modulation value (duty cycle) of less than the threshold set by Register 0xFE69, pulse skipping mode is enabled. In pulse skipping mode, the PWM output appears intermittently. If the digital compensator signals an error requiring a modulation value that is less than the threshold set by Register 0xFE69, no PWM pulses are generated. If the digital compensator signals an error requiring a modulation value that is greater than the threshold that is set by Register 0xFE69, PWM pulses are generated. Pulse skipping mode is always blanked during soft start. VOUT is the output voltage sensed on the VS± pins. VOUT_NOM is the nominal output voltage set by VOUT_COMMAND (Register 0x21). VIN_NOM is the nominal input voltage when the VF pin voltage = 1 V. VIN is the sensed input voltage. In addition, Register 0xFE6C[1] is set for correct operation. To sense the input voltage (represented by VF) when the power supply is off, use additional circuitry, such as an auxiliary power circuit, to sense the input voltage. If the input voltage signal is not available when the power is off, the tMODU_INI value is calculated based on the tMODU_NOM and the output voltage information. In this case, Register 0xFE6C[1] is cleared to 0. The initial modulation value is calculated as follows: t MODU _ INI = t MODU _ NOM × PREBIAS STARTUP The prebias start-up function provides the capability to start up the ADP1050 with a prebiased voltage on the output. It protects the power supply against existing external voltage on the output during startup and ensures a monotonic startup before the power supply reaches full regulation (see Figure 27). PSON VOUT 12039-033 The prebias start-up function is enabled by Register 0xFE25[7]. During prebias startup, the ADP1050 soft start ramp starts at the existing voltage value sensed on the VS± pins, and the soft start ramp time is reduced proportionally. The initial PWM modulation value does not begin with zero but, instead, with a value that builds a balanced relationship between the input voltage and the output voltage. This balance avoids the sudden charging or discharging of the output capacitor and achieves a monotonic and smooth startup. The initial modulation value is calculated by the following equation: VOUT VOUT _ NOM × where: tMODU_INI is the initial modulation value when the controller begins to generate PWM pulses during startup. tMODU_NOM is the modulation value set by Register 0xFE39. This value emulates the modulation value when the input voltage and the output voltage are in the nominal condition. VOUT is the output voltage sensed on the VS± pins. VOUT_NOM is the nominal output voltage set by VOUT_COMMAND (Register 0x21). SR soft start can also be enabled in this mode to achieve a smooth transition. See the Synchronous Rectification section for more information. Figure 27. Prebias Startup t MODU _ INI = t MODU _ NOM × VOUT _ NOM If the closed-loop line voltage feedforward function is selected, the input voltage is introduced from the feedforward loop, and the VIN value is always included for calculation of the initial modulation value. 0V PWM OUTPUTS VOUT V IN _ NOM V IN where: tMODU_INI is the initial modulation value when the controller begins to generate PWM pulses during startup. tMODU_NOM is the modulation value set by Register 0xFE39. This value emulates the modulation value when the input voltage and the output voltage are in the nominal condition. VDD AND VCORE When the voltage of the VDD pin (VDD) is applied, there is a delay before the ADP1050 can regulate the power supply. When VDD rises above the power-on reset and UVLO levels, it takes ~20 μs for the VCORE pin (Pin 15) to reach its operational point of 2.6 V. The EEPROM contents are then downloaded to the registers. The download takes approximately 120 μs. After the EEPROM contents are downloaded, the ADP1050 is ready for operation; however, it takes a maximum of 52 ms for the ADP1050 to complete initialization of the address after a power-on reset. Therefore, it is recommended that the master device access the ADP1050 at least 52 ms after a power-on reset. If the ADP1050 is programmed to power up at this time, the soft start ramp begins. Otherwise, the device waits for a PSON signal, as programmed in Register 0x01 and Register 0x02. Rev. A | Page 23 of 92 ADP1050 Data Sheet To minimize trace length, the proper amount of decoupling capacitance must be placed between the VDD pin (Pin 16) and the AGND pin (Pin 17), as close as possible to the device. The same requirement applies to the VCORE pin (Pin 15). It is recommended that the VCORE pin not be used as a reference or to generate other logic levels using resistive dividers. Lock the Chip Password CHIP PASSWORD Change the Chip Password On power-up, some registers in the ADP1050 are locked and protected from being written to or read from. When the chip is locked, the following commands and all read only registers are accessible: To change the chip password, first write the old password using the CHIP_PASSWORD command (Register 0xD7). Next, write the new password using the same command. The chip password is changed to the new password. If the chip password is to be changed permanently, the register contents must be saved in the EEPROM after the chip password is changed. If the correct chip password is lost, the RESTORE_DEFAULT_ALL command (Register 0x12) restores the factory default settings. In this case, all the user settings are reset. • • • • • • • • Operation ON_OFF_CONFIG CLEAR_FAULTS WRITE_PROTECT RESTORE_DEFAULT_ALL VOUT_COMMAND VOUT_TRIM VOUT_CAL_OFFSET To lock the chip password, use the CHIP_PASSWORD command (Register 0xD7) to write any value other than the correct password. The CHIP_PASSWORD_UNLOCKED flag (Register 0xFEA0[7]) is then cleared to indicate that the chip password is locked from access. Unlock the Chip Password To unlock the chip password, perform two consecutive writes with the correct password (default value = 0xFFFF) using the CHIP_PASSWORD command (Register 0xD7). Between the two write actions, any read or write action to another register in this device interrupts the unlocking of the chip password. The CHIP_PASSWORD_UNLOCKED flag (Register 0xFEA0[7]) is set to indicate that the chip password is unlocked for access. Rev. A | Page 24 of 92 Data Sheet ADP1050 POWER MONITORING, FLAGS, AND FAULT RESPONSES The ADP1050 has extensive system and fault condition monitoring capabilities for the sensed signals. The system monitoring functions include current, voltage, 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, and flags are set when the limits are exceeded. FLAGS The ADP1050 has an extensive set of flags, including the PMBus standard flags and manufacturer specific flags, that are set when certain limits, thresholds are exceeded or certain conditions are met. A setting of 1 indicates that a fault or warning event has occurred. A setting of 0 indicates that a fault or warning event has not occurred. PMBus Standard Flags Figure 28 shows a summary of the ADP1050 PMBus standard fault status registers. The CLEAR_FAULTS command (Register 0x03) is used to clear all bits in the PMBus status registers (Register 0x78 to Register 0x7E) simultaneously. Manufacturer Specific Flags Register 0xFEA0 to Register 0xFEA2 store the manufacturer specific flags. These flags include the following: • • • Housekeeping flags, such as CHIP_PASSWORD_ UNLOCKED, VDD_OV, EEPROM_UNLOCKED, and CRC_FAULT. Flags that can be programmed for protection responses, such as CS3_OC_FAULT and FLAGIN. Status flags, such as PGOOD, SYNC_LOCKED, CHIP_ID, PULSE_SKIPPING, modulation, and SOFT_START_FILTER. For detailed descriptions of these flags, see the Manufacturer Specific Fault Flag Registers section. STATUS_VOUT (REG 0x7A) VOUT_OV_FAULT VOUT_OV_WARNING VOUT_UV_WARNING VOUT_UV_FAULT VOUT_MAX WARNING TON_MAX_FAULT TOFF_MAX_WARNING VOUT TRACKING ERROR STATUS_IOUT (REG 0x7B) 7 6 5 4 3 2 1 0 IOUT_OC_FAULT IOUT_OC_LV_FAULT IOUT_OC_WARNING IOUT_UC_FAULT CURRENT SHARE FAULT IN POWER LIMITING MODE POUT_OP_FAULT POUT_OP_WARNING STATUS_TEMPERATURE (REG 0x7D) 7 6 5 4 3 2 1 0 OT_FAULT OT_WARNING UT_WARNING UT_FAULT RESERVED RESERVED RESERVED RESERVED STATUS_INPUT (REG 0x7C) STATUS_WORD (REG 0x79) (UPPER BYTE OF STATUS_WORD) 15 14 13 12 VOUT IOUT INPUT MFR_SPECIFIC 11 10 9 8 POWER_GOOD FANS OTHER UNKNOWN STATUS_BYTE (REG 0x78) (LOWER BYTE OF STATUS_WORD) 7 6 5 4 3 2 1 0 BUSY POWER_OFF VOUT_OV_FAULT IOUT_OC_FAULT VIN_UV_FAULT TEMPERATURE CML NONE OF THE ABOVE 7 6 5 4 3 2 1 0 VIN_OV_FAULT VIN_OV_WARNING VIN_UV_WARNING VIN_UV_FAULT VIN_LOW IIN_OC_FAST_FAULT IIN_OC_WARNING PIN_OP_WARNING STATUS_MFR_SPECIFIC 7 MANUFACTURER DEFINED 6 MANUFACTURER DEFINED 5 MANUFACTURER DEFINED 4 MANUFACTURER DEFINED 3 MANUFACTURER DEFINED 2 MANUFACTURER DEFINED 1 MANUFACTURER DEFINED 0 MANUFACTURER DEFINED STATUS_FANS_1_2 7 6 5 4 3 2 1 0 FAN 1 FAULT FAN 2 FAULT FAN 1 WARNING FAN 2 WARNING FAN 1 SPEED OVERRIDE FAN 2 SPEED OVERRIDE AIR FLOW FAULT AIR FLOW WARNING STATUS_CML (REG 0x7E) STATUS_OTHER STATUS_FANS_3_4 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 CMD_ERR DATA_ERR PACKET ERROR CHECK FAILED MEMORY FAULT DETECTED PROCESSOR FAULT DETECTED RESERVED COMM_ERR OTHER MEMORY OR LOGIC FAULT RESERVED RESERVED INPUT A FUSE/BREAKER FAULT INPUT B FUSE/BREAKER FAULT INPUT A OR’ING DEVICE FAULT INPUT B OR’ING DEVICE FAULT OUTPUT OR’ING DEVICE FAULT RESERVED FAN 3 FAULT FAN 4 FAULT FAN 3 WARNING FAN 4 WARNING FAN 3 SPEED OVERRIDE FAN 4 SPEED OVERRIDE RESERVED RESERVED 12039-034 7 6 5 4 3 2 1 0 Figure 28. Summary of the Fault Status Registers (Only the Commands in Black Are Supported by the ADP1050; the Commands in Gray are Not Supported.) Rev. A | Page 25 of 92 ADP1050 Data Sheet Manufacturer Specific Latched Flags The ADP1050 has a set of latched flag registers (Register 0xFEA3 to Register 0xFEA5). The latched flag registers have the same flags as Register 0xFEA0 to Register 0xFEA2, but the flags in the latched registers remain set so that intermittent faults can be detected. Reading a latched flag register resets all the flags in that register. A PSON signal can also reset the latched flags. Flags Debounce Time The debounce timing of the manufacturer specific flags and the PMBus standard flags is programmable (see Table 6). The debounce time is the time during which the fault condition must be continuously triggered before the flag is set. Refer to the corresponding register settings for more information. The debounce time is used for flag setting. Only the PGOOD flag has a debounce time for flag clearing. For all other flags, the flag reenable delay, specified in Register 0xFE05[7:6] (see Table 99), functions as the debounce time for flag clearing. Refer to the Manufacturer Specific Protection Responses section for details. Housekeeping Flags The CHIP_PASSWORD_UNLOCKED flag (Register 0xFEA0[7]) indicates that the chip password is in the unlocked state, and all the registers can be accessed. The VDD_OV flag (Register 0xFEA0[0]) is set when the VDD voltage exceeds the VDD overvoltage lockout (OVLO) threshold. The debounce time is programmable as 2 μs or 500 μs, using Register 0xFE05[4]. When the flag is set, the ADP1050 shuts down. The flag is always cleared when Register 0xFE05[5] is set, regardless of the VDD voltage. The EEPROM_UNLOCKED flag (Register 0xFEA2[3]) indicates that the EEPROM is in the unlocked state and can be updated. The CRC_FAULT flag (Register 0xFEA2[2]) indicates that an error has occurred when downloading the EEPROM contents to the internal registers. The device shuts down and requires a PSON signal (programmed in Register 0x01 and Register 0x02) and/or the toggling of the CTRL pin (Pin 13) to restart. Flag Blanking During Soft Start Flag blanking means that when a fault condition is met, the corresponding flag is set, but there are no related actions. The following flags are always blanked during soft start: • • VOUT_UV_FAULT OT_FAULT The following flags can be programmed to be blanked during soft start, using Register 0xFE0B: • • • • • VOUT_OV_FAULT (Bit 0) CS3_OC_FAULT (Bit 1) IIN_OC_FAST_FAULT (Bit 3) VIN_UV_FAULT (Bit 4) FLAGIN (Bit 6) If a flag is blanked during soft start, it is also blanked during the TON_DELAY time. Table 6. Flag Debounce Time Flag VOUT_OV_FAULT VOUT_UV_FAULT OT_FAULT OT_WARNING CS3_OC_FAULT VIN_UV_FAULT FLAGIN VDD_OV PGOOD Debounce Time 0 μs, 1 μs, 2 μs, 8 μs 0 ms, 20 ms, 40 ms, 80 ms, 160 ms, 320 ms, 640 ms, 1280 ms 1 sec 0 ms, 100 ms 0 ms, 10 ms, 20 ms, 200 ms 0 ms, 2.5 ms, 10 ms, 100 ms 0 μs, 100 μs 2 μs, 500 μs 0 ms, 200 ms, 320 ms, 600 ms Rev. A | Page 26 of 92 Register 0xFE26[7:6] 0x45[2:0] 0x50[2:0] 0xFE2F[2] 0xFE19[6:5] 0xFE29[1:0] 0xFE12[1] 0xFE05[4] 0xFE0E[3:0] Data Sheet ADP1050 When the ADP1050 registers one or several fault conditions, it stores the first flag in a dedicated first flag ID register (Register 0xFEA6). The first flag ID represents the first flag that triggers a shutdown response. The following types of flags are not recorded in the first flag ID register: • • • Flags that are configured to be ignored Flags that have a configured response causing the PWM outputs to be disabled, but that do not use a soft start to reenable the PWM outputs after the fault is resolved Flags that have a configured response causing the synchronous rectifiers to be disabled The first flag ID register gives the user more information for fault diagnosis than a simple flag. This register also stores the previous first fault ID. Figure 29 shows the timing diagram for the first flag ID recording scheme. Table 7 describes the actions shown in Figure 29. VDD FLAG Y FLAG Z POWER SUPPLY STATUS FIRST FLAG ID (CURRENT) X Y Z FIRST FLAG ID (PREVIOUS) 0 X Y The status of the first flag ID register can be saved to the EEPROM, as well, by setting Register 0xFE0C[3]. To limit the number of writes to the EEPROM, only the first flag after a VDD power reset can be saved to the EEPROM. During the next VDD power-on, the first flag ID is downloaded from the EEPROM and loaded to the first flag ID register (Register 0xFEA6). EEPROM UPDATE t0 t1 t2 t3 t4 t5 t6 t7 t8 t9 12039-035 First Flag ID Recording Figure 29. First Flag Timing Table 7. First Flag ID Timing 1 Step t0 t1 t2 t3 t4 t5 t6 t7 t8 t9 1 Action As an example, the previous ID and the current ID in the EEPROM are 0 and Flag X, respectively. When the VDD voltage is applied on the ADP1050, the first flag ID is downloaded from the EEPROM to the first flag ID register (Register 0xFEA6). A fault (Flag Y) shuts down the power supply. In the first flag ID register, Flag Y is now the current flag ID, and Flag X is the previous flag ID. The first flag ID register is updated accordingly. The EEPROM is then updated to save this information. Another fault (Flag Z) occurs while the power supply is off. Because Flag Z is not the first flag that caused the shutdown, neither the first flag ID register nor the EEPROM is updated. Flag Y is cleared, but Flag Z keeps the power supply off. The first flag ID register and the EEPROM are not updated. Flag Z is cleared. The first flag ID register is not updated. The power supply is turned on again after the flag reenable delay. The first flag ID register is not updated. The fault indicated by Flag Z shuts down the power supply. Flag Z is now the current first flag ID, and Flag Y is the previous flag ID. The first flag ID register is updated accordingly. The EEPROM is not updated to save the information. Flag Z is cleared. The first flag ID register is not updated. The power supply is turned on again after the flag reenable delay. The first flag ID register is not updated. The VDD voltage is removed and the power supply is turned off. First Flag ID in Register First Flag ID in EEPROM Power Supply On Previous ID 0 Current ID Flag X Previous ID 0 Current ID Flag X Off Flag X Flag Y Flag X Flag Y Off Flag X Flag Y Flag X Flag Y Off Flag X Flag Y Flag X Flag Y Off On Flag X Flag X Flag Y Flag Y Flag X Flag X Flag Y Flag Y Off Flag Y Flag Z Flag X Flag Y Off On Flag Y Flag Y Flag Z Flag Z Flag X Flag X Flag Y Flag Y Off N/A N/A N/A N/A N/A means not applicable. Rev. A | Page 27 of 92 ADP1050 Data Sheet VOLTAGE READINGS Input Voltage Reading The input voltage, which is reported in the READ_VIN command (Register 0x88), is updated every 10 ms. The VIN_SCALE_ MONITOR command (Register 0xD8) is set for correct input voltage reading. The input voltage is sensed through the VF pin (Pin 4). The VF ADC has an input range of 1.6 V. The raw data is stored in Register 0xFEAC. The reading is 11 bits, meaning that the LSB size is 1.6 V/2048 = 781.25 μV. The input current reading is derived from the CS1 ADC, which has an input range of 1.6 V. The raw data is stored in Register 0xFEA7. The reading is 12 bits, which means that the LSB size is 1.6 V/ 4096 = 390.625 μV. CS3 Current Reading The CS3 reading is an alternative output current reading that is calculated using the CS1 reading and the duty cycle values. The CS3 reading can be used as an alternate output current reading and protection when the current sense resistor is not used. The output current reading is derived from the following equation: IOUT = ICS3 × n Because the input voltage signal can be sensed through the switching node of the secondary windings, the voltage drop caused by the conduction current in the primary switches, transformer windings, and copper trace adds to the error to the input voltage sense. The following equation is used to compensate for the error: where ICS3 is read from Register 0xFEA9[15:4], and n is the turns ratio of the main transformer (n = NPRI/NSEC). Each LSB size in Register 0xFEA9[15:4] is 4× the LSB size of the CS1 reading in Register 0xFEA7. For example, if 1 LSB = 0.1 A in Register 0xFEA7[15:4], 1 LSB in Register 0xFEA9[15:4] = 0.4 A. YCOMP = YUNCOMP ± (N × X ÷ 211) where: YCOMP is the compensated VF value in Register 0xFEAC[15:5]. YUNCOMP is the uncompensated VF value in Register 0xFEAC[15:5]. N is the compensation coefficient set in Register 0xFE59[7:0], and the polarity is set in Register 0xFE58[0]. X is the CS1 current value in Register 0xFEA7[15:4]. The compensated VF value is used for conversion of the READ_VIN value. Output Voltage Reading The output voltage is reported in the READ_VOUT command (Register 0x8B) and updated every 10 ms. The VOUT_SCALE_ MONITOR command (Register 0x2A) is programmed for correct output voltage reading. The VS voltage value register (Register 0xFEAA) is updated every 10 ms via the VS low frequency ADC. The VS low frequency ADC has an input range of 1.6 V. The raw data is stored in Register 0xFEAA. The reading is 12 bits, which means that the LSB size is 1.6 V/4096 = 390.625 μV. CURRENT READINGS By default, the current readings are updated every 10 ms; however, Register 0xFE65[1:0] can be used to change the update rate to 52 ms, 105 ms, or 210 ms. POWER READINGS Input Power Reading The input power value (Register 0xFEAE) is the product of the VF voltage value in Register 0xFEAC[15:5] and the CS1 current value in Register 0xFEA7[15:4]. Therefore, a combination of both voltage and current formulas is used to calculate the power reading in watts (W). Register 0xFEAE is a 16-bit word. It multiplies two 12-bit numbers and then discards the eight LSBs. For example, if 1 LSB in Register 0xFEAC[15:5] is 0.01 V and 1 LSB in Register 0xFEA7[15:4] is 0.01 A, 1 LSB in Register 0xFEAE[15:0] is 0.01 V × 0.01 A × 28 = 0.0256 W. DUTY CYCLE READING The READ_DUTY_CYCLE command (Register 0x94, which gives the duty cycle of the PWM output value) is updated every 10 ms. Register 0xFE58[3:2] is set for correct reading of general PWM type topologies; these bits select the PWM channel (OUTA or OUTB) for which the duty cycle value is reported. SWITCHING FREQUENCY READING The READ_FREQUENCY command (Register 0x95) is used to report the switching frequency information in kHz. Input Current Reading The input current is reported in the READ_IIN command (Register 0x89). The IIN_SCALE_MONITOR command (Register 0xD9) is set for correct input current reading. Rev. A | Page 28 of 92 Data Sheet ADP1050 The RTD pin (Pin 20) 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. The RTD ADC has an input range of 1.6 V. The raw data is stored in Register 0xFEAB. It is a 12-bit reading, which means that the LSB size is 1.6 V/4096 = 390.625 μV. Using Register 0xFE2D[7:6], an internal precision current source can be configured to generate a 10 μA, 20 μA, 30 μA, or 40 μA current. This current source can be trimmed, by means of an internal DAC, to compensate for thermistor accuracy. To set the current source to the factory default value of 46 μA, write 0xE6 to Register 0xFE2D. 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, it is necessary to perform postprocessing on the RTD ADC reading to accurately read the temperature. By connecting an external resistor in parallel with the NTC thermistor, linearization is achieved. Figure 31 shows the RTD and OTP operation. Using the factory default value of 46 μA and the linearization scheme, the temperature, expressed in degrees Celsius (°C), can be read directly via the READ_TEMPERATURE command (Register 0x8D). The temperature reading is derived from the RTD ADC output, and it is updated every 10 ms. The ADP1050 implements a linearization scheme that is based on a preselected combination of external components and current selection (see the Temperature Linearization Scheme section). In this case, the external resistor in parallel is not needed. With an internal current source of 46 μA, the equation to calculate the ADC code at a certain NTC value (RX) is given by the following formula: ADC CODE = 46 μA × RX/390.7 μV For example, at 60°C, the NTC thermistor connected to the RTD pin is 21.82 kΩ. Therefore, RTD ADC CODE = 46 μA × 21.82 kΩ/390.7 μV = 2570 For the overtemperature function, the RTD threshold (in volts) can be transferred through the OT_FAULT_LIMIT command in Register 0x4F, using the linearization equations shown in the Temperature Linearization Scheme section. Alternatively, the temperature reading and overtemperature protection function can be implemented by applying an external analog temperature sensor, such as the STLM20. See Figure 30 for more information. Using this solution, the temperature sense range can be as low as −40°C. To facilitate this approach, disable the internal current source by writing 0x00 to Register 0xFE2D and setting Register 0xFE2B[2]. The temperature reading in degrees Celsius can be derived by the following formula: T = 159.65 − ADC CODE R1 + R2 × 29.92 R2 where the ADC CODE is the reading in Register 0xFEAB[15:4]. The recommended values of R1 and R2 are 20 kΩ and 10 kΩ, respectively. 10µA/20µA/30µA/40µA VOUT 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. STLM20 GND R1 20kΩ R2 10kΩ RTD ADC RTD RTD TEMPERATURE VALUE REGISTER REG 0xFEAB[15:4] 12039-037 TEMPERATURE READING Figure 30. Temperature Sensing by an Analog Temperature Sensor 10µA/20µA/30µA/40µA OT_FAULT_RESPONSE REG 0x50 100kΩ NTC RTD ADC SIGNAL CONDITIONING 16.5kΩ OT_FAULT RESPONSE TEMPERATURE VALUE IN CELSIUS READ_TEMPERATURE REG 0x8D RTD TEMPERATURE VALUE REGISTER OT_FAULT_LIMIT REG 0x4F OT_FAULT FLAG REG 0x7D[7] PGOOD 12039-036 RTD REG 0xFEAB[15:4] Figure 31. RTD and OTP Operation Rev. A | Page 29 of 92 ADP1050 Data Sheet TEMPERATURE LINEARIZATION SCHEME The ADP1050 linearization scheme is based on a combination of a thermistor (R25 = 100 kΩ, 1%), an external resistor (16.5 kΩ, 1%), and the 46 µA current source, preselected for best performance when linearizing measured temperatures in the industrial range. The NTC thermistor that is required must have a resistance of R25 = 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. The linearization equations show the relationship between the RTD voltage, VRTD (in volts), and temperature reading, T (in degrees Celsius). If T < 104°C, VRTD = (130 − T) × 1.6 256 If T ≥ 104°C, VRTD = (156 − T) × 1.6 PMBus PROTECTION COMMANDS VOUT Overvoltage Protection (OVP) The VOUT overvoltage protection feature in the ADP1050 follows PMBus specifications. The limits are programmed in the VOUT_OV_FAULT_LIMIT command (Register 0x40) to correspond to the voltage between 75% and 150% of the nominal output voltage. The responses are programmed using the VOUT_ OV_FAULT_RESPONSE command (Register 0x41). The VOUT_OV_FAULT flag (Register 0x78[5], Register 0x79[5], and Register 0x7A[7]) is set when the voltage reading exceeds the overvoltage limit. In a direct parallel system, multiple power supply units are connected directly in parallel without any OR’ing device. An overvoltage condition in one power supply can raise the common bus voltage, causing the activation of overvoltage protection in the other power supplies connected to the common bus. As a result of this overvoltage protection action, the common bus may fail. The ADP1050 provides a highly flexible, conditional overvoltage protection function for redundant control in a direct parallel system. It consists of an overvoltage detection block, a modulation flag triggering block, and an overvoltage response block (see Figure 33). 512 where T represents the temperature reading in Register 0x8D. Figure 32 shows the temperature linearization curves. 0.8 LINEARIZATION VOLT TEMP CURVE ACTUAL VOLT TEMP CURVE 0.7 0.6 0.5 0.4 0.3 0.2 0.1 10 20 30 40 50 60 70 80 90 TEMPERATURE (°C) 100 110 120 130 Figure 32. Temperature Linearization Scheme Curves VO CONDITIONAL OVP ENABLE REG 0xFE6C[0] OVP VOUT_OV_FAULT FLAG DEBOUNCE REG 0xFE26[7:6] VS– DAC VOUT_OV_FAULT_RESPONSE REG 0x41 VOUT_OV_FAULT REG 0x7A[7] VOUT_OV_FAULT_LIMIT REG 0x40 0 0 AND 0 MODULATION VALUE MODULATION THRESHOLD REG 0xFE6B 0 LARGE_MODULATION REG 0xFE6C[2] 0 0 AND EXTENDED VOUT_OV_FAULT_RESPONSE REG 0xFE01[7:4] Figure 33. VOUT Overvoltage Protection Circuit Implementation Rev. A | Page 30 of 92 12039-039 0 12039-038 RTD VOLTAGE (V) Using the internal linearization scheme, the READ_TEMPERATURE command (Register 0x8D) returns the current temperature in degrees Celsius. For overtemperature protection, the user can directly set the OT_FAULT_LIMIT command (Register 0x4F) in degrees Celsius. See the OT_FAULT and OT_WARNING section for more information. Data Sheet ADP1050 In the overvoltage responses block, there are two groups of overvoltage protection responses: the VOUT_OV_FAULT_RESPONSE PMBus command, set in Register 0x41, and the extended VOUT_ OV_FAULT_RESPONSE, set in Register 0xFE01[7:4]. There is a conditional OVP enable switch in Register 0xFE6C[0]. If the switch is cleared to 0, the conditional OVP function is disabled and the OVP response always follows the VOUT_OV_ FAULT_RESPONSE PMBus command (Register 0x41). If the switch is set to 1, the OVP response follows the VOUT_OV_ FAULT_RESPONSE command or the extended VOUT_OV_ FAULT_RESPONSE, depending on the status of the LARGE_ MODULATION flag. For example, when using a direct parallel system, if the VS+ pin (Pin 3) and the VS− pin (Pin 2) in one power supply unit (PSU) are shorted and this PSU experiences overvoltage failure, all the PSUs detect the overvoltage signal. The LARGE_MODULATION flag is used to identify the failed PSU. Typically, the failed PSU is shut down, and the other PSUs continue to operate normally. The modulation threshold is typically set with a value that is slightly less than the modulation limit setting in Register 0xFE3C; however, the modulation limit can change when the ADP1050 unit acts as a slave device to synchronize with an external clock (see the Switching Frequency and Synchronization Registers section for more information). For more information about extended overvoltage protection, see the Manufacturer Specific Protection Responses section and the related register settings. VOUT Undervoltage Protection (UVP) The VOUT undervoltage protection feature follows PMBus specifications. The limits are programmed using the VOUT_UV_ FAULT_LIMIT command (Register 0x44), and the responses are programmed in the VOUT_UV_FAULT_RESPONSE command (Register 0x45). When the voltage reading in the READ_VOUT command (Register 0x8B) falls below the VOUT_UV_FAULT_ LIMIT value, the VOUT_UV_FAULT flag in Register 0x7A[4] is set. OT_FAULT and OT_WARNING The overtemperature protection feature in the ADP1050 follows PMBus specifications. With the default setting, the OTP limit is programmed using the OT_FAULT_LIMIT command in Register 0x4F, and the response is programmed using the OT_FAULT_RESPONSE command (Register 0x50). There is an overtemperature warning flag, OT_WARNING, in Register 0x7D[6]. The OT_WARNING limit is less than the OT_FAULT_LIMIT, with an overtemperature hysteresis specified by Register 0xFE2F[1:0]. When the temperature sensed at the RTD pin (Pin 20) exceeds the OT_WARNING limit, the OT_WARNING flag (Register 0x7D[6]) is set. When the temperature sensed at RTD pin exceeds the OT_FAULT_LIMIT, the OT_FAULT flag (Register 0x7D[7]) is set. The OT_FAULT and OT_WARNING flags are cleared when the temperature falls below the OT_WARNING limit (see Figure 34). The OT_FAULT flag and the OT_WARNING flag can each be separately set to trigger the PGOOD flag and drive the PG/ALT pin (Pin 14) low. OT_FAULT FLAG IS SET OT_FAULT_LIMIT OT_WARNING FLAG IS SET OT HYSTERESIS OT_WARNING LIMIT OT_FAULT AND OT_WARNING FLAGS ARE CLEARED OT_FAULT FLAG OT_WARNING FLAG TIME 12039-040 In the modulation flag triggering block, the real-time modulation value is compared to the internal reference to generate the LARGE_MODULATION flag. Register 0xFE6C[2] sets the LARGE_MODULATION flag when the real-time modulation value exceeds the modulation threshold set by Register 0xFE6B. the flag reenable delay time is specified by Register 0xFE05[7:6]. The VOUT_UV_FAULT flag is always blanked. Under these conditions, the VOUT_UV_FAULT flag is never triggered by an undervoltage condition. TEMPERATURE In the overvoltage detection block, there is an internal analog comparator to detect the output voltage and generate the VOUT_ OV_FAULT flag when an overvoltage condition occurs. The overvoltage reference voltage is set in Register 0x40. The debounce time of the flag setting can be programmed for 0 μs, 1 μs, 2 μs, or 8 μs, using Register 0xFE26[7:6]. There is also a 40 ns propagation delay, which is measured from the time when the OVP voltage exceeds the threshold to the time when the comparator output status is changed. Figure 34. OT Protection and OT Warning Operation Optionally, the user can process the RTD reading and use the linearization equation to determine the overtemperature protection setting. This allows the user to program the RTD threshold for greater overtemperature protection accuracy. Alternatively, if an analog temperature sensor, such as the STLM20, is used, the OT_FAULT limit can still be programmed using the OT_FAULT_LIMIT command (Register 0x4F), but a conversion equation is needed. During the period of the soft start ramp, the turn-on delay time is specified by the TON_DELAY command (Register 0x60), and Rev. A | Page 31 of 92 ADP1050 Data Sheet Using Figure 30 as an example, assume that R1 and R2 are 20 kΩ and 10 kΩ, respectively, and the value in Register 0x4F is TOT_SET_LIMIT. Alternatively, if the input voltage signal is not available before startup, the VIN_ON and VIN_OFF commands can be set for input voltage undervoltage protection using Register 0xFE29[5]. If TOT_SET_LIMIT < 104 decimal, The VIN_UV_FAULT flag in Register 0x78[3], Register 0x79[3], and Register 0x7C[4] is set if the input voltage reading falls below the VIN_OFF limit. TOT_ACTUAL_LIMIT = 1.6039 × TOT_SET_LIMIT − 48.8623 If TOT_SET_LIMIT ≥ 104 decimal TOT_ACTUAL_LIMIT = 0.801967 × TOT_SET_LIMIT + 34.5423 Table 8 shows some typical OTP threshold settings when using an analog temperature sensor, such as the STLM20. The response to the VIN_UV_FAULT flag is programmed via the VIN_UV_FAULT_RESPONSE bits (Register 0xFE02[7:4]). Refer to the Manufacturer Specific Protection Responses section and Table 97 for details. Table 8. Typical OT Fault Limit Settings When Using an Analog Temperature Sensor TOT_SET_LIMIT OT Limit Programmed in Register 0x4F (In Decimal) 55 60 65 70 75 80 85 90 95 100 105 110 115 120 125 130 The debounce time of the VIN_UV_FAULT flag setting can be programmed at 0 ms, 2.5 ms, 10 ms, or 100 ms, using Register 0xFE29[1:0]. Because the VIN reading is averaged every 1 ms, there is an additional debounce time of up to 1 ms. TOT_ACTUAL_LIMIT Actual OT Limit (°C) 39.35 47.37 55.39 63.41 71.43 79.45 87.47 95.49 103.51 111.53 118.75 122.76 126.77 130.78 134.79 138.80 MANUFACTURER SPECIFIC PROTECTION COMMANDS CS1 Cycle-by-Cycle Current Limit The CS1 cycle-by-cycle current limit is implemented using an internal analog comparator (see Figure 23). When the voltage at the CS1 pin (Pin 5) exceeds the threshold set by Register 0xFE1B[6], the comparator output is triggered high and an internal flag (CS1_ OCP, which is not accessible by the user and, therefore, not listed in the register tables) is triggered. There is a 105 ns (maximum) propagation delay in the comparators. A blanking time of 0 ns, 40 ns, 80 ns, 120 ns, 200 ns, 400 ns, 600 ns, or 800 ns can be set to ignore the current spike at the beginning of the current signal. The blanking time is set in Register 0xFE1F[6:4]. During this time, the comparator output is ignored. The blanking time of the CS1_OCP flag can be referenced to the rising edges of OUTA and OUTB, using Register 0xFE1D[1:0]. A debounce time of 0 ns, 40 ns, 80 ns, or 120 ns can also be added to improve the noise immunity of the CS1 OCP comparator output circuit. The debounce time is set using Register 0xFE1F[1:0]. This is the minimum time that the CS1 signal must be constantly above the threshold before the PWM outputs are shut down. If the STLM20 is used, the temperature hysteresis can be set using Register 0xFE2F[1:0], as follows: 00 = 3.21°C, 01 = 6.42°C, 10 = 9.62°C, or 11 = 12.83°C VIN_ON and VIN_OFF Two PMBus commands, VIN_ON (Register 0x35) and VIN_OFF (Register 0x36), allow the user to set the input voltage on and off limits independently. The VIN_LOW flag in Register 0x7C[3] is set at initialization. When the input voltage exceeds the VIN_ON limit, the VIN_LOW flag is cleared. If the PSON signal is asserted, the power conversion starts. When the input voltage drops below the VIN_OFF limit, the VIN_LOW flag is set and the power conversion stops. The delay time for the power conversion start and stop can be set separately by Register 0xFE29[3:2] and Register 0xFE29[4]. Rev. A | Page 32 of 92 Data Sheet ADP1050 Figure 35 shows an example of CS1 cycle-by-cycle current-limit timing, with the rising edge of OUTA as the blanking time reference. When the CS1_OCP flag is set, it is not cleared until the beginning of the next switching cycle. OUTA CS1 CYCLE-BY-CYCLE CURRENT LIMIT REFERENCE CS1 SIGNAL COMPARATOR OUTPUT IIN_OC_FAST_FAULT FLAG REG 0xFEA0[5] CS1 CYCLE-BY-CYCLE CURRENT LIMIT THRESHOLD IIN_OC_FAST_FAULT FLAG REG 0xFEA3[5] IIN_OC_FAST_FAULT FLAG REG 0x7C[2] COMPARATOR OUTPUT t0 tS 2tS 3tS 4tS 5tS 6tS 7tS 12039-042 CS1 PIN SIGNAL Figure 36. IIN Overcurrent Fast Fault Triggering CS1_OCP FLAG tBLANKING tDEBOUNCING t0 tDEBOUNCING 12039-041 tBLANKING tS Figure 35. CS1 Cycle-by-Cycle Current-Limit Timing When the CS1_OCP flag is triggered, Register 0xFE08[6:5] and Register 0xFE0E[5:4] can be used to disable all PWM outputs for the remainder of the switching cycle. They are reenabled at the start of the next switching cycle. During one switching cycle, if the rising edge of a PWM output occurs after the CS1_OCP flag is triggered, the PWM remains enabled for the switching cycle. To avoid current overstress of the body diode of the synchronous rectifiers, the cycle-by-cycle current-limit actions of the SR1 and SR2 outputs can be further programmed by Register 0xFE1E[1:0]. They can be programmed in the same way as the other PWM outputs, or they can be programmed so that when the CS1_OCP flag is triggered, the SR PWM output is turned on. There is a 145 ns to 180 ns delay (dead time) between the CS1_OCP flag being triggered and the turning on of the SR PWM outputs. The falling edges continue to follow the programmed value. The cycle-by-cycle current limit is always activated regardless of the IIN overcurrent fast protection settings. The comparator output can be completely ignored by setting Register 0xFE1F[7]. IIN Overcurrent Fast Protection N, an internal counter, is a positive integer or zero, with an initial value of 0. The counters work as follows: When the CS1_OCP flag is triggered in one cycle (the CS1 OCP comparator is triggered high), N is counted as NCURRENT = NPREVIOUS + 2. If the CS1_OCP flag is not triggered in one cycle and NPREVIOUS > 0, NCURRENT = NPREVIOUS − 1. If the CS1_OCP flag is not triggered in one cycle and NPREVIOUS = 0, NCURRENT = 0. When the value of N reaches the limit specified by IIN_OC_ FAST_FAULT_LIMIT, the IIN_OC_FAST_FAULT flag is triggered (see Figure 36). For the single-ended topologies, such as forward converter and buck converter, a switching cycle consists of one cycle. For the double-ended topologies, such as full bridge converter, half bridge converter, and push pull converter, there are two cycles in a switching cycle. The IIN_OC_FAST_FAULT_LIMIT bits are in Register 0xFE1A[6:4]. In Figure 36, the IIN_OC_FAST_ FAULT_LIMIT value is set to 8. The response of the IIN_OC_FAST_FAULT flag can be programmed in the IIN_OC_FAST_FAULT_RESPONSE bits (Register 0xFE00[3:0]). See the Manufacturer Specific Protection Responses section and the register settings for the action details. Matched Cycle-by-Cycle Current Limit in a Half Bridge Converter For the half bridge converter, the cycle-by-cycle current-limit feature, described in the CS1 Cycle-by-Cycle Current Limit, cannot guarantee the balance of duty cycles between two half cycles in one switching cycle. The imbalances of each half cycle can cause the center point voltage of the capacitive divider to drift from VIN/2 toward either the ground or the input voltage, VIN. This drift, in turn, can lead to output voltage regulation failure, transformer saturation, and doubling of the drain to source voltage (VDS) stress of the synchronous rectifiers. To compensate for these imbalances, matched cycle-by-cycle current limiting is implemented in the ADP1050 by forcing each cycle to be equalized, or matched, to the previous one. When the matched cycle-by-cycle current limit is triggered, the duty cycle in the following half cycle exactly matches the actual duty cycle in the preceding half cycle. However, the cycle-by-cycle current limit is always the highest priority to terminate the PWM channels. For example, if one previous cycle has a duty cycle of 20% under a cycle-by-cycle current-limit condition, also match the following cycle to a duty cycle of 20%. However, if the cycle-bycycle current limit occurs in the following cycle and it must terminate the PWM with a smaller duty cycle, the cycle-bycycle current limit takes higher priority and the duty cycle can be a value that is smaller than 20%. The matched cycle-by-cycle current limit is enabled by Register 0xFE1D[6]. Rev. A | Page 33 of 92 ADP1050 Data Sheet CS3 Overcurrent Protection CS3 overcurrent protection provides alternative output overcurrent protection if the direct output current sense is not available. The reading is calculated from the CS1 and duty cycle readings. The CS3_OC_FAULT flag (Register 0xFEA0[3]) is set when the CS3 current reading of the eight most significant bits (MSBs) in Register 0xFEA9 exceeds the CS3_OC_FAULT_LIMIT that is programmed in Register 0xFE6A. The debounce time of the flag setting can be programmed at 0 ms, 10 ms, 20 ms, or 200 ms in Register 0xFE19[6:5]. The response of the CS3_OC_FAULT flag is programmed in the CS3_OC_FAULT_RESPONSE bits (Register 0xFE01[3:0]). See the Manufacturer Specific Protection Responses section. FLAGIN Protection The SYNI/FLGI pin (Pin 10) can be configured in flag input mode (FLGI). An external signal can be sent to the ADP1050 to trigger an action. The polarity of the external signal is configured by the FLGI polarity bit (Register 0xFE12[2]). When the ADP1050 detects an external signal, the FLAGIN flag is set. The response to the FLAGIN flag is programmed in the FLAGIN_RESPONSE bits (Register 0xFE03[3:0]). See the Manufacturer Specific Protection Responses section. MANUFACTURER SPECIFIC PROTECTION RESPONSES For the VDD_OV flag and protection action, see the VDD OVLO Protection section. The following flags can be configured to trigger protection responses: IIN_OC_FAST_FAULT, VOUT_OV_FAULT, CS3_OC_FAULT, VIN_UV_FAULT, and FLAGIN. The VOUT_OV_FAULT flag, which triggers the manufacturer specific protection in Register 0xFE01[7:4], is used only for conditional overvoltage protection. See the VOUT Overvoltage Protection (OVP) section for details. Each of the aforementioned flags can be individually programmed to trigger one of the following responses: • • • After the condition that triggered the flag is resolved and the flag is cleared, the ADP1050 can be programmed to respond as follows: • • VDD OVLO Protection The ADP1050 has built-in overvoltage protection (OVP) on its supply rail. The VDD overvoltage response bits (VDD_OV_ RESPONSE), found in Register 0xFE05[5:4], are used to specify the response to a VDD overvoltage condition. • • If Register 0xFE05[5] = 0, the VDD_OV flag is set and the ADP1050 shuts down when the VDD voltage rises above the OVLO threshold. When the VDD overvoltage condition ends, the VDD_OV flag is cleared and the ADP1050 downloads the EEPROM contents before restarting with a soft start process. The debounce time of the VDD_OV flag can be programmed using Register 0xFE05[4]. If Register 0xFE05[5] = 1, the VDD_OV flag is always cleared, regardless of VDD voltage conditions. The ADP1050 continues to operate without interruption. Continue operation without interruption (flag ignored) Disable SR1 and SR2 Disable all PWM outputs • After the flag reenable delay time elapses, reenable the disabled PWM outputs with a soft start sequence. Reenable the disabled PWM outputs immediately without the soft start process. Keep the PWM output disabled. A PSON reset signal must be used to reenable the PWM outputs with a soft start sequence. The first flag that causes all PWM outputs to be disabled and requires a soft start if the PWM outputs are reenabled is recorded as the first flag ID. For more information about use of the first flag ID, see the First Flag ID Recording section. A flag reenable delay can be set for the listed manufacturer specific flags. This delay is used if the configured action for a flag is to reenable the PWM outputs after the flag reenable delay. This delay can be set to 250 ms, 500 ms, 1 sec, or 2 sec, using Register 0xFE05[7:6]. It is recommended that the VDD_OV flag response not be programmed as always cleared. Rev. A | Page 34 of 92 Data Sheet ADP1050 POWER SUPPLY CALIBRATION AND TRIM All the ADP1050 devices are factory trimmed. If the ADP1050 is not trimmed in the power supply production environment, it is recommended that components with a 0.1% tolerance be used for the inputs to the CS1, VS±, VF, and OVP pins to meet data sheet specifications (see the Specifications section). In the power supply production environment, the ADP1050 can calibrate items, such as output voltage and trim, for tolerance errors that are introduced by sense resistors and resistor dividers, as well as its own internal circuitry. The ADP1050 allows the user enough trim capability to trim for external components with a tolerance of ≤0.5%. To unlock the trim registers for write access, the user must perform two consecutive write actions with the correct password (factory default value = 0xFF), using the TRIM_PASSWORD command (Register 0xD6). Any read or write action to another register in this device, occurring between these two write actions, interrupts the unlocking of the chip password. The trim registers are Register 0xFE14, Register 0xFE20, Register 0xFE28, and Register 0xFE2A through Register 0xFE2C. For complete information about these registers, see the Manufacturer Specific Extended Commands Descriptions section. VOUT TRIM (VS TRIM) The voltage sense input at the VS± pins is optimized for sensing signals at 1 V and cannot sense a signal greater than 1.6 V. It is recommended that the nominal output voltage be reduced to 1 V for best performance. The resistor divider introduces errors that must be trimmed. The ADP1050 has enough trim range to trim errors that are introduced by resistors with a tolerance of ≤0.5%. To trim the errors introduced by the resistor divider, use the following procedure: 1. 2. 3. 4. IIN TRIM (CS1 TRIM) Using a DC Signal Set the VOUT_COMMAND (Register 0x21) with the nominal output voltage value. Set the VOUT_SCALE_ LOOP command (Register 0x29) and the VOUT_SCALE_ MONITOR command (Register 0x2A) based on the resistor divider information. Enable the power supply with the no-load current. The voltage of the VS± pins is divided down by the VS± resistor dividers to give a target of 1 V at the VS± pins. Adjust the VOUT_CAL_OFFSET trim (Register 0x23) to ensure that the output voltage is exactly the target output voltage. Adjust the VS gain trim register (Register 0xFE20) when the READ_VOUT reading in Register 0x8B is the exact output voltage reading. A known dc voltage (Vx) is applied at the CS1 pin. The IIN_ SCALE_MONITOR command (Register 0xD9) is set to 0x0001. The READ_IIN input current reading command (Register 0x89) generates a digital code (representing the input current in amperes) that is equal to the Vx voltage value. The CS1 gain trim register (Register 0xFE14) is adjusted until the input current reading in Register 0x89 reads the correct digital code. VIN TRIM (VF GAIN TRIM) Using an AC Signal Use the following procedure: A known ac 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 IIN_SCALE_ MONITOR is calculated as follows: 1. The voltage sense inputs are optimized for the VF pin signals at 1 V and cannot sense a signal greater than 1.6 V. A resistor divider is required to divide the sensed voltage signal into a voltage of less than 1.6 V. It is recommended that the VF voltage signal be reduced to 1 V for best performance. The resistor divider introduces errors, which must be trimmed. IN_SCALE_MONITOR = IIN_SCALE_MONITOR = (NPRI/NSEC) × RCS1 where NPRI and NSEC are the turns of the primary side and secondary side windings, respectively, of the current transformer. The READ_IIN input current reading command generates a digital code, representing the input current, Ix. The CS1 gain trim register (Register 0xFE14) is adjusted until the input current reading in Register 0x89 reads the correct digital code. Set the VIN_SCALE_MONITOR command in Register 0xD8 based on the resistor divider information (see Figure 20) and the turns ratio information of the transformer. 2. 3. 4. Rev. A | Page 35 of 92 N R2 × SEC R1 + R2 N PRI where NPRI and NSEC are the turns of the primary side and secondary side windings, respectively, of the transformer. Apply the nominal input voltage at the no load condition to achieve a targeted voltage of approximately 1 V at the VF pin. Adjust the VF gain trim register (Register 0xFE28) when the READ_VIN reading in Register 0x88 is the exact nominal voltage reading. Adjust the input voltage compensation multiplier (Register 0xFE59) to make the READ_VIN reading match the exact input voltage at the full load condition. ADP1050 Data Sheet RTD AND OTP TRIM Trimming the ADC The RTD requires two trims, one for the ADC and one for the current source. To use the internal linearization scheme, additional trimming procedures are required. The first option for trimming the ADC uses the internal linearization scheme with 46 µA RTD current, which provides an accurate reading, expressed in degrees Celsius, read in the READ_TEMPERATURE command (Register 0x8D) in decimal format. Trimming the Current Source Register 0xFE2D[7:6] sets the value of the RTD current source to 10 µA, 20 µA, 30 µA, or 40 µA. Register 0xFE2D[5:0] can be used to fine-tune the current value. By fine-tuning the internal current source, component tolerance can be compensated 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 Register 0xFE2D[5:0]; a decimal value of 63 adds 63 × 160 nA = 10.08 µA to the current source set by Register 0xFE2D[7:6]. Use Register 0xFE2D[7:6] to program a value for the current source, selecting the nearest possible option (10 µA, 20 µA, 30 µA, or 40 µA). Then use Register 0xFE2D[5:0] to achieve the finer step size. Use an R25 = 100 kΩ, 1% accuracy NTC thermistor with beta = 4250, 1% accuracy (such as the NCP15WF104F03RC) in parallel with an external resistor of 16.5 kΩ, 1% accuracy, with the ADP1050. With this NTC thermistor and resistor combination, the ADP1050 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 value in Register 0xFEAB 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. For example, to use a value of 46 µA as the current source, complete the following steps: 1. 2. 3. Place a known resistor (Rx) from the RTD pin to AGND. Set Register 0xFE2D[7:6] to 11 binary (40 µA). Increase the value of Register 0xFE2D[5:0], 1 LSB at a time, until the voltage at the RTD pin is VRTD = 46 µA × Rx. The current source is now calibrated and set to the factory default value. Rev. A | Page 36 of 92 Data Sheet ADP1050 LAYOUT GUIDELINES This section explains best practices to ensure optimal performance of the ADP1050. In general, place all components of the ADP1050 control circuit as close to the ADP1050 as possible. The OVP and VS+ signals are referred to VS−. All other signals are referred to the AGND plane. VCORE PIN CS1 PIN Place a 10 kΩ (±0.1%) resistor from the RES pin to AGND, as close as possible to the ADP1050. Route the traces from the current sense transformer to the ADP1050, parallel to each other. Keep the traces near each other, but far away from the switch nodes. Place a 330 nF decoupling capacitor from the VCORE pin to AGND, as close as possible to the ADP1050. RES PIN SDA AND SCL PINS VS+ AND VS− PINS Route the traces from the remote voltage sense point to the ADP1050 parallel to each other. Connect VS− to AGND, with a low ohmic connection. Keep the traces near each other, but far away from the switch nodes. Place a 100 nF capacitor from VS− to AGND to reduce the common-mode noise. If VS− is connected directly to AGND, the capacitor is not needed. Place 10 Ω resistors between the PWM outputs and isolators or drivers inputs, especially if the isolators and drivers are far from the ADP1050. Keep the traces far away from the switch nodes. VDD PIN Place decoupling capacitors as close as possible to the ADP1050. A 2.2 μF capacitor connected from VDD to AGND is recommended. Route the traces to the SDA and SCL pins parallel to each other. Keep the traces near each other, but far away from the switch nodes. EXPOSED PAD Solder the exposed pad under the ADP1050 to the PCB AGND plane. RTD PIN Route the traces (including the ground returning trace) from the thermistor to the ADP1050. Place the thermistor near the hotspot of the power supply, and keep the thermistor and the traces away from the switching node. Place the 1 nF filtering capacitor nearby, in parallel with the thermistor. AGND PIN Create an AGND ground plane on the adjacent layer of the ADP1050 and make a single-point (star) connection to the power supply system ground. Rev. A | Page 37 of 92 ADP1050 Data Sheet PMBus/I2C COMMUNICATION The PMBus slave allows a device to interface with a PMBuscompliant master device, as specified by the PMBus Power System Management Protocol Specification (Revision 1.2, September 6, 2010). The PMBus slave is a 2-wire interface that can be used to communicate with other PMBus compliant devices and is compatible in a multimaster, multislave bus configuration. In this case, the PMBus slave must respond to the invalid command or data, as defined by the PMBus specification, and indicate to the master device that an error or fault condition has occurred. This method of handshaking can be used as a first level of defense against inadvertent programming of the slave device that can potentially damage the chip or system. PMBus FEATURES The PMBus specification defines a set of generic PMBus commands that is recommended for a power management system; however, each PMBus device manufacturer can choose to implement and support certain commands that are deemed fit for the system. In addition, the PMBus device manufacturer can choose to implement manufacturer specific commands, the functions of which are not included in the generic PMBus command set. The list of standard PMBus and manufacturer specific commands can be found in the PMBus Command Set and Manufacturer Specific Extended Command List sections. The function of the PMBus slave is to decode the command that is sent from the master device and respond as requested. Communication is established using an I2C-like, 2-wire interface with a clock line (SCL) and data line (SDA). The PMBus slave is designed to externally move chunks of 8-bit data (bytes) while maintaining compliance with the PMBus protocol. The PMBus protocol is based on the System Management Bus (SMBus) Specification, Version 2.0, August 2000. The SMBus specification is, in turn, based on the Philips I2C Bus Specification, Version 2.1, dated January 2000. The PMBus incorporates the following features: • • • • • • • Slave operation on multiple device systems 7-bit addressing 100 kbps and 400 kbps data rates General call address support Support for clock low extension (clock stretching) Separate multibyte receive and transmit FIFOs Extensive fault monitoring PMBus/I2C ADDRESS The PMBus address of the ADP1050 is set by connecting an external resistor from the ADD pin (Pin 19) to AGND. Table 9 lists the recommended resistor values and the associated PMBus addresses. Eight different addresses can be used. Table 9. PMBus Address Settings and Resistor Values OVERVIEW The PMBus slave module is a 2-wire interface that can be used to communicate with other PMBus compliant devices. Its transfer protocol is based on the Philips I2C transfer mechanism. The ADP1050 is always configured as a slave device in the overall system. The ADP1050 communicates with the master device using one data pin (SDA, Pin 12) and one clock pin (SCL, Pin 11). Because the ADP1050 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 request of the master. Communication is initiated when the master device sends a command to the PMBus slave device. Commands can be read or write commands, and data is transferred between the devices in a byte wide format. Commands can also be send commands; in that case, the command is executed by the slave device upon receiving the stop bit. The stop bit is the last bit in a complete data transfer, as defined in the PMBus/I2C communication protocol. During communication, the master and slave devices send acknowledge (A) or no acknowledge (A) bits as a method of handshaking between devices. See the PMBus specification for a more detailed description of the communication protocol. When communicating with the master device, it is possible for illegal or corrupted data to be received by the PMBus slave. PMBus Address 0x70 0x71 0x72 0x73 0x74 0x75 0x76 0x77 Resistor Value (kΩ) 10 (or connect the ADD pin directly to AGND) 31.6 51.1 71.5 90.9 110 130 150 (or connect the ADD pin directly to VDD) The recommended resistor values in Table 9 can vary by ±2 kΩ. Therefore, it is recommended that 1% tolerance resistors be used on the ADD pin. The ADP1050 responds to the standard PMBus broadcast address (general call) of 0x00. However, when more than one ADP1050 device is connected to the master device, it is not recommended that the general call address be used because the data returned by multiple slave devices is corrupted. For more information, see the General Call Support section. DATA TRANSFER Format Overview The PMBus slave follows the transfer protocol of the SMBus specification, which is based on the fundamental transfer protocol format of the 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 37. See the Rev. A | Page 38 of 92 Data Sheet ADP1050 SMBus and I2C specifications for in-depth descriptions of the transfer protocols. Command Overview Data transfer using the PMBus slave is established using PMBus commands. The PMBus specification requires that all PMBus commands start with a slave address, with the R/W bit cleared to 0, followed by the command code. All PMBus commands that are supported by the ADP1050 follow one of the protocol types shown in Figure 38 through Figure 44. Figure 37 through Figure 44 use the abbreviations listed in Table 10. Table 10. Abbreviations Used in Data Transfer Diagrams Abbreviation S P Sr W R A A The ADP1050 also supports manufacturer specific extended commands. These commands follow the same protocol as the standard PMBus commands; however, the command code consists of two bytes that range from 0xFF00 to 0xFFAF. Using the manufacturer specific extended commands, the PMBus device manufacturer can add an additional 256 manufacturer specific commands to its PMBus command set. N/A means not applicable. 7-BIT SLAVE ADDRESS W A 8-BIT DATA A P 12039-043 S MASTER TO SLAVE SLAVE TO MASTER Figure 37. Basic Data Transfer 7-BIT SLAVE ADDRESS W A COMMAND CODE A P 12039-044 S MASTER TO SLAVE SLAVE TO MASTER Figure 38. Send Byte Protocol 7-BIT SLAVE ADDRESS S W A COMMAND CODE A DATA BYTE A P 12039-045 MASTER TO SLAVE SLAVE TO MASTER Figure 39. Write Byte Protocol W COMMAND CODE A DATA BYTE LOW A A DATA BYTE HIGH A P 12039-046 S 7-BIT SLAVE ADDRESS MASTER TO SLAVE SLAVE TO MASTER Figure 40. Write Word Protocol S 7-BIT SLAVE ADDRESS W A COMMAND CODE 7-BIT SLAVE R ADDRESS A Sr A DATA BYTE A P 12039-047 MASTER TO SLAVE SLAVE TO MASTER Figure 41. Read Byte Protocol 7-BIT SLAVE ADDRESS W A COMMAND CODE A Sr 7-BIT SLAVE ADDRESS R A DATA BYTE LOW A DATA BYTE HIGH A P 12039-048 S MASTER TO SLAVE SLAVE TO MASTER Figure 42. Read Word Protocol S 7-BIT SLAVE W ADDRESS A COMMAND CODE A BYTE COUNT = N A DATA BYTE 1 A DATA BYTE N A P 12039-049 MASTER TO SLAVE SLAVE TO MASTER Figure 43. Block Write Protocol S 7-BIT SLAVE W ADDRESS A COMMAND CODE A Sr 7-BIT SLAVE R ADDRESS A BYTE COUNT = N A DATA BYTE 1 A DATA BYTE N A P 12039-050 1 Setting1 N/A N/A N/A 0 1 0 1 Description Start condition Stop condition Repeated start condition Write bit Read bit Acknowledge bit No acknowledge bit MASTER TO SLAVE SLAVE TO MASTER Figure 44. Block Read Protocol Rev. A | Page 39 of 92 ADP1050 Data Sheet Clock Generation and Stretching 10-BIT ADDRESSING The ADP1050 is always a PMBus slave device in the overall system; therefore, the device never needs to generate the clock, which is done by the master device in the system. However, the PMBus slave device is capable of clock stretching to put the master in a wait state. By stretching the SCL signal during the low period, the slave device communicates to the master device that it is not ready and the master device must wait. The ADP1050 does not support 10-bit addressing as defined in the I2C specification. Conditions in which the PMBus slave device stretches the SCL line low include the following: • • • FAST MODE Fast mode, with a data rate of 400 kbps, uses essentially the same mechanics as the standard mode of operation; the electrical specifications and timing are most affected. The PMBus slave is capable of communicating with a master device operating in fast mode or in standard mode, which has a data rate of 100 kbps. FAULT CONDITIONS The master device is transmitting at a higher baud rate than the slave device. The receive buffer of the slave device is full and must be read before continuing. This prevents a data overflow condition. The slave device is not ready to send data that the master has requested. The PMBus protocol provides a comprehensive set of fault conditions that must be monitored and reported. These fault conditions can be grouped into two major categories: communication faults and monitoring faults. Note that the PMBus slave device can stretch the SCL line only during the low period. Also, whereas the I2C specification allows indefinite stretching of the SCL line, the PMBus specification limits the maximum time that the SCL line can be stretched, or held low, to 25 ms. After this time period, the slave device must release the communication lines and reset its state machine. Start and Stop Conditions Start and stop conditions involve serial data transitions when the serial clock is at a logic high level. The PMBus slave device monitors the SDA and SCL lines to detect the start and stop conditions and transitions its internal state machine accordingly. Typical start and stop conditions are shown in Figure 45. SCL Communication faults are error conditions associated with the data transfer mechanism of the PMBus protocol. Monitoring faults are error conditions associated with the operation of the ADP1050, such as output overvoltage protection. These fault conditions are described in detail in the Power Monitoring, Flags, and Fault Responses section. TIMEOUT CONDITIONS The SMBus specification includes three clock stretching specifications related to timeout conditions. A timeout condition occurs if any single SCL clock pulse is held low for longer than the minimum tTIMEOUT value of 25 ms. Upon detecting the timeout condition, the PMBus slave device has 10 ms to abort the transfer, release the bus lines, and be ready to accept a new start condition. The device that is initiating the timeout must hold the SCL clock line low for at least the maximum tTIMEOUT value of 35 ms, guaranteeing that the slave device is given enough time to reset its communication protocol. DATA TRANSMISSION FAULTS START 12039-154 SDA STOP Figure 45. Start and Stop Conditions GENERAL CALL SUPPORT The PMBus slave is capable of decoding and acknowledging a general call address. The PMBus slave device responds to both its own address and the general call address (0x00). The general call address enables all devices on the PMBus to be written to simultaneously. Note that all PMBus commands must start with a slave address, with the R/W bit cleared to 0 and followed by the command code. This is also true when using the general call address to communicate with the PMBus slave device. Data transmission faults occur when two communicating devices violate the PMBus communication protocol, as specified in the PMBus Power System Management Protocol Specification (Revision 1.2, September 6, 2010). See the specification for more details on each fault conditions. Corrupted Data, Packet Error Checking (PEC) Packet error checking is not supported by the ADP1050. Sending Too Few Bits Transmission is interrupted by a start or stop condition before a complete byte (eight bits) has been sent. This function is 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. This function is not supported; any received data is ignored. Rev. A | Page 40 of 92 Data Sheet ADP1050 Host Sends or Reads Too Few Bytes Invalid or Unsupported Command Code If a host ends a packet with a stop condition before the required bytes are sent/received, it is assumed that the host intended to stop the transfer. Therefore, the PMBus does not consider this to be an error and takes no action, except to flush any remaining bytes in the transmit FIFO. If an invalid or unsupported command code is sent to the PMBus slave, the code is considered to be a data content fault, and the PMBus slave responds as follows: Host Sends Too Many Bytes • • If a host sends more bytes than are expected for the corresponding command, the PMBus slave considers this a data transmission fault and responds as follows: • • • Issues a no acknowledge for all unexpected bytes as they are received Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) Host Reads Too Many Bytes If a host reads more bytes than are expected for the corresponding command, the PMBus slave considers this a data transmission fault and responds as follows: • • Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) Device Busy • Reserved Bits Accesses to reserved bits are not a fault. Writes to reserved bits are ignored, and reads from reserved bits return undefined data. Write to Read Only Commands If a host performs a write to a read only command, the PMBus slave considers this a data content fault and responds as follows: • • • Note that this is the same error described in the Host Sends Too Many Bytes section. Read from Write Only Commands • DATA CONTENT FAULTS Data content faults may occur when the data transmission is successful, but the PMBus slave device cannot process the data that is received from the master device. Improperly Set Read Bit in the Address Byte • Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) Note that this is the same error response that is described in the Host Reads Too Many Bytes section. All PMBus commands start with a slave address with the R/W bit cleared to 0, followed by the command code. If a host starts a PMBus transaction with R/W set in the address phase (equivalent to an I2C read), the PMBus slave considers this a data content fault and responds as follows: • Issues a no acknowledge for all unexpected data bytes as they are received Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) If a host performs a read from a write only command, the PMBus slave considers this a data content fault and responds as follows: The PMBus slave device is too busy to respond to a request from the master device. This condition is not supported in the ADP1050. • • • Issues a no acknowledge for the illegal/unsupported command byte and data bytes Flushes and ignores the received command and data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) Acknowledges (ACKs) the address byte Issues a no acknowledge for the command and data bytes Sends all 1s (0xFF) as long as the host continues to request data Sets the CML bit in the STATUS_BYTE command register (Register 0x78[1]) Rev. A | Page 41 of 92 ADP1050 Data Sheet The ADP1050 has a built-in EEPROM controller that is used to communicate with the embedded 8000-byte EEPROM. The EEPROM, also called Flash/EE, is partitioned into two major blocks: the information block and the main block. The information block contains 128 8-bit bytes (for internal use only), and the main block contains 8000 8-bit bytes. The main block is further partitioned into 16 pages, with each page containing 512 bytes. EEPROM FEATURES The function of the EEPROM controller is to decode the operation that is requested by the ADP1050 and to provide the necessary timing to the EEPROM interface. Data is written to or read from the EEPROM, as requested by the decoded command. Features of the EEPROM controller include • • • • • Separate page erase functions for each page in the EEPROM Single byte and multibyte (block) read of the information block with up to 128 bytes at a time Single byte and multibyte (block) write and read of the main block with up to 256 bytes at a time Automatic upload on startup, from the user settings to the internal registers Separate commands to upload and download data, from the factory default or user settings to the internal registers EEPROM OVERVIEW The EEPROM controller provides an interface between the ADP1050 core logic and the built-in EEPROM. The user can control data access to and from the EEPROM through this controller interface. Different PMBus commands are available for the read, write, and erase operations to the EEPROM. Communication is initiated by the master device sending a command to the PMBus slave device to access data from or send data to the EEPROM. Read, write, and erase commands are supported. Data is transferred between devices in a byte wide format. Using a read command, data is received from the EEPROM and transmitted to the master device. Using a write command, data is received from the master device and stored in the EEPROM through the EEPROM controller. EEPROM PASSWORD On ADP1050 VDD power-up, the EEPROM is locked and protected from accidental writes or erases. Only reads from Page 2 to Page 15 are allowed when the EEPROM is locked. Before any data can be written (programmed) to the EEPROM, the EEPROM must be unlocked for write access. After it is unlocked, the EEPROM is opened for reading, writing, and erasing. Unlock the EEPROM To unlock the EEPROM, perform two consecutive writes with the correct password (default = 0xFF), using the EEPROM_PASSWORD command (Register 0xD5). The EEPROM_UNLOCKED flag (Register 0xFEA2[3]) is set to indicate that the EEPROM is unlocked for write access. Lock the EEPROM To lock the EEPROM, write any byte other than the correct password, using the EEPROM_PASSWORD command (Register 0xD5). The EEPROM_UNLOCKED flag is cleared to indicate that the EEPROM is locked from write access. Change the EEPROM Password To change the EEPROM password, first write the correct password, using the EEPROM_PASSWORD command (Register 0xD5). Immediately write the new password, using the same command. The password is now changed to the new password. 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 3 is reserved for storing the power board parameters for the GUI. Only Page 4 to Page 15 of the main block can 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. Each page of the main block, from Page 4 to Page 15, can be individually erased using the EEPROM_PAGE_ERASE command (Register 0xD4). For example, to perform a page erase of Page 10, execute the command shown in Figure 46. S 7-BIT SLAVE ADDRESS W A COMMAND CODE A DATA BYTE MASTER TO SLAVE SLAVE TO MASTER A P 12039-051 EEPROM Figure 46. Example Erase Command In this example, command code = 0xD4 and data byte = 0x0A. Note that it is important to wait at least 35 ms for the page erase operation to complete before executing the next PMBus command. 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 to logic high) for that byte to be writeable. Subsequent writes to any bytes in that page are allowed as long as that byte has not been previously written to a logic low. On power-up, Page 0 and Page 1 are also protected from read access. The EEPROM must first be unlocked to read these pages. Rev. A | Page 42 of 92 Data Sheet ADP1050 READ OPERATION (BYTE READ AND BLOCK READ) Read from Main Block, Page 0 and Page 1 Page 0 and Page 1 of the main block are reserved for storing the default settings and the 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 and Page 1 returns invalid data. Read from Main Block, Page 2 to Page 15 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 multiple bytes in series, using the EEPROM_DATA_xx commands (Register 0xB0 to Register 0xBF). Before executing this command, the user must program the number of bytes to read, using the EEPROM_NUM_RD_BYTES command (Register 0xD2). Also, the user can program the offset from the page boundary where the first read byte is returned, using the EEPROM_ADDR_OFFSET command (Register 0xD3). In the following example, three bytes from Page 4 are read from the EEPROM, starting from the sixth byte of that page. Set number of return bytes = 3. W A 0xD2 A A 0x03 W A Data in Page 2 to Page 15 of the EEPROM main block can be programmed (written to) one byte at a time or multiple bytes in series, using the EEPROM_DATA_xx commands (Register 0xB0 to Register 0xBF). Before executing this command, the user can program the offset from the page boundary where the first byte is written, using the EEPROM_ADDR_OFFSET command (Register 0xD3). 0xD3 A 0x05 A 0x00 A Set address offset = 256. 7-BIT SLAVE ADDRESS S P 12039-056 7-BIT SLAVE ADDRESS Before performing a write to Page 2 through Page 15 of the main block, the user must first unlock the EEPROM (see the Unlock the EEPROM section). 1. Set address offset = 5. S Write to Main Block, Page 2 to Page 15 In the following example, four bytes are written to Page 9, starting from the 257th byte of that page. Figure 47. Set Number of Return Bytes = 3 2. Page 0 and Page 1 of the main block are reserved for storing the default settings and the user settings, respectively. The user cannot perform a direct write operation to Page 0 or Page 1 using the EEPROM_DATA_xx commands. If the user writes to Page 0, Page 1 returns a no acknowledge. To program the register contents of Page 1 of the main block, it is recommended that the STORE_ USER_ALL command be used (Register 0x15). See the Save Register Settings to the User Settings section. If the targeted page has not yet been erased, the user can erase the page, as described in the EEPROM Password section. P MASTER TO SLAVE SLAVE TO MASTER Write to Main Block, Page 0 and Page 1 MASTER TO SLAVE SLAVE TO MASTER W BYTE COUNT = 0x03 A A 0xB4 DATA BYTE 1 A A Sr 7-BIT SLAVE ADDRESS ... DATA BYTE 3 R A 7-BIT SLAVE ADDRESS A 0x00 0x01 A P A A 0xB9 ... A DATA BYTE 4 BYTE COUNT = 4 A A P MASTER TO SLAVE SLAVE TO MASTER Figure 51. Write Four Bytes to Page 9 Figure 49. Read Three Bytes from Page 4 Note that the block read command can read a maximum of 256 bytes for any single transaction. W DATA BYTE 1 P MASTER TO SLAVE SLAVE TO MASTER A Write four bytes to Page 9. S A 12039-057 S 7-BIT SLAVE ADDRESS 0xD3 Figure 50. Set Address Offset = 256 2. Read three bytes from Page 4. A MASTER TO SLAVE SLAVE TO MASTER Figure 48. Set Address Offset = 5 3. W 12039-058 7-BIT SLAVE ADDRESS The user cannot write directly to the information block; this block is used by the ADP1050 to store the first flag information (see the First Flag ID Recording section). Note that the block write command can write a maximum of 256 bytes for any single transaction. Rev. A | Page 43 of 92 12039-059 S 12039-055 1. WRITE OPERATION (BYTE WRITE AND BLOCK WRITE) ADP1050 Data Sheet 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: • • On power-up. The user settings are automatically downloaded into the internal registers, powering up the ADP1050 in a state previously saved by the user. On execution of the RESTORE_USER_ALL command (Register 0x16). 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. 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 on Page 1 of the EEPROM main block, after which the registers are stored in the EEPROM. Therefore, it is important to wait at least 40 ms for the operation to complete before executing the next PMBus command. EEPROM CRC CHECKSUM As a simple method of checking that the values downloaded from the EEPROM and the internal registers are consistent, a CRC checksum is implemented. • Download Factory Settings to Registers The factory default settings are stored in Page 0 of the EEPROM main block. The factory settings can be downloaded from the EEPROM into the internal registers, using the RESTORE_ DEFAULT_ALL command (Register 0x12). When this command is executed, the EEPROM password is also reset to the factory default setting of 0xFF. • SAVING REGISTER SETTINGS TO THE EEPROM The register settings cannot be saved to the factory scratch pad located in Page 0 of the EEPROM main block. This is to prevent the user from accidentally overriding the factory trim settings and the default register settings. Save Register Settings to the 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 0x15). Before this command can be executed, the EEPROM must first be unlocked for writing (see the Unlock the EEPROM section). 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 is saved that sums all 1s from the values loaded into the registers. 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 CRC_FAULT flag is set (Register 0xFEA2[2]). To read the EEPROM CRC checksum value, execute the EEPROM_CRC_CHKSUM command (Register 0xD1). This command returns the CRC checksum accumulated in the counter during the download operation. Note that the CRC checksum is an 8-bit cyclical accumulator that wraps around to 0 when 255 is reached. Rev. A | Page 44 of 92 Data Sheet ADP1050 GUI SOFTWARE Free GUI software is available for programming and configuring the ADP1050. The ADP1050 GUI, which is intuitive by design, dramatically reduces power supply design and development time. 12039-123 The software includes filter design and power supply PWM topology windows. The ADP1050 GUI is also an information center, displaying the status of all readings, monitoring, and flags on the ADP1050. For more information about the ADP1050 GUI, contact Analog Devices, Inc., for the latest software and a user guide. Evaluation boards are also available by contacting Analog Devices or by visiting http://www.analog.com/digitalpower. Figure 52. GUI Software Rev. A | Page 45 of 92 ADP1050 Data Sheet PMBus COMMAND SET Table 11. PMBus/SMBus Command List Overview Command Code Command Name 0x01 OPERATION PMBus/ SMBus Transaction Type R/W 0x02 ON_OFF_CONFIG R/W 0x03 CLEAR_FAULTS Send byte 0x10 WRITE_PROTECT R/W 0x12 RESTORE_DEFAULT_ALL Send byte 0x15 STORE_USER_ALL Send byte 0x16 RESTORE_USER_ALL Send byte 0x19 CAPABILITY R 0x20 VOUT_MODE R 0x21 0x22 VOUT_COMMAND VOUT_TRIM R/W R/W 0x23 VOUT_CAL_OFFSET R/W 0x24 0x25 VOUT_MAX VOUT_MARGIN_HIGH R/W R/W 0x26 VOUT_MARGIN_LOW R/W 0x27 0x29 VOUT_TRANSITION_RATE VOUT_SCALE_LOOP R/W R/W 0x2A VOUT_SCALE_MONITOR R/W 0x33 0x35 FREQUENCY_SWITCH VIN_ON R/W R/W 0x36 VIN_OFF R/W 0x40 0x41 0x44 VOUT_OV_FAULT_LIMIT R/W VOUT_OV_FAULT_RESPONSE R/W VOUT_UV_FAULT_LIMIT R/W 0x45 0x4F 0x50 0x5E VOUT_UV_FAULT_RESPONSE OT_FAULT_LIMIT OT_FAULT_RESPONSE POWER_GOOD_ON R/W R/W R/W R/W 0x5F POWER_GOOD_OFF R/W Number of Data Bytes Default Value 1 Description 1 0x00 Turns the unit on and off in conjunction with the input from the CTRL pin. 1 0x00 The combination of CTRL pin and serial bus commands needed to turn the unit on and off. 0 N/A Clears all bits in the PMBus status registers simultaneously. 1 0x00 Protects against accidental writes to the PMBus device. Reads are allowed. 0 N/A Downloads the factory default settings from EEPROM (Page 0) to registers. 0 N/A Saves the user settings from the registers to the EEPROM (Page 1). 0 N/A Downloads the user settings from the EEPROM (Page 1) to the registers. 1 0x20 Allows the host system to determine the capabilities of the PMBus device. 1 0x16 Sets/reads the formats for the output voltage related commands. 2 0x0000 Sets the output voltage to the commanded value. 2 0x0000 Applies a fixed offset voltage to the output voltage command value. 2 0x0000 Applies a fixed offset voltage to the output voltage command value. 2 0x0000 Sets an upper limit on the output voltage. 2 0x0000 Defines the voltage to which the output is set when the OPERATION command is set to margin high. 2 0x0000 Defines the voltage to which the output is set when the OPERATION command is set to margin low. 2 0x7BFF Sets the rate at which the output changes voltage. 2 0x0001 The scale factor for setting the output voltage, which is related to the resistor divider. 2 0x0001 The scale factor for the READ_VOUT command, which typically is the same as the VOUT_SCALE_LOOP command. 2 0x0031 Sets the switching frequency of the output voltage. 2 0x0000 Sets the input voltage at which the unit starts the power conversion. 2 0x0000 Sets the input voltage at which the unit stops the power conversion. 2 0x0000 Sets the limit for triggering the VOUT_OV_FAULT flag. 1 0x00 The fault response for the VOUT_OV_FAULT flag. 2 0x0000 Sets the limit for triggering the VOUT_UV_FAULT flag. 1 0x00 The fault response for the VOUT_UV_FAULT flag. 2 0x0000 Sets the limit for triggering the OT_FAULT flag. 1 0x00 The fault response for the OT_FAULT flag. 2 0x0000 Sets the output voltage at which an optional POWER_GOOD signal is asserted. 2 0x0000 Sets the output voltage at which an optional POWER_GOOD signal is negated. Rev. A | Page 46 of 92 Data Sheet ADP1050 Command Code Command Name 0x60 TON_DELAY PMBus/ SMBus Transaction Type R/W 0x61 TON_RISE R/W 0x64 TOFF_DELAY R/W 0x78 STATUS_BYTE R 0x79 STATUS_WORD R 0x7A 0x7C STATUS_VOUT STATUS_INPUT R R 0x7D 0x7E STATUS_TEMPERATURE STATUS_CML R R 0x88 0x89 0x8B 0x8D 0x94 0x95 READ_VIN READ_IIN READ_VOUT READ_TEMPERATURE READ_DUTY_CYCLE READ_FREQUENCY R R R R R R 0x98 READ_PMBUS_REVISION R 0x99 0x9A MFR_ID MFR_MODEL R/W R/W 0x9B 0xAD 0xAE 0xB0 MFR_REVISION IC_DEVICE_ID IC_DEVICE_REV EEPROM_DATA_00 R/W R R R block 0xB1 EEPROM_DATA_01 R block 0xB2 EEPROM_DATA_02 R/W block 0xB3 EEPROM_DATA_03 R/W block 0xB4 EEPROM_DATA_04 R/W block 0xB5 EEPROM_DATA_05 R/W block 0xB6 EEPROM_DATA_06 R/W block 0xB7 EEPROM_DATA_07 R/W block 0xB8 EEPROM_DATA_08 R/W block 0xB9 EEPROM_DATA_09 R/W block Number of Data Bytes Default Value 1 Description 2 0x0000 The time from when a start condition is received (as programmed by the ON_OFF_CONFIG command) until the output voltage starts to rise. 2 0xC00D The time from when the output begins to rise until the voltage has entered the regulation band. 2 0x0000 The time from when a stop condition is received (as programmed by the ON_OFF_CONFIG command) until the unit stops transferring energy to the output. 1 0x00 Returns the low byte of the STATUS_WORD command. 2 0x0000 Returns the low byte and high byte of the STATUS_WORD command. 1 0x00 Returns the fault flag for the output voltage. 1 0x00 Returns the fault flag for the input voltage and current. 1 0x00 Returns the fault flag for the OT fault and warning. 1 0x00 Returns the fault flag for the communication memory and logic. 2 0x0000 Returns the input voltage value. 2 0x0000 Returns the input current value. 2 0x0000 Returns the output voltage value. 2 0x0000 Returns the temperature reading in degrees Celsius. 2 0x0000 Returns the duty cycle of the power converter. 2 0x0000 Returns the switching frequency of the power converter. 1 0x22 Reads the PMBus revision to which the device is compliant. 1 0x00 Reads/writes the ID of the manufacturer. 1 0x00 Reads/writes the model number of the manufacturer. 1 0x00 Reads/writes revision number of the manufacturer. 2 0x4151 Reads the IC device ID. 1 0x20 Reads the IC device revision. Variable N/A Block reads from Page 0. The EEPROM must first be unlocked. Variable N/A Block reads from Page 1. The EEPROM must first be unlocked. Variable N/A Blocks reads/writes to Page 2. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 3. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 4. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 5. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 6. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 7. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 8. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 9. The EEPROM must first be unlocked for writes. Rev. A | Page 47 of 92 ADP1050 1 Data Sheet Command Code Command Name 0xBA EEPROM_DATA_10 PMBus/ SMBus Transaction Type R/W block 0xBB EEPROM_DATA_11 R/W block 0xBC EEPROM_DATA_12 R/W block 0xBD EEPROM_DATA_13 R/W block 0xBE EEPROM_DATA_14 R/W block 0xBF EEPROM_DATA_15 R/W block 0xD1 EEPROM_CRC_CHKSUM R 0xD2 EEPROM_NUM_RD_BYTES R/W 0xD3 0xD4 EEPROM_ADDR_OFFSET EEPROM_PAGE_ERASE R/W W 0xD5 EEPROM_PASSWORD W 0xD6 TRIM_PASSWORD W 0xD7 CHIP_PASSWORD W 0xD8 VIN_SCALE_MONITOR R/W 0xD9 IIN_SCALE_MONITOR R/W 0xF1 0xFA 0xFB EEPROM_INFO MFR_SPECIFIC_1 MFR_SPECIFIC_2 Read block R/W R/W Number of Data Bytes Default Value 1 Description Variable N/A Blocks reads/writes to Page 10. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 11. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 12. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 13. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 14. The EEPROM must first be unlocked for writes. Variable N/A Blocks reads/writes to Page 15. The EEPROM must first be unlocked for writes. 1 N/A Returns the CRC checksum value from the EEPROM download operation. 1 N/A Sets the number of return read bytes when using the EEPROM_DATA_xx commands. 2 N/A Sets the address offset of the current EEPROM page. 1 N/A Performs a page erase on a selected page (Page 3 to Page 15). Wait at least 35 ms for each page erase operation. The EEPROM must first be unlocked. A page erase of Page 0 and Page 1 is not allowed. 1 0xFF Writes the password to this register to unlock the EEPROM, and/or changes the EEPROM password. 1 0xFF Writes the password to this register to unlock the trim registers for write access. 2 0xFFFF Writes the password to this register to unlock the chip password for register access. 2 0x0001 The scale factor for the input voltage reading (READ_VIN). 2 0x0001 The scale factor for the input current reading (READ_IIN). Variable N/A Reads the first fault information. 1 0x00 Stores the user customized information. 1 0x00 Stores the user customized information. N/A = Not applicable. Rev. A | Page 48 of 92 Data Sheet ADP1050 MANUFACTURER SPECIFIC EXTENDED COMMAND LIST Table 12. Manufacturer Specific Extended Command List Overview Address Register Function Flag Configuration Registers 0xFE00 IIN_OC_FAST_FAULT_RESPONSE 0xFE01 CS3_OC_FAULT_RESPONSE, extended VOUT_OV_FAULT_RESPONSE 0xFE02 VIN_UV_FAULT_RESPONSE 0xFE03 FLAGIN_RESPONSE 0xFE05 Flag reenable delay, VDD_OV_RESPONSE Soft Start Software Reset Setting Registers 0xFE06 Software reset go command 0xFE07 Software reset settings 0xFE08 Synchronous rectifier (SR) soft start settings 0xFE09 Soft start setting of open-loop operation Blanking and PGOOD Setting Registers 0xFE0B 0xFE0C 0xFE0D Flag blanking during soft start Volt-second balance blanking and SR disable during soft start PGOOD mask settings 0xFE0E PGOOD flag debounce 0xFE0F Debounce time for asserting PGOOD Switching Frequency and Synchronization Setting Registers 0xFE11 Synchronization delay time 0xFE12 Synchronization general settings 0xFE13 Dual-ended topology mode Current Sense and Limit Setting Registers 0xFE14 CS1 gain trim 0xFE19 CS3 OC debounce 0xFE1A IIN_OC_FAST_FAULT_LIMIT 0xFE1B CS1 cycle-by-cycle current limit reference 0xFE1D Matched cycle-by-cycle current-limit settings 0xFE1E SR1 and SR2 response to cycle-by-cycle current limit 0xFE1F CS1 cycle-by-cycle current-limit settings Voltage Sense and Limit Setting Registers 0xFE20 VS gain trim 0xFE25 Prebias start-up enable 0xFE26 VOUT_OV_FAULT flag debounce 0xFE28 VF gain trim 0xFE29 VIN_ON and VIN_OFF delay Temperature Sense and Protection Setting Registers 0xFE2A RTD gain trim 0xFE2B RTD offset trim (MSBs) 0xFE2C RTD offset trim (LSBs) 0xFE2D RTD current source settings 0xFE2F OT hysteresis settings Digital Compensator and Modulation Setting Registers 0xFE30 Normal mode compensator low frequency gain settings 0xFE31 Normal mode compensator zero settings 0xFE32 Normal mode compensator pole settings 0xFE33 Normal mode compensator high frequency gain settings 0xFE38 CS1 threshold for volt-second balance 0xFE39 Nominal modulation value for prebias startup 0xFE3A SR driver delay 0xFE3B PWM 180° phase shift settings 0xFE3C Modulation limit 0xFE3D Feedforward and soft start filter gain Rev. A | Page 49 of 92 ADP1050 Data Sheet Address Register Function PWM Outputs Timing Registers 0xFE3E OUTA rising edge timing 0xFE3F OUTA falling edge timing 0xFE40 OUTA rising and falling edges timing (LSBs) 0xFE41 OUTB rising edge timing 0xFE42 OUTB falling edge timing 0xFE43 OUTB rising and falling edges timing (LSBs) 0xFE4A SR1 rising edge timing 0xFE4B SR1 falling edge timing 0xFE4C SR1 rising and falling edges timing (LSBs) 0xFE4D SR2 rising edge timing 0xFE4E SR2 falling edge timing 0xFE4F SR2 rising and falling edges timing (LSBs) 0xFE50 OUTA and OUTB modulation settings 0xFE52 SR1 and SR2 modulation settings 0xFE53 PWM output disable Volt-Second Balance Control Registers 0xFE54 Volt-second balance control general settings 0xFE55 Volt-second balance control on OUTA and OUTB 0xFE57 Volt-second balance control on SR1 and SR2 Duty Cycle Reading Setting Registers 0xFE58 Duty cycle reading settings 0xFE59 Input voltage compensation multiplier Other Setting Registers 0xFE61 Go commands 0xFE62 Customized register 0xFE63 Modulation reference MSBs setting for open-loop input voltage feedforward operation 0xFE64 Modulation reference LSBs setting for open-loop input voltage feedforward operation 0xFE65 Current value update rate setting 0xFE67 Open-loop operation settings 0xFE69 Pulse skipping mode threshold 0xFE6A CS3_OC_FAULT_LIMIT 0xFE6B Modulation threshold for OVP selection 0xFE6C Modulation flag for OVP selection 0xFE6D OUTA and OUTB adjustment reference during synchronization 0xFE6F SR1 and SR2 adjustment reference during synchronization Manufacturer Specific Fault Flag Registers 0xFEA0 Flag Register 1 0xFEA1 Flag Register 2 0xFEA2 Flag Register 3 0xFEA3 Latched Flag Register 1 0xFEA4 Latched Flag Register 2 0xFEA5 Latched Flag Register 3 0xFEA6 First flag ID Manufacturer Specific Value Reading Registers 0xFEA7 CS1 value 0xFEA9 CS3 value 0xFEAA VS± value 0xFEAB RTD value 0xFEAC VF value 0xFEAD Duty cycle value 0xFEAE Input power value Rev. A | Page 50 of 92 Data Sheet ADP1050 PMBus COMMAND DESCRIPTIONS BASIC PMBus COMMANDS OPERATION The OPERATION command is used to turn the unit on and off in conjunction with the input from the CTRL pin. It is also used to set the output voltage to the upper or lower voltage margin. The unit stays in the commanded operating mode until a subsequent OPERATION command instructs the device to change to another mode. Table 13. Register 0x01—OPERATION Bits [7:6] [5:4] [3:0] Bit Name/Function Enable Margin control Reserved R/W R/W Description These bits determine the response to the OPERATION command. R/W Bit 7 Bit 6 Description 0 0 Immediate off (no sequencing) 0 1 Soft off (power-down based on the programmed TOFF_DELAY command) 1 0 Unit on 1 1 Reserved These bits set the voltage margin level. R Bit 5 Bit 4 0 0 0 1 1 0 1 1 Reserved. Description Off Margin low Margin high Reserved ON_OFF_CONFIG The ON_OFF_CONFIG command configures the combination of CTRL pin input and serial bus commands needed to turn the unit on and off, including how the unit responds when power is applied. Table 14. Register 0x02—ON_OFF_CONFIG Bits [7:5] 4 Bit Name/Function Reserved Power-up control R/W R R/W 3 Command enable R/W 2 Pin enable R/W 1 CTRL pin polarity R/W 0 Power-down delay setting R/W Description Reserved. Controls how the device responds to the OPERATION command. 0 = the unit powers up whenever power is present. 1 = the unit powers up only when commanded by the CTRL pin and the OPERATION command (as programmed in Register 0x02, Bits[3:0]). Controls how the device responds to the OPERATION command. 0 = ignores the OPERATION command. 1 = requires that the OPERATION command be set to the on state to enable the unit (in addition to the setting of Bit 2). Controls how the device responds to the value on the CTRL pin. 0 = ignores the CTRL pin. 1 = requires the CTRL pin to be asserted to enable the unit (in addition to the setting of Bit 3). Sets the polarity for the CTRL pin. 0 = active low. 1 = active high. Action to take at power-down. 0 = uses the TOFF_DELAY value (TOFF_FALL is not supported by the ADP1050) to stop the transfer of energy to the output. 1 = turns off the output and stops energy transfer to the output as fast as possible. Rev. A | Page 51 of 92 ADP1050 Data Sheet CLEAR_FAULTS The CLEAR_FAULTS command is a send byte, no data. This command clears all PMBus fault bits in all PMBus status registers simultaneously. Table 15. Register 0x03—CLEAR_FAULTS Bits N/A Bit Name/Function CLEAR_FAULTS Type Send Description Clears all bits in PMBus status registers (Register 0x78 to Register 0x7E) simultaneously. WRITE_PROTECT The WRITE_PROTECT command is used to control writing to the PMBus device. This command provides protection against accidental changes. This command is not intended to provide protection against deliberate or malicious changes to the configuration or operation of the device. Table 16. Register 0x10—WRITE_PROTECT Bits 7 6 5 Bit Name/Function Write Protect 1 Write Protect 2 Write Protect 3 R/W R/W R/W R/W [4:0] Reserved R Description Disables writes to all commands except the WRITE_PROTECT command. Disables writes to all commands except the WRITE_PROTECT and OPERATION commands. Disables writes to all commands except the WRITE_PROTECT, OPERATION, ON_OFF_CONFIG, and VOUT_COMMAND commands. Reserved. RESTORE_DEFAULT_ALL The RESTORE_DEFAULT_ALL command is a send byte, no data. This command downloads the factory default settings (including the basic PMBus commands, the manufacturer specific extended commands (starting with 0xFE), and other data such as the checksum, the EEPROM password, and the chip password) from the EEPROM (Page 0 of the main block) into the registers. Table 17. Register 0x12—RESTORE_DEFAULT_ALL Bits N/A Bit Name/Function RESTORE_DEFAULT_ALL Type Send Description Restores the factory default settings from the EEPROM to the registers. STORE_USER_ALL The STORE_USER_ALL command is a send byte, no data. This command copies the entire contents of the registers into the EEPROM (Page 1 of the main block) as the user settings. The settings are automatically restored on power-up of VDD. Table 18. Register 0x15—STORE_USER_ALL Bits N/A Bit Name/Function STORE_USER_ALL Type Send Description Saves the user settings from the registers to the EEPROM. RESTORE_USER_ALL The RESTORE_USER_ALL command is a send byte, no data. This command downloads the stored user settings including the basic PMBus commands, the manufacturer specific extended commands (starting with 0xFE), and other data (for example, the checksum, the EEPROM password, and the chip password) from the EEPROM (Page 1 of the main block) into the registers. Table 19. Register 0x16—RESTORE_USER_ALL Bits N/A Bit Name/Function RESTORE_USER_ALL Type Send Description Restores the user settings from the EEPROM to the registers. Rev. A | Page 52 of 92 Data Sheet ADP1050 CAPABILITY This command summarizes the PMBus optional communication protocols supported by the ADP1050. The reading of this command should result in 0x20. Table 20. Register 0x19—CAPABILITY Bits [7] Bit Name/Function Packet error R/W R [6:5] Maximum bus speed R 4 SMBALERT R [3:0] Reserved R Description Checks the packet error capability of the device. 0 = not supported. Checks the PMBus speed capability of the device. 01 = maximum bus speed of 400 kHz. Checks support of the SMBALERT pin and the SMBus alert response protocol. 0 = not supported. Reserved. VOUT_MODE The VOUT_MODE command sets the data format for output voltage related data. The data byte for the VOUT_MODE command consists of a 3-bit mode and 5-bit exponent parameter. The 3-bit mode determines whether the device uses linear format or direct format for the output voltage related commands. The 5-bit parameter sets the exponent value for linear format. Table 21. Register 0x20—VOUT_MODE Bits [7:5] Bit Name/Function Mode R/W R [4:0] Exponent R Description Output voltage data format. The value is fixed at 000, meaning that only linear format is supported. The N value for the output voltage related commands in linear format: V = Y × 2N. The value is fixed at 10110 (twos complement, −10 decimal). The exponent for linear format values is −10. VOUT_COMMAND The VOUT_COMMAND command sets the output voltage. The VOUT_TRANSITION_RATE command is used if this command is modified while the output is active and in a steady state condition. The maximum programmable output voltage is 64 V. Table 22. Register 0x21—VOUT_COMMAND Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage reference value, in volts. 16-bit unsigned integer Y value for linear format: V = Y × 2N. N is defined in the VOUT_MODE command. VOUT_TRIM The VOUT_TRIM command applies a fixed offset voltage to the output voltage command value. It is typically set by the user to trim the output voltage at the time that the PMBus device is assembled into the system of the user. The trim range is −32 V to +32 V, and each LSB resolution is 2−10 = 0.9765625 mV. Table 23. Register 0x22—VOUT_TRIM Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage trim value. 16-bit twos complement Y value for linear format: V = Y × 2N. N is defined in the VOUT_MODE command. Rev. A | Page 53 of 92 ADP1050 Data Sheet VOUT_CAL_OFFSET The VOUT_CAL_OFFSET command is used to apply a fixed offset voltage to the output voltage command value. It is typically used by the PMBus device manufacturer to calibrate the device in the factory. The trim range is −32 V to +32 V and each LSB size is 2−10 = 0.9765625 mV. Table 24. Register 0x23—VOUT_CAL_OFFSET Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage trim value. 16-bit twos complement Y value for linear format: V = Y × 2N. N is defined in the VOUT_MODE command. VOUT_MAX The VOUT_MAX command sets an upper limit on the output voltage the unit can attain, regardless of any other commands or combinations. If an attempt is made to program the output voltage higher than the limit set by this command, the device responds as follows: • • • • The commanded output voltage is set to the VOUT_MAX value. The NONE OF THE ABOVE bit is set in the STATUS_BYTE command (Register 0x78[0]). The VOUT bit is set in the STATUS_WORD command (Register 0x79[15]). The VOUT_MAX warning bit is set in the STATUS_VOUT command (Register 0x7A[3]). Table 25. Register 0x24—VOUT_MAX Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage upper limit. 16-bit unsigned integer Y value for linear format: V = Y × 2N. N is defined in the VOUT_MODE command. VOUT_MARGIN_HIGH The VOUT_MARGIN_HIGH command sets the target voltage to which the output changes when the OPERATION command is set to margin high. The VOUT_TRANSITION_RATE command is used if this command is modified while the output is active and in a steady state condition. Table 26. Register 0x25—VOUT_MARGIN_HIGH Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the margin high value for the output voltage, in volts. 16-bit unsigned integer Y value for linear format: V = Y × 2N. N is defined by the VOUT_MODE command. Rev. A | Page 54 of 92 Data Sheet ADP1050 VOUT_MARGIN_LOW The VOUT_MARGIN_LOW command sets the target voltage, to which the output changes when the OPERATION command is set to margin low. The VOUT_TRANSITION_RATE command is used if this command is modified while the output is active and in a steadystate condition. Table 27. Register 0x26—VOUT_MARGIN_LOW Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the margin low value for the output voltage, in volts. 16-bit unsigned integer Y value for linear format: V = Y × 2N. N is defined by the VOUT_MODE command. OPERATION COMMAND VOUT_MAX VOUT_MARGIN_HIGH 3:1 MUX VOUT_COMMAND LIMITER VOUT_ SCALE_ LOOP REFERENCE VOLTAGE EQUIVALENT VOUT_MARGIN_LOW VOUT_TRIM 12039-061 VOUT_CAL_OFFSET Figure 53. Conceptual View of the Output Voltage Related Commands VOUT_TRANSITION_RATE When the ADP1050 receives either a VOUT_COMMAND command or an OPERATION command (margin high, margin low) that causes the output voltage to change, this command sets the rate, in mV/µs, at which the VS± pins change voltage. This commanded rate of change does not apply when the unit is turned on or off. The maximum positive value (0x7BFF) of the two data bytes indicates that the unit makes the transition as quickly as possible. Only the limited options in Table 28 are supported by the ADP1050. Table 28. Register 0x27—VOUT_TRANSITION_RATE (Rate-of-Change Options Supported by the ADP1050) Register Setting 1001100000001101 (0x980D) 1010000000001101 (0xA00D) 1010100000001101 (0xA80D) 1011000000001101 (0xB00D) 1011100000001101 (0xB80D) 1100000000001101 (0xC00D) 1100100000001101 (0xC80D) 1101000000001101 (0xD00D) 0111101111111111 (0x7BFF) Rate of Change (mV/μs) 0.0015625 0.003125 0.00625 0.0125 0.025 0.050 0.1 0.2 Infinite (default) Table 29. Register 0x27—VOUT_TRANSITION_RATE Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R/W R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. Rev. A | Page 55 of 92 ADP1050 Data Sheet VOUT_SCALE_LOOP The VOUT_SCALE_LOOP command is equal to the feedback resistor ratio. The nominal output voltage is set by a resistor divider and the internal 1 V reference voltage. For example, if the nominal output voltage is 12 V, the VOUT_SCALE_LOOP value = 1 V/12 V = 0.08333 and the VOUT_SCALE_LOOP can be set as 0xA155. Table 30. Register 0x29—VOUT_SCALE_LOOP Bits [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear format: KR = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear format: KR = Y × 2N. RESISTOR DIVIDER RATIO VOUT PMBus DEVICE KR VOUT_ SCALE_ LOOP ERROR PROCESSING/ CONTROL LOOP 16 K 12039-062 VOUT_COMMAND Figure 54. Conceptual View of the VOUT_SCALE_LOOP Command VOUT_SCALE_MONITOR This command is typically the same as the VOUT_SCALE_LOOP command. It is used for reading the output voltage with the READ_VOUT command (Register 0x8B). Table 31. Register 0x2A—VOUT_SCALE_MONITOR Bits [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear format: KR = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear format: KR = Y × 2N. Rev. A | Page 56 of 92 Data Sheet ADP1050 FREQUENCY_SWITCH The FREQUENCY_SWITCH command, which sets the switching frequency in kHz, is in linear format. Only the limited switching frequency options in Table 32 are supported by the ADP1050. In the ADP1050, because the switching frequency is calculated from the switching period, the switching period value that is used is an accurate measure, whereas the switching frequency may not be. For example, for the first switching frequency option of 49 kHz (see Table 32), the actual switching frequency is calculated by 1/(20.48 µs) = 48.828125 kHz, which is simplified (rounded) to 49 kHz. To avoid an incorrect switching frequency setting, the go commands in Register 0xFE61[2:1] must be used to latch this setting and the PWM setting. Table 32. Register 0x33—FREQUENCY_SWITCH (Options Supported by the ADP1050) Register Setting 0000000000110001 (0x0031) 0000000000111000 (0x0038) 0000000000111100 (0x003C) 0000000001000001 (0x0041) 0000000001000111 (0x0047) 0000000001001110 (0x004E) 0000000001010111 (0x0057) 1111100011000011 (0xF8C3) 0000000001101000 (0x0068) 1111100011011111 (0xF8DF) 0000000001111000 (0x0078) 0000000010000010 (0x0082) 0000000010001000 (0x0088) 0000000010001110 (0x008E) 0000000010010101 (0x0095) 1111100100111001 (0xF939) 1111100101001001 (0xF949) 1111100101011011 (0xF95B) 0000000010111000 (0x00B8) 1111100110000111 (0xF987) 1111100110010011 (0xF993) 1111100110100001 (0xF9A1) 1111100110101111 (0xF9AF) 0000000011011111 (0xDF) 1111100111001111 (0xF9CF) 1111100111100001 (0xF9E1) 0000000011111010 (0x00FA) 1111101000001001 (0xFA09) 1111101000011111 (0xFA1F) 0000000100011100 (0x011C) 1111101001010011 (0xFA53) 1111101001110001 (0xFA71) 1111101010000001 (0xFA81) 0000000101001001 (0x0149) 0000000101010010 (0x0152) 0000000101011011 (0x15B) 0000000101100101 (0x0165) 1111101011011111 (0xFADF) 0000000101111011 (0x017B) 1111101100001101 (0xFB0D) 0000000110001101 (0x018D) 0000000110010011 (0x0193) 0000000110011010 (0x019A) Switching Frequency (kHz) 49 56 60 65 71 78 87 97.5 104 111.5 120 130 136 142 149 156.5 164.5 173.5 184 195.5 201.5 208.5 215.5 223 231.5 240.5 250 260.5 271.5 284 297.5 312.5 320.5 329 338 347 357 367.5 379 390.5 397 403 410 Rev. A | Page 57 of 92 Accurate Switching Period (µs) 20.48 17.92 16.64 15.36 14.08 12.80 11.52 10.24 9.60 8.96 8.32 7.68 7.36 7.04 6.72 6.40 6.08 5.76 5.44 5.12 4.96 4.80 4.64 4.48 4.32 4.16 4.00 3.84 3.68 3.52 3.36 3.20 3.12 3.04 2.96 2.88 2.80 2.72 2.64 2.56 2.52 2.48 2.44 ADP1050 Data Sheet Register Setting 1111101101000001 (0xFB41) 1111101101001111 (0xFB4F) 0000000110101111 (0x1AF) 1111101101101101 (0xFB6D) 1111101101111101 (0xFB7D) 1111101110001101 (0xFB8D) 0000000111001111 (0x01CF) 0000000111011000 (0x01D8) 0000000111100001 (0x01E1) 0000000111101010 (0x1EA) 0000000111110100 (0x1F4) 0000000111111110 (0x01FE) 0000001000001000 (0x0208) 0000001000010011 (0x0213) 0000001000011111 (0x0x21F) 0000001000101100 (0x022C) 0000001000111000 (0x0238) 0000001001000101 (0x0245) 0000001001010011 (0x0253) 0000001001100010 (0x0262) 0000001001110001 (0x0271) Switching Frequency (kHz) 416.5 423.5 431 438.5 446.5 454.5 463 472 481 490 500 510 520 531 543 556 568 581 595 610 625 Accurate Switching Period (µs) 2.40 2.36 2.32 2.28 2.24 2.20 2.16 2.12 2.08 2.04 2.00 1.96 1.92 1.88 1.84 1.80 1.76 1.72 1.68 1.64 1.60 Table 33. Register 0x33—FREQUENCY_SWITCH Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R/W R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. VIN_ON The VIN_ON command sets the value of the input voltage (in volts) at which the unit starts power conversion. Table 34. Register 0x35—VIN_ON Bit [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear format: X = Y × 2N. VIN_OFF The VIN_OFF command sets the value of the input voltage (in volts) at which the unit stops power conversion after operation has started. Table 35. Register 0x36—VIN_OFF Bit [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear format: X = Y × 2N. Rev. A | Page 58 of 92 Data Sheet ADP1050 VOUT_OV_FAULT_LIMIT The VOUT_OV_FAULT_LIMIT command sets the threshold value for overvoltage protection of the output voltage. Table 36. Register 0x40—VOUT_OV_FAULT_LIMIT Bits [15:0] Bit Name/Function Mantissa R/W R/W Description 16-bit unsigned integer Y value for linear mode format: X = Y × 2N. N is defined by the VOUT_MODE command. Note that the available OV protection limit value must be in the range of 75% to 150% of the nominal output voltage. VOUT_OV_FAULT_RESPONSE The VOUT_OV_FAULT_RESPONSE command determines the fault response for the VOUT_OV_FAULT flag. Table 37. Register 0x41—VOUT_OV_FAULT_RESPONSE Bits [7:6] Bit Name/Function Response R/W R/W [5:3] Retry setting R/W [2:0] Delay time R/W Description 00 = continues operation without interruption. 01 = continues operation for the debounce time (Delay Time 1) specified by Register 0xFE26[7:6]. If the fault persists, retry the number of times specified by the retry setting of this command (Bits[5:3]). 10 = shuts down and responds according to the retry setting in Bits[5:3]. 11 = the output is disabled while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. 000 = restart not attempted. The output remains disabled until the fault is cleared. 001 to 110 = attempts to restart the number of times set by these bits. If the ADP1050 fails to restart in the allowed number of retries, the output is disabled and remains off until the fault is cleared. The time between the start of each attempt to restart is set by the Delay Time 2 value in Bits[2:0], along with the delay time unit specified for that particular fault. 111 = attempts to restart continuously, without limitation, until it is commanded off (by the CTRL pin or the OPERATION command, or both), VDD is removed, or another fault condition causes the unit to shut down. These bits set the delay time between the start of each attempt to restart. Bit 2 Bit 1 Bit 0 Delay Time 2 (ms) 0 0 0 252 0 0 1 588 0 1 0 924 0 1 1 1260 1 0 0 1596 1 0 1 1932 1 1 0 2268 1 1 1 2604 VOUT_UV_FAULT_LIMIT The VOUT_UV_FAULT_LIMIT command sets the threshold value for undervoltage protection of the output voltage. Table 38. Register 0x44—VOUT_UV_FAULT_LIMIT Bits [15:0] Bit Name/Function Mantissa R/W R/W Bit Name/Function 16-bit unsigned integer Y value for linear format: X = Y × 2N. N is defined by the VOUT_MODE command. Rev. A | Page 59 of 92 ADP1050 Data Sheet VOUT_UV_FAULT_RESPONSE The VOUT_UV_FAULT_RESPONSE command determines the fault response for the VOUT_UV_FAULT flag. Table 39. Register 0x45—VOUT_UV_FAULT_RESPONSE Bits [7:6] Bit Name/Function Response R/W R/W [5:3] Retry setting R/W [2:0] Delay time R/W Description 00 = continues operation without interruption. 01 = continues operation for the Delay Time 1 (Bits[2:0]). If the fault persists, retry the number of times specified by the retry setting (Bits[5:3]). 10 = shuts down (disables the output) and responds according to the retry setting in Bits[5:3]. 11 = the output is disabled while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. 000 = restart not attempted. The output remains disabled until the fault is cleared. 001 to 110 = attempts to restart the number of times set by these bits. If the unit fails to restart in the allowed number of retries, it disables the output and remains off until the fault is cleared. The time between the start of each attempt to restart is set by the Delay Time 2 value in Bits[2:0], together with the delay time unit specified for that particular fault. 111 = attempts to restart continuously, without limitation, until it is commanded off (by the CTRL pin or the OPERATION command, or both), VDD is removed, or another fault condition causes the unit to shut down. These bits set the delay time for the VOUT_UV_FAULT_RESPONSE Delay Time 1 and Delay Time 2 as described in Bits[7:6] and Bits[5:3]. Bit 2 Bit 1 Bit 0 Delay Time 1 (ms) Delay Time 2 (ms) 0 0 0 0 252 0 0 1 20 588 0 1 0 40 924 0 1 1 80 1260 1 0 0 160 1596 1 0 1 320 1932 1 1 0 640 2268 1 1 1 1280 2604 OT_FAULT_LIMIT The OT_FAULT_LIMIT command sets the threshold value in degrees Celsius (°C) for overtemperature protection. The range is 0°C to 156°C. If the setting value is out of range, the limit is 156 and the return value is 156. Table 40. Register 0x4F—OT_FAULT_LIMIT Bits [15:11] [10:8] [7:0] Bit Name/Function Exponent Mantissa high bits Mantissa low bits R/W R R R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. N is fixed at 0. Mantissa high bits Y[10:8] value fixed at 0. Mantissa low bits Y[7:0] value for linear format: X = Y × 2N. Rev. A | Page 60 of 92 Data Sheet ADP1050 OT_FAULT_RESPONSE The OT_FAULT_RESPONSE command determines the fault response for the OT_FAULT flag. Table 41. Register 0x50—OT_FAULT_RESPONSE Bits [7:6] Bit Name/Function Response R/W R/W [5:3] Retry setting R/W [2:0] Delay time R/W Description 00 = continues operation without interruption. 01 = continues operation for the Delay Time 1 specified by Bits[2:0] and the delay time unit specified for that particular fault. If the fault condition is still present at the end of the delay time, the unit responds as programmed in the retry setting (Bits[5:3]). 10 = shuts down (disables the output) and responds according to the retry setting in Bits[5:3]. 11 = the output is disabled while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. 000 = restart not attempted. The output remains disabled until the fault is cleared. 001 to 110 = attempts to restart the number of times set by these bits. If the device fails to restart in the allowed number of retries, it disables the output and remains off until the fault is cleared. The time between the start of each attempt to restart is set by the Delay Time 2 value in Bits[2:0], together with the delay time unit specified for that particular fault. 111 = attempts to restart continuously, without limitation, until commanded off (by the CTRL pin or the OPERATION command, or both), VDD is removed, or another fault condition causes the unit to shut down. These bits set the delay time. Bit 2 Bit 1 Bit 0 Delay Time 1 (sec) Delay Time 2 (ms) 0 0 0 1 252 0 0 1 1 588 0 1 0 1 924 0 1 1 1 1260 1 0 0 1 1596 1 0 1 1 1932 1 1 0 1 2268 1 1 1 1 2604 POWER_GOOD_ON The POWER_GOOD_ON command sets the output voltage (in volts) at which the POWER_GOOD signal is asserted. The POWER_GOOD status bit (POWER_GOOD) in the STATUS_WORD command is always reflective of VOUT with regard to the POWER_GOOD_ON and POWER_GOOD_OFF limits. Table 42. Register 0x5E—POWER_GOOD_ON Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage for the POWER_GOOD_ON command. 16-bit unsigned integer Y value for linear format X = Y × 2N. N is defined by the VOUT_MODE command. POWER_GOOD_OFF The POWER_GOOD_OFF command sets the output voltage (in volts) at which the POWER_GOOD signal is negated. The POWER_GOOD status bit (POWER_GOOD) in the STATUS_WORD command is always reflective of VOUT with regard to the POWER_GOOD_ON and POWER_GOOD_OFF limits. Table 43. Register 0x5F—POWER_GOOD_OFF Bits [15:0] Bit Name/Function Mantissa R/W R/W Description Sets the output voltage for the POWER_GOOD_OFF command. 16-bit unsigned integer Y value for linear format X = Y × 2N. N is defined by the VOUT_MODE command. Rev. A | Page 61 of 92 ADP1050 Data Sheet TON_DELAY The TON_DELAY command sets the turn-on delay time in milliseconds (ms). Only the options in Table 44 are supported in the ADP1050. Table 44. Register 0x60—TON_DELAY (Turn-On Delay Options Supported in the ADP1050) Register Setting 0000000000000000 (0x0000) 0000000000001010 (0x000A) 0000000000011001 (0x0019) 0000000000110010 (0x0032) 0000000001001011 (0x004B) 0000000001100100 (0x0064) 0000000011111010 (0x00FA) 0000001111101000 (0x03E8) Turn-On Delay Time (ms) 0 10 25 50 75 100 250 1000 Table 45. Register 0x60—TON_DELAY Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R/W R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. TON_RISE The TON_RISE command sets the turn-on rise time in milliseconds (ms). Only the values in Table 46 are supported in the ADP1050. Table 46. Register 0x61—TON_RISE (Turn-On Rise Time Options Supported in the ADP1050) Register Setting 1100000000001101 (0xC00D) 1101000000001101 (0xD00D) 1111000000000111 (0xF007) 1111100000010101 (0xF815) 0000000000010101 (0x0015) 1111000010100001 (0xF0A1) 0000000000111100 (0x003C) 0000000001100100 (0x0064) Turn-On Rise Time (ms) 0.05 0.2 1.75 10.5 21 40.25 60 100 Table 47. Register 0x61—TON_RISE Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R/W R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. TOFF_DELAY The TOFF_DELAY command sets the turn-off delay time in milliseconds (ms). Only the values listed in Table 48 are supported in the ADP1050. Table 48. Register 0x64—TOFF_DELAY (Turn-Off Delay Options Supported in the ADP1050) Register Setting 0000000000000000 (0x0000) 0000000000110010 (0x0032) 0000000011111010 (0x00FA) 0000001111101000 (0x03E8) Turn-Off Delay Time (ms) 0 50 250 1000 Table 49. Register 0x64—TOFF_DELAY Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R/W R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. Rev. A | Page 62 of 92 Data Sheet ADP1050 STATUS_BYTE Table 50. Register 0x78—STATUS_BYTE Bits 7 6 Bit Name/Function Reserved POWER_OFF R/W R R 5 4 3 2 1 0 VOUT_OV_FAULT Reserved VIN_UV_FAULT TEMPERATURE CML NONE OF THE ABOVE R R R R R R Description Reserved. This bit is asserted if the device is not providing power to the output, regardless of the reason, including simply not being enabled. An output overvoltage fault has occurred. Reserved. An input undervoltage fault has occurred. A temperature fault or warning has occurred. A communications, memory, or logic fault has occurred. A fault or warning not listed in Bits[7:1] has occurred. STATUS_WORD Table 51. Register 0x79—STATUS_WORD Bits 15 14 13 12 11 Bit Name/Function VOUT Reserved INPUT Reserved POWER_GOOD R/W R R R R R [10:7] 6 Reserved POWER_OFF R R 5 4 3 2 1 0 VOUT_OV_FAULT Reserved VIN_UV_FAULT TEMPERATURE CML NONE OF THE ABOVE R R R R R R Description Any bit asserted in STATUS_VOUT asserts this bit. Reserved. Any bit asserted in STATUS_INPUT asserts this bit. Reserved. POWER_GOOD is a negation of POWER_GOOD, which means that the output power is not good. This bit is set when the sensed VOUT is less than the limit programmed in the POWER_GOOD_OFF command. This bit is cleared when the sensed VOUT voltage is greater than the limit that is programmed in the POWER_GOOD_ON command. This flag also triggers the PGOOD flag in Register 0xFEA0[6]. Reserved. This bit is asserted if the device is not providing power to the output, regardless of the reason, including not being enabled. An output overvoltage fault has occurred. Reserved. An input undervoltage fault has occurred. An overtemperature fault or warning has occurred. A communications, memory, or logic fault has occurred. A fault or warning not listed in Bits[7:1] has occurred. STATUS_VOUT Table 52. Register 0x7A—STATUS_VOUT Bits 7 [6:5] 4 3 [2:0] Bit Name/Function VOUT_OV_FAULT Reserved VOUT_UV_FAULT VOUT_MAX warning Reserved R/W R R R R Description An output overvoltage fault has occurred. Reserved. An output undervoltage fault has occurred. An attempt was made to set the output voltage to a value greater than allowed by the VOUT_MAX command. Reserved. STATUS_INPUT Table 53. Register 0x7C—STATUS_INPUT Bits [7:5] 4 3 2 [1:0] Bit Name/Function Reserved VIN_UV_FAULT VIN_LOW IIN_OC_FAST_FAULT Reserved R/W R R R R R Description Reserved. An input undervoltage fault has occurred. The unit is off due to insufficient input voltage. An input overcurrent fast fault has occurred. Reserved. Rev. A | Page 63 of 92 ADP1050 Data Sheet STATUS_TEMPERATURE Table 54. Register 0x7D—STATUS_TEMPERATURE Bits 7 6 [5:0] Bit Name/Function OT_FAULT OT_WARNING Reserved R/W R R R Description An overtemperature fault has occurred. An overtemperature warning has occurred. Reserved. STATUS_CML Table 55. Register 0x7E—STATUS_CML Bits 7 6 [5:2] 1 0 Bit Name/Function CMD_ERR DATA_ERR Reserved COMM_ERR Reserved R/W R R R R R Description An invalid or unsupported command is received. Invalid or unsupported data is received. Reserved. Other communication fault is detected. Reserved. READ_VIN The READ_VIN command returns the input voltage value (in V) in linear format. Table 56. Register 0x88—READ_VIN Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R R Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. READ_IIN The READ_IIN command returns the input current value (in A) in linear format. Table 57. Register 0x89—READ_IIN Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R R Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. READ_VOUT The READ_VOUT command returns the output voltage value (in V) in linear format. Table 58. Register 0x8B—READ_VOUT Bits [15:0] Bit Name/Function Mantissa R/W R Description 16-bit unsigned integer Y value for linear format: X = Y × 2N. N is defined in the VOUT_MODE command. READ_TEMPERATURE The READ_TEMPERATURE command returns the temperature value (in °C) in linear format. Table 59. Register 0x8D—READ_TEMPERATURE Bits [15:11] Bit Name/Function Exponent R/W R [10:0] Mantissa R Description 5-bit N value for linear format: X = Y × 2N. 5-bit twos complement fixed at 00000. 11-bit twos complement Y value for linear format: X = Y × 2N. Rev. A | Page 64 of 92 Data Sheet ADP1050 READ_DUTY_CYCLE The READ_DUTY_CYCLE command returns the duty cycle of the PWM output value in linear format. Table 60. Register 0x94—READ_DUTY_CYCLE Bits [15:11] Bit Name/Function Exponent R/W R [10:0] Mantissa R Description 5-bit N value for linear format: X = Y × 2N. 5-bit twos complement fixed at 10110 (−10 decimal). 11-bit twos complement Y value for linear format: X = Y × 2N. READ_FREQUENCY The READ_FREQUENCY command returns the switching frequency value in linear format. Table 61. Register 0x95—READ_FREQUENCY Bits [15:11] [10:0] Bit Name/Function Exponent Mantissa R/W R R Description 5-bit twos complement N value for linear format: X = Y × 2N. 11-bit twos complement Y value for linear format: X = Y × 2N. READ_PMBUS_REVISION The READ_PMBUS_REVISION command returns the PMBus version information. The ADP1050 supports PMBus Revision 1.2. Reading of this command results in a value of 0x22. Table 62. Register 0x98—READ_PMBUS_REVISION Bits [7:4] [3:0] Bit Name/Function Part1 revision Part2 revision R/W R R Description Compliant to PMBus specifications, part 1: 0010 = Revision 1.2. Compliant to PMBus specifications, part 2: 0010 = Revision 1.2. MFR_ID Table 63. Register 0x99—MFR_ID Bits [7:0] Bit Name/Function MFR_ID R/W R/W Description Reads/writes the ID information of the manufacturer, which can be saved in the EEPROM. MFR_MODEL Table 64. Register 0x9A—MFR_MODEL Bit [7:0] Bit Name/Function MFR_MODEL R/W R/W Description Reads/writes the model information of the manufacturer, which can be saved in the EEPROM. MFR_REVISION Table 65. Register 0x9B—MFR_REVISION Bit [7:0] Bit Name/Function MFR_REVISION R/W R/W Description Reads/writes the revision information of the manufacturer, which can be saved in the EEPROM. IC_DEVICE_ID Table 66. Register 0xAD—IC_DEVICE_ID Bit [15:0] Bit Name/Function IC_DEVICE_ID R/W R Description Reads the IC device ID (default value = 0x4151). IC_DEVICE_REV Table 67. Register 0xAE—IC_DEVICE_REV Bits [7:0] Bit Name/Function IC_DEVICE_REV R/W R Description Reads the IC revision information. The value is 0x20 in the current silicon. Rev. A | Page 65 of 92 ADP1050 Data Sheet EEPROM_DATA_00 Table 68. Register 0xB0—EEPROM_DATA_00 Bits [7:0] Bit Name/Function EEPROM_DATA_00 R/W R block Description Block read data from Page 0 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_01 Table 69. Register 0xB1—EEPROM_DATA_01 Bits [7:0] Bit Name/Function EEPROM_DATA_01 R/W R block Description Block read data from Page 1 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_02 Table 70. Register 0xB2—EEPROM_DATA_02 Bits [7:0] Bit Name/Function EEPROM_DATA_02 R/W R/W block Description Block read/write data of Page 2 of the EEPROM main block. The EEPROM must first be unlocked. This page is not recommended for other use. EEPROM_DATA_03 Table 71. Register 0xB3—EEPROM_DATA_03 Bits [7:0] Bit Name/Function EEPROM_DATA_03 R/W R/W block Description Block read/write data of Page 3 of the EEPROM main block. The EEPROM must first be unlocked. This page is reserved for storing power board parameter data for GUI use. EEPROM_DATA_04 Table 72. Register 0xB4—EEPROM_DATA_04 Bits [7:0] Bit Name/Function EEPROM_DATA_04 R/W R/W block Description Block read/write data of Page 4 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_05 Table 73. Register 0xB5—EEPROM_DATA_05 Bits [7:0] Bit Name/Function EEPROM_DATA_05 R/W R/W block Description Block read/write data of Page 5 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_06 Table 74. Register 0xB6—EEPROM_DATA_06 Bits [7:0] Bit Name/Function EEPROM_DATA_06 R/W R/W block Description Block read/write data of Page 6 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_07 Table 75. Register 0xB7—EEPROM_DATA_07 Bits [7:0] Bit Name/Function EEPROM_DATA_07 R/W R/W block Description Block read/write data of Page 7 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_08 Table 76. Register 0xB8—EEPROM_DATA_08 Bits [7:0] Bit Name/Function EEPROM_DATA_08 R/W R/W block Description Block read/write data of Page 8 of the EEPROM main block. The EEPROM must first be unlocked. Rev. A | Page 66 of 92 Data Sheet ADP1050 EEPROM_DATA_09 Table 77. Register 0xB9—EEPROM_DATA_09 Bits [7:0] Bit Name/Function EEPROM_DATA_09 R/W R/W block Description Block read/write data of Page 9 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_10 Table 78. Register 0xBA—EEPROM_DATA_10 Bits [7:0] Bit Name/Function EEPROM_DATA_10 R/W R/W block Description Block read/write data of Page 10 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_11 Table 79. Register 0xBB—EEPROM_DATA_11 Bits [7:0] Bit Name/Function EEPROM_DATA_11 R/W R/W block Description Block read/write data of Page 11 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_12 Table 80. Register 0xBC—EEPROM_DATA_12 Bits [7:0] Bit Name/Function EEPROM_DATA_12 R/W R/W block Description Block read/write data of Page 12 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_13 Table 81. Register 0xBD—EEPROM_DATA_13 Bits [7:0] Bit Name/Function EEPROM_DATA_13 R/W R/W block Description Block read/write data of Page 13 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_14 Table 82. Register 0xBE—EEPROM_DATA_14 Bits [7:0] Bit Name/Function EEPROM_DATA_14 R/W R/W block Description Block read/write data of Page 14 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_DATA_15 Table 83. Register 0xBF—EEPROM_DATA_15 Bits [7:0] Bit Name/Function EEPROM_DATA_15 R/W R/W block Description Block read/write data of Page 15 of the EEPROM main block. The EEPROM must first be unlocked. EEPROM_CRC_CHKSUM Table 84. Register 0xD1—EEPROM_CRC_CHKSUM Bits [7:0] Bit Name/Function CRC checksum R/W R Description Returns the CRC checksum value from the EEPROM download operation EEPROM_NUM_RD_BYTES Table 85. Register 0xD2—EEPROM_NUM_RD_BYTES Bits [7:0] Bit Name/Function Number of read bytes returned R/W R/W Description These bits set the number of read bytes that are returned when the EEPROM_DATA_xx commands are used. Rev. A | Page 67 of 92 ADP1050 Data Sheet EEPROM_ADDR_OFFSET Table 86. Register 0xD3—EEPROM_ADDR_OFFSET Bits [15:0] Bit Name/Function Address offset R/W R/W Description These bits set the address offset of the current EEPROM page. EEPROM_PAGE_ERASE Table 87. Register 0xD4—EEPROM_PAGE_ERASE Bits [7:0] Bit Name/Function EEPROM page erase R/W W Description Perform a page erase on the selected EEPROM page (Page 3 to Page 15). Wait at least 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 is reserved for internal use; do not erase the contents of Page 2. Page 3 is reserved for storing the board parameters for GUI use; erase Page 3 before storing the board parameters. The following list shows the register setting used to access each page: 0x03 = Page 3. 0x04 = Page 4. 0x05 = Page 5. 0x06 = Page 6. 0x07 = Page 7. 0x08 = Page 8. 0x09 = Page 9. 0x0A = Page 10. 0x0B = Page 11. 0x0C = Page 12. 0x0D = Page 13. 0x0E = Page 14. 0x0F = Page 15. EEPROM_PASSWORD Table 88. Register 0xD5—EEPROM_PASSWORD Bits [7:0] Bit Name/Function EEPROM password R/W W Description Writes the password using this command to unlock the EEPROM for read/write access. Writes the EEPROM password two consecutive times to unlock the EEPROM. Writes any other value to exit. The factory default password is 0xFF. TRIM_PASSWORD Table 89. Register 0xD6—TRIM_PASSWORD Bits [7:0] Bit Name/Function Trim password R/W W Description Writes the password using this command to unlock the trim registers for write access. Writes the trim password two consecutive times to unlock the registers. Writes any other value to exit. The trim password is the same as the EEPROM password. The factory default password is 0xFF. CHIP_PASSWORD Table 90. Register 0xD7—CHIP_PASSWORD Bits [15:0] Bit Name/Function Chip password R/W W Description Writes the correct chip password two consecutive times to unlock the chip registers for read/write access. Writes any other value to exit. The factory default password is 0xFFFF. This register cannot be read. Any read action on this register returns 0. Rev. A | Page 68 of 92 Data Sheet ADP1050 VIN_SCALE_MONITOR The VIN_SCALE_MONITOR command is the scale factor between the VIN ADC value and the real input voltage. It is typically used with the READ_VIN command. The value must be in the range of 0 to 1 decimal. Table 91. Register 0xD8—VIN_SCALE_MONITOR Bits [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear format: X = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear format: X = Y × 2N. IIN_SCALE_MONITOR The IIN_SCALE_MONITOR command is the scale factor between the IIN ADC value and the real input current. It is typically used with the READ_IIN command. The value must be in the range of 0 to 1 decimal. Table 92. Register 0xD9—IIN_SCALE_MONITOR Bits [15:11] Bit Name/Function Exponent R/W R/W [10:0] Mantissa R/W Description 5-bit twos complement N value for linear mode format: X = Y × 2N. N must be in the range of −12 to 0 decimal. 11-bit twos complement Y value for linear mode format: X = Y × 2N. EEPROM_INFO Register 0xF1 is a read block. The EEPROM_INFO command reads the first flag data from the EEPROM. Table 93. Register 0xF1—EEPROM_INFO Bits [7:0] Bit Name/Function EEPROM_INFO R/W R block Description Block read data of the EEPROM information block. MFR_SPECIFIC_1 Table 94. Register 0xFA—MFR_SPECIFIC_1 Bits [7:0] Bit Name/Function Customized register R/W R/W Description These bits are available to the user to store customized information. MFR_SPECIFIC_2 Table 95. Register 0xFB—MFR_SPECIFIC_2 Bits [7:0] Bit Name/Function Customized register R/W R/W Description These bits are available to the user to store customized information. Rev. A | Page 69 of 92 ADP1050 Data Sheet MANUFACTURER SPECIFIC EXTENDED COMMANDS DESCRIPTIONS FLAG CONFIGURATION REGISTERS Register 0xFE00 to Register 0xFE03 are used to set the fault flag response and the resolution after the flag is cleared. Register 0xFE05[5:4] sets the VDD_OV flag response. Register 0xFE05[7:6] sets the global flag reenable delay time. Table 96. Register 0xFE00 to Register 0xFE05—Flag Response Registers Register 0xFE00 Bits [7:4] [3:0] Flag Reserved IIN_OC_FAST_FAULT_RESPONSE 0xFE01 [7:4] [3:0] [7:4] [3:0] [7:4] [3:0] [5:4] [3:0] Extended VOUT_OV_FAULT_RESPONSE CS3_OC_FAULT_RESPONSE VIN_UV_FAULT_RESPONSE Reserved Reserved FLAGIN_RESPONSE VDD_OV_RESPONSE Reserved 0xFE02 0xFE03 0xFE05 Additional Settings Reserved Register 0xFE08, Register 0xFE0E, Register 0xFE1A, Register 0xFE1F, Register 0xFEA0, Register 0xFEA3 Register 0x40, Register 0x41, Register 0xFE26, Register 0xFE6B, Register 0xFE6C Register 0xFE6A, Register 0xFEA0, Register 0xFEA3 Register 0x35, Register 0x36, Register 0xFE29, Register 0xFEA1, Register 0xFEA4 Reserved Reserved Register 0xFE12, Register 0xFEA1, Register 0xFEA4 Register 0xFE05, Register 0xFEA0, Register 0xFEA3 Reserved Table 97. Register 0xFE00 to Register 0xFE02—Flag Response Register Bit Descriptions Bits [7:6] Bit Name/Function Fault response R/W R/W [5:4] Action after flag is cleared R/W [3:2] Fault response R/W [1:0] Action after flag is cleared R/W Description These bits specify the action when the flag is set. Bit 7 Bit 6 Flag Action 0 0 Continues operation without interruption. 0 1 Disables SR1 and SR2. 1 0 Disables all PWM outputs. 1 1 Reserved. These bits specify the action when the flag is cleared. Bit 5 Bit 4 Action After Flag Clearing 0 0 After the reenable delay time, the PWM outputs are reenabled with a soft start. 0 1 The PWM outputs are reenabled immediately without a soft start. 1 0 A PSON signal, through Register 0x01, Register 0x02, and/or the CTRL pin, is needed to reenable the PWM outputs. 1 1 Reserved. These bits specify the action when the flag is set. Bit 3 Bit 2 Flag Action 0 0 Continues operation without interruption. 0 1 Disables SR1 and SR2. 1 0 Disables all PWM outputs. 1 1 Reserved. These bits specify the action when the flag is cleared. Bit 1 Bit 0 Action After Flag Clearing 0 0 After the reenable delay time, the PWM outputs are reenabled with a soft start. 0 1 The PWM outputs are reenabled immediately without a soft start. 1 0 A PSON signal, through Register 0x01, Register 0x02, and/or the CTRL pin, is needed to reenable the PWM outputs. 1 1 Reserved. Rev. A | Page 70 of 92 Data Sheet ADP1050 Table 98. Register 0xFE03—Flag Response, FLAGIN_RESPONSE Bits [7:4] Bit Name/Function Reserved R/W R/W Description Reserved. [3:2] Fault response R/W [1:0] Action after the fault flag is cleared R/W These bits specify the action when the flag is set. Bit 3 Bit 2 Fault Response 0 0 Continues operation without interruption. 0 1 Disable SR1 and SR2. 1 0 Disable all PWM outputs. 1 1 Reserved. These bits specify the action when the flag is cleared. Bit 1 Bit 0 Action After Fault Flag Clears 0 0 After the flag reenable delay time, the PWM outputs are reenabled with a soft start. 0 1 The PWM outputs are reenabled immediately without a soft start. 1 0 A PSON signal, programmed in Register 0x01, Register 0x02, and/or the CTRL pin, is needed to reenable the PWM outputs. 1 1 Reserved. Table 99. Register 0xFE05—Flag Reenable Delay, VDD_OV_RESPONSE Bits [7:6] Bit Name/Function Flag reenable delay R/W R/W 5 VDD_OV flag ignore R/W 4 VDD_OV flag debounce R/W [3:0] Reserved R/W Description These bits specify the global delay from the time when a manufacturer specific flag is cleared to the soft start. Bit 7 Bit 6 Typical Delay Time 0 0 250 ms 0 1 500 ms 1 0 1 sec 1 1 2 sec This bit enables or disables the VDD_OV flag. 0 = VDD_OV flag is set when there is a VDD overvoltage condition. When there is a VDD overvoltage condition, the flag is set and the ADP1050 shuts down. When the VDD overvoltage condition ends, the flag is cleared and the device downloads the EEPROM contents before restarting with a soft start process. 1 = VDD_OV flag is always cleared. When there is a VDD overvoltage condition, the flag is always cleared and the device continues to operate without interruption. This bit sets the debounce time for the VDD_OV flag. 0 = 500 μs debounce time. 1 = 2 μs debounce time. Reserved. Rev. A | Page 71 of 92 ADP1050 Data Sheet SOFT START AND SOFTWARE RESET REGISTERS Table 100. Register 0xFE06—Software Reset Go Command Bits [7:1] 0 Bit Name/Function Reserved Software reset go R/W R/W W Description Reserved. This bit lets the user perform a software reset of the ADP1050. Setting this bit resets the device with a restart delay period from the time the ADP1050 is turned off to the time ADP1050 restarts. The restart delay is set using Register 0xFE07[1:0] . Table 101. Register 0xFE07—Software Reset Settings Bits [7:3] Bit Name/Function Reserved R/W R/W Description Reserved. 2 Additional flag reenable delay R/W [1:0] Restart delay R/W This bit specifies whether an additional TON_DELAY value is added to the reenable delay after a manufacturer specific flag is cleared and before the ADP1050 begins a soft start. 0 = no additional delay is added to the reenable delay. 1 = additional delay is added to the reenable delay. The delay time is specified in the TON_DELAY command (Register 0x60). These bits specify the delay from the time when a PSON signal is set to the time when the soft start begins. Bit 1 Bit 0 Restart Delay 0 0 0 ms 0 1 500 ms 1 0 1 sec 1 1 2 sec Table 102. Register 0xFE08—Synchronous Rectifier (SR) Soft Start Settings Bits 7 6 R/W R/W R/W 4 Bit Name/Function Reserved CS1 cycle-by-cycle current limit to disable SR2 CS1 cycle-by-cycle current limit to disable SR1 SR soft start setting [3:2] SR soft start speed R/W 1 0 SR2 soft start SR1 soft start R/W R/W 5 R/W R/W Description Reserved. Setting this bit enables the CS1 cycle-by-cycle current limit to disable the SR2 output for the remainder of the switching cycle when cycle-by-cycle current limiting occurs. Setting this bit enables the CS1 cycle-by-cycle current limit to disable the SR1 output for the remainder of the switching cycle when cycle-by-cycle current limiting occurs. 0 = the synchronous rectifiers perform a soft start only the first time that they are enabled. 1 = the synchronous rectifiers perform a soft start every time that they are enabled. When an SR PWM output is configured to turn on with soft start (using Bits [1:0]), the rising edge of the output moves to the left in steps of 40 ns. These bits specify the number of switching cycles that are required to move the SR PWM output in 40 ns. Bit 3 Bit 2 SR Soft Start Timing 0 0 The SR PWM outputs change 40 ns in one switching cycle. 0 1 The SR PWM outputs change 40 ns in four switching cycles. 1 0 The SR PWM outputs change 40 ns in 16 switching cycles. 1 1 The SR PWM outputs change 40 ns in 64 switching cycles. Setting this bit enables soft start for SR2. Setting this bit enables soft start for SR1. Rev. A | Page 72 of 92 Data Sheet ADP1050 Table 103. Register 0xFE09—Soft Start Setting of Open-Loop Operation Bits 7 R/W R/W Description Setting this bit enables the soft start of open-loop operation. 6 Bit Name/Function Open-loop operation soft start enable OUTA and OUTB edges R/W 5 SR1 and SR2 edges R/W [4:3] Soft start speed of open-loop operation and open-loop feedforward operation R/W 2 Soft start variation for open-loop operation R/W [1:0] Reserved R/W When this bit is set, the falling edges of OUTA and OUTB are always after the rising edges in one cycle during the soft start of open-loop operation. This bit is valid only when Bit 7 of this register is set to 1. 0 = the rising edges of SR1 and SR2 always occur after the falling edges in one cycle during a soft start. 1 = the falling edges of SR1 and SR2 always occur after the rising edges in one cycle during a soft start. When the ADP1050 is configured for open-loop operation, the falling edge of the PWM output moves to the right in steps of 40 ns. When the ADP1050 is configured for openloop feedforward operation, the modulation edge of the PWM output moves from the original position in steps of 40 ns. These bits specify how many switching cycles are required to move the PWM outputs in 40 ns. Bit 4 Bit 3 Open-Loop Soft Start Timing 0 0 The PWM outputs change 40 ns in one switching cycle 0 1 The PWM outputs change 40 ns in four switching cycles 1 0 The PWM outputs change 40 ns in 16 switching cycles 1 1 The PWM outputs change 40 ns in 64 switching cycles Setting this bit enables global variation during the soft start of open-loop operation. 1 = all outputs use the time variation calculated by OUTB (tF2 − tR2). Reserved. BLANKING AND PGOOD SETTING REGISTERS Table 104. Register 0xFE0B—Flag Blanking During Soft Start Bits 7 6 Bit Name/Function Reserved Blank FLAGIN flag R/W R/W R/W 5 4 Reserved Blank VIN_UV_FAULT flag R/W R/W 3 Blank IIN_OC_FAST_FAULT flag R/W 2 1 Reserved Blank CS3_OC_FAULT flag R/W R/W 0 Blank VOUT_OV_FAULT flag R/W Description Reserved. 0 = blank this flag during soft start. 1 = do not blank this flag during soft start. Reserved. 0 = blank this flag during soft start. 1 = do not blank this flag during soft start. 0 = blank this flag during soft start. 1 = do not blank this flag during soft start. Reserved. 0 = blank this flag during soft start. 1 = do not blank this flag during soft start. 0 = blank this flag during soft start. 1 = do not blank this flag during soft start. Rev. A | Page 73 of 92 ADP1050 Data Sheet Table 105. Register 0xFE0C—Volt-Second Balance Blanking and SR Disable During Soft Start Bits [7:5] 4 Bit Name/Function Reserved VIN_UV_FAULT reenable blank R/W R/W R/W 3 First flag ID update R/W 2 Flag shutdown timing R/W 1 Volt-second balance blanking R/W 0 SR disable R/W Description Reserved. 0 = VIN_UV_FAULT flag is not blanked during the flag reenable delay. This is the recommended setting if the input voltage signal can be sensed by the ADP1050 before the PSU starts to operate. 1 = VIN_UV_FAULT flag is blanked during the flag reenable delay. This bit specifies whether the first flag ID is saved in the EEPROM. If it is set, the first flag ID is saved in the EEPROM. During the VDD power reset, the first flag ID is downloaded from the EEPROM to Register 0xFEA6. 0 = the first flag ID is not saved in the EEPROM. 1 = the first flag ID is saved in the EEPROM. Specifies when the PWM outputs are shut down after a manufacturer specific flag is triggered. 0 = the PWM outputs are shut down at the end of the switching cycle. 1 = the PWM outputs are shut down immediately. 0 = the volt-second balance control is not blanked during soft start. 1 = the volt-second balance control is blanked during soft start. 0 = SR1 and SR2 are not disabled during soft start. 1 = SR1 and SR2 are disabled during soft start. Table 106. Register 0xFE0D—PGOOD Mask Settings Bits 7 6 5 4 3 2 1 0 Bit Name/Function VIN_UV_FAULT flag IIN_OC_FAST_FAULT flag Reserved VOUT_OV_FAULT flag VOUT_UV_FAULT flag OT_FAULT flag OT_WARNING flag Reserved R/W R/W R/W R/W R/W R/W R/W R/W R/W Description 1 = the VIN_UV_FAULT flag is ignored by PGOOD. 1 = the IIN_OC_FAST_FAULT flag is ignored by PGOOD. Reserved. 1 = the VOUT_OV_FAULT flag is ignored by PGOOD. 1 = the VOUT_UV_FAULT flag is ignored by PGOOD. 1 = the OT_FAULT flag is ignored by PGOOD. 1 = the OT_WARNING flag is ignored by PGOOD. Reserved. Table 107. Register 0xFE0E—PGOOD Flag Debounce Bits [7:6] 5 4 [3:2] [1:0] Bit Name/Function Reserved CS1 cycle-by-cycle current limit to disable OUTB CS1 cycle-by-cycle current limit to disable OUTA PGOOD flag clearing debounce PGOOD flag setting debounce R/W R/W R/W R/W R/W R/W Description Reserved. Setting this bit enables the CS1 cycle-by-cycle current limit to disable the OUTB output for the remainder of the switching cycle when cycle-by-cycle current limiting occurs. Setting this bit enables the CS1 cycle-by-cycle current limit to disable the OUTA output for the remainder of the switching cycle when cycle-by-cycle current limiting occurs. These bits specify the PGOOD flag clearing debounce, which is the time from when the PGOOD clearing condition is met to the time when the PGOOD flag is cleared. PGOOD Flag Setting Debounce (ms) Bit 3 Bit 2 0 0 0 0 1 200 1 0 320 1 1 600 These bits specify the PGOOD flag setting debounce, which is the time from when the PGOOD setting condition is met to the time when the PGOOD flag is set and the PG/ALT pin is pulled low. PGOOD Flag Clearing Debounce (ms) Bit 1 Bit 0 0 0 1 1 0 1 0 1 0 200 320 600 Rev. A | Page 74 of 92 Data Sheet ADP1050 Table 108. Register 0xFE0F—Debounce Time for Asserting PGOOD Bits 7 Bit Name/Function VIN_UV_FAULT to assert PGOOD R/W R/W 6 IIN_OC_FAST_FAULT to assert PGOOD R/W 5 4 Reserved VOUT_OV_FAULT to assert PGOOD R/W R/W 3 VOUT_UV_FAULT to assert PGOOD R/W 2 OT_FAULT to assert PGOOD R/W 1 OT_WARNING to assert PGOOD R/W 0 Reserved R/W Debounce Time (ms) 0=0 1 = 1.3 0=0 1 = 1.3 Reserved. 0=0 1 = 1.3 0=0 1 = 1.3 0=0 1 = 1.3 0=0 1 = 1.3 Reserved. SWITCHING FREQUENCY AND SYNCHRONIZATION REGISTERS When synchronization is enabled, the ADP1050 takes the SYNI signal and adds the tSYNC_DELAY, together with a 760 ns propagation delay, to generate the internal synchronization reference clock as shown in Figure 55. The ADP1050 uses the reference clock to generate its own clock. SYNI CLOCKSYNC t0 tS 12039-064 760ns + tSYNC_DELAY Figure 55. Synchronization Timing Table 109. Register 0xFE11—Synchronization Delay Time Bits [7:0] Bit Name/Function tSYNC_DELAY R/W R/W Description Sets the additional delay of the synchronization reference clock to the rising edge of the SYNI signal. Each LSB size is 40 ns. Note that this delay time cannot exceed one switching period. If the PWM 180° phase shift is enabled, this delay time cannot exceed half of one switching period. Table 110. Register 0xFE12—Synchronization General Settings Bits 7 6 Bit Name/Function Reserved Phase capture range for synchronization R/W R/W R/W [5:4] 3 Reserved Enable synchronization FLGI polarity R/W R/W 1 FLAGIN flag debounce time R/W 0 SYNI/FLGI pin function selection R/W 2 R/W Description Reserved. Sets the phase capture range. The ADP1050 detects the phase shift between the external and internal clocks when synchronization is enabled. When the phase shift falls within the range, synchronization starts. 0 = phase capture range is ±3.125% (±11.25°). 1 = phase capture range is ±6.25% (±22.5°). This is the recommended setting. Reserved. This bit enables frequency synchronization as a slave device. The ADP1050 synchronizes with the external clock through the SYNI/FLGI pin. Bit 0 = 0 if synchronization is enabled. Sets the polarity for the SYNI/FLGI pin when the pin is programmed as FLGI. 0 = a high logic level on the SYNI/FLGI pin sets the FLAGIN flag; a low logic level clears the FLAGIN flag. 1 = a low logic level on the SYNI/FLGI pin sets the FLAGIN flag; a high logic level sets the FLAGIN flag. 0 = 0 μs debounce time for the FLAGIN flag. 1 = 100 μs debounce time for the FLAGIN flag. Configures the SYNI/FLGI pin as a flag input or a synchronization input. When SYNI is not enabled, this bit must be set to 1. 0 = the SYNI/FLGI pin is used as the synchronization input (SYNI). 1 = the SYNI/FLGI pin is used as the flag input (FLGI). Rev. A | Page 75 of 92 ADP1050 Data Sheet Table 111. Register 0xFE13—Dual-Ended Topology Mode Bits 7 6 Bit Name/Function Reserved Dual-ended topology enable R/W R/W R/W [5:0] Reserved R/W Description Reserved. Setting this bit to 1 means that dual-ended topologies are used. It affects the modulation high limit. The modulation limit in each half cycle is half of the modulation limit that is programmed in Register 0xFE3C. 0 = operates in single-ended topologies, such as buck, forward, and flyback. 1 = operates in dual-ended topologies, such as full bridge, half bridge, and push pull. Reserved. CURRENT SENSE AND LIMIT SETTING REGISTERS Table 112. Register 0xFE14—CS1 Gain Trim Bits 7 Bit Name/Function Gain polarity R/W R/W [6:0] CS1 gain trim R/W Description Setting this bit to 1 means that negative gain is introduced. 0 = positive gain is introduced. 1 = negative gain is introduced. This value calibrates the CS1 current sense gain. Apply 1 V dc at the CS1 pin. This register is trimmed until the CS1 value reads 2560 decimal (0xA00). Table 113. Register 0xFE19—CS3 OC Debounce Bits 7 [6:5] Bit Name/Function Reserved CS3_OC_FAULT flag debounce R/W R/W R/W [4:0] Reserved R/W Description Reserved. These two bits set the CS3_OC_FAULT flag debounce time. Bit 6 Bit 5 Debounce Time (ms) 0 0 0 0 1 10 1 0 20 1 1 200 Reserved. Table 114. Register 0xFE1A—IIN_OC_FAST_FAULT_LIMIT Bits 7 [6:4] Bit Name/Function Reserved IIN_OC_FAST_ FAULT_LIMIT R/W R/W R/W [3:0] Reserved R/W Description Reserved. If the CS1 cycle-by-cycle current-limit comparator is set and the CS1_OCP flag is triggered, all PWM outputs that are on at that time can be programmed to be immediately disabled for the remainder of the switching cycle. The PWM outputs resume normal operation at the beginning of the next switching cycle. There is an internal counter, N, with an initial value of 0. N counts the CS1_OCP flag triggering number in consecutive switching cycles. If the CS1_OCP flag is triggered in one cycle, then NCURRENT = NPREVIOUS + 2. If the CS1_OCP flag is not triggered in one cycle and the previous N > 0, then NCURRENT = NPREVIOUS − 1. If the CS1_OCP flag is not triggered and the previous N = 0, then NCURRENT = 0. When N reaches the IIN_OC_FAST_FAULT_LIMIT value, the IIN_OC_FAST_FAULT flag is set. Note that there is one cycle in single-ended topologies, such as buck converter and forward converter. There are two cycles in double-ended topologies, such as full bridge converter, half bridge converter, and push pull converter. Bit 6 Bit 5 Bit 4 Limit Value 0 0 0 2 0 0 1 8 0 1 0 16 0 1 1 64 1 0 0 128 1 0 1 256 1 1 0 512 1 1 1 1024 Reserved. Rev. A | Page 76 of 92 Data Sheet ADP1050 Table 115. Register 0xFE1B—CS1 Cycle-by-Cycle Current-Limit Reference Bits 7 6 Bit Name/Function Reserved CS1 cycle-by-cycle current-limit ref R/W R/W R/W [5:0] Reserved R/W Description Reserved. 0 = the CS1 cycle-by-cycle current-limit reference is 1.2 V. 1 = the CS1 cycle-by-cycle current-limit reference is 0.25 V. Reserved. Table 116. Register 0xFE1D—Matched Cycle-by-Cycle Current-Limit Settings Bits 7 6 [5:2] 1 0 Bit Name/Function Reserved Enable matched cycleby-cycle current limit Reserved OUTB rising edge blanking OUTA rising edge blanking R/W R/W R/W Description Reserved. Setting this bit enables the matched cycle-by-cycle current-limit function. R/W R/W Reserved. This bit specifies whether the blanking time for the CS1 cycle-by-cycle current-limit comparator is referenced to the rising edge of OUTB. 0 = no blanking at the OUTB rising edge. 1 = blanking time referenced to the OUTB rising edge. This bit specifies whether the blanking time for the CS1 cycle-by-cycle current-limit comparator is referenced to the rising edge of OUTA. 0 = no blanking at the OUTA rising edge. 1 = blanking time referenced to the OUTA rising edge. R/W Table 117. Register 0xFE1E—SR1 and SR2 Response to Cycle-by-Cycle Current Limit Bits [7:2] 1 Bit Name/Function Reserved SR2 response to cycleby-cycle current limit R/W R/W R/W 0 SR1 response to cycleby-cycle current limit R/W Description Reserved. This bit is applicable only when the SR2 output is programmed to be in complement with the OUTA output. When this bit is set and there is a cycle-by-cycle current limit, the SR2 rising edge is turned on when the cycle-by-cycle current limit disables the OUTA. Its falling edge still follows the programmed value. This bit is applicable only when the SR1 output is programmed to be in complement with the OUTB output. When this bit is set and there is a cycle-by-cycle current limit, the SR1 rising edge is turned on when the cycle-by-cycle current limit disables the OUTB. Its falling edge still follows the programmed value. Rev. A | Page 77 of 92 ADP1050 Data Sheet Table 118. Register 0xFE1F—CS1 Cycle-by-Cycle Current-Limit Settings Bits 7 [6:4] [3:2] [1:0] Bit Name/Function CS1 cycle-by-cycle currentlimit comparator ignored Leading edge blanking R/W R/W Reserved CS1 cycle-by-cycle current-limit debounce time R/W R/W R/W Description Setting this bit causes the CS1 OCP comparator output to be ignored. The CS1_OCP internal flag is always cleared. These bits determine the leading edge blanking time. During this time, the CS1 OCP comparator output is ignored. This time is measured from the rising edges of OUTA and OUTB (programmable in Register 0xFE1D[1:0]). Bit 6 Bit 5 Bit 4 Leading Edge Blanking Time (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 Reserved. These bits set the CS1 cycle-by-cycle current-limit debounce time. This is the minimum time that the CS1 signal must be constantly above the CS1 cycle-by-cycle current-limit reference before the PWM outputs are shut down. When this happens, the selected PWM outputs can be disabled for the remainder of the switching cycle. Bit 1 Bit 0 Debounce Time (ns) 0 0 0 0 1 40 1 0 80 1 1 120 VOLTAGE SENSE AND LIMIT SETTING REGISTERS Table 119. Register 0xFE20—VS Gain Trim Bits 7 Bit Name/Function Trim polarity R/W R/W [6:0] VS gain trim R/W Description 0 = positive gain is introduced. 1 = negative gain is introduced. These bits set the amount of gain trim that is applied to the VS ADC reading. This register trims the voltage reading in the READ_VOUT command after the VOUT_CAL_OFFSET trimming is completed. This register is trimmed until the READ_VOUT reading in the register exactly matches the output voltage measurement result. Table 120. Register 0xFE25—Prebias Start-Up Enable Bits 7 Bit Name/Function Prebias startup enable R/W R/W [6:0] Reserved R/W Description Setting this bit enables the prebias start-up function. If it is enabled, the soft start ramp starts from the current output voltage. The initial PWM modulation value is generated based on the following: the Register 0xFE39 setting, the sensed VOUT value, and the sensed VIN value. To introduce the VIN value for initial modulation calculation, set Register 0xFE6C[1] = 1, unless closed-loop input voltage feedforward operation mode is in use. Reserved. Table 121. Register 0xFE26—VOUT_OV_FAULT Flag Debounce Bits [7:6] Bit Name/Function VOUT_OV_FAULT flag debounce R/W R/W [5:0] Reserved R/W Description These bits set the VOUT_OV_FAULT flag debounce time. Bit 7 Bit 6 Typical Debounce Time (μs) (Delay Time 1) 0 0 0 0 1 1 1 0 2 1 1 8 Reserved Rev. A | Page 78 of 92 Data Sheet ADP1050 Table 122. Register 0xFE28—VF Gain Trim Bits 7 Bit Name/Function Trim polarity R/W R/W [6:0] VF trim R/W Description 0 = positive gain is introduced. 1 = negative gain is introduced. These bits set the amount of gain trim that is applied to the VF ADC reading. This register trims the voltage at the VF pin for external resistor tolerances. When there is 1 V on the VF pin, this register is trimmed until the VF value register reads 1280 decimal (0x500). Table 123. Register 0xFE29—VIN_ON and VIN_OFF Delay Bits [7:6] 5 4 Bit Name/Function Reserved VIN_UV_FAULT enable Power conversion stop delay R/W R/W R/W R/W [3:2] Power conversion start delay R/W [1:0] VIN_UV_FAULT flag debounce R/W Description Reserved Setting this bit enables the VIN_ON value and the VIN_OFF value used to generate the VIN_UV_FAULT flag. Sets the delay time from when the VIN_LOW flag is set to when the power conversion stops. 0 = 0 ms. 1 = 1 ms. Sets the delay time from the clearing of the VIN_LOW flag to the start of the power conversion. Bit 3 Bit 2 Delay Time (ms) 0 0 0 0 1 10 1 0 40 1 1 80 When Bit 5 is set, sets the VIN_UV_FAULT flag debounce time. Bit 1 Bit 0 Typical Debounce Time (ms) 0 0 0 0 1 2.5 1 0 10 1 1 100 TEMPERATURE SENSE AND PROTECTION SETTING REGISTERS Table 124. Register 0xFE2A—RTD Gain Trim Bits 7 Bit Name/Function Gain polarity R/W R/W [6:0] RTD gain trim R/W Description Setting this bit to 1 means that negative gain is introduced. Setting this bit to 0 means that positive gain is introduced. This value calibrates the RTD sensing gain. Table 125. Register 0xFE2B—RTD Offset Trim (MSBs) Bits [7:3] 2 R/W R/W R/W Description Reserved. Setting this bit to 1 and writing 0x00 to Register 0xFE2D disables the RTD current source. 1 Bit Name/Function Reserved RTD current source disable Trim polarity R/W 0 RTD offset trim, MSB R/W Setting this bit to 1 means that negative offset is introduced. Setting this bit to 0 means that positive offset is introduced. This bit, together with Register 0xFE2C as the LSBs, sets the amount of offset trim that is applied to the RTD ADC reading. Table 126. Register 0xFE2C—RTD Offset Trim (LSBs) Bits [7:0] Bit Name/Function RTD offset trim, LSBs R/W R/W Description These eight bits, together with Bit 0 in Register 0xFE2B as the MSB, set the amount of offset trim that is applied to the RTD ADC reading. Rev. A | Page 79 of 92 ADP1050 Data Sheet Table 127. Register 0xFE2D—RTD Current Source Settings Bits [7:6] Bit Name/Function RTD current setting R/W R/W [5:0] RTD 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 Bits[7:6]. Table 128. Register 0xFE2F—OT Hysteresis Settings Bits [7:3] 2 Bit Name/Function Reserved OT_WARNING flag debounce R/W R/W R/W [1:0] OT hysteresis R/W Description Reserved. This bit sets the OT_WARNING flag debounce time. 0 = sets the flag actions debounce time to 100 ms. 1 = sets the flag actions debounce time to 0 ms. These bits set the OT hysteresis. Due to the negative temperature coefficient of the NTC thermistor or analog temperature sensor, the OT_FAULT flag clearing voltage threshold is programmed with a voltage greater than the OT_FAULT flag setting voltage threshold. Bit 1 Bit 0 OT Hysteresis 0 0 OT hysteresis = 12.5 mV (4 LSBs) 0 1 OT hysteresis = 25 mV (8 LSBs) 1 0 OT hysteresis = 37.5 mV (12 LSBs) 1 1 OT hysteresis = 50 mV (16 LSBs) 48.13dB LF FILTER POLE HF GAIN RANGE HF FILTER 48.13dB LF GAIN RANGE DIGITAL COMPENSATOR AND MODULATION SETTING REGISTERS 500Hz 1kHz POLE LOCATION RANGE 5kHz 10kHz 12039-065 100Hz 48.13dB ZERO RANGE ZERO Figure 56. Digital Compensator Programmability Table 129. Register 0xFE30—Normal Mode Compensator Low Frequency Gain Settings Bits [7:0] Bit Name/Function Normal mode low frequency gain R/W R/W Description This register determines the low frequency gain of the digital compensator in normal mode. It is programmable over a 48.13 dB range. See Figure 56. Table 130. Register 0xFE31—Normal Mode Compensator Zero Settings Bits [7:0] Bit Name/Function Normal mode zero settings R/W R/W Description This register determines the position of the zero of the digital compensator in normal mode. See Figure 56. Rev. A | Page 80 of 92 Data Sheet ADP1050 Table 131. Register 0xFE32—Normal Mode Compensator Pole Settings Bits [7:0] Bit Name/Function Normal mode pole settings R/W R/W Description This register determines the position of the pole of the digital compensator in normal mode. See Figure 56. Table 132. Register 0xFE33—Normal Mode Compensator High Frequency Gain Settings Bits [7:0] Bit Name/Function Normal mode high frequency gain R/W R/W Description This register determines the high frequency gain of the digital compensator in normal mode. It is programmable over a 48.13 dB range. See Figure 56. Table 133. Register 0xFE38—CS1 Threshold for Volt-Second Balance Bits [7:0] Bit Name/Function CS1 threshold for volt-second balance R/W R/W Description This register sets the CS1 threshold to enable volt-second balance control. The volt-second balance control function is activated only if the CS1 value is greater than this threshold value. Each LSB is 6.25 mV. Table 134. Register 0xFE39—Nominal Modulation Value for Prebias Startup Bits [7:0] Bit Name/Function Nominal modulation value for prebias start-up function R/W R/W Description These bits set the nominal modulation value when the input voltage and the output voltage are in nominal conditions. It is used to calculate the initial modulation value, based on the sensed VOUT value and the sensed VIN value, for the prebias startup. If Register 0xFE6C[1] is cleared, the input voltage is always regarded as the nominal input condition unless closed-loop feedforward operation is in use. Switching Frequency Range (kHz) Resolution Corresponding to LSB (ns) 49 to 87 80 97.5 to 184 40 195.5 to 379 20 390.5 to 625 10 Table 135. Register 0xFE3A—SR Driver Delay Bits [7:6] [5:0] Bit Name/Function Reserved SR gate drive delay R/W R/W R/W Description Reserved. These bits set the SR gate drive delay in steps of 5 ns, from 0 ns to a maximum of 315 ns. Table 136. Register 0xFE3B—PWM 180° Phase Shift Settings Bits 7 Bit Name/Function Volt-second balance leading edge blanking R/W R/W 6 Volt-second balance 50% blanking of each phase SR2 180° phase shift SR1 180° phase shift Reserved OUTB 180° phase shift OUTA 180° phase shift R/W Description Setting this bit means that CS1 is blanked for volt-second balance calculations at the rising edge of those PWMs selected for volt-second balance. The blanking time is the same as for the CS1 cycleby-cycle current-limit setting. Setting this bit limits the sampling period for the current on CS1 to less than 50% of a half cycle. R/W R/W R/W R/W R/W Setting this bit adds a 180° phase shift for the timing of the SR2 edges. Setting this bit adds a 180° phase shift for the timing of the SR1 edges. Reserved. Setting this bit adds a 180° phase shift for the timing of the OUTB edges. Setting this bit adds a 180° phase shift for the timing of the OUTA edges. 5 4 [3:2] 1 0 Rev. A | Page 81 of 92 ADP1050 Data Sheet Figure 57 and Register 0xFE3C describe the modulation limit settings. tMODU_LIMIT OUTX tRX tFX tMODU_LIMIT OUTY tRY t0, START OF SWITCHING CYCLE tS/2 tS, END OF SWITCHING CYCLE 3tS/2 12039-066 tFY Figure 57. Setting Modulation Limits Table 137. Register 0xFE3C—Modulation Limit Bits [7:0] Bit Name/Function Modulation limit R/W R/W Description This register sets the modulation limit, tMODU_LIMIT (maximum duty cycle). The modulation limit is the maximum time variation for the modulated edges from the default timing (see Figure 57). The step size of an LSB depends on the switching frequency. Switching Frequency Range (kHz) LSB Step Size (ns) 49 to 87 80 97.5 to 184 40 195.5 to 379 20 390.5 to 625 10 Table 138. Register 0xFE3D—Feedforward and Soft Start Filter Gain Bits 7 Bit Name/Function Soft start enable of open-loop input voltage feedforward operation R/W R/W 6 Open-loop input voltage feedforward operation enable R/W 5 High frequency ADC debounce time R/W 4 R/W 3 2 High frequency ADC debounce enable Feedforward ADC selection Feedforward enable [1:0] Soft start filter gain R/W R/W R/W Description Setting this bit enables the soft start procedure of the open-loop input voltage feedforward operation. Set Bit 6 if this function is used. 0 = open-loop input voltage feedforward operation is disabled. 1 = open-loop input voltage feedforward operation is enabled. This bit sets the debounce time for detecting the settling of the VS high frequency ADC. Bit 4 must be set to 1 to enable this function. 0 = 5 ms debounce time. 1 = 10 ms debounce time. Setting this bit enables a debounce time for detecting the settling of the VS high frequency ADC at the end of a soft start. The debounce time is set using Bit 5. Always set this bit to select the 11-bit VF ADC (factory default setting). This bit enables or disables feedforward control during closed-loop operation. 0 = closed-loop input voltage feedforward control is disabled. 1 = closed-loop input voltage feedforward control is enabled. These bits set the soft start gain of the soft start filter. Bit 1 Bit 0 Soft Start Filter Gain 0 0 1 0 1 2 1 0 4 1 1 8 Rev. A | Page 82 of 92 Data Sheet ADP1050 PWM OUTPUTS TIMING REGISTERS Figure 58 and Register 0xFE3E to Register 0xFE53 describe the implementation and programming of the four PWM signals that are generated by the ADP1050. tF1 OUTA tR1 tF2 OUTB tR2 tF5 SR1 tR5 SR2 tF6 tPERIOD tPERIOD 12039-067 tR6 Figure 58. PWM Timing Diagram Table 139. Register 0xFE3E/Register 0xFE41/Register 0xFE4A/Register 0xFE4D—OUTA/OUTB/SR1/SR2 Rising Edge Timing Bits [7:0] Bit Name/Function Rising edge timing, tRX, MSBs R/W R/W Description These bits contain the eight MSBs of the 12-bit tRX time. This value is always used with the four MSBs of Register 0xFE40, Register 0xFE43, Register 0xFE4C, and Register 0xFE4F, which contain the four LSBs of the tRX time. tRx represents tR1, tR2, tR5, and tR6. Each LSB corresponds to 5 ns resolution. Table 140. Register 0xFE3F/Register 0xFE42/Register 0xFE4B/Register 0xFE4E—OUTA/OUTB/SR1/SR2 Falling Edge Timing Bits [7:0] Bit Name/Function Falling edge timing, tFX, MSBs R/W R/W Description These bits contain the eight MSBs of the 12-bit tFX time. This value is always used with the four LSBs of Register 0xFE40, Register 0xFE43, Register 0xFE4C, and Register 0xFE4F, which contain the four LSBs of the tFX time. tFX represents tF1, tF2, tF5, and tF6. Each LSB corresponds to 5 ns resolution. Table 141. Register 0xFE40/Register 0xFE43/Register 0xFE4C/Register 0xFE4F—OUTA/OUTB/ SR1/SR2 Rising and Falling Edge Timing (LSBs) Bits [7:4] Bit Name/Function Rising edge timing, tRX, LSBs R/W R/W [3:0] Falling edge timing, tFX, LSBs R/W Description These bits contain the four LSBs of the 12-bit tRX time. This value is always used with the eight bits of Register 0xFE3E, Register 0xFE41, Register 0xFE4A, and Register0xFE4D, which contain the eight MSBs of the tRX time. tRx represents tR1, tR2, tR5, and tR6. Each LSB corresponds to 5 ns resolution. These bits contain the four LSBs of the 12-bit tFX time. This value is always used with the eight bits of Register 0xFE3F, Register 0xFE42, Register 0xFE4B, and Register 0xFE4E, which contain the eight MSBs of the tFX time. tFX represents tF1, tF2, tF5, and tF6. Each LSB corresponds to 5 ns resolution. Rev. A | Page 83 of 92 ADP1050 Data Sheet Table 142. Register 0xFE50—OUTA and OUTB Modulation Settings Bits 7 Bit Name/Function OUTB tR2 modulation enable R/W R/W 6 OUTB tR2 modulation sign R/W 5 OUTB tF2 modulation enable R/W 4 OUTB tF2 modulation sign R/W 3 OUTA tR1 modulation enable R/W 2 OUTA tR1 modulation sign R/W 1 OUTA tF1 modulation enable R/W 0 OUTA tF1 modulation sign R/W Description 0 = no PWM modulation of the tR2 edge. 1 = PWM modulation acts on the tR2 edge. 0 = positive sign. Increase of PWM modulation moves tR2 to the right. 1 = negative sign. Increase of PWM modulation moves tR2 to the left. 0 = no PWM modulation of the tF2 edge. 1 = PWM modulation acts on the tF2 edge. 0 = positive sign. Increase of PWM modulation moves tF2 to the right. 1 = negative sign. Increase of PWM modulation moves tF2 to the left. 0 = no PWM modulation of the tR1 edge. 1 = PWM modulation acts on the tR1 edge. 0 = positive sign. Increase of PWM modulation moves tR1 to the right. 1 = negative sign. Increase of PWM modulation moves tR1 to the left. 0 = no PWM modulation of the tF1 edge. 1 = PWM modulation acts on the tF1 edge. 0 = positive sign. Increase of PWM modulation moves tF1 to the right. 1 = negative sign. Increase of PWM modulation moves tF1 to the left. Table 143. Register 0xFE52—SR1 and SR2 Modulation Settings Bits 7 Bit Name/Function SR2 tR6 modulation enable R/W R/W 6 SR2 tR6 modulation sign R/W 5 SR2 tF6 modulation enable R/W 4 SR2 tF6 modulation sign R/W 3 SR1 tR5 modulation enable R/W 2 SR1 tR5 modulation sign R/W 1 SR1 tF5 modulation enable R/W 0 SR1 tF5 modulation sign R/W Description 0 = no PWM modulation of the tR6 edge. 1 = PWM modulation acts on the tR6 edge. 0 = positive sign. Increase of PWM modulation moves tR6 to the right. 1 = negative sign. Increase of PWM modulation moves tR6 to the left. 0 = no PWM modulation of the tF6 edge. 1 = PWM modulation acts on the tF6 edge. 0 = positive sign. Increase of PWM modulation moves tF6 to the right. 1 = negative sign. Increase of PWM modulation moves tF6 to the left. 0 = no PWM modulation of the tR5 edge. 1 = PWM modulation acts on the tR5 edge. 0 = positive sign. Increase of PWM modulation moves tR5 to the right. 1 = negative sign. Increase of PWM modulation moves tR5 to the left. 0 = no PWM modulation of the tF5 edge. 1 = PWM modulation acts on the tF5 edge. 0 = positive sign. Increase of PWM modulation moves tF5 to the right. 1 = negative sign. Increase of PWM modulation moves tF5 to the left. Table 144. Register 0xFE53—PWM Output Disable Bits [7:6] 5 4 [3:2] 1 0 Bit Name/Function Reserved SR2 disable SR1 disable Reserved OUTB disable OUTA disable R/W R/W R/W R/W R/W R/W R/W Description Reserved. Setting this bit disables the SR2 output. Setting this bit disables the SR1 output. Reserved. Setting this bit disables the OUTB output. Setting this bit disables the OUTA output. Rev. A | Page 84 of 92 Data Sheet ADP1050 VOLT-SECOND BALANCE CONTROL REGISTERS Table 145. Register 0xFE54—Volt-Second Balance Control General Settings Bits 7 [6:5] 4 R/W R/W R/W R/W 2 Bit Name/Function Volt-second balance enable control Reserved Volt-second balance control source selection, OUTB Volt-second balance control source selection, OUTA Volt-second balance control limit [1:0] Volt-second balance control gain R/W 3 R/W R/W Description Setting this bit enables volt-second balance control. Reserved. If this bit is set, OUTB rising edge is selected as the start of the integration period for volt-second balance control. If this bit is set, OUTA rising edge is selected as the start of the integration period for volt-second balance control. This bit sets the maximum amount of modulation from the volt-second control circuit. 0 = ±160 ns. 1 = ±80 ns. These bits set the gain of the volt-second balance control. 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 Loop Gain 0 0 1 0 1 4 1 0 16 1 1 64 Table 146. Register 0xFE55—Volt-Second Balance Control on OUTA and OUTB Bits 7 6 Bit Name/Function tR2 balance setting tR2 balance direction R/W R/W R/W 5 4 tF2 balance setting tF2 balance direction R/W R/W 3 2 tR1 balance setting tR1 balance direction R/W R/W 1 0 tF1 balance setting tF1 balance direction R/W R/W Description Setting this bit enables modulation from balancing control on the OUTB rising edge, tR2. 0 = positive sign. Increase of balancing control modulation moves tR2 right. 1 = negative sign. Increase of balancing control modulation moves tR2 left. Setting this bit enables modulation from balancing control on the OUTB falling edge, tF2. 0 = positive sign. Increase of balancing control modulation moves tF2 right. 1 = negative sign. Increase of balancing control modulation moves tF2 left. Setting this bit enables modulation from balancing control on the OUTA rising edge, tR1. 0 = positive sign. Increase of balancing control modulation moves tR1 right. 1 = negative sign. Increase of balancing control modulation moves tR1 left. Setting this bit enables modulation from balancing control on the OUTA falling edge, tF1. 0 = positive sign. Increase of balancing control modulation moves tF1 right. 1 = negative sign. Increase of balancing control modulation moves tF1 left. Table 147. Register 0xFE57—Volt-Second Balance Control on SR1 and SR2 Bits 7 6 Bit Name/Function tR6 balance setting tR6 balance direction R/W R/W R/W 5 4 tF6 balance setting tF6 balance direction R/W R/W 3 2 tR5 balance setting tR5 balance direction R/W R/W 1 0 tF5 balance setting tF5 balance direction R/W R/W Description Setting this bit enables modulation from balancing control on the SR2 rising edge, tR6. 0 = positive sign. Increase of balancing control modulation moves tR6 right. 1 = negative sign. Increase of balancing control modulation moves tR6 left. Setting this bit enables modulation from balancing control on the SR2 falling edge, tF6. 0 = positive sign. Increase of balancing control modulation moves tF6 right. 1 = negative sign. Increase of balancing control modulation moves tF6 left. Setting this bit enables modulation from balancing control on the SR1 rising edge, tR5. 0 = positive sign. Increase of balancing control modulation moves tR5 right. 1 = negative sign. Increase of balancing control modulation moves tR5 left. Setting this bit enables modulation from balancing control on the SR1 falling edge, tF5. 0 = positive sign. Increase of balancing control modulation moves tF5 right. 1 = negative sign. Increase of balancing control modulation moves tF5 left. Rev. A | Page 85 of 92 ADP1050 Data Sheet DUTY CYCLE READING SETTING REGISTERS Table 148. Register 0xFE58—Duty Cycle Reading Settings Bits [7:4] 3 2 1 0 Bit Name/Function Reserved OUTB duty cycle reporting OUTA duty cycle reporting Reserved Polarity setting for input voltage compensation R/W R/W R/W R/W R/W R/W Description Reserved. 1 = READ_DUTY_CYCLE reports OUTB duty cycle value. 1 = READ_DUTY_CYCLE reports OUTA duty cycle value. Reserved. Setting this bit applies an offset on the input voltage reading, READ_VIN, based on the reading of the input current, READ_IIN. The compensation multipler is set in Register 0xFE59. It is used to compensate the voltage drop caused by the current conduction. 0 = positive polarity compensation. 1 = negative polarity compensation. Table 149. Register 0xFE59—Input Voltage Compensation Multiplier Bits [7:0] Bit Name/Function Input voltage compensation multiplier R/W R/W Description These bits specify the multiplier, N, for the input voltage compensation coefficient. The compensation equation is N × (Register 0xFEA7[15:4] value) ÷ 211, and the result is added to Register 0xFEAC[15:5]. The compensation polarity is set by Register 0xFE58[0]. OTHER REGISTER SETTINGS Table 150. Register 0xFE61—Go Commands Bits [7:3] 2 Bit Name/Function Reserved Frequency go R/W R/W R/W 1 PWM setting go R/W 0 Reserved R/W Description Reserved. This bit synchronously latches the contents of Register 0x33 into the shadow registers used to calculate the switching frequency. Reading of this bit always returns 1. This bit synchronously latches the contents of Registers 0xFE3E to Register 0xFE53 into the shadow registers used to calculate the PWM edge timing. Reading this bit always returns 1. Reserved. Table 151. Register 0xFE62—Customized Register Bits [7:0] Bit Name/Function Customized register R/W R/W Description These bits are available to the user to store customized information. Table 152. Register 0xFE63—Modulation Reference MSBs Setting for Open-Loop Input Voltage Feedforward Operation Bits [7:0] Bit Name/Function Modulation reference setting MSBs R/W R/W Description This register sets the eight MSBs of the modulation reference in open-loop feedforward operation mode. The step size of an LSB depends on the switching frequency. Switching Frequency Range (kHz) LSB Step Size (ns) 49 to 87 80 97.5 to 184 40 195.5 to 379 20 390.5 to 625 10 Table 153. Register 0xFE64—Modulation Reference LSBs Setting for Open-Loop Input Voltage Feedforward Operation Bits [7:0] Bit Name/Function Modulation reference setting LSBs R/W R/W Description This register sets the eight LSBs of the modulation reference in open-loop feedforward operation mode. The step size of an LSB depends on the switching frequency. Switching Frequency Range (kHz) LSB Step Size (ps) 49 to 87 312.5 97.5 to 184 156.25 195.5 to 379 78.125 390.5 to 625 39.0625 Rev. A | Page 86 of 92 Data Sheet ADP1050 Table 154. Register 0xFE65—Current Value Update Rate Setting Bits [7:2] [1:0] Bit Name/Function Reserved Current value update rate R/W R/W R/W Description Reserved. These bits specify the update rate for the current value of CS1 (READ_IIN command, Register 0x89). By default, the current values are updated every 10 ms. Bit 1 Bit 0 CS1 Value Update Rate (ms) 0 0 10 (defaut) 0 1 52 1 0 105 1 1 210 Table 155. Register 0xFE67—Open-Loop Operation Settings Bits 7 6 Bit Name/Function Reserved Pulse skipping mode enable R/W R R/W 5 4 3 2 1 0 SR2 open-loop operation enable SR1 open-loop operation enable Reserved Reserved OUTB open-loop operation enable OUTA open-loop operation enable R/W R/W R/W R/W R/W R/W Description Reserved. 1 = enables pulse skipping mode. If the ADP1050 requires a modulation value that is less than the threshold set by Register 0xFE69, pulse skipping is in use. This bit is set when SR2 is used in open-loop operation mode. This bit is set when SR1 is used in open-loop operation mode. Reserved. Reserved. This bit is set when OUTB is used in open-loop operation mode. This bit is set when OUTA is used in open-loop operation mode. Table 156. Register 0xFE69—Pulse Skipping Mode Threshold Bits [7:0] Bit Name/Function Pulse skipping mode threshold R/W R/W Description These bits set the modulation pulse width threshold for pulse skipping. Each LSB is 5 ns. Table 157. Register 0xFE6A—CS3_OC_FAULT_LIMIT Bits [7:0] Bit Name/Function CS3_OC_FAULT_LIMIT R/W R/W Description The eight MSB value of the CS3 value register in Register 0xFEA9 is compared with this 8-bit number. If the 8 MSB value is greater, the CS3_OC_FAULT flag is set. Table 158. Register 0xFE6B—Modulation Threshold for OVP Selection Bits [7:0] Bit Name/Function Modulation threshold for conditional OVP responses R/W R/W Description This value sets modulation threshold for conditional OVP response. When the real-time modulation value is above this threshold, the LARGE_MODULATION flag in Register 0xFE6C[2] is set. Switching Frequency Range (kHz) Resolution Corresponding to LSB (ns) 49 to 87 80 97.5 to 184 40 195.5 to 379 20 390.5 to 625 10 Rev. A | Page 87 of 92 ADP1050 Data Sheet Table 159. Register 0xFE6C—Modulation Flag for OVP Selection Bits [7:3] 2 1 Bit Name/Function Reserved LARGE_MODULATION VIN feedforward prebias startup R/W R/W R R/W 0 Conditional OVP enable R/W Description Reserved. This bit is set when the modulation value is above the threshold set in Register 0xFE6B. This bit is applicable only if the closed-loop feedforward operation is disabled (Register 0xFE3D[2] = 0). If the closed-loop feedforward operation is enabled, VIN is always included for the calculation of the initial PWM modulation value. 1 = the initial PWM modulation value is calculated by the nominal modulation value (Register 0xFE39), the sensed VIN voltage, and the sensed VOUT voltage. 0 = the initial PWM modulation value is calculated by the nominal modulation value (Register 0xFE39) and the sensed VOUT voltage. The VIN voltage is ignored. This bit sets the OVP actions when the VOUT_OV_FAULT flag is triggered. 0 = conditional OVP is disabled. The OVP action follows the PMBus VOUT_OV_FAULT_RESPONSE command (Register 0x41). 1 = conditional OVP is enabled. If Bit 2 = 1, OVP action follows the PMBus VOUT_OV_FAULT_RESPONSE (Register 0x41). If Bit 2 = 0, OVP action follows the extended VOUT_OV_FAULT_RESPONSE action (Register 0xFE01[7:4]). Table 160. Register 0xFE6D—OUTA and OUTB Adjustment Reference During Synchronization Bits 7 6 Bit Name/Function tR2 adjustment reference tR2 refers to tS or tS/2 R/W R/W R/W 5 4 tF2 adjustment reference tF2 refers to tS or tS/2 R/W R/W 3 2 tR1 adjustment reference tR1 refers to tS or tS/2 R/W R/W 1 0 tF1 adjustment reference tF1 refers to tS or tS/2 R/W R/W Description Setting this bit enables edge adjustment on the OUTB rising edge, tR2. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the OUTB falling edge, tF2. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the OUTA rising edge, tR1. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the OUTA falling edge, tF1. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Table 161. Register 0xFE6F—SR1 and SR2 Adjustment Reference During Synchronization Bits 7 6 Bit Name/Function tR6 adjustment reference tR6 refers to tS or tS/2 R/W R/W R/W 5 4 tF6 adjustment reference tF6 refers to tS or tS/2 R/W R/W 3 2 tR5 adjustment reference tR5 refers to tS or tS/2 R/W R/W 1 0 tF5 adjustment reference tF5 refers to tS or tS/2 R/W R/W Description Setting this bit enables edge adjustment on the SR2 rising edge, tR6. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the SR2 falling edge, tF6. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the SR1 rising edge, tR5. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Setting this bit enables edge adjustment on the SR1 falling edge, tF5. 0 = adjustment refers to tS/2. 1 = adjustment refers to tS. Register 0xFE70 to Register 0xFE9F—Reserved Rev. A | Page 88 of 92 Data Sheet ADP1050 MANUFACTURER SPECIFIC FAULT FLAG REGISTERS Table 162. Register 0xFEA0—Flag Register 1 and Register 0xFEA3—Latched Flag Register 1 (1 = Fault, 0 = Normal Operation) Bits 7 6 Bit Name/Function CHIP_PASSWORD_UNLOCKED PGOOD R/W R R 5 4 3 [2:1] 0 IIN_OC_FAST_FAULT Reserved CS3_OC_FAULT Reserved VDD_OV R R R R R 1 Description Chip password is unlocked. At least one of the following flags has been set: VOUT_OV_FAULT, VOUT_UV_FAULT, OT_FAULT, OT_WARNING, VIN_UV_FAULT, IIN_OC_FAST_FAULT, POWER_OFF, CRC_FAULT, SOFT_START_FILTER, or POWER_GOOD. Some of the flags are maskable according to Register 0xFE0D. An input overcurrent fast fault is triggered. Reserved. A CS3 overcurrent fault is triggered. Reserved. VDD is above the OVLO limit. The I2C/PMBus interface remains functional, but power conversion stops. Register1 0xFE0D and 0xFE0E 0xFE1F N/A 0xFE6A N/A 0xFE05 Action1 None PG/ALT pin set low Programmable N/A Programmable N/A Programmable N/A means not applicable. Table 163. Register 0xFEA1—Flag Register 2 and Register 0xFEA4—Latched Flag Register 2 (1 = Fault, 0 = Normal Operation) Bits [7:3] 2 1 0 1 Bit Name/Function Reserved VIN_UV_FAULT SYNC_LOCKED FLAGIN R/W R R R R Description Reserved. VIN reading is below the VIN_OFF limit. Cycle-by-cycle synchronization starts. FLAGIN flag (SYNI/FLGI pin) is set. Register1 N/A 0xFE29 N/A 0xFE12 Action1 N/A Programmable Programmable Programmable N/A means not applicable. Table 164. Register 0xFEA2—Flag Register 3 and Register 0xFEA5—Latched Flag Register 3 (1 = Fault, 0 = Normal Operation) Bits 7 6 [5:4] 3 2 Bit Name/Function CHIP_ID PULSE_SKIPPIING Reserved EEPROM_UNLOCKED CRC_FAULT R/W R R R R R Description In the ADP1050, this bit is 0. Pulse skipping mode is in use. Reserved. The EEPROM is unlocked. The EEPROM contents that were downloaded are incorrect. Register1 N/A 0xFE69 N/A N/A N/A 1 Modulation R N/A 0 SOFT_START_FILTER R Digital compensator output is at its minimum or maximum limit. The soft start filter is in use. Action1 N/A Programmable N/A None Immediate shutdown None N/A None 1 N/A means not applicable. Rev. A | Page 89 of 92 ADP1050 Data Sheet Table 165. Register 0xFEA6—First Flag ID Bits [7:4] Bit Name/Function Previous first flag ID R/W R [3:0] Current first flag ID R Description These bits return the flag fault ID of the flag that caused the previous shutdown of the power supply. This previous shutdown occurred before the shutdown caused by the fault identified in Bits[3:0]. Bit 7 Bit 6 Bit 5 Bit 4 First Flag 0 0 0 0 No flag 0 0 0 1 IIN_OC_FAST_FAULT 0 0 1 0 Reserved 0 0 1 1 CS3_OC_FAULT 0 1 0 0 VOUT_OV_FAULT 0 1 0 1 VOUT_UV_FAULT 0 1 1 0 VIN_UV_FAULT 0 1 1 1 FLAGIN 1 0 0 0 Reserved 1 0 0 1 OT_FAULT 1 0 1 0 Reserved 1 0 1 1 Reserved 1 1 0 0 Reserved 1 1 0 1 Reserved 1 1 1 0 Reserved 1 1 1 1 Reserved These bits return the flag fault ID of the fault that caused the shutdown of the power supply. Bit 3 Bit 2 Bit 1 Bit 0 First Flag 0 0 0 0 No flag 0 0 0 1 IIN_OC_FAST_FAULT 0 0 1 0 Reserved 0 0 1 1 CS3_OC_FAULT 0 1 0 0 VOUT_OV_FAULT 0 1 0 1 VOUT_UV_FAULT 0 1 1 0 VIN_UV_FAULT 0 1 1 1 FLAGIN 1 0 0 0 Reserved 1 0 0 1 OT_FAULT 1 0 1 0 Reserved 1 0 1 1 Reserved 1 1 0 0 Reserved 1 1 0 1 Reserved 1 1 1 0 Reserved 1 1 1 1 Reserved Rev. A | Page 90 of 92 Data Sheet ADP1050 MANUFACTURER SPECIFIC VALUE READING REGISTERS Table 166. Register 0xFEA7—CS1 Value Bits [15:4] Bit Name/Function CS1 current value R/W R [3:0] Reserved R Description This register contains 12-bit CS1 current information. The range of the CS1 input pin is from 0 V to 1.6 V. Each LSB corresponds to 390.625 μV. At 0 V input, the value in this register is 0 decimal. The nominal voltage at the CS1 pin is 1 V. At 1 V input, the value of these bits is 0xA00 (2560 decimal). The reading is equivalent to the READ_IIN command. Reserved. Table 167. Register 0xFEA9—CS3 Value Bits [15:4] Bit Name/Function CS3 voltage value Type R [3:0] Reserved R Description This register contains 12-bit CS3 current information calculated by using the CS1 reading and duty cycle information. Each LSB corresponds to 4× the CS1 LSB in Register 0xFEA7, multiplied by the turns ratio of the main transformer, n (n = NPRI/NSEC). Reserved. Table 168. Register 0xFEAA—VS Value Bits [15:4] Bit Name/Function VS voltage value R/W R [3:0] Reserved R Description This register contains the 12-bit VS± output voltage information. The range of the VS± input pins is from 0 V to 1.6 V. Each LSB corresponds to 390.625 μV. At 0 V input, the value in this register is 0. The nominal voltage at the VS+ and VS− pins is 1 V. At 1 V input, the value of these bits is 0xA00 (2560 decimal). The reading is equivalent to the READ_VOUT command. Reserved. Table 169. Register 0xFEAB—RTD Value Bits [15:4] Bit Name/Function RTD temperature value R/W R [3:0] Reserved R Description These bits contain the 12-bit RTD temperature information, as determined from the RTD pin. The range of the RTD input pin is from 0 V to 1.6 V. Each LSB corresponds to 390.625 μV. At 0 V input, the value in this register is 0. The nominal voltage at the RTD pin is 1 V. At 1 V input, the value of these bits is 0xA00 (2560 decimal). Reserved. Table 170. Register 0xFEAC—VF Value Bits [15:5] Bit Name/Function VF voltage value R/W R [4:0] Reserved R Description This register contains the 11-bit VF voltage information. The range of the VF input pin is from 0 V to 1.6 V. Each LSB corresponds to 781.25 μV. At 0 V input, the value in this register is 0. The nominal voltage at the VF pin is 1 V. At 1 V input, the value of these bits is 0x500 (1280 decimal). The reading is equivalent to the READ_VIN command. Reserved. Table 171. Register 0xFEAD—Duty Cycle Value Bits [15:12] [11:0] Bit Name/Function Reserved Duty cycle value R/W R R Description Reserved. This register contains the 12-bit duty cycle information. Each LSB corresponds to 0.0244% duty cycle. At 100% duty cycle, the value of these bits is 0xFFF (4095 decimal). Table 172. Register 0xFEAE—Input Power Value Bits [15:0] Bit Name/Function Input power value R/W R Description This register contains the 16-bit input power information. This value is the product of the input voltage value (VF) and input current value (CS1). The product of two 12-bit values is a 24-bit value, and the eight LSBs are discarded. Rev. A | Page 91 of 92 ADP1050 Data Sheet OUTLINE DIMENSIONS PIN 1 INDICATOR 4.10 4.00 SQ 3.90 0.30 0.25 0.20 0.50 BSC 20 16 15 PIN 1 INDICATOR 1 EXPOSED PAD 2.65 2.50 SQ 2.35 5 11 0.80 0.75 0.70 0.50 0.40 0.30 0.25 MIN BOTTOM VIEW 0.05 MAX 0.02 NOM COPLANARITY 0.08 0.20 REF SEATING PLANE 6 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-WGGD. 061609-B TOP VIEW 10 Figure 59. 20-Lead Lead Frame Chip Scale Package [LFCSP_WQ] 4 mm × 4 mm Body, Very Very Thin Quad (CP-20-10) Dimensions shown in millimeters ORDERING GUIDE Model 1 ADP1050ACPZ-RL ADP1050ACPZ-R7 ADP1051-240-EVALZ ADP1050DC1-EVALZ ADP-I2C-USB-Z 1 Temperature Range −40°C to +125°C −40°C to +125°C Package Description 20-Lead Lead Frame Chip Scale Package [LFCSP_WQ] 20-Lead Lead Frame Chip Scale Package [LFCSP_WQ] 240 W Evaluation Board for the ADP1051 and the ADP1050 ADP1050 Daughter Card USB to I2C Adapter Z = RoHS Compliant Part. I2C refers to a communications protocol originally developed by Philips Semiconductors (now NXP Semiconductors). ©2014 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D12039-0-6/14(A) Rev. A | Page 92 of 92 Package Option CP-20-10 CP-20-10