ZHCSFG4B July   2016  – November 2016 TPS546C23

PRODUCTION DATA.  

  1. 特性
  2. 应用范围
  3. 说明
  4. 修订历史记录
  5. Pin Configuration and Functions
  6. Specifications
    1. 6.1 Absolute Maximum Ratings
    2. 6.2 ESD Ratings
    3. 6.3 Recommended Operating Conditions
    4. 6.4 Thermal Information
    5. 6.5 Electrical Characteristics
    6. 6.6 Typical Characteristics
  7. Detailed Description
    1. 7.1 Overview
    2. 7.2 Functional Block Diagram
    3. 7.3 Feature Description
      1. 7.3.1  2-Phase Application
      2. 7.3.2  Linear Regulators BP3 and BP6
      3. 7.3.3  Input Undervoltage Lockout (UVLO)
      4. 7.3.4  Turnon and Turnoff Delay and Sequencing
      5. 7.3.5  Voltage Reference
      6. 7.3.6  Differential Remote Sense and Compensation
      7. 7.3.7  Set Output Voltage and Adaptive Voltage Scaling (AVS)
        1. 7.3.7.1 VOUT_COMMAND
        2. 7.3.7.2 VREF_TRIM
        3. 7.3.7.3 MARGIN
      8. 7.3.8  Reset VOUT
      9. 7.3.9  Switching Frequency and Synchronization
        1. 7.3.9.1 Synchronization
          1. 7.3.9.1.1 Stand-Alone Device
          2. 7.3.9.1.2 Master-Slave Configuration
          3. 7.3.9.1.3 SYNC Fault
      10. 7.3.10 Current Sharing
      11. 7.3.11 Soft-Start Time and TON_RISE Command
      12. 7.3.12 Prebiased Output Start-Up
      13. 7.3.13 Soft-Stop time and TOFF_FALL Command
      14. 7.3.14 Output Current Telemetry and Low-Side MOSFET Overcurrent Protection
        1. 7.3.14.1 Output Current Telemetry
        2. 7.3.14.2 Low-Side MOSFET Overcurrent Protection
        3. 7.3.14.3 Negative Overcurrent Protection
      15. 7.3.15 High-Side MOSFET Short-Circuit Protection
      16. 7.3.16 Die Temperature Telemetry and Overtemperature Protection
      17. 7.3.17 Output Voltage Telemetry and Over-/Under-voltage Protection
        1. 7.3.17.1 Output Voltage Telemetry
        2. 7.3.17.2 Output Overvoltage and Undervoltage Protection
      18. 7.3.18 TON_MAX Fault
      19. 7.3.19 Power Good (PGOOD) Indicator
      20. 7.3.20 Fault Protection Responses
      21. 7.3.21 Switching Node
      22. 7.3.22 PMBus General Description
      23. 7.3.23 PMBus Address
      24. 7.3.24 PMBus Connections
      25. 7.3.25 Auto ARA (Alert Response Address) Response
    4. 7.4 Device Functional Modes
      1. 7.4.1 Continuous Conduction Mode
      2. 7.4.2 Operation with CNTL Signal Control
      3. 7.4.3 Operation with OPERATION Control
      4. 7.4.4 Operation with CNTL and OPERATION Control
    5. 7.5 Programming
      1. 7.5.1 Supported PMBus Commands
    6. 7.6 Register Maps
      1. 7.6.1  OPERATION (01h)
        1. 7.6.1.1 On Bit
        2. 7.6.1.2 Off Bit
        3. 7.6.1.3 Margin Bit
      2. 7.6.2  ON_OFF_CONFIG (02h)
        1. 7.6.2.1 pu Bit
        2. 7.6.2.2 cmd Bit
        3. 7.6.2.3 cpr Bit
        4. 7.6.2.4 pol Bit
        5. 7.6.2.5 cpa Bit
      3. 7.6.3  CLEAR_FAULTS (03h)
      4. 7.6.4  WRITE_PROTECT (10h)
        1. 7.6.4.1 bit5
        2. 7.6.4.2 bit6
        3. 7.6.4.3 bit7
      5. 7.6.5  STORE_DEFAULT_ALL (11h)
      6. 7.6.6  RESTORE_DEFAULT_ALL (12h)
      7. 7.6.7  STORE_USER_ALL (11h)
      8. 7.6.8  RESTORE_USER_ALL (12h)
      9. 7.6.9  CAPABILITY (19h)
      10. 7.6.10 SMBALERT_MASK (1Bh)
      11. 7.6.11 VOUT_MODE (20h)
        1. 7.6.11.1 Mode Bit
        2. 7.6.11.2 Exponent Bit
      12. 7.6.12 VOUT_COMMAND (21h)
        1. 7.6.12.1 Exponent
        2. 7.6.12.2 Mantissa
      13. 7.6.13 VOUT_MAX (24h)
        1. 7.6.13.1 Exponent
        2. 7.6.13.2 Mantissa
      14. 7.6.14 VOUT_TRANSITION_RATE (27h)
        1. 7.6.14.1 Exponent
        2. 7.6.14.2 Mantissa
      15. 7.6.15 VOUT_SCALE_LOOP (29h)
        1. 7.6.15.1 Exponent
        2. 7.6.15.2 Mantissa
      16. 7.6.16 VOUT_MIN (2Bh)
        1. 7.6.16.1 Exponent
        2. 7.6.16.2 Mantissa
      17. 7.6.17 VIN_ON (35h)
        1. 7.6.17.1 Exponent
        2. 7.6.17.2 Mantissa
      18. 7.6.18 VIN_OFF (36h)
        1. 7.6.18.1 Exponent
        2. 7.6.18.2 Mantissa
      19. 7.6.19 IOUT_CAL_OFFSET (39h)
        1. 7.6.19.1 Exponent
        2. 7.6.19.2 Mantissa
      20. 7.6.20 VOUT_OV_FAULT_RESPONSE (41h)
        1. 7.6.20.1 RSP[1] Bit
        2. 7.6.20.2 RS[2:0] Bits
        3. 7.6.20.3 TD[2:0] Bits
      21. 7.6.21 VOUT_UV_FAULT_RESPONSE (45h)
        1. 7.6.21.1 RSP[1] Bit
        2. 7.6.21.2 RS[2:0] Bits
        3. 7.6.21.3 TD[2:0] Bits
      22. 7.6.22 IOUT_OC_FAULT_LIMIT (46h)
        1. 7.6.22.1 Exponent
        2. 7.6.22.2 Mantissa
      23. 7.6.23 IOUT_OC_FAULT_RESPONSE (47h)
        1. 7.6.23.1 RSP[1:0] Bits
        2. 7.6.23.2 RS[2:0] Bits
        3. 7.6.23.3 TD[2:0] Bits
      24. 7.6.24 IOUT_OC_WARN_LIMIT (4Ah)
        1. 7.6.24.1 Exponent
        2. 7.6.24.2 Mantissa
      25. 7.6.25 OT_FAULT_LIMIT (4Fh)
        1. 7.6.25.1 Exponent
        2. 7.6.25.2 Mantissa
      26. 7.6.26 OT_FAULT_RESPONSE (50h)
        1. 7.6.26.1 RSP[1] Bit
        2. 7.6.26.2 RS[2:0] Bits
        3. 7.6.26.3 TD[2:0] Bits
      27. 7.6.27 OT_WARN_LIMIT (51h)
        1. 7.6.27.1 Exponent
        2. 7.6.27.2 Mantissa
      28. 7.6.28 TON_DELAY (60h)
        1. 7.6.28.1 Exponent
        2. 7.6.28.2 Mantissa
      29. 7.6.29 TON_RISE (61h)
        1. 7.6.29.1 Exponent
        2. 7.6.29.2 Mantissa
      30. 7.6.30 TON_MAX_FAULT_LIMIT (62h)
        1. 7.6.30.1 Exponent
        2. 7.6.30.2 Mantissa
      31. 7.6.31 TON_MAX_FAULT_RESPONSE (63h)
        1. 7.6.31.1 RSP[1] Bit
        2. 7.6.31.2 RS[2:0] Bits
        3. 7.6.31.3 TD[2:0] Bits
      32. 7.6.32 TOFF_DELAY (64h)
        1. 7.6.32.1 Exponent
        2. 7.6.32.2 Mantissa
      33. 7.6.33 TOFF_FALL (65h)
        1. 7.6.33.1 Exponent
        2. 7.6.33.2 Mantissa
      34. 7.6.34 STATUS_BYTE (78h)
      35. 7.6.35 STATUS_WORD (79h)
      36. 7.6.36 STATUS_VOUT (7Ah)
      37. 7.6.37 STATUS_IOUT (7Bh)
      38. 7.6.38 STATUS_INPUT (7Ch)
      39. 7.6.39 STATUS_TEMPERATURE (7Dh)
      40. 7.6.40 STATUS_CML (7Eh)
      41. 7.6.41 STATUS_MFR_SPECIFIC (80h)
      42. 7.6.42 READ_VOUT (8Bh)
        1. 7.6.42.1 Exponent
        2. 7.6.42.2 Mantissa
      43. 7.6.43 READ_IOUT (8Ch)
        1. 7.6.43.1 Exponent
        2. 7.6.43.2 Mantissa
      44. 7.6.44 READ_TEMPERATURE_1 (8Dh)
        1. 7.6.44.1 Exponent
        2. 7.6.44.2 Mantissa
      45. 7.6.45 PMBUS_REVISION (98h)
      46. 7.6.46 IC_DEVICE_ID (ADh)
      47. 7.6.47 IC_DEVICE_REV (AEh)
      48. 7.6.48 MFR_SPECIFIC_00 (D0h)
      49. 7.6.49 VREF_TRIM (MFR_SPECIFIC_04) (D4h)
      50. 7.6.50 STEP_VREF_MARGIN_HIGH (MFR_SPECIFIC_05) (D5h)
      51. 7.6.51 STEP_VREF_MARGIN_LOW (MFR_SPECIFIC_06) (D6h)
      52. 7.6.52 PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h)
      53. 7.6.53 OPTIONS (MFR_SPECIFIC_21) (E5h)
        1. 7.6.53.1  DIS_NEGILIM Bit
        2. 7.6.53.2  EN_RESET_B Bit
        3. 7.6.53.3  EN_ADC_CNTL Bit
        4. 7.6.53.4  VSM Bit
        5. 7.6.53.5  DLO Bit
        6. 7.6.53.6  AVG_PROG[1:0] Bits
        7. 7.6.53.7  EN_AUTO_ARA Bit
        8. 7.6.53.8  READ_VOUT_RANGE[1:0] Bits
        9. 7.6.53.9  RST_VOUT_oSD Bit
        10. 7.6.53.10 RSMLO_VAL Bit
        11. 7.6.53.11 RSMHI_VAL Bit
      54. 7.6.54 MISC_CONFIG_OPTIONS (MFR_SPECIFIC_32) (F0h)
        1. 7.6.54.1 OV_RESP_SEL Bit
        2. 7.6.54.2 HSOC_USER_TRIM[1:0] Bits
        3. 7.6.54.3 EN_AVS_USER Bit
        4. 7.6.54.4 FORCE_SYNC_OUT Bit
        5. 7.6.54.5 FORCE_SYNC_IN Bit
        6. 7.6.54.6 SYNC_FAULT_DIS Bit
  8. Applications and Implementation
    1. 8.1 Application Information
    2. 8.2 Typical Application
      1. 8.2.1 4.5-V to 18-V Input, 1-V Typical Output, 35-A Converter
        1. 8.2.1.1 Design Requirements
        2. 8.2.1.2 Detailed Design Procedure
          1. 8.2.1.2.1  Switching Frequency Selection
          2. 8.2.1.2.2  Inductor Selection
          3. 8.2.1.2.3  Output Capacitor Selection
          4. 8.2.1.2.4  Output Voltage Deviation During Load Transient
          5. 8.2.1.2.5  Output Voltage Ripple
          6. 8.2.1.2.6  Input Capacitor Selection
          7. 8.2.1.2.7  AVIN, BP6, BP3 Bypass Capacitor
          8. 8.2.1.2.8  Bootstrap Capacitor Selection
          9. 8.2.1.2.9  R-C Snubber
          10. 8.2.1.2.10 Output Voltage Setting and Frequency Compensation Selection
          11. 8.2.1.2.11 Key PMBus Parameter Selection
          12. 8.2.1.2.12 Enable, UVLO
          13. 8.2.1.2.13 Soft-Start Time
          14. 8.2.1.2.14 Overcurrent Threshold and Response
        3. 8.2.1.3 Application Curves
  9. Power Supply Recommendations
  10. 10Layout
    1. 10.1 Layout Guidelines
    2. 10.2 Layout Example
    3. 10.3 Mounting and Thermal Profile Recommendation
  11. 11器件和文档支持
    1. 11.1 开发支持
      1. 11.1.1 德州仪器 (TI) Fusion Digital Power Designer
      2. 11.1.2 WEBENCH® 工具
    2. 11.2 接收文档更新通知
    3. 11.3 社区资源
    4. 11.4 商标
    5. 11.5 静电放电警告
    6. 11.6 Glossary
  12. 12机械、封装和可订购信息

封装选项

机械数据 (封装 | 引脚)
散热焊盘机械数据 (封装 | 引脚)
订购信息

7 Detailed Description

7.1 Overview

The devices are PMBus 1.3 compliant 35-A, high-performance, synchronous buck converters with two integrated N-channel NexFET™ power MOSFETs, enabling high-power density and minimal PCB area. These devices implement the industry-standard fixed switching frequency, voltage-mode control with input feed-forward topology that responds instantly to input voltage change. These devices can be synchronized to the external clock to eliminate beat noise and reduce EMI and EMC. Monotonic prebias capability eliminates concerns about damaging sensitive loads. Two devices can be paralleled together to provide up to 70-A load. Current sensing for overcurrent protection, current reporting and current sharing between two devices are implemented by sampling a small portion of the power stage current which provides accurate information independent on the device temperature. The integrated PMBus interface capability provides precise current, voltage, and internal die-temperature monitoring, as well as many user-programmable configuration options including Adaptive Voltage Scaling (AVS) function through standard VOUT_COMMAND on the PMBus.

7.2 Functional Block Diagram

TPS546C23 fbd_sluscc7.gif

7.3 Feature Description

7.3.1 2-Phase Application

Figure 23 shows the setup for a 2-phase application using two devices.

TPS546C23 Application_C23_Stack.gif Figure 23. 2-Phase Application

7.3.2 Linear Regulators BP3 and BP6

The devices have two onboard linear regulators to provide suitable power for the internal circuitry of the device. Bypass the BP3 and BP6 pins externally for the converter to function properly. The BP3 pin requires a minimum of 2.2 µF of capacitance connected to AGND. The BP6 pin requires a minimum 2.2 µF of capacitance connected to PGND. TI recommends using a 4.7-µF capacitor and an additional 100-nF capacitor to reduce the ripple on the BP6 pin.

NOTE

Place bypass capacitors as close as possible to the device pins, with a minimum return loop back to ground and the return loop should be kept away from fast switching voltage and main current path. For more information, see the Layout section. Poor bypassing can degrade the performance of the regulator.

The use of the internal regulators to power other circuits is not recommended because the loads placed on the regulators might adversely affect operation of the controller.

7.3.3 Input Undervoltage Lockout (UVLO)

The devices provide flexible user adjustment of the undervoltage lockout (UVLO) threshold and hysteresis. Two PMBus commands, VIN_ON (35h) and VIN_OFF (36h), allow the user to independently set turnon and turnoff thresholds of these input voltages, with a minimum of 4-V turnoff to a maximum 7.75-V turnon. For more information, see Table 4.

7.3.4 Turnon and Turnoff Delay and Sequencing

The devices provide many sequencing options. Using the ON_OFF_CONFIG command, the device can be configured to start up whenever the input voltage is above the UVLO threshold, to require an additional signal on the CNTL pin, to receive an update to the OPERATION command through the PMBus interface, or a combination of these configurations. When the gating signal as specified by the ON_OFF_CONFIG command is asserted, a programmable turnon delay can be set with the TON_DELAY command to delay the start of regulation. Similarly, a programmable turnoff delay can be set with the TOFF_DELAY command to delay the stop of regulation once the gating signal is deasserted. Delay times are specified in milliseconds (ms), from 0 to 100 ms.

Figure 24 shows control of the start-up and shutdown operations of the device when the device is configured to respond to both the CNTL signal and the OPERATION command. The device can also be configured to independently use either the CNTL signal or the OPERATION command, or to convert power when a sufficient input voltage is available.

TPS546C23 op_ctrl_wave_slusc81.gif Figure 24. Turnon Controlled by Both Operation(1) and Control Bit 7 of OPERATION is used to control power conversion.
1. Bit 7 of OPERATION is used to control power conversion.

7.3.5 Voltage Reference

A reference digital-to-analog converter (DAC) with a 350-mV to 1650-mV range and 2–9-V (1.953 mV) resolution connects to the noninverting input of the error amplifier. The tight tolerance on the reference voltage allows the user to design power supply with very-high DC accuracy.

7.3.6 Differential Remote Sense and Compensation

The devices implement a differential remote-sense amplifier to provide excellent load regulation by cancelling IR-drop in high-current applications. The RSP and RSN pins should be kelvin-connected to the output capacitor bank directly at the load, and routed back to the device as a tightly coupled differential pair. Ensure that these traces are isolated from fast switching signals and high current paths on the final PCB layout, as these can add differential-mode noise. Optionally, use a small coupling capacitor (1-nF typical) between the RSP and RSN pins to improve noise immunity. The output of the differential remote sense amplifier (DIFFO) is used for output voltage setting and error amplifier frequency compensation local to the device as shown in Figure 25.

The devices use voltage mode control with input feedforward. Frequency compensation can be accomplished using standard Type III techniques as shown in Figure 25.

In 2-phase configuration, the FB pin of the loop slave device should be tied to BP3 and the typical application circuit is shown in Figure 23. The loop master passes the internal COMP voltage through VSHARE pin to the loop slave device. For more information, see the Current Sharing section.

Additionally, the voltage at the DIFFO pin is digitized, averaged to reduce measurement noise and continually stored in the READ_VOUT command, enabling output voltage telemetry.

TPS546C23 output_voltage_setting_tps546c23.gif Figure 25. Output Voltage Setting

7.3.7 Set Output Voltage and Adaptive Voltage Scaling (AVS)

A voltage divider from the DIFFO pin to the FB pin is typically required to set the nominal output voltage like the one formed by R1 and RBIAS resistors shown in Figure 25 and the resulted output voltage is shown in Equation 1.

Equation 1. VOUT = EA_REF × (RBIAS + R1) / RBIAS

7.3.7.1 VOUT_COMMAND

To allow PMBus devices to map between the nominal commanded voltage and the voltage at the control circuit input FB (VOUT divided down to match the reference voltage EA_REF), the device uses the
VOUT_SCALE_LOOP command.

Equation 2. VOUT_SCALE_LOOP = RBIAS / (RBIAS + R1)

Table 1 lists the range of valid VOUT_COMMAND values which are dependent upon the configured
VOUT_SCALE_LOOP (29h) command.

Table 1. FB Resistor Divider Ratio and VOUT_COMMAND Data Valid Range

VOUT_SCALE_LOOP RESISTOR DIVIDER
RBIAS: R1
(IN Figure 25)		 OUTPUT VOLTAGE RANGE (V) VOUT_COMMAND
DATA VALID RANGE
MIN MAX MIN MAX
1 Unnecessary 0.35 1.65 179 845
0.5 1:1 0.7 3.3 358 1690
0.25 1:3 1.4 5.5 716 2816

If the value programmed to VOUT_COMMAND exceeds the value stored in either VOUT_MIN or VOUT_MAX. In this case, VOUT_COMMAND will be set to the appropriate VOUT_MIN or VOUT_MAX value (which ever was violated). For the specific status bits set in either case, see the command descriptions for the VOUT_MIN (28h) or VOUT_MAX (24h) command.

7.3.7.2 VREF_TRIM

The nominal output voltage of the converter can also be adjusted by changing the feedback voltage, VFB, using the VREF_TRIM command. The adjustment range is from –64 × 1.953 mV to +63 × 1.953 mV from the nominal FB voltage. This command adjusts the final output voltage of the converter to a high degree of accuracy without relying on high-precision feedback resistors. The resolution of the adjustment is approximately 1.953 mV.

7.3.7.3 MARGIN

The devices also allow simple testing of the output-voltage margin, by applying a either a positive or negative offset to the feedback voltage. The STEP_VREF_MARGIN_HIGH (MFR_SPECIFIC_05) (D5h) and STEP_VREF_MARGIN_LOW (MFR_SPECIFIC_06) (D6h) commands control the size of the applied high offset or low offset (respectively). The adjustment range is from –64 × 1.953 mV to 31 × 1.953 mV from the nominal feedback voltage. The OPERATION command toggles the converter between the following three states:

  • Margin none (no output margining)
  • Margin high
  • Margin low

Use Equation 3 to calculate the resulted internal-reference voltage.

Equation 3. EA_REF = [(VOUT_COMMAND × VOUT_SCALE_LOOP) + (VREF_TRIM + STEP_VREF_MARGIN_HIGH × OPERATION[5] + STEP_VREF_MARGIN_LOW × OPERATION[4])] × 1.953 mV

The total adjustable range of the output voltage, including VOUT_COMMAND, MARGIN, and VREF_TRIM, is limited by the internal reference DAC of 0.35 V – 1.65 V . For more information on the implementation, see the Supported PMBus Commands section.

NOTE

  • The VOUT_SCALE_LOOP is limited to only 3 possible options: 1 (default, no bottom resistor required for the divider), 0.5, and 0.25.
  • When VOUT_SCALE_LOOP is set to 1 (default), no bottom RBIAS resistor is required. The reference voltage is equal to the output voltage, which allows tighter system DC accuracy by removing the resistor divider tolerance.
  • If the divider ratio, RBIAS / (RBIAS + R1), does not match the programed
    VOUT_SCALE_LOOP, the user should be aware that the actual output voltage determined by Equation 1 and Equation 3 may not match the programed VOUT_COMMAND.

7.3.8 Reset VOUT

Without power cycling, the VOUT_COMMAND value and the corresponding output voltage can be reset to the default value which is latched when the devices are powered up from AVIN. When the RESET/PGD pin is pulled low, the digital core sets the VOUT_COMMAND value to the default value. Figure 26 shows the timing diagram for resetting the output voltage. When theRESET/PGD pin is asserted low, after a short delay (less than 2 µs), the output voltage begins to transition from the current value to the default VOUT_COMMAND value according to the slew-rate set in the VOUT_TRANSITION_RATE command. The VOUT_COMMAND value does not change to any values programmed in the VOUT_COMMAND register while the RESET/PGD pin is held low. The reset_vout status bit in the STATUS_MFR_SPECIFIC (80h) register is set for indication.

In the case of fault restart, the user has access to allow the VOUT_COMMAND value to be reset to the initial boot-up voltage by setting the RST_VOUT_oSD Bit in the OPTIONS (MFR_SPECIFIC_21) (E5h) register.

TPS546C23 reset_delay_tps546c23.gif
A. VOUT_COMMAND adjustment occurs through the PMBus interface.
B. Reset to the default VOUT_COMMAND value which is latched when the devices are powered up from AVIN. The slew rate is defined by the VOUT_TRANSITION_RATE comand.
Figure 26. Output Voltage Reset

7.3.9 Switching Frequency and Synchronization

A resistor from the RT pin (RRT) to AGND sets the switching frequency. Use Equation 4 to calculate the RRT resistor value.

Equation 4. TPS546C23 eq_SLVSCC5_rt.gif

where

  • RRT is the timing resistor in Ohms
  • fSW is the switching frequency in Hertz

The devices are designed to operate from 200 kHz to 1 MHz.

7.3.9.1 Synchronization

The devices can synchronize to an external clock that is ±20% of the free-running frequency.

7.3.9.1.1 Stand-Alone Device

The device supports auto detection on the SYNC pin of the stand-alone device or the PWM-loop master device in a 2-phase configuration. With the external clock applied to the SYNC pin before AVIN power-up or pulling up the SYNC pin to the BP3 or BP6 pin, the SYNC pin is configured as SYNC-IN, and is synchronized to the rising edge of the external clock applied to this pin, with a minimum pulse width of 200 ns (maximum). If no external clock edges occur or logic-high voltage is applied to the SYNC pin at AVIN power-up, the SYNC pin is configured as SYNC-OUT, and the internal free-running frequency set by the RT resistor is output on the SYNC pin. A sudden change in synchronization clock frequency causes an associated control-loop response, resulting in an overshoot or undershoot on the output voltage.

7.3.9.1.2 Master-Slave Configuration

Without the requirement of an external clock, the SYNC pin of the PWM-loop master device can be configured as SYNC-OUT and output a 50% duty-cycle clock to the slave device. The slave device is then synchronized to the falling edge of the clock applied to the SYNC pin. Both the loop master and slave devices require an RT resistor to set the free-running frequency. Figure 27 shows the simplified schematic for this configuration. For the loop slave device in a 2-phase configuration, the SYNC pin is always configured as SYNC-IN, and is synchronized to the falling edge of the incoming clock on the SYNC pin. Figure 28 shows the timing for phase interleaving.

TPS546C23 sync1_schem_slusc64.gif Figure 27. Master-Slave Synchronization and Phase Interleaving Setting
TPS546C23 sync1_wave_slusc64.gif Figure 28. Phase Interleaving Timing

An external clock can optionally be applied to both the PWM-loop master and the slave device to synchronize the stack. Only 50% duty cycle of the external clock can be applied to the 2-phase stack to realize the interleaving of two phases. The loop master automatically (auto) detects if an external clock is available for synchronisation. One clock master can also sync another stack as shown in Figure 29. When the auto detection determines the clock master and clock slave, the configuration cannot change until AVIN power cycling.

The EEPROM setup (FORCE_SYNC_IN Bit and FORCE_SYNC_OUT Bit) overrides auto detection of the SYNC pin. Therefore, if the FORCE_SYNC_OUT Bit is set to 1, the user should not apply the external clock to SYNC pin, which may cause catastrophic damage to the device. The FORCE_SYNC_IN Bit has higher priority than the FORCE_SYNC_OUT Bit. Neither the FORCE_SYNC_IN Bit nor the FORCE_SYNC_OUT Bit are set as a factory-default setting.

TPS546C23 sync2_schem_slusc64.gif Figure 29. Phase Interleaving Timing

7.3.9.1.3 SYNC Fault

The converter is allowed to stop switching after detecting the SYNC signal is expected, but not present or has been lost. The device also reports a live (essentially unlatched) sync_flt bit in the STATUS_MFR_SPECIFIC (80h) register. The SMBALERT is not triggered if the SYNC_FAULT bit goes high. The default SYNC fault response is as follows.

  • For the case of a clock that is lost after it was previously present, the SYNC-loss detection latency is approximately 10 µs. During this delay time (between when the clock is lost to when the controller detects it), the clock slave (loop slave or loop master set as clock slave) continues to operate at a frequency that is approximately 40% less than the free-running frequency. The frequencies of two devices are most likely not identical during this 10-µs duration. The clock master continues to operate at the free-running frequency during the 10-µs duration.
  • For the case of a clock signal that is never present, both phases (for 2-phase) or the standalone PWM-loop master (1-phase) remain off (never switch) while waiting for the external clock to arrive.
After the external clock is restored, seven clock cycles are counted and then the rail performs a new soft-start. No further user intervention (for example, power-cycle, CNTL toggle, CLEAR_FAULTS, or others) is required for the rail to start up after clock restoration

NOTE

The SYNC fault response can be disabled by setting the SYNC_FAULT_DIS Bit in the MISC_CONFIG_OPTIONS (MFR_SPECIFIC_32) (F0h) register. The SYNC_FAULT_DIS Bit, when set, disables the sync_flt reporting status, and the devices that lost the SYNC clock input (loop slave or loop master set clock slave) continue to operate at a frequency approximately 40% less than the free-running frequency for approximately 10 µs, then back to the free-running frequency without shutting down. But the frequencies of two devices are most likely not identical because the clock master continues to operate at its own free-running frequency.

7.3.10 Current Sharing

For two devices to operate in a 2-phase application, the SYNC, VSHARE, and ISHARE pins of both devices should be connected respectively, as shown in Figure 30. The loop master device shares the same VSHARE voltage. Essentially the internal COMP voltage is shared with the loop slave by connecting the VSHARE pin of each device together. The sensed current in each phase is compared first by connecting the ISHARE pin of each device, then the error current is added into the internal COMP. The resulting voltage is compared with the PWM ramp to generate the PWM pulse. This current sharing loop maintains the current balance between devices.

An additional resistor connected between the ISHARE pins of both devices can be used to lower the current-sharing loop gain for better stability margin. Use to calculate the current sharing gain (GISHARE).

GISHARE = 19.5 × 10 kΩ / (10 kΩ + RSHARE) mV/A
TPS546C23 current_share_schem.gif Figure 30. Current Sharing

In addition to sharing the same internal COMP voltage, the VSHARE pin is also used for fault communication between the loop master and slave devices. The VSHARE pin voltage is pulled low if any device encounters any fault conditions so that the other device sharing VSHARE pin is alerted and stops switching accordingly.

An optional high-frequency capacitor can be added between the VSHARE pin and ground in noisy systems, but the capacitance should not exceed 10 pF.

7.3.11 Soft-Start Time and TON_RISE Command

To control the inrush current required to charge the output capacitor bank during start up, the devices implement a soft-start time. When the device is enabled, the feedback reference voltage, VREF, ramps from 0 V to the final level defined by Equation 3 at a slew rate defined by the TON_RISE command. The specified rise times are defined by the slew rate required to ramp the reference voltage from 0 V to the final value at each given rise time.

The actual rise time of the converter output is slightly less than the rise time defined by the TON_RISE command. This difference occurs because switching does not occur until the error-amplifier output reaches the valley of the PWM ramp. During the soft-start time, the error-amplifier output voltage starts at 0 V and then begins switching again only when the VSHARE voltage reaches the valley of the PWM ramp which is 1.23 V (typical). When the VSHARE voltage reaches the valley of the PWM ramp, the converter output voltage rises quickly until the feedback voltage, VFB, reaches the VREF level, at which point they track through the end of the soft-start period.

TPS546C23 ss_timing_tps546c23.gif Figure 31. Soft-Start Timing

The devices support several soft-start times from 1 ms to 100 ms which are selected by the TON_RISE command.

7.3.12 Prebiased Output Start-Up

The devices prevent current from being discharged from the output during start-up, when a prebiased output condition exists. If the output is prebiased, no SW pulses occur until the internal soft-start voltage rises above the error-amplifier input voltage (FB pin). As soon as the soft-start voltage exceeds the error-amplifier input, and SW pulses start and the device limits synchronous rectification after each SW pulse with a narrow on-time. The on-time of the low-side MOSFET slowly increases on a cycle-by-cycle basis until 128 pulses have been generated and the synchronous rectifier runs fully complementary to the high-side MOSFET. This approach prevents the sinking of current from a prebiased output, and ensures the output-voltage start-up and ramp-to-regulation sequences are smooth and monotonic.

For prebias that is higher than regulation, the PWM-loop master device is forced to go through the 128 cycles of prebias operation at the end of TON_RISE time.

The output overvoltage warn is tripped when the FB pin is prebiased to higher than 5% about the regulation level. These devices respond to a prebiased output overvoltage condition immediately upon AVIN powered up and when the BP6 regulator voltage is above the BP6 UVLO of 3.73 V (typical).

7.3.13 Soft-Stop time and TOFF_FALL Command

The devices implement the TOFF_FALL command to define the time for the output voltage to drop from regulation to 0 as shown in Figure 24. Negative current in the devices can occur during the TOFF_FALL time to discharge the output voltage. The setting of the TOFF_FALL command to 0 ms causes the unit to bring the output voltage down to 0 as quickly as possible, which results in an effective TOFF_FALL time of 1 ms (fastest time supported). This feature can be disabled in the ON_OFF_CONFIG command for the turnoff controlled by the CNTL pin or bit 6 of the OPERATION register if the regulator is turned off by the OPERATION command. If the regulator is turned off by the OPERATION command, both the high-side and low-side FET drivers are turned off immediately and the output voltage is discharged by the load.

7.3.14 Output Current Telemetry and Low-Side MOSFET Overcurrent Protection

7.3.14.1 Output Current Telemetry

The devices sense the average output current using an internal sense FET as shown in Figure 32. A sense FET conducts a scaled-down version of the power-stage current. Sampling this current in the middle of the low-side drive signal determines the average output current. This architecture achieves excellent current monitoring and better overcurrent threshold accuracy than the current sensing of a DC-resistance (DCR) inductor with minimal temperature variation and no dependence on power loss in a higher DCR inductor. Use the IOUT_CAL_OFFSET command to improve current sensing and overcurrent accuracy by removing systematic errors related to board layout after assembly. The devices continually digitize the sensed output current, and average it to reduce measurement noise. The devices then store the current value in the read-only register, READ_IOUT, which enables output-current telemetry.

TPS546C23 sense_fet_avg_isense_tps546c23.gif Figure 32. SenseFET Average Current Sensing and Overcurrent Protection

7.3.14.2 Low-Side MOSFET Overcurrent Protection

The devices implement low-side MOSFET overcurrent protection with programmable fault and warning thresholds. The IOUT_OC_FAULT_LIMIT and IOUT_OC_WARN_LIMIT commands set the low-side overcurrent thresholds.

If an overcurrent event is detected in a given switching cycle, the device increments an overcurrent counter as shown in Figure 32. When the device detects three consecutive overcurrent events (either high-side or low-side), the converter responds by flagging the appropriate status registers, triggering the SMBALERT signal if it is not masked, and entering either continuous-restart-hiccup mode or latches off according to the IOUT_OC_FAULT_RESPONSE command. In continuous-restart-hiccup mode, the devices implement a seven TON_RISE time, followed by a normal soft-start attempt. When the overcurrent fault clears, normal operation resumes, otherwise, the device detects overcurrent and the process repeats. The IOUT_OC_FAULT_RESPONSE command can also be set to ignore the OC fault for debugging purposes. Table 2 summarizes the fault-response scheme.

7.3.14.3 Negative Overcurrent Protection

The devices also implement low-side MOSFET Rds,on based negative overcurrent protection. After detecting negative current (sinking from SW to PGND) beyond the negative OC limit, the low-side MOSFET gate drive will be turned off immediately. The low-side gate drive signal will always be turned on for the duration of the minimum off-time in Specifications to re-detect negative OC condition. If negative OC condition persists, the next low-side gate drive pulse will be skipped, except at the end of the clock period, where the low-side gate drive still being turned on for the minimum off-time. This is a cycle-by-cycle clamp. Set the DIS_NEGILIM bit in OPTIONS (MFR_SPECIFIC_21) can disable negative OC protection. The output Overvoltge proteciton has higher priority than negative OC protection, in other words, in case of output Overvoltage condition persists, the low-side FET will be turned on with the negative OC protection being ignored in order to discharge the output voltage and protect the load equipment.

7.3.15 High-Side MOSFET Short-Circuit Protection

The devices also implement a fixed high-side MOSFET overcurrent (HSOC) protection to limit peak current, and prevent inductor saturation in the event of a short circuit. The devices detect an overcurrent event by sensing the voltage drop across the high-side MOSFET when it is on. If the peak current reaches the IHOSC level on any given cycle, the cycle terminates to prevent the current from increasing any further. High-side MOSFET overcurrent events are counted using the method shown in Figure 32. If the devices detect three consecutive overcurrent events (high-side or low-side), the converter responds by flagging the appropriate status registers, triggering the SMBALERT signal if it is not masked, and entering either continuous-restart-hiccup mode or latches off according to the IOUT_OC_FAULT_RESPONSE command. For accurate overcurrent protection for the high-side MOSFET, the PVIN and AVIN pins must have the same potential because split-rail operation is not supported. The IOUT_OC_FAULT_RESPONSE command can also be set to ignore the OC fault for debugging purposes. When the IOUT_OC_FAULT_RESPONSE command is set to ignore, the device continues to have cycle-by-cycle HSOC protection. Table 2 summarizes the fault-response scheme.

7.3.16 Die Temperature Telemetry and Overtemperature Protection

An internal temperature sensor based off the bandgap reference protects the devices from thermal runaway. The internal thermal shutdown threshold, TSD, is fixed at 145°C (typical). When the devices sense a temperature above TSD, an otf_bg bit in the STATUS_MFR_SPECIFIC command is flagged, and power conversion stops until the sensed junction temperature decreases by the amount of the thermal shutdown hysteresis, THYST (20°C typical). The SMBALERT signal is triggered if it is not masked.

The devices also provide temperature telemetry and programmable internal overtemperature fault or warning thresholds using measurements from an internal temperature sensor as shown in Figure 33. The temperature-sensor circuit applies two bias currents to an internal diode-connected NPN transistor, and measures ΔVBE to infer the junction temperature of the sensor. The devices then digitize the result and compare it to the user-configured overtemperature fault and warning thresholds. When an internal overtemperature fault (OTF) is detected, power conversion stops until the sensed temperature decreases by 20°C. The READ_TEMPERATURE_1 (8Dh) register is continually updated with the digitized temperature measurement, enabling temperature telemetry. The OT_FAULT_LIMIT (4Fh) and OT_WARN_LIMIT (51h) commands set the overtemperature fault and warning thresholds through the PMBus interface. When an overtemperature event is detected, the device sets the appropriate flags in STATUS_TEMPERATURE (7Dh) command and triggers the SMBALERT signal if it is not masked.

The device response upon internal overtemperature fault can be set to Latch-off, Restart and Ignore in OT_FAULT_RESPONSE. The default response to an over temperature fault is to ignore. Fixed band gap-detected overtemperature (OT) faults are never ignored. The band gap OT faults always respond in a shutdown and attempted restart once the part cools. Table 2 summarizes the fault-response scheme.

TPS546C23 temp_sense_tps546c23.gif Figure 33. Overtemperature Protection

7.3.17 Output Voltage Telemetry and Over-/Under-voltage Protection

7.3.17.1 Output Voltage Telemetry

The output voltage is sensed at the remote sense amplifier output pin, and the device continually digitizes the sensed output voltage, and average it to reduce measurement noise. The devices then store the current value in the read-only register, READ_VOUT, which enables output voltage telemetry. Please refer to OPTIONS (MFR_SPECIFIC_21) for details of programming output voltage telemetry signal range, averaging and update rate.

7.3.17.2 Output Overvoltage and Undervoltage Protection

The devices include both output overvoltage protection and output undervoltage protection capability by comparing the FB pin voltage to internal selectable pre-set voltages, as defined by the
PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) command.

If the FB pin voltage rises above the output overvoltage protection threshold, the device terminates normal switching and turns on the low-side MOSFET to discharge the output capacitor and prevent further increases in the output voltage. The device also declares an OV fault, flagging the appropriate status registers, triggering SMBALERT if it is not masked. Then the device enters continuous-restart-hiccup mode or latches off according to the VOUT_OV_FAULT_RESPONSE command. The devices respond to the output Overvoltage condition immediately upon AVIN powered up and BP6 regulator voltage above its own UVLO of 3.73 V (typical). The VOUT_OV_FAULT_RESPONSE can also be set to ignore the output overvotlage fault and continue without interruption. Under this configuration, the control loop continues to respond and adjust PWM duty cycle to keep output voltage within regulation.

If the FB pin voltage falls below the Undervoltage protection level after soft-start has completed, the device terminates normal switching and forces both the high-side and low-side MOSFETs off, and awaits an external reset or begins a hiccup time-out delay prior to restart, depending on the value of the VOUT_UV_FAULT_RESPONSE command. The device also declares a UV fault by flagging the appropriate status registers and triggering SMBALERT if it is not masked. The VOUT_UV_FAULT_RESPONSE can also be set to ignore the output undervoltage fault and continue without interruption for debug purpose.

The devices also provide FB referred fixed threshold (2.2 V typical) output overvoltage protection.

Table 2 summarizes the fault-response scheme.

7.3.18 TON_MAX Fault

The TON_MAX_FAULT_LIMIT command sets an upper limit, in milliseconds, on how long the unit can attempt to power up the output without reaching the output undervoltage fault limit. The devices differentiate a startup UV fault and a regulation UV fault by implementing the TON_MAX_FAULT_LIMIT command. The TON_MAX_FAULT_LIMIT command can allow the devices more time than the soft-start time defined by TON_RISE to come into regulation and the UV detection is essentially delayed up to the TON_MAX_FAULT_LIMIT time. For more details, see the TON_MAX_FAULT_LIMIT (62h) section.

7.3.19 Power Good (PGOOD) Indicator

When the output voltage remains within the PGOOD window after the start-up period, PGOOD as an open-drain output is released, and rises to an externally supplied logic level. The PGOOD window is defined by OV warning limit and UV warning limit in PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h), which can be programmed through the PMBus interface, as shown in Figure 34. The PGOOD pin pulls low upon any fault condition on default. Please refer to Table 2 for the possible sources to pull down the PGOOD pin.

The PGOOD signal can be connected to the CNTL pin of another device to provide additional controlled turnon and turnoff sequencing.

The OVW or PGOOD signal trips when the FB pin is prebiased to higher than 5% about the regulation level. This level of prebias is unusual and it is beneficial to flag a warning in this situation.

TPS546C23 pgood_waveform_tps546c23.gif Figure 34. PGOOD Threshold and Hysteresis

NOTE

Pulling PGOOD pin high before the devices gets input power could cause PGOOD pin going high due to the limited pulldown capability in un-powered condition. If this is not desired, increase the pullup resistance or reduce the external pullup supply voltage.

7.3.20 Fault Protection Responses

Table 2 summarizes the various fault protections and associated responses.

Table 2. Fault Protection Summary

FAULT or WARN PROGRAMMING FAULT RESPONSE SETTING FET BEHAVIOR ACTIVE DURING TON_RISE SOURCE OF SMBALERT SMBALERT MASKABLE PGOOD
Internal Over Temp Fault OT_FAULT_LIMIT (4Fh) Latch-off Both FETs off Yes Yes Yes Low
Restart Both FETs off, then restart after cooling down(1) Low
Ignore FETs still controlled by PWM High
Internal Over Temp Warn OT_WARN_LIMIT (51h) Latch-off or Restart on Fault PWM maintains control of FETs Yes Yes Yes Low
Ignore Fault High
Bandgap Over Temp Fault Threshold fixed internally Latch-off Both FETs off Yes Yes Yes Low
Restart Both FETs off, then restart after cooling down(1)
Ignore Both FETs off, then restart after cooling down(2)
Low-Side OC Fault IOUT_OC_FAULT_LIMIT (46h) Latch-off 3 PWM counts, then both FETs off Yes Yes Yes Low
Restart 3 PWM counts, then both FETs off, restart after 7×TON_RISE Low
Ignore FETs still controlled by PWM High
Low-Side OC Warn IOUT_OC_WARN_LIMIT Latch-off or Restart on Fault PWM maintains control of FETs Yes Yes Yes Low
Ignore Fault High
High-Side OC Fault Latch-off 3 PWM counts, then both FETs off Yes Yes Yes Low
Restart 3 PWM counts, then both FETs off, restart after 7 × TON_RISE Low
Ignore Cycle-by-cycle peak current limit High
VOUT OV Fault PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) Latch-off High-side FET OFF, low-side FET response configured byOV_RESP_SEL Bit: latch ON or turn on till FB drops below 0.2 V Yes Yes Yes Low
Restart High-side FET OFF, low-side FET response configured byOV_RESP_SEL Bit: latch ON or turn on till FB drops below 0.2 V. Then restart after 7 × TON_RISE
Ignore PWM maintains control of FETs
VOUT OV Warn PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) Latch-off or Restart on Fault PWM maintains control of FETs Yes Yes Yes Low
Ignore Fault
VOUT UV Fault PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) Latch-off Both FETs off No Yes Yes Low
Restart Both FETs off, then restart after 7×TON_RISE
Ignore PWM maintains control of FETs
VOUT UV Warn PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) Latch-off or Restart on Fault PWM maintains control of FETs No Yes Yes Low
Ignore Fault
TON Max Fault TON_MAX_FAULT_LIMIT Latch-off Both FETs off No Yes Yes Low
Restart Both FETs off, then restart after 7×TON_RISE
Ignore PWM maintains control of FETs
VIN UVLO VIN_ON, VIN_OFF Shut down Both FETs off Yes Yes Yes Low
(1) When the overtemperature fault is tripped, the device shuts off both FETs and restarts until the sensed temperature decreases 20°C from the tripping threshold.
(2) The bandgap overtemperature Fault cannot be ignored, the device shuts off both FETs and restarts after the internal die temperature drops below the threshold.

NOTE

The best practice is to have the fault response of the loop master and slave device set as the same to avoid unexpected behavior.

7.3.21 Switching Node

The SW pin connects to the switching node of the power-conversion stage and acts as the return path for the high-side gate driver. When configured as a synchronous buck stage, the voltage swing on SW normally traverses from below ground to well above the input voltage. Parasitic inductance in the high-side FET and the output capacitance (COSS) of both power FETs form a resonant circuit that can produce high frequency ( > 100 MHz) ringing on this node. The voltage peak of this ringing, if not controlled, can be significantly higher than the input voltage. Ensure that the peak ringing amplitude does not exceed the absolute maximum rating limit for the pin.

In many cases, a series resistor and capacitor snubber network connected from the switching node to PGND can be helpful in damping the ringing and decreasing the peak amplitude. Provide provisions for snubber network components in the layout of the printed circuit board. If testing reveals that the ringing amplitude at the SW pin exceeds the limit, then include snubber components. For more information about snubber circuits design, refer to Snubber Circuits: Theory, Design and Application (SLUP100).

Placing a BOOT resistor in series with the BOOT capacitor slows down the turnon of the high-side FET and can help to reduce the peak ringing at the switching node as well.

7.3.22 PMBus General Description

Timing and electrical characteristics of the PMBus interface specification can be found in the PMB Power Management Protocol Specification, Part 1, revision 1.3 available at http://pmbus.org. The devices support both the 100-kHz and 400-kHz bus timing requirements. The devices do not stretch pulses when communicating with the master device.

Communication over the PMBus interface can support the Packet Error Checking (PEC) scheme if desired. If the master supplies clock (CLK pin) pulses for the PEC byte, PEC is used. If the CLK pulses are not present before a STOP, the PEC is not used.

The devices support a subset of the commands in the PMBus 1.3 Power Management Protocol Specification. See Supported PMBus Commands for more information

The devices also support the SMBALERT response protocol. The SMBALERT response protocol is a mechanism by which a slave device (such as the devices ) can alert the bus master that it is available for communication. The master processes this event and simultaneously accesses all slaves on the bus (that support the protocol) through the alert response address (ARA). Only the slave that caused the alert acknowledges this request. The host performs a modified receive byte operation to ascertain the slave address. At this point, the master can use the PMBus status commands to query the slave that caused the alert. By default these devices implement the auto alert response, a manufacturer specific improvement to the SMBALERT response protocol, intended to mitigate the issue of bus hogging. For more information, see the Auto ARA Response section. For more information on the SMBus alert response protocol, refer to the System Management Bus (SMBus) specification.

The devices contain nonvolatile memory that stores configuration settings and scale factors. However, the device does not save the settings programmed into this nonvolatile memory. The STORE_DEFAULT_ALL (11h) or STORE_USER_ALL (11h) command must be used to commit the current settings to nonvolatile memory as device defaults. The settings that are capable of being stored in nonvolatile memory are noted in the detailed command descriptions.

7.3.23 PMBus Address

The PMBus specification requires that each device connected to the PMBus have a unique address on the bus. The devices each have 64 possible addresses (0 through 63 in decimal) that can be assigned by connecting resistors from the ADDR0 and ADDR1 pins to AGND. The address is set in the form of two octal (0 to 7) digits, one digit for each pin. ADDR1 is the high order digit and ADDR0 is the low-order digit. These address selection resistors must be 1% tolerance or better. Using resistors other than the recommended values can result in devices responding to adjacent addresses.

The E48 series resistors with no worse than 1% tolerance suggested for each digit value are shown in Table 3.

Table 3. Required Address Resistors

DIGIT RESISTOR VALUE (kΩ)
0 7.15
1 14
2 22.6
3 34.8
4 51.1
5 78.7
6 121
7 187

The devices also detect values that are out of range on the ADDR0 and ADDR1 pins. If the device detects that either pin has an out-of-range resistance connected to it, the device continues to respond to PMBus interface commands, but does so at address 127 decimal, which is outside of the possible programmed addresses. It is possible but not recommended to use the device in this condition, especially if other devices are present on the bus or if another device could possibly occupy the 127 decimal address.

Certain addresses in the I2C address space are reserved for special functions and it is possible to set the address of the devices to respond to these addresses. The user is responsible for knowing which of these reserved addresses are in use in a system and for setting the address of the devices accordingly so as not to interfere with other system operations. The devices can be set to respond to the global call address or 0. It is recommended not to set the devices to this address unless the user is certain that no other devices respond to this address and that the overall bus is not affected by having such an address present.

7.3.24 PMBus Connections

The devices support both the 100-kHz and 400-kHz bus speeds, 1.8-V or 3.3-V and 5-V PMBus-interface logic level. For more information, see the PMBus Interface section of the Specifications.

7.3.25 Auto ARA (Alert Response Address) Response

By default, the devices implement the auto alert response, a manufacturer specific improvement to the standard SMBALERT response protocol defined in the SMBus specification. The auto alert response is designed to prevent SMBALERT monopolizing in the case of a persistent fault condition on the bus. The user can choose to disable the auto ARA response, and use the standard SMBALERT response as defined in the SMBus specification, by using the EN_AUTO_ARA Bit of the OPTIONS (MFR_SPECIFIC_21) register.

In the case of a fault condition, the slave device experiencing the fault pulls down the shared SMBALERT line, to alert the host that a fault condition has occurred. To establish which slave device has experienced the fault, the host issues a modified receive byte operation to the alert response address (ARA), to which only the slave pulling down on SMBALERT should respond. The SMBus protocol provides a method for address arbitration in the case that multiple slaves on the same bus are experiencing fault conditions. When the host has established the address of the offending device, it must take any necessary action to release the SMBALERT line. For more information on the standard SMBus alert response protocol, refer to the SMBus specification.

In the case of a non-persistent fault (a single-time event, such as an invalid command or data byte), the host can ascertain the address of the slave experiencing a fault using the standard ARA response, and simply issue CLEAR_FAULTS to release the SMBALERT line, and resume normal operation. However, in the case of a persistent fault (one which remains active for some time, such as a short-circuit, or thermal shutdown), once the device issues a CLEAR_FAULTS command, the fault immediately re-triggers, and SMBALERT continues to be pulled low. In this case, the device holds low the SMBALERT line until the host masks the SMBALERT line using SMBALERT_MASK and then issues the CLEAR_FAULTS command. Because the SMBALERT line remains low, the host cannot be alerted to other fault conditions on the bus until it clears SMBALERT. Figure 35 and Figure 36 show this response.

TPS546C23 dd_too_SLVSCC5_DESC_NON_AUTO_ARA.gif Figure 35. Example Standard ARA Response to Nonpersistent Fault
TPS546C23 dd_too_SLVSCC5_NON-AUTO_ARA_PERSIST.gif Figure 36. Example Standard ARA Response to a Persistent Fault

To mitigate the problem of SMBALERT bus hogging described previously, the devices implement the Auto ARA response. When Auto ARA is enabled, the devices releases SMBALERT automatically after successfully responding to access from the host at the alert response address. In this case, even when the device is experiencing a persistent fault, it does not hold the SMBALERT line low following successful notification of the host, and the host can be alerted to other faults on the bus in the normal manner. Examples of the auto ARA response are shown in Figure 37 and Figure 38.

TPS546C23 dd_too_SLVSCC5_AUTO_ARA_NON-PERSIST.gif Figure 37. Example Auto ARA Response to Nonpersistent Fault
TPS546C23 dd_too_SLVSCC5_AUTO_ARA_PERSIST.gif Figure 38. Example Auto ARA Response to Persistent Fault

7.4 Device Functional Modes

7.4.1 Continuous Conduction Mode

The devices operate in continuous conduction mode (CCM) at a fixed frequency, regardless of the output current. For the first 128 switching cycles, the low-side MOSFET on-time is slowly increased to prevent excessive current sinking in the event the device is started with a prebiased output. Following the first 128 clock cycles, the low-side MOSFET and the high-side MOSFET on-times are fully complementary.

7.4.2 Operation with CNTL Signal Control

According to the value in the ON_OFF_CONFIG register, the devices can be commanded to use the CNTL pin to enable or disable regulation, regardless of the state of the OPERATION command. The CNTL pin can be configured as either active high or active low (inverted) logic.

7.4.3 Operation with OPERATION Control

According to the value in the ON_OFF_CONFIG register, the devices can be commanded to use the OPERATION command to enable or disable regulation, regardless of the state of the CNTL signal.

7.4.4 Operation with CNTL and OPERATION Control

According to the value in the ON_OFF_CONFIG register, the devices can be commanded to require both a signal on the CNTL pin, and the OPERATION command to enable or disable regulation.

7.5 Programming

7.5.1 Supported PMBus Commands

The commands listed in Table 4 are implemented as described to conform to the PMBus 1.3 specification. Table 4 also lists the default for the bit behavior and register values.

Table 4. Supported PMBus Commands and Default Values

CMD
CODE		 PMBus 1.3
COMMAND NAME		 PMBus COMMAND DESCRIPTION DEFAULT BEHAVIOR DEFAULT
REGISTER
VALUE		 NVM
01h OPERATION Can be configured through ON_OFF_CONFIG to be used to turn the output on and off with or without input from the CTRL pin. OPERATION is not used to enable regulation 00h No
02h ON_OFF_CONFIG Configures the combination of CNTL pin input and OPERATION command for turning output on and off. CNTL only. Active High 16h Yes
03h CLEAR_FAULTS Clears all fault status registers to 0x00 and releases SMBALERT. Write-only n/a No
10h WRITE_PROTECT Used to control writing to the volatile operating memory (PMBus and restore from EEPROM). Allow writes to all registers 00h Yes
11h STORE_DEFAULT_ALL Stores all current storable register settings into EEPROM as new defaults. Write-only n/a No
12h RESTORE_DEFAULT_ALL Restores all storable register settings from EEPROM. Write-only n/a No
15h RESTORE_USER_ALL Stores all current storable register settings into EEPROM as new defaults. Write-only n/a No
16h RESTORE_USER_ALL Restores all storable register settings from EEPROM. Write-only n/a No
19h CAPABILITY Provides a way for a host system to determine key PMBus capabilities of the device. Read only. PMBus v1.3, 400 kHz, PEC and SMBus Alert Response Protocol supported. B0h No
1Bh SMBALERT_MASK Mask Warn or Fault status bits Mask PGOODz only n/a Yes
20h VOUT_MODE Read-only output mode indicator. Linear, exponent = –9 17h No
21h VOUT_COMMAND Default Regulation Setpoint 600mV 0133h Yes
24h VOUT_MAX Sets the maximum output voltage. VOUT_MAX imposes a higher bound to any attempted VOUT setting. If VOUT_SCALE_LOOP = 1: VOUT_MAX will restore to 1.65 V. 034Dh No
If VOUT_SCALE_LOOP = 0.5: VOUT_MAX will restore to 3.3 V. 069Ah
If VOUT_SCALE_LOOP = 0.25: VOUT_MAX will restore to 6 V. 0C00h
27h VOUT_TRANSITION_RATE Sets the rate at which the output should change voltage. 1 mV/us D03Ch No
29h VOUT_SCALE_LOOP Sets output sense scaling ratio for main control loop. 1 F004h Yes
2Bh VOUT_MIN Sets the minimum output voltage. VOUT_MIN imposes a lower bound to any attempted VOUT setting. If VOUT_SCALE_LOOP = 1: VOUT_MIN will restore to 0.35 V. 00B3h No
If VOUT_SCALE_LOOP = 0.5: VOUT_MIN will restore to 0.7 V. 0166h
If VOUT_SCALE_LOOP = 0.25: VOUT_MIN will restore to 1.4 V. 02CCh
35h VIN_ON Sets value of input voltage at which the device should start power conversion. 4.5 V F012h Yes
36h VIN_OFF Sets value of input voltage at which the device should stop power conversion. 4 V F010h Yes
39h IOUT_CAL_OFFSET Can be set to null out offsets in the current sensing circuit. 0.0000 A E000h Yes
41h VOUT_OV_FAULT_RESPONSE Sets output overvoltage fault response. Restart BFh Yes
45h VOUT_UV_FAULT_RESPONSE Sets output undervoltage fault response. Restart BFh Yes
46h IOUT_OC_FAULT_LIMIT Sets the value of the output current that causes an overcurrent fault condition. 42 A F854h Yes
47h IOUT_OC_FAULT_RESPONSE Sets response to output overcurrent faults to latch-off, hiccup mode or ignore. Restart FFh Yes
4Ah IOUT_OC_WARN_LIMIT Sets the value of the output current that causes an overcurrent warning condition. 37 A F84Ah No
4Fh OT_FAULT_LIMIT Sets the value of the sensed temperature that causes an overtemperature fault condition. 145°C 0091h Yes
50h OT_FAULT_RESPONSE Sets response to over temperature faults to latch-off, hiccup mode or ignore. Ignore 3Fh Yes
51h OT_WARN_LIMIT Sets the value of the sensed temperature that causes an overtemperature warning condition. 120°C 0078h No
60h TON_DELAY Sets the turnon delay. 0 ms 0000h Yes
61h TON_RISE Sets the time from when the output starts to rise until the voltage has entered the regulation band. 3 ms 0003h Yes
62h TON_MAX_FAULT_LIMIT Sets an UPPER limt in milliseconds, on how long the unit can attempt to power up the output without reaching the output undervoltage fault limit. The time begins counting as the device enters the soft-start period. Disabled 0000h No
63h TON_MAX_FAULT_RESPONSE Sets the soft start timeout fault response. Restart BFh Yes
64h TOFF_DELAY Sets the turnoff delay. 0 ms 0000h Yes
65h TOFF_FALL Sets the soft stop fall time. 0 ms 0000h Yes
78h STATUS_BYTE Returns one byte summarizing the most critical faults. Current status No
79h STATUS_WORD Returns two bytes summarizing fault and warning conditions. Current status No
7Ah STATUS_VOUT Returns one byte detailing if an output fault or warning has occurred Current status No
7Bh STATUS_IOUT Returns one byte detailing if an overcurrent fault or warning has occurred Current status No
7Ch STATUS_INPUT Returns one byte of information relating to the status of the converter's input related faults. Current status No
7Dh STATUS_TEMPERATURE Returns one byte detailing if a sensed temperature fault or warning has occurred. Current status No
7Eh STATUS_CML Returns one byte containing PMBus serial communication faults. Current status No
80h STATUS_MFR_SPECIFIC Returns one byte detailing if internal overtemperature or address detection fault has occurred. Current status No
8Bh READ_VOUT Returns the output voltage in volts. Read only Current status No
8Ch READ_IOUT Returns the output current in amps. Read only Current status No
8Dh READ_TEMPERATURE_1 Returns the sensed die temperature in degrees Celsius. Read-only Current status No
98h PMBUS_REVISION Returns PMBus revision to which the device is compliant. PMBus 1.3 33h No
ADh IC_DEVICE_ID This Read-only Block Read command returns a single word (16 bits) with the unique Device Code identifier for each device for which this device can be configured. The BYTE_COUNT field in the Block Read command is 2 (indicating 2 bytes follow): Low Byte first, then High Byte. TPS546C23 4623h No
AEh IC_DEVICE_REV This Read-only Block Read command returns a single word (16 bits) with the unique Device revision identifier. The BYTE_COUNT field in the Block Read command is 2 (indicating 2 bytes follow): Low Byte first, then High Byte. Read only 0001h No
D0h MFR_SPECIFIC_00 User scratch pad. 0000h Yes
D4h VREF_TRIM (MFR_SPECIFIC_04) (D4h) Applies a fixed offset voltage to the Error Amplifier Reference voltage (EA_REF). Fixed offset of 0 mV 0000h Yes
D5h STEP_VREF_MARGIN_HIGH (MFR_SPECIFIC_05) (D5h) Increases the value of the reference voltage by shifting the reference higher. If RSMHI_VAL = 0: STEP_VREF_MARGIN_HIGH will restore to 17.6 mV If RSMHI_VAL = 0: 0009h No
If RSMHI_VAL = 1: STEP_VREF_MARGIN_HIGH will restore to 29.3 mV If RSMHI_VAL = 1: 000fh
D6h STEP_VREF_MARGIN_LOW (MFR_SPECIFIC_06) (D6h) Decreases the value of the reference voltage by shifting the reference lower. If RSMLO_VAL = 0: STEP_VREF_MARGIN_LOW will restore to –17.6 mV If RSMLO_VAL = 0: fff7h No
If RSMLO_VAL = 1: STEP_VREF_MARGIN_LOW will restore to –29.3 mV If RSMLO_VAL = 1: fff1h
D7h PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h) Sets the PGOOD, VOUT_UNDER_VOLTAGE (UV) and VOUT_OVER_VOLTAGE (OV) Limits as a percentage of nominal. –17% for UV Fault, –12% for UV Warning, +12% for OV Warning, +17% for OV Fault. 00h Yes
E5h OPTIONS (MFR_SPECIFIC_21) Sets user selectable options. See detailed command description 1184h Yes
F0h MISC_CONFIG_OPTIONS (MFR_SPECIFIC_32) Sets miscellaneous user selectable options. See detailed command description 0013h Yes

7.6 Register Maps

This family of devices supports the following commands from the PMBus 1.3 specification.

Table 5. Legend for Register Access Type

Access Type Code Description
Read Type
R r Read
Write Type
W w Write
Other
superscript E
r/wE		 E Bit is backed up with nonvolatile EEPROM

7.6.1 OPERATION (01h)

The OPERATION command turns the device output on or off in conjunction with input from the CNTL signal. It is also used to set the output voltage to the upper or lower margin voltages. The unit stays in the commanded operating mode until a subsequent OPERATION command or a change in the state of the CNTL pin instructs the device to change to another mode.

For PWM loop slave device, which is recognized during power-up calibration, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

COMMAND OPERATION
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/w r/w r/w r/w r/w r/w r r
Function ON OFF MARGIN X X
Default Value 0 0 0 0 0 0 X X

7.6.1.1 On Bit

This bit is an enable command to the converter.

  • 0: output switching is disabled. Both drivers placed in an off or low state.
  • 1: output switching is enabled if the input voltage is above undervoltage lockout, OPERATION is configured as a gating signal in ON_OFF_CONFIG, and no fault conditions exist.

7.6.1.2 Off Bit

This bit sets the turnoff behavior when commanding the unit to turn off through OPERATION[7] ( the On bit).

  • 0: Immediately turn off the output (not honoring the programmed turnoff delay (TOFF_DELAY) and ramp down (TOFF_FALL)) when commanded off through OPERATION[7] ( the On bit).
  • 1: Use the programmed turnoff delay (TOFF_DELAY) and ramp down (TOFF_FALL) when commanded off through OPERATION[7] (also called soft off).

NOTE

The device ignores any values written to read-only bits. Additionally, both the on and off bits being set at the same time is not allowed and considered invalid data per section 12.1 of the PMBus Specification Part II; any attempt to do so causes the device to set the cml bit in the STATUS_BYTE and the ivd bit in the STATUS_CML registers, and triggers SMBALERT signal.

7.6.1.3 Margin Bit

If Margin Low is enabled, load the value from the STEP_VREF_MARGIN_LOW command. If Margin High is enabled, load the value from the STEP_VREF_MARGIN_HIGH command.

  • 0001: Margin Off. Output voltage source is VOUT_COMMAND. OV and UV faults are ignored.
  • 0000, 0010, 0011: Margin Off. Output voltage source is VOUT_COMMAND. OV/UV faults behave normally as programmed in their respective fault response registers.
  • 0101: Margin Low (Ignore Fault). Output voltage defined directly below.
  • 0110: Margin Low (Act On Fault). Output voltage defined directly below.
  • 1001: Margin High (Ignore Fault). Output voltage defined directly below.
  • 1010: Margin High (Act On Fault). Output voltage defined directly below.
  • 11XX, 0100, 0111, 1000, 1011: Shall be invalid and shall declare an Invalid Data Fault (Part II Rev 1.3 Section 10.9.3, Page 52)

VOUT_MARGIN_LOW data shall be equal to:
VOUT_COMMAND + (VREF_TRIM – STEP_VREF_MARGIN_LOW) / VOUT_SCALE_LOOP

VOUT_MARGIN_HIGH data shall be equal to:
VOUT_COMMAND + (VREF_TRIM + STEP_VREF_MARGIN_HIGH) / VOUT_SCALE_LOOP

For the Margin Low, Ignore Fault configuration (essentially [5:2] = 4’b0101), any incoming UV faults shall trigger the normal UVF status, and trigger SMB_ALERT (albeit the state machine response will be to ignore and not respond). If the desired response is to have the device to not trigger SMB_ALERT for UVF events when margining, they must set the UVF SMBALERT_MASK bit. For the Margin High, Ignore Fault configuration (essentially [5:2] = 4’b1001), any incoming OV faults shall trigger the normal OVF status, and trigger SMB_ALERT (albeit the state machine response will be to ignore and not respond). If the desired response is to have the device to not trigger SMB_ALERT for UVF events when margining, they must set the UVF SMBALERT_MASK bit. OVF and UVF can also be ignored when VOUT_COMMAND is the VOUT source by programming [5:2] to a value of 4’b0001. OVF and UVF events will still set status and trigger SMB_ALERT.

7.6.2 ON_OFF_CONFIG (02h)

The ON_OFF_CONFIG command configures the combination of CNTL pin input and serial bus commands needed to turn the unit on and off. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL (11h) command. The default value in ON_OFF_CONFIG register is to have the device power up by CNTL pin only with the active high polarity and use the programmed turnoff delay (TOFF_DELAY) and ramp down (TOFF_FALL) for powering off the converter.

For PWM loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

COMMAND ON_OFF_CONFIG
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r/wE r/wE r/wE r/wE r/wE
Function X X X pu cmd cpr pol cpa
Default Value X X X 1 0 1 1 0

7.6.2.1 pu Bit

The pu bit sets the default to either operate any time power is present or for power conversion to be controlled by CNTL pin and PMBus OPERATION command. This bit is used in conjunction with the cpr, cmd, and on bits to determine start up.

BIT VALUE ACTION
0 Device powers up any time power is present regardless of state of the CNTL pin.
1 Device does not power up until commanded by the CNTL pin and/or OPERATION command as programmed in bits [3:0] of the ON_OFF_CONFIG register.

7.6.2.2 cmd Bit

The cmd bit controls how the device responds to the OPERATION command. This bit is used in conjunction with the cpr, pu, and on bits to determine start up.

BIT VALUE ACTION
0 Device ignores the “on” bit in the OPERATION command.
1 Device responds to the “on” bit in the OPERATION command.

7.6.2.3 cpr Bit

The cpr bit sets the CNTL pin response. This bit is used in conjunction with the cmd, pu, and on bits to determine start up.

BIT VALUE ACTION
0 Device ignores the CNTL pin. Power conversion is controlled only by the OPERATION command.
1 Device requires the CNTL pin to be asserted to start the unit.

7.6.2.4 pol Bit

The pol bit controls the polarity of the CNTL pin. For a change to become effective, the contents of the ON_OFF_CONFIG register must be stored to nonvolatile memory using the STORE_DEFAULT_ALL command and the device power cycled. Simply writing a new value to this bit does not change the polarity of the CNTL pin.

BIT VALUE ACTION
0 CNTL pin is active low.
1 CNTL pin is active high.

7.6.2.5 cpa Bit

The cpa bit sets the CNTL pin action when turning the converter off.

BIT VALUE ACTION
0 Use the programmed turnoff delay (TOFF_DELAY) and ramp down (TOFF_FALL).
1 Immediately turn off the output (not honoring the programmed turnoff delay (TOFF_DELAY) and ramp down (TOFF_FALL)).

7.6.3 CLEAR_FAULTS (03h)

The CLEAR_FAULTS command is used to clear any fault bits that have been set. This command clears all bits in all status registers simultaneously. At the same time, the device negates (clears, releases) its SMBALERT signal output if the device is asserting the SMBALERT signal. The CLEAR_FAULTS command does not cause a unit that has latched off for a fault condition to restart. If the fault is still present when the bit is cleared, the fault bit is immediately reset and the host notified by the usual means.

NOTE

  • To get a reliable clear fault result, the clear_fault command should be issued (8 × TON_RISE + TON_DELAY) after the switcher shuts down.
  • In the case of OV fault with a latch off response, the LS FET latches on when the fault is detected. If the OV_RESP_SEL Bit in (F0h) MFR_SPECIFIC_32 is set to 1, then the LS FET releases when the FB pin voltage falls below 0.2 V. Otherwise, it remains on until the CLEAR_FAULTS command is issued. The CLEAR FAULTS command causes the LS FET to turn off.
  • CNTL pin toggling can also clear fault, but the logic low duration should be higher than 100 ns for the internal circuit to recognize.

7.6.4 WRITE_PROTECT (10h)

The WRITE_PROTECT command is used to control writing to the PMBus device. The intent of this command is to provide protection against accidental changes. This command is not intended to provide protection against deliberate or malicious changes to the device configuration or operation. All supported command parameters may have their parameters read, regardless of the WRITE_PROTECT settings. Write protection also prevents protected registers from being updated in the event of a RESTORE_DEFAULT_ALL. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

COMMAND WRITE_PROTECT
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r/wE r/wE X X X X X
Function bit7 bit6 bit5 X X X X X
Default Value 0 0 0 X X X X X

7.6.4.1 bit5

BIT VALUE ACTION
0 Enable all writes as permitted in bit6 or bit7
1 Disable all writes except the WRITE_PROTECT, OPERATION, ON_OFF_CONFIG, and VOUT_COMMAND. (bit6 and bit7 must be 0 to be valid data)

7.6.4.2 bit6

BIT VALUE ACTION
0 Enable all writes as permitted in bit5 or bit7
1 Disable all writes except for the WRITE_PROTECT, and OPERATION commands. (bit5 and bit7 must be 0 to be valid data)

7.6.4.3 bit7

BIT VALUE ACTION
0 Enable all writes as permitted in bit5 or bit6
1 Disable all writes except for the WRITE_PROTECT command. (bit5 and bit6 must be 0 to be valid data)

In any case, only one of the three bits may be set at any one time. Attempting to set more than one bit results in an alert being generated and the cml bit is STATUS_WORD being set. An invalid setting of the WRITE_PROTECT command results in no write protection.

Data Byte Value ACTION
1000 0000 Disables all WRITES except to the WRITE_PROTECT command.
0100 0000 Disables all WRITES except to the WRITE_PROTECT, and OPERATION commands.
0010 0000 Disables all WRITES except to the WRITE_PROTECT, OPERATION, ON_OFF_CONFIG, and VOUT_COMMAND commands.

7.6.5 STORE_DEFAULT_ALL (11h)

The STORE_DEFAULT_ALL command stores all of the current storable register settings in the EEPROM memory as the new defaults on power up.

It is permissible to use this command while the device is switching. Note however that the device continues to switch but ignores all fault conditions until the internal store process has completed. Issuing STORE_DEFAULT_ALL also causes the device to be unresponsive through PMBus for a period of approximately 100 ms.

EEPROM programming faults cause the device to NACK and set the cml bit in the STATUS_BYTE and the mem bit in the STATUS_CML registers.

7.6.6 RESTORE_DEFAULT_ALL (12h)

The RESTORE_DEFAULT_ALL command restores all of the storable register settings from EEPROM memory to those registers which are unprotected according to current setting of WRITE_PROTECT. Issuing STORE_DEFAULT_ALL also causes the device to be unresponsive through PMBus for a period of approximately 100 ms.

NOTE

Do not use this command while the device is actively switching, this causes the device to stop switching and the output voltage to fall during the restore event. Depending on loading conditions, the output voltage could reach an undervoltage level and trigger an undervoltage fault response if programmed to do so. The command can be used while the device is switching, but this usage is not recommended as it results in a restart that could disrupt power sequencing requirements in more complex systems. TI strongly recommends stopping the device before issuing this command.

7.6.7 STORE_USER_ALL (11h)

The STORE_USER_ALL command stores all of the current storable register settings in the EEPROM memory as the new defaults on power up.

It is permissible to use this command while the device is switching. Note however that the device continues to switch but ignores all fault conditions until the internal store process has completed. Issuing STORE_USER_ALL also causes the device to be unresponsive through PMBus for a period of approximately 100 ms.

EEPROM programming faults cause the device to NACK and set the cml bit in the STATUS_BYTE and the mem bit in the STATUS_CML registers.

This command shres the same harware implementation as STORE_DEFAULT_ALL.

7.6.8 RESTORE_USER_ALL (12h)

The RESTORE_USER_ALL command restores all of the storable register settings from EEPROM memory to those registers which are unprotected according to current setting of WRITE_PROTECT. Issuing STORE_USER_ALL also causes the device to be unresponsive through PMBus for a period of approximately 100 ms.

This command shres the same harware implementation as RESTORE_DEFAULT_ALL.

NOTE

Do not use this command while the device is actively switching, this causes the device to stop switching and the output voltage to fall during the restore event. Depending on loading conditions, the output voltage could reach an undervoltage level and trigger an undervoltage fault response if programmed to do so. The command can be used while the device is switching, but this usage is not recommended as it results in a restart that could disrupt power sequencing requirements in more complex systems. TI strongly recommends stopping the device before issuing this command.

7.6.9 CAPABILITY (19h)

The CAPABILITY command provides a way for a host system to determine some key capabilities of this PMBus device.

COMMAND CAPABILITY
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r r
Function PEC SPD ALRT Reserved
Default Value 1 0 1 1 0 0 0 0

The default values indicate that the device supports packet-error checking (PEC), a maximum bus speed of 400 kHz (SPD) and the SMBus alert-response protocol using SMBALERT.

7.6.10 SMBALERT_MASK (1Bh)

The SMBALERT_MASK command can be used to prevent a warning or fault condition from asserting the SMBALERT signal.

NOTE

The command uses the SMBus Write Word command protocol to overlay a “mask byte” with an associated/designated status register. It uses the SMBus Block Write/Block Read protocol – with a block size = 1, to read the mask settings for any given status register. If the host in the Block_Count field of the Block Write portion sends a block size unequal to 1 the device returns a NACK. The device always returns a Block Count of 1 upon reads of SMBALERT_MASK.

The bits in the mask byte align with the bits in the corresponding status register. For example, if the STATUS_TEMPERATURE command were sent with the mask byte 01000000b, then an Overtemperature Warning condition would be blocked from asserting SMBALERT. Please refer to the PMBus v1.3 specification - section 15.38 (SMBALERT_MASK Command) and the SMBus specification Block Write/Block Read protocol for further details.

There are 19 maskable SMBALERT sources in the TPS546C23. Each of these 19 status conditions has an associated EEPROM backed mask bit. These sources are represnted and identified in the status register command descriptions by a particular status bit denoted as having EEPROM backup (for example a bit access of r/wE). Writes and reads to SMBALERT_MASK command code accepts only the following as valid STATUS_x command codes:

Attempting to write a mask byte for any STATUS_X command code other than this list causes the device to set the cml bit in the STATUS_BYTE and the ivd bit in the STATUS_CML registers, and triggers SMBALERT. Attempting to read a mask byte for any STATUS_x command code other than this list returns 00h for the mask byte. Refer to these individual command descriptions for further details on their specific SMBALERT masking capabilities.

There is 1 unique status bit in the TPS546C23 that warrants special clarification: PGOOD_Z (STATUS_WORD[10]) is maskable as an SMBALERT source through SMBALERT_MASK commands to STATUS_WORD. If the user wants to write, or read, the mask bit for PGOOD_Z, the user must put 79h in the STATUS_x COMMAND_CODE field of the SMBALERT_MASK command. PGOOD_Z SMBALERT_MASK bit default to 1.

7.6.11 VOUT_MODE (20h)

The PMBus specification dictates that the data word for the VOUT_MODE command is one byte that consists of a 3-bit mode and 5-bit exponent parameter, as shown below. The 3-bit mode sets whether the device uses the Linear or Direct modes for output voltage related commands. The 5-bit parameter sets the exponent value for the linear data mode. The mode and exponent parameters are fixed and do not permit the user to change the values.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

COMMAND VOUT_MODE
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r r
Function Mode Exponent
Default Value 0 0 0 1 0 1 1 1

7.6.11.1 Mode Bit

Value fixed at 000, linear mode.

7.6.11.2 Exponent Bit

Value fixed at 10111, Exponent for Linear mode values is –9 (equivalent of 1.95mV/count).

7.6.12 VOUT_COMMAND (21h)

The VOUT_COMMAND command sets the output voltage in volts. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command. The exponent is set be VOUT_MODE at –9 (equivalent of 1.953 mV/count). The programmed internal reference voltage is computed as:

Equation 5. EA_REF = [(VOUT_COMMAND × VOUT_SCALE_LOOP) + (VREF_TRIM + STEP_VREF_MARGIN_HIGH × OPERATION[5] + STEP_VREF_MARGIN_LOW × OPERATION[4] )] × 2–9 (V)

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The range of valid VOUT_COMMAND values is dependent upon the configured VOUT_SCALE_LOOP (29h) as follows:

VOUT_SCALE_LOOP Vout Range (volts) VOUT_COMMAND data valid range
1 0.35 to 1.65 179 to 845
0.5 0.7 to 3.3 358 to 1690
0.25 1.4 to 5.5 716 to 2816

Any VOUT_COMMAND > 2816 (5.5-V maximum VOUT equivalent) is treated as invalid data:

If the value programmed to VOUT_COMMAND exceeds the value stored in either VOUT_MIN or VOUT_MAX. In this case, VOUT_COMMAND will be set to the appropriate VOUT_MIN or VOUT_MAX value (which ever was violated). See the command descriptions for (28h) VOUT_MIN or (24h) VOUT_MAX for the specific status bits set in either case.

COMMAND VOUT_COMMAND
Format Linear, unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Mantissa
Default Value 0 0 0 0 0 0 0 1 0 0 1 1 0 0 1 1

7.6.12.1 Exponent

Value fixed at 10111, Exponent for Linear mode values is –9 (equivalent of 1.95mV/count, specified in VOUT_MODE command).

7.6.12.2 Mantissa

This is the Mantissa for the linear format. The default for this bit value is: 0000 0001 0011 0011 (binary) 486 (decimal) (equivalent Vout default = 0.6 V).

7.6.13 VOUT_MAX (24h)

The VOUT_MAX command sets the maximum output voltage. The purpose is to protect the devices on the output rail supplied by this device from a higher than acceptable output voltage. VOUT_MAX imposes an upper bound to any attempt to program the output voltage to a VOUT_EQUIV setting by changing any of the following registers:

  • VOUT_COMMAND
  • VOUT_MAX
  • VOUT_MIN
  • OPERATION[5]
  • OPERATION[4]
  • VREF_TRIM
  • STEP_VREF_MARGIN_HIGH
  • STEP_VREF_MARGIN_LOW
  • VOUT_SCALE_LOOP

The exponent is set be VOUT_MODE at –9 (equivalent of 1.953 mV/count). Use Equation 6 to calculate the programmed output voltage.

Equation 6. MAXIMUM VOUT allowed = VOUT_MAX × VOUT_MODE (V) = VOUT_MAX × 2–9 (V)

The range of valid VOUT_MAX values is dependent upon the configured (29h) VOUT_SCALE_LOOP as shown in Equation 7.

Equation 7. MAXIMUM VOUT Reference allowed = VOUT_MAX × VOUT_SCALE_LOOP x VOUT_MODE (V) = VOUT_MAX × VOUT_SCALE_LOOP × 2–9 (V)

If, while the output voltage is turned on, any attempt is made to program: (1) VOUT_EQUIV to be greater than VOUT_MAX; (2) VOUT_MAX to be less than, or equal to, VOUT_MIN, or; (3) VOUT_MIN to be greater than, or equal to, VOUT_MAX – the device will:

  • Clamp the internal reference voltage to VOUT_MAX × VOUT_SCALE_LOOP × VOUT_MODE value. In the event VOUT_MAX < VOUT_MIN, VOUT_MAX shall dominate.
  • Sets the OTH (other) bit in the STATUS_BYTE
  • Sets the VFW bit in the STATUS_WORD
  • Sets the VOUT_MAX_MIN_Warning bit in the STATUS_VOUTregister
  • Notifies the host through the SMBALERT pin

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

COMMAND VOUT_MAX
Format Linear, unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w
Function Mantissa

7.6.13.1 Exponent

Value fixed at 10111, Exponent for Linear mode values is –9 (equivalent of 1.95 mV/count, specified in VOUT_MODE command).

7.6.13.2 Mantissa

The range of valid VOUT_MAX values is dependent upon the configured (29h) VOUT_SCALE_LOOP as follows.

If VOUT_SCALE_LOOP = 1:

  • default: 0000 0011 0100 1101 (binary) 845 (decimal) (equivalent VOUT_MAX = 1.65 V)
  • Minimum: 0000 0001 0001 1010 (binary) 282 (decimal) (equivalent VOUT_MAX = 0.55 V)
  • Maximum: 0000 0011 0100 1101 (binary) 845 (decimal) (equivalent VOUT_MAX = 1.65 V)

If VOUT_SCALE_LOOP = 0.5:

  • default: 0000 0110 1001 1010 (binary) 1690 (decimal) (equivalent VOUT_MAX = 3.3 V)
  • Minimum: 0000 0010 0011 0100 (binary) 564 (decimal) (equivalent VOUT_MAX = 1.1 V)
  • Maximum: 0000 0110 1001 0000 (binary) 1690 (decimal) (equivalent VOUT_MAX = 3.3 V)

If VOUT_SCALE_LOOP = 0.25:

  • default: 0000 1100 0000 0000 (binary) 3072 (decimal) (equivalent VOUT_MAX = 6 V)
  • Minimum: 0000 0100 0110 1000 (binary) 1128 (decimal) (equivalent VOUT_MAX = 2.2 V)
  • Maximum: 0000 1100 0000 0000 (binary) 3072 (decimal) (equivalent VOUT_MAX = 6 V)

7.6.14 VOUT_TRANSITION_RATE (27h)

The VOUT_TRANSITION_RATE command sets the rate of change in mV/µs of any output voltage change during normal operation (also includes vout changes in TOFF_DELAY state. In contrast the soft-start transition rate is controlled by TON_RISE and the TOFF_FALL transition rate is controlled by TOFF_FALL command).

For PWM loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

Only 8 fixed output voltage transition rates are available in the device. As such, the range of programmed VOUT-transition rates are sub-divided into 8 buckets that then selects one of the 8 fixed VOUT-transition rates. Programmed values are rounded to the nearest bucket/transition rate as outlined below:

COMMAND VOUT_TRANSITION_RATE
Format Linear, two’s complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/w r/w r/w r/w r/w r/w r/w
Function Exponent Mantissa
Default Value 1 1 0 1 0 0 0 0 0 0 1 1 1 1 0 0

7.6.14.1 Exponent

default: 11010 (binary) –6 (decimal) (0.015625)

These default settings are not programmable.

7.6.14.2 Mantissa

default: 000 0011 1100 (binary) 60 (decimal) (equivalent VOUT_TRANSITION_RATE = 1 mV/µs)

NOTE

Using VOUT_TRANSITION_RATE to slew Vref faster than the voltage loop can track is possible. This usage causes a control related overshoot/undershoot response on the output voltage.

VOUT_TRANSITION rate (mV/µs) VOUT_TRANSITION Mantissa (d)
Greater than Less than or equal to
0.067 5
0.1 5 7
0.143 7 12
0.222 12 17
0.333 17 25
0.5 25 47
1 47 79
1.5 79

7.6.15 VOUT_SCALE_LOOP (29h)

The VOUT_SCALE_LOOP command is equal to the feedback resistor ratio (RBIAS / (RBIAS + R1) in the configuration shown in Figure 25). This command is limited to only 3 possible options/ratios: 1 (default, no RBIAS needed), 0.5, and 0.25. Attempting to write a value unequal to one of these three options cause the device to set the cml bit in the STATUS_BYTE, and the ivd bit in the STATUS_CML registers. Additionally, SMBALERT is asserted and the value of VOUT_SCALE_LOOP remains unchanged. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

NOTE

Construct the feedback resistor ratio appropriately (see Table 1). If the
VOUT_SCALE_LOOP does not match the external feedback resistor ratio, the converter will regulate the output with the reference voltage as outlined in Equation 1 and Equation 2.

Program the VOUT_SCALE_LOOP setting before the output is turned on.

For the range checking to work properly and to avoid invalid data scenarios:

  • VOUT_SCALE_LOOP should be changed first, if needed.
  • VOUT_MIN and VOUT_MAX should be changed after VOUT_SCALE_LOOP, if needed.
  • Additionally, it is assumed that VOUT_SCALE_LOOP will be programmed before the output is turned on; but, the hardware will not do anything to prohibit changing VOUT_SCALE_LOOP in any state.
COMMAND VOUT_SCALE_LOOP
Format Linear, two’s complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 1 1 1 1 0 0 0 0 0 0 0 0 0 1 0 0

7.6.15.1 Exponent

default: 11110 (binary) –2 (decimal) (equivalent LSB = 0.25)

These default settings are not programmable.

7.6.15.2 Mantissa

default: 000 0000 0100 (binary) 4 (decimal) (equivalent VOUT_SCALE_LOOP voltage = 1)

For VOUT_SCALE_LOOP = 1, mantissa = 004h. (4 × 2–2 = 1)

For VOUT_SCALE_LOOP = 0.5, mantissa = 002h. (2 × 2–2 = 0.5)

For VOUT_SCALE_LOOP = 0.25, mantissa = 001h. (1 × 2–2 = 0.25)

7.6.16 VOUT_MIN (2Bh)

The VOUT_MIN command sets the minimum output voltage. The purpose is to protect the devices on the output rail supplied by this device from a lower than acceptable output voltage. VOUT_MIN imposes a lower bound to any attempt to program the output voltage to a VOUT_EQUIV setting by changing any of the following registers:

  • VOUT_COMMAND
  • VOUT_MAX
  • VOUT_MIN
  • OPERATION[5]
  • OPERATION[4]
  • VREF_TRIM
  • STEP_VREF_MARGIN_HIGH
  • STEP_VREF_MARGIN_LOW
  • VOUT_SCALE_LOOP

The exponent is set be VOUT_MODE at –9 (equivalent of 1.953 mV/count). Use Equation 8 to calculate the programmed output voltage.

Equation 8. MINIMUM VOUT allowed = VOUT_MIN × VOUT_MODE (V) = VOUT_MIN × 2–9 (V)

The range of valid VOUT_MIN values is dependent upon the configured (29h) VOUT_SCALE_LOOP as shown in Equation 9.

Equation 9. MINIMUM VOUT allowed = VOUT_MIN × VOUT_SCALE_LOOP × VOUT_MODE (V) = VOUT_MIN × VOUT_SCALE_LOOP × 2–9 (V)

If, while the output voltage is turned on, any attempt is made to program: (1) VOUT_EQUIV to be less than VOUT_MIN, the device will:

  • Clamp the internal reference voltage to VOUT_MIN × VOUT_SCALE_LOOP × VOUT_MODE value. In the event VOUT_MAX < VOUT_MIN, VOUT_MAX shall dominate.
  • Sets the OTH (other) bit in the STATUS_BYTE
  • Sets the VFW bit in the STATUS_WORD
  • Sets the VOUT_MAX_MIN_Warning bit in the STATUS_VOUTregister
  • Notifies the host through the SMBALERT pin

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

COMMAND VOUT_MIN
Format Linear, unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w r/w
Function Mantissa

7.6.16.1 Exponent

Value fixed at 10111, Exponent for Linear mode values is –9 (equivalent of 1.95 mV/count, specified in VOUT_MODE command).

7.6.16.2 Mantissa

The range of valid VOUT_MIN values is dependent upon the configured (29h) VOUT_SCALE_LOOP as follows.

If VOUT_SCALE_LOOP = 1:

  • default: 0000 0000 1011 0011 (binary) 179 (decimal) (equivalent VOUT_MIN = 0.35 V)
  • Minimum: 0000 0000 1011 0011 (binary) 179 (decimal) (equivalent VOUT_MIN = 0.35 V)
  • Maximum: 0000 0011 0000 0000 (binary) 768 (decimal) (equivalent VOUT_MIN = 1.5 V)

If VOUT_SCALE_LOOP = 0.5:

  • default: 0000 0001 0110 0110 (binary) 358 (decimal) (equivalent VOUT_MIN = 0.7 V)
  • Minimum: 0000 0001 0110 0110 (binary) 358 (decimal) (equivalent VOUT_MIN = 0.7 V)
  • Maximum: 0000 0110 0000 0000 (binary) 1536 (decimal) (equivalent VOUT_MIN = 3 V)

If VOUT_SCALE_LOOP = 0.25:

  • default: 0000 0010 1100 1100 (binary) 716 (decimal) (equivalent VOUT_MIN = 1.4 V)
  • Minimum: 0000 0010 1100 1100 (binary) 716 (decimal) (equivalent VOUT_MIN = 1.4 V)
  • Maximum: 0000 1100 0000 0000 (binary) 3072 (decimal) (equivalent VOUT_MIN = 6 V)

7.6.17 VIN_ON (35h)

The VIN_ON command sets the value of the input voltage at which the unit should start operation assuming all other required startup conditions are met. Values are mapped to the nearest supported increment. Values outside the supported range are treated as invalid data and cause the device set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers, and trigger SMBALERT signal. The value of VIN_ON remains unchanged on an out-of-range write attempt. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The supported VIN_ON values are shown in Table 6:

Table 6. Supported VIN_ON Values

VIN_ON Values (V)
4.25 4.5 (default) 4.75 5 5.25
5.5 5.75 6 6.25 6.5
6.75 7 7.25 7.5 7.75

VIN_ON must be set higher than VIN_OFF. Attempting to write either VIN_ON lower than VIN_OFF or VIN_OFF higher than VIN_ON results in the new value being rejected, SMBALERT signal being asserted along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML.

The data word that accompanies this command is divided into a fixed 5-bit exponent and an 11-bit mantissa. The four most significant bits of the mantissa are fixed, while the lower 4 bits may be altered.

COMMAND VIN_ON
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 1 1 1 1 0 0 0 0 0 0 0 1 0 0 1 0

7.6.17.1 Exponent

default: 11110 (binary) –2 (decimal) (equivalent LSB = 0.25 V)

These default settings are not programmable.

7.6.17.2 Mantissa

default: 000 0001 0010 (binary) 18 (decimal) (equivalent VIN_ON voltage = 4.5 V)

Minimum: 000 0001 0001 (binary) 17 (decimal) (equivalent VIN_ON voltage = 4.25 V)

Maximum: 000 0001 1111 (binary) 31 (decimal) (equivalent VIN_ON voltage = 7.75 V)

7.6.18 VIN_OFF (36h)

The VIN_OFF command sets the value of the input voltage at which the unit should stop operation. Values are mapped to the nearest supported increment. Values outside the supported range is treated as invalid data and causes the device to set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers, and trigger SMBALERT signal. The value of VIN_OFF remains unchanged during an out-of-range write attempt. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The supported VIN_OFF values are shown in Table 7:

Table 7. Supported VIN_OFF Values

VIN_OFF Values (V)
4 (default) 4.25 4.5 4.75 5
5.25 5.5 5.75 6 6.25
6.5 6.75 7 7.25 7.5

VIN_ON must be set higher than VIN_OFF. Attempting to write either VIN_ON lower than VIN_OFF or VIN_OFF higher than VIN_ON results in the new value being rejected, SMBALERT being asserted along with the cml bit in STATUS_BYTE and the invalid data bit in STATUS_CML.

The data word that accompanies this command is divided into a fixed 5 bit exponent and an 11 bit mantissa. The 4 most significant bits of the mantissa are fixed, while the lower 7 bits may be altered.

COMMAND VIN_OFF
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 1 1 1 1 0 0 0 0 0 0 0 1 0 0 0 0

7.6.18.1 Exponent

default: 11110 (binary) –2 (decimal) (equivalent LSB = 0.25 V)

These default settings are not programmable.

7.6.18.2 Mantissa

default: 000 0001 0000 (binary) 16 (decimal) (equivalent VIN_OFF voltage = 4 V)

Minimum: 000 0001 0000 (binary) 16 (decimal) (equivalent VIN_OFF voltage = 4 V)

Maximum: 000 0001 1110 (binary) 30 (decimal) (equivalent VIN_OFF voltage = 7.5 V)

7.6.19 IOUT_CAL_OFFSET (39h)

The IOUT_CAL_OFFSET command is used to compensate for offset errors in the READ_IOUT results and the IOUT_OC_FAULT_LIMIT and IOUT_OC_WARN_LIMIT thresholds. The units are amperes. The default setting is 0 A. The resolution of the argument for this command is 62.5 mA and the range is +3.9375 A to –4 A. Values written outside of this range alias into the supported range. This occurs because the read-only bits are fixed. The exponent is always –4 and the 5 MSB bits of the Mantissa are always equal to the sign bit. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

COMMAND IOUT_CAL_OFFSET
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r/wE r r r r r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.19.1 Exponent

default: 11100 (binary) –4 (decimal) (LSB = 62.5 mA)

These default settings are not programmable.

7.6.19.2 Mantissa

MSB is programmable with sign, next 4 bits are sign extend only.
Lower six bits are programmable with a default value of 0 (decimal).

7.6.20 VOUT_OV_FAULT_RESPONSE (41h)

The VOUT_OV_FAULT_RESPONSE command instructs the device on what action to take in response to an Output Over Voltage Fault based on MFR_SPECIFIC_07 (PCT_OV_UV_WRN_FLT_LIMITS). The device also:

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The default response to a output overvoltage fault is to shut down and restart with 7 × TON_RISE time delay.

COMMAND VOUT_OV_FAULT_RESPONSE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r/wE r/w r/w r r r
Function RSP[1] 0 RS[2] RS[1] RS[0] TD[2] TD[1] TD[0]
Default Value 1 0 1 1 1 1 1 1

7.6.20.1 RSP[1] Bit

This bit sets the output voltage overvoltage response to either ignore or not. The default for this bit is 1.

BIT VALUE ACTION
0 The PMBus device continues operation without interruption. Note: In this ignore fault response mode, the associated fault status bits is set. Additionally, SMBALERT remains triggered if it is not masked.
1 The PMBus device shuts down and restarts according to RS[2:0].

7.6.20.2 RS[2:0] Bits

These bits are output voltage overvoltage retry setting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry setting means that the unit does not attempt to restart. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry setting means that the unit goes through a normal startup (Soft start) continuously, without limitation, until it is commanded off or bias power is removed or another fault condition causes the unit to shutdown.

Any value other than 000 or 111 is not accepted. Attempting to write any other value is rejected, causing the device to assert SMBALERT along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML. Note: because all 3 bits must be the same, only one (bit 5) is stored in EEPROM.

7.6.20.3 TD[2:0] Bits

These bits are output voltage overvoltage retry time delay retting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry time delay setting means that the unit does not attempt to delay a restart. This is only supported when Restart is disabled by RS[2:0] = 000. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry time delay setting means that the unit waits 7 TON_RISE times before it goes through a normal startup (Soft start). This is only supported when Restart is enabled by RS[2:0] = 111.

These bits are direct reflections of the RS[2] (bit 5) value in this register.

7.6.21 VOUT_UV_FAULT_RESPONSE (45h)

The VOUT_UV_FAULT_RESPONSE command instructs the device on what action to take in response to an Output Under Voltage Fault based on MFR_SPECIFIC_07 (PCT_OV_UV_WRN_FLT_LIMITS). The device also:

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The default response to a output undervoltage fault is to shut down and restart with 7 × TON_RISE time delay.

COMMAND VOUT_UV_FAULT_RESPONSE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r/wE r/w r/w r r r
Function RSP[1] 0 RS[2] RS[1] RS[0] TD[2] TD[1] TD[0]
Default Value 1 0 1 1 1 1 1 1

7.6.21.1 RSP[1] Bit

This bit sets the output voltage undervoltage response to either ignore or not. The default for this bit is 1.

BIT VALUE ACTION
0 The PMBus device continues operation without interruption. Note: In this ignore fault response mode, the associated fault status bits are set. Additionally, SMBALERT continues to be triggered if it is not masked.
1 The PMBus device shuts down and restarts according to RS[2:0].

7.6.21.2 RS[2:0] Bits

These bits are output voltage undervoltage retry setting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry setting means that the unit does not attempt to restart. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry setting means that the unit goes through a normal startup (soft start) continuously, without limitation, until it is commanded off or bias power is removed or another fault condition causes the unit to shutdown.

Any value other than 000 or 111 is not accepted. Attempting to write any other value is rejected, causing the device to assert SMBALERT along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML. Because all 3 bits must be the same, only one (bit 5) is stored in EEPROM.

7.6.21.3 TD[2:0] Bits

These bits are output voltage undervoltage retry time delay retting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry time delay setting means that the unit does not attempt to delay a restart. This is only supported when Restart is disabled by RS[2:0] = 000. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry time delay setting means that the unit waits 7 TON_RISE times before it goes through a normal startup (Soft start). This is only supported when Restart is enabled by RS[2:0] = 111.

These bits are direct reflections of the RS[2] (bit 5) value in this register.

7.6.22 IOUT_OC_FAULT_LIMIT (46h)

The IOUT_OC_FAULT_LIMIT command sets the value of the output current, in amperes, that causes the overcurrent detector to indicate an overcurrent fault condition. The IOUT_OC_FAULT_LIMIT should be set equal to or greater than the IOUT_OC_WARN_LIMIT. Writing a value to IOUT_OC_FAULT_LIMIT less than IOUT_OC_WARN_LIMIT causes the device to set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers as well as assert the SMBALERT signal. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command. Since 2-LSBs are not stored in EEPROM, on STORE, always round up. If IOUT_OC_FAULT_LIMIT [1:0] > 0, add 1 to IOUT_OC_FAULT_LIMIT [6:2]

The IOUT_OC_FAULT_LIMIT takes a two-byte data word formatted as shown below:

COMMAND IOUT_OC_FAULT_LIMIT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/w r/w
Function Exponent Mantissa
Default Value See Below

7.6.22.1 Exponent

default: 11111 (binary) –1 (decimal) (0.5 A)

These default settings are not programmable.

7.6.22.2 Mantissa

The upper four bits are fixed at 0.

The lower seven bits are programmable.

Use Equation 10 to calculate the actual output current for a given mantissa and exponent.

Equation 10. TPS546C23 q_ioutoc_lus930.gif

The default values and allowable ranges for each device are summarized below:

DEVICE OC_FAULT_LIMIT UNIT
MIN DEFAULT MAX
TPS546C23 5 42 52 A

7.6.23 IOUT_OC_FAULT_RESPONSE (47h)

The IOUT_OC_FAULT_RESPONSE command instructs the device on what action to take in response to an IOUT_OC_FAULT_LIMIT. The device also:

The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The default response to an overcurrent fault is to shut down and restart with 7 × TON_RISE time delay.

COMMAND IOUT_OC_FAULT_RESPONSE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r/w r/wE r/w r/w r r r
Function RSP[1] RSP[0] RS[2] RS[1] RS[0] TD[2] TD[1] TD[0]
Default Value 1 1 1 1 1 1 1 1

7.6.23.1 RSP[1:0] Bits

These bits set the overcurrent fault response to either ignore or not. The default for this bit is 11b. Any value other than 00b or 11b will not be accepted, such and attempt will cause the ’cml’ bit in the STATUS_BYTE register and the ivd bit in the STATUS_CML register to be set, and assert SMBALERT. Because both bits must be the same, only one (bit 7) is stored in EEPROM. The default for this bit is 11b.

BIT VALUE ACTION
00 The PMBus device continues operation without interruption. Note: In this “ignore” fault response mode, the associated fault status bits are set. Additionally, SMBALERT continues to be triggered if it is not masked.
11 The PMBus device shuts down and restarts according to RS[2:0].

7.6.23.2 RS[2:0] Bits

These bits are overcurrent fault retry setting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry setting means that the unit does not attempt to restart. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry setting means that the unit goes through a normal startup (soft-start) continuously, without limitation, until it is commanded off or bias power is removed or another fault condition causes the unit to shutdown.

Any value other than 000 or 111 is not accepted. Attempting to write any other value is rejected, causing the device to assert SMBALERT along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML. Because all 3 bits must be the same, only one (bit 5) is stored in EEPROM.

7.6.23.3 TD[2:0] Bits

These bits are over current retry time delay retting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry time delay setting means that the unit does not attempt to delay a restart. This is only supported when Restart is disabled by RS[2:0] = 000. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry time delay setting means that the unit waits 7 TON_RISE times before it goes through a normal startup (Soft start). This is only supported when Restart is enabled by RS[2:0] = 111.

These bits are direct reflections of the RS[2] (bit 5) value in this register.

7.6.24 IOUT_OC_WARN_LIMIT (4Ah)

The IOUT_OC_WARN_LIMIT command sets the value of the output current, in amperes, that causes the overcurrent detector to indicate an overcurrent warning. When this current level is exceeded the device:

The IOUT_OC_WARN_LIMIT threshold should always be set to less than or equal to the IOUT_OC_FAULT_LIMIT. Writing a value to IOUT_OC_WARN_LIMIT greater than IOUT_OC_FAULT_LIMIT causes the device to set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers as well as assert the SMBALERT signal. In such case, the register content will remain unchanged. This behavior can be overridden by the user setting Data Limit Override (DLO) in MFR_SPECIFIC_21[4].

The default IOUT_OC_WARN_LIMIT is always set to relative to 87.5% of the OCF value. Because the IOUT_OC_WARN_LIMIT is not stored in EEPROM, the IOUT_OC_WARN_LIMIT register is set to 12.5% less than the stored OCF threshold upon any RESTORE from EEPROM (reset_restore, or RESTORE_DEFAULT_ALL command). The digital math to achieve this is: OCW_default = (OCF – OCF/8).

The IOUT_OC_WARN_LIMIT takes a two byte data word formatted as shown below:

COMMAND IOUT_OC_WARN_LIMIT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/w r/w r/w r/w r/w r/w r/w
Function Exponent Mantissa
Default Value See Below

7.6.24.1 Exponent

default: 11111 (binary) –1 (decimal) (0.5 A)

These default settings are not programmable.

7.6.24.2 Mantissa

The upper four bits are fixed at 0.

Lower seven bits are programmable.

The actual output warning current level for a given mantissa and exponent is:

Equation 11. TPS546C23 eq_iout_ocw.gif

The default values and allowable ranges for each device are summarized below:

DEVICE OC_WARN_LIMIT UNIT
MIN DEFAULT MAX
TPS546C23 4 37 50 A

7.6.25 OT_FAULT_LIMIT (4Fh)

The OT_FAULT_LIMIT command sets the value of the temperature, in degrees Celsius, that causes an overtemperature fault condition, when the sensed temperature from the external sensor exceeds this limit.

The OT_FAULT_LIMIT must always be greater than the OT_WARN_LIMIT. Writing a value to OT_FAULT_LIMIT less than or equal to OT_WARN_LIMIT causes the device to set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers as well as asserts the SMBALERT signal. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The OT_FAULT_LIMIT takes a two byte data word formatted as shown below.

COMMAND OT_FAULT_LIMIT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 1 0 0 1 0 0 0 1

7.6.25.1 Exponent

default: 00000 (binary) 0 (decimal) (represents mantissa with steps of 1 degree Celcius)

These default settings are not programmable.

7.6.25.2 Mantissa

default: 000 1001 0001 (binary) 145 (decimal) (145°C)

Minimum: 000 0111 1000 (binary) (equivalent OTF = 120°C)

Maximum: 000 1010 0101 (binary) (equivalent OTF = 165°C)

7.6.26 OT_FAULT_RESPONSE (50h)

The OT_FAULT_RESPONSE command instructs the device on what action to take in response to an OT_FAULT_LIMIT. The device also:

When the overtemperature fault is tripped, the fault flag is latched until the external sensed temperature decreases 20°C from the OT_FAULT_LIMIT.

The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The default response to an over temperature fault is to ignore. Fixed Bandgap Detected Overtemperature faults are never ignored. The Bandgap OT faults always respond in a shutdown and attempted restart once the part cools.

COMMAND OT_FAULT_RESPONSE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r/wE r/w r/w r r r
Function RSP[1] 0 RS[2] RS[1] RS[0] TD[2] TD[1] TD[0]
Default Value 0 0 1 1 1 1 1 1

7.6.26.1 RSP[1] Bit

This bit sets the over temperature fault response to either ignore or not. The default for this bit is 0.

BIT VALUE ACTION
0 The PMBus device continues operation without interruption. Note: In this “ignore” fault response mode, the associated fault status bits are set. Additionally, SMBALERT continues to be triggered if it is not masked.
1 The PMBus device shuts down and restarts according to RS[2:0].

7.6.26.2 RS[2:0] Bits

These bits are over temperature fault retry setting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the Retry Setting means that the unit does not attempt to restart. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the Retry Setting means that the unit goes through a normal startup (Soft start) continuously, without limitation, until it is commanded off or bias power is removed or another fault condition causes the unit to shutdown.

Any value other than 000 or 111 is not accepted. Attempting to write any other value is rejected, causing the device to assert SMBALERT along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML. Because all 3 bits must be the same, only one (bit 5) is stored in EEPROM.

NOTE

The programmed response here is also applied to the bandgap-detected overtemperture (OT) faults with the one exception of the ignore response. The fixed Bandgap-detected overtemperature faults are never ignored. The bandgap OT faults always respond in a shutdown and attempted restart when the part cools.

7.6.26.3 TD[2:0] Bits

These bits are overtemperature fault retry time delay retting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry time delay setting means that the unit does not attempt to delay a restart. This is only supported when restart is disabled by RS[2:0] = 000. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry time delay setting means that the unit waits 7 TON_RISE times before it goes through a normal startup (soft start). This is only supported when restart is enabled by RS[2:0] = 111.

These bits are direct reflections of the RS[2] (bit 5) value in this register.

7.6.27 OT_WARN_LIMIT (51h)

The OT_WARN_LIMIT command sets the value of the temperature, in degrees Celsius, that causes an overtemperature warning condition, when the sensed temperature from the external sensor exceeds this limit. Upon triggering the overtemperature warning, the device takes the following actions:

Once the overtemperature warning is tripped, the warning flag is latched until the external sensed temperature decreases 20°C from the OT_WARN_LIMIT.

The OT_WARN_LIMIT must always be less than the OT_FAULT_LIMIT. Writing a value to OT_WARN_LIMIT greater than or equal to OT_FAULT_LIMIT causes the device to set the CML bit in the STATUS_BYTE and the invalid data (ivd) bit in the STATUS_CML registers as well as assert the SMBALERT signal. In such case, the register content will remain unchanged. This behavior can be overridden by the user setting Data Limit Override (DLO) in MFR_SPECIFIC_21[4].

The default OT_WARN_LIMIT is mathematically derived from the EEPROM backed OTF limit by subtracting 25 from (4Fh) OT_FAULT_LIMIT to reach the default OT_WARN_LIMIT. If the calculated OTW is less than 100°C, then the default value is set to 100°C. OTW=max(OTF-25, 100)

The OT_WARN_LIMIT takes a two byte data word formatted as shown below:

COMMAND OT_WARN_LIMIT
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r/w r/w r/w r/w r/w r/w r/w r/w
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 1 1 1 1 0 0 0

7.6.27.1 Exponent

default: 00000 (binary) 0 (decimal) (represents mantissa with steps of 1 degree Celcius)

These default settings are not programmable.

7.6.27.2 Mantissa

default: 000 0111 1000 (binary) 120 (decimal) (120°C) 25°C less than default OTF

Minimum: 000 0110 0100 (binary) (equivalent OTF = 100°C)

Maximum: 000 1000 1100 (binary) (equivalent OTF = 140°C)

7.6.28 TON_DELAY (60h)

The TON_DELAY command sets the time in milliseconds, from when a start condition is received to when the output voltage starts to rise. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The TON_DELAY command is formatted as a linear mode two’s complement binary integer.

COMMAND TON_DELAY
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.28.1 Exponent

default: 00000 (binary) 0 (decimal) (1 millisecond)

These default settings are not programmable.

7.6.28.2 Mantissa

The upper four bits are fixed at 0. The lower seven bits are programmable with a default value of 000 0000 0000 (binary) (0 ms).

Only 16 fixed TON_DELAY times are available in the device. As such, the range of programmed TON_DELAY settings are sub-divided into 16 buckets that then selects one of the 16 supported times. Programmed values are rounded to the nearest bucket/transition rate as outlined in the table Supported TON_DELAY Values:

Table 8. Supported TON_DELAY Values

EFFECTIVE TON_DELAY (ms) PROGRAMMED TON_DELAY MANTISSA (decimal)
Greater than Less than or equal to
0 (50 us) 0
1 0 1
2 1 2
3 2 3
4 3 4
5 4 5
6 5 6
7 6 9
10 9 12
14 12 17
19 17 22
27 22 32
37 32 44
52 44 62
72 62 86
100 86

7.6.29 TON_RISE (61h)

The TON_RISE command sets the time in milliseconds, from when the reference starts to rise until the voltage has entered the regulation band. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

Programming a value of 0 instructs the unit to bring its output voltage to the programmed regulation value as quickly as possible. For the TPS546C23 device, this results in an effective TON_RISE time of 1ms (fastest time supported).

The TON_RISE command is formatted as a linear mode two’s complement binary integer.

COMMAND TON_RISE
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1

7.6.29.1 Exponent

default: 00000 (binary) 0 (decimal) (1 millisecond)

These default settings are not programmable.

7.6.29.2 Mantissa

The upper four bits are fixed at 0. The lower seven bits are programmable with a default value of 000 0000 0011 (binary) (3 ms). For PWM loop slave device, the effective TON_RISE time is locked at 100 ms.

The supported TON_RISE times over PMBus are shown in Table 9:

Table 9. Supported TON_RISE Values

Effective TON_RISE (ms) Programmed TON_RISE Mantissa (d)
Greater than Less than or equal to
1 1
2 1 2
3 2 3
4 3 4
5 4 5
6 5 6
7 6 9
10 9 12
14 12 17
19 17 22
27 22 32
37 32 44
52 44 62
72 62 86
100 86

7.6.30 TON_MAX_FAULT_LIMIT (62h)

The TON_MAX_FAULT_LIMIT command sets an UPPER limt in milliseconds, on how long the unit can attempt to power up the output without reaching the output undervoltage fault limit. The time begins counting as soon as the device enters the soft-start state begins to ramp the output. In other words, the TON_MAX_FAULT_LIMIT timer starts at the beginning of the TON_RISE state.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

When TON_MAX_FAULT_LIMIT is set to 0, the TON_MAX_FAULT timer is disabled, which means that there is no limit and that the unit can attempt to bring up the output voltage indefinitely.

The device does not prohibit setting TON_MAX_FAULT_LIMIT < TON_RISE, however, in this configuration, the device will trigger a TON_MAX_FAULT if the VOUT has not risen above the UVF threshold by 4 seconds after the TON_DELAY and TON_RISE times expire.

The TON_MAX_FAULT_LIMIT command is formatted as a linear mode two’s complement binary integer.

COMMAND TON_MAX_FAULT_LIMIT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/w r/w r/w r/w r/w r/w r/w
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.30.1 Exponent

default: 00000 (binary) 0 (decimal) (Disable)

These default settings are not programmable.

7.6.30.2 Mantissa

The upper four bits are fixed at 0.

This register is not EEPROM backed, a RESTORE_DEFAULT_ALL command causes the TON_MAX_FAULT_LIMIT to restore to the default 0 ms value.

The supported TON_MAX_FAULT_LIMIT times over PMBus are shown in Supported TON_MAX_FAULT_LIMIT Values:

Table 10. Supported TON_MAX_FAULT_LIMIT Values

Effective TON_MAX_FAULT_LIMIT (ms) Programmed TON_MAX_FAULT_LIMIT Mantissa (d)
Greater than Less than or equal to
No Limit (timer disabled) 0
1 0 1
2 1 2
3 2 3
4 3 4
5 4 5
6 5 6
7 6 9
10 9 12
14 12 17
19 17 22
27 22 32
37 32 44
52 44 62
72 62 86
100 86

7.6.31 TON_MAX_FAULT_RESPONSE (63h)

The TON_MAX_FAULT_RESPONSE command instructs the device on what action to take in response to an TON_MAX_FAULT_LIMIT.

The device also:

  • Sets the oth bit in the STATUS_BYTE
  • Sets the VFW bit in the STATUS_WORD
  • Sets the TONMAXF bit in the STATUS_VOUT register, and
  • Notifies the host by asserting SMBALERT

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

The default response to a TON_MAX_FAULT is to shut down and restart with 7 × TON_RISE time delay.

COMMAND TON_MAX_FAULT_RESPONSE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r/wE r/w r/w r r r
Function RSP[1] 0 RS[2] RS[1] RS[0] TD[2] TD[1] TD[0]
Default Value 1 0 1 1 1 1 1 1

7.6.31.1 RSP[1] Bit

This bit sets the TON_MAX_FAULT response to either ignore or not. The default for this bit is 1.

BIT VALUE ACTION
0 The PMBus device continues operation without interruption. Note: In this ignore fault response mode, the associated fault status bits are set. Additionally, SMBALERT continues to be triggered if it is not masked.
1 The PMBus device shuts down and restarts according to RS[2:0].

7.6.31.2 RS[2:0] Bits

These bits are TON_MAX_FAULT retry setting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry setting means that the unit does not attempt to restart. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry setting means that the unit goes through a normal startup (soft start) continuously, without limitation, until it is commanded off or bias power is removed or another fault condition causes the unit to shutdown.

Any value other than 000 or 111 is not accepted. Attempting to write any other value is rejected, causing the device to assert SMBALERT along with the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML. Because all 3 bits must be the same, only one (bit 5) is stored in EEPROM.

7.6.31.3 TD[2:0] Bits

These bits are TON_MAX_FAULT retry time delay retting. The default for this bit is 111b.

BIT VALUE ACTION
000 A zero value for the retry time delay setting means that the unit does not attempt to delay a restart. This is only supported when restart is disabled by RS[2:0] = 000. The output remains disabled until the fault is cleared (Refer to section 10.7 of the PMBus specification)
111 A one value for the retry time delay setting means that the unit waits 7 TON_RISE times before it goes through a normal startup (soft start). This is only supported when restart is enabled by RS[2:0] = 111.

These bits are direct reflections of the RS[2] (bit 5) value in this register.

7.6.32 TOFF_DELAY (64h)

The TOFF_DELAY command sets the time in milliseconds, from when a stop condition is received and when the output voltage starts to fall. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The TOFF_DELAY command is formatted as a linear mode two’s complement binary integer.

COMMAND TOFF_DELAY
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.32.1 Exponent

default: 00000 (binary) 0 (decimal) (1 millisecond)

These default settings are not programmable.

7.6.32.2 Mantissa

The upper four bits are fixed at 0. The lower seven bits are programmable with a default value of 000 0000 0000 (binary) (0 ms).

Only 16 fixed TOFF_DELAY times are available in the device. As such, the range of programmed TOFF_DELAY settings are sub-divided into 16 buckets that then selects one of the 16 supported times. Programmed values are rounded to the nearest bucket/transition rate as outlined in the table Supported TOFF_DELAY Values:

Table 11. Supported TOFF_DELAY Values

EFFECTIVE TOFF_DELAY (ms) PROGRAMMED TOFF_DELAY MANTISSA (decimal)
Greater than Less than or equal to
0 0
1 0 1
2 1 2
3 2 3
4 3 4
5 4 5
6 5 6
7 6 9
10 9 12
14 12 17
19 17 22
27 22 32
37 32 44
52 44 62
72 62 86
100 86

7.6.33 TOFF_FALL (65h)

The TOFF_FALL command sets the time in milliseconds, from the end of the TOFF_DELAY time until the voltage reaches 0 V. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

Programming a value of 0 instructs the unit to bring its output voltage down to 0 as quickly as possible. For the TPS546C23 device, this results in actively ramping down the output voltage in 1 ms (the fastest supported ramp down).

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The TOFF_FALL command is formatted as a linear mode two’s complement binary integer.

COMMAND TOFF_FALL
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function Exponent Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.33.1 Exponent

default: 00000 (binary) 0 (decimal) (1 millisecond)

These default settings are not programmable.

7.6.33.2 Mantissa

The upper four bits are fixed at 0. The lower seven bits are programmable with a default value of 000 0000 0000 (binary) (0 ms).

The supported TOFF_FALL times over PMBus are shown in Supported TOFF_FALL Values:

Table 12. Supported TOFF_FALL Values

Effective TOFF_FALL (ms) Programmed TOFF_FALL Mantissa (d)
Greater than Less than or equal to
1 1
2 1 2
3 2 3
4 3 4
5 4 5
6 5 6
7 6 9
10 9 12
14 12 17
19 17 22
27 22 32
37 32 44
52 44 62
72 62 86
100 86

7.6.34 STATUS_BYTE (78h)

The STATUS_BYTE command returns one byte of information with a summary of the most critical device faults.

COMMAND STATUS_BYTE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r r
Function X OFF OVF OCF X OTFW CML oth
Default Value 0 X 0 0 0 0 0 1

A 1 in any of these bit positions indicates that:

    OFF The device is not providing power to the output, regardless of the reason. In this family of devices, this flag means that the converter is not enabled.
    OVF An output overvoltage fault has occurred. This bit directly reflects the state of STATUS_VOUT[7] – OVF. If the user wants this fault source to be masked and not trigger SMBALERT, they must do it by masking STATUS_VOUT[7]. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_VOUT that cause this bit to be set. For loop slave device, this bit is 0.
    OCF An output overcurrent fault has occurred. This bit directly reflect the state of STATUS_IOUT[7] – OCF. If the user wants this fault sourced to be masked and not trigger SMBALERT, they must do it by masking STATUS_IOUT[7]. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_IOUT that cause this bit to be set.
    OTFW A temperature fault or warning has occurred. Check STATUS_TEMPERATURE. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_TEMPERATURE that cause this bit to be set.
    CML A communications, memory or logic fault has occurred. Check STATUS_CML. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_CML that cause this bit to be set.
    oth A fault or warning not listed through bits 1-7 has occurred, which include an undervoltage fault, over current warning, overvotlge warning, undervoltage warning, TON_MAX_FAULT, LOW_VIN, VOUT_MAX_MIN_Warning, OTF_BG, or IV_PPV1. Check other status registers. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_VOUT, STATUS_IOUT, STATUS_IOUT (7Bh), or STATUS_MFR_SPECIFIC (80h)that cause this bit to be set. The default for this bit is 1 because the default of STATUS_INPUT[3] LOW_Vin defaulting to 1.

7.6.35 STATUS_WORD (79h)

The STATUS_WORD command returns two bytes of information with a summary of the device fault and warning conditions. The low byte is identical to the STATUS_BYTE above. The additional byte reports the warning conditions for output overvoltage and overcurrent, as well as the power good status of the converter.

COMMAND STATUS_WORD (low byte) = STATUS_BYTE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r r
Function X OFF OVF OCF x OTFW CML oth
Default Value 0 X 0 0 0 0 0 1
COMMAND STATUS_WORD (high byte)
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r rE r r r
Function VFW OCFW INPUT MFR PGOOD_Z X X X
Default Value 0 0 X 0 X 0 0 0

A 1 in any of the high byte bit positions indicates that:

    VFW An output voltage fault or warning has occurred (OVF or OVW or UVW or UVF or VOUT_MAX_Warning or TONMAXF). Check STATUS_VOUT. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_VOUT that cause this bit to be set.
    OCFW An output current warning or fault has occurred (OCF or OCW). Check STATUS_IOUT. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_IOUT that cause this bit to be set.
    INPUT INPUT fault or warning in STATUS_INPUT is present. Check STATUS_INPUT. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_INPUT that cause this bit to be set.
    MFR An manufacturer specific fault or warning condition has occurred (over temperature fault from Bandgap or IV_PPV1). Check STATUS_MFR_SPECIFIC. Per the PMBus v1.3 spec sections 10.2.4 and 10.2.5, this bit is not clearable through a PMBus write. In contrast, the bit is to be cleared by clearing the bits in STATUS_MFR_SPECIFIC that cause this bit to be set.
    PGOOD_Z Power is not good, and the following condition is present: output over or under voltage warning or fault, TON_MAX_FAULT, over temperature warning or fault, over current warning or fault, insufficient input voltage. Please refer to the FAULT RESPONSE table for the possible sources to trigger PGOOD_Z. The signal is unlatched and always represents the current state of the device. The factory default setting for PGOOD_Z mask bit is 1, indicating that PGOOD_Z itself cannot trigger SMBALERT by default. If unmask PGOOD_Z bit, the SMBALERT is set not to trigger before Power Good going high the first time, which is to avoid the device holding up SMBALERT bus when it is not commanded to start up and PGOOD stays low.

7.6.36 STATUS_VOUT (7Ah)

The STATUS_VOUT command returns one byte of information relating to the status of the output voltage related faults.

COMMAND STATUS_VOUT
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r/wE r/wE r/wE r/wE r/wE r r
Function OVF OVW UVW UVF VOUT_MAX_MIN_Warning TONMAXF X X
Default Value 0 0 0 0 0 0 0 0

A 1 in any of these bit positions indicates that:

    OVF The device has seen the output voltage rise above the output overvoltage fault threshold VOUT_OV_FAULT_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.
    OVW The device has seen the output voltage rise above the output overvoltage warn threshold VOUT_OV_WARN_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.
    UVW The device has seen the output voltage fall below the output undervoltage warn threshold VOUT_UV_WARN_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.
    UVF The device has seen the output voltage fall below the output undervoltage fault threshold VOUT_UV_FAULT_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.
    VOUT_MAX_MIN_Warning An attempt is made to program the VOUT_COMMAND in excess of the value in VOUT_MAX or under the value in VOUT_MIN. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.
    TONMAXF A TON_MAX_FAULT has occurred. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. For loop slave device, this bit is forced to 0.

7.6.37 STATUS_IOUT (7Bh)

The STATUS_IOUT command returns one byte of information relating to the status of the output current related faults.

COMMAND STATUS_IOUT
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r/wE r r r r r
Function OCF X OCW X X X X X
Default Value 0 0 0 0 0 0 0 0

A 1 in any of these bit positions indicates that:

    OCF The device has seen the output current rise above the level set by IOUT_OC_FAULT_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    OCW The device has seen the output current rise above the level set by IOUT_OC_WARN_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.

7.6.38 STATUS_INPUT (7Ch)

The STATUS_INPUT command returns one byte of information relating to the status of the input-related faults of the converter.

COMMAND STATUS_INPUT
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r/wE r r r
Function X X X X LOW_Vin X X X
Default Value 0 0 0 0 1 0 0 0

A 1 in any of these bit positions indicates that:

    LOW_Vin The unit is off because of insufficient input voltage. The bit sets when the unit powers up and stays set until the first time AVIN exceeds VIN_ON. During the initial power up, LOW_Vin is not latched and does not trigger SMBALERT. Once AVIN does exceed VIN_ON for the first time, any subsequent AVIN < VIN_OFF events are latched, trigger SMBALERT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.

7.6.39 STATUS_TEMPERATURE (7Dh)

The STATUS_TEMPERATURE command returns one byte of information relating to the status of the external temperature related faults.

COMMAND STATUS_TEMPERATURE
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r/wE r r r r r r
Function OTF OTW X X X X X X
Default Value 0 0 0 0 0 0 0 0

A 1 in any of these bit positions indicates that:

    OTF The measured external temperature value of READ_TEMPERATURE_1 is equal to or greater than the level set by OT_FAULT_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. However, once cleared, the bit is set again unless the value in READ_TEMPERATURE_1 has fallen 20°C from the OT_FAULT_LIMIT.
    OTW The measured external temperature value of READ_TEMPERATURE_1 is equal to or greater than the level set by OT_WARN_LIMIT. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK. However, once cleared, the bit is set again unless the value in READ_TEMPERATURE_1 has fallen 20°C from the OT_WARN_LIMIT.

7.6.40 STATUS_CML (7Eh)

The STATUS_CML command returns one byte of information relating to the status of the communication-related faults of the converter.

COMMAND STATUS_CML
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r/wE r/wE r/wE r r r/wE r
Function ivc ivd pec mem X X oth X
Default Value 0 0 0 0 0 0 0 0

A 1 in any of these bit positions indicates that:

    ivc An invalid or unsupported command has been received. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    ivd An invalid or unsupported data has been received. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    pec A packet error check failed. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    mem A fault has been detected with the internal memory. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    oth Some other communication fault or error has occurred. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.

7.6.41 STATUS_MFR_SPECIFIC (80h)

The STATUS_MFR_SPECIFIC command returns one byte of information relating to the status of manufacturer-specific faults or warnings.

COMMAND STATUS_MFR_SPECIFIC
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r/wE r r r/wE r r r r
Function otf_bg illzero illmany1s iv_ppv1 iv_ppv0 0 is_Slave sync_flt
Default Value 0 0 0 0 0 0 0 0

A 1 in any of these bit positions indicates that:

    otf_bg The internal temperature from bandgap is above the thermal shutdown (TSD) fault threshold. This bit is writeable to clear and the EEPROM bit is for SMBALERT_MASK.
    illzero The operation FSM has hit an illegal ZERO state. The FSM is a one-hot implementation, so all zeros in the state is illegal and should never occur. This event is informational only and would not trigger SMBALERT.
    illmany1s The operation FSM for has hit an illegal more than one hot state. The FSM is a one-hot implementation, so a state where multiple state bits are HI is illegal and should never occur. This event is informational only and would not trigger SMBALERT.
    iv_ppv1 The ADDR1 detection fails to resolve 4 consecutive values. To avoid initial turnon events from clearing this condition and the user not being aware why the default ADDR1 value was used, this bit is only clearable through the CLEAR_FAULTS command or writing a logic 1 to this bit, essentially off and on events do not clear it as with the other standard status bits. This condition will trigger SMBALERT.
    iv_ppv0
    sync_flt A synchronization fault. This could be because (a) Clock slave: an expected external SYNC was never present; or present, then lost, or (b) Clock master: an internal SYNC signal is not sensed on the SYNC pin. This bit is a live (essentially, unlatched) indicator. This event is informational only and would not trigger SMBALERT.

7.6.42 READ_VOUT (8Bh)

The READ_VOUT commands returns two bytes of data in the linear data format that represent the output voltage of the converter. The output voltage is sensed at the remote sense amplifier output pin so voltage drop to the load is not accounted for. The data format is as shown below:

COMMAND READ_VOUT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r r r
Function Mantissa
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.42.1 Exponent

Value fixed at 10111, Exponent for linear mode values is –9 (equivalent of 1.95 mV/count, specified in the VOUT_MODE command).

7.6.42.2 Mantissa

Use Equation 12 to calculate the output voltage.

Equation 12. TPS546C23 q_voutmantissa_lusaq4.gif

7.6.43 READ_IOUT (8Ch)

The READ_IOUT commands returns two bytes of data in the linear data format that represent the output current of the converter. The average output current is sensed according to the method described in Low-Side MOSFET Current Sensing and Overcurrent Protection. The data format is as shown below:

COMMAND READ_IOUT
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r r r
Function Exponent Mantissa
Default Value 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0

The device scales the output current before it reaches the internal analog to digital converter so that resolution of the output current read is 62.5 mA. The maximum value that can be reported is 40 A. The user must set the IOUT_CAL_OFFSET parameter correctly to obtain accurate results. Use Equation 13 to calculate the output current.

Equation 13. TPS546C23 q_ioutm_lus930.gif

7.6.43.1 Exponent

default: 11100 (binary) -4 (decimal) (62.5 mA LSB)

These default settings are not programmable.

7.6.43.2 Mantissa

The lower 10 bits are the result of the ADC conversion of the average output current, as indicated by the output of the internal current sense amplifier. The 11th bit is fixed at 0 because only positive numbers are considered valid. Any computed negative current is reported as 0 A.

7.6.44 READ_TEMPERATURE_1 (8Dh)

The READ_TEMPERATURE_1 command returns the external temperature in degrees Celsius.

COMMAND READ_TEMPERATURE_1
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r r r
Function Exponent Mantissa

7.6.44.1 Exponent

default: 00000 (binary) 0 (decimal)

These default settings are not programmable.

7.6.44.2 Mantissa

The lower 11 bits are the result of the ADC conversion of the external temperature.

7.6.45 PMBUS_REVISION (98h)

The PMBUS_REVISION command returns a single, unsigned binary byte that indicates that these devices are compatible with the 1.3 revision of the PMBus specification (Part I and Part II).

COMMAND PMBUS_REVISION
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r r
Default Value 0 0 1 1 0 0 1 1

7.6.46 IC_DEVICE_ID (ADh)

Th IC_DEVICE_ID command is a read-only block-read command that returns a single word (16 bits) with the unique device-code identifier for each device for which this device can be configured. The BYTE_COUNT field in the block read command is 2 (indicating 2 bytes follow): low byte first, high byte second.

COMMAND IC_DEVICE_ID
Format Linear, binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r r r
Default Value See below

The default for the device identifier code is 4623h – Code Identifier for TPS546C23.

7.6.47 IC_DEVICE_REV (AEh)

The IC_DEVICE_REV command is a read-only block-read command that returns a single word (16 bits) with the unique Device revision identifier. The DEVICE_REV starts at 0 with the first silicon and is incremented with each subsequent silicon revision. The BYTE_COUNT field in the Block Read command is 2 (indicating 2 bytes follow): low byte first, high byte second.

COMMAND IC_DEVICE_REV
Format Linear, tbinary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r r r r r
Default Value See below

The default of the device identifier code is 0001b.

7.6.48 MFR_SPECIFIC_00 (D0h)

The MFR_SPECIFIC_00 command is dedicated as a user scratch pad. Only the lower 8 bits are writeable for users. This is a read word command, with only the lower 8 bits accessible. This command is not a read byte command. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

COMMAND MFR_SPECIFIC_00
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE r/wE r/wE
Function User scratch pad
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

7.6.49 VREF_TRIM (MFR_SPECIFIC_04) (D4h)

The VREF_TRIM command applies a fixed offset voltage to the Error Amplifier reference (EA_REF) voltage. It is most typically used to trim the output voltage at the time the PMBus device is assembled into the end user’s system. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The settings of the VOUT_MODE command determine the effect of VREF_TRIM command. In this device, the VOUT_MODE is fixed to Linear with an exponent of –9 (decimal).

Equation 14. EA_REF = [(VOUT_COMMAND × VOUT_SCALE_LOOP) + (VREF_TRIM + STEP_VREF_MARGIN_HIGH × OPERATION[5] + STEP_VREF_MARGIN_LOW × OPERATION[4])] × 1.953 mV

The maximum trim ranges between –64*1.953 mV to +63*1.953 mV in 1.953-mV steps.

If a value outside this range is given with this command, the device sets the reference voltage to the upper or lower limit depending on the direction of the setting, asserts SMBALERT and sets the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML.

The value of EA_REF including VREF_TRIM is also limited by the values of VOUT_MAX, VOUT_MIN, VOUT_COMMAND, VOUT_SCALE_LOOP and STEP_VREF_MARGIN_HIGH/LOW. See VOUT_MAX and VOUT_MIN for additional details.

The EA_REF voltage transition occurs at the rate determined by the current state:

The VREF_TRIM has two data bytes formatted as two’s complement binary integer and can have positive and negative values.

COMMAND VREF_TRIM
Format Linear, two’s complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r/wE r r r r r r r r r r/wE r/wE r/wE r/wE r/wE r/wE
Function High Byte Low Byte
Default Value 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

High Byte:

default: 0000 0000 (binary) 0 (decimal)

Minimum: 1111 1111 (binary) (sign extended)

Maximum: 0000 0000 (binary) (sign extended)

Low Byte:

default: 0000 0000 (binary) 0 (decimal)

Minimum: 1100 0000 (binary) –64 (decimal) (–125 mV) (sign extended, two's compliment)

Maximum: 0011 1111 (binary) 63 (decimal) (123 mV)

7.6.50 STEP_VREF_MARGIN_HIGH (MFR_SPECIFIC_05) (D5h)

The STEP_VREF_MARGIN_HIGH command, specifing a positive offset voltage on EA_VREF, is used to increase the reference voltage by shifting the reference higher. When the OPERATION command is set to Margin High, the output will increase by the voltage indicated by this command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The effect of this command is determined by the settings of the VOUT_MODE command. In this device, the VOUT_MODE is fixed to Linear with an exponent of –9 (decimal). The actual reference voltage commanded by a margin high command can be found in Equation 14.

The margin high range is between 0 and 31 × 1.953 mV in 1.953-mV steps.

If a value outside this range is given with this command, the device sets the reference voltage to the upper or lower limit depending on the direction of the setting, asserts SMBALERT and sets the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML.

The value of EA_REF including STEP_VREF_MARGIN_HIGH is also limited by the values of VOUT_MAX, VOUT_MIN, VOUT_COMMAND, VOUT_SCALE_LOOP and VREF_TRIM. See VOUT_MAX and VOUT_MIN for additional details.

The EA_REF voltage transition occurs at the rate determined by the current state:

COMMAND STEP_VREF_MARGIN_HIGH
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r r r r r/w r/w r/w r/w r/w
Function High Byte Low Byte

High Byte:

default: 0000 0000 (binary) 0 (decimal)

Low Byte:

Minimum: 0000 0000 (binary) 0 (decimal) (0 mV)

Maximum: 0001 1111 (binary) 31 (decimal) (60.5 mV)

The read-writeable bits in this register do NOT have direct EEPROM backup; however, the register does restore to one of two configurable values as determined by RSMHI_VAL in (E5h) MFR_SPECIFIC_21 (OPTIONS).

  • RSMHI_VAL = 0: STEP_VREF_MARGIN_HIGH will restore to 0009h (9 decimal or 17.6 mV).
  • RSMHI_VAL = 1: STEP_VREF_MARGIN_HIGH will restore to 000fh (15 decimal or 29.3 mV).

7.6.51 STEP_VREF_MARGIN_LOW (MFR_SPECIFIC_06) (D6h)

The STEP_VREF_MARGIN_LOW command, specifying a negative offset voltage on EA_VREF, is used to decrease the reference voltage by shifting the reference lower. When the OPERATION command is set to Margin Low, the output will decrease by the voltage indicated by this command.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The effect of this command is determined by the settings of the VOUT_MODE command. In this device, the VOUT_MODE is fixed to Linear with an exponent of –9 (decimal). The actual reference voltage commanded by a margin low command can be found in Equation 14.

The margin low range is between -64*1.953 mV and -1*1.953 mV in 1.953-mV steps.

If a value outside this range is given with this command, the device sets the reference voltage to the upper or lower limit depending on the direction of the setting, asserts SMBALERT and sets the CML bit in STATUS_BYTE and the invalid data bit in STATUS_CML.

The value of EA_REF including STEP_VREF_MARGIN_LOW is also limited by the values of VOUT_MAX, VOUT_MIN, VOUT_COMMAND, VOUT_SCALE_LOOP and VREF_TRIM. See VOUT_MAX and VOUT_MIN for additional details.

The EA_REF voltage transition occurs at the rate determined by the current state:

COMMAND STEP_VREF_MARGIN_LOW
Format Linear, two's complement binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r/w r r r r r r r r r r/w r/w r/w r/w r/w r/w
Function High Byte Low Byte

High Byte:

default: 1111 1111 (binary) (MSB is sign bit, sign extended)

Low Byte:

Minimum: 1100 0000 (binary) –64 (decimal) (–125 mV)

Maximum: 1111 1111 (binary) –1 (decimal) (–2 mV)

The read-writeable bits in this register do NOT have direct EEPROM backup; however, the register does restore to one of two configurable values as determined by RSMLO_VAL in (E5h) MFR_SPECIFIC_21 (OPTIONS).

  • RSMLO_VAL = 0: STEP_VREF_MARGIN_LOW will restore to fff7h (–9 decimal or –17.6 mV)
  • RSMLO_VAL = 1: STEP_VREF_MARGIN_LOW will restore to fff1h (–15 decimal or –29.3 mV)

7.6.52 PCT_OV_UV_WRN_FLT_LIMITS (MFR_SPECIFIC_07) (D7h)

The PCT_OV_UV_WRN_FLT_LIMITS command is used to set the PGOOD, VOUT_UNDER_VOLTAGE (UV) and VOUT_OVER_VOLTAGE (OV) limits as a percentage of nominal.

For loop slave device, this command cannot be accessed. Any writes to this command will be ignored. An attempt to read or write this command will result in a NACK’d command, the reporting of an IVC fault, and triggering of SMB_ALERT.

The PCT_OV_UV_WRN_FLT_LIMITS takes a one byte data formatted as shown below:

COMMAND PCT_OV_UV_WRN_FLT_LIMITS
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0
Access r r r r r r r/wE r/wE
Function X X X X X X PCT_MSB PCT_LSB
Default Value 0 0 0 0 0 0 0 0

The PGOOD, VOUT_UNDER_VOLTAGE (UV) and VOUT_OVER_VOLTAGE (OV) settings are shown in Table 13, as a percentage of nominal reference voltage on the FB pin.

Table 13. OV/UV Protection Settings (Typical Values)

PCT_MSB PCT_LSB UV FAULT UV WARN OV WARN OV FAULT UNIT
0 0 –83% –88% 112% 117% EA_REF
0 1 –88% –90% 110% 112% EA_REF
1 0 –72% –78% 112% 117% EA_REF
1 1 –58% –64% 112% 117% EA_REF

The PGOOD pin may trip if the output voltage is too high (using OV WARN) or too low (using UV WARN). Additionally, the PGOOD pin has hysteresis. When the OV WARN output voltage OV WARN is tripped, the FB voltage must lower below the 105% of EA_REF, before PGOOD is reset. Likewise, when output voltage UV WARN is tripped, the FB voltage must rise above 95% of EA_REF, before PGOOD is reset.

7.6.53 OPTIONS (MFR_SPECIFIC_21) (E5h)

The OPTIONS register can be used for setting user selectable options, as shown below. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

COMMAND OPTIONS
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r/wE r/wE r/wE r/wE r/wE r/w r/wE r/wE r/wE r/wE r/w r/w r/wE r/wE r/wE
Function X RSMHI_
VAL		 RSMLO_
VAL		 x RST_VOUT_
oSD		 x READ_VOUT_
RANGE[1:0]		 EN_AUTO_
ARA		 AVG_
PROG[1:0]		 DLO VSM EN_ADC_
CNTL		 EN_RESET_
B		 DIS_
NEGILIM
Default Value 0 0 0 1 0 0 0 1 1 0 0 0 0 1 0 0

7.6.53.1 DIS_NEGILIM Bit

When set, this bit disables the negative current limit protection on the LFET.

7.6.53.2 EN_RESET_B Bit

When set, this bit enables the RESET_B functionality of the RESET/PGD pin.

BIT VALUE ACTION
0 RESET/PGD pin = PGOOD
1 RESET/PGD pin = RESET_B

7.6.53.3 EN_ADC_CNTL Bit

This bit enables ADC operation used for voltage, current and temperature monitoring.

BIT VALUE ACTION
0 Disable ADC operation
1 Enable ADC operation

NOTE

The EN_ADC_CNTL bit must be set to enable output voltage, current and temperature telemetry. When the EN_ADC_CNTL bit is zero, the READ_VOUT, READ_IOUT and READ_TEMPERATURE_2 registers do not update continuously, and retain the previous values from the last time EN_ADC_CNTL was set.

7.6.53.4 VSM Bit

This bit configures the measurement system for fast, VOUT-only measurement mode. Setting this bit disables READ_IOUT, and READ_TEMPERATURE_1, and instead allows the device to update READ_VOUT more frequently. This bit does not have EEPROM backup.

BIT VALUE ACTION
0 Measure VOUT, temperature, and IOUT
1 Measure only VOUT

NOTE

For READ_VOUT, multiple samples (defined by AVG_PROG[1:0] Bits) are obtained and averaged. When entering and exiting VSM mode, the first calculated result could lose one sample, for example, 7 sampled value but averaged by 8, resulting the first updated READ_VOUT data point have worst case error about 1/8 of the nominal value.

7.6.53.5 DLO Bit

This bit allows bypassing the normal valid data checks on register writes. This feature is included for flexibility during debug to quickly generate fault conditions and/or possibly work around any data limit protection mechanisms prohibiting output voltage programming. This bit does not have EEPROM backup.

BIT VALUE ACTION
0 Normal PMBus data write restrictions
1 Data write restrictions are overridden for the following registers: SMBALERT_MASK, VOUT_COMMAND, VOUT_SCALE_LOOP, VREF_TRIM, STEP_VREF_MARGIN_HIGH, STEP_VREF_MARGIN_LOW, IOUT_OC_FAULT_LIMIT, IOUT_OC_WARN_LIMIT, OT_FAULT_LIMIT, OT_WARN_LIMIT, VOUT_MIN, VOUT_MAX, VIN_ON, VIN_OFF, and OPERATION.

NOTE

CAUTION: Users should use this bit with extreme caution. Setting this bit allows invalid data conditions to be programmed into the device which can lead to damage. Invalid data written into any register when DLO is enabled does NOT set the IVD bit; nor trigger SMBALERT. The invalid data is simply allowed to be programmed. Furthermore, invalid data programmed into a command/status register while DLO is enabled, does not trigger SMBALERT upon deassertion of DLO. So, it is possible to exit DLO mode with invalid data in command/status registers. Use with extreme caution.

7.6.53.6 AVG_PROG[1:0] Bits

These bits configure programmable digital measurement averaging. Bits provide programmable averaging for current (READ_IOUT), temperature (READ_TEMPERATURE_1), and voltage (READ_VOUT). The default (00b) yields 16x averaging for all three parameters; however, this default can be changed and stored in EEPROM, if necessary. The programming options are as follows:

BIT VALUE ACTION
00 Accumulating Averaging = 16x
01 Accumulating Averaging = 0x. Use this setting to bypass the averagers. Every sample from measurement system updates corresponding READ_XXX CSR.
10 Accumulating Averaging = 8x
11 Accumulating Averaging = 32x

7.6.53.7 EN_AUTO_ARA Bit

This bit enables auto-alert response address response. When this feature is enabled, and after the device has successfully responded to an ARA transaction, the hardware automatically masks any fault source currently set from reasserting SMBALERT. This prevents PMBus bus hogging in the case of a persistent fault in a device that consistently wins ARA arbitration because of the device address. In contrast, when this bit is cleared, immediate reassertion of SMBALERT is allowed in the event of a persistent fault and the responsibility is upon the host to mask each source individually.

7.6.53.8 READ_VOUT_RANGE[1:0] Bits

The ADC input voltage range is limited to 0.9 V. For READ_VOUT, the output voltage is divided down before input to ADC. Large signal amplitude gives better signal-to-noise ratio. The READ_VOUT_RANGE[1:0] bits are used to force the input voltage divider of the internal ADC for output voltage measurement to one of the 3 possible values.

VOUT_SCALE_LOOP READ_VOUT_RANGE[1:0] OUT
1 00b 1/2 IN
x 11b
0.5 00b 1/4 IN
x 10b
0.25 00b 1/8 IN
x 01b

7.6.53.9 RST_VOUT_oSD Bit

When set high, this bit is used to force VOUT_COMMAND to the default value upon any shutdown or fault condition:

  • FAULT with programmed shutdown response
  • FAULT with programmed restart response
  • Normal, controlled shutdown (e.g. CNTL pin)
  • LOW_VIN

7.6.53.10 RSMLO_VAL Bit

The restore step-margin low-value (RSMLO_VAL) bit is used to configure the default restore value for (D6h) MFR_SPECIFIC_06 (STEP_VREF_MARGIN_LOW).

BIT VALUE ACTION
0 STEP_VREF_MARGIN_LOW will restore to fff7h (–9 decimal or –17.6 mV)
1 STEP_VREF_MARGIN_LOW will restore to fff1h (–15 decimal or –29.3 mV)

7.6.53.11 RSMHI_VAL Bit

This restore step margin high value (RSMHI_VAL) bit is used to configure the default restore value for (D5h) MFR_SPECIFIC_05 (STEP_VREF_MARGIN_HIGH).

BIT VALUE ACTION
0 STEP_VREF_MARGIN_HIGH will restore to 0009h (9 decimal or 17.6 mV)
1 STEP_VREF_MARGIN_HIGH will restore to 000fh (15 decimal or 29.3 mV)

7.6.54 MISC_CONFIG_OPTIONS (MFR_SPECIFIC_32) (F0h)

This user-accessible register is used for miscellaneous options, as shown below. The contents of this register can be stored to nonvolatile memory using the STORE_DEFAULT_ALL command.

COMMAND MISC_CONFIG_OPTIONS
Format Unsigned binary
Bit Position 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Access r r r r r r r r/wE r/wE r/wE r r/wE r r/wE r/wE r/wE
Function X X X X X X X SYNC_FAULT_DIS FORCE_SYNC_IN FORCE_SYNC_OUT X EN_AVS_USER X HSOC_USER_TRIM[1:0] OV_RESP_SEL
Default Value 0 0 0 0 0 0 0 0 0 0 0 1 0 0 1 1

7.6.54.1 OV_RESP_SEL Bit

This bit selects between two options for low-side FET behavior after an output overvoltage fault condition. Regardless of the setting of this bit, the low-side FET latches on when an output OV fault is detected (if the OV_FAULT_RESPONSE is not programmed to ignore).

BIT VALUE ACTION
0 The low-side FET remains on until either the part initiates a new startup of the output voltage or the CLEAR_FAULTS command is given while the part is in the DISABLE operational state
1 The low-side FET turns off as soon as the sensed output (at FB pin) drops below 0.2 V.

7.6.54.2 HSOC_USER_TRIM[1:0] Bits

These trim bits are provided so the user can adjust the HSOC threshold to account for the application-specific requirements for input-voltage sensing parasitics and component-current handling. The bit settings are defined as follows:

BIT VALUE ACTION
00 HSOC change from default = 0
01 HSOC change from default = 12.5%
10 HSOC change from default = –25%
11 HSOC change from default = –12.5%

7.6.54.3 EN_AVS_USER Bit

Setting this bit high is required enabling the COMP-level shifter that eliminates overshoot and undershoot of VOUT when the reference is ramped. The value of this bit is latched when the driver is enabled to swtich which prevents the user from enabling or disabling the level shifter while the output is switching.

7.6.54.4 FORCE_SYNC_OUT Bit

This bit forces the device to output the free-running clock on the SYNC pin.

7.6.54.5 FORCE_SYNC_IN Bit

This bit forces the device to be synchronized to an external PWM clock applied on the SYNC pin.

7.6.54.6 SYNC_FAULT_DIS Bit

When set, this bit disables any reporting (digital status) and response (analog and digital) upon SYNC_FAULT.