LTM4678S
Synchronous Buck ConverterThe LTM4678S is a synchronous buck converter from Analog Devices. View the full LTM4678S datasheet below including specifications and datasheet sections.
Manufacturer
Analog Devices
Category
Synchronous Buck Converter
Overview
Part: LTM4678 — Analog Devices (formerly Linear Technology)
Type: Dual 25A or Single 50A Step-Down μModule (Power Module) DC/DC Regulator
Description: The LTM4678 is a dual 25A or single 50A step-down μModule DC/DC regulator with a wide input voltage range of 4.5V to 16V, an output voltage range of 0.5V to 3.4V, and a PMBus-compliant I2C serial interface for remote configurability and telemetry monitoring.
Operating Conditions:
- Supply voltage: 4.5V to 16V
- Operating temperature: -40°C to 125°C
- Output voltage range: 0.5V to 3.4V
- Switching frequency: 350kHz (typical, factory default)
Absolute Maximum Ratings:
- Max supply voltage: 16V (V IN n, SV IN, I IN+, I IN-)
- Max continuous current: 25A (per channel)
- Max internal operating temperature: 125°C
- Storage temperature range: -55°C to 150°C
Key Specs:
- Input DC Voltage (V IN n, SV IN): 4.5V (min) to 16V (max)
- Output Voltage Range (V OUT n): 0.5V (min) to 3.4V (max)
- Output Continuous Current Range (I OUT n): 0A to 25A
- Output Voltage, Total Variation with Line and Load (V OUT n (DC)): ±0.5% (max, Digital Servo Engaged)
- Line Regulation Accuracy (∆V OUT n (LINE) / V OUT n): ±0.2 %/V (max, Digital Servo Engaged)
- Load Regulation Accuracy (∆V OUT n (LOAD) / V OUT n): 0.5% (max, Digital Servo Disengaged)
- Output Voltage Ripple (V OUT n (AC)): 10 mV P-P (typical)
- Input Supply Bias Current (I Q(SVIN)): 25 mA (typical, Forced Continuous Mode)
Features:
- Dual Digitally Adjustable Analog Loops with Digital Interface for Control and Monitoring
- PMBus-Compliant I2C Serial Interface (400kHz)
- Integrated 16-Bit ∆Σ ADC
- Sub-Milliohm DCR Current Sensing
- Integrated Input Current Sense Amplifier
- Parallel and Current Share Up to 250A
- Onboard EEPROM Fault Log Record
- Supports Telemetry Polling Rates up to 125Hz
Applications:
- System Optimization, Characterization and Data Mining in Prototype, Production and Field Environments
Package:
- 16mm × 16mm × 5.86mm CoP-BGA Package
Features
- n Dual Digitally Adjustable Analog Loops with Digital Interface for Control and Monitoring
- n Wide Input Voltage Range: 4.5V to 16V
- n Output Voltage Range: 0.5V to 3.4V
- n ±0.5% Maximum DC Output Error Over Temperature
- n ±3.5% Current Readback Accuracy, -20°C to 125°C
- n Sub-Milliohm DCR Current Sensing
- n Integrated Input Current Sense Amplifier
- n 400kHz PMBus-Compliant I 2 C Serial Interface
- n Supports Telemetry Polling Rates up to 125Hz
- n Integrated 16-Bit ∆ Σ ADC
- n Constant Frequency Current Mode Control
- n Parallel and Current Share Up to 250A
- n 16mm × 16mm × 5.86mm CoP-BGA Package
Applications
- n System Optimization, Characterization and Data Mining in Prototype, Production and Field Environments
Pin Configuration
The l denotes the specifications which apply over the specified internal operating temperature range (Note 2). n is specified as each individual output channel (Note 4). T A = 25°C, V IN = 12V, RUN n = 3.3V, EXTV CC = 0, FREQUENCY_SWITCH = 350kHz and V OUT n commanded to 1.000V unless otherwise noted. Configured with factory-default EEPROM settings and per Test Circuit 1, unless otherwise noted.
| SYMBOL | PARAMETER | CONDITIONS | MIN | TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|---|
| V IN n , SV IN | Input DC Voltage | Test Circuit 1 Test Circuit 2; VIN_OFF < VIN_ON = 4V | l l | 5.75 4.5 | 16 5.75 | V V | |
| V OUT n | Range of Output Voltage Regulation | V OUT0 Differentially Sensed on V OSNS0 + /V OSNS0 - Pin-Pair; V OUT1 Differentially Sensed on V OSNS1 + /V OSNS1 - Pin-Pair; Commanded by Serial Bus or with Resistors Present at Start- Up on V OUT n_ CFG (Note 19) | l l | 0.5 0.5 | 3.4 3.4 | V V | |
| V OUT n (DC) | Output Voltage, Total Variation with Line and Load | (Note 5) Digital Servo Engaged (MFR_PWM_MODE n [6] = 1b) Digital Servo Disengaged (MFR_PWM_MODE n [6] = 0b) V OUT n Commanded to 1.000V, V OUT n Low Range (MFR_PWM_MODE n [1] = 1b) | l | 0.995 0.985 | 1.000 1.000 | 1.005 1.015 | V V |
| V UVLO | Undervoltage Lockout Threshold, When V IN < 4.3V | V INTVCC Falling V INTVCC Rising | 3.55 3.90 | V V | |||
| Input Specifications | Input Specifications | Input Specifications | Input Specifications | Input Specifications | Input Specifications | Input Specifications | Input Specifications |
| I INRUSH(VIN) | Input Inrush Current at Start-Up | Test Circuit 1, V OUT n =1V, V IN = 12V; No Load Besides Capacitors; TON_RISE n = 3ms | 400 | mA | |||
| I Q(SVIN) | Input Supply Bias Current | Forced Continuous Mode, MFR_PWM_MODE n [0] = 1b RUN n = 3.3V Shutdown, RUN0 = RUN1 = 0V (Note 16) | 25 23 | mA mA | |||
| I S(VIN n ,PSM) | Input Supply Current in Pulse- Skipping Mode Operation | Pulse-Skipping Mode, MFR_PWM_MODE n [0] = 0b, I OUT n = 100mA | 20 | mA | |||
| I S(VIN n ,FCM) | Input Supply Current in Forced- Continuous Mode Operation | Forced Continuous Mode, MFR_PWM_MODE n [0] = 1b I OUT n = 100mA I OUT n = 25A | 50 2.4 | mA A | |||
| Output Specifications | Output Specifications | Output Specifications | Output Specifications | Output Specifications | Output Specifications | Output Specifications | Output Specifications |
| I OUT n | Output Continuous Current Range | (Note 6) Utilizing MFR_PWM_MODE[7] = 1 and Using ~I OUT = 36A for IOUT_OC_FAULT_LIMIT, Page 89 | 0 | 25 | A | ||
| ∆V OUT n (LINE) V OUT n | Line Regulation Accuracy | Digital Servo Engaged (MFR_PWM_MODE n [6] = 1b) Digital Servo Disengaged (MFR_PWM_MODE n [6] = 0b) SV IN and V IN n Electrically Shorted Together and INTV CC Open Circuit; I OUT n = 0A, 5.75V ≤ V IN ≤ 16V, V OUT Low Range (MFR_PWM_MODE n [1] = 1b), FREQUENCY_SWITCH = 350kHz (Note 5) | l | 0.03 0.03 | ±0.2 | %/V %/V | |
| ∆V OUT n (LOAD) V OUT n | Load Regulation Accuracy | Digital Servo Engaged (MFR_PWM_MODE n [6] = 1b) Digital Servo Disengaged (MFR_PWM_MODE n [6] = 0b) 0A ≤ I OUT n ≤ 25A, V OUT Low Range, (MFR_PWM_MODE n [1] = 1b) (Note 5) | l | 0.2 | 0.03 | 0.5 | % % |
| V OUT n (AC) | Output Voltage Ripple | 10 | mV P-P | ||||
| f S (Each Channel) | V OUT n Ripple Frequency | FREQUENCY_SWITCH Set to 350kHz (0xFABC) | l | 325 | 350 | 375 | kHz |
| ∆V OUT n (START) | Turn-On Overshoot | TON_RISE n = 3ms (Note 12) | 8 | mV | |||
| t START | Turn-On Start-Up Time | Time from V IN Toggling from 0V to 12V to Rising Edge PGOOD n . TON_DELAY n = 0ms, TON_RISE n = 3ms | l | 30 | ms | ||
| t DELAY(0ms) | Turn-On Delay Time | Time from First Rising Edge of RUN n to Rising Edge of PGOOD n . TON_DELAY n = 0ms, TON_RISE n = 3ms, V IN Having Been Established for at Least 70ms | l | 2.95 | 3.3 | 3.7 | ms |
| ∆V OUT n (LS) | Peak Output Voltage Deviation for Dynamic Load Step | Load: 0A to 12.5A and 12.5A to 0A at 12.5A/μs, V OUT n = 1V, V IN = 12V (Note 12) See Load Transient Graphs | 50 | mV |
Rev. A
The l denotes the specifications which apply over the specified internal operating temperature range (Note 2). n is specified as each individual output channel (Note 4). T A = 25°C, V IN = 12V, RUN n = 3.3V, EXTV CC = 0, FREQUENCY_SWITCH = 350kHz and V OUT n commanded to 1.000V unless otherwise noted. Configured with factory-default EEPROM settings and per Test Circuit 1, unless otherwise noted.
| SYMBOL | PARAMETER | CONDITIONS | MIN TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|
| t SETTLE | Settling Time for Dynamic Load Step | Load: 0A to 12.5A and 12.5A to 0A at 12.5A/μs, V OUT n = 1V, V IN = 12V (Note 12) See Load Transient Graphs | 25 | μs | ||
| I OUT n (OCL_AVG) | Output Current Limit, Time Averaged | Time-Averaged Output Inductor Current Limit Inception Threshold, Commanded by IOUT_OC_FAULT_LIMIT n (Note 12) Utilizing MFR_PWM_MODE[7] = 1, Using ~I OUT = 36A, Page 89 | 30A; See I O-RB-ACC Specification (Output Current Readback Accuracy) | 30A; See I O-RB-ACC Specification (Output Current Readback Accuracy) | 30A; See I O-RB-ACC Specification (Output Current Readback Accuracy) | |
| Control Section | Control Section | Control Section | Control Section | Control Section | Control Section | Control Section |
| V FBCM0 | Channel 0 Feedback Input Common Mode Range | V OSNS0 - Valid Input Range (Referred to SGND) V OSNS0 + Valid Input Range (Referred to SGND) | l l | -0.1 | 0.3 3.6 | V V |
| V FBCM1 | Channel 1 Feedback Input Common Mode Range | V OSNS1 - Valid Input Range (Referred to SGND) V OSNS1 + Valid Input Range (Referred to SGND) | l l | -0.1 | 0.3 3.6 | V V |
| V OUT-RNGL | Full-Scale Command Voltage, Range Low (0.5V to 2.75V) Set Point Accuracy Resolution LSB Step Size | V OUT n Commanded to 2.75V, MFR_PWM_MODE n [1] = 1b (Note 15) | -0.5 2.75 12 0.688 | -0.5 | V % Bits mV | |
| V OUT-RNGH | Full-Scale Command Voltage, Range High (0.5V to 3.6V) Set Point Accuracy Resolution LSB Step Size | V OUT n Commanded to 3.6V, MFR_PWM_MODE n [1] = 0b (Notes 7, 15) | -0.5 3.6 12 1.375 | 0.5 | V % Bits mV | |
| R VSNS0 + | V OSNS0 + Impedance to SGND | 0.05V ≤ V VOSNS0 + - V SGND ≤ 3.3V | 50 | kΩ | ||
| R VSNS1 + | V OSNS1 Impedance to SGND | 0.05V ≤ V VOSNS1 - V SGND ≤ 3.3V | 50 | kΩ | ||
| t ON(MIN) | Minimum On-Time | (Note 8 ) | 60 | ns | ||
| R COMP0,1 | Resolution Compensation Resistor R TH(MAX) Compensation Resistor R TH(MIN) | MFR_PWM_CONFIG[4:0] = 0 to 31 (See Figure 1, Note Section) (Note 15) | 5 62 0 | Bits kΩ kΩ | ||
| g m0,1 | Resolution Error Amplifier g m(MAX) Error Amplifier g m(MIN) LSB Step Size | COMP0,1 = 1.35V, MFR_PWM_CONFIG[7:5] = 0 to 7 (Note 15) | 3 5.76 1 0.68 | Bits mmho mmho mmho | ||
| Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) | Analog OV/UV (Overvoltage/Undervoltage) Output Voltage Supervisor Comparators (VOUT_OV/UV_FAULT_LIMIT and VOUT_OV/UV_WARN_LIMIT Monitors) |
| N OV/UV_COMP | Resolution, Output Voltage Supervisors | (Notes 14, 15) | 9 | Bits | ||
| V OV-RNG | Output OV Comparator Threshold Detection Range | (Notes 14, 15) High Range Scale, MFR_PWM_MODE n [1] = 0b Low Range Scale, MFR_PWM_MODE n [1] = 1b | 1 0.5 | 3.6 2.7 | V V | |
| V OUSTP | Output OV and UV Comparator Threshold Programming LSB Step Size | (Note 15) High Range Scale, MFR_PWM_MODE n [1] = 0b Low Range Scale, MFR_PWM_MODE n [1] = 1b | 11.2 5.6 | mV mV | ||
| V OV-ACC-0,1 | Output OV Comparator Threshold Accuracy Channel 0 and 1 | (See Note 14) 1V≤V VOSNS n + -V VOSNS n - ≤2.7V,MFR_PWM_MODE[1]=1b 0.5V≤V VOSNS n + -V VOSNS n - ≤1V,MFR_PWM_MODE[1]=1b 2.0V≤V VOSNS n + -V VOSNS n - ≤3.6V,MFR_PWM_MODE[1]=0b | l l l | ±1.5 ±40 ±1.5 | % mV % | |
| V UV-RNG | Output UV Comparator Threshold Detection Range | (Note 15) High Range Scale, MFR_PWM_MODE n [1] = 0b Low Range Scale, MFR_PWM_MODE n [1] = 1b | 1 0.5 | 3.6 2.7 | V V |
The l denotes the specifications which apply over the specified internal operating temperature range (Note 2). n is specified as each individual output channel (Note 4). T A = 25°C, V IN = 12V, RUN n = 3.3V, EXTV CC = 0, FREQUENCY_SWITCH = 350kHz and V OUT n commanded to 1.000V unless otherwise noted. Configured with factory-default EEPROM settings and per Test Circuit 1, unless otherwise noted.
| SYMBOL | PARAMETER | CONDITIONS | MIN TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|
| V UV-ACC | Output UV Comparator Threshold Accuracy | (See Note 14) 1V≤V VOSNS n + -V VOSNS n - ≤2.7V,MFR_PWM_MODE[1]=1b 0.5V≤V VOSNS n + -V VOSNS n - ≤1V,MFR_PWM_MODE[1]=1b 2.0V≤V VOSNS n + -V VOSNS n - ≤3.6V,MFR_PWM_MODE[1]=0b | l l l | ±1.5 | ±1.5 ±40 | % mV % |
| t PROP-OV | Output OV Comparator Response Times | Overdrive to 10% Above Programmed Threshold | 100 | μs | ||
| t PROP-UV | Output UV Comparator Response Times | Under Drive to 10% Below Programmed Threshold | 100 | μs | ||
| Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) | Analog OV/UV SV IN Input Voltage Supervisor Comparators (Threshold Detectors for VIN_ON and VIN_OFF) |
| N SVIN-OV/UV-COMP | SV IN OV/UV Comparator Threshold- Programming Resolution | (Note 15) | 9 | Bits | ||
| SV IN-OU-RANGE | SV IN OV/UV Comparator Threshold- Programming Range | l | 4.5 | 16 | V | |
| SV IN-OU-STP | SV IN OV/UV Comparator Threshold- Programming LSB Step Size | (Note 15) | 76 | mV | ||
| SV IN-OU-ACC | SV IN OV/UV Comparator Threshold Accuracy | 4.5V ≤ SV IN ≤ 16V | l | ±350 | mV | |
| t PROP-SVIN-HIGH-VIN | SV IN OV/UV Comparator Response Time, High V IN Operating Configuration | Test Circuit 1, and: VIN_ON = 9V; SV IN Driven from 8.775V to 9.225V VIN_OFF = 9V; SV IN Driven from 9.225V to 8.775V | l l | 100 100 | μs μs | |
| t PROP-SVIN-LOW-VIN | SV IN OV/UV Comparator Response Time, Low V IN Operating Configuration | Test Circuit 2, and: VIN_ON = 4.5V; SV IN Driven from 4.225V to 4.725V VIN_OFF = 4.5V; SV IN Driven from 4.725V to 4.225V | l l | 100 100 | μs μs | |
| Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) | Channels 0 and 1 Output Voltage Readback (READ_VOUT n ) |
| N VO-RB | Output Voltage Readback Resolution and LSB Step Size | (Note 15) | 16 244 | Bits μV | ||
| V O-F/S | Output Voltage Full-Scale Digitizable Range | V RUN n = 0V (Note 15) | 8 | V | ||
| V O-RB-ACC | Output Voltage Readback Accuracy | Channel 0, 1: 1V ≤ V VOSNS + - V VOSNS - ≤ 3.6V Channel 0, 1: 0.5V ≤ V VOSNS + - V VOSNS - < 1V | l l | Within±0.5%ofReading Within±5mVofReading | ||
| t CONVERT-VO-RB | Output Voltage Readback Update Rate | MFR_ADC_CONTROL = 0x00 (Notes 9, 15) MFR_ADC_CONTROL = 0x01 through 0x0C (Notes 9, 15) MFR_ADC_CONTROL Section | 90 8 | ms ms ms | ||
| Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) | Input Voltage (SV IN ) Readback (READ_VIN) |
| N SVIN-RB | Input Voltage Readback Resolution and LSB Step Size | (Notes 10, 15) Limited to Abs Max = 18V for LTM4678 Module | 10 15.625 | Bits mV | ||
| SV IN-F/S | Input Voltage Full-Scale Digitizable Range | (Notes 11, 15) | 43 | V | ||
| SV IN-RB-ACC | Input Voltage Readback Accuracy | READ_VIN, 4.5V ≤ SV IN ≤ 16V | l | Within ±2% of Reading | Within ±2% of Reading | Within ±2% of Reading |
| t CONVERT-SVIN-RB | Input Voltage Readback Update Rate | MFR_ADC_CONTROL = 0x00 (Notes 9, 15) MFR_ADC_CONTROL = 0x01 (Notes 9, 15) | 90 8 | ms ms | ||
| Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) | Channels0and1OutputCurrent(READ_IOUT n ) |
| N IO-RB | Output Current Readback Resolution and LSB Step Size | (Notes 10, 12) | 10 34.1 | Bits mA | ||
| I O-F/S | Output Current Full-Scale Digitizable Range | (Note 12) Utilizing MFR_PWM_MODE[7] = 1, Using IOUT_OC_FAULT_ LIMIT = 34A, Page 89 | 40 | A |
ELECTRICAL CHARACTERISTICS The l denotes the specifications which apply over the specified internal operating temperature range (Note 2). n is specified as each individual output channel (Note 4). T A = 25°C, V IN = 12V, RUN n = 3.3V, EXTV CC = 0, FREQUENCY_SWITCH = 350kHz and V OUT n commanded to 1.000V unless otherwise noted. Configured with factory-default EEPROM settings and per Test Circuit 1, unless otherwise noted.
| SYMBOL | PARAMETER | CONDITIONS | MIN TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|
| I O-RB-ACC | Output Current, Readback Accuracy | READ_IOUT n , Channels 0 and 1, 0 ≤ I OUT n ≤ 25A, (Note 12), -20°C to 125°C Forced-Continuous Mode, MFR_PWM_MODE n [1:0] = 1b, -40°C to 125°C | l | Within ±0.875A of Reading Within ±1.50A of Reading | Within ±0.875A of Reading Within ±1.50A of Reading | Within ±0.875A of Reading Within ±1.50A of Reading |
| I O-RB(25A) | Full Load Output Current Readback | I OUT n = 25A (Note 12). See Histograms in Typical Performance Characteristics (Note 12) | 25 | A | ||
| t CONVERT-IO-RB | Output Current Readback Update Rate | MFR_ADC_CONTROL = 0x00 (Notes 9, 15) MFR_ADC_CONTROL = 0x06 (CH0 I OUT ) or 0x01 (CH1 I OUT ) (Notes 9, 15) See MFR_ADC_CONTROL Section | 90 8 | ms ms | ||
| Input Current Readback | Input Current Readback | Input Current Readback | Input Current Readback | Input Current Readback | Input Current Readback | Input Current Readback |
| N | Resolution | (Note 10) | 10 | Bits | ||
| V IINSTP | LSB Step Size Full-Scale Range = 16mV LSB Step Size Full-Scale Range = 32mV LSB Step Size Full-Scale Range = 64mV | Gain = 8, 0V ≤ \ | V IIN + - V IIN - \ | ≤ 5mV Gain = 4, 0V ≤ \ | V IIN + - V IIN - \ | ≤ 20mV Gain = 2, 0V ≤ \ |
| I IN_TUE | Total Unadjusted Error | Gain = 8, 2.5mV ≤ \ | V IIN + - V IIN - \ | Gain = 4, 4mV ≤ \ | V IIN + - V IIN - \ | Gain = 2, 6mV ≤ \ |
| V OS | Zero-Code Offset Voltage | (Note 15) | ±50 | μV | ||
| t CONVERT | Update Rate | (Notes 9,15) See MFR_ADC_CONTROL Section for Faster Update Rates | 90 | ms | ||
| Supply Current Readback | Supply Current Readback | Supply Current Readback | Supply Current Readback | Supply Current Readback | Supply Current Readback | Supply Current Readback |
| N | Resolution | (Note 10) | 10 | Bits | ||
| V ICHIPSTP | LSB Step Size Full-Scale Range = 256mV | Onboard 1Ω Resistor (Note 15) | 244 | μV | ||
| I CHIP-RB | I CHIP Readback | SV IN Curent | ±50 | mA | ||
| t CONVERT | Update Rate | (Notes 9,15) See MFR_ADC_CONTROL Section for Faster Update Rates | 90 | ms | ||
| Temperature Readback (T0, T1) | Temperature Readback (T0, T1) | Temperature Readback (T0, T1) | Temperature Readback (T0, T1) | Temperature Readback (T0, T1) | Temperature Readback (T0, T1) | Temperature Readback (T0, T1) |
| T RES-RB | Temperature Readback Resolution | Channel 0, Channel 1, and Controller (Note 15) | 0.25 | °C | ||
| T0_TUE | External Temperature Total Unadjusted Readback Error | Supporting Only ∆V BE Sensing | ±5 | °C °C | ||
| T1_TUE | Internal TSNS TUE | V RUN0,1 = 0.0, f SYNC = 0kHz (Note 15) | l | ±1 | °C | |
| t CONVERT | Update Rate | (Note 9) MFR_ADC_CONTROL = 0x04 or 0x0C (Notes 9, 15) | 90 8 | ms ms | ||
| INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC | INTV CC Regulator/EXTV CC |
| V INTVCC | Internal V CC Voltage No Load | 6V ≤ V IN ≤ 16V | l | 5.25 5.5 | 5.75 | V |
| V LDO_INT | INTV CC Load Regulation | I CC = 0mA to 20mA, 6V ≤ V IN ≤ 16V | 0.5 | ±2 | % | |
| V EXTVCC | EXTV CC Switchover Voltage | V IN ≥ 7V, EXTV CC Rising | l | 4.5 4.7 | 4.95 | V |
| V LDO_HYS | EXTV CC Hysteresis | 290 | mV | |||
| V LDO_EXT | EXTV CC Voltage Drop | I CC = 20mA, V EXTVCC = 5.5V | 80 | 120 | mV |
V
| SYMBOL | PARAMETER | CONDITIONS | MIN | TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|---|
| V IN_THR | V IN Threshold to Enable EXTV CC Switchover | V IN Rising | 7 | 7.5 | V | ||
| V IN_THF | V IN Hysteresis to Disable EXTV CC Switchover | V IN Falling | 600 | mV | |||
| V DD33 Regulator | V DD33 Regulator | ||||||
| V VDD33 | Internal V DD33 Voltage | 4.5V < V INTVCC or 4.8V < V EXTVCC | 3.2 | 3.3 | 3.4 | V | |
| I LIM | V DD33 Current Limit | V DD33 = GND | 100 | mA | |||
| V VDD33_OV | V DD33 Overvoltage Threshold | (Note 15) | 3.5 | V | |||
| V VDD33_UV | V DD33 Undervoltage Threshold | (Note 15) | 3.1 | V | |||
| V DD25 Regulator | V DD25 Regulator | ||||||
| V VDD25 | Internal V DD25 Voltage | 2.5 | V | ||||
| I LIM | V DD25 Current Limit | V DD25 = GND | 80 | mA | |||
| Oscillator and Phase-Locked Loop (PLL) | Oscillator and Phase-Locked Loop (PLL) | ||||||
| f RANGE | PLL SYNC Range | Synchronized with Falling Edge of SYNC | l | 300 | 1000 | kHz | |
| f OSC | Oscillator Frequency Accuracy | Frequency Switch = 350.0kHz to 1000.0kHz (Note | ±7.5 | % | |||
| V TH(SYNC) | SYNC Input Threshold | V SYNC Falling V SYNC Rising (Note 15) | 1 1.5 | V V | |||
| V OL(SYNC) | SYNC Low Output Voltage | I LOAD = 3mA | 0.2 | 0.4 | V | ||
| I LEAK(SYNC) | SYNC Leakage Current in Slave Mode | 0V ≤ V PIN ≤ 3.6V | ±5 | μA | |||
| θ SYNC- θ 0 | SYNC to Ch0 Phase Relationship Based on the Falling Edge of Sync and Rising Edge of TG0 (Note 15) | MFR_PWM_CONFIG[2:0] = 0,2,3 MFR_PWM_CONFIG[2:0] = 5 MFR_PWM_CONFIG[2:0] = 1 MFR_PWM_CONFIG[2:0]= 4,6 | 0 60 90 120 | Deg Deg Deg Deg | |||
| θ SYNC- θ 1 | SYNC to Ch1 Phase Relationship Based on the Falling Edge of Sync and Rising Edge of TG1 (Note 15) | MFR_PWM_CONFIG[2:0] = 3 MFR_PWM_CONFIG[2:0] = 0 MFR_PWM_CONFIG[2:0] = 2,4,5 MFR_PWM_CONFIG[2:0] = 1 MFR_PWM_CONFIG[2:0] = 6 | 120 180 240 270 300 | Deg Deg Deg Deg Deg | |||
| EEPROM Characteristics | EEPROM Characteristics | ||||||
| Endurance | (Notes 13 and 17) | 0°C ≤ T J ≤ 85°C During EEPROM Write Operations | l | 10000 | Cycles | ||
| Retention | (Notes 13 and 17) | T J < 125°C | l | 10 | Years | ||
| Mass_Write | Mass Write Operation Time (Notes 13 and 17) | STORE_USER_ALL, 0°C < T J < 85°C During EEPROM Write Operation | 440 | 4100 | ms | ||
| Leakage Current SDA, SCL, ALERT , RUN | Leakage Current SDA, SCL, ALERT , RUN | ||||||
| I OL | Input Leakage Current | OV ≤ V PIN ≤ 5.5V | l | ±5 | μA | ||
| Leakage Current FAULT n , PGOOD n | Leakage Current FAULT n , PGOOD n | ||||||
| I GL | Input Leakage Current | OV ≤ V PIN ≤ 3.6V | l | ±2 | μA | ||
| Digital Inputs SCL, SDA, RUN n , GPI0 n (Note 15) | Digital Inputs SCL, SDA, RUN n , GPI0 n (Note 15) | Digital Inputs SCL, SDA, RUN n , GPI0 n (Note 15) | |||||
| V IH | Input High Threshold Voltage | l | 1.35 | V | |||
| V IL | Input Low Threshold Voltage | l | 0.8 | V | |||
| V HYST | Input Hysteresis | SCL, SDA | 0.08 | V | |||
| C PIN | Input Capacitance | 10 | pF |
Rev. A
9
The l denotes the specifications which apply over the specified internal operating temperature range (Note 2). n is specified as each individual output channel (Note 4). T A = 25°C, V IN = 12V, RUN n = 3.3V, EXTV CC = 0, FREQUENCY_SWITCH = 575kHz and V OUT n commanded to 1.000V unless otherwise noted. Configured with factory-default EEPROM settings and per Test Circuit 1, unless otherwise noted.
| SYMBOL | PARAMETER | CONDITIONS | MIN | TYP | MAX | UNITS | |
|---|---|---|---|---|---|---|---|
| Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) | Digital Input WP (Note 15) |
| I PUWP | Input Pull-Up Current | WP | 10 | μA | |||
| Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) | Open-Drain Outputs SCL, SDA, FAULT n , ALERT , RUN n , SHARE_CLK, PGOOD n (Note 15) |
| V OL | Output Low Voltage | I SINK = 3mA | 0.4 | V | |||
| Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) | Digital Inputs SHARE_CLK, WP (Note 15) |
| V IH | Input High Threshold Voltage | l | 1.5 | 1.8 | V | ||
| V IL | Input Low Threshold Voltage | l | 0.6 | 1 | V | ||
| Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) | Digital Filtering of FAULT n (Note 15) |
| I FLTG | Input Digital Filtering FAULT n | 3 | μs | ||||
| Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) | Digital Filtering of PGOOD n (Note 15) |
| I FLTG | Output Digital Filtering PGOOD n | 60 | μs | ||||
| Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) | Digital Filtering of RUN n (Note 15) |
| I FLTG | Input Digital Filtering RUN | 10 | μs | ||||
| PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) | PMBus Interface Timing Characteristics (Note 15) |
| f SCL | Serial Bus Operating Frequency | l | 10 | 400 | kHz | ||
| t BUF | Bus Free Time Between Stop and Start | l | 1.3 | μs | |||
| t HD(STA) | Hold Time After Repeated Start Condition After This Period, the First Clock is Generated | l | 0.6 | μs | |||
| t SU(STA) | Repeated Start Condition Setup Time | l | 0.6 | 10000 | μs | ||
| t SU(ST0) | Stop Condition Setup Time | l | 0.6 | μs | |||
| t HD(DAT) | Date Hold Time Receiving Data Transmitting Data | l l | 0 0.3 | 0.9 | μs μs | ||
| t SU(DAT) | Data Setup Time Receiving Data | 0.1 | μs | ||||
| t TIMEOUT_SMB | Stuck PMBus Timer Non-Block Reads Stuck PMBus Timer Block Reads | Measured from the Last PMBus Start Event | 32 255 | ms | |||
| t LOW | Serial Clock Low Period | l | 1.3 | 10000 | μs | ||
| t HIGH | Serial Clock High Period | l | 0.6 | μs |
Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime.
Note 2: The LTM4678 is tested under pulsed-load conditions such that T J ≈ T A . The LTM4678E is guaranteed to meet performance specifications over the 0°C to 125°C internal operating temperature range. Specifications over the -40°C to 125°C internal operating temperature range are assured by design, characterization and correlation with statistical process controls. The LTM4678I is guaranteed to meet specifications over the full -40°C to 125°C internal operating temperature range. T J is calculated from
the ambient temperature T A and the power dissipation PD according the formula:
Note that the maximum ambient temperature consistent with these specifications is determined by specific operating conditions in conjunction with board layout, the rated package thermal resistance and other environmental factors.
Note 3: All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to ground unless otherwise specified
Note 4: The two power inputs-V IN0 and V IN1 -and their respective power outputs-V OUT0 and V OUT1 -are tested independently in production. A shorthand notation is used in this document that allows these parameters to be referred to by 'V IN n ' and 'V OUT n ', where n is permitted to take on a value of 0 or 1. This italicized, subscripted ' n ' notation and convention is extended to encompass all such pin names, as well as register names with channel-specific, i.e., paged data. For example, VOUT_COMMAND n refers to the VOUT_COMMAND command code data located in Pages 0 and 1, which in turn relate to channel 0 (V OUT0 ) and channel 1 (V OUT1 ). Registers containing non-page-specific data, i.e., whose data is 'global' to the module or applies to both of the module's channels lack the italicized, subscripted ' n ', e.g., FREQUENCY_SWITCH.
Note 5: V OUT n (DC) and line and load regulation tests are performed in production with digital servo disengaged (MFR_PWM_MODE n [6] = 0b) and low V OUT n range selected MFR_PWM_MODE n [1] = 1b. The digital servo control loop is exercised in production (setting MFR_PWM_ MODE n [6] = 1b), but convergence of the output voltage to its final settling value is not necessarily observed in final test-due to potentially long time constants involved-and is instead guaranteed by the output voltage readback accuracy specification. Evaluation in application demonstrates capability; see the Typical Performance Characteristics section.
Note 6: See output current derating curves for different V IN , V OUT , and T A , located in the Applications Information section.
Note 7: Even though V OUT0 and V OUT1 are specified for 6V absolute maximum, the maximum recommended command voltage to regulate output channels 0 and 1 is 3.6V with V OUT range-setting bit set using MFR_PWM_MODE[1] = 0b.
Note 8: Minimum on-time is tested at wafer sort.
Note 9: The data conversion is done by default in round robin fashion. All inputs signals are continuously converted for a typical latency of 90ms. Setting MFR_ADC_CONTRL value to be 0 to 12, LTM4678 can do fast data conversion with only 8ms to 10ms. See section PMBus Command for details.
Note 10: The following telemetry parameters are formatted in PMBusdefined 'Linear Data Format', in which each register contains a word comprised of 5 most significant bits-representing a signed exponent, to be raised to the power of 2-and 11 least significant bits-representing a signed mantissa: input voltage (on SV IN ), accessed via the READ_VIN command code; output currents (I OUT n ), accessed via the READ_IOUT n command codes; module input current (I VIN0 + I VIN1 + I SVIN ), accessed via the READ_IIN command code; channel input currents (I VIN n + 1/2 · I SVIN ), accessed via the MFR_READ_IIN n command codes;and duty cycles of channel 0 and channel 1 switching power stages, accessed via the READ_DUTY_CYCLE n command codes. This data format limits the resolution of telemetry readback data to 10 bits even though the internal ADC is 16 bits and the LTM4678's internal calculations use 32-bit words.
Note 11: The absolute maximum rating for the SV IN pin is 18V. Input voltage telemetry (READ_VIN) is obtained by digitizing a voltage scaled down from the SV IN pin.
Note 12: These typical parameters are based on bench measurements and are not production tested. Improved output current readback can be achieved by evaluating the system using the LTM4678. Measurements of the ambient temperature and the module inductor temperature for each channel with airflow can be compared with the GUI readback temperature. Once this temperature difference is known, then MFR_TEMP_1_GAIN and the MFR_TEMP_1_OFFSET parameters can be adjusted to further improve output current readback accuracy.
Note 13: EEPROM endurance and retention are guaranteed by wafer-level testing for data retention. The minimum retention specification applies for devices whose EEPROM has been cycled less than the minimum endurance specification, and whose EEPROM data was written to at 0°C ≤ T J ≤ 85°C. The RESTORE_USER_ALL or MFR_RESET is valid over the entire operating temperature range and does not influence EEPROM characteristics.
Note 14: Channel 0 OV/UV comparator threshold accuracy for MFR_PWM_MODE n [1] = 1b tested in ATE at V VOSNS0 + - V VOSNS0 -= 0.5V and 3.6V. 1V condition tested at IC-Level, only. Channel 1 OV/UV comparator threshold accuracy for MFR_PWM_MODE n [1] = 1b tested in ATE with V VOSNS1 + - V VOSNS1 -= 0.5V and 3.6V. 1.5V condition tested at IC-level, only. MFR_PWM_MODE n [1] = 1b is the Low Range.
Note 15: Tested at IC-level ATE.
Note 16: The LTM4678 quiescent current (I Q ) equals the I Q of V IN plus the I Q of INTV CC .
Note 17: The LTM4678's EEPROM temperature range for valid write commands is 0°C to 85°C. To achieve guaranteed EEPROM data retention, execution of the 'STORE_USER_ALL' command-i.e., uploading RAM contents to NVM-outside this temperature range is not recommended. However, as long as the LTM4678's EEPROM temperature is less than 130°C, the LTM4678 will obey the STORE_USER_ALL command. Only when EEPROM temperature exceeds 130°C, the LTM4678 will not act on any STORE_USER_ALL transactions: instead, the LTM4678 NACKs the serial command and asserts its relevant CML (communications, memory, logic) fault bits. EEPROM temperature can be queried prior to commanding STORE_USER_ALL; see the Applications Information section.
Note 18: The LTM4678 includes overtemperature protection that is intended to protect the device during momentary overload conditions. Junction temperature will exceed 125°C when overtemperature protection is active. Continuous operation above the specified maximum operating junction temperature may impair device reliability.
Note 19: The maximum programmable output voltage is 3.6V, therefore, any of the overvoltage margining commands will be limited as the output voltage is programmed up to 3.6V.
3
1
4678 F01
Figure 1. Programmable R COMP
1
9
Thermal Information
The thermal resistances reported in the Pin Configuration section of this data sheet are consistent with those parameters defined by JESD51-12 and are intended for use with finite element analysis (FEA) software modeling tools that leverage the outcome of thermal modeling, simulation, and correlation to hardware evaluation performed on a μModule package mounted to a hardware test board defined by JESD51-9 ('Test Boards for Area Array Surface Mount Package Thermal Measurements'). The motivation for providing these thermal coefficients is found in JESD51-12 ('Guidelines for Reporting and Using Electronic Package Thermal Information').
Many designers may opt to use laboratory equipment and a test vehicle such as the demo board to predict the μModule regulator's thermal performance in their appli-
cation at various electrical and environmental operating conditions to compliment any FEA activities. Without FEA software, the thermal resistances reported in the Pin Configuration section are in-and-of themselves not relevant to providing guidance of thermal performance; instead, the derating curves provided later in this data sheet can be used in a manner that yields insight and guidance pertaining to one's application-usage, and can be adapted to correlate thermal performance to one's own application.
The Pin Configuration section gives four thermal coefficients explicitly defined in JESD51-12; these coefficients are quoted or paraphrased below:
- θ JA , the thermal resistance from junction to ambient, is the natural convection junction-to-ambient air thermal resistance measured in a one cubic foot sealed enclosure. This environment is sometimes referred to as 'still air' although natural convection causes the air to move. This value is determined with the part mounted to a JESD51-9 defined test board, which does not reflect an actual application or viable operating condition.
- θ JCbottom , the thermal resistance from junction to the bottom of the product case, is determined with all of the component power dissipation flowing through the bottom of the package. In the typical μModule regulator , the bulk of the heat flows out the bottom of the package, but there is always heat flow out into the ambient environment. As a result, this thermal resistance value may be useful for comparing pack-
- ages but the test conditions don't generally match the user's application.
- θ JCtop , the thermal resistance from junction to top of the product case, is determined with nearly all of the component power dissipation flowing through the top of the package. As the electrical connections of the typical μModule regulator are on the bottom of the package, it is rare for an application to operate such that most of the heat flows from the junction to the top of the part. As in the case of θ JCbottom , this value may be useful for comparing packages but the test conditions don't generally match the user's application.
- 4 θ JB , the thermal resistance from junction to the printed circuit board, is the junction-to-board thermal resistance where almost all of the heat flows through the bottom of the μModule regulator and into the board, and is really the sum of the θ JCbottom and the thermal resistance of the bottom of the part through the solder joints and through a portion of the board. The board temperature is measured a specified distance from the package, using a two sided, two layer board. This board is described in JESD51-9.
A graphical representation of the aforementioned thermal resistances is given in Figure 34; blue resistances are contained within the μModule regulator , whereas green resistances are external to the μModule package.
As a practical matter , it should be clear to the reader that no individual or sub-group of the four thermal resistance parameters defined by JESD51-12 or provided in the
Figure 34. Graphical Representation of JESD51-12 Thermal Coefficients
Figure 34. Graphical Representation of JESD51-12 Thermal Coefficients
Pin Configuration section replicates or conveys normal operating conditions of a μModule regulator . For example, in normal board-mounted applications, never does 100% of the device's total power loss (heat) thermally conduct exclusively through the top or exclusively through bottom of the μModule package-as the standard defines for θ JCtop and θ JCbottom , respectively. In practice, power loss is thermally dissipated in both directions away from the package-granted, in the absence of a heat sink and airflow, a majority of the heat flow is into the board.
Within the LTM4678, be aware there are multiple power devices and components dissipating power , with a consequence that the thermal resistances relative to different junctions of components or die are not exactly linear with respect to total package power loss. To reconcile this complication without sacrificing modeling simplicity-but also, not ignoring practical realities-an approach has been taken using FEA software modeling along with laboratory testing in a controlled-environment chamber to reasonably define and correlate the thermal resistance values supplied in this data sheet: (1) Initially, FEA software is used to accurately build the mechanical geometry of the LTM4678 and the specified PCB with all of the correct material coefficients along with accurate power loss source definitions; (2) this model simulates a software-defined JEDEC environment consistent with JESD51-9 and JESD51-12 to predict power loss heat flow and temperature readings at different interfaces that enable the calculation of the JEDEC-defined thermal resistance values; (3) the model and FEA software is used to evaluate the LTM4678 with heat sink and airflow; (4) having solved for and analyzed these thermal resistance values and simulated various operating conditions in the software model, a thorough laboratory evaluation replicates the simulated conditions with thermocouples within a controlled environment chamber while operating the device at the same power loss as that which was simulated. The outcome of this process and due diligence yields the set of derating curves provided in later sections of this data sheet, along with
well-correlated JESD51-12-defined θ values provided in the Pin Configuration section of this data sheet.
The 5V, 8V and 12V power loss curves in Figure 35, Figure 36 and Figure 37 respectively can be used in coordination with the load current derating curves in Figure 38 to Figure 43 for calculating an approximate θ JA thermal resistance for the LTM4678 with airflow conditions. These thermal resistances represent demonstrated performance of the LTM4678 on hardware; a 6-layer FR4 PCB measuring 99mm × 130mm × 1.6mm using 2oz copper on all layers. The power loss curves are taken at room temperature, and are increased with multiplicative factors of 1.35 when the junction temperature reaches 125°C. The derating curves are plotted with the LTM4678's paralleled outputs initially sourcing up to 50A and the ambient temperature at 25°C. The output voltages are 0.9V and 1.8V. These are chosen to include the lower and higher output voltage ranges for correlating the thermal resistance. Thermal models are derived from several temperature measurements in a controlled temperature chamber along with thermal modeling analysis. The junction temperatures are monitored while ambient temperature is increased with and without airflow.
The power loss increase with ambient temperature change is factored into the derating curves. The junctions are maintained at 125°C maximum while lowering output current or power while increasing ambient temperature. The decreased output current decreases the internal module loss as ambient temperature is increased. The monitored junction temperature of 125°C minus the ambient operating temperature specifies how much module temperature rise can be allowed. As an example in Figure 40, the load current is derated to ~35A at ~73°C ambient with no air or heat sink and the room temperature (25°C) power loss for this 12V IN to 0.9V OUT at 35A OUT condition is ~4W. A 5.4W loss is calculated by multiplying the ~4W room temperature loss from the 12V IN to 0.9V OUT power loss curve at 35A (Figure 35), with the 1.35 multiplying factor . If the 73°C ambient temperature is subtracted from the 125°C junction temperature, then the difference of
52°C divided by 5.4W yields a thermal resistance, θ JA , of 9.6°C/W-in good agreement with Table 10. Table 10 and Table 11 provide equivalent thermal resistances for 0.9V and 1.8V outputs with and without airflow. The derived thermal resistances in Table 10 and Table 11 for the various conditions can be multiplied by the calculated power loss
Typical Application
Dual 25A μModule Regulator with Digital Interface for Control and Monitoring*
V
V
I
N
C
I
N
V
V
I
N
I
N
I
N
1
V
I
N
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