MAXM17536ALY#

**EVALUATION KIT AVAILABLE** 

_Click_ _**here** for production status of specific part numbers._ 

## **MAXM17536** 

## **4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor** 

## **General Description** 

The Himalaya series of voltage regulator ICs and power modules enable cooler, smaller and simpler power supply solutions. The MAXM17536 is an easy-to-use, step-down power module that combines a switching power supply controller, dual n-channel MOSFET power switches, fully shielded inductor, and the compensation components in a low-profile, thermally-efficient system-in-package (SiP). The device operates over a wide input voltage-range of 4.5V to 60V and delivers up to 4A continuous output current with excellent line and load regulation over an output-voltage range of 0.9V to 12V. The high level of integration significantly reduces design complexity, manufacturing risks, and offers a true plug-and-play power supply solution, reducing time-to-market. 

The device can be operated in the pulse-width modulation (PWM), pulse-frequency modulation (PFM), or discontinuous conduction mode (DCM) control schemes. 

The MAXM17536 is available in a low-profile, highly thermal-emissive, compact, 29-pin, 9mm x 15mm x 4.32mm SiP package that reduces power dissipation in the package and enhances efficiency. The package is easily soldered onto a printed circuit board and suitable for automated circuit board assembly. 

## **Applications** 

- Test and Measurement Equipment 

- Distributed Supply Regulation 

- FPGA and DSP Point-of-Load Regulator 

- Base-Station Point-of-Load Regulator 

- HVAC and Building Control Systems 

## **Typical Application Circuit** 

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VIN 7.5V TO 60V<br>CIN<br>4 x 4.7µF<br>IN VOUT 5V, 4A<br>OUT<br>EN/UVLO<br>665kRΩ3 VCC EXTVCC 174kΩ R1 COUT<br>DL MAXM17536 FB 3 x 47µF<br>RESET BSTLX 2.2pFCF R2<br>38.3kΩ<br>CF<br>CSS MODE/SYNC RT<br>SGND PGND<br>22nF<br>CIN : GRM31CZ72A475KE11L<br>COUT : GRM32ER71A476KE15L<br>**----- End of picture text -----**<br>


## **Benefits and Features** 

- Reduces Design Complexity, Manufacturing Risks, and Time-to-Market 

   - Integrated Synchronous Step-Down DC-DC Converter 

   - Integrated Inductor 

   - Integrated FETs 

   - Integrated Compensation Components 

- Saves Board Space in Space-Constrained Applications 

   - Complete Integrated Step-Down Power Supply in a Single Package 

   - Small Profile, 9mm x 15mm x 4.32mm SiP Package 

   - Simplified PCB Design with Minimal External BOM Components 

- Offers Flexibility for Power-Design Optimization 

   - Wide Input-Voltage Range from 4.5V to 60V 

   - Output-Voltage Adjustable Range from 0.9V to 12V 

   - Adjustable Frequency with External Frequency Synchronization (100kHz to 2.2MHz) 

   - PWM, PFM, or DCM Current-Mode Control 

   - Programmable Soft-Start 

   - Auxiliary Bootstrap LDO for Improved Efficiency 

   - Optional Programmable EN/UVLO 

- Operates Reliably in Adverse Environments 

   - Integrated Thermal Protection 

   - Hiccup Mode Overload Protection 

   - RESET Output-Voltage Monitoring 

   - Ambient Operating Temperature Range (-40°C to +125°C)/Junction Temperature Range (-40°C to +150°C) 

   - Complies with CISPR22(EN55022) Class B Conducted and Radiated Emissions 

_**Ordering Information** appears at end of data sheet._ 

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_19-100573; Rev 0; 6/19_ 

## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Absolute Maximum Ratings** 

|**Absolute Maximum Ratings**||
|---|---|
|IN to PGND ...........................................................-0.3V to +65V|EXTVCC to PGND ................................................-0.3V to +26V|
|EN/UVLO, SS to SGND ........................................-0.3V to +65V|OUT to PGND (VIN≤16V) ..........................-0.3V to (VIN+ 0.3V)|
|LX to PGND................................................-0.3V to (VIN+ 0.3V)|OUT to PGND (VIN> 16V) ......................................-0.3V to 16V|
|BST to PGND ........................................................-0.3V to +70V|Output Short-Circuit Duration ....................................Continuous|
|BST to LX .............................................................-0.3V to +6.5V|Operating Temperature Range  ...........................-40°C to 125°C|
|BST to VCC...........................................................-0.3V to +65V|Junction Temperature (Note 1) ........................................+150°C|
|FB, CF,RESET, MODE/SYNC, RT to SGND ......-0.3V to +6.5V|Storage Temperature Range ............................ -55°C to +150°C|
|DL, VCCto PGND ................................................-0.3V to +6.5V|Soldering Temperature (reflow) .......................................+240°C|
|SGND to PGND ....................................................-0.3V to +0.3V||



## **Note 1:** Junction temperature greater than +125°C degrades operating lifetimes. 

_Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability._ 

## **Package Information** 

## **PACKAGE TYPE: 29-PIN SiP** 

|**PACKAGE TYPE: 29-PIN SiP**<br>**Package Information**||
|---|---|
|Package Code|L29915#1|
|Outline Number|**21-100177**|
|Land Pattern Number|**90-100055**|
|**Thermal Resistance, Four-Layer Board: (Note 2)**||
|Junction to Ambient (θJA)|24 °C/W|



For the latest package outline information and land patterns (footprints), go to **www.maximintegrated.com/packages** . Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. 

**Note 2:** Package thermal resistance is measured on an evaluation board with natural convection. 

## **Electrical Characteristics** 

(VIN = VEN/UVLO = 24V, RRT = OPEN (450kHz), VPGND = VSGND = VMODE/SYNC = 0V, LX = SS = RESET = CF = DL = VCC = OUT = open, VEXTVCC = 0V, VBST  to VLX = 5V, VFB = 1V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to SGND, unless otherwise noted.) (Note 3) 

|**PARAMETER**|**SYMBOL**|**CONDITIONS**|**MIN**<br>**TYP**<br>**MAX**|**UNITS**|
|---|---|---|---|---|
|**INPUT SUPPLY (VIN)**|||||
|Input-Voltage Range|VIN||4.5<br>60|V|
|Input-Shutdown Current|IIN_SH|VEN/UVLO= 0V, (Shutdown mode)|11<br>16|μA|
|Input-Quiescent Current|IQ_PFM|MODE/SYNC = open|128|μA|
||IQ_DCM|DCM Mode|1.27<br>2|mA|
||IQ_PWM|PWM Mode, no load, VOUT= VEXTVCC= 5V|19||
|**ENABLE/UNDERVOLTAGE LOCKOUT (EN/UVLO)**|||||
|EN/UVLO Threshold|VENR|VEN/UVLOrising|1.185<br>1.215<br>1.245|V|
||VENF|VEN/UVLOfalling|1.06<br>1.09<br>1.12||
|Enable Pullup Resistor|RENP|Pullup resistor between IN and EN/UVLO pins|3.15<br>3.32<br>3.45|MΩ|



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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Electrical Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, RRT = OPEN (450kHz), VPGND = VSGND = VMODE/SYNC = 0V, LX = SS = RESET = CF = DL = VCC = OUT = open, VEXTVCC = 0V, VBST  to VLX = 5V, VFB = 1V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to SGND, unless otherwise noted.) (Note 3) 

|**PARAMETER**|**SYMBOL**|**CONDITIONS**|**MIN**<br>**TYP**<br>**MAX**|**UNITS**|
|---|---|---|---|---|
|**LOW DROPOUT (INLDO)**|||||
|VCCOutput Voltage<br>Range|VCC|6V < VIN< 60V, IVCC= 1mA|4.75<br>5<br>5.25|V|
|||1mA < IVCC< 45mA|4.75<br>5<br>5.25||
|VCCCurrent Limit|IVCC_MAX|VCC= 4.3V, VIN= 7V|50<br>90<br>150|mA|
|IN to VCCDropout|VCC_DO|VIN= 4.5V, IVCC= 45mA|0.4|V|
|VCCUVLO|VCC_UVR|VCCrising|4.1<br>4.2<br>4.3|V|
||VCC_UVF|VCCfalling|3.7<br>3.8<br>3.9||
|**LOW DROPOUT (EXTVCC)**|||||
|EXTVCC<br>Operating Voltage Range|||4.84<br>24|V|
|EXTVCC Switchover<br>Voltage||Rising|4.56<br>4.7<br>4.84|V|
|||Falling|4.33<br>4.45<br>4.6||
|EXTVCC to VCCDropout|VEXTVCC_DO|VEXTVCC= 5V, IEXTVCC= 45mA|0.6|V|
|EXTVCC Current Limit|IEXTVCC_MAX|VCC= 4.3V, EXTVCC = 8V|45<br>85<br>140|mA|
|**SOFT-START (SS)**|||||
|Charging Current|ISS|VSS= 0.5V|4.7<br>5<br>5.3|μA|
|**OUTPUT SPECIFICATIONS**|||||
|Line Regulation Accuracy||VIN= 7.5V to 60V, VOUT= 5V|0.16|mV/V|
|Load Regulation<br>Accuracy||Tested with IOUT= 0A to 4A at VOUT= 5V|1|mV/A|
|FB Regulation Voltage|VFB_REG|MODE/SYNC = SGND or MODE = VCC|0.8875<br>0.9<br>0.9135|V|
|||MODE/SYNC = OPEN|0.8875<br>0.915<br>0.936||
|FB Input Bias Current|IFB|0 < VFB< 1V|-75<br>+75|nA|
|FB Undervoltage Trip<br>Level to Cause Hiccup|VFB_HICF||0.55<br>0.58<br>0.61|V|
|HICCUP Timeout|||32768|Cycles|
|**MODE/SYNC PIN**|||||
|MODE Threshold|VM_DCM|MODE/SYNC = VCC(DCM Mode)|VCC- 0.6|V|
||VM_PFM|MODE/SYNC = OPEN (PFM mode)|VCC/2||
||VM_PWM|MODE/SYNC = GND (PWM mode)|0.6||
|SYNC Frequency-<br>Capture Range||fSWset by RRT|1.1 x fSW<br>1.4 x fSW|kHz|
|SYNC Pulse Width|||50|ns|
|SYNC Threshold|VIH||2.0|V|
||VIL||0.8||



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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Electrical Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, RRT = OPEN (450kHz), VPGND = VSGND = VMODE/SYNC = 0V, LX = SS = RESET = CF = DL = VCC = OUT = open, VEXTVCC = 0V, VBST  to VLX = 5V, VFB = 1V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to SGND, unless otherwise noted.) (Note 3) 

|**PARAMETER**|**SYMBOL**|**CONDITIONS**|**MIN**<br>**TYP**<br>**MAX**|**UNITS**|
|---|---|---|---|---|
|**RT PIN**|||||
|Switching Frequency<br>Accuracy||fSW= 100kHz to 2.2MHz|-12<br>+12|%|
|Switching Frequency|fSW|RRT= open|420<br>450<br>480|kHz|
|Switching Frequency<br>Adjustable Range|||100<br>2200|kHz|
|Minimum On-Time|tON(MIN)||114<br>160|ns|
|**RESET PIN**|||||
|RESETSink Current|IRESET||10|mA|
|RESETOutput-Level Low||IRESET= 10mA|400|mV|
|RESETOutput-Leakage<br>Current||VRESET= 5.5V|-100<br>+100|nA|
|VOUTThreshold for<br>RESETAssertion|VOUT_OKF|VFBfalling|90.4<br>92.5<br>94.6|%|
|VOUTThreshold for<br>RESETDeassertion|VOUT_OKR|VFBrising|93.4<br>95.5<br>97.7|%|
|RESETDeassertion<br>Delay After FB Reaches<br>95% Regulation|||1024|Cycles|
|**THERMAL SHUTDOWN**|||||
|Thermal Shutdown<br>Threshold||Temperature Rising|165|°C|
|Thermal Shutdown<br>Hystersis|||10|°C|



**Note 3:** Electrical specifications are production tested at TA = + 25°C. Specifications over the entire operating temperature range are guaranteed by design and characterization. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

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EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(3.3V OUTPUT, PWM MODE, fSW = 300kHz) (5V OUTPUT, PWM MODE, fSW = 450kHz) (3.3V OUTPUT, PFM MODE, fSW = 300kHz)<br>100 toc01 100 toc02 100 toc03<br>90 90 90<br>80 80 80<br>70 70 70<br>60 VIN =  60V 60 VIN = 60V 60<br>50 VIN = 48V 50 VIN = 48V 50 VINV = 48VIN = 60V<br>40 VIN = 36V 40 VIN = 36V 40 VIN = 36V<br>30 VIN = 24V 30 VIN = 24V 30 VIN = 24V<br>20 VIN = 12V 20 VIN = 12V 20 VIN = 12V<br>10 VIN = 5V 10 VIN = 7.5V 10 VIN = 5V<br>0 0 0<br>0 1000 2000 3000 4000 0 1000 2000 3000 4000 1 10 100 1000<br>LOAD CURRENT (mA) LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY (%)<br>EFFICIENCY (%) EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(5V OUTPUT, PFM MODE, fSW = 450kHz) (3.3V OUTPUT, DCM MODE, fSW = 300kHz)  (5V OUTPUT, DCM MODE, fSW = 450kHz)<br>100 toc04 100 toc05 100 toc06<br>90 90 VIN = 24V 90 VIN = 24V<br>80 80 VIN = 12V 80 VIN = 12V<br>70 70 VIN = 5V 70 VIN = 7.5V<br>60 VIN = 60V 60 60<br>50 VIN = 48V 50 VIN = 60V 50<br>VIN = 60V<br>40 VIN = 36V 40 VIN = 48V 40 VIN = 48V<br>30 VIN = 24V 30 30 VIN = 36V<br>20 VIN = 12V 20 VIN = 36V 20<br>10 VIN = 7.5V 10 10<br>0 0 0<br>1 10 100 1000 1 10 100 1000 1 10 100 1000<br>LOAD CURRENT (mA) LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(0.9V OUTPUT, PWM MODE, fSW = 300kHz) (1.2V OUTPUT, PWM MODE, fSW = 400kHz)  (1.5V OUTPUT, PWM MODE, fSW = 400kHz)<br>100 toc07 100 toc08 100 toc09<br>90 90 90<br>80 80 80<br>70 70 70<br>60 60 60<br>5040 VIN = 12V 5040 VIN = 12V 5040 VIN = 12V<br>VIN = 5V VIN = 5V<br>30 VIN = 5V 30 30<br>20 20 20<br>10 10 10<br>0 0 0<br>0 1000 2000 3000 4000 0 1000 2000 3000 4000 0 1000 2000 3000 4000<br>LOAD CURRENT (mA) LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY (%) EFFICIENCY (%) EFFICIENCY (%)<br>EFFICIENCY (%) EFFICIENCY (%) EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down 

## SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

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EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(1.8V OUTPUT, PWM MODE, fSW = 400kHz) (2.5V OUTPUT, PWM MODE, fSW = 400kHz)<br>100 toc10 100 toc11<br>90 90<br>80 80<br>70 70<br>60 60 VIN = 24V<br>50 VIN = 24V 50 VIN = 12V<br>40 VIN = 12V 40 VIN = 5V<br>30 VIN = 5V 30<br>20 20<br>10 10<br>0 0<br>0 1000 2000 3000 4000 0 1000 2000 3000 4000<br>LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY (%) EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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EFFICIENCY vs. LOAD CURRENT<br>(8V OUTPUT, PWM MODE, fSW = 750kHz)<br>100 toc12<br>90<br>80<br>70<br>60 VIN = 60V<br>50 VIN = 48V<br>40 VIN = 36V<br>30<br>VIN = 24V<br>20<br>10 VIN = 12V<br>0<br>0 1000 2000 3000 4000<br>LOAD CURRENT (mA)<br>EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(12V OUTPUT, PWM MODE, fSW = 900kHz) (0.9V OUTPUT, PFM MODE, fSW = 300kHz)<br>100 toc1 3 100 toc14<br>90 90<br>80 80<br>70 70<br>60 60<br>50 VIN = 60V 50 VIN = 12V<br>VIN = 48V<br>40 40<br>VIN = 36V VIN = 5V<br>30 30<br>VIN = 24V<br>20 20<br>VIN = 16V<br>10 10<br>0 0<br>0 1000 2000 3000 4000 1 10 100 1000<br>LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY vs. LOAD CURRENT EFFICIENCY vs. LOAD CURRENT<br>(1.5V OUTPUT, PFM MODE, fSW = 400kHz) (1.8V OUTPUT, PFM MODE, fSW = 400kHz)<br>100 toc16 100 toc17<br>90 90<br>80 80<br>70 70<br>60 60<br>50 VIN = 12V 50 VIN = 24V<br>40 40 VIN = 12V<br>VIN = 5V<br>30 30 VIN = 5V<br>20 20<br>10 10<br>0 0<br>1 10 100 1000 1 10 100 1000<br>LOAD CURRENT (mA) LOAD CURRENT (mA)<br>EFFICIENCY (%) EFFICIENCY (%)<br>EFFICIENCY (%) EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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EFFICIENCY vs. LOAD CURRENT<br>(1.2V OUTPUT, PFM MODE, fSW = 400kHz)<br>100 toc15<br>90<br>80<br>70<br>60<br>50<br>VIN = 12V<br>40<br>VIN = 5V<br>30<br>20<br>10<br>0<br>1 10 100 1000<br>LOAD CURRENT (mA)<br>EFFICIENCY vs. LOAD CURRENT<br>(2.5V OUTPUT, PFM MODE, fSW = 400kHz)<br>100 toc18<br>90<br>80<br>70<br>60 VIN = 24V<br>50 VIN = 12V<br>40<br>VIN = 5V<br>30<br>20<br>10<br>0<br>1 10 100 1000<br>LOAD CURRENT (mA)<br>EFFICIENCY (%)<br>EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

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EFFICIENCY vs. LOAD CURRENT<br>(8V OUTPUT, PFM MODE, fSW = 750kHz)<br>100 toc19<br>90 ee eee eese<br>80<br>70 VT nt |<br>60 Zn<br>50 XI MCNINE VIN  TTT  = 48V NCE VIN = 60V TT<br>4030 LATINrN TN VIN = 36V ATMm<br>20 PTT VIN = 12VVIN = 24V [IT<br>100 PMPC oITnTAINTTTT<br>1 10 100 1000<br>LOAD CURRENT (mA)<br>EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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STEADY-STATE SWITCHING WAVEFORMS<br>(VIN = 24V, VOUT = 5V, IOUT = 0A, PWM MODE)<br>toc21<br>VOUT (AC) 20mV/div<br>10V/div<br>VLX<br>2 µ s/div<br>**----- End of picture text -----**<br>


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STEADY-STATE SWITCHING WAVEFORMS<br>(VIN = 24V, VOUT = 5V, IOUT = 25mA, PFM MODE)<br>toc23<br>VOUT (AC) 100mV/div<br>10V/div<br>VLX<br>100 µ s/div<br>**----- End of picture text -----**<br>


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EFFICIENCY vs. LOAD CURRENT<br>(12V OUTPUT, PFM MODE, fSW = 900kHz)<br>100 toc20<br>90 ee<br>80<br>70 VET<br>60 NIK TTI VIN = 60V TT<br>50 PZ2011NINEAN VIN = 48V<br>403020 PINYTPTT VIN UTR  = 16VV NUN IN = 24VVIN = 36V AinullHiii TT<br>10 7<br>0 |PC TT |<br>1 10 100 1000<br>LOAD CURRENT (mA)<br>STEADY-STATE SWITCHING WAVEFORMS<br>(VIN = 24V, VOUT = 5V, IOUT = 4A, PWM MODE)<br>toc22<br>VOUT (AC) 20mV/div<br>10V/div<br>VLX<br>2 µ s/div<br>STEADY-STATE SWITCHING WAVEFORMS<br>(VIN = 24V, VOUT = 5V, IOUT = 100mA, DCM MODE)<br>toc24<br>VOUT (AC) 10mV/div<br>10V/div<br>VLX<br>1 µ s/div<br>EFFICIENCY (%)<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

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OUTPUT VOLTAGE vs. LOAD CURRENT OUTPUT VOLTAGE vs. LOAD CURRENT<br>(5V OUTPUT, PWM MODE, fSW = 450kHz) (5V OUTPUT, PFM MODE, fSW = 450kHz)<br>5.000 toc25 5.150 toc26<br>5.130<br>4.995 VIN = 24V<br>ET ET et 5.110 | VIN = 36V<br>4.990 TooBEER EEE 5.090 aNY T<br>4.985 SSeS See eres erie 5.070 TLV VIN = 7.5V TT VIN = 48V Th<br>VIN = 7.5V 5.050 VIN = 12V VIN = 60V<br>4.980 B ! V E IN = 12V EEES 5.030 PaPT Ca LePEEL LT<br>VIN = 24V<br>VIN = 36V 5.010<br>4.975<br>it VIN = 48V t 4.990 natn<br>4.970 PEMAEREDeaall VIN = 60V 4.970 CET<br>0 1000 2000 3000 4000 0 1000 2000 3000 4000<br>LOAD CURRENT (mA) LOAD CURRENT (mA)<br>OUTPUT VOLTAGE vs. LOAD CURRENT OUTPUT VOLTAGE vs. LOAD CURRENT<br>(3.3V OUTPUT, PWM MODE, fSW = 300kHz) (3.3V OUTPUT, PFM MODE, fSW = 300kHz)<br>3.317 toc27 3.42 toc28<br>3.316 MUTT TTT 3.40 VIN = 5VVIN = 12V<br>3.315 VIN = 24V<br>SERRSEETTUTT EET 3.38 Ht V SHITE IN = 36V<br>3.314 VIN = 48V<br>3.313 VIN = 60V 3.36 VIN = 60V<br>3.312 Hi VIN = 48VVIN = 36V ELPA 3.34 NA AT<br>3.311 VIN = 24V<br>" VIN = 12V AL 3.32 SN ATT<br>3.310 TTT VIN = 5V Ath AT<br>3.309 SEHAAAGERARTORARAEL 3.30 0 ANTE 1000 2000 3000 4000<br>0 1000 2000 3000 4000<br>LOAD CURRENT (mA) LOAD CURRENT (mA)<br>OUTPUT VOLTAGE (V) OUTPUT VOLTAGE (V)<br>OUTPUT VOLTAGE (V) OUTPUT VOLTAGE (V)<br>**----- End of picture text -----**<br>


**POWER-UP AND DOWN THROUGH EN/UVLO (VIN = 24V, VOUT = 5V, IOUT = 25mA, PFM MODE)** 

**==> picture [158 x 127] intentionally omitted <==**

**----- Start of picture text -----**<br>
toc29<br>2V/div<br>VEN/UVLO<br>5V/div<br>VOUT<br>5V/div<br>VRESET<br>4ms/div<br>**----- End of picture text -----**<br>


**==> picture [160 x 151] intentionally omitted <==**

**----- Start of picture text -----**<br>
POWER-UP AND DOWN THROUGH EN/UVLO<br>(VIN = 24V, VOUT = 3.3V, IOUT = 25mA, PFM MODE)<br>toc30<br>2V/div<br>VEN/UVLO<br>2V/div<br>VOUT<br>5V/div<br>VRESET<br>4ms/div<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

**==> picture [391 x 161] intentionally omitted <==**

**----- Start of picture text -----**<br>
POWER-UP AND DOWN THROUGH EN/UVLO<br>POWER-UP AND DOWN THROUGH EN/UVLO<br>(VIN = 24V, VOUT = 5V, IOUT = 4A, PWM MODE)<br>(VIN = 24V, VOUT = 3.3V, IOUTIN = 24V, VOUT = 3.3V, IOUT = 24V, VOUT = 3.3V, IOUTOUT = 3.3V, IOUT = 3.3V, IOUTOUT = 4A, PWM MODE)<br>toc31 toc32<br>2V/div<br>VEN/UVLO VEN/UVLOEN/UVLO<br>VOUT 5V/div VOUTOUT<br>5V/div<br>VRESET VRESETRESET<br>5A/div<br>IOUT IOUTOUT<br>4ms/div<br>ae a 4ms/div<br>**----- End of picture text -----**<br>


**==> picture [162 x 156] intentionally omitted <==**

**----- Start of picture text -----**<br>
POWER-UP AND DOWN THROUGH EN/UVLO<br>(VIN = 24V, VOUT = 3.3V, IOUTIN = 24V, VOUT = 3.3V, IOUT = 24V, VOUT = 3.3V, IOUTOUT = 3.3V, IOUT = 3.3V, IOUTOUT = 4A, PWM MODE)<br>toc32<br>2V/div<br>VEN/UVLOEN/UVLO<br>2V/div<br>VOUTOUT<br>5V/div<br>VRESETRESET<br>5A/div<br>IOUTOUT<br>a 4ms/div<br>**----- End of picture text -----**<br>


**==> picture [155 x 148] intentionally omitted <==**

**----- Start of picture text -----**<br>
POWER-UP WITH 2.5V BIAS<br>(VIN = 24V, VOUT = 5V, IOUT = 0A, PWM MODE)<br>toc33<br>2V/div<br>VEN/UVLO<br>2V/div<br>VOUT<br>5V/div<br>VRESET<br>4ms/div<br>**----- End of picture text -----**<br>


**==> picture [157 x 155] intentionally omitted <==**

**----- Start of picture text -----**<br>
POWER-UP WITH 2.5V BIAS<br>(VIN = 24V, VOUT = 3.3V, IOUT = 0A, PWM MODE)<br>toc34<br>2V/div<br>VEN/UVLO<br>1V/div<br>VOUT 5V/div<br>VRESET<br>4ms/div<br>**----- End of picture text -----**<br>


**LOAD TRANSIENT (VIN = 24V, VOUT = 5V, IOUT = 0A TO 2A, PWM MODE)** 

**==> picture [167 x 131] intentionally omitted <==**

**----- Start of picture text -----**<br>
toc35<br>VOUT (AC) 100mV/div<br>IOUT 2A/div<br>400 µ s/div<br>**----- End of picture text -----**<br>


**==> picture [166 x 151] intentionally omitted <==**

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LOAD TRANSIENT<br>(VIN = 24V, VOUT = 5V, IOUT = 2A TO 4A, PWM MODE)<br>toc36<br>VOUT (AC) 100mV/div<br>2A/div<br>IOUT<br>400 µ s/div<br>**----- End of picture text -----**<br>


Maxim Integrated │ 9 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

**==> picture [165 x 146] intentionally omitted <==**

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LOAD TRANSIENT<br>(VIN = 24V, VOUT = 3.3V, IOUT = 0A TO 2A, PWM MODE)<br>toc37<br>VOUT (AC) 100mV/div<br>1A/div<br>IOUT<br>400 µ s/div<br>**----- End of picture text -----**<br>


**==> picture [168 x 149] intentionally omitted <==**

**----- Start of picture text -----**<br>
LOAD TRANSIENT<br>(VIN = 24V, VOUT = 3.3V, IOUT = 2A TO 4A, PWM MODE)<br>toc38<br>VOUT (AC) 100mV/div<br>2A/div<br>IOUT<br>400 µ s/div<br>**----- End of picture text -----**<br>


**==> picture [167 x 143] intentionally omitted <==**

**----- Start of picture text -----**<br>
LOAD TRANSIENT<br>(VIN = 24V, VOUT = 5V, IOUT = 25mA TO 2A, PFM MODE)<br>toc39<br>VOUT (AC) 100mV/div<br>IOUT 1A/div<br>400 µ s/div<br>**----- End of picture text -----**<br>


**==> picture [167 x 142] intentionally omitted <==**

**----- Start of picture text -----**<br>
LOAD TRANSIENT<br>(VIN = 24V, VOUT = 3.3V, IOUT = 25mA TO 2A, PFM MODE)<br>toc40<br>VOUT (AC) 100mV/div<br>IOUT 1A/div<br>400µs/div<br>**----- End of picture text -----**<br>


**==> picture [168 x 137] intentionally omitted <==**

**----- Start of picture text -----**<br>
LOAD TRANSIENT<br>(VIN = 24V, VOUT = 5V, IOUT = 25mA TO 2A, DCM MODE)<br>toc41<br>VOUT (AC) 100mV/div<br>IOUT 1A/div<br>400 µ s/div<br>**----- End of picture text -----**<br>


**==> picture [161 x 140] intentionally omitted <==**

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LOAD TRANSIENT<br>(VIN = 24V, VOUT = 3.3V, IOUT = 25mA TO 2A, DCM MODE)<br>toc42<br>VOUT (AC) 100mV/div<br>IOUT 1A/div<br>400 µ s/div<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down 

## SiP Power Module with Integrated Inductor 

## **Typical Operating Characteristics (continued)** 

(VIN = VEN/UVLO = 24V, VSGND = VPGND = 0V, TA = -40°C to +125°C, unless otherwise noted. Typical values are at TA = +25°C. All voltages are referenced to GND, unless otherwise noted. The circuit values for different output-voltage applications are as in Table 1, unless otherwise noted.) 

**==> picture [506 x 324] intentionally omitted <==**

**----- Start of picture text -----**<br>
OUTPUT SHORT IN STEADY STATE STARTUP INTO SHORT SYNC FREQUENCY AT 630kHz<br>(VIN = 24V, VOUT = 5V, PWM MODE) (VIN = 24V, VOUT = 5V, PWM MODE) (VIN = 24V, VOUT = 5V, IOUT = 4A, PWM MODE)<br>toc43 toc44 toc45<br>20V/div  2V/div  10V/div<br>VLX VEN/UVLO<br>VOUT 500mV/div  VLX<br>VOUT 5V/div  20V/div<br>5V/div  VLX 50mV/div<br>SHORT 5A/div<br>5V/div<br>5A/div<br>IOUT IOUT VSYNC<br>ima fc<br>20ms/div 2ms/div 10 µ s/div<br>BODE PLOT BODE PLOT OUTPUT CURRENT<br>(VIN = 24V, VOUT = 5V, IOUT = 4A) (VIN = 24V, VOUT = 5V, IOUT = 4A) vs. AMBIENT TEMPERATURE<br>40 toc46 120 40 toc47 120 5 toc48<br>30 PHASE 100 30 PHASE 100<br>20 | 80 20 SRE a 80 4<br>SSS | SSI<br>10 Oi 60 10 TL LT 60 3 Ht<br>40 40<br>0 COIS 0 lll LA VOUT = 5V L<br>-10 Er GAIN 20 -10 PATTISON GAIN 20 2 S Ea eeve<br>0 0<br>-20-30 PTET fPHASE MARGIN = 63°CR = 36.49kHz,  Ta -20-40 -20-30 A fPHASE MARGIN = 58.7CR = 33.33kHz,  ° -20-40 1 VOUT = 3.3V Lat<br>-40 en CHAt -60 -40 naeAT CH -60 0 Pf Eype tT yy y<br>10 [3] 10 [4] 10 [5] 10 [3] 10 [4] 10 [5] 0 20 40 60 80 100 120 140<br>FREQUENCY (Hz) FREQUENCY (Hz) AMBIENT TEMPERATURE (°C)<br>GAIN (dB) ) ° PHASE ( GAIN (dB) ) ° PHASE (<br>OUTPUT CURRENT (A)<br>**----- End of picture text -----**<br>


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**----- Start of picture text -----**<br>
CONDUCTED EMISSION PLOT<br>(WITH FILTER C18 = C19 = C20 = C21 = C22 = 4.7µF,  L1 = 8.2µH)<br>toc49<br>CISPR-22 CLASS B QP LIMIT<br>60<br>CISPR-22 CLASS B AVG LIMIT<br>50<br>40 AVERAGE EMISSION<br>PEAK EMISSION<br>30<br>20<br>10<br>cc aeaeni i<br>0.15 1 10 30<br>FREQUENCY (MHz)<br>CONDITIONS : VIN = 24V, VOUT = 5V, IOUT = 4A<br>FROM :  MAXM17536EVKIT#<br>AMPLITUDE (dBµV)<br>**----- End of picture text -----**<br>


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RADIATED EMISSION PLOT<br>(NO FILTER C18 = C19 = C20 = C21 = C22 = OPEN, L1 = SHORT)<br>toc50<br>60<br>50<br>40 CISPR-22 CLASS B QP LIMIT<br>30<br>VERTICAL SCAN<br>20<br>10<br>0<br>HORIZONTAL SCAN<br>-<br>30 100 1000<br>FREQUENCY (MHz)<br>CONDITIONS : VIN = 24V, VOUT = 5V, IOUT = 4A<br>FROM :  MAXM17536EVKIT#<br>AMPLITUDE (dBµV/m)<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Pin Configuration** 

**==> picture [505 x 295] intentionally omitted <==**

**----- Start of picture text -----**<br>
MODE/SYNC IN PGND DL OUT OUT<br>+<br>VCC 1 29 28 27 26 25 23 OUT<br>24<br>RESET 2 22 OUT<br>MAXM17536<br>RT 3 21 PGND<br>EP1 EP2<br>SGND 4 20 PGND<br>CF 5 19 PGND<br>EP3<br>FB 6 18 PGND<br>7 8 9 10 11 12 13 14 15 16 17 PGND<br>SS EN/UVLO IN PGND EXTVCC BST LX PGND PGND PGND<br>29-PIN SiP<br>(9mm x 15mm x 4.32mm)<br>**----- End of picture text -----**<br>


## **Pin Description** 

|**PIN**|**NAME**|**FUNCTION**|
|---|---|---|
|1|VCC|5V LDO Output. The VCCis bypassed to PGND internally through a 2.2µF capacitor.<br>Do not connect any external components to the VCCpin.|
|2|RESET|Open-DrainRESETOutput. TheRESEToutput is driven low if FB drops below 92.5% of its set value.<br>RESETgoes high 1024 clock cycles after FB rises above 95.5% of its set value. See the _RESET Output_<br>section for more details.|
|3|RT|Switching Frequency Programming. Connect a resistor from RT to SGND to set the regulator's<br>switching frequency. Leave RT open for the default 450kHz frequency. See the _Setting the Switching_<br>_Frequency (RT)_ section for more details.|
|4|SGND|Analog Ground.|
|5|CF|Compensation Pin. Connect a 2.2pF capacitor from CF to FB.|
|6|FB|Feedback Input. Connect FB to the center tap of an external resistor-divider from the OUT to SGND to<br>set the output voltage.|



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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Pin Description (continued)** 

|**PIN**|**NAME**|**FUNCTION**|
|---|---|---|
|7|SS|Soft-Start Input. Connect a capacitor from SS to SGND to set the soft-start time.|
|8|EN/UVLO|Enable/Undervoltage-Lockout Input. Connect a resistor from EN/UVLO to SGND to set the UVLO<br>threshold. By default, the module is enabled with the EN/UVLO pin open.|
|9, 28|IN|Power-Supply Input. Decouple to PGND with a capacitor; place the capacitor close to the IN and<br>PGND pins.|
|10, 14-21,<br>27|PGND|Power Ground|
|11|EXTVCC|External Power Supply Input for the Internal LDO. Applying a voltage between 4.7V and 24V at the<br>EXTVCC pin bypasses the internal LDO and improves efciency.|
|12|BST|Boost Flying Capacitor Node. Internally a 0.1μF is connected from BST to LX. Do not connect any<br>external components to the BST pin.|
|13|LX|Switching Node. Leave unconnected; do not connect any external components to the LX pin.|
|22-25|OUT|Regulator Output Pin. Connect a capacitor from OUT to PGND.|
|26|DL|Gate Drive for Low-Side MOSFET. Do not connect any external components to the DL pin.|
|29|MODE/<br>SYNC|MODE Pin Confgures the Part to Operate in PWM, PFM, or DCM Modes of Operation. Leave MODE<br>unconnected for PFM operation (pulse skipping at light loads). Connect MODE to SGND for<br>constant frequency PWM operation at all loads. Connect MODE to VCCfor DCM operation.<br>The device can be synchronized to an external clock using this pin. See the_Mode Selection (MODE)_<br>section for more details.|
|EP1, EP2,<br>EP3|—|Exposed Pad. Create a large copper plane below the module connecting EP1, EP2, and EP3 to<br>improve heat dissipation capability. PGND and SGND are shorted through this plane.|



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## MAXM17536 

- 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Functional Diagrams** 

## **Internal Diagram** 

**==> picture [506 x 498] intentionally omitted <==**

**----- Start of picture text -----**<br>
MAXM17536<br>IN<br>VCC LDO<br>SELECT<br>1µF 1µF<br>2.2µF<br>INLDO<br>EXTVCC<br>BST<br>4.7Ω LDO 3.32MΩ<br>0.1µF 0.1µF<br>SGND CURRENT SENSE LX<br>LOGIC<br>4.7uH<br>EN/UVLO<br>PEAK  OUT<br>CURRENT<br>1.215V MODE  0.22µF<br>HICCUP CONTROLLER<br>RT OSCILLATOR 4.7Ω PGND<br>DL<br>CF<br>FB MODE<br>ERROR AMPLIFIER SELECTION MODE/<br>/LOOP COMPENSATION LOGIC SYNC<br>SLOPE<br>VCC COMPENSATION<br>SWITCHOVER<br>LOGIC<br>RESET<br>5μ A<br>SS<br>FB<br>HICCUP RESET<br>Logic<br>EN/UVLO<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Detailed Description** 

The MAXM17536 is a high-efficiency, high-voltage, synchronous step-down module with dual-integrated MOSFETs that operates over a 4.5V to 60V input, and supports a programmable output voltage from 0.9V to 12V, delivering up to 4A current. Built-in compensation for the entire output-voltage range eliminates the need for external components. The feedback (FB) regulation accuracy over -40°C to +125°C is ±1.5%. 

The device features a peak-current-mode control architecture. An internal transconductance-error amplifier produces an integrated error voltage at an internal node that sets the duty cycle using a PWM comparator, a highside current-sense amplifier, and a slope-compensation generator. At each rising edge of the clock, the highside MOSFET turns on and remains on until either the appropriate or maximum duty cycle is reached, or the peak current limit is detected. During the high-side MOSFET’s on-time, the inductor current ramps up. During the second half of the switching cycle, the high-side MOSFET turns off and the low-side MOSFET turns on. The inductor releases the stored energy as its current ramps down and provides current to the output. The device features a MODE/SYNC pin that can be used to operate the device in PWM, PFM, or DCM control schemes and to synchronize the switching frequency to an external clock. The device integrates adjustable-input undervoltage lockout, adjustable soft-start, open-drain RESET , auxiliary bootstrap LDO, and DL-to-OUT short-detection features. 

## **Mode Selection (MODE)** 

The logic state of the MODE/SYNC pin is latched when VCC and EN/UVLO voltages exceed the respective UVLO rising thresholds and all internal voltages are ready to allow LX switching. If the MODE/SYNC pin is open at power-up, the device operates in PFM mode at light loads. If the MODE/SYNC pin is grounded at power-up, the device operates in constant-frequency PWM mode at all loads. Finally, if the MODE/SYNC pin is connected to VCC at power-up, the device operates in constant frequency DCM mode at light loads. State changes on the MODE/SYNC pin are ignored during normal operation. 

## **PWM-Mode Operation** 

In PWM mode, the inductor current is allowed to go negative. PWM operation provides constant frequency operation at all loads, and is useful in applications sensitive to changes in switching frequency. However, the PWM mode of operation gives lower efficiency at light loads compared to PFM and DCM modes of operation. 

## **PFM-Mode Operation** 

The PFM mode of operation disables negative inductor current and additionally skips pulses at light loads for high efficiency. In PFM mode, the inductor current is forced to a fixed peak of 2A (typ) every clock cycle until the output rises to 102.3% of the nominal voltage. Once the output reaches 102.3% of the nominal voltage, both the highside and low-side FETs are turned off and the device enters hibernate operation until the load discharges the output to 101.1% of the nominal voltage. Most of the internal blocks are turned off in hibernate operation to minimize quiescent current. After the output falls below 101.1% of the nominal voltage, the device comes out of hibernate operation, turns on all internal blocks, and again commences the process of delivering pulses of energy to the output until it reaches 102.3% of the nominal output voltage. The advantage of the PFM mode is higher efficiency at light loads because of lower quiescent current drawn from the supply. The disadvantage is that the output-voltage ripple is higher compared to PWM or DCM modes of operation and switching frequency is not constant at light loads. 

## **DCM-Mode Operation** 

DCM mode of operation features constant frequency operation down to lighter loads than PFM mode, by not skipping pulses but only disabling negative inductor current at light loads. DCM operation offers efficiency performance that lies between PWM and PFM modes 

## **Linear Regulator** 

The MAXM17536 has two internal low-dropout (LDO) regulators that powers VCC. During power-up, when the EN/UVLO pin voltage is above the true shutdown voltage (0.8V), then the VCC is powered from INLDO. When VCC voltage is above the VCC UVLO threshold and EXTVCC voltage is greater than 4.7V (typ) the VCC is powered from EXTVCC LDO. Only one of the two LDOs is in operation at a time depending on the voltage level present at EXTVCC. Powering VCC from EXTVCC increases efficiency at higher input voltages. EXTVCC voltage should not exceed 24V. 

Typical VCC output voltage is 5V. Internally VCC is bypassed with a 2.2μF ceramic capacitor to PGND. See the _Electrical Characteristics_ table for the current limit details for both the regulators. In applications where the buck converter output is connected to the EXTVCC pin, if the output is shorted to ground, then the transfer from EXTVCC LDO to INLDO happens seamlessly without any impact on the normal functionality. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Setting the Switching Frequency (RT)** 

The switching frequency of the MAXM17536 can be programmed from 100kHz to 2.2MHz by using a resistor connected from RT to SGND. The switching frequency (fSW) is related to the resistor connected at the RT pin (RRT) by the following equation: 

**==> picture [114 x 24] intentionally omitted <==**

where RRT is in kΩ and fSW is in kHz. Leaving the RT pin open causes the device to operate at the default switching frequency of 450kHz. See the _Electrical Characteristics_ table for RT resistor value recommendations for a few common frequencies. 

## **Operating Input-Voltage Range** 

The minimum and maximum operating input voltages for a given output voltage should be calculated as follows: 

**==> picture [228 x 72] intentionally omitted <==**

## where, 

VOUT = Steady-state output voltage, 

IOUT(MAX) = Maximum load current, 

fSW(MAX) = Maximum switching frequency, 

tON(MIN) = Worst-case minimum switch on-time (160ns). Also, for duty cycle > 0.5; 

**==> picture [189 x 16] intentionally omitted <==**

where fSW is the switching frequency in Hz. 

Choose greater of the two VIN(MIN) values obtained from the above equations as the minimum operating input voltage. 

The _Component Selection Table_ , Table 1 provides the operating input-voltage range and the optimum switchingfrequency range for the different selected output voltages. 

## **External Frequency Synchronization (SYNC)** 

The internal oscillator of the MAXM17536 can be synchronized to an external clock signal on the MODE/ SYNC pin. The external synchronization clock frequency must be between 1.1 x fSW and 1.4 x fSW, where fSW is the frequency programmed by the RT resistor. When an external clock is applied to the MODE/SYNC pin, the internal oscillator frequency changes to the external clock frequency (from the original frequency based on the RT setting) after detecting 16 external clock edges. The converter operates in PWM mode during synchronization operation. When the external clock is applied to the MODE/SYNC pin, the mode of operation changes to PWM from the initial state of PFM/DCM. When the external clock is removed on-fly then the internal oscillator frequency changes to the RT set frequency and the converter still continues to operate in PWM mode. The minimum external clock pulse-width high should be greater than 50ns. See the MODE/SYNC section in the _Electrical Characteristics_ table for details. 

## **DL-to-OUT Short Detection** 

In the MAXM17536, DL and OUT pins are adjacent to each other. To prevent damage to the low-side FET in case the DL pin is shorted to the OUT pins, the DL-toOUT short detection feature has been implemented. If the MAXM17536 detects that the DL pin is shorted to the OUT pins before startup, the startup sequence is not initiated and output voltage is not soft-started. 

## **Overcurrent Protection** 

The MAXM17536 is provided with a robust overcurrent protection (OCP) scheme that protects the modules under overload and output short-circuit conditions. A cycle-bycycle peak current limit turns off the high-side MOSFET whenever the high-side switch current exceeds an internal limit of 7.8A (typ). The module enters hiccup mode of operation, either if one occurrence of the runaway current limit 8.8A (typ), or if the FB node goes below 64.5% of its nominal regulation threshold after soft-start is complete. In hiccup mode, the module is protected by suspending switching for a hiccup timeout period of 32,768 switching cycles. Once the hiccup timeout period expires, soft-start is attempted again. Hiccup mode of operation ensures low power dissipation under output overload or short-circuit conditions. Note that when soft-start is attempted under overload condition, if feedback voltage does not exceed 64.5% of desired output voltage, the device switches at half the programmed switching frequency. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

The MAXM17536 is designed to support a maximum load current of 4A. The inductor ripple current is calculated as follows: 

**==> picture [239 x 27] intentionally omitted <==**

where: 

VOUT = Steady-state output voltage 

VIN = Operating input voltage 

## **Thermal-Shutdown Protection** 

Thermal shutdown protection limits total power dissipation in the MAXM17536. When the junction temperature of the device exceeds +165°C (typ), an on-chip thermal sensor shuts down the device, allowing the device to cool. The thermal sensor turns the device on again after the junction temperature cools by 10°C. Soft-start resets during thermal shutdown. Carefully evaluate the total power dissipation (see the _Power Dissipation_ section) to avoid unwanted triggering of the thermal shutdown in normal operation. 

fSW = Switching Frequency 

L = Power module output inductance (4.7µH ±20%) 

IOUT = Required output (load) current 

The following condition should be satisfied at the desired load current, IOUT: 

**==> picture [70 x 22] intentionally omitted <==**

## **RESET Output** 

The MAXM17536 includes a  comparator to monitor the output voltage. The open-drain RESET output requires an external pullup resistor. RESET goes high (high impedance) 1024 switching cycles after the regulator output increases above 95.5% of the designed nominal regulated voltage. RESET goes low when the regulator output voltage drops to below 92.5% of the nominal regulated voltage. RESET also goes low during thermal shutdown. 

## **Prebiased Output** 

When the MAXM17536 starts into a prebiased output, both the high-side and the low-side switches are turned off so that the converter does not sink current from the output. High-side and low-side switches do not start switching until the PWM comparator commands the first PWM pulse, at which point switching commences. The output voltage is then smoothly ramped up to the target value in alignment with the internal reference. 

## **Applications Information** 

## **Input-Capacitor Selection** 

The input-filter capacitor reduces peak currents drawn from the power source and reduces noise and voltage ripple on the input caused by the circuit’s switching. The input capacitor RMS current requirement (IRMS) is defined by the following equation: 

**==> picture [215 x 31] intentionally omitted <==**

where, IOUT(MAX) is the maximum load current. IRMS has a maximum value when the input voltage equals twice the output voltage (VIN = 2 x VOUT), so IRMS(MAX) = IOUT(MAX)/2. Choose an input capacitor that exhibits less than a +10°C temperature rise at the RMS input current for optimal long-term reliability. Use low-ESR ceramic capacitors with high ripple-current capability at the input. X7R capacitors are recommended in industrial applications for their temperature stability. The CIN capacitor values in Table 1 are the minimum recommended values for the associated operating conditions. 

In applications where the source is located distant from the MAXM17536 input, an electrolytic capacitor should be added in parallel to the ceramic capacitor to provide necessary damping for potential oscillations caused by the inductance of the longer input power path and input ceramic capacitor. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Output-Capacitor Selection** 

X7R ceramic output capacitors are preferred due to their stability over temperature in industrial applications. The output capacitors are usually sized to support a step load of 50% of the maximum output current in the application, so the output-voltage deviation is contained to 3% of the output-voltage change. The minimum required output capacitance can be calculated as follows: 

**==> picture [148 x 59] intentionally omitted <==**

where: 

ISTEP = Load-current step, 

tRESPONSE = Response time of the controller, 

VOUT = Allowable output-voltage deviation, 

fC = Target closed-loop crossover frequency, 

fSW = Switching frequency.Select fC to be 1/10th of fSW if the swtiching frequency is less than or equal to 400kHz. Select fC to be 40kHz if the switching frequency is more than 400kHz. 

## **Soft-Start Capacitor Selection** 

The MAXM17536 implements adjustable soft-start operation to reduce inrush current. A capacitor connected from the SS pin to SGND programs the soft-start time. The selected output capacitance (CSEL) and the output voltage (VOUT) determine the minimum required soft-start capacitor as follows: 

**==> picture [161 x 14] intentionally omitted <==**

The soft-start time (tSS) is related to the capacitor connected at SS (CSS) by the following equation: 

**==> picture [60 x 19] intentionally omitted <==**

## **Setting the Input Undervoltage-Lockout Level** 

The MAXM17536 offers an adjustable input undervoltage lockout level. Set the voltage at which MAXM17536 turns on. Calculate R3 as follows: 

**==> picture [78 x 26] intentionally omitted <==**

where R3 is in MΩ and VINU is the voltage at which the MAXM17536 is required to turn on. Ensure that VINU is higher than 0.8 x VOUT. 

## **Loop Compensation** 

The MAXM17536 is internally loop-compensated. Connect a 2.2pF capacitor from CF to FB for stable operation. Typically, designs with crossover frequency (fC) less than fSW/10 and less than 40kHz offers good phase margin and transient response. For other choices of fC, the design should be carefully evaluated according to user requirements. 

## **Adjusting Output Voltage** 

Set the output voltage with a resistive voltage-divider connected from the positive terminal of the output capacitor (VOUT) to SGND (see Figure 2). Connect the center node of the divider to the FB pin. To choose the resistive voltage-divider values calculate for resistor R1, then R2. 

First, calculate resistor R1 from the output to FB as follows: 

where: 

R1 is in kΩ 

fC = Desired crossover frequency (kHz) 

COUT = Derated value of the capacitor (µF) Then, calculate resistor R2 from FB to SGND as follows: 

**==> picture [73 x 26] intentionally omitted <==**

where tSS is in milliseconds and CSS is in nanofarads. For example, to program a 4ms soft-start time, a 22nF capacitor should be connected from the SS pin to SGND. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

**==> picture [504 x 130] intentionally omitted <==**

**----- Start of picture text -----**<br>
VOUT<br>MAXM17536<br>MAXM17536 R1<br>EN/UVLO FB<br>R3 SGND SGND R2<br>**----- End of picture text -----**<br>


_Figure 1. Setting the Input-Undervoltage Lockout_ 

_Figure 2. Setting the Output Voltage_ 

## **Component Selection Table** 

**Table 1. Selection Component Values** 

|**VIN**<br>**(V)**|**VOUT**<br>**(V)**|**CIN**|**COUT**|**R1**<br>**(kΩ)**|**R2**<br>**(kΩ)**|**fSW**<br>**(kHz)**|**RRT**<br>**(KΩ)**|
|---|---|---|---|---|---|---|---|
|4.5 to 16|0.9|4 x 4.7µF, 1206, X7R, 50V|12 x 47μF, 1210, X7R, 10V|33.2|Open|300|61.9|
|4.5 to 17|1.2|4 x 4.7µF, 1206, X7R, 50V|9 x 47μF, 1210, X7R, 10V|39.2|118|400|45.3|
|4.5 to 21|1.5|4 x 4.7µF, 1206, X7R, 50V|7 x 47μF, 1210, X7R, 10V|52.3|78.7|400|45.3|
|4.5 to 26|1.8|4 x 4.7µF, 1206, X7R, 50V|5 x 47μF, 1210, X7R, 10V|71.5|71.5|400|45.3|
|4.5 to 35|2.5|4 x 4.7µF, 1206, X7R, 50V|5 x 47μF, 1210, X7R, 10V|57.6|32.4|400|45.3|
|4.5 to 60|3.3|4 x 4.7µF, 1206, X7R, 100V|4 x 47μF, 1210, X7R, 10V|121|45.3|300|61.9|
|7 to 60|5|4 x 4.7µF, 1206, X7R, 100V|3 x 22μF, 1210, X7R, 25V|174|38.3|450|Open|
|11 to 60|8|4 x 4.7µF, 1206, X7R, 100V|3 x 22μF, 1210, X7R, 25V|294|37.4|750|24|
|16 to 60|12|4 x 4.7µF, 1206, X7R, 100V|3 x 22μF, 1210, X7R, 25V|340|27.4|900|19.6|



## **Power Dissipation** 

The power dissipation inside the module leads to increase in the junction temperature of the MAXM17536. The power loss inside the module at full load can be estimated as follows: 

**==> picture [188 x 58] intentionally omitted <==**

where: 

POUT = Total output power, VOUT = Output voltage, VIN = Input voltage, 

η is the efficiency of the power module at the desired operating conditions. See the _Typical Operating Characteristics_ for the power-conversion efficiency or measure the efficiency to determine the total power dissipation. The junction temperature (TJ) of the module can be estimated at any given maximum ambient temperature (TA) from the following equation: 

**==> picture [106 x 10] intentionally omitted <==**

For the MAXM17536 evaluation board, the thermal resistance from junction-to-ambient (θJA) is 24°C/W. Operating the module at junction temperatures greater than +125°C degrades operating lifetimes. An EE-SIM model is available for the MAXM17536 to simulate efficiency and power loss for the desired operating conditions. 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **PCB Layout Guidelines** 

- All connections carrying pulsed currents must be very short and as wide as possible. The inductance of these connections must be kept to an absolute minimum due to the high di/dt of the currents. Since inductance of a current carrying loop is proportional to the area enclosed by the loop, if the loop area is made very small, inductance is reduced. Additionally, small current-loop areas reduce radiated EMI. 

- A ceramic input-filter capacitor should be placed close to the IN pins of the module. This eliminates as much trace-inductance effects as possible and gives the module a cleaner voltage supply. 

- PCB layout also affects the thermal performance of the design. A number of thermal vias that connect to a large ground plane should be provided under the exposed pad of the part, for efficient heat dissipation. 

- For a sample layout that ensures first pass success, refer to the MAXM17536 evaluation kit PCB layout available at **www.maximintegrated.com** . 

## **Typical Application Circuits** 

## **Typical Application Circuit for 5V Output** 

**==> picture [504 x 261] intentionally omitted <==**

**----- Start of picture text -----**<br>
VIN 4.5V TO 60V<br>C1 C2 C3 C4<br>4.7µF 4.7µF 4.7µF 4.7µF IN<br>EN/UVLO OUT VOUT 3.3V, 4A<br>1.8MΩR3 VCC MAXM17536 121kΩR1 C5 C6 C7 C8<br>DL FB 47µF 47µF 47µF 47µF<br>BST CF<br>RESET LX R2<br>2.2pF 45.3kΩ<br>SS CF<br>CSS MODE/SYNC RT<br>22nF SGND EXTVCC PGND<br>R4<br>61.9kΩ<br>C1 ,C2 ,C3 ,C4 :  : GRM31CZ72A475KE11L<br>C5, C6, C7, C8: : GRM32ER71A476KE15L<br>**----- End of picture text -----**<br>


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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Typical Application Circuits (continued)** 

## **Typical Application Circuit 3.3V** 

**==> picture [504 x 260] intentionally omitted <==**

**----- Start of picture text -----**<br>
VIN 4.5V TO 60V<br>C1 C2 C3 C4<br>4.7µF 4.7µF 4.7µF 4.7µF IN<br>EN/UVLO OUT VOUT 3.3V, 4A<br>1.8MΩR3 VCC MAXM17536 R121kΩ1 C5 C6 C7 C8<br>DL FB 47µF 47µF 47µF 47µF<br>BST CF<br>RESET LX R2<br>2.2pF 45.3kΩ<br>SS CF<br>CSS MODE/SYNC RT<br>22nF SGND EXTVCC PGND<br>R4<br>61.9kΩ<br>C1 ,C2 ,C3 ,C4 :  : GRM31CZ72A475KE11L<br>C5, C6, C7, C8: : GRM32ER71A476KE15L<br>**----- End of picture text -----**<br>


## **Ordering Information** 

|**PART NUMBER**|**TEMP RANGE**|**PIN-PACKAGE**|
|---|---|---|
|MAXM17536ALY#|-40°C to +125°C|29 SiP|
|MAXM17536ALY#T|-40°C to +125°C|29 SiP|



_#Denotes a RoHS-compliant device that may include lead(Pb) that is exempt under the RoHS requirements. T = Tape and reel._ 

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## MAXM17536 

## 4.5V to 60V, 4A High-Efficiency, DC-DC Step-Down SiP Power Module with Integrated Inductor 

## **Revision History** 

|**Revision**|**History**|||
|---|---|---|---|
|**REVISION**<br>**NUMBER**|**REVISION**<br>**DATE**|**DESCRIPTION**|**PAGES**<br>**CHANGED**|
|0|6/19|Initial release|—|



For pricing, delivery, and ordering information, please visit Maxim Integrated’s online storefront at https://www.maximintegrated.com/en/storefront/storefront.html. 

_Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance._ 

© 2019 Maxim Integrated Products, Inc. │ 22 

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