MAX20734EPL+

EVALUATION KIT AVAILABLE MAX20734 Integrated, Step-Down Switching Regulator with PMBus General Description Benefits and Features The IC offers a broad range of programmable features through either the PMBus or a capacitor and resistor connected to a dedicated programming pin. Using this feature, the operation can be optimized for a specific application, reducing the component count and/or setting appropriate trade-offs between the regulator’s performance and system cost. Ease of programming enables using the same design for multiple applications. ●● Optimized Component Performance and Efficiency with Reduced Design-In Time • PMBus-Compliant Interface for Telemetry and Power Management • Voltage, Current, and Temperature Reporting through the Digital Bus The MAX20734 is a fully integrated, highly efficient switching regulator with PMBus™ for applications operating from 4.5V to 16V and requiring up to 40A (max) load. This single-chip regulator provides extremely compact, highefficiency power-delivery solutions with high-precision output voltages and excellent transient response for networking, datacom, and telecom equipment. The IC includes protection and telemetry features. Positive and negative cycle-by-cycle overcurrent protection and overtemperature protection ensure a rugged design. Input undervoltage lockout shuts down the device to prevent operation when the input voltage is out of specification. A status pin provides an output signal to show that the output voltage is within range and the system is regulating. ●● High Power Density and Low Component Count • Overall Solution Size 509mm2 Including Inductor and Output Capacitors • 90.7% Peak Efficiency with VDDH = 12V and VOUT = 1V • Fast Transient Response: Supports Up to 300A/μs Load-Step Transients ●● Increased Power-Supply Reliability with System and IC Self-Protection Features • Differential Remote Sense with Open-Circuit Detection • Hiccup Overcurrent Protection • Programmable Thermal Shutdown Typical System Efficiency vs. Load Current (VDDH = 12V) Applications 100 Communications Equipment Networking Equipment Servers and Storage Equipment Point-of-Load Voltage Regulators µP Chipsets Memory VDDQ I/O DESCRIPTION CURRENT INPUT RATING* VOLTAGE 95 90 85 EFFICIENCY (%) ●● ●● ●● ●● ●● ●● ●● 75 VOUT Vout = 5V= 5V 70 VOUT = 3.3V Vout = 3.3V 65 VOUT = 1.8V Vout = 1.8V OUTPUT VOLTAGE 60 VOUT Vout = 1V= 1V 50 Electrical rating 40A 4.5V to 16V 0.6V to 5.5V Thermal rating, TA = 55°C, 200LFM 35A 12V 1V Thermal rating, TA = 85°C, 0LFM 22A 12V 1V *For specific operating conditions, refer to the SOA curves in the Typical Operating Characteristics section. 19-8585; Rev 0; 1/17 80 VOUT = 1.2V Vout = 1.2V VOUT = 0.8V Vout = 0.8V 55 VOUT = 0.65V Vout = 0.65V 0 5 10 15 20 25 30 35 IOUT (A) Order Information appears at end of data sheet. PMBus is a trademark of SMIF, Inc. 40 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Absolute Maximum Ratings Input Pin Voltage (VDDH) (Note 1).........................-0.3V to +18V VCC ..........................................................................-0.3V to +2V STAT, OE, CLK, DATA, and SMALERT Pin Voltages........................................-0.3V to +4V PGMA, PGMB, VSENSE+ and VSENSE- Pin Voltages..........................................-0.3V to +2V Switching Node Voltage (VX) DC...........................-0.3V to +18V Switching Node Voltage (VX) 25ns (Note 2)...........-10V to +23V (BST - VX) Pin Differential....................................-0.3V to +2.5V Junction Temperature (TJ)................................................+150°C Storage Temperature Range............................. -65°C to +150°C Peak Reflow Temperature Lead-Free.............................. +260°C 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. Operating Ratings Input Voltage (VDDH)................................................. 4.5V to 16V Junction Temperature (TJ)................................. -40°C to +125°C Maximum Average Input Current (VDDH_MAX) (Note 3)..........6A Maximum Average Output Current (IMAX).............................40A Peak Output Current (IPK)......................................................90A Package Information PACKAGE TYPE: 15 FCQFN Package Code P154A9F+1 Outline Number 21-100027 Land Pattern Number 90-100025 THERMAL RESISTANCE Junction to Ambient (θJA) (Note 4; Still Air, No Heatsink) 12°C/W Junction to Case (θJC) 0.42°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 1: As measured at the VDDH pin referenced to GND pin immediately adjacent using a high-frequency scope probe with ILOAD at IMAX. A high-frequency input bypass capacitor must be located less than 60 mils from the VDDH pin per our design guidelines. Note 2: The 25ns rating is the allowable voltage on the VX node in excess of the -0.3V to +18V DC ratings. The VX voltage may exceed the DC rating in either the positive or negative direction for up to 25ns per cycle. Note 3: See the Average Input Current Limit section. Note 4: Data taken using Maxim’s evaluation kit (MAX20734EVKIT#). The PCB has four layers of 2oz copper. www.maximintegrated.com Maxim Integrated │  2 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Electrical Characteristics (Circuit of Figure 6, VDDH = 4.5V to 16V, TA = +25°C, unless otherwise noted. Typical values are at TA = +25°C. All devices 100% tested at TA = +25°C. Limits over temperature guaranteed by design.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 16 V 5.5 V SUPPLY VOLTAGE Supply-Voltage Range OUTPUT VOLTAGE (Note 5) Output-Voltage Range VDDH TJ = -40°C to +125°C 4.5 VOUT (Note 6) 0.6 1 Default is 1mV/μs; other values are set through PMBus; measured at VSENSE+/pins Programmable VOUT Slew Rates 2 VREF 0.6484 VBOOT Values VREF Tolerance mV/μs 4 Selected by C_SELA (Note 7) 0.8984 V 1.0 VREF VREF = 0.6484V, 0.8984V, and 1.0V (Notes 6, 8), referred to VSENSE+/- pins See Table 8 for accuracy vs. VREF (Note 7) Programmable VREF Range -1.0 +1.0 % 0.6016 1.0 V FEEDBACK LOOP Integrator Recovery Time Constant Gain (see the Control Loop Stability section for details) tREC RGAIN Gain Accuracy 20 Selected by R_SELB or PMBus (Notes 6, 7, 8, 9) (Notes 6, 8, 9) μs 0.8 1.6 mV/A 3.2 -20 +20 % SWITCHING FREQUENCY 400 Switching Frequency fSW 500 400kHz/600kHz/800kHz selected by C_SEL_B; other values are set through PMBus (Note 7) 600 kHz 700 800 900 Switching Frequency Accuracy (Notes 6, 8, 9) -20 +20 % INPUT PROTECTION Rising VDDH UVLO Threshold Falling VDDH UVLO Threshold Hysteresis www.maximintegrated.com VDDH UVLO (Note 6) 4.25 3.7 3.9 350 4.47 V mV Maxim Integrated │  3 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Electrical Characteristics (continued) (Circuit of Figure 6, VDDH = 4.5V to 16V, TA = +25°C, unless otherwise noted. Typical values are at TA = +25°C. All devices 100% tested at TA = +25°C. Limits over temperature guaranteed by design.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 9.5 13 16.5 % OUTPUT-VOLTAGE PROTECTION (OVP) Overvoltage-Protection, Rising Threshold OVP Relative to programmed VOUT OVP Deglitch Filter Time 8 Power-Good Protection, Falling Threshold Power-Good Protection Rising Threshold Relative to programmed VOUT PWRGD µs 6 9 12 % 3 6 9 % Power-Good Deglitch Filter Time 8 µs OVERCURRENT PROTECTION (OCP) Selected by R_SELB or PMBus (Notes 6, 7, 8, 9) Positive OCP Inception Threshold (Inductor Valley Current) OCP Negative OCP Inception Threshold (Inductor Valley Current) Selected by R_ SELB or PMBus Hysteresis OCP Setting 0 16.3 21 26.1 OCP Setting 1 20.8 27 33.0 OCP Setting 2 24.6 32 39.9 OCP Setting 3 30.6 38 45.5 OCP Setting 0 -28 OCP Setting 1 -33 OCP Setting 2 -39 OCP Setting 3 -44 Hysteresis applies only to positive OCP A A 15 % OVERTEMPERATURE PROTECTION (OTP) OTP Inception Threshold OTP Default is 150, 130 is set through PMBus (Notes 7, 8, 9) 120 130 140 140 150 160 Hysteresis °C 10 OE MAXIMUM VOLTAGE OE Maximum Voltage Rising Threshold Hysteresis OE Full VCC supply range; measured at the OE pin (Note 6) VDDH 2.5 0.83 0.97 V 0.2 OE Pin Input Resistance 200 OE Deglitch Filter Time 0.9 (Note 9) 275 0.9 350 kΩ 2.2 µs STARTUP TIMING Enable Time from OE Rise to Start of BST Charge tOE After tINIT 16 µs 0.75 Soft-Start Ramp Time tSS BST Charging Time tBST 3 or 1.5 can be bet by R_SELA; any value can be set by PMBus (Note 7) 1.5 3 ms 6 www.maximintegrated.com 8 µs Maxim Integrated │  4 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Electrical Characteristics (continued) (Circuit of Figure 6, VDDH = 4.5V to 16V, TA = +25°C, unless otherwise noted. Typical values are at TA = +25°C. All devices 100% tested at TA = +25°C. Limits over temperature guaranteed by design.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 3.6 V STAT PIN Allowable Pullup Voltage Status Output Low VOHSTAT VOLSTAT ISTAT = 2.5mA 0.4 ISTAT = 0.2mA, 0V < VCC < UVLO and 0V < VDDH < UVLO (Note 6) 0.65 ISTAT = 1.3mA, 0V < VCC < UVLO and 0V < VDDH < UVLO (Note 6) 0.75 Status Output High Leakage Current ISTAT STAT pulled up to 3.3V through 20kΩ (Note 6) Time from VOUT Ramp Completion to STAT Pin Released tSTAT STAT output low to high, default is 125; 2000 can be set through PMBus (Note 7) 7 125 V µA µs 2000 PGMA AND PGMB PINS (see Tables 2–5) Allowable R_SEL Resistor Range 12 resistor values detected R_SEL Resistor Required Accuracy EIA standard resistor values only Allowable C_SEL Capacitor Range 3 options (0pF, 220pF, or 1000pF) C_SEL Capacitor Required Accuracy Use X7R or better Allowable External Capacitance Load and stray capacitance in addition to C_SELA/B 1.78 162 ±1 0 kΩ % 1000 ±20 pF % 20 pF 16 V PMBus TELEMETRY Reading Range 4.5 Reading Update Interval Reading Averaging Interval Reading Error VDDH Readback TA = -40°C to TJ = +125°C (Notes 8, 9, 10, 11) VSENSE Readback TA = -40°C to TJ = +125°C (Notes 8, 9, 10, 11) Reading Resolution www.maximintegrated.com ms 1 ms +25 0 Reading Update Interval IOUT Readback TA = -40°C to TJ = +125°C (Notes 8, 9, 10, 11) V 5 1.95 Reading Range % mV 1.25 -25 Reading Resolution Reading Error +3 0 Reading Update Interval Reading Averaging Interval ms 28 Reading Range Referred to SENSE Pins (VOUT may be scaled by divider in feedback) ms 1 -3 Reading Resolution Reading Averaging Interval 5 mV mV 25 A 5 ms 1 ms ±3 A 0.07 A Maxim Integrated │  5 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Electrical Characteristics (continued) (Circuit of Figure 6, VDDH = 4.5V to 16V, TA = +25°C, unless otherwise noted. Typical values are at TA = +25°C. All devices 100% tested at TA = +25°C. Limits over temperature guaranteed by design.) PARAMETER SYMBOL CONDITIONS Reading Range Reading Update Interval Reading Averaging Interval Reading Error MIN TYP -40 Temperature Readback (Notes 6, 8, 9) Reading Resolution MAX UNITS +125 °C 5 ms 1 ms ±8 °C 0.52 °C PMBus PINS (CLK, DATA, SMALERT) Input Rising Threshold Input Falling Threshold Hysteresis Output Low Voltage PMBus Clock Frequency SYSTEM SPECIFICATIONS (Note 10) Line Regulation Load Regulation (Static) Efficiency (VDDH = 12V, VOUT = 1V) VT_RISE VT_FALL VHYS VOL 0.83 0.9 0.97 V 0.62 0.7 0.79 V 0.2 Sinking 4mA fPM_CLK VOUT η ±0.2 IOUT = 0 - IMAX ±0.7 Peak 90.7 Full load (40A) 84.3 V 0.4 V 400 kHz % % Note 5: For proper regulation, it is required that VDDH > (VOUT + 2V). If VOUT is set > (UVLO - 2V), the IC may come out of UVLO, but regulation is not guaranteed while VDDH is below (VOUT + 2V). To avoid this condition, OE can be held low until VDDH > (VOUT + 2V). Note 6: Denotes specifications that apply over the temperature range of TJ = -40 to +125°C. Note 7: Denotes parameters that are programmable. Note 8: Min/Max limits are ≥ 4σ about the mean. Note 9: Guaranteed by design; not production tested. Note 10: These specifications refer to the operation of the system and are based on the circuit shown in the reference schematic. Tolerance of external components may affect these parameters. System performance numbers are measured using the Maxim evaluation board for this product with BOM, as shown on the MAX20734 EV kit data sheet. If a different PCB layout and different external components are used, these values may change. Note 11: A -40°C test condition is specified at a TA test condition, instead of TJ, to allow for self-heating. www.maximintegrated.com Maxim Integrated │  6 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Typical Operating Characteristics (Unless otherwise stated: Tested on the MAX20734EVKIT# EV kit with component values per Table 7, VDDH = 12V, VOUT = 1V, fSW = 400kHz, TA = 25°C, Still Air, and No Heatsink.) STARTUP RESPONSE TRANSIENT RESPONSE toc01 toc02 VX (20V/div) VOUT (20mV/div) STAT(2V/div) OE (2V/div) VOUT (200mV/div) TIME: 50µs/div CONDITIONS: IOUT = 20A to 30A STEP at 1A/µs TIME: 500µs/div TYPICAL VOUT RIPPLE SYSTEM EFFICIENCY vs. OUTPUT LOAD toc03 100 toc04 95 90 85 VX (10V/div) EFFICIENCY (%) VOUT (20mV/div) 80 75 VOUT Vout = 5V= 5V Vout = 3.3V VOUT = 3.3V 70 VOUT = 1.8V Vout = 1.8V Vout = 1.2V VOUT = 1.2V 65 60 Vout = 1V= 1V VOUT Vout = 0.8V VOUT = 0.8V 55 TIME: 5µs/div CONDITIONS: IOUT = 40A www.maximintegrated.com 50 Vout = 0.65V VOUT = 0.65V 0 5 10 15 20 25 IOUT (A) 30 35 40 Maxim Integrated │  7 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Typical Operating Characteristics (continued) (Unless otherwise stated: Tested on the MAX20734EVKIT# EV kit with component values per Table 7, VDDH = 12V, VOUT = 1V, fSW = 400kHz, TA = 25°C, Still Air, and No Heatsink.) JUNCTION TEMPERATURE vs. SYSTEM POWER DISSIPATION LOAD REGULATION toc05 0.4 VOUT = 5.5V 5.5V VOUT = 3.3V 3.3V 100 VOUT = 1.8V 1.8V 0.2 JUNCTION TEMPERATURE (°C) LOAD REGULATION (%) 0.3 1VVOUT = 1V VOUT = 0.65V .65V 0.1 0.0 -0.1 -0.2 -0.3 -0.4 5 10 15 20 25 30 35 SLOPE = 12°C/W 80 60 40 20 0 0 40 0 1 SYSTEM POWER DISSIPATION 35 Vout = 1.8V VOUT = 1.8V Vout = 1.2V VOUT = 1.2V 6 Vout = 0.65V VOUT = 0.65V 4 6 7 toc08 25 Vout=5.0V VOUT = 5.0V 20 15 3 10 2 5 1 0 0 5 Vout=0.8V VOUT = 0.8V Vout=1.2V VOUT = 1.2V Vout=3.3V VOUT = 3.3V 30 Vout = 1V= 1V VOUT Vout = 0.8V VOUT = 0.8V 5 4 40 IOUT (A) SYSTEM POWER DISSIPATION (W) 45 VOUT Vout = 5V= 5V Vout = 3.3V VOUT = 3.3V 7 3 SAFE OPERATING AREA (SOA) toc07 8 2 SYSTEM POWER DISSIPATION (W) IOUT (A) 9 toc06 120 0 5 10 15 20 IOUT (A) www.maximintegrated.com 25 30 35 40 30 40 50 60 70 80 90 100 TA (°C) CONDITIONS: 400LFM CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST Maxim Integrated │  8 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Typical Operating Characteristics (continued) (Unless otherwise stated: Tested on the MAX20734EVKIT# EV kit with component values per Table 7, VDDH = 12V, VOUT = 1V, fSW = 400kHz, TA = 25°C, Still Air, and No Heatsink.) SAFE OPERATING AREA (SOA) SAFE OPERATING AREA (SOA) toc09 45 45 40 40 35 25 Vout=5.0V VOUT = 5.0V 20 20 15 10 10 5 5 30 40 0 80 90 100 60 70 TA (°C) CONDITIONS: 200LFM CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST 50 SYSTEM EFFICIENCY vs. OUTPUT LOAD (VDDH = 5V) 100 80 90 100 60 70 TA (°C) CONDITIONS: STILL AIR / NO HEATSINK CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST 40 SYSTEM POWER DISSIPATION (W) 85 80 75 70 Vout = 1.8V VOUT = 1.8V Vout = 1.2V VOUT = 1.2V Vout = 1V= 1V VOUT Vout = 0.8V VOUT = 0.8V Vout = 0.65V VOUT = 0.65V 65 60 55 0 5 10 www.maximintegrated.com 15 20 IOUT (A) 25 30 toc12 Vout = 1.8V VOUT = 1.8V Vout = 1.2V VOUT = 1.2V Vout = 1V VOUT = 1V 5 Vout = 0.8V VOUT = 0.8V Vout = 0.65V VOUT = 0.65V 4 3 2 1 0 35 50 7 6 90 50 30 SYSTEM POWER DISSIPATION (VDDH = 5V) toc11 95 EFFICIENCY (%) 25 15 0 VOUT = 5.0V Vout=5.0V 30 IOUT (A) 30 IOUT (A) 35 Vout=0.8V VOUT = 0.8V Vout=1.2V VOUT = 1.2V Vout=3.3V VOUT = 3.3V toc10 Vout=0.8V VOUT = 0.8V Vout=1.2V VOUT = 1.2V Vout=3.3V VOUT = 3.3V 0 5 10 15 20 25 30 35 IOUT (A) Maxim Integrated │  9 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Typical Operating Characteristics (continued) (Unless otherwise stated: Tested on the MAX20734EVKIT# EV kit with component values per Table 7, VDDH = 12V, VOUT = 1V, fSW = 400kHz, TA = 25°C, Still Air, and No Heatsink.) SAFE OPERATING AREA (SOA) (VDDH = 5V) 40 35 35 30 30 25 25 IOUT (A) IOUT (A) SAFE OPERATING AREA (SOA) (VDDH = 5V) toc13 40 20 15 10 5 0 30 40 20 15 Vout=0.8V VOUT = 0.8V Vout=1.0V VOUT = 1.0V VOUT = 1.2V Vout=1.2V Vout=0.8V VOUT = 0.8V Vout=1.0V VOUT = 1.0V VOUT = 1.2V Vout=1.2V 10 5 50 60 70 80 90 100 TA (°C) CONDITIONS: 400LFM CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST toc14 0 30 40 50 60 70 80 90 100 TA (°C) CONDITIONS: 200LFM CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST SAFE OPERATING AREA (SOA) (VDDH = 5V) toc15 40 35 30 IOUT (A) 25 20 15 Vout=0.8V VOUT = 0.8V Vout=1.0V VOUT = 1.0V VOUT = 1.2V Vout=1.2V 10 5 0 60 70 80 90 100 TA (°C) CONDITIONS: STILL AIR / NO HEATSINK CURVE INDICATES TJ = 125°C, IOUT = IMAX, or IVDDH = IVDDH_MAX, WHICHEVER HAPPENS FIRST www.maximintegrated.com 30 40 50 Maxim Integrated │  10 MAX20734 Integrated, Step-Down Switching Regulator with PMBus PGMB DATA STAT Pin Configuration 15 14 13 VSENSE+ 1 12 CLK VSENSE- 2 11 AGND SMALERT 3 10 VCC PGMA 4 9 OE VDDH 5 8 BST 7 VX GND 6 (TOP VIEW) www.maximintegrated.com Maxim Integrated │  11 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Pin Description PIN NAME FUNCTION 1 VSENSE+ Remote-Sense Positive Node. Connect this node to VOUT at the load. A resistive voltage-divider can be used to regulate the output above the reference voltage. 2 VSENSE- Remote-Sense Negative Node. Connect this node to ground at the load using a Kelvin connection. 3 SMALERT 4 PGMA Program Node. Connect this node to ground through a programming resistor and capacitor. 5 VDDH Power Input Voltage. The high-side MOSFET switch is connected to this node. See the Input Capacitor Selection section for decoupling requirements. 6 GND Power Ground Node. The low-side MOSFET switch is connected to this node. 7 VX Power Switching Node. Connect this node to the inductor. 8 BST Bootstrap for High-Side Switch. Connect a 0.22μF ceramic capacitor between BST and VX. 9 OE Output Enable Node. This node is used to enable the regulator and has a precise threshold to allow sequencing of multiple regulators. There is an internal 275kΩ (typ) pulldown on this node. 10 VCC Analog/Gate-Drive Supply for the IC from Internal 1.85V (typ) LDO. This node must be connected to three 10µF X5R or better decoupling capacitors with very short, wide traces. VCC can be connected to 20kΩ pullups for STAT and OE, as shown in Figure 6. Do not connect VCC to other external loads. Do not overdrive VCC from an external source. 11 AGND SMALERT Pin Analog/Signal Ground. See the PCB Layout section for layout information. 12 CLK PMBus Clock 13 STAT Open-Drain Power-Good/Fault-Status Indication. Connect a pullup resistor to 1.8V or 3.3V. 14 DATA PMBus Data 15 PGMB Program Node. Connect this node to ground through a programming resistor and capacitor. www.maximintegrated.com Maxim Integrated │  12 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Block Diagram VCC tON TIMER STAT LDO VDDH BST R OE S DIGITAL CONTROL POWER SWITCHING Q VX PGMA CURRENT SENSE OCP PGMB GND CLK PMBus INTERFACE DATA PWM ERROR AMP VSENSE+ SMALERT VCC TELEMETRY VCC VCC CURRENT DAC VSENSE- AGND Operation Control Architecture The MAX20734 provides an extremely compact, highefficiency regulator solution with minimal external components and circuit design required. The monolithic solution includes the top and bottom power switches, gate drives, precision DAC reference, PWM controller, fault protections, and PMBus interface (see the Block Diagram). An external bootstrap capacitor is used to provide the drive voltage for the top switch. Other external components include the input and output filter capacitors, buck inductor, and a few resistors and capacitors to set the operating mode. The IC implements an advanced valley current-mode control algorithm that supports all multi-layer ceramic chip (MLCC) output capacitors and fast transient response. In steady state, it operates at a fixed switching frequency. When loading transients, the switching frequency speeds up to minimize the output voltage undershoot. Likewise, when unloading transients, the switching frequency slows down to minimize the output voltage overshoot. www.maximintegrated.com REFERENCE VOLTAGE AND SOFT-START The switching frequency can be set to 400kHz, 600kHz, or 800kHz through C_SELB and can be overridden through PMBus to 400kHz, 500kHz, 600kHz, 700kHz, 800kHz, or 900kHz. Voltage regulation is achieved by modulating the low-side on-time, comparing the difference between the feedback and reference voltages with the low-side current-sense signal using Maxim’s proprietary integrated current-sense technology. Once the PWM modulator forces a low-to-high transition, the high-side switch is enabled for a fixed time, after which the low-side switch is turned on again. An error amplifier with an integrator is used to maintain zero-droop operation. The integrator has a transient recovery time constant of 20μs (typ). During regulation, the differential voltage between the VSENSE+ and VSENSE- pins tracks the reference voltage, which is set by the DAC and can be set from 0.6016V to 1V. The sense pins can be connected to the output voltage through a voltage-divider so VOUT can be higher than 1V. The switching frequency is determined by the high-side on-time, as shown in Equation 1. Maxim Integrated │  13 MAX20734 Equation 1: Integrated, Step-Down Switching Regulator with PMBus completion of the soft-start ramp time plus the userprogrammable STAT blanking time (tSTAT) of 125μs or 2ms. If OE is pulled low, the IC shuts down. V f SW = × OUT t H_ON VDDH 1 Alternatively, the IC can be enabled by sending a PMBus Operate command. This raises the internal Operation signal, which is OR’d with the OE pin to create an internal OE signal. Therefore, when either the OE pin or the internal Operate signal go high, startup is initiated, but it takes both to be low to shut the part down. where: fSW = Switching frequency (MHz) tH_ON = On-period for high-side switch (μs) VOUT = Output voltage (V) VDDH = Input voltage (V) The tH_ON high-side on-time is controlled by the IC to be proportional to the duty cycle so that the resulting switching frequency is independent of supply voltage and output voltage. Equation 2: V t H_ON ∝ OUT VDDH The tH_ON pulse width is clamped to a minimum of 50ns (after tSS) and a maximum of 2µs to prevent any unexpected operation during extreme VOUT conditions. Voltage-Regulator Enable and Turn-On Sequencing The startup timing is shown in Figure 1. After VDDH is applied, the IC goes through an initialization time (tINIT) that takes up to 308μs. After initialization, OE is read. Once OE is high for more than the 16μs OE filter time (tOE), BST charging starts and is performed for 8μs (tBST), and then the soft-start ramp begins. The soft-start ramp time (tSS) can be 0.75ms, 1.5ms, 3ms, or 6ms depending on the user’s programmed value. VOUT ramps up linearly during the soft-start ramp time. If there are no faults, the STAT pin is released from being held low after the Soft-Start Control The initial output voltage behavior is determined by a linear ramp of the internal reference voltage from zero to the final value (tSS in Figure 1). The ramp time (tSS) is programmable from 0.75ms to 6ms. If the regulator is enabled when the output voltage has a residual voltage, the system will not regulate until the reference voltage ramps above this residual value. In this case, the tOE (OE valid to onset of regulation) specification is extended by the time required for the desired voltage startup ramp to reach the actual residual output voltage, but the time to reach the steady-state output voltage is unchanged. If the residual voltage is higher than the set output voltage, neither the high-side or low-side switch is turned on by the end of tSS. Under these conditions, switching begins after tSS. The MAX20734 exhibits a non-linearity during startup. This behavior is normal and does not have an adverse effect on system operation. With the circuit of Figure 6, the typical nonlinearity is 55mV with RGAIN = 0.8mV/A or 1.6mV/A, 330mV with RGAIN = 3.2mV/A, and 480mV with RGAIN = 6.4mV/A. The nonlinearity gets proportionately smaller as COUT increases. tINIT VCC tOE SHUTDOWN OE or OPERATE VOUT tBST tSS STAT tSTAT tINIT : Initialization, 308µs. tOE : OE enable filter time, 16µs. If OE enabled earlier than tINIT completion, it is ignored until tINIT completes. tBST : BST charging time, 8µs. tSS : Soft-start time per user selection, 0.75ms – 6ms. tSTAT : STAT blanking time, 2ms or 125µs through user selection. Figure 1. Startup Timing www.maximintegrated.com Maxim Integrated │  14 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Remote Output-Voltage Sensing To ensure the most accurate sensing of the output voltage, a differential voltage-sense topology is used, with a negative remote-sense pin provided. Point-of-load (PoL) sensing compensates for voltage drops between the output of the regulator and its load and provides the highest regulation accuracy. The voltage-sensing circuit features excellent common-mode rejection to further improve load voltage regulation. Protection and Status Operation Output-Voltage Protection The feedback voltage is continuously monitored for both undervoltage and overvoltage conditions. The typical fault-detection threshold is 13% above and 9% below the reference voltage (see the Electrical Characteristics table). If the output voltage falls below the power-good protection (PWRGD) threshold beyond the filter time, the STAT output goes low, but the system continues to operate, attempting to maintain regulation. If the output voltage rises above the overvoltage protection (OVP) threshold beyond the filter time, the STAT pin is lowered and the system shuts down until the output voltage falls within the valid range. the OCP threshold current, as shown in Figure 2. In this situation, turn-on of the high-side switch is prevented until the current falls below the threshold level. Since the inductor valley current is the controlled parameter, the average current delivered during positive current clamping remains a function of several system-level parameters. Note that IOCP has hysteresis and the value drops down to IOCP2 once it has been triggered (see Figure 2). Undervoltage Lockout (UVLO) The regulator internally monitors VDDH with a UVLO circuit. When the input supply voltage is below the UVLO threshold, the regulator stops switching, and the STAT pin is driven low. For UVLO levels, see the Electrical Characteristics table. Overtemperature Protection (OTP) The OTP-level default is 150°C and can be set to 130°C over PMBus. If the die temperature reaches the OTP level during operation, the regulator is disabled and the STAT pin is driven low. Overtemperature is a nonlatching fault, with the hysteresis shown in the Electrical Characteristics table. Table 1. Summary of Fault Actions FAULT Current Limiting and Short-Circuit Protection The regulator’s valley current-mode control architecture provides inherent current limiting and short-circuit protection. The bottom switch’s instantaneous current is monitored using integrated current sensing and is controlled on a cycle-by-cycle basis within the control block. Current clamping occurs when the minimum instantaneous (“valley”) low-side switch current level exceeds ACTION Power Good (Output Undervoltage) STAT LOW Output OVP STAT LOW, Shutdown and Restart Overtemperature STAT LOW, Shutdown and Restart Supply Fault (VDDH_ UVLO, VCC_UVLO) STAT LOW, Shutdown and Restart BST Fault STAT LOW, Shutdown and Restart IOCP(AVG) IOCP IOCP2 IOCP(AVG) = IOCP2 + I L 1 2 ( VDDH − VOUT ) x tH_ON LOUT where: IOCP2 = IOCP - Hysteresis Figure 2. Inductor Current During Current Limiting www.maximintegrated.com Maxim Integrated │  15 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Regulator Status (STAT) PGMA and PGMB Pin Functionality The STAT pin is low while the regulator is disabled and goes high after the startup ramp is completed, plus the programmed tSTAT blanking interval if the output voltage is within the PWRGD/OVP regulation window. The STAT pin is an open-drain output and is 3.3V tolerant. The pin remains low when VDDH is not present. The parasitic loading on the PGMA and PGMB pins must be limited to less than 20pF and greater than 20mΩ to avoid interfering with the R_SEL and C_SEL decoding. The STAT signal provides an open-drain output consistent with CMOS logic levels, which indicates whether the regulator is functioning properly. An external pullup resistor is required for connecting STAT to VCC or another 1.8V or 3.3V supply. The PGMA and PGMB pins are used to set up some of the key programmable features of the regulator IC. A resistor and capacitor are connected to the PGMA/B pins and their values are read during power-up initialization (e.g., power must be cycled to re-read the values). Table 3. PGMA Pin C_SELA Capacitor Values The STAT pin is driven low when one or more of the following conditions occurs: NO. C (pF) ±20% ● PWRGD fault (see the Output-Voltage Protection section) 1 Open 2 220 0.8984 3 1000 1 ● VSENSE- pin is left unconnected or shorted to VDDH ● Die temperature exceeds the temperature shutdown threshold shown in the Electrical Characteristics table VBOOT (V) 0.6484 Table 4. PGMB Pin R_SELB Values NO. R (kΩ) ±1% RGAIN (mΩ) OCP SETTING* 1 1.78 0.8 0 ● Supply voltage drops below the UVLO threshold 2 2.67 0.8 1 ● Fault detected on the BST node, such as shorted or open bootstrap capacitor 3 4.02 0.8 2 4 6.04 0.8 3 The ensuing startup follows the same timing shown in Figure 1. 5 9.09 3.2 0 6 13.3 3.2 1 7 20 3.2 2 8 30.9 3.2 3 ● OVP circuit detects that the output voltage is above the tolerance limit Table 2. PGMA Pin R_SELA Values NO. R (kΩ) ±1% SOFT-START TIME (mS) PMBus SLAVE ADDRESS (1010_xxx) 1 1.78 3 1010 000b 2 2.67 3 1010 001b 3 4.02 3 1010 010b 4 6.04 3 1010 011b 5 9.09 3 1010 100b 6 13.3 3 1010 101b 7 20 3 1010 110b 8 30.9 3 1010 111b 9 46.4 1.5 1010 000b NO. C (pF) ±20% 10 71.5 1.5 1010 001b 1 Open 11 107 1.5 1010 010b 2 220 600 12 162 1.5 1010 011b 3 1000 800 www.maximintegrated.com 9 46.4 1.6 0 10 71.5 1.6 1 11 107 1.6 2 12 162 1.6 3 *See the Electrical Characteristics table for values. Table 5. PGMB Pin C_SELB Capacitor Values fSW FEQUENCY (kHz) 400 Maxim Integrated │  16 MAX20734 Integrated, Step-Down Switching Regulator with PMBus PMBus Commands A summary of PMBus commands is shown in Table 6. PMBus communication can be initiated as soon as VCC is valid (after tINIT, Figure 1), regardless of the state of the OE and STAT pins. For more information, refer to AN6209: MAX20734 PMBus Application Note. PMBus Telemetry The IC provides input and output voltage, output current, and junction-temperature telemetry. Output voltage is measured at the VSENSE+/- pins. Therefore, if there is a divider in the feedback, the measurement is scaled by the divide ratio. For range and accuracy specifications, see the Electrical Characteristics table. For data format, refer to AN6209: MAX20734 PMBus Application Note. Table 6. Summary of PMBus Commands COMMAND NAME TYPE* NO. OF DATA BYTES COMMAND CODE COMMAND NAME TYPE* NO. OF DATA BYTES 01h OPERATION RW 1 7Dh STATUS_TEMPERATURE RO 1 02h ON_OFF_CONFIG RO 1 7Eh STATUS_CML RO 1 03h CLEAR_FAULTS WO 0 80h STATUS_MFR_SPECIFIC RO 1 10h WRITE_PROTECT RW 1 88h READ_VIN RO 2 1Bh PMBALERT_MASK RW 2 8Bh READ_VOUT RO 2 20h VOUT_MODE RO 1 8Ch READ_IOUT RO 2 21h VOUT_COMMAND RW 2 8Dh READ_TEMPERATURE_1 RO 2 24h VOUT_MAX RW 2 99h MFR_ID BLK 4 78h STATUS_BYTE RO 1 9Bh MFR_REVISION BLK 1 79h STATUS_WORD RO 2 D1h MFR_VOUT_MIN RW 2 7Ah STATUS_VOUT RO 1 D2h MFR_DEVSET1 RW 2 7Bh STATUS_IOUT RO 1 7Ch STATUS_INPUT RO 1 COMMAND CODE www.maximintegrated.com D3h MFR_DEVSET2 RW 2 *RW = Read/Write, WO = Write Only, RO = Read Only, and BLK = Block. Maxim Integrated │  17 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Reference Design Equation 3: A typical application schematic is shown in Figure 3, and optimum component values for common output voltages are shown in Table 7. where: Output-Voltage Setting VOUT = Output voltage I VDDH = If an output voltage not listed in Table 7 is required, calculate new values for RFB1 and RFB2 (as discussed below) and use the other circuit values of the closest output voltage in Table 7, or calculate them as shown below. VOUT × I OUT VDDH × η IOUT = Output current VDDH = Input voltage η = Efficiency (refer to the Typical Operating Characteristics section) Average Input Current Limit The input current of VDDH is given by Equation 3. VOUT, IOUT, and VDDH should be properly chosen so that the average input current does not exceed 6A (IVDDH_MAX). VDDH CVCC CIN VCC 1.8V or 3.3V STAT OE CLK DATA SMALERT CLK DATA SMALERT AGND C_SELA R_SELB CBST BST LOUT VOUT VX PGMA PGMB R_SELA VDDH MAX20734 RSTAT STAT OE 1.8V or 3.3V COMPLIANT I/O U1 RFB1 VSENSE+ VSENSECOUT RFB2 GND C_SELB Figure 3. Typical Application Circuit Table 7. Reference Design Component Values VOUT (V) RFB1 (kΩ) RFB2 R_SELA C_SELA R_SELB C_SELB (kΩ) (pF) (kΩ) (pF) (kΩ) 0.6484 1 Open 1.78 Open 107 0.8 1.37 5.9 1.78 Open fSW LOUT (kHz) (nH) RGAIN (mΩ) VREF (V) Open 1.6 0.6484 400 170 12 x 100μF + 1 x 22μF 71.5 Open 1.6 0.6484 400 170 10 x 100μF + 1 x 22μF COUT 1 1.87 3.48 1.78 Open 71.5 Open 1.6 0.6484 400 170 9 x 100μF + 1 x 22μF 1.2 1.74 2.05 1.78 Open 71.5 Open 1.6 0.6484 400 170 9 x 100μF + 1 x 22μF 1.8 3.09 1.74 1.78 Open 71.5 220 1.6 0.6484 600 170 9 x 100μF + 1 x 22μF 3.3 5.62 1.37 1.78 Open 162 220 1.6 0.6484 600 210 9 x 100μF + 1 x 22μF 5.0 7.15 1.07 1.78 Open 107 220 1.6 0.6484 600 210 9 x 100μF + 1 x 22μF Note: For input caps, see the Input Capacitor Selection section. www.maximintegrated.com Maxim Integrated │  18 MAX20734 Integrated, Step-Down Switching Regulator with PMBus The output voltage is set by the VREF DAC and divider ratio of resistors RFB1 and RFB2 per Equation 4. The IC regulates the VSENSE+ pin to the reference voltage (VREF) set by the DAC. Upon power-up, the DAC voltage initializes to one of the user-selectable VBOOT voltages. Using PMBus, the DAC can also be set to any voltage from 0.6016V to 1V with 3.9mV resolution, as shown in Table 8. The divider resistors are chosen to give the correct output voltage and to have an approximate parallel resistance of RPAR = 1kΩ for best common-mode rejection of the error amplifier. In applications requiring less than 10mV peak-topeak output voltage ripple, setting a lower DAC reference voltage such as 0.6484V or less is recommended because the part will have less DAC voltage noise. The divider resistors are then given by Equation 5. Equation 4: VOUT = Output voltage Equation 5:  R PAR  R =  FB1 VOUT ×   VREF   R PAR  R=  FB2 R FB1 ×  R -R  FB1 PAR  where: RFB1 = Top divider resistor RFB2 = Bottom divider resistor RPAR = Desired parallel resistance of RFB1 and RFB2 VREF = Reference voltage = 0.6016V to 1V (set by DAC)  R  VOUT = VREF × 1 + FB1  R FB2   where VREF = 0.6016V to 1V (set by DAC). Table 8. Voltage vs. PMBus VOUT_COMMAND VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) 307 0.6016 1.2% 325 0.6367 1.1% 343 0.6719 1.0% 308 0.6016 1.2% 326 0.6367 1.1% 344 0.6719 1.0% 309 0.6055 1.2% 327 0.6406 1.0% 345 0.6758 1.0% 310 0.6055 1.2% 328 0.6406 1.0% 346 0.6758 1.0% 311 0.6094 1.2% 329 0.6445 1.0% 347 0.6797 1.0% 312 0.6094 1.2% 330 0.6445 1.0% 348 0.6797 1.0% 313 0.6133 1.2% 331 0.6484 1.0% 349 0.6836 1.0% 314 0.6133 1.2% 332 0.6484 1.0% 350 0.6836 1.0% 315 0.6172 1.1% 333 0.6523 1.0% 351 0.6875 1.0% 316 0.6172 1.1% 334 0.6523 1.0% 352 0.6875 1.0% 317 0.6211 1.1% 335 0.6563 1.0% 353 0.6914 1.0% 318 0.6211 1.1% 336 0.6563 1.0% 354 0.6914 1.0% 319 0.6250 1.1% 337 0.6602 1.0% 355 0.6953 1.0% 320 0.6250 1.1% 338 0.6602 1.0% 356 0.6953 1.0% 321 0.6289 1.1% 339 0.6641 1.0% 357 0.6992 1.0% 322 0.6289 1.1% 340 0.6641 1.0% 358 0.6992 1.0% 323 0.6328 1.1% 341 0.6680 1.0% 359 0.7031 1.0% 324 0.6328 1.1% 342 0.6680 1.0% 360 0.7031 1.0% www.maximintegrated.com Maxim Integrated │  19 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Table 8. Voltage vs. PMBus VOUT_COMMAND (continued) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) 361 0.7070 1.0% 396 0.7734 1.0% 431 0.8438 1.0% 362 0.7070 1.0% 397 0.7773 1.0% 432 0.8438 1.0% 363 0.7109 1.0% 398 0.7773 1.0% 433 0.8477 1.0% 364 0.7109 1.0% 399 0.7813 1.0% 434 0.8477 1.0% 365 0.7148 1.0% 400 0.7813 1.0% 435 0.8516 1.0% 366 0.7148 1.0% 401 0.7852 1.0% 436 0.8516 1.0% 367 0.7188 1.0% 402 0.7852 1.0% 437 0.8555 1.0% 368 0.7188 1.0% 403 0.7891 1.0% 438 0.8555 1.0% 369 0.7227 1.0% 404 0.7891 1.0% 439 0.8594 1.0% 370 0.7227 1.0% 405 0.7930 1.0% 440 0.8594 1.0% 371 0.7266 1.0% 406 0.7930 1.0% 441 0.8633 1.0% 372 0.7266 1.0% 407 0.7969 1.0% 442 0.8633 1.0% 373 0.7305 1.0% 408 0.7969 1.0% 443 0.8672 1.0% 374 0.7305 1.0% 409 0.8008 1.0% 444 0.8672 1.0% 375 0.7344 1.0% 410 0.8008 1.0% 445 0.8711 1.0% 376 0.7344 1.0% 411 0.8047 1.0% 446 0.8711 1.0% 377 0.7383 1.0% 412 0.8047 1.0% 447 0.8750 1.0% 378 0.7383 1.0% 413 0.8086 1.0% 448 0.8750 1.0% 379 0.7422 1.0% 414 0.8086 1.0% 449 0.8789 1.0% 380 0.7422 1.0% 415 0.8125 1.0% 450 0.8789 1.0% 381 0.7461 1.0% 416 0.8125 1.0% 451 0.8828 1.0% 382 0.7461 1.0% 417 0.8164 1.0% 452 0.8828 1.0% 383 0.7500 1.0% 418 0.8164 1.0% 453 0.8867 1.0% 384 0.7500 1.0% 419 0.8203 1.0% 454 0.8867 1.0% 385 0.7539 1.0% 420 0.8203 1.0% 455 0.8906 1.0% 386 0.7539 1.0% 421 0.8242 1.0% 456 0.8906 1.0% 387 0.7578 1.0% 422 0.8242 1.0% 457 0.8945 1.0% 388 0.7578 1.0% 423 0.8281 1.0% 458 0.8945 1.0% 389 0.7617 1.0% 424 0.8281 1.0% 459 0.8984 1.0% 390 0.7617 1.0% 425 0.8320 1.0% 460 0.8984 1.0% 391 0.7656 1.0% 426 0.8320 1.0% 461 0.9023 1.0% 392 0.7656 1.0% 427 0.8359 1.0% 462 0.9023 1.0% 393 0.7695 1.0% 428 0.8359 1.0% 463 0.9063 1.0% 394 0.7695 1.0% 429 0.8398 1.0% 464 0.9063 1.0% 395 0.7734 1.0% 430 0.8398 1.0% 465 0.9102 1.0% www.maximintegrated.com Maxim Integrated │  20 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Table 8. Voltage vs. PMBus VOUT_COMMAND (continued) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) VOUT COMMAND [9:0] (decimal) VOLTAGE ACCURACY (V) (+/-) 466 0.9102 1.0% 482 0.9414 1.0% 498 0.9727 1.0% 467 0.9141 1.0% 483 0.9453 1.0% 499 0.9766 1.0% 468 0.9141 484 0.9453 1.0% 500 0.9766 1.0% 469 0.9180 1.0% 1.0% 0.9492 1.0% 501 0.9805 1.0% 0.9180 1.0% 485 470 486 0.9492 1.0% 502 0.9805 1.0% 471 0.9219 487 0.9531 1.0% 503 0.9844 1.0% 472 0.9219 488 0.9531 1.0% 504 0.9844 1.0% 473 0.9258 489 0.9570 1.0% 505 0.9883 1.0% 474 0.9258 490 0.9570 1.0% 506 0.9883 1.0% 475 0.9297 491 0.9609 1.0% 507 0.9922 1.0% 476 0.9297 492 0.9609 1.0% 508 0.9922 1.0% 477 0.9336 493 0.9648 1.0% 509 0.9961 1.0% 478 0.9336 494 0.9648 1.0% 510 0.9961 1.0% 479 0.9375 1.0% 495 0.9688 1.0% 511 1.0000 1.0% 480 0.9375 1.0% 496 0.9688 1.0% 512 1.0000 1.0% 481 0.9414 1.0% 497 0.9727 1.0% — — — 1.0% 1.0% 1.0% 1.0% 1.0% 1.0% 1.0% 1.0% Notes: The repeated voltage values in the table are due to ignoring the LSB in hardware. The available VBOOT values are highlighted in gray. Voltages shown are referenced to the sense pins. Actual VOUT can be scaled by a voltage-divider in the feedback. www.maximintegrated.com Maxim Integrated │  21 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Control-Loop Stability The IC uses valley current-mode control which is stabilized by selecting appropriate values of COUT and RGAIN. No compensation network is required. For stability, the loop bandwidth (BW) should be 100kHz or less. Consider the case of using MLCC output capacitors that have nearly ideal impedance characteristics in the frequency range of interest with negligible ESR and ESL. The loop bandwidth can be approximated by breaking the loop into gain terms as outlined below. 1) The IC’s valley current-mode control scheme has an effective transconductance gain of 1/RGAIN. 2) For MLCC capacitors, the output capacitors contribute an impedance gain of 1/(2 x π x COUT x f). 3) The feedback-divider contributes an attenuation of KDIV = RFB2/(RFB1 + RFB2). 4) An inherent high-frequency pole located at 150kHz. When the BW is 100kHz or less, the high-frequency pole can be ignored and the approximate loop gain and BW are given by Equation 6. Equation 6: LOOP_GAIN (f) = BW = OR BW = K DIV 2 × π × R GAIN × C OUT × f K DIV 2 × π × R GAIN × C OUT Integrator The IC has an integrator included in its error amplifier, which was ignored in the above equations for simplicity. The integrator only adds gain at low frequencies, so it does not really effect the loop BW calculation. The purpose of the integrator is to improve load regulation. The integrator adds a factor of (1/tREC + s)/s to the loop gain. Step Response RGAIN_EFF is important because it determines the smallsignal transient response of the regulator. When a load step is applied that does not exceed the slew-rate capability of the inductor current, the regulator responds linearly and VOUT temporarily changes by the amount of VOUT_ERROR (see Equation 7). Equation 7: VOUT_ERROR = I STEP × R GAIN_EFF The integrator causes VOUT to recover to the nominal value with a time constant of tREC = 20μs. The regulator can be modeled to a first-order by the averaged smallsignal equivalent circuit shown in Figure 4. Here, VEQ is an ideal voltage source, REQ is an equivalent lossless resistance created by the control-loop action, and LEQ is an equivalent inductance. Note that LEQ is not the same as the actual LOUT inductor that has been absorbed into the model. COUT is the actual output capacitance. tREC RGAIN_EFF 1 2 × π × R GAIN_EFF × C OUT LEQ where: RGAIN_EFF = RGAIN/KDIV For stability, RGAIN and COUT should be chosen so that BW < 100kHz. RGAIN_EFF The available RGAIN settings are shown in Table 4. When choosing which RGAIN setting to use, one should consider that while higher RGAIN allows the loop to be stabilized with less COUT, less COUT generally results in higher ripple and larger transient overshoot and undershoot, so there needs to be a balance. REQ VOUT COUT VOUT VEQ GND Figure 4. Averaged Small-Signal Equivalent Circuit of Regulator Note: The large-signal transient response is approximately the larger between the VOUT_ERROR and the unloading transient. www.maximintegrated.com Maxim Integrated │  22 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Output-Capacitor ESR In the above control-loop discussion, the case of MLCC output capacitors has been considered. Another case worth mentioning is the use of output capacitors with more significant ESR. This can be considered as long as the capacitors are rated to handle the inductor current ripple and expected surge currents. Thus far, it has been assumed that COUT is comprised of MLCCs and the net ESR is negligible compared to RGAIN/KDIV. If the net ESR of the COUT bank is not negligible compared to RGAIN/ KDIV, the inductor current ripple is effectively sensed by the ESR and adds to the RGAIN_EFF, as shown in Equation 8. Equation 8: R GAIN_EFF = R GAIN + ESR K DIV The capacitor’s ESR also introduces a zero into the loop gain. The inherent high-frequency pole helps to compensate this zero. For a more in-depth view of the effect of circuit values on regulator performance, the Maxim Simplis model and MAX20734 evaluation kit can be used. It is recommended to simulate and/or test regulator performance when using values other than the recommended component values. The performance data shown in the Typical Operating Characteristics section was taken using the MAX20734 evaluation kit and component values in Table 7. For most applications, these are the optimum values to use. Table 9, Table 10, and Table 11 show suitable part numbers for input and output capacitors and the inductor. Table 9. Recommended Inductors COMPANY VALUE (nH) I SAT (A) R DC (mΩ) FOOTPRINT (mm) HEIGHT (mm) PART NUMBER WEBSITE Cooper 170 60 0.29 10.4 x 8.0 7.5 FP1007R3-R17-R www.cooperindustries.com Pulse 215 41 0.29 10.4 x 7.9 7.3 PA2607.211NL www.pulseelectronics.com Pulse 270 34 0.29 10.4 x 7.9 7.3 PA2607.271NL www.pulseelectronics.com Pulse 320 45 0.32 13.5 x 13.0 8.0 PA0513.321NLT www.pulseelectronics.com Pulse 440 30 0.32 13.5 x 13.0 8.0 PA0513.441NLT www.pulseelectronics.com Table 10. MLCC Input Capacitors CASE SIZE VALUE (µF) TEMPERATURE RATING VOLTAGE RATING T (mm) (NOTE 1) COMPANY 0603 1 X7S X7R 16V 0.8 (Note 2) Murata TDK GRM188C71C105KA12D C1608X7R1C105K 0805 2.2 X7R 25V 16V 16V 1.25 1.25 1.25 Murata TDK AVX GRM21BR71E225KA73L C2012X7R1C225M 0805YC225MAT 0805 4.7 X7R 16V 1.25 Murata GRM21BR71C475K 1206YC475MAT GRM31CR71C475KA01L PART NUMBER 1206 4.7 X7R 16V 1.65 AVX Murata 1206 10 X7R 16V 1.65 Murata TDK AVX GRM31CR71C106KAC7L C3216X7R1C106M 1206YC106MAT 1210 10 X7R 16V 25V 2.0 2.5 Murata TDK GRM32DR71C106KA01L C3225X7R1E106M 1210 22 X7R 16V 2.45 2.5 2.5 AVX Murata TDK 1210YC226MAT GRM32ER71A476K C3225X7R1C226M Note 1: T indicates nominal thickness. Note 2: Indicates capacitors with nominal thickness smaller than the minimum FCQFN package thickness. www.maximintegrated.com Maxim Integrated │  23 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Table 11. Recommended Output Capacitors COMPANY VALUE (µF) PART NUMBER TEMPERATURE RATING VOLTAGE RATING CASE SIZE Τ (mm) (Note 1) WEBSITE AVX Corp. 22 22 08054D226MAT2A 12066D226MAT2A X5R X5R 4V 6.3V 0805 1206 1.3 1.65 www.avxcorp.com Murata 22 22 22 GRM21BR60J226ME39L GRM31CR60J226KE19L GRM32DR60J226KA01L X5R X5R X5R 6.3V 6.3V 6.3V 0805 1206 1210 1.25 1.6 2.0 www.murata.co.jp Panasonic 22 22 22 ECJ3YB0J226M ECJHVB0J226M ECJ3Y70J226M X5R X5R X7R 6.3V 6.3V 6.3V 1206 1206 1206 1.6 0.85 1.65 www.panasonic. com Taiyo Yuden 22 22 22 AMK212BJ226MG JMK316BJ226ML JMK325BJ226MY X5R X5R X5R 4V 6.3V 6.3V 0805 1206 1210 1.25 1.6 1.9 www.taiyo-yuden. com TDK Corp. 22 22 22 22 C2012X5R0J226M C3216X5R0J226M C3225X5R0J226M C3216X6S0J226M X5R X5R X5R X6S 6.3V 6.3V 6.3V 6.3V 0805 1206 1210 1206 1.25 1.6 1.6 1.6 www.component. tdk.com Note 1: T indicates nominal thickness. Inductor Selection The output inductor has an important influence on the overall size, cost, and efficiency of the voltage regulator. Since the inductor is typically one of the larger components in the system, a minimum inductor value is particularly important in space-constrained applications. Smaller inductor values also permit faster transient response, reducing the amount of output cap needed to maintain transient tolerances. For any buck regulator, the maximum current slew rate through the output inductor is given by Equation 9. Equation 9: dIL VL SlewRate = = dt L OUT where: IL = Inductor current LOUT = Output inductance VL = VDDH - VOUT during high-side FET conduction and -VOUT during low-side FET conduction Equation 9 shows that larger inductor values limit the regulator’s ability to slew current through the output inductor in response to step-load transients. Consequently, more output capacitors are required to supply (or store) sufficient charge to maintain regulation while the inductor current ramps up to supply the load. www.maximintegrated.com In contrast, smaller inductor values increase the regulator’s maximum achievable slew rate and decrease the necessary capacitance, at the expense of higher ripple current. The peak-to-peak ripple current is given by Equation 10. Equation 10: I OUTRIPPLE = t H_ON × (VDDH − VOUT ) L OUT where: tH_ON = High-side switch on-time (based on nominal VOUT) (see Equation 1) LOUT = Output inductance VDDH = Input voltage VOUT = Output voltage From Equation 10, for the same switching frequency and ripple current increases as L decreases. This increased ripple current results in increased AC losses, larger peak current, and for the same output capacitance, results in increased output voltage ripple. Maxim Integrated │  24 MAX20734 Integrated, Step-Down Switching Regulator with PMBus IOUTRIPPLE should be set to 25% to 50% of the IC’s rated output current. A suitable inductor value can then be found by solving Equation 10 for inductance as in Equation 11 and Equation 12. Equation 11: L OUT = VOUT (VDDH − VOUT ) VDDH × I OUTRIPPLE × f SW Assuming IOUTRIPPLE = 0.5 x IOUT for a typical inductor value, see Equation 12. Equation 12: LOUT = VOUT ( VDDH − VOUT ) VDDH × ( 0.5 ×IOUT ) × fSW For a 25A regulator running at 400kHz, with VDDH = 12V and VOUT = 1V, Equation 13 shows the target value for the inductor. Equation 13: LOUT = 1× (12 − 1) 12 × 0.5 × 25 × 400000 = 183nH The saturation current rating of the inductor is another important consideration. At current limit, the peak inductor current is given in Equation 14. Equation 14: IPK = I OCP + I OUTRIPPLE where: IOCP = Overcurrent protection trip point (see the Electrical Characteristics table and the Current Limiting and ShortCircuit Protection section) IOUTRIPPLE = Peak-to-peak inductor current ripple, as defined above For proper OCP operation of the regulator, it is important that IPK never exceeds the saturation current rating of the inductor (ISAT). It is recommended that a margin of at least 20% is included between IPK and ISAT, as shown in Equation 15. Equation 15: I SAT > 1.2 × IPK www.maximintegrated.com Also, note that during a hard VOUT short circuit, IOUTRIPPLE increases due to VOUT going to zero in Equation 10. Finally, the power dissipation of the inductor influences the regulation efficiency. Losses in the inductor include core loss, DC resistance loss, and AC resistance loss. For the best efficiency, use inductors with core material exhibiting low loss in the range of 0.5MHz to 2MHz, and low-winding resistance. Table 9 provides a summary of the recommended inductor suppliers and part numbers. Output Capacitor Selection The minimum recommended output capacitance for stability is described in the Control-Loop Stability section and is normally implemented using several 100µF 1206 (or similar) MLCCs. For low slew-rate transient loads, RGAIN_ EFF determines the VOUT_ERROR for a given load step per the small-signal model, as discussed above. In this case, COUT has no effect on the VOUT_ERROR. However, in the event that the slew rate of the load transient greatly exceeds the slew rate of the inductor current, the transient VOUT_ERROR may be larger than predicted by the small-signal model. In this case, the VOUT loading and unloading transients can be approximated by taking the larger result between Equation 7 and Equation 16. Equation 16: I   LOUT ×  ISTEP + OUTRIPPLE  2   LOADINGTRANSIENT(V) = 2 × COUT × ( VDDH − VOUT ) 2 I   LOUT ×  ISTEP + OUTRIPPLE  2   UNLOADINGTRANSIENT(V) = 2 × COUT × VOUT + ISTEP × 2 tH _ ON COUT In order to meet an aggressive transient specification, COUT may have to be increased and/or LOUT decreased; however, note that decreasing LOUT results in larger inductor ripple current; thus, decreased efficiency and increased output ripple. Maxim Integrated │  25 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Output voltage ripple is another important consideration in the selection of output capacitors. For a buck regulator operating in CCM, the total voltage ripple across the output capacitor bank can be approximated as the sum of three voltage waveforms: 1) the triangle wave that results from multiplying the AC ripple current by the ESR, 2) the square wave that results from multiplying the ripple current slew rate by the ESL, and 3) the piecewise quadratic waveform that results from charging/discharging the output capacitor. Although the phasing of these three components impacts the total output ripple, a common approximation is to ignore the phasing and to find the upper bound of the peak-to-peak ripple by summing all three components, as shown in Equation 17. the triangular AC ripple current at the output, the total RMS current and power is given by Equation 18 and Equation 19. Equation 17: ESR = Equivalent series resistance of the entire output capacitor bank  VDDH   IOUTRIPPLE  VP =  +   −P ESR (IOUTRIPPLE ) + ESL   LOUT   8 × fSW × COUT  where: ESR = Equivalent series resistance at the output IOUTRIPPLE = Peak-to-peak inductor current ripple ESL = High-frequency equivalent series inductance at output VDDH = Input voltage LOUT = Output inductance fSW = Switching frequency COUT = Output capacitance In a typical MAX20734 application with a bank of 0805, X5R, 6.3V, 22µF output capacitors, these three components are roughly equal. The ESL effect of an output capacitor on output voltage ripple cannot be easily estimated from the resonant frequency so the high-frequency (10MHz or above) impedance of that capacitor should be used instead. PCB traces and vias in the VOUT/GND loop contribute additional parasitic inductance. The final considerations in the selection of output capacitors are ripple-current rating and power dissipation. Using a conservative design approach, the output capacitors should be designed to handle the maximum peak-topeak AC ripple current experienced in the worst-case scenario. Because the recommended output capacitors have extremely low ESR values, they are typically rated well above the current and power stresses seen here. For Equation 18: I IRMS _ COUT = OUTRIPPLE 12 where: IOUTRIPPLE = Peak-to peak ripple current value Equation 19: = PCOUT IRMS _ COUT 2 × ESR where: Input Capacitor Selection The selection and placement of input capacitors are important considerations. High-frequency input capacitors serve to control switching noise. Bulk input capacitors are designed to filter the pulsed DC current that is drawn by the regulator. For the best performance, lowest cost, and smallest size of the MAX20734 systems, MLCC capacitors with 1210 or smaller case sizes, capacitance values of 47µF or smaller, 16V or 25V voltage ratings, and X5R or better temperature characteristics are recommended as bulk. The minimum recommended value of capacitance are 2 x 47µF (bulk) and 1.0µF + 0.1µF (high frequency). Smaller values of bulk capacitance can be used in direct proportion to the maximum load current. It is recommended to choose the main MLCC input capacitance to control the peak-to-peak input-voltage ripple to 2% to 3% of its DC value in accordance with Equation 20. Equation 20: I × VOUT × (VDDH − VOUT ) C IN = MAX f SW × VDDH 2 × VINPP ( ) where: CIN = Input capacitance (MLCC) IMAX = Maximum load current VDDH = DC input voltage VOUT = DC output voltage fSW = Switching frequency VINPP = Target peak-to-peak input-voltage ripple www.maximintegrated.com Maxim Integrated │  26 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Because the bulk input capacitors must source the pulsed DC input current of the regulator, the power dissipation and ripple current rating for these capacitors are far more important than that for the output capacitors. The RMS current that the input capacitor must withstand can be approximated using Equation 21. Equation 21: IRMS _ CIN = ILOAD VOUT ( VDDH − VOUT ) VDDH where: ILOAD = Output DC load current With an equivalent series resistance of the bulk input capacitor bank (ESRCIN), the total power dissipation in the input capacitors is given by Equation 22. Equation 22: = PCIN IRMS _ CIN2 × ESRCIN Resistor Selection and its Effect on DC Output-Voltage Accuracy RFB1 and RFB2 set the output voltage, as described in Equation 4. The tolerance of these resistors affects the accuracy of the set output voltage. Due to the form of Equation 4, the effect is higher at higher output voltages. Figure 5 shows the effect of 0.1% tolerance resistors over a range of output voltages. For different tolerance resistors, multiply the output voltage error by the resistors’ tolerances divided by 0.1% (e.g., for 0.5% tolerance resistors, multiply the output error shown by 5). To obtain accuracy over temperature, for a worst-case scenario, the temperature coefficients multiplied by the temperature range should be added to the tolerance (i.e., for 25ppm/°C resistors over a 50°C excursion, add 0.125% to the 25°C tolerance). The error due to the voltage feedback resistors’ tolerance (RFB1 and RFB2) should be added to the output-voltage tolerance due to the IC’s feedback-voltage accuracy shown in the Electrical Characteristics table. Voltage Margining Voltage margining can be achieved by changing the VOUT setting through PMBus. VOUT changes occur with a default linear slew rate of 1V/ms. The slew rate can be set to 1, 2, or 4mV/μs using the VRATE bits. Refer to the AN6140: MAX20734 PMBus Application Note for details. If a voltage-divider is present in the feedback loop, the VOUT slew rate will be scaled accordingly. 0.180% 0.160% 0.140% ERROR (%) 0.120% 0.100% εVOUT = 2εR(VOUT - VREF)/VOUT 0.080% 0.060% 0.040% 0.020% 0.000% 1 1.5 2 2.5 3 3.5 4 4.5 5 VOUT/VREF RATIO Figure 5. DC Accuracy Impact Showing Effect of 0.1% Tolerance for RFB1 and RFB2 www.maximintegrated.com Maxim Integrated │  27 MAX20734 PCB Layout Guidelines PCB layout can dramatically affect the performance of the regulator. A poorly designed board can degrade efficiency, noise performance, and even control-loop stability. At higher switching frequencies, layout issues are especially critical. As a general guideline, the input capacitors and the output inductor should be placed in close proximity to the regulator IC, while the output capacitors should be lumped together as close as possible to the load. Traces to these components should be kept as short and wide as possible to minimize parasitic inductance and resistance. Traces connecting the input capacitors and VDDH (power input node) on the IC require particular attention since they carry currents with the largest RMS values and fastest slew rates. According to best practice, the input capacitors should be placed as close as possible to the input supply pins, with the smallest package highfrequency capacitor being the closest to the IC and no more than 60 mils from the IC pins. Preferably, there should be an uninterrupted ground plane located immediately underneath these high-frequency current paths, with the ground plane located no more than 8 mils below the top layer. By keeping the flow of this high-frequency AC current localized to a tight loop at the regulator, electromagnetic interference (EMI) can be minimized. Voltage-sense lines should be routed differentially directly from the load points. The ground plane can be used as a shield for these or other sensitive signals to protect them from capacitive or magnetic coupling of high-frequency noise. www.maximintegrated.com Integrated, Step-Down Switching Regulator with PMBus For remote-sense applications where the load and regulator IC are separated by a significant distance or impedance, it is important to place the majority of the output capacitors directly at the load. Ideally, for system stability, all the output capacitors should be placed as close as possible to the load. In remote-sense applications, common-mode filtering is necessary to filter high-frequency noise in the sense lines. The following layout recommendations should be used for optimal performance: ● It is essential to have a low-impedance and uninterrupted ground plane under the IC and extended out underneath the inductor and output capacitor bank. ● Multiple vias are recommended for all paths that carry high currents (i.e., GND, VDDH, VX). Vias should be placed close to the chip to create the shortest possible current loops. Via placement must not obstruct the flow of currents or mirror currents in the ground plane. ● A single via in close proximity to the chip should be used to tie the top layer AGND trace to the second layer ground plane, it must not be connected to the top power ground area. ● The feedback-divider and compensation network should be close to the IC to minimize the noise on the IC side of the divider. Gerber files with layout information and complete reference designs can be obtained by contacting a Maxim account representative. Maxim Integrated │  28 R1 1.78K 0402 C32 1000pF 0402 C4 DNS 0402 DNS = Do Not Stuff Vboot = 0.6484V PMBus Addr = 1010 000b Soft Start Time = 3ms SMALERT DATA CLK OE STAT 20K R8 0402 PGMB PGMA C23 DNS 0402 C51 10uF X5R 0402 Fsw = 400kHz OCP = 38A Valley Rgain = 1.6 m-ohms R2 162K 0402 C9 10uF X5R 0402 PGMB PGMA VX BST U1 VSENSE- VSENSE+ MAX20734 SMALERT DATA CLK OE STAT C36 10uF X5R 0402 VDDH VDDH VCC VCC AGND 20K GND www.maximintegrated.com R5 0402 C3 0.1uF X7R 0402 SENSE- SENSE+ VX BST C8 0.22uF X7R 0402 C7 1uF X7R 0603 Diff Pair C5 47uF X5R 1206 170nH L1 C6 47uF X5R 1206 C10 47uF X5R 1206 VDDH R9 3.48K 0402 R6 1.87K 0402 SENSE_VOUT C11 47uF X5R 1206 Diff Pair INPUT SUPPLY 0 0402 0 R11 R4 0402 C24 0.01uF 0402 C21 22uF 0805 C12-20 9x100uf 1206 VOUT = 1V VOUT MAX20734 Integrated, Step-Down Switching Regulator with PMBus Figure 6. Reference Schematic (VOUT = 1V, VDDH = 4.5V to 16V) Maxim Integrated │  29 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Ordering Information PART TEMP RANGE PIN-PACKAGE MAX20734EPL+ -40°C to +125°C 15 FCQFN MAX20734EPL+T -40°C to +125°C 15 FCQFN +Denotes a lead(Pb)-free/RoHS-compliant package. T = Tape and reel. www.maximintegrated.com Maxim Integrated │  30 MAX20734 Integrated, Step-Down Switching Regulator with PMBus Revision History REVISION NUMBER REVISION DATE 0 1/17 PAGES CHANGED DESCRIPTION Initial release — For information on other Maxim Integrated products, visit Maxim Integrated’s website at www.maximintegrated.com. 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. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. ©  2017 Maxim Integrated Products, Inc. │  31