ISL62875 Features The ISL62875 is a Single-Phase Synchronous-Buck PWM voltage regulator featuring Intersil’s Robust Ripple Regulator (R3) Technology™. The wide 3.3V to 25V input voltage range is ideal for systems that run on battery or AC-adapter power sources. The ISL62875 is a low-cost solution for applications requiring dynamically selected slew-rate controlled output voltages. The soft-start and dynamic setpoint slew-rates are capacitor programmed. Voltage identification logic-inputs select four resistor-programmed setpoint reference voltages that directly set the output voltage of the converter between 0.5V to 1.5V, and up to 3.3V using a feedback voltage divider. Robust integrated MOSFET drivers and Schottky bootstrap diode reduce the implementation area and component cost. • Input Voltage Range: 3.3V to 25V Intersil’s R3 Technology™ combines the best features of both fixed-frequency and hysteretic PWM control. The PWM frequency is 500kHz during static operation, becoming variable during changes in load, setpoint voltage, and input voltage when changing between battery and AC-adapter power. The modulators ability to change the PWM switching frequency during these events in conjunction with external loop compensation produces superior transient response. For maximum efficiency, the converter automatically enters diodeemulation mode (DEM) during light-load conditions such as system standby. • Output Voltage Range: 0.5V to 3.3V • Output Load up to 30A • Extremely Flexible Output Voltage Programmability - 2-Bit VID Selects Four Independent Setpoint Voltages - Simple Resistor Programming of Setpoint Voltages - Accepts External Setpoint Reference such as DAC • ±0.75% System Accuracy: -10°C to +100°C • Fixed 500kHz PWM Frequency in Continuous Conduction • Integrated High-current MOSFET Drivers and Schottky Boot-Strap Diode for Optimal Efficiency Applications*(see page 21) • Mobile PC GPU Core Power • Mobile PC I/O Controller Hub (ICH) VCC Rail • Tablet PCs/Slates and Netbooks • Hand-Held Portable Instruments Related Literature*(see page 21) • TB389 “PCB Land Pattern Design and Surface Mount Guidelines for QFN Packages” Typical Application +5V VIN 3.3V TO 25V 1 5 GPIO 6 7 8 9 LGATE PVCC EN UGATE VID1 PHASE SET0 OCSET SET1 RSET4 CSOFT RSET1 RSET2 RSET3 1 17 LO 16 QLS VO FB CBOOT 14 13 12 GPIO VOUT 0.5V TO 3.3V COUT COCSET RO VCC RPGOOD 10 11 FN6905.1 September 18, 2009 QHS 18 VID0 SREF CIN 19 RCOMP ROFS 4 VCC BOOT GND SET2 3 PGND PGOOD 2 CVCC 20 ROCSET CPVCC CCOMP RFB CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc. Copyright Intersil Americas Inc. 2009. All Rights Reserved All other trademarks mentioned are the property of their respective owners. ISL62875 PWM DC/DC Controller with VID Inputs for Portable GPU Core-Voltage Regulator ISL62875 Application Schematics RVCC SREF SET0 16 6 15 7 14 8 13 9 RSET2 RSET3 RSET4 CSOFT RSET1 PVCC 5 SET2 SET1 17 12 CINB QHS BOOT UGATE LO PHASE QLS NC OCSET CBOOT VO COB COCSET FB RO RCOMP VCC GPIO VOUT 0.5V TO 3.3V COC ROCSET VID0 4 CINC VCC CCOMP RFB ROFS GPIO 18 11 VID1 19 3 PGOOD EN 2 CVCC RPGOOD GND 10 PGND 1 CPVCC VIN 3.3V TO 25V 20 LGATE +5V FIGURE 1. ISL62875 APPLICATION SCHEMATIC WITH FOUR OUTPUT VOLTAGE SETPOINTS AND DCR CURRENT SENSE RVCC SET0 RSET2 16 6 15 7 14 8 13 9 RSET3 RSET4 CSOFT RSET1 PVCC 5 SET2 SET1 17 12 CINB QHS BOOT UGATE LO RSNS PHASE QLS NC OCSET ROCSET SREF 4 CINC VCC CBOOT VO FB RCOMP VCC GPIO VOUT 0.5V TO 3.3V COC COB COCSET RO ROFS VID0 18 11 GPIO 19 3 PGOOD EN VID1 CVCC RPGOOD GND 2 10 PGND 1 CPVCC VIN 3.3V TO 25V 20 LGATE +5V CCOMP RFB FIGURE 2. ISL62875 APPLICATION SCHEMATIC WITH FOUR OUTPUT VOLTAGE SETPOINTS AND RESISTOR CURRENT SENSE 2 September 18, 2009 FN6905.1 ISL62875 Application Schematics (Continued) RVCC VID0 EXT_REF CSOFT SREF SET0 SET1 4 17 5 16 6 15 7 14 8 13 9 12 GPIO CINB QHS BOOT UGATE LO PHASE QLS NC OCSET CBOOT VO FB VOUT 0.5V TO 3.3V COC COB COCSET RO RCOMP ROFS RPGOOD PVCC 18 SET2 VCC 19 CINC VCC ROCSET VID1 CVCC 3 11 EN GPIO 2 VIN 3.3V TO 25V PGOOD GND 10 PGND 20 CPVCC 1 LGATE +5V CCOMP RFB FIGURE 3. ISL62875 APPLICATION SCHEMATIC WITH EXTERNAL REFERENCE INPUT AND DCR CURRENT SENSE 3 September 18, 2009 FN6905.1 Block Diagram EN VCC 100kΩ POR FAULT 4 − EA + FB VW VCOMP BOOT RUN RUN PWM H L IN DRIVER UGATE PHASE SHOOT-THROUGH PROTECTION OTP PVCC PWM RUN DRIVER LGATE 100pF PGND gmVIN + VCC + − − ISL62875 VSET Cr VR SW0 + SREF SW1 SET0 gmVO SW2 − SET1 SW3 SET2 VID1 VID DECODER VID0 EXT VREF GND 500mV INT SW4 − OCP + FB − UVP + FAULT September 18, 2009 FN6905.1 FIGURE 4. SIMPLIFIED FUNCTIONAL BLOCK DIAGRAM OF ISL62875 VO OCSET IOCSET 10µA PGOOD ISL62875 Pin Configuration 2 PVCC PGND 2 1 LGATE ISL62875 (20 LD 3.2X1.8 µTQFN) TOP VIEW 19 VCC 18 BOOT GND 3 VID1 5 16 PHASE VID0 6 15 NC SREF 7 14 OCSET SET0 8 13 VO SET1 9 12 FB PGOOD 11 17 UGATE SET2 10 EN 4 ISL62875 Functional Pin Descriptions PIN NUMBER SYMBOL DESCRIPTION 1 LGATE Low-side MOSFET gate driver output. Connect to the gate terminal of the low-side MOSFET of the converter. 2 PGND Return current path for the LGATE MOSFET driver. Connect to the source of the low-side MOSFET. 3 GND 4 EN 5 VID1 Logic input for setpoint voltage selector. Use in conjunction with the VID0 pin to select among four setpoint reference voltages. 6 VID0 Logic input for setpoint voltage selector. Use in conjunction with the VID1 pin to select among four setpoint reference voltages. External reference input when enabled by connecting the SET0 pin to the VCC pin. 7 SREF Soft-start and voltage slew-rate programming capacitor input. Setpoint reference voltage programming resistor input. Connects internally to the inverting input of the VSET voltage setpoint amplifier. 8 SET0 Voltage set-point programming resistor input. 9 SET1 Voltage set-point programming resistor input. 10 SET2 Voltage set-point programming resistor input. 11 PGOOD Power-good open-drain indicator output. This pin changes to high impedance when the converter is able to supply regulated voltage. The pull-down resistance between the PGOOD pin and the GND pin identifies which protective fault has shut down the regulator. 12 FB Voltage feedback sense input. Connects internally to the inverting input of the control-loop error amplifier. The converter is in regulation when the voltage at the FB pin equals the voltage on the SREF pin. The control loop compensation network connects between the FB pin and the converter output. 13 VO Output voltage sense input for the R3 modulator. The VO pin also serves as the reference input for the overcurrent detection circuit. IC ground for bias supply and signal reference. Enable input for the IC. Pulling EN above the VENTHR rising threshold voltage initializes the soft-start sequence. 5 September 18, 2009 FN6905.1 ISL62875 ISL62875 Functional Pin Descriptions (Continued) PIN NUMBER SYMBOL 14 OCSET 15 NC 16 PHASE Return current path for the UGATE high-side MOSFET driver. VIN sense input for the R3 modulator. Inductor current polarity detector input. Connect to junction of output inductor, high-side MOSFET, and low-side MOSFET. See Figures 1 and 2 on page 2. 17 UGATE High-side MOSFET gate driver output. Connect to the gate terminal of the high-side MOSFET of the converter. 18 BOOT Positive input supply for the UGATE high-side MOSFET gate driver. The BOOT pin is internally connected to the cathode of the Schottky boot-strap diode. Connect an MLCC between the BOOT pin and the PHASE pin. 19 VCC Input for the IC bias voltage. Connect +5V to the VCC pin and decouple with at least a 1µF MLCC to the GND pin. See “Application Schematics” (Figures 1 and 2) on page 2. 20 PVCC DESCRIPTION Input for the overcurrent detection circuit. The overcurrent setpoint programming resistor ROCSET connects from this pin to the sense node. No internal connection. Pin 15 should be connected to the GND pin. Input for the LGATE and UGATE MOSFET driver circuits. The PVCC pin is internally connected to the anode of the Schottky boot-strap diode. Connect +5V to the PVCC pin and decouple with a 10µF MLCC to the PGND pin. See “Application Schematics” (Figures 1 and 2) on page 2. Ordering Information PART NUMBER (Notes 1, 2, 3) PART MARKING ISL62875HRUZ-T* GAR TEMP RANGE (°C) -10 to +100 PACKAGE (Pb-Free) 20 Ld 3.2x1.8 µTQFN (Tape and Reel) PKG. DWG. # L20.3.2x1.8 NOTES: 1. Please refer to TB347 for details on reel specifications. 2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets; molding compounds/die attach materials and NiPdAu plate - e4 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. 3. For Moisture Sensitivity Level (MSL), please see device information page for ISL62875. For more information on MSL please see techbrief TB363. 6 September 18, 2009 FN6905.1 ISL62875 Table of Contents Application Schematics ....................................................................................................................... 2 Block Diagram .................................................................................................................................... 4 Pin Configuration ................................................................................................................................ 5 ISL62875 Functional Pin Descriptions ................................................................................................ 5 Ordering Information ......................................................................................................................... 6 Absolute Maximum Ratings ................................................................................................................ 8 Thermal Information .......................................................................................................................... 8 Recommended Operating Conditions .................................................................................................. 8 Electrical Specifications ...................................................................................................................... 8 Theory of Operation .......................................................................................................................... 11 Modulator ...................................................................................................................................... Synchronous Rectification ................................................................................................................. Diode Emulation .............................................................................................................................. Power-On Reset .............................................................................................................................. VIN and PVCC Voltage Sequence ....................................................................................................... Start-Up Timing .............................................................................................................................. PGOOD Monitor ............................................................................................................................... LGATE and UGATE MOSFET Gate-Drivers ............................................................................................ Adaptive Shoot-Through Protection .................................................................................................... 11 11 11 12 12 12 12 12 12 Setpoint Reference Voltage Programming ........................................................................................ 13 Calculating Setpoint Voltage Programming Resistor Values ................................................................... 13 External Setpoint Reference .............................................................................................................. 14 Soft-Start and Voltage-Step Delay .................................................................................................... 14 Circuit Description ........................................................................................................................... 14 Component Selection For CSOFT Capacitor .......................................................................................... 15 Compensation Design ....................................................................................................................... 15 Fault Protection ................................................................................................................................ 15 Overcurrent .................................................................................................................................... Component Selection for ROCSET and CSEN ......................................................................................... Overvoltage .................................................................................................................................... Undervoltage .................................................................................................................................. Over-Temperature ........................................................................................................................... 15 16 16 16 16 General Application Design Guide ..................................................................................................... 16 Selecting the LC Output Filter ........................................................................................................... Selection of the Input Capacitor ........................................................................................................ Selecting The Bootstrap Capacitor ..................................................................................................... Driver Power Dissipation .................................................................................................................. MOSFET Selection and Considerations ................................................................................................ 17 17 17 18 18 PCB Layout Considerations ............................................................................................................... 19 Power and Signal Layers Placement on the PCB ................................................................................... Component Placement ..................................................................................................................... Signal Ground and Power Ground ...................................................................................................... Routing and Connection Details ......................................................................................................... Copper Size for the Phase Node ........................................................................................................ 19 19 19 19 20 Revision History ............................................................................................................................... 21 Products ........................................................................................................................................... 21 Package Outline Drawing ................................................................................................................. 22 7 September 18, 2009 FN6905.1 ISL62875 Absolute Maximum Ratings Thermal Information VCC, PVCC, PGOOD to GND . . . . . . . . . . . . . -0.3V to +7.0V VCC, PVCC to PGND . . . . . . . . . . . . . . . . . . -0.3V to +7.0V GND to PGND . . . . . . . . . . . . . . . . . . . . . . -0.3V to +0.3V EN, SET0, SET1, SET2, VO, VID0, VID1, FB, OCSET, SREF . . . -0.3V to GND, VCC + 0.3V BOOT Voltage (VBOOT-GND) . . . . . . . . . . . . . . . -0.3V to 33V BOOT To PHASE Voltage (VBOOT-PHASE) . . . -0.3V to 7V (DC) -0.3V to 9V (<10ns) PHASE Voltage . . . . . . . . . . . . . . . . . . . . GND - 0.3V to 28V GND -8V (<20ns Pulse Width, 10µJ) UGATE Voltage . . . . . . . . . . . . VPHASE - 0.3V (DC) to VBOOT VPHASE - 5V (<20ns Pulse Width, 10µJ) to VBOOT LGATE Voltage . . . . . . . . . . GND - 0.3V (DC) to VCC + 0.3V GND - 2.5V (<20ns Pulse Width, 5µJ) to VCC + 0.3V Thermal Resistance (Typical) θJA (°C/W) 20 Ld µTQFN Package (Notes 4, 5) . . . . . . . . 84 Junction Temperature Range . . . . . . . . . . . -55°C to +150°C Operating Temperature Range . . . . . . . . . . -10°C to +100°C Storage Temperature . . . . . . . . . . . . . . . . . -65°C to +150°C Pb-free Reflow Profile . . . . . . . . . . . . . . . . . .see link below http://www.intersil.com/pbfree/Pb-FreeReflow.asp Recommended Operating Conditions Ambient Temperature Range . . . . . . . . . . -10°C to +100°C Converter Input Voltage to GND . . . . . . . . . . . . 3.3V to 25V VCC, PVCC to GND . . . . . . . . . . . . . . . . . . . . . . . . 5V ±5% CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product reliability and result in failures not covered by warranty. NOTES: 4. θJA is measured in free air with the component mounted on a high effective thermal conductivity test board with “direct attach” features. See Tech Brief TB379. 5. For θJC, the “case temp” location is the center of the exposed metal pad on the package underside. Electrical Specifications PARAMETER These specifications apply for TA = -10°C to +100°C, unless otherwise stated. All typical specifications TA = +25°C, VCC = 5V. Boldface limits apply over the operating temperature range, -10°C to +100°C. MIN MAX (Note 7) TYP (Note 7) UNIT SYMBOL TEST CONDITIONS VCC Input Bias Current IVCC EN = 5V, VCC = 5V, FB = 0.55V, SREF < FB - 1.1 1.5 mA VCC Shutdown Current IVCCoff EN = GND, VCC = 5V - 0.1 1.0 µA PVCC Shutdown Current IPVCCoff EN = GND, PVCC = 5V - 0.1 1.0 µA VCC and PVCC VCC POR THRESHOLD Rising VCC POR Threshold Voltage VVCC_THR 4.40 4.49 4.60 V Falling VCC POR Threshold Voltage V 4.10 4.22 4.35 V - 0.50 - V -0.75 - +0.75 % 450 500 550 kHz 0 - 3.6 V EN = 5V - 600 - kΩ VCC_THF REGULATION Reference Voltage VREF(int) System Accuracy VID0 = VID1 = GND, PWM Mode = CCM PWM Switching Frequency FSW PWM Mode = CCM VO VO Input Voltage Range VVO VO Input Impedance RVO VO Reference Offset Current IVOSS VENTHR < EN, SREF = Soft-Start Mode - 10 - µA VO Input Leakage Current IVOoff EN = GND, VO = 3.6V - 0.1 - µA EN = 5V, FB = 0.50V -20 - +50 nA Nominal SREF Setting with 1% Resistors 0.5 - 1.5 V SREF = Soft-Start Mode 10 20 30 µA ERROR AMPLIFIER FB Input Bias Current IFB SREF SREF Operating Voltage Range Soft-Start Current VSREF ISS 8 September 18, 2009 FN6905.1 ISL62875 Electrical Specifications PARAMETER These specifications apply for TA = -10°C to +100°C, unless otherwise stated. All typical specifications TA = +25°C, VCC = 5V. Boldface limits apply over the operating temperature range, -10°C to +100°C. (Continued) SYMBOL Voltage Step Current IVS TEST CONDITIONS SREF = Setpoint-Stepping Mode MIN MAX (Note 7) TYP (Note 7) UNIT ±60 ±100 ±140 µA 0 - 1.5 V -0.5 - +0.5 % EXTERNAL REFERENCE EXTREF Operating Voltage Range EXTREF Accuracy VEXT SET0 = VCC VEXT_OFS SET0 = VCC, VID0 = 0V to 1.5V POWER GOOD PGOOD Pull-down Impedance PGOOD Leakage Current RPG_SS PGOOD = 5mA Sink 75 95 150 Ω RPG_UV PGOOD = 5mA Sink 75 95 150 Ω RPG_OV PGOOD = 5mA Sink 50 65 90 Ω RPG_OC PGOOD = 5mA Sink 25 35 50 Ω - 0.1 1.0 µA - 5.0 - mA IPG PGOOD Maximum Sink Current (Note 6) PGOOD = 5V IPG_max GATE DRIVER UGATE Pull-Up Resistance (Note 6) RUGPU 200mA Source Current - 1.0 1.5 Ω UGATE Source Current (Note 6) IUGSRC UGATE - PHASE = 2.5V - 2.0 - A UGATE Sink Resistance (Note 6) RUGPD 250mA Sink Current - 1.0 1.5 Ω UGATE Sink Current (Note 6) IUGSNK UGATE - PHASE = 2.5V - 2.0 - A LGATE Pull-Up Resistance (Note 6) RLGPU 250mA Source Current - 1.0 1.5 Ω LGATE Source Current (Note 6) ILGSRC LGATE - GND = 2.5V - 2.0 - A LGATE Sink Resistance (Note 6) RLGPD 250mA Sink Current - 0.5 0.9 Ω LGATE Sink Current (Note 6) ILGSNK LGATE - PGND = 2.5V - 4.0 - A UGATE to LGATE Deadtime tUGFLGR UGATE falling to LGATE rising, no load - 21 - ns LGATE to UGATE Deadtime tLGFUGR LGATE falling to UGATE rising, no load - 21 - ns RPHASE - 33 - kΩ PHASE PHASE Input Impedance BOOTSTRAP DIODE Forward Voltage VF PVCC = 5V, IF = 2mA - 0.58 - V Reverse Leakage IR VR = 25V - 0.2 - µA CONTROL INPUTS EN High Threshold Voltage VENTHR 2.0 - - V EN Low Threshold Voltage VENTHF - - 1.0 V 1.5 2.0 2.5 µA - 0.1 1.0 µA EN Input Bias Current IEN EN Leakage Current IENoff EN = 5V EN = GND VID<0,1> High Threshold Voltage VVIDTHR 0.6 - - V VID<0,1> Low Threshold Voltage VVIDTHF - - 0.5 V - 0.5 - µA - 0 - µA VID<0,1> Input Bias Current VID<0,1> Leakage Current IVID IVIDoff 9 EN = 5V, VVID = 1V September 18, 2009 FN6905.1 ISL62875 Electrical Specifications PARAMETER These specifications apply for TA = -10°C to +100°C, unless otherwise stated. All typical specifications TA = +25°C, VCC = 5V. Boldface limits apply over the operating temperature range, -10°C to +100°C. (Continued) SYMBOL TEST CONDITIONS MIN MAX (Note 7) TYP (Note 7) UNIT PROTECTION OCP Threshold Voltage VOCPTH OCP Reference Current IOCP OCSET Input Resistance VOCSET - VO -1.75 - 1.75 mV EN = 5.0V 9.0 10 11 µA ROCSET EN = 5.0V - 600 - kΩ OCSET Leakage Current IOCSET EN = GND - 0 - µA UVP Threshold Voltage VUVTH VFB = %VSREF 81 84 87 % OTP Rising Threshold Temperature (Note 6) TOTRTH - 150 - °C OTP Hysteresis (Note 6) TOTHYS - 25 - °C NOTES: 6. Limits established by characterization and are not production tested. 7. Parameters with MIN and/or MAX limits are 100% tested at +25°C, unless otherwise specified. Temperature limits established by characterization and are not production tested. 10 September 18, 2009 FN6905.1 ISL62875 Theory of Operation The modulator features Intersil’s R3 Robust-RippleRegulator technology, a hybrid of fixed frequency PWM control and variable frequency hysteretic control. The PWM frequency is maintained at 500kHz under static continuous-conduction-mode operation within the entire specified envelope of input voltage, output voltage, and output load. If the application should experience a rising load transient and/or a falling line transient such that the output voltage starts to fall, the modulator will extend the on-time and/or reduce the off-time of the PWM pulse in progress. Conversely, if the application should experience a falling load transient and/or a rising line transient such that the output voltage starts to rise, the modulator will truncate the on-time and/or extend the off-time of the PWM pulse in progress. The period and duty cycle of the ensuing PWM pulses are optimized by the R3 modulator for the remainder of the transient and work in concert with the error amplifier VERR to maintain output voltage regulation. Once the transient has dissipated and the control loop has recovered, the PWM frequency returns to the nominal static 500kHz. Modulator The R3 modulator synthesizes an AC signal VR, which is an analog representation of the output inductor ripple current. The duty-cycle of VR is the result of charge and discharge current through a ripple capacitor CR. The current through CR is provided by a transconductance amplifier gm that measures the input voltage (VIN) at the PHASE pin and output voltage (VOUT) at the VO pin. The positive slope of VR can be written as Equation 1: V RPOS = ( g m ) ⋅ ( V IN – V OUT ) ⁄ C R (EQ. 1) The negative slope of VR can be written as Equation 2: (EQ. 2) V RNEG = g m ⋅ V OUT ⁄ C R Where, gm is the gain of the transconductance amplifier. A window voltage VW is referenced with respect to the error amplifier output voltage VCOMP, creating an envelope into which the ripple voltage VR is compared. The amplitude of VW is controlled internally by the IC. The VR, VCOMP, and VW signals feed into a window comparator in which VCOMP is the lower threshold voltage and VW is the higher threshold voltage. Figure 5 shows PWM pulses being generated as VR traverses the VW and VCOMP thresholds. The PWM switching frequency is proportional to the slew rates of the positive and negative slopes of VR; it is inversely proportional to the voltage between VW and VCOMP. Synchronous Rectification A standard DC/DC buck regulator uses a free-wheeling diode to maintain uninterrupted current conduction through the output inductor when the high-side MOSFET switches off for the balance of the PWM switching cycle. Low conversion efficiency as a result of the conduction loss of the diode makes this an unattractive option for all but the lowest current applications. Efficiency is dramatically improved when the free-wheeling diode is 11 replaced with a MOSFET that is turned on whenever the high-side MOSFET is turned off. This modification to the standard DC/DC buck regulator is referred to as synchronous rectification, the topology implemented by the ISL62875 controller. RIPPLE CAPACITOR VOLTAGE CR WINDOW VOLTAGE VW ERROR AMPLIFIER VOLTAGE VCOMP PWM FIGURE 5. MODULATOR WAVEFORMS DURING LOAD TRANSIENT Diode Emulation The polarity of the output inductor current is defined as positive when conducting away from the phase node, and defined as negative when conducting towards the phase node. The DC component of the inductor current is positive, but the AC component known as the ripple current, can be either positive or negative. Should the sum of the AC and DC components of the inductor current remain positive for the entire switching period, the converter is in continuous-conduction-mode (CCM.) However, if the inductor current becomes negative or zero, the converter is in discontinuous-conduction-mode (DCM.) Unlike the standard DC/DC buck regulator, the synchronous rectifier can sink current from the output filter inductor during DCM, reducing the light-load efficiency with unnecessary conduction loss as the lowside MOSFET sinks the inductor current. The ISL62875 controller avoids the DCM conduction loss by making the low-side MOSFET emulate the current-blocking behavior of a diode. This smart-diode operation called diodeemulation-mode (DEM) is triggered when the negative inductor current produces a positive voltage drop across the rDS(ON) of the low-side MOSFET for eight consecutive PWM cycles while the LGATE pin is high. The converter will exit DEM on the next PWM pulse after detecting a negative voltage across the rDS(ON) of the low-side MOSFET. It is characteristic of the R3 architecture for the PWM switching frequency to decrease while in DCM, increasing efficiency by reducing unnecessary gate-driver switching losses. The extent of the frequency reduction is proportional to the reduction of load current. Upon entering DEM, the PWM frequency is forced to fall approximately 30% by forcing a similar increase of the September 18, 2009 FN6905.1 ISL62875 window voltage V W. This measure is taken to prevent oscillating between modes at the boundary between CCM and DCM. The 30% increase of VW is removed upon exit of DEM, forcing the PWM switching frequency to jump back to the nominal CCM value. LGATE and UGATE MOSFET Gate-Drivers Power-On Reset The LGATE driver is optimized for low duty-cycle applications where the low-side MOSFET experiences long conduction times. In this environment, the low-side MOSFETs require exceptionally low rDS(ON) and tend to have large parasitic charges that conduct transient currents within the devices in response to high dv/dt switching present at the phase node. The drain-gate charge in particular can conduct sufficient current through the driver pull-down resistance that the VGS(th) of the device can be exceeded and turned on. For this reason the LGATE driver has been designed with low pull-down resistance and high sink current capability to ensure clamping the MOSFETs gate voltage below VGS(th). The IC is disabled until the voltage at the VCC pin has increased above the rising power-on reset (POR) threshold voltage VVCC_THR. The controller will become disabled when the voltage at the VCC pin decreases below the falling POR threshold voltage VVCC_THF. The POR detector has a noise filter of approximately 1µs. VIN and PVCC Voltage Sequence Prior to pulling EN above the VENTHR rising threshold voltage, the following criteria must be met: - VPVCC is at least equivalent to the VCC rising power-on reset voltage VVCC_THR - VVIN must be 3.3V or the minimum required by the application Start-Up Timing Once VCC has ramped above VVCC_THR, the controller can be enabled by pulling the EN pin voltage above the input-high threshold VENTHR. Approximately 20µs later, the voltage at the SREF pin begins slewing to the designated VID set-point. The converter output voltage at the FB feedback pin follows the voltage at the SREF pin. During soft-start, The regulator always operates in CCM until the soft-start sequence is complete. PGOOD Monitor The PGOOD pin indicates when the converter is capable of supplying regulated voltage. The PGOOD pin is an undefined impedance if the VCC pin has not reached the rising POR threshold VVCC_THR, or if the VCC pin is below the falling POR threshold VVCC_THF. The PGOOD pull-down resistance corresponds to a specific protective fault, thereby reducing troubleshooting time and effort. Table 1 maps the pull-down resistance of the PGOOD pin to the corresponding fault status of the controller. TABLE 1. PGOOD PULL-DOWN RESISTANCE CONDITION PGOOD RESISTANCE VCC Below POR Undefined Soft-Start or Undervoltage 95Ω Overcurrent 35Ω The LGATE pin and UGATE pins are MOSFET driver outputs. The LGATE pin drives the low-side MOSFET of the converter while the UGATE pin drives the high-side MOSFET of the converter. Adaptive Shoot-Through Protection Adaptive shoot-through protection prevents a gate-driver output from turning on until the opposite gate-driver output has fallen below approximately 1V. The dead-time shown in Figure 6 is extended by the additional period that the falling gate voltage remains above the 1V threshold. The high-side gate-driver output voltage is measured across the UGATE and PHASE pins while the low-side gate-driver output voltage is measured across the LGATE and PGND pins. The power for the LGATE gate-driver is sourced directly from the PVCC pin. The power for the UGATE gate-driver is supplied by a bootstrap capacitor connected across the BOOT and PHASE pins. The capacitor is charged each time the phase node voltage falls a diode drop below PVCC such as when the low-side MOSFET is turned on. UGATE 1V 1V 1V 1V LGATE FIGURE 6. GATE DRIVER ADAPTIVE SHOOT-THROUGH 12 September 18, 2009 FN6905.1 ISL62875 Setpoint Reference Voltage Programming the attenuation factor K in all the calculations for selecting the RSET programming resistors. Voltage identification (VID) pins select user-programmed setpoint reference voltages that appear at the SREF pin. The converter is in regulation when the FB pin voltage (VFB) equals the SREF pin voltage (VSREF.) The IC measures VFB and VSREF relative to the GND pin, not the PGND pin. The setpoint reference voltages use the naming convention VSET(x) where (x) is the first, second, third, or fourth setpoint reference voltage where: - VSET1 < VSET2 < VSET3 < VSET4 - VOUT1 < VOUT2 < VOUT3 < VOUT4 The VSET1 setpoint is fixed at 500mV because it corresponds to the closure of internal switch SW0 that configures the VSET amplifier as a unity-gain voltage follower for the 500mV voltage reference VREF. A feedback voltage-divider network may be required to achieve the desired reference voltages. Using the feedback voltage-divider allows the maximum output voltage of the converter to be higher than the 1.5V maximum setpoint reference voltage that can be programmed on the SREF pin. Likewise, the feedback voltage-divider allows the minimum output voltage of the converter to be higher than the fixed 500mV setpoint reference voltage of VSET1. Scale the voltage-divider network such that the voltage VFB equals the voltage VSREF when the converter output voltage is at the desired level. The voltage-divider relation is given in Equation 3: R OFS V FB = V OUT ⋅ ---------------------------------R +R FB (EQ. 3) OFS The value of offset resistor ROFS can be calculated only after the value of loop-compensation resistor RFB has been determined. The calculation of ROFS is written as Equation 5: V SET ( x ) ⋅ R FB R OFS = -------------------------------------------V OUT – V SET ( x ) (EQ. 5) The setpoint reference voltages are programmed with resistors that use the naming convention RSET(x) where (x) is the first, second, third, or fourth programming resistor connected in series starting at the SREF pin and ending at the GND pin. When one of the internal switches closes, it connects the inverting input of the VSET amplifier to a specific node among the string of RSET programming resistors. All the resistors between that node and the SREF pin serve as the feedback impedance RF of the VSET amplifier. Likewise, all the resistors between that node and the GND pin serve as the input impedance RIN of the VSET amplifier. Equation 6 gives the general form of the gain equation for the VSET amplifier: RF ⎞ ⎛ V SET ( X ) = V REF ⋅ ⎜ 1 + ----------⎟ R IN⎠ ⎝ (EQ. 6) Where: - VREF is the 500mV internal reference of the IC - VSET(x) is the resulting setpoint reference voltage that appears at the SREF pin Calculating Setpoint Voltage Programming Resistor Values Where: TABLE 2. ISL62875 VID TRUTH TABLE - VFB = VSREF - RFB is the loop-compensation feedback resistor that connects from the FB pin to the converter output - ROFS is the voltage-scaling programming resistor that connects from the FB pin to the GND pin The attenuation of the feedback voltage divider is written as: R OFS V SREF ( lim ) K = ------------------------------- = ---------------------------------V OUT ( lim ) R FB + R OFS (EQ. 4) Where: - K is the attenuation factor - VSREF(lim) is the VSREF voltage setpoint of either 500mV or 1.50V - VOUT(lim) is the output voltage of the converter when VSREF = VSREF(lim) Since the voltage-divider network is in the feedback path, all output voltage setpoints will be attenuated by K, so it follows that all of the setpoint reference voltages will be attenuated by K. It will be necessary then to include 13 VID STATE RESULT VID1 VID0 CLOSE VSREF VOUT 1 1 SW0 VSET1 VOUT1 1 0 SW1 VSET2 VOUT2 0 1 SW2 VSET3 VOUT3 0 0 SW3 VSET4 VOUT4 First, determine the attenuation factor K. Next, assign an initial value to RSET4 of approximately 100kΩ then calculate RSET1, RSET2, and RSET3 using Equations 7, 8, and 9 respectively. The equation for the value of RSET1 is written as Equation 7: R SET4 ⋅ KV SET4 ⋅ ( KV SET2 – V REF ) R SET1 = ---------------------------------------------------------------------------------------------------V REF ⋅ KV SET2 (EQ. 7) The equation for the value of RSET2 is written as Equation 8: R SET4 ⋅ KV SET4 ⋅ ( KV SET3 – KV SET2 ) R SET2 = ----------------------------------------------------------------------------------------------------------KV SET2 ⋅ KV SET3 (EQ. 8) September 18, 2009 FN6905.1 ISL62875 The equation for the value of RSET3 is written as Equation 9: R SET4 ⋅ ( KV SET4 – KV SET3 ) R SET3 = -------------------------------------------------------------------------------KV SET3 (EQ. 9) The sum of all the programming resistors should be approximately 300kΩ as shown in Equation 10 otherwise adjust the value of RSET4 and repeat the calculations. R SET1 + R SET2 + R SET3 + R SET4 ≅ 300kΩ (EQ. 10) Equations 11, 12, 13 and 14 give the specific VSET gain equations for the ISL62875 setpoint reference voltages. The ISL62875 VSET1 setpoint is written as Equation 11: (EQ. 11) V SET1 = V REF The ISL62875 VSET2 setpoint is written as Equation 12: R SET1 ⎛ ⎞ V SET2 = V REF ⋅ ⎜ 1 + ---------------------------------------------------------------------⎟ R SET2 + R SET3 + R SET4⎠ ⎝ (EQ. 12) The ISL62875 VSET3 setpoint is written as Equation 13: R SET1 + R SET2⎞ ⎛ V SET3 = V REF ⋅ ⎜ 1 + --------------------------------------------⎟ R SET3 + R SET4⎠ ⎝ (EQ. 13) The ISL62875 VSET4 setpoint is written as Equation 14: R SET1 + R SET2 + R ⎛ SET3⎞ V SET4 = V REF ⋅ ⎜ 1 + ---------------------------------------------------------------------⎟ R ⎝ ⎠ SET4 (EQ. 14) External Setpoint Reference RFB FB VCOMP EA ROFS VOUT + + VSET SW0 SW1 SET0 SW2 SET1 SW3 SET2 - VID0 pin opens its 500nA pull-down current sink - Reference source selector switch SW4 moves from INT position (internal 500mV) to EXT position (VID0 pin) - VID1 pin is disabled The converter will now be in regulation when the voltage on the FB pin equals the voltage on the VID0 pin. As with resistor-programmed setpoints, the reference voltage range on the VID0 pin is 500mV to 1.5V. Use Equations 3, 4, and 5 beginning on page 13 should it become necessary to implement an output voltage-divider network to make the external setpoint reference voltage compatible with the 500mV to 1.5V constraint. Soft-Start and Voltage-Step Delay Circuit Description When the voltage on the VCC pin has ramped above the rising power-on reset voltage VVCC_THR, and the voltage on the EN pin has increased above the rising enable threshold voltage VENTHR, the SREF pin releases its discharge clamp and enables the reference amplifier VSET. The soft-start current ISS is limited to 20µA and is sourced out of the SREF pin into the parallel RC network of capacitor CSOFT and resistance RT. The resistance RT is the sum of all the series connected RSET programming resistors and is written as Equation 15: R T = R SET1 + R SET2 + …R SET ( n ) (EQ. 15) The voltage on the SREF pin rises as ISS charges CSOFT to the voltage reference setpoint selected by the state of the VID inputs at the time the EN pin is asserted. The regulator controls the PWM such that the voltage on the FB pin tracks the rising voltage on the SREF pin. Once CSOFT charges to the selected setpoint voltage, the ISS current source comes out of the 20µA current limit and decays to the static value set by VSREF ÷ RT. The elapsed time from when the EN pin is asserted to when VSREF has reached the voltage reference setpoint is the softstart delay tSS which is given by Equation 16: V START-UP t SS = – ( R T ⋅ C SOFT ) ⋅ LN(1 – ------------------------------) I SS ⋅ R T (EQ. 16) Where: RSET4 RSET3 RSET2 RSET1 SREF CSOFT VREF 500mV voltage to the VID0 pin. When SET0 and VCC are tied together, the following internal reconfigurations take place: FIGURE 7. VOLTAGE PROGRAMMING CIRCUIT The IC can use an external setpoint reference voltage as an alternative to VID-selected, resistor-programmed setpoints. This is accomplished by removing all setpoint programming resistors, connecting the SET0 pin to the VCC pin, and feeding the external setpoint reference 14 - ISS is the soft-start current source at the 20µA limit - VSTART-UP is the setpoint reference voltage selected by the state of the VID inputs at the time EN is asserted - RT is the sum of the RSET programming resistors The end of soft-start is detected by ISS tapering off when capacitor CSOFT charges to the designated VSET voltage September 18, 2009 FN6905.1 ISL62875 reference setpoint. The SSOK flag is set, the PGOOD pin goes high, and the ISS current source changes over to the voltage-step current source IVS which has a current limit of ±100µA. Whenever the VID inputs or the external setpoint reference, programs a different setpoint reference voltage, the IVS current source charges or discharges capacitor CSOFT to that new level at ±100µA. Once CSOFT charges to the selected setpoint voltage, the IVS current source comes out of the 100µA current limit and decays to the static value set by VSREF ÷ RT. The elapsed time to charge CSOFT to the new voltage is called the voltage-step delay tVS and is given by Equation 17: ( V NEW – V OLD ) t VS = – ( R T ⋅ C SOFT ) ⋅ LN(1 – -------------------------------------------) I VS ⋅ R T Compensation Design Figure 8 shows the recommended Type-II compensation circuit. The FB pin is the inverting input of the error amplifier. The COMP signal, the output of the error amplifier, is inside the chip and unavailable to users. CINT is a 100pF capacitor integrated inside the IC, connecting across the FB pin and the COMP signal. RFB, RCOMP, CCOMP and CINT form the Type-II compensator. The frequency domain transfer function is given by Equation 20: 1 + s ⋅ ( R FB + R COMP ) ⋅ C COMP G COMP ( s ) = --------------------------------------------------------------------------------------------------------------s ⋅ R FB ⋅ C INT ⋅ ( 1 + s ⋅ R COMP ⋅ C ) (EQ. 17) CINT = 100pF Where: - IVS is the ±100µA setpoint voltage-step current - VNEW is the new setpoint voltage selected by the VID inputs - VOLD is the setpoint voltage that VNEW is changing from - RT is the sum of the RSET programming resistors Choosing the CSOFT capacitor to meet the requirements of a particular soft-start delay tSS is calculated with Equation 18, which is written as: (EQ. 18) Where: - tSS is the soft-start delay - ISS is the soft-start current source at the 20µA limit - VSTART-UP is the setpoint reference voltage selected by the state of the VID inputs at the time EN is asserted - RT is the sum of the RSET programming resistors Choosing the CSOFT capacitor to meet the requirements of a particular voltage-step delay tVS is calculated with Equation 19, which is written as: – t VS C SOFT = -----------------------------------------------------------------------------V NEW – V OLD ⎞ ⎛ ⎜ R T ⋅ LN(1 – ---------------------------------------)⎟ ± I VS ⋅ R T ⎝ ⎠ (EQ. 19) CCOMP RCOMP RFB - VOUT FB EA COMP ROFS + SREF Component Selection For CSOFT Capacitor – t SS C SOFT = --------------------------------------------------------------------V START-UP ⎞ ⎛ ⎜ R T ⋅ LN(1 – ------------------------------)⎟ I SS ⋅ R T ⎠ ⎝ FIGURE 8. COMPENSATION REFERENCE CIRCUIT The LC output filter has a double pole at its resonant frequency that causes rapid phase change. The R3 modulator used in the IC makes the LC output filter resemble a first order system in which the closed loop stability can be achieved with the recommended Type-II compensation network. Intersil provides a PC-based tool that can be used to calculate compensation network component values and help simulate the loop frequency response. Fault Protection Overcurrent The overcurrent protection (OCP) setpoint is programmed with resistor ROCSET which is connected across the OCSET and PHASE pins. Resistor RO is connected between the VO pin and the actual output voltage of the converter. During normal operation, the VO pin is a high impedance path, therefore there is no voltage drop across RO. The value of resistor RO should always match the value of resistor ROCSET. L Where: DCR - tVS is the voltage-step delay - VNEW is the new setpoint voltage - VOLD is the setpoint voltage that VNEW is changing from - IVS is the ±100µA setpoint voltage-step current; positive when VNEW > VOLD, negative when VNEW < VOLD - RT is the sum of the RSET programming resistors 15 (EQ. 20) COMP PHASE + ROCSET 10µA OCSET + VROCSET IL VDCR CSEN _ VO CO _ RO VO FIGURE 9. OVERCURRENT PROGRAMMING CIRCUIT September 18, 2009 FN6905.1 ISL62875 Figure 9 shows the overcurrent set circuit. The inductor consists of inductance L and the DC resistance DCR. The inductor DC current IL creates a voltage drop across DCR, which is given by Equation 21: V DCR = I L ⋅ DCR (EQ. 21) The IOCSET current source sinks 10µA into the OCSET pin, creating a DC voltage drop across the resistor ROCSET, which is given by Equation 22: V ROCSET = 10μA ⋅ R OCSET (EQ. 22) The DC voltage difference between the OCSET pin and the VO pin, which is given by Equation 23: V OCSET – V VO = V DCR – V ROCSET = I L ⋅ DCR – I OCSET ⋅ R OCSET (EQ. 23) The IC monitors the voltage of the OCSET pin and the VO pin. When the voltage of the OCSET pin is higher than the voltage of the VO pin for more than 10µs, an OCP fault latches the converter off. Component Selection for ROCSET and CSEN The value of ROCSET is calculated with Equation 24, which is written as: I OC ⋅ DCR R OCSET = ---------------------------I OCSET (EQ. 24) Where: - ROCSET (Ω) is the resistor used to program the overcurrent setpoint - IOC is the output DC load current that will activate the OCP fault detection circuit - DCR is the inductor DC resistance For example, if IOC is 20A and DCR is 4.5mΩ, the choice of ROCSET is = 20A x 4.5mΩ/10µA = 9kΩ. Resistor ROCSET and capacitor CSEN form an R-C network to sense the inductor current. To sense the inductor current correctly not only in DC operation, but also during dynamic operation, the R-C network time constant ROCSET CSEN needs to match the inductor time constant L/DCR. The value of CSEN is then written as Equation 25: L C SEN = -----------------------------------------R OCSET ⋅ DCR (EQ. 25) For example, if L is 1.5µH, DCR is 4.5mΩ, and ROCSET is 9kΩ, the choice of CSEN = 1.5µH/(9kΩ x 4.5mΩ) = 0.037µF. When an OCP fault is declared, the PGOOD pin will pull-down to 35Ω and latch off the converter. The fault will remain latched until the EN pin has been pulled below the falling EN threshold voltage VENTHF or if VCC has decayed below the falling POR threshold voltage V VCC_THF. 16 Overvoltage The ISL62875 does not feature overvoltage fault protection. Undervoltage The UVP fault detection circuit triggers after the FB pin voltage is below the undervoltage threshold VUVTH for more than 2µs. For example, if the converter is programmed to regulate 1.0V at the FB pin, that voltage would have to fall below the typical VUVTH threshold of 84% for more than 2µs in order to trip the UVP fault latch. In numerical terms, that would be 84% x 1.0V = 0.84V. When a UVP fault is declared, the PGOOD pin will pull-down to 95Ω and latch-off the converter. The fault will remain latched until the EN pin has been pulled below the falling EN threshold voltage VENTHF or if VCC has decayed below the falling POR threshold voltage VVCC_THF. Over-Temperature When the temperature of the IC increases above the rising threshold temperature TOTRTH, it will enter the OTP state that suspends the PWM, forcing the LGATE and UGATE gate-driver outputs low. The status of the PGOOD pin does not change nor does the converter latch-off. The PWM remains suspended until the IC temperature falls below the hysteresis temperature TOTHYS at which time normal PWM operation resumes. The OTP state can be reset if the EN pin is pulled below the falling EN threshold voltage VENTHF or if VCC has decayed below the falling POR threshold voltage VVCC_THF. All other protection circuits remain functional while the IC is in the OTP state. It is likely that the IC will detect an UVP fault because in the absence of PWM, the output voltage decays below the undervoltage threshold VUVTH. General Application Design Guide This design guide is intended to provide a high-level explanation of the steps necessary to design a singlephase power converter. It is assumed that the reader is familiar with many of the basic skills and techniques referenced in the following. In addition to this guide, Intersil provides complete reference designs that include schematics, bills of materials, and example board layouts. Selecting the LC Output Filter The duty cycle of an ideal buck converter is a function of the input and the output voltage. This relationship is expressed in Equation 26: VO D = --------V IN (EQ. 26) The output inductor peak-to-peak ripple current is expressed in Equation 27: VO ⋅ ( 1 – D ) I P-P = ------------------------------F SW ⋅ L (EQ. 27) September 18, 2009 FN6905.1 ISL62875 2 (EQ. 28) P COPPER = I LOAD ⋅ DCR Where, ILOAD is the converter output DC current. The copper loss can be significant so attention has to be given to the DCR selection. Another factor to consider when choosing the inductor is its saturation characteristics at elevated temperature. A saturated inductor could cause destruction of circuit components, as well as nuisance OCP faults. A DC/DC buck regulator must have output capacitance CO into which ripple current IP-P can flow. Current IP-P develops a corresponding ripple voltage VP-P across CO, which is the sum of the voltage drop across the capacitor ESR and of the voltage change stemming from charge moved in and out of the capacitor. These two voltages are expressed in Equations 29 and 30: (EQ. 29) ΔV ESR = I P-P ⋅ E SR I P-P ΔΔV C = --------------------------------8 ⋅ CO ⋅ F (EQ. 30) SW If the output of the converter has to support a load with high pulsating current, several capacitors will need to be paralleled to reduce the total ESR until the required VP-P is achieved. The inductance of the capacitor can cause a brief voltage dip if the load transient has an extremely high slew rate. Low inductance capacitors should be considered. A capacitor dissipates heat as a function of RMS current and frequency. Be sure that IP-P is shared by a sufficient quantity of paralleled capacitors so that they operate below the maximum rated RMS current at FSW. Take into account that the rated value of a capacitor can fade as much as 50% as the DC voltage across it increases. Selection of the Input Capacitor The important parameters for the bulk input capacitance are the voltage rating and the RMS current rating. For reliable operation, select bulk capacitors with voltage and current ratings above the maximum input voltage and capable of supplying the RMS current required by the switching circuit. Their voltage rating should be at least 1.25x greater than the maximum input voltage, while a voltage rating of 1.5x is a preferred rating. Figure 10 is a graph of the input RMS ripple current, normalized relative to output load current, as a function of duty cycle that is adjusted for converter efficiency. The ripple current calculation is written as Equation 31: 2 2 D 2 ( I MAX ⋅ ( D – D ) ) + ⎛ x ⋅ I MAX ⋅ ------ ⎞ ⎝ 12 ⎠ I IN_RMS = ----------------------------------------------------------------------------------------------------I MAX Where: 17 (EQ. 31) - IMAX is the maximum continuous ILOAD of the converter - x is a multiplier (0 to 1) corresponding to the inductor peak-to-peak ripple amplitude expressed as a percentage of IMAX (0% to 100%) - D is the duty cycle that is adjusted to take into account the efficiency of the converter Duty cycle is written as Equation 32: VO D = -------------------------V IN ⋅ EFF (EQ. 32) In addition to the bulk capacitance, some low ESL ceramic capacitance is recommended to decouple between the drain of the high-side MOSFET and the source of the low-side MOSFET. NORMALIZED INPUT RMS RIPPLE CURRENT A typical step-down DC/DC converter will have an IP-P of 20% to 40% of the maximum DC output load current. The value of IP-P is selected based upon several criteria, such as MOSFET switching loss, inductor core loss, and the resistive loss of the inductor winding. The DC copper loss of the inductor can be estimated using Equation 28: 0.60 x=1 0.55 0.50 0.45 x = 0.75 0.40 0.35 x = 0.50 x = 0.25 0.30 0.25 0.20 x=0 0.15 0.10 0.05 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 DUTY CYCLE FIGURE 10. NORMALIZED RMS INPUT CURRENT FOR x = 0.8 Selecting The Bootstrap Capacitor Adding an external capacitor across the BOOT and PHASE pins completes the bootstrap circuit. We selected the bootstrap capacitor breakdown voltage to be at least 10V. Although the theoretical maximum voltage of the capacitor is PVCC-VDIODE (voltage drop across the boot diode), large excursions below ground by the phase node requires we select a capacitor with at least a breakdown rating of 10V. The bootstrap capacitor can be chosen from Equation 33: Q GATE C BOOT ≥ -----------------------ΔV BOOT (EQ. 33) Where: - QGATE is the amount of gate charge required to fully charge the gate of the upper MOSFET - ΔVBOOT is the maximum decay across the BOOT capacitor As an example, suppose an upper MOSFET has a gate charge, QGATE , of 25nC at 5V and also assume the droop in the drive voltage over a PWM cycle is 200mV. One will find that a bootstrap capacitance of at least 0.125µF is required. The next larger standard value capacitance is September 18, 2009 FN6905.1 ISL62875 source and the voltage spike that occurs when the MOSFET switches off. 2.0 1000 1.8 900 1.6 800 1.4 700 POWER (mW) CBOOT_CAP (µF) 0.15µF. A good quality ceramic capacitor such as X7R or X5R is recommended. 1.2 1.0 0.8 QGATE = 100nC 0.6 0.2 QU = 50nC QL = 50nC 600 QU = 20nC QL = 50nC 500 400 300 nC 50 0.4 QU = 100nC QU = 50nC QL = 200nCQL = 100nC 200 100 20nC 0.0 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 ΔVBOOT_CAP (V) 1.0 FIGURE 11. BOOT CAPACITANCE vs BOOT RIPPLE VOLTAGE Driver Power Dissipation Switching power dissipation in the driver is mainly a function of the switching frequency and total gate charge of the selected MOSFETs. Calculating the power dissipation in the driver for a desired application is critical to ensuring safe operation. Exceeding the maximum allowable power dissipation level will push the IC beyond the maximum recommended operating junction temperature of +125°C. When designing the application, it is recommended that the following calculation be performed to ensure safe operation at the desired frequency for the selected MOSFETs. The power dissipated by the drivers is approximated as Equation 34: P = F sw ( 1.5V U Q + V L Q ) + P L + P U U L (EQ. 34) Where: Fsw is the switching frequency of the PWM signal VU is the upper gate driver bias supply voltage VL is the lower gate driver bias supply voltage QU is the charge to be delivered by the upper driver into the gate of the MOSFET and discrete capacitors - QL is the charge to be delivered by the lower driver into the gate of the MOSFET and discrete capacitors - PL is the quiescent power consumption of the lower driver - PU is the quiescent power consumption of the upper driver - MOSFET Selection and Considerations Typically, a MOSFET cannot tolerate even brief excursions beyond their maximum drain to source voltage rating. The MOSFETs used in the power stage of the converter should have a maximum VDS rating that exceeds the sum of the upper voltage tolerance of the input power 18 0 0 200 400 600 800 1k 1.2k 1.4k 1.6k 1.8k 2k FREQUENCY (Hz) FIGURE 12. POWER DISSIPATION vs FREQUENCY There are several power MOSFETs readily available that are optimized for DC/DC converter applications. The preferred high-side MOSFET emphasizes low switch charge so that the device spends the least amount of time dissipating power in the linear region. Unlike the low-side MOSFET which has the drain-source voltage clamped by its body diode during turn-off, the high-side MOSFET turns off with VIN -VOUT, plus the spike, across it. The preferred low-side MOSFET emphasizes low r DS(ON) when fully saturated to minimize conduction loss. For the low-side MOSFET, (LS), the power loss can be assumed to be conductive only and is written as Equation 35: 2 P CON_LS ≈ I LOAD ⋅ r DS ( ON )_LS ⋅ ( 1 – D ) (EQ. 35) For the high-side MOSFET, (HS), its conduction loss is written as Equation 36: 2 P CON_HS = I LOAD ⋅ r DS ( ON )_HS ⋅ D (EQ. 36) For the high-side MOSFET, its switching loss is written as Equation 37: V IN ⋅ I VALLEY ⋅ t ON ⋅ F V IN ⋅ I PEAK ⋅ t OFF ⋅ F SW SW P SW_HS = ---------------------------------------------------------------------- + -----------------------------------------------------------------2 2 (EQ. 37) Where: - IVALLEY is the difference of the DC component of the inductor current minus 1/2 of the inductor ripple current - IPEAK is the sum of the DC component of the inductor current plus 1/2 of the inductor ripple current - tON is the time required to drive the device into saturation September 18, 2009 FN6905.1 ISL62875 - tOFF is the time required to drive the device into cut-off PCB Layout Considerations Power and Signal Layers Placement on the PCB As a general rule, power layers should be close together, either on the top or bottom of the board, with the weak analog or logic signal layers on the opposite side of the board. The ground-plane layer should be adjacent to the signal layer to provide shielding. The ground plane layer should have an island located under the IC, the compensation components, and the SREF components. The island should be connected to the rest of the ground plane layer at one point. Component Placement There are two sets of critical components in a DC/DC converter; the power components and the small signal components. The power components are the most critical because they switch large amount of energy. The small signal components connect to sensitive nodes or supply critical bypassing current and signal coupling. The power components should be placed first and these include MOSFETs, input and output capacitors, and the inductor. Keeping the distance between the power train and the control IC short helps keep the gate drive traces short. These drive signals include the LGATE, UGATE, PGND, PHASE and BOOT. When placing MOSFETs, try to keep the source of the upper MOSFETs and the drain of the lower MOSFETs as close as thermally possible (see Figure 13). Input highfrequency capacitors should be placed close to the drain of the upper MOSFETs and the source of the lower MOSFETs. Place the output inductor and output capacitors between the MOSFETs and the load. Highfrequency output decoupling capacitors (ceramic) should be placed as close as possible to the decoupling target (GPUor CPU), making use of the shortest connection paths to any internal planes. Place the components in such a way that the area under the IC has less noise traces with high dV/dt and di/dt, such as gate signals and phase node signals. VIAS TO GROUND PLANE GND VOUT INDUCTOR PHASE NODE HIGH-SIDE MOSFETS VIN OUTPUT CAPACITORS SCHOTTKY DIODE LOW-SIDE MOSFETS INPUT CAPACITORS FIGURE 13. TYPICAL POWER COMPONENT PLACEMENT 19 Signal Ground and Power Ground The GND pin is the signal-common also known as analog ground of the IC. When laying out the PCB, it is very important that the connection of the GND pin to the bottom setpoint-reference programming-resistor, bottom feedback voltage-divider resistor (if used), and the CSOFT capacitor be made as close as possible to the GND pin on a conductor not shared by any other components. In addition to the critical single point connection discussed in the previous paragraph, the ground plane layer of the PCB should have a single-point-connected island located under the area encompassing the IC, setpoint reference programming components, feedback voltage divider components, compensation components, CSOFT capacitor, and the interconnecting traces among the components and the IC. The island should be connected using several filled vias to the rest of the ground plane layer at one point that is not in the path of either large static currents or high di/dt currents. The single connection point should also be where the VCC decoupling capacitor and the GND pin of the IC are connected. Anywhere not within the analog-ground island is Power Ground. Connect the input capacitor(s), the output capacitor(s), and the source of the lower MOSFET(s) to the power ground plane. Routing and Connection Details Specific pins (and the trace routing from them), require extra attention during the layout process. The following sub-sections outline concerns by pin name. VCC PIN For best performance, place the decoupling capacitor next to the VCC and GND pins. The VCC decoupling capacitor should not share any vias with the PVCC decoupling capacitor. PVCC PIN For best performance, place the PVCC decoupling capacitor next to the PVCC and PGND pins, preferably on the same side of the PCB as the ISL62875. The PVCC decoupling capacitor should have a very short and wide trace connection to the PGND pin. EN, PGOOD, VID0, AND VID1 PINS These are logic signals that are referenced to the GND pin. Treat as a typical logic signal. OCSET AND VO PINS The current-sensing network consisting of ROCSET, RO, and CSEN must be connnected to the inductor pads for accurate measurement of the DCR voltage drop. These components however, should be located physically close to the OCSET and VO pins with traces leading back to the inductor. It is critical that the traces are shielded by the ground plane layer all the way to the inductor pads. The procedure is the same for resistive current sense. September 18, 2009 FN6905.1 ISL62875 FB, SREF, SET0, SET1, AND SET2 PINS Copper Size for the Phase Node The input impedance of these pins is high, making it critical to place the loop compensation components, setpoint reference programming resistors, feedback voltage divider resistors, and CSOFT close to the IC, keeping the length of the traces short. The parasitic capacitance and parasitic inductance of the phase node should be kept very low to minimize ringing. It is best to limit the size of the PHASE node copper in strict accordance with the current and thermal management of the application. An MLCC should be connected directly across the drain of the upper MOSFET and the source of the lower MOSFET to suppress the turn-off voltage. LGATE, PGND, UGATE, BOOT, AND PHASE PINS The signals going through these traces are boht high dv/dt and di/dt, with high peak charging and discharging current. The PGND pin can only flow current from the gate-source charge of the low-side MOSFETs when LGATE goes low. Ideally, route the trace from the LGATE pin in parallel with the trace from the PGND pin, route the trace from the UGATE pin in parallel with the trace from the PHASE pin, and route the trace from the BOOT pin in parallel with the trace from the PHASE pin. These pairs of traces should be short, wide, and away from other traces with high input impedance; weak signal traces should not be in proximity with these traces on any layer. 20 September 18, 2009 FN6905.1 ISL62875 Revision History The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to web to make sure you have the latest Rev. DATE REVISION CHANGE 8/09 FN6905.0 Initial Release 9/09 FN6905.1 Page 10: Removed “OVP Rising Threshold Voltage” and “OVP Falling Threshold Voltage” lines from the “Electrical Specifications” table. Products Intersil Corporation is a leader in the design and manufacture of high-performance analog semiconductors. The Company's products address some of the industry's fastest growing markets, such as, flat panel displays, cell phones, handheld products, and notebooks. Intersil's product families address power management and analog signal processing functions. Go to www.intersil.com/products for a complete list of Intersil product families. *For a complete listing of Applications, Related Documentation and Related Parts, please see the respective device information page on intersil.com: ISL62875 To report errors or suggestions for this datasheet, please go to www.intersil.com/askourstaff FITs are available from our website at http://rel.intersil.com/reports/search.php For additional products, see www.intersil.com/product_tree Intersil products are manufactured, assembled and tested utilizing ISO9000 quality systems as noted in the quality certifications found at www.intersil.com/design/quality Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com 21 September 18, 2009 FN6905.1 ISL62875 Package Outline Drawing L20.3.2x1.8 20 LEAD ULTRA THIN QUAD FLAT NO-LEAD PLASTIC PACKAGE (UTQFN) Rev 0, 5/08 1.80 A 6 PIN #1 ID 16X 0.40 B 20 6 PIN 1 ID# 1 19 2 3.20 0.50±0.10 (4X) 0.10 9 12 11 10 VIEW “A-A” TOP VIEW 0.10 M C A B 0.05 M C 4 20X 0.20 19X 0.40 ± 0.10 BOTTOM VIEW ( 1.0 ) (1 x 0.70) SEE DETAIL "X" 0.10 C MAX 0.55 C BASE PLANE ( 2. 30 ) SEATING PLANE 0.05 C SIDE VIEW ( 16 X 0 . 40 ) C 0 . 2 REF 5 ( 20X 0 . 20 ) 0 . 00 MIN. 0 . 05 MAX. ( 19X 0 . 60 ) DETAIL "X" TYPICAL RECOMMENDED LAND PATTERN NOTES: 1. Dimensions are in millimeters. Dimensions in ( ) for Reference Only. 2. Dimensioning and tolerancing conform to AMSE Y14.5m-1994. 3. Unless otherwise specified, tolerance : Decimal ± 0.05 4. Dimension b applies to the metallized terminal and is measured between 0.15mm and 0.30mm from the terminal tip. 5. Tiebar shown (if present) is a non-functional feature. 6. The configuration of the pin #1 identifier is optional, but must be located within the zone indicated. The pin #1 identifier may be either a mold or mark feature. 22 September 18, 2009 FN6905.1