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LTC3731

LTC3731

  • 厂商:

    LINER

  • 封装:

  • 描述:

    LTC3731 - 3-Phase, 600kHz, Synchronous Buck Switching Regulator Controller - Linear Technology

  • 数据手册
  • 价格&库存
LTC3731 数据手册
FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ LTC3731 3-Phase, 600kHz, Synchronous Buck Switching Regulator Controller DESCRIPTIO The LTC®3731 is a PolyPhase® synchronous step-down switching regulator controller that drives all N-channel external power MOSFET stages in a phase-lockable fixed frequency architecture. The 3-phase controller drives its output stages with 120° phase separation at frequencies of up to 600kHz per phase to minimize the RMS current losses in both the input and output filter capacitors. The 3-phase technique effectively triples the fundamental frequency, improving transient response while operating each controller at an optimal frequency for efficiency and ease of thermal design. Light load efficiency is optimized by using a choice of output Stage Shedding or Burst Mode operation. A differential amplifier provides true remote sensing of both the high and low side of the output voltage at the point of load. The precision reference supports output voltages from 0.6V to 6V. Soft-start and a defeatable, timed short-circuit shutdown protect the MOSFETs and the load. Current foldback provides protection for the external MOSFETs under short-circuit or overload conditions. , LTC and LT are registered trademarks of Linear Technology Corporation. Burst Mode, OPTI-LOOP and PolyPhase are registered trademarks of Linear Technology Corporation. Stage Shedding is a trademark of Linear Technology Corporation. *Protected by U.S. Patents including 5481178, 5929620, 6177787, 6144194, 6100678, 5408150, 6580258, 6462525, 6304066, 5705919. 3-Phase Current Mode Controller with Onboard MOSFET Drivers ±5% Output Current Matching Optimizes Thermal Performance and Size of Inductors and MOSFETs Differential Amplifier Accurately Senses VOUT ±1% VREF Accuracy Over Temperature Reduced Power Supply Induced Noise ±10% Power Good Output Indicator 250kHz to 600kHz Per Phase, PLL, Fixed Frequency PWM, Stage SheddingTM or Burst Mode® Operation OPTI-LOOP® Compensation Minimizes COUT Adjustable Soft-Start Current Ramping Short-Circuit Shutdown Timer with Defeat Option Overvoltage Soft Latch Adjustable Undervoltage Lockout Threshold Selectable Phase Output for Up to 12-Phase Operation Available in 5mm × 5mm QFN and 36-Pin Narrow (0.209") SSOP Packages APPLICATIO S ■ ■ ■ Desktop Computers and Servers High Performance Notebook Computers High Output Current DC/DC Power Supplies TYPICAL APPLICATIO VCC 4.5V TO 7V VCC 10µF LTC3731 BOOST1 BOOST2 BOOST3 0.1µF SW3 SW2 SW1 TG1 SW1 BG1 SENSE1+ SENSE1– TG2 SW2 BG2 PGND SENSE2+ SENSE2– TG3 SW3 BG3 SENSE3+ SENSE3– VIN VIN 0.8µH 0.003Ω POWER GOOD INDICATOR OPTIONAL SYNC IN PGOOD PLLIN PLLFLTR 0.8µH 0.003Ω 36k VIN 12k 680pF ITH 5k 0.01µF 100pF 7.5k 6.04k RUN/SS SGND EAIN DIFFOUT IN – IN + UVADJ 0.8µH 0.003Ω Figure 1. High Current Triple Phase Step-Down Converter 3731fa U U U + VIN 5V TO 28V 22µF 35V VOUT 1.35V 55A + COUT 470µF 4V 3731 F01 1 LTC3731 ABSOLUTE AXI U RATI GS Topside Driver Voltages (BOOSTN) ............ 38V to –0.3V Switch Voltage (SWN)................................... 32V to –5V Boosted Driver Voltage (BOOSTN – SWN) .... 7V to –0.3V Peak Output Current fOSC Power Good Output Indication IPGOOD = 2mA, G Package IPGOOD = 1.6mA, UH Package VPGOOD = 5V, G Package 0 ≤ VPHASMD/PG ≤ VCC, UH Package VDIFFOUT with Respect to Set Output Voltage, HGOOD Goes Low After VUVDLY Delay After VEAIN is Forced Outside the PGOOD Thresholds VPLLFLTR = 1.2V VPLLFLTR = 0V VPLLFLTR = 2.4V Minimum Pulse Width > 100ns 360 190 600 –10 –7 7 ±3 –10 10 100 400 225 680 1 50 20 20 120 240 30 60 1.000 0.5 1.005 5 VCC 0.1 0.5 0.3 1.0 1 10 –13 13 150 440 260 750 V V µA µA % % µs kHz kHz kHz V kΩ µA µA Deg Deg Deg Deg V/V mV V dB mA MHz V/µs V kΩ The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = VRUN/SS = 5V unless otherwise noted. CONDITIONS MIN TYP MAX UNITS Oscillator and Phase-Locked Loop RRELPHS CLKOUT Differential Amplifier AV VOS CM CMRR ICL GBP SR VO(MAX) RIN Differential Gain Input Offset Voltage Magnitude Common Mode Input Voltage Range Common Mode Rejection Ratio Output Current Sourcing Gain Bandwidth Product Slew Rate Maximum High Output Voltage Input Resistance Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: TJ is calculated from the ambient temperature TA and power dissipation PD according to the following formula: LTC3731CG/LTC3731IG: TJ = TA + (PD × 95°C/W) LTC3731CG/LTC3731IG: TJ = TCASE + (PD × 32°C/W) LTC3731CUH/LTC3731IUH: TJ = TA + (PD × 34°C/W) Note 3: The IC is tested in a feedback loop that includes the differential amplifier loaded with 100µA to ground driving the error amplifier and servoing the resultant voltage to the midrange point for the error amplifier (VITH = 1.2V). Note 4: Dynamic supply current is higher due to the gate charge being delivered at the switching frequency. See Applications Information. Note 5: The minimum on-time condition corresponds to an inductor peakto-peak ripple current of ≥ 40% of IMAX (see minimum on-time considerations in the Applications Information Section). Note 6: This IC includes overtemperature protection that is intended to protect the device during momentary overload conditions. Junction temperature will exceed 125°C when overtemperature protection is active. Continuous operation above the specified maximum operating junction temperature may impair device reliability. 3731fa 4 LTC3731 PI FU CTIO S BG1 to BG3: High Current Gate Drives for Bottom N-Channel MOSFETs. Voltage swing at these pins is from ground to VCC. BOOST1 to BOOST3: Positive Supply Pins to the Topside Floating Drivers. Bootstrapped capacitors, charged with external Schottky diodes and a boost voltage source, are connected between the BOOST and SW pins. Voltage swing at the BOOST pins is from boost source voltage (typically VCC) to this boost source voltage + VIN (where VIN is the external MOSFET supply rail). CLKOUT: Output clock signal available to synchronize other controller ICs for additional MOSFET stages/phases. DIFFOUT: Output of the Remote Output Voltage Sensing Differential Amplifier. EAIN: This is the input to the error amplifier that compares the feedback voltage to the internal 0.6V reference voltage. FCB: Forced Continuous Control Input. The voltage applied to this pin sets the operating mode of the controller. The forced continuous current mode is active when the applied voltage is less than 0.6V. Burst Mode operation will be active when the pin is allowed to float and a Stage Shedding mode will be active if the pin is tied to the VCC pin. (Do not apply voltage directly to this pin prior to the application of voltage on the VCC pin.) PGOOD: This open-drain output is pulled low when the output voltage has been outside the PGOOD tolerance window for the VPGDLY delay of approximately 100µs. IN+, IN–: Inputs to a precision, unity-gain differential amplifier with internal precision resistors. This provides true remote sensing of both the positive and negative load terminals for precise output voltage control. ITH: Error Amplifier Output and Switching Regulator Compensation Point. All three current comparator’s thresholds increase with this control voltage. PGND: Driver Power Ground. This pin connects directly to the sources of the bottom N-channel external MOSFETs and the (–) terminals of CIN. PHASMD: This pin determines the phase shift between the first controller’s rising TG signal and the rising edge of the CLKOUT signal. Logic 0 yields 30 degrees and Logic 1 yields 60 degrees. Note: the PHASMD and PGOOD functions are internally tied together on the LTC3731CUH device. PLLIN: Synchronization Input to Phase Detector. This pin is internally terminated to SGND with 50kΩ. The phase-locked loop will force the rising top gate signal of controller 1 to be synchronized with the rising edge of the PLLIN signal. PLLFLTR: The phase-locked loop’s lowpass filter is tied to this pin. Alternatively, this pin can be driven with an AC or DC voltage source to vary the frequency of the internal oscillator. (Do not apply voltage directly to this pin prior to the application of voltage on the VCC pin.) RUN/SS: Combination of Soft-Start, Run Control Input and Short-Circuit Detection Timer. A capacitor to ground at this pin sets the ramp time to full current output as well as the time delay prior to an output voltage short-circuit shutdown. A minimum value of 0.01µF is recommended on this pin. SENSE1+, SENSE2+, SENSE3+, SENSE1–, SENSE2–, SENSE3–: The Inputs to Each Differential Current Comparator. The ITH pin voltage and built-in offsets between SENSE– and SENSE+ pins, in conjunction with RSENSE, set the current trip threshold level. SGND: Signal Ground. This pin must be routed separately under the IC to the PGND pin and then to the main ground plane. The exposed pad on the LTC3731UH package is SGND and must be soldered to the PCB. SW1 to SW3: Switch Node Connections to Inductors. Voltage swing at these pins is from a Schottky diode (external) voltage drop below ground to VIN (where VIN is the external MOSFET supply rail). TG1 to TG3: High Current Gate Drives for Top N-channel MOSFETs. These are the outputs of floating drivers with a voltage swing equal to the boost voltage source superimposed on the switch node voltage SW. UVADJ: Input to the Undervoltage Shutdown Comparator. When the applied input voltage is less than 1.2V, this comparator turns off the output MOSFET driver stages and discharges the RUN/SS capacitor. VCC: Main Supply Pin. Because this pin supplies both the controller circuit power as well as the high power pulses supplied to drive the external MOSFET gates in the LTC3731CUH, this pin needs to be very carefully and closely decoupled to the IC’s PGND pin. VDR: (LTC3731G Package Only) Supplies power to the bottom gate drivers only. This pin needs to be very carefully and closely decoupled to the IC’s PGND pin. 3731fa U U U 5 LTC3731 TYPICAL PERFOR A CE CHARACTERISTICS Efficiency vs IOUT (Figure 14) 100 90 VFCB = OPEN 80 VFCB = 5V VFCB = 0V 70 60 50 40 30 20 10 0 0.1 1 10 VIN = 8V VOUT = 1.5V 100 3731 G01 EFFICIENCY (%) EFFICIENCY (%) 80 75 70 65 60 55 50 0 5 IL = 45A EFFICIENCY (%) INDUCTOR CURRENT (A) Reference Voltage vs Temperature 610 6.0 605 MAXIMUM ISENSE THRESHOLD (mV) ERROR AMPLIFIER gm (mmho) REFERENCE VOLTAGE (mV) 600 595 590 –50 –25 0 25 50 75 TEMPERATURE (°C) Oscillator Frequency vs Temperature 700 600 500 400 VPLLFLTR = 1.2V 300 200 100 0 –50 200 –25 0 25 50 75 100 125 VPLLFLTR = 0V VPLLFLTR = 2.4V 700 500 UNDER VOLTAGE RESET (V) VPLLFLTR = 5V OPERATING FREQUENCY (kHz) FREQUENCY (kHz) TEMPERATURE (°C) 3731 G07 6 UW 100 3731 G04 Efficiency vs VIN (Figure 14) 100 95 90 85 IL = 15A VOUT = 1.5V f = 250kHz 100 Efficiency vs Frequency (Figure 14) ILOAD = 20A VOUT = 1.5V 95 VIN = 5V 90 VIN = 12V 85 VIN = 20V 80 VIN = 8V 10 15 VIN (V) 20 25 3731 G02 75 200 300 400 FREQUENCY (kHz) 500 600 3731 G03 Error Amplifier gm vs Temperature 85 Maximum ISENSE Threshold vs Temperature 5.5 80 VO = 1.75V 75 VO = 0.6V 70 5.0 4.5 125 4.0 –50 –25 0 25 50 75 TEMPERATURE (°C) 100 125 65 –50 –25 0 25 50 75 TEMPERATURE (°C) 100 125 3731 G05 3731 G06 Operating Frequency vs VPLLFLTR 5 Undervoltage Reset Voltage vs Temperature 600 4 3 400 2 300 1 0 0.5 1 1.5 2 PLLFLTR PIN VOLTAGE (V) 2.5 3731 G08 0 –50 –25 0 25 50 75 100 125 TEMPERATURE (°C) 3731 G09 3731fa LTC3731 TYPICAL PERFOR A CE CHARACTERISTICS Short-Circuit Arming and Latchoff vs Temperature 5 2.8 ARMING RUN/SS PIN VOLTAGE (V) 4 2.4 80 RUN/SS PULLUP CURRENT (µA) SUPPLY CURRENT (mA) 3 LATCHOFF 2 1 0.4 0 –50 –25 0 25 50 75 100 125 0 –50 –25 0 25 50 75 100 TEMPERATURE (°C) 3731 G10 Maximum ISENSE vs VRUN/SS 80 70 75 ISENSE VOLTAGE THRESHOLD (mV) MAXIMUM ISENSE (mV) ISENSE VOLTAGE (mV) 60 50 40 30 20 10 0 0 1 3 4 VRUN/SS VOLTAGE (V) 2 5 6 3731 G13 Percentage of Nominal Output vs Peak ISENSE (Foldback) 80 70 100 MAXIMUM DUTY FACTOR (%) PEAK ISENSE VOLTAGE (mV) 60 50 40 30 20 10 0 0 10 20 30 40 50 60 70 80 90 100 PERCENTAGE OF NOMINAL OUTPUT VOLTAGE (%) 3731 G16 ISENSE PIN CURRENT (µA) UW Supply Current vs Temperature 100 VCC = 5V 2.5 RUN/SS Pull-Up Current vs Temperature VRUN/SS = 1.9V 2.0 SHUTDOWN CURRENT (µA) 2.0 1.6 1.2 0.8 60 1.5 40 1.0 20 0.5 0 125 0 –50 –25 TEMPERATURE (°C) 3731 G11 0 25 50 75 TEMPERATURE (°C) 100 125 3731 G12 Maximum Current Sense Threshold vs Duty Factor 75 60 45 30 15 0 –15 Peak Current Threshold vs VITH 50 25 0 0 20 40 60 DUTY FACTOR (%) 80 100 3731 G14 0 0.6 1.2 VITH (V) 1.8 2.4 3731 G15 Maximum Duty Factor vs Temperature 40 VPLLFLTR = 0V 98 30 20 10 0 –10 –20 90 –50 –30 ISENSE Pin Current vs VOUT 96 94 92 –25 0 25 50 75 TEMPERATURE (°C) 100 125 0 1 3 2 VOUT (V) 4 5 3731 G18 3731 G17 3731fa 7 LTC3731 TYPICAL PERFOR A CE CHARACTERISTICS Differential Amplifier Gain-Phase 0 0 GAIN (dB) Shed Mode at 1 Amp, Light Load Current (Circuit of Figure 14) VOUT AC, 20mV/DIV VSW1 10V/DIV VSW2 10V/DIV VSW3 10V/DIV 4µs/DIV VIN = 12V VOUT = 1.5V VFCB = VCC FREQUENCY = 250kHz Continuous Mode at 1 Amp, Light Load Current (Circuit of Figure 14) VOUT AC, 20mV/DIV VSW1 10V/DIV VSW2 10V/DIV VSW3 10V/DIV VIN = 12V 4µs/DIV VOUT = 1.5V VFCB = 0V FREQUENCY = 250kHz ILOAD 20A/DIV 8 UW –3 –45 PHASE (DEG) –6 –90 –9 –135 –12 –180 –15 0001 0.01 0.1 FREQUENCY (MHz) 1 –225 10 3731 G19 Burst Mode at 1 Amp, Light Load Current (Circuit of Figure 14) VOUT AC, 20mV/DIV VSW1 10V/DIV VSW2 10V/DIV VSW3 10V/DIV 4µs/DIV VIN = 12V VOUT = 1.5V VFCB = OPEN FREQUENCY = 250kHz 3731 G20 3731 G21 Transient Load Current Response: 0 Amp to 50 Amp (Circuit of Figure 14) VOUT AC, 20mV/DIV 3731 G22 VIN = 12V 20µs/DIV VOUT = 1.5V VFCB = VCC FREQUENCY = 250kHz 3731 G23 3731fa LTC3731 FU CTIO AL DIAGRA PLLIN FIN 50k RLP PLLFLTR CLP CLKOUT OSCILLATOR PHASMD** PHASE DET CLK1 CLK2 CLK3 PGOOD** 100µs DELAY PROTECTION FCB FCB 40k + – + 0.66V EAIN – + 0.54V RS LATCH S R Q Q 0.6V IN– 40k IN+ 40k DIFFOUT – A1 + 40k I1 R1 EAIN R2 0.600V VFB – + + 0.660V ITH CC RC VCC – EA OV SS CLAMP 54k 2.4V 54k VOUT FCB SHED 1.2V 0.600V VREF VCC INTERNAL SUPPLY SGND* UV RESET RUN/SS VCC 1.5µA SHDN RST 5(VFB) 6V UVADJ – 1.2V + RUN SOFTSTART + CCC CSS + *THE LTC3731CUH USES THE EXPOSED DIE ATTACH PAD FOR THE SGND CONNECTIONS **THE PHASMD AND PGOOD PIN FUNCTIONS ARE TIED TOGETHER IN THE LTC3731CUH PACKAGE ***LTC3731CG/HG ONLY W DUPLICATE FOR SECOND AND THIRD CONTROLLER CHANNELS BOOST DROP OUT DET VCC DB VIN BOT FORCE BOT SWITCH LOGIC SW VCC (VDR)*** B FCB SHDN – + – + L BOT BG PGND TOP TG CB – U U + CIN 0.55V – ++ 3mV – I2 VCC + 36k SENSE SLOPE COMP 5(VFB) 0.86V – 36k SENSE RSENSE COUT 3731 F02 Figure 2 3731fa 9 LTC3731 OPERATIO Main Control Loop The IC uses a constant frequency, current mode stepdown architecture. During normal operation, each top MOSFET is turned on each cycle when the oscillator sets the RS latch, and turned off when the main current comparator, I1, resets each RS latch. The peak inductor current at which I1 resets the RS latch is controlled by the voltage on the ITH pin, which is the output of the error amplifier EA. The EAIN pin receives a portion of output voltage feedback signal via the DIFFOUT pin through the external resistive divider and is compared to the internal reference voltage. When the load current increases, it causes a slight decrease in the EAIN pin voltage relative to the 0.6V reference, which in turn causes the ITH voltage to increase until each inductor’s average current matches one third of the new load current (assuming all three current sensing resistors are equal). In Burst Mode operation and Stage Shedding mode, after each top MOSFET has turned off, the bottom MOSFET is turned on until either the inductor current starts to reverse, as indicated by current comparator I2, or the beginning of the next cycle. The top MOSFET drivers are biased from floating bootstrap capacitor CB, which is normally recharged through an external Schottky diode when the top FET is turned off. When VIN decreases to a voltage close to VOUT, however, the loop may enter dropout and attempt to turn on the top MOSFET continuously. The dropout detector counts the number of oscillator cycles that the bottom MOSFET remains off and periodically forces a brief on period to allow CB to recharge. The main control loop is shut down by pulling the RUN/SS pin low. Releasing RUN/SS allows an internal 1.5µA current source to charge soft-start capacitor CSS. When CSS reaches 1.5V, the main control loop is enabled and the internally buffered ITH voltage is clamped but allowed to ramp as the voltage on CSS continues to ramp. This “softstart” clamping prevents abrupt current from being drawn from the input power source. When the RUN/SS pin is low, all functions are kept in a controlled state. The RUN/SS pin is pulled low when the supply input voltage is below 4V, when the undervoltage lockout pin (UVADJ) is below 1.2V, or when the IC die temperature rises above 150°C. 10 U (Refer to Functional Diagram) Low Current Operation The FCB pin is a logic input to select between three modes of operation. A) Burst Mode Operation When the FCB pin voltage is below 0.6V, the controller performs as a continuous, PWM current mode synchronous switching regulator. The top and bottom MOSFETs are alternately turned on to maintain the output voltage independent of direction of inductor current. When the FCB pin is below VCC – 1.5V but greater than 0.6V, the controller performs as a Burst Mode switching regulator. Burst Mode operation sets a minimum output current level before turning off the top switch and turns off the synchronous MOSFET(s) when the inductor current goes negative. This combination of requirements will, at low current, force the ITH pin below a voltage threshold that will temporarily shut off both output MOSFETs until the output voltage drops slightly. There is a burst comparator having 60mV of hysteresis tied to the ITH pin. This hysteresis results in output signals to the MOSFETs that turn them on for several cycles, followed by a variable “sleep” interval depending upon the load current. The resultant output voltage ripple is held to a very small value by having the hysteretic comparator after the error amplifier gain block. B) Stage Shedding Operation When the FCB pin is tied to the VCC pin, Burst Mode operation is disabled and the forced minimum inductor current requirement is removed. This provides constant frequency, discontinuous current operation over the widest possible output current range. At approximately 10% of maximum designed load current, the second and third output stages are shut off and the phase 1 controller alone is active in discontinuous current mode. This “stage shedding” optimizes efficiency by eliminating the gate charging losses and switching losses of the other two output stages. Additional cycles will be skipped when the output load current drops below 1% of maximum designed load current in order to maintain the output voltage. This stage shedding operation is not as efficient as Burst Mode operation at very light loads, but does provide lower noise, constant frequency operating mode down to very light load conditions. 3731fa LTC3731 OPERATIO C) Continuous Current Operation Tying the FCB pin to ground will force continuous current operation. This is the least efficient operating mode, but may be desirable in certain applications. The output can source or sink current in this mode. When forcing continuous operation and sinking current, this current will be forced back into the main power supply, potentially boosting the input supply to dangerous voltage levels— BEWARE! Frequency Synchronization The phase-locked loop allows the internal oscillator to be synchronized to an external source using the PLLIN pin. The output of the phase detector at the PLLFLTR pin is also the DC frequency control input of the oscillator which operates over a 250kHz to 600kHz range corresponding to a voltage input from 0V to 2.4V. When locked, the PLL aligns the turn on of the top MOSFET to the rising edge of the synchronizing signal. When no frequency information is supplied to the PLLIN pin, PLLFLTR goes low, forcing the oscillator to minimum frequency. A DC source can be applied to the PLLFLTR pin to externally set the desired operating frequency. An approximate 20µA discharge current will be present at the pin with no PLLIN input signal. Input capacitance ESR requirements and efficiency losses are reduced substantially in a multiphase architecture because the peak current drawn from the input capacitor is effectively divided by the number of phases used and power loss is proportional to the RMS current squared. A 3-stage, single output voltage implementation can reduce input path power loss by 90%. Differential Amplifier This amplifier provides true differential output voltage sensing. Sensing both VOUT+ and VOUT– benefits regulation in high current applications and/or applications having electrical interconnection losses. This sensing also isolates the physical power ground from the physical signal ground preventing the possibility of troublesome “ground loops” on the PC layout and prevents voltage errors caused by board-to-board interconnects, particularly helpful in VRM designs. U (Refer to Functional Diagram) Power Good The PGOOD pin is connected to the drain of an internal N-channel MOSFET. The MOSFET is turned on once an internal delay of about 100µs has elapsed and the output voltage has been away from its nominal value by greater than 10%. If the output returns to normal prior to the delay timeout, the timer is reset. There is no delay time for the rising of the PGOOD output once the output voltage is within the ±10% “window.” Phase Mode The PHASMD pin determines the phase shift between the rising edge of the TG1 output and the rising edge of the CLKOUT signal. Grounding the pin will result in 30 degrees phase shift and tying the pin to VCC will result in 60 degrees. These phase shift values enable extension to 6and 12-phase systems. The PGOOD function above and the PHASMD function are tied to a common pin in the UH package. Undervoltage Shutdown Adjust The voltage applied to the UVADJ pin is compared to the internal 1.2V reference to have an externally programmable undervoltage shutdown. The RUN/SS pin is internally held low until the voltage applied to the UVADJ pin exceeds the 1.2V threshold. Short-Circuit Detection The RUN/SS capacitor is used initially to turn on and limit the inrush current from the input power source. Once the controllers have been given time, as determined by the capacitor on the RUN/SS pin, to charge up the output capacitors and provide full load current, the RUN/SS capacitor is then used as a short-circuit timeout circuit. If the output voltage falls to less than 70% of its nominal output voltage, the RUN/SS capacitor begins discharging, assuming that the output is in a severe overcurrent and/or short-circuit condition. If the condition lasts for a long enough period, as determined by the size of the RUN/SS capacitor, the controller will be shut down until the RUN/SS pin voltage is recycled. This built-in latchoff 3731fa 11 LTC3731 OPERATIO can be overridden by providing >5µA at a compliance of 3.8V to the RUN/SS pin. This additional current shortens the soft-start period but prevents net discharge of the RUN/SS capacitor during a severe overcurrent and/or short-circuit condition. Foldback current limiting is activated when the output voltage falls below 70% of its nominal level whether or not the short-circuit latchoff circuit is enabled. Foldback current limit can be overridden by clamping the EAIN pin such that the voltage is held above the (70%)(0.6V) or 0.42V level even when the actual output voltage is low. Up to 100µA of input current can safely be accommodated by the RUN/SS pin. APPLICATIO S I FOR ATIO The basic application circuit is shown in Figure 1 on the first page of this data sheet. External component selection is driven by the load requirement, and normally begins with the selection of an inductance value based upon the desired operating frequency, inductor current and output voltage ripple requirements. Once the inductors and operating frequency have been chosen, the current sensing resistors can be calculated. Next, the power MOSFETs and Schottky diodes are selected. Finally, C IN and COUT are selected according to the required voltage ripple requirements. The circuit shown in Figure 1 can be configured for operation up to a MOSFET supply voltage of 28V (limited by the external MOSFETs and possibly the minimum on-time). Operating Frequency The IC uses a constant frequency, phase-lockable architecture with the frequency determined by an internal capacitor. This capacitor is charged by a fixed current plus an additional current which is proportional to the voltage applied to the PLLFLTR pin. Refer to the Phase-Locked Loop and Frequency Synchronization section for additional information. A graph for the voltage applied to the PLLFLTR pin versus frequency is given in Figure 3. As the operating frequency is increased the gate charge losses will be higher, reducing OPERATING FREQUENCY (kHz) 12 U W UU U (Refer to Functional Diagram) Input Undervoltage Reset The RUN/SS capacitor will be reset if the input voltage, (VCC) is allowed to fall below approximately 4V. The capacitor on the RUN/SS pin will be discharged until the short-circuit arming latch is disarmed. The RUN/SS capacitor will attempt to cycle through a normal soft-start ramp up after the VCC supply rises above 4V. This circuit prevents power supply latchoff in the event of input power switching break-before-make situations. The PGOOD pin is held low during start-up until the RUN/SS capacitor rises above the short-circuit latchoff arming threshold of approximately 3.8V. 700 600 500 400 300 200 0 0.5 1 1.5 2 PLLFLTR PIN VOLTAGE (V) 2.5 3731 F03 Figure 3. Operating Frequency vs VPLLFLTR efficiency (see Efficiency Considerations). The maximum switching frequency is approximately 680kHz. Inductor Value Calculation and Output Ripple Current The operating frequency and inductor selection are interrelated in that higher operating frequencies allow the use of smaller inductor and capacitor values. So why would anyone ever choose to operate at lower frequencies with larger components? The answer is efficiency. A higher frequency generally results in lower efficiency because of MOSFET gate charge and transition losses. In addition to this basic tradeoff, the effect of inductor value on ripple 3731fa LTC3731 APPLICATIO S I FOR ATIO ∆IO(P-P) VO/fL current and low current operation must also be considered. The PolyPhase approach reduces both input and output ripple currents while optimizing individual output stages to run at a lower fundamental frequency, enhancing efficiency. The inductor value has a direct effect on ripple current. The inductor ripple current ∆IL per individual section, N, decreases with higher inductance or frequency and increases with higher VIN or VOUT: ⎛V⎞ V ∆IL = OUT ⎜ 1 − OUT ⎟ fL ⎝ VIN ⎠ where f is the individual output stage operating frequency. In a PolyPhase converter, the net ripple current seen by the output capacitor is much smaller than the individual inductor ripple currents due to the ripple cancellation. The details on how to calculate the net output ripple current can be found in Application Note 77. Figure 4 shows the net ripple current seen by the output capacitors for the different phase configurations. The output ripple current is plotted for a fixed output voltage as the duty factor is varied between 10% and 90% on the x-axis. The output ripple current is normalized against the inductor ripple current at zero duty factor. The graph can be used in place of tedious calculations. As shown in Figure 4, the zero output ripple current is obtained when: VOUT k = where k = 1, 2, ..., N – 1 VIN N So the number of phases used can be selected to minimize the output ripple current and therefore the output ripple voltage at the given input and output voltages. In applications having a highly varying input voltage, additional phases will produce the best results. Accepting larger values of ∆IL allows the use of low inductances but can result in higher output voltage ripple. A reasonable starting point for setting ripple current is ∆IL = 0.4(IOUT)/N, where N is the number of channels and IOUT is the total load current. Remember, the maximum ∆IL occurs at the maximum input voltage. The individual inductor ripple currents are constant determined by the inductor, input and output voltages. U 1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 DUTY FACTOR (VOUT/VIN) 0.8 0.9 1-PHASE 2-PHASE 3-PHASE 4-PHASE 6-PHASE 12-PHASE 3731 F04 W UU Figure 4. Normalized Peak Output Current vs Duty Factor [IRMS = 0.3(IO(P-P)] Inductor Core Selection Once the value for L1 to L3 is determined, the type of inductor must be selected. High efficiency converters generally cannot afford the core loss found in low cost powdered iron cores, forcing the use of ferrite, molypermalloy or Kool Mµ® cores. Actual core loss is independent of core size for a fixed inductor value, but it is very dependent on inductance selected. As inductance increases, core losses go down. Unfortunately, increased inductance requires more turns of wire and therefore copper losses will increase. Ferrite designs have very low core loss and are preferred at high switching frequencies, so design goals can concentrate on copper loss and preventing saturation. Ferrite core material saturates “hard,” which means that inductance collapses abruptly when the peak design current is exceeded. This results in an abrupt increase in inductor ripple current and consequent output voltage ripple. Do not allow the core to saturate! Molypermalloy (from Magnetics, Inc.) is a very good, low loss core material for toroids, but it is more expensive than ferrite. A reasonable compromise from the same manufacturer is Kool Mµ. Toroids are very space efficient, especially when you can use several layers of wire. Because they lack a bobbin, mounting is more difficult. However, designs for surface mount are available which do not increase the height significantly. Kool Mµ is a registered trademark of Magnetics, Inc. 3731fa 13 LTC3731 APPLICATIO S I FOR ATIO Power MOSFET and D1, D2, D3 Selection At least two external power MOSFETs must be selected for each of the three output sections: One N-channel MOSFET for the top (main) switch and one or more N-channel MOSFET(s) for the bottom (synchronous) switch. The number, type and “on” resistance of all MOSFETs selected take into account the voltage step-down ratio as well as the actual position (main or synchronous) in which the MOSFET will be used. A much smaller and much lower input capacitance MOSFET should be used for the top MOSFET in applications that have an output voltage that is less than 1/3 of the input voltage. In applications where VIN >> VOUT, the top MOSFETs’ “on” resistance is normally less important for overall efficiency than its input capacitance at operating frequencies above 300kHz. MOSFET manufacturers have designed special purpose devices that provide reasonably low “on” resistance with significantly reduced input capacitance for the main switch application in switching regulators. The peak-to-peak MOSFET gate drive levels are set by the voltage, VCC, requiring the use of logic-level threshold MOSFETs in most applications. Pay close attention to the BVDSS specification for the MOSFETs as well; many of the logic-level MOSFETs are limited to 30V or less. Selection criteria for the power MOSFETs include the “on” resistance RDS(ON), input capacitance, input voltage and maximum output current. MOSFET input capacitance is a combination of several components but can be taken from the typical “gate charge” curve included on most data sheets (Figure 5). The curve is generated by forcing a constant input current into the gate of a common source, current source loaded VIN MILLER EFFECT VGS a QIN CMILLER = (QB – QA)/VDS b V + VGS +V DS – 3731 F05 – Figure 5. Gate Charge Characteristic 14 U stage and then plotting the gate voltage versus time. The initial slope is the effect of the gate-to-source and the gateto-drain capacitance. The flat portion of the curve is the result of the Miller multiplication effect of the drain-to-gate capacitance as the drain drops the voltage across the current source load. The upper sloping line is due to the drain-to-gate accumulation capacitance and the gate-tosource capacitance. The Miller charge (the increase in coulombs on the horizontal axis from a to b while the curve is flat) is specified for a given VDS drain voltage, but can be adjusted for different VDS voltages by multiplying by the ratio of the application VDS to the curve specified VDS values. A way to estimate the CMILLER term is to take the change in gate charge from points a and b on a manufacturers data sheet and divide by the stated VDS voltage specified. CMILLER is the most important selection criteria for determining the transition loss term in the top MOSFET but is not directly specified on MOSFET data sheets. CRSS and COS are specified sometimes but definitions of these parameters are not included. When the controller is operating in continuous mode the duty cycles for the top and bottom MOSFETs are given by: W UU Main Switch Duty Cycle = VOUT VIN ⎛V –V ⎞ Synchronous Switch Duty Cycle = ⎜ IN OUT ⎟ ⎝ ⎠ VIN The power dissipation for the main and synchronous MOSFETs at maximum output current are given by: V ⎛I ⎞ PMAIN = OUT ⎜ MAX ⎟ (1 + δ )RDS(ON) + VIN ⎝ N ⎠ I VIN2 MAX (RDR )(C MILLER ) • 2N ⎡ 1 1⎤ + ⎢ ⎥( f ) ⎣ VCC – VTH(IL) VTH(IL) ⎦ PSYNC = VIN – VOUT ⎛ IMAX ⎞ ⎜ ⎟ (1 + δ )RDS(ON) ⎝N⎠ VIN 2 2 3731fa LTC3731 APPLICATIO S I FOR ATIO where N is the number of output stages, δ is the temperature dependency of RDS(ON), RDR is the effective top driver resistance (approximately 2Ω at VGS = VMILLER), VIN is the drain potential and the change in drain potential in the particular application. VTH(IL) is the data sheet specified typical gate threshold voltage specified in the power MOSFET data sheet at the specified drain current. CMILLER is the calculated capacitance using the gate charge curve from the MOSFET data sheet and the technique described above. Both MOSFETs have I2R losses while the topside N-channel equation includes an additional term for transition losses, which peak at the highest input voltage. For VIN < 12V, the high current efficiency generally improves with larger MOSFETs, while for VIN > 12V, the transition losses rapidly increase to the point that the use of a higher RDS(ON) device with lower CMILLER actually provides higher efficiency. The synchronous MOSFET losses are greatest at high input voltage when the top switch duty factor is low or during a short circuit when the synchronous switch is on close to 100% of the period. The term (1 + δ ) is generally given for a MOSFET in the form of a normalized RDS(ON) vs temperature curve, but δ = 0.005/°C can be used as an approximation for low voltage MOSFETs. The Schottky diodes, D1 to D3 shown in Figure 1 conduct during the dead time between the conduction of the two large power MOSFETs. This prevents the body diode of the bottom MOSFET from turning on, storing charge during the dead time and requiring a reverse recovery period which could cost as much as several percent in efficiency. A 2A to 8A Schottky is generally a good compromise for both regions of operation due to the relatively small average current. Larger diodes result in additional transition loss due to their larger junction capacitance. CIN and COUT Selection In continuous mode, the source current of each top N-channel MOSFET is a square wave of duty cycle VOUT/VIN. A low ESR input capacitor sized for the maximum RMS current must be used. The details of a close form equation RMS INPUT RIPPLE CURRENT DC LOAD CURRENT U can be found in Application Note 77. Figure 6 shows the input capacitor ripple current for different phase configurations with the output voltage fixed and input voltage varied. The input ripple current is normalized against the DC output current. The graph can be used in place of tedious calculations. The minimum input ripple current can be achieved when the product of phase number and output voltage, N(VOUT), is approximately equal to the input voltage VIN or: W UU VOUT k = where k = 1, 2, ..., N – 1 VIN N So the phase number can be chosen to minimize the input capacitor size for the given input and output voltages. In the graph of Figure 4, the local maximum input RMS capacitor currents are reached when: VOUT 2k – 1 where k = 1, 2, ..., N = VIN N These worst-case conditions are commonly used for design because even significant deviations do not offer much relief. Note that capacitor manufacturer’s ripple current ratings are often based on only 2000 hours of life. This makes it advisable to further derate the capacitor or to choose a capacitor rated at a higher temperature than required. Several capacitors may also be paralleled to meet 0.6 0.5 0.4 0.3 0.2 0.1 0 1-PHASE 2-PHASE 3-PHASE 4-PHASE 6-PHASE 12-PHASE 0.1 0.2 0.3 0.4 0.5 0.6 0.7 DUTY FACTOR (VOUT/VIN) 0.8 0.9 3731 F06 Figure 6. Normalized Input RMS Ripple Current vs Duty Factor for One to Six Output Stages 3731fa 15 LTC3731 APPLICATIO S I FOR ATIO size or height requirements in the design. Always consult the capacitor manufacturer if there is any question. The Figure 6 graph shows that the peak RMS input current is reduced linearly, inversely proportional to the number N of stages used. It is important to note that the efficiency loss is proportional to the input RMS current squared and therefore a 3-stage implementation results in 90% less power loss when compared to a single phase design. Battery/input protection fuse resistance (if used), PC board trace and connector resistance losses are also reduced by the reduction of the input ripple current in a PolyPhase system. The required amount of input capacitance is further reduced by the factor, N, due to the effective increase in the frequency of the current pulses. Ceramic capacitors are becoming very popular for small designs but several cautions should be observed. “X7R”, “X5R” and “Y5V” are examples of a few of the ceramic materials used as the dielectric layer, and these different dielectrics have very different effect on the capacitance value due to the voltage and temperature conditions applied. Physically, if the capacitance value changes due to applied voltage change, there is a concommitant piezo effect which results in radiating sound! A load that draws varying current at an audible rate may cause an attendant varying input voltage on a ceramic capacitor, resulting in an audible signal. A secondary issue relates to the energy flowing back into a ceramic capacitor whose capacitance value is being reduced by the increasing charge. The voltage can increase at a considerably higher rate than the constant current being supplied because the capacitance value is decreasing as the voltage is increasing! Ceramic capacitors, when properly selected and used however, can provide the lowest overall loss due to their extremely low ESR. The selection of COUT is driven by the required effective series resistance (ESR). Typically once the ESR requirement is satisfied the capacitance is adequate for filtering. The steady-state output ripple (∆VOUT) is determined by: ⎛ 1⎞ ∆VOUT ≈ ∆IRIPPLE⎜ ESR + ⎟ ⎝ 8NfC OUT ⎠ 16 U where f = operating frequency of each stage, N is the number of output stages, COUT = output capacitance and ∆IL = ripple current in each inductor. The output ripple is highest at maximum input voltage since ∆IL increases with input voltage. The output ripple will be less than 50mV at max VIN with ∆IL = 0.4IOUT(MAX) assuming: COUT required ESR < N • RSENSE and COUT > 1/(8Nf)(RSENSE) The emergence of very low ESR capacitors in small, surface mount packages makes very small physical implementations possible. The ability to externally compensate the switching regulator loop using the ITH pin allows a much wider selection of output capacitor types. The impedance characteristics of each capacitor type is significantly different than an ideal capacitor and therefore requires accurate modeling or bench evaluation during design. Manufacturers such as Nichicon, United Chemicon and Sanyo should be considered for high performance throughhole capacitors. The OS-CON semiconductor dielectric capacitor available from Sanyo and the Panasonic SP surface mount types have a good (ESR)(size) product. Once the ESR requirement for COUT has been met, the RMS current rating generally far exceeds the IRIPPLE(P-P) requirement. Ceramic capacitors from AVX, Taiyo Yuden, Murata and Tokin offer high capacitance value and very low ESR, especially applicable for low output voltage applications. In surface mount applications, multiple capacitors may have to be paralleled to meet the ESR or RMS current handling requirements of the application. Aluminum electrolytic and dry tantalum capacitors are both available in surface mount configurations. New special polymer surface mount capacitors offer very low ESR also but have much lower capacitive density per unit volume. In the case of tantalum, it is critical that the capacitors are surge tested for use in switching power supplies. Several excellent choices are the AVX TPS, AVX TPSV, the KEMET T510 series of surface-mount tantalums or the Panasonic SP 3731fa W UU LTC3731 APPLICATIO S I FOR ATIO series of surface mount special polymer capacitors available in case heights ranging from 2mm to 4mm. Other capacitor types include Sanyo POS-CAP, Sanyo OS-CON, Nichicon PL series and Sprague 595D series. Consult the manufacturer for other specific recommendations. RSENSE Selection for Output Current Once the frequency and inductor have been chosen, RSENSE1, RSENSE2, RSENSE3 are determined based on the required peak inductor current. The current comparator has a typical maximum threshold of 75mV/RSENSE and an input common mode range of SGND to (1.1) • VCC. The current comparator threshold sets the peak inductor current, yielding a maximum average output current IMAX equal to the peak value less half the peak-to-peak ripple current, ∆IL. Allowing a margin for variations in the IC and external component values yields: 50mV RSENSE = N IMAX The IC works well with values of RSENSE from 0.002Ω to 0.02Ω. VCC Decoupling The VCC pin supplies power not only to the internal circuits of the controller but also to the top and bottom gate drivers on the LTC3731CUH and therefore must be bypassed very carefully to ground with a ceramic capacitor, type X7R or X5R (depending upon the operating temperature environment) of at least 1µF immediately next to the IC and preferably an additional 10µF placed very close to the IC due to the extremely high instantaneous currents involved. The total capacitance, taking into account the voltage coefficient of ceramic capacitors, should be 100 times as large as the total combined gate charge capacitance of ALL of the MOSFETs being driven. Good bypassing close to the IC is necessary to supply the high transient currents required by the MOSFET gate drivers while keeping the 5V supply quiet enough so as not to disturb the very small-signal high bandwidth of the current comparators. U Topside MOSFET Driver Supply (CB, DB) External bootstrap capacitors, CB, connected to the BOOST pins, supply the gate drive voltages for the topside MOSFETs. Capacitor CB in the Functional Diagram is charged though diode DB from VCC when the SW pin is low. When one of the topside MOSFETs turns on, the driver places the CB voltage across the gate-source of the desired MOSFET. This enhances the MOSFET and turns on the topside switch. The switch node voltage, SW, rises to VIN and the BOOST pin follows. With the topside MOSFET on, the boost voltage is above the input supply (VBOOST = VCC + VIN). The value of the boost capacitor CB needs to be 30 to 100 times that of the total gate charge capacitance of the topside MOSFET(s) as specified on the manufacturer’s data sheet. The reverse breakdown of DB must be greater than VIN(MAX). Differential Amplifier/Output Voltage Programming The IC has a true remote voltage sense capability. The sensing connections should be returned from the load, back to the differential amplifier’s inputs through a common, tightly coupled pair of PC traces. The differential amplifier rejects common mode signals capacitively or inductively radiated into the feedback PC traces as well as ground loop disturbances. The differential amplifier output signal is divided down with an external resistive divider and compared with the internal, precision 0.6V voltage reference by the error amplifier. The differential amplifier has a 0V to VCC common mode input range and an output swing range of 0V to VCC – 1.2V. The output uses an NPN emitter follower without any internal pull-down current. A DC resistive load to ground is required in order to sink current. The output voltage is set by an external resistive divider according to the following formula: ⎛ R1⎞ VOUT = 0.6V⎜ 1 + ⎟ ⎝ R2⎠ The resistive divider is connected to the output as shown in Figure 2, allowing remote voltage sensing. 3731fa W UU 17 LTC3731 APPLICATIO S I FOR ATIO Soft-Start/Run Function The RUN/SS pin provides three functions: 1) ON/OFF, 2) soft-start and 3) a defeatable short-circuit latch off timer. Soft-start reduces the input power sources’ surge currents by gradually increasing the controller’s current limit (proportional to an internal buffered and clamped VITH). The latchoff timer prevents very short, extreme load transients from tripping the overcurrent latch. A small pull-up current (>5µA) supplied to the RUN/SS pin will prevent the overcurrent latch from operating. A maximum pull-up current of 200µA is allowed into the RUN/SS pin even though the voltage at the pin may exceed the absolute maximum rating for the pin. This is a result of the limited current and the internal protection circuit on the pin. The following explanation describes how this function operates. An internal 1.5µA current source charges up the CSS capacitor. When the voltage on RUN/SS reaches 1.5V, the controller is permitted to start operating. As the voltage on RUN/SS increases from 1.5V to 3.5V, the internal current limit is increased from 20mV/RSENSE to 75mV/RSENSE. The output current limit ramps up slowly, taking an additional 1s/µF to reach full current. The output current thus ramps up slowly, eliminating the starting surge current required from the input power supply. If RUN/SS has been pulled all the way to ground, there is a delay before starting of approximately: tDELAY tIRAMP 1.5V = C SS = (1s/µF) C SS 1.5µA 3V − 1.5V C SS = (1s/µF) C SS = 1.5µA By pulling the RUN/SS controller pin below 0.4V the IC is put into low current shutdown (IQ < 100 µA). The RUN/SS pin can be driven directly from logic as shown in Figure7. Diode, D1, in Figure 7 reduces the start delay but allows CSS to ramp up slowly providing the soft-start function. VCC RUN/SS PIN 3.3V OR 5V RUN/SS PIN 5V D1 SHDN CSS SHDN CSS 3731 F07 RSS Figure 7. RUN/SS Pin Interfacing 18 U The RUN/SS pin has an internal 6V zener clamp (see the Functional Diagram). Fault Conditions: Overcurrent Latchoff The RUN/SS pins also provide the ability to latch off the controllers when an overcurrent condition is detected. The RUN/SS capacitor is used initially to turn on and limit the inrush current of all three output stages. After the controllers have been started and been given adequate time to charge up the output capacitor and provide full load current, the RUN/SS capacitor is used for a short-circuit timer. If the output voltage falls to less than 70% of its nominal value, the RUN/SS capacitor begins discharging on the assumption that the output is in an overcurrent condition. If the condition lasts for a long enough period, as determined by the size of the RUN/SS capacitor, the discharge current, and the circuit trip point, the controller will be shut down until the RUN/SS pin voltage is recycled. If the overload occurs during start-up, the time can be approximated by: tLO1 >> (CSS • 0.6V)/(1.5µA) = 4 • 105 (CSS) If the overload occurs after start-up, the voltage on the RUN/SS capacitor will continue charging and will provide additional time before latching off: tLO2 >> (CSS • 3V)/(1.5µA) = 2 • 106 (CSS) This built-in overcurrent latchoff can be overridden by providing a pull-up resistor to the RUN/SS pin from VCC as shown in Figure 7. When VCC is 5V, a 200k resistance will prevent the discharge of the RUN/SS capacitor during an overcurrent condition but also shortens the soft-start period, so a larger RUN/SS capacitor value may be required. Why should you defeat overcurrent latchoff? During the prototyping stage of a design, there may be a problem with noise pick-up or poor layout causing the protection circuit to latch off the controller. Defeating this feature allows troubleshooting of the circuit and PC layout. The internal foldback current limiting still remains active, thereby protecting the power supply system from failure. A decision can be made after the design is complete whether to rely solely on foldback current limiting or to enable the latchoff feature by removing the pull-up resistor. 3731fa W UU LTC3731 APPLICATIO S I FOR ATIO The value of the soft-start capacitor CSS may need to be scaled with output current, output capacitance and load current characteristics. The minimum soft-start capacitance is given by: CSS > (COUT )(VOUT) (10 –4) (RSENSE) The minimum recommended soft-start capacitor of CSS = 0.1µF will be sufficient for most applications. Current Foldback In certain applications, it may be desirable to defeat the internal current foldback function. A negative impedance is experienced when powering a switching regulator. That is, the input current is higher at a lower VIN and decreases as VIN is increased. Current foldback is designed to accommodate a normal, resistive load having increasing current draw with increasing voltage. The EAIN pin should be artificially held 70% above its nominal operating level of 0.6V, or 0.42V in order to prevent the IC from “folding back” the peak current level. A suggested circuit is shown in Figure 8. The emitter of Q1 will hold up the EAIN pin to a voltage in the absence of VOUT that will prevent the internal sensing circuitry from reducing the peak output current. Removing the function in this manner eliminates the external MOSFET’s protective feature under short-circuit conditions. This technique will also prevent the short-circuit latchoff function from turning off the part during a shortcircuit event and the peak output current will only be limited to N • 75mV/RSENSE. VCC VCC LTC3731 Q1 CALCULATE FOR 0.42V TO 0.55V EAIN 3731 F08 Figure 8. Foldback Current Elimination U Undervoltage Reset In the event that the input power source to the IC (VCC) drops below 4V, the RUN/SS capacitor will be discharged to ground. When VCC rises above 4V, the RUN/SS capacitor will be allowed to recharge and initiate another softstart turn-on attempt. This may be useful in applications that switch between two supplies that are not diode connected, but note that this cannot make up for the resultant interruption of the regulated output. Phase-Locked Loop and Frequency Synchronization The IC has a phase-locked loop comprised of an internal voltage controlled oscillator and phase detector. This allows the top MOSFET of output stage 1’s turn-on to be locked to the rising edge of an external source. The frequency range of the voltage controlled oscillator is ±50% around the center frequency fO. A voltage applied to the PLLFLTR pin of 1.2V corresponds to a frequency of approximately 400kHz. The nominal operating frequency range of the IC is 225kHz to 680kHz. The phase detector used is an edge sensitive digital type that provides zero degrees phase shift between the external and internal oscillators. This type of phase detector will not lock the internal oscillator to harmonics of the input frequency. The PLL hold-in range, ∆fH, is equal to the capture range, ∆fC: ∆fH = ∆fC = ±0.5 fO The output of the phase detector is a complementary pair of current sources charging or discharging the external filter components on the PLLFLTR pin. A simplified block diagram is shown in Figure 9. If the external frequency (fPLLIN) is greater than the oscillator frequency, fOSC, current is sourced continuously, pulling up the PLLFLTR pin. When the external frequency is less than fOSC, current is sunk continuously, pulling down the PLLFLTR pin. If the external and internal frequencies are the same, but exhibit a phase difference, the current sources turn on for an amount of time corresponding to the phase difference. Thus, the voltage on the 3731fa W UU 19 LTC3731 APPLICATIO S I FOR ATIO PHASE DETECTOR/ OSCILLATOR EXTERNAL OSC OSC 2.4V RLP 10k PLLFLTR PLLIN DIGITAL PHASE/ FREQUENCY DETECTOR 50k 3731 F09 Figure 9. Phase-Locked Loop Block Diagram PLLFLTR pin is adjusted until the phase and frequency of the external and internal oscillators are identical. At this stable operating point, the phase comparator output is open and the filter capacitor CLP holds the voltage. The IC PLLIN pin must be driven from a low impedance source such as a logic gate located close to the pin. When using multiple ICs for a phase-locked system, the PLLFLTR pin of the master oscillator should be biased at a voltage that will guarantee the slave oscillator(s) ability to lock onto the master’s frequency. A voltage of 1.7V or below applied to the master oscillator’s PLLFLTR pin is recommended in order to meet this requirement. The resultant operating frequency will be approximately 550kHz for 1.7V. The loop filter components (CLP, RLP) smooth out the current pulses from the phase detector and provide a stable input to the voltage controlled oscillator. The filter components CLP and RLP determine how fast the loop acquires lock. Typically RLP =10k and CLP ranges from 0.01µF to 0.1µF. Minimum On-Time Considerations Minimum on-time, tON(MIN), is the smallest time duration that the IC is capable of turning on the top MOSFET. It is determined by internal timing delays and the gate charge of the top MOSFET. Low duty cycle applications may approach this minimum on-time limit and care should be taken to ensure that: tON(MIN) < VOUT VIN ( f) 20 U CLP W UU If the duty cycle falls below what can be accommodated by the minimum on-time, the IC will begin to skip every other cycle, resulting in half-frequency operation. The output voltage will continue to be regulated, but the ripple current and ripple voltage will increase. The minimum on-time for the IC is generally about 110ns. However, as the peak sense voltage decreases the minimum on-time gradually increases. This is of particular concern in forced continuous applications with low ripple current at light loads. If the duty cycle drops below the minimum on-time limit in this situation, a significant amount of cycle skipping can occur with correspondingly larger current and voltage ripple. If an application can operate close to the minimum ontime limit, an inductor must be chosen that is low enough in value to provide sufficient ripple amplitude to meet the minimum on-time requirement. As a general rule, keep the inductor ripple current for each channel equal to or greater than 30% of IOUT(MAX) at VIN(MAX). Efficiency Considerations The percent efficiency of a switching regulator is equal to the output power divided by the input power times 100%. It is often useful to analyze individual losses to determine what is limiting the efficiency and which change would produce the most improvement. Percent efficiency can be expressed as: %Efficiency = 100% – (L1 + L2 + L3 + ...) where L1, L2, etc. are the individual losses as a percentage of input power. Checking Transient Response The regulator loop response can be checked by looking at the load transient response. Switching regulators take several cycles to respond to a step in DC (resistive) load current. When a load step occurs, VOUT shifts by an amount equal to ∆ILOAD • ESR, where ESR is the effective series resistance of COUT. ∆ILOAD also begins to charge or discharge COUT, generating the feedback error signal that forces the regulator to adapt to the current change and return VOUT to its steady-state value. During this recovery 3731fa LTC3731 APPLICATIO S I FOR ATIO time, VOUT can be monitored for excessive overshoot or ringing, which would indicate a stability problem. The availability of the ITH pin not only allows optimization of control loop behavior, but also provides a DC coupled and AC filtered closed-loop response test point. The DC step, rise time and settling at this test point truly reflects the closed-loop response. Assuming a predominantly second order system, phase margin and/or damping factor can be estimated using the percentage of overshoot seen at this pin. The bandwidth can also be estimated by examining the rise time at the pin. The ITH external components shown in the Figure 1 circuit will provide an adequate starting point for most applications. The ITH series RC-CC filter sets the dominant pole-zero loop compensation. The values can be modified slightly (from 0.2 to 5 times their suggested values) to maximize transient response once the final PC layout is done and the particular output capacitor type and value have been determined. The output capacitors need to be decided upon because the various types and values determine the loop feedback factor gain and phase. An output current pulse of 20% to 80% of full load current having a rise time of 1µF) supply bypass capacitors. The discharged bypass capacitors are effectively put in parallel with COUT, causing a rapid drop in VOUT. No regulator can alter its delivery of current quickly enough to prevent this sudden step change in output voltage if the load switch resistance is low and it is driven quickly. If CLOAD is greater than 2% of COUT , the switch rise time should be controlled so that the load rise time is limited to approximately 1000 • RSENSE • CLOAD. Thus a 250µF capacitor and a 2mΩ RSENSE resistor would require a 500µs rise time, limiting the charging current to about 1A. Automotive Considerations: Plugging into the Cigarette Lighter As battery-powered devices go mobile, there is a natural interest in plugging into the cigarette lighter in order to conserve or even recharge battery packs during operation. But before you connect, be advised: you are plugging into the supply from hell. The main battery line in an automobile is the source of a number of nasty potential transients, including load dump, reverse battery and double battery. Load dump is the result of a loose battery cable. When the cable breaks connection, the field collapse in the alternator can cause a positive spike as high as 60V which takes several hundred milliseconds to decay. Reverse battery is just what it says, while double battery is a consequence of tow-truck operators finding that a 24V jump start cranks cold engines faster than 12V. The network shown in Figure 10 is the most straightforward approach to protect a DC/DC converter from the ravages of an automotive battery line. The series diode prevents current from flowing during reverse battery, while the transient suppressor clamps the input voltage during load dump. Note that the transient suppressor should not conduct during double-battery operation, but must still clamp the input voltage below breakdown of the 3731fa W UU 21 LTC3731 APPLICATIO S I FOR ATIO VCC 5V + LTC3731 3731 F10 Figure 10. Automotive Application Protection converter. Although the IC has a maximum input voltage of 32V on the SW pins, most applications will be limited to 30V by the MOSFET BVDSS. Design Example As a design example, assume VCC = 5V, VIN = 12V(nominal), VIN = 20V(max), VOUT = 1.3V, IMAX = 45A and f = 400kHz. The inductance value is chosen first based upon a 30% ripple current assumption. The highest value of ripple current in each output stage occurs at the maximum input voltage. L= = VOUT ⎛ VOUT ⎞ ⎜ 1− ⎟ f( ∆I) ⎝ VIN ⎠ 1.3V ⎛ 1.3V ⎞ ⎜ 1− ⎟ (400kHz)(30%)(15A) ⎝ 20V ⎠ ≥ 0.68µH Using L = 0.6µH, a commonly available value results in 34% ripple current. The worst-case output ripple for the three stages operating in parallel will be less than 11% of the peak output current. RSENSE1, RSENSE2 and RSENSE3 can be calculated by using a conservative maximum sense current threshold of 65mV and taking into account half of the ripple current: RSENSE = 65mV = 0.0037Ω ⎛ 34%⎞ 15A⎜ 1 + ⎟ ⎝ 2⎠ 22 U VBAT 12V W UU Use a commonly available 0.003Ω sense resistor. Next verify the minimum on-time is not violated. The minimum on-time occurs at maximum VCC: tON(MIN) = VOUT VIN(MAX) ( f) = 1.3V = 162ns 20V(400kHz ) The output voltage will be set by the resistive divider from the DIFFOUT pin to SGND, R1 and R2 in the Functional Diagram. Set R1 = 13.3k and R2 = 11.3k. The power dissipation on the topside MOSFET can be estimated. Using a Fairchild FDS6688 for example, RDS(ON) = 7mΩ, CMILLER = 15nC/15V = 1000pF. At maximum input voltage with T(estimated) = 50°C: PMAIN ≈ 1.8V (15)2 1+ (0.005)(50°C − 25°C ) 20V 2 ⎛ 45A ⎞ 0.007Ω + (20) ⎜ ⎟ (2Ω)(1000pF ) ⎝ (2)(3) ⎠ [ ] 1 1⎞ ⎛ + ⎜ ⎟ (400kHz ) = 2.2W ⎝ 5V – 1.8V 1.8V ⎠ The worst-case power dissipation by the synchronous MOSFET under normal operating conditions at elevated ambient temperature and estimated 50°C junction temperature rise is: PSYNC = 20V − 1.3V (15A)2 (1.25)(0.007Ω) = 1.84W 20V A short circuit to ground will result in a folded back current of: ISC ≈ 25mV 1 ⎛ 150ns(20V ) ⎞ +⎜ = 7.5A (2 + 3)mΩ 2 ⎝ 0.6µH ⎟ ⎠ with a typical value of RDS(ON) and d = (0.005/°C)(50°C) = 0.25. The resulting power dissipated in the bottom MOSFET is: PSYNC = (7.5A)2(1.25)(0.007Ω) ≈ 0.5W 3731fa LTC3731 APPLICATIO S I FOR ATIO which is less than one third of the normal, full load conditions. Incidentally, since the load no longer dissipates any power, total system power is decreased by over 90%. Therefore, the system actually cools significantly during a shorted condition! SW1 D1 VIN SW2 RIN + CIN D2 COUT BOLD LINES INDICATE HIGH, SWITCHING CURRENT LINES. KEEP LINES TO A MINIMUM LENGTH SW3 Figure 11. Branch Current Waveforms U PC Board Layout Checklist When laying out the printed circuit board, the following checklist should be used to ensure proper operation of the IC. These items are also illustrated graphically in the layout diagram of Figure 11. Check the following in the PC layout: L1 RSENSE1 L2 RSENSE2 VOUT W UU + RL L3 RSENSE3 D3 3731 F11 3731fa 23 LTC3731 APPLICATIO S I FOR ATIO 1) Are the signal and power ground paths isolated? Keep the SGND at one end of a printed circuit path thus preventing MOSFET currents from traveling under the IC. The IC signal ground pin should be used to hook up all control circuitry on one side of the IC, routing the copper through SGND, under the IC covering the “shadow” of the package, connecting to the PGND pin and then continuing on to the (–) plates of CIN and COUT. The VCC decoupling capacitor should be placed immediately adjacent to the IC between the VCC pin and PGND. A 1µF ceramic capacitor of the X7R or X5R type is small enough to fit very close to the IC to minimize the ill effects of the large current pulses drawn to drive the bottom MOSFETs. An additional 5µF to 10µF of ceramic, tantalum or other very low ESR capacitance is recommended in order to keep the internal IC supply quiet. The power ground returns to the sources of the bottom N-channel MOSFETs, anodes of the Schottky diodes and (–) plates of CIN, which should have as short lead lengths as possible. 2) Does the IC IN+ pin connect to the (+) plates of COUT? A 30pF to 300pF feedforward capacitor between the IN+ and EAIN pins should be placed as close as possible to the IC. 3) Are the SENSE– and SENSE+ printed circuit traces for each channel routed together with minimum PC trace spacing? The filter capacitors between SENSE+ and SENSE– for each channel should be as close as possible to the pins of the IC. Connect the SENSE– and SENSE+ pins to the pads of the sense resistor as illustrated in Figure 12. 4) Do the (+) plates of CPWR connect to the drains of the topside MOSFETs as closely as possible? This capacitor provides the pulsed current to the MOSFETs. LTC3731 SENSE+ SENSE– 1000pF Figure 12. Kelvin Sensing RSENSE 3731fa 24 U 5) Keep the switching nodes, SWITCH, BOOST and TG away from sensitive small-signal nodes (SENSE+, SENSE –, IN +, IN –, EAIN). Ideally the SWITCH, BOOST and TG printed circuit traces should be routed away and separated from the IC and especially the “quiet” side of the IC. Separate the high dv/dt traces from sensitive smallsignal nodes with ground traces or ground planes. 6) Use a low impedance source such as a logic gate to drive the PLLIN pin and keep the lead as short as possible. 7) The 47pF to 330pF ceramic capacitor between the ITH pin and signal ground should be placed as close as possible to the IC. Figure 11 illustrates all branch currents in a three-phase switching regulator. It becomes very clear after studying the current waveforms why it is critical to keep the high switching current paths to a small physical size. High electric and magnetic fields will radiate from these “loops” just as radio stations transmit signals. The output capacitor ground should return to the negative terminal of the input capacitor and not share a common ground path with any switched current paths. The left half of the circuit gives rise to the “noise” generated by a switching regulator. The ground terminations of the synchronous MOSFETs and Schottky diodes should return to the bottom plate(s) of the input capacitor(s) with a short isolated PC trace since very high switched currents are present. A separate isolated path from the bottom plate(s) of the input and output capacitor(s) should be used to tie in the IC power ground pin (PGND). This technique keeps inherent signals generated by high current pulses taking alternate current paths that have finite impedances during the total period of the switching INDUCTOR SENSE RESISTOR 3731 F12b W UU OUTPUT CAPACITOR LTC3731 APPLICATIO S I FOR ATIO regulator. External OPTI-LOOP compensation allows overcompensation for PC layouts which are not optimized but this is not the recommended design procedure. Simplified Visual Explanation of How a 3-Phase Controller Reduces Both Input and Output RMS Ripple Current The effect of multiphase power supply design significantly reduces the amount of ripple current in both the input and output capacitors. The RMS input ripple current is divided by, and the effective ripple frequency is multiplied up by the number of phases used (assuming that the input voltage is greater than the number of phases used times the output voltage). The output ripple amplitude is also reduced by, and the effective ripple frequency is increased by the number of phases used. Figure 13 graphically illustrates the principle. The worst-case input RMS ripple current for a single stage design peaks at twice the value of the output voltage. The worst-case input RMS ripple current for a two stage design results in peaks at 1/4 and 3/4 of the input voltage, VSW ICIN ICOUT VSW1 VSW2 VSW3 IL1 IL2 IL3 ICIN ICOUT 3731 F13 Figure 13. Single and Polyphase Current Waveforms 3731fa U and the worst-case input RMS ripple current for a three stage design results in peaks at 1/6, 1/2, and 5/6 of the input voltage. The peaks, however, are at ever decreasing levels with the addition of more phases. A higher effective duty factor results because the duty factors “add” as long as the currents in each stage are balanced. Refer to AN19 for a detailed description of how to calculate RMS current for the single stage switching regulator. Figure 6 illustrates the RMS input current drawn from the input capacitance versus the duty cycle as determined by the ration of input and output voltage. The peak input RMS current level of the single phase system is reduced by 2/3 in a 3-phase solution due to the current splitting between the three stages. The output ripple current is reduced significantly when compared to the single phase solution using the same inductance value because the VOUT/L discharge currents term from the stages that has their bottom MOSFETs on subtract current from the (VCC – VOUT)/L charging current resulting from the stage which has its top MOSFET on. The SINGLE PHASE TRIPLE PHASE W UU 25 LTC3731 APPLICATIO S I FOR ATIO output ripple current for a 3-phase design is: IP-P = VOUT (1– 3DC ) VIN > 3VOUT ( f)(L) The ripple frequency is also increased by three, further reducing the required output capacitance when VCC < 3VOUT as illustrated in Figure 6. The addition of more phases by phase locking additional controllers, always results in no net input or output ripple at VOUT/VIN ratios equal to the number of stages implemented. Designing a system with multiple stages close to the VOUT/VIN ratio will significantly reduce the ripple voltage at the input and outputs and thereby improve efficiency, physical size and heat generation of the overall switching power supply. Refer to Application Note 77 for more information on Polyphase circuits. Efficiency Calculation To estimate efficiency, the DC loss terms include the input and output capacitor ESR, each MOSFET RDS(ON), inductor resistance RL, the sense resistance RSENSE and the forward drop of the Schottky rectifier at the operating output current and temperature. Typical values for the design example given previously in this data sheet are: Main MOSFET RDS(ON) = 7mΩ (9mΩ at 90°C) Sync MOSFET RDS(ON) = 7mΩ (9mΩ at 90°C) CINESR = 20mΩ COUTESR = 3mΩ RL = 2.5mΩ RSENSE = 3mΩ VSCHOTTKY = 0.8V at 15A (0.7V at 90°C) VOUT = 1.3V VIN = 12V 26 U IMAX = 45A δ = 0.5%°C (MOSFET temperature coefficient) N=3 f = 400kHz The main MOSFET is on for the duty factor VOUT/VIN and the synchronous MOSFET is on for the rest of the period or simply (1 – VOUT/VIN). Assuming the ripple current is small, the AC loss in the inductor can be made small if a good quality inductor is chosen. The average current, IOUT is used to simplify the calaculations. The equation below is not exact but should provide a good technique for the comparison of selected components and give a result that is within 10% to 20% of the final application. The temperature of the MOSFET’s die temperature may require interative calculations if one is not familiar typical performance. A maximum operating junction temperature of 90° to 100°C for the MOSFETs is recommended for high reliability applications. Common output path DC loss: ⎛I ⎞ PCOMPATH ≈ N⎜ MAX ⎟ (RL + RSENSE ) + C OUTESR Loss ⎝N⎠ 2 W UU This totals 3.7W + COUTESR loss. Total of all three main MOSFET’s DC loss: ⎛ V ⎞⎛I ⎞ PMAIN = N⎜ OUT ⎟ ⎜ MAX ⎟ (1 + δ )RDS(ON) + CINESR Loss ⎝N⎠ ⎝ VIN ⎠ 2 This totals 0.87W + CINESR loss (at 90°C). Total of all three synchronous MOSFET’s DC loss: PSYNC ⎛ V ⎞⎛I ⎞ = N⎜ 1 – OUT ⎟ ⎜ MAX ⎟ (1 + δ )RDS(ON) ⎝ VIN ⎠ ⎝ N ⎠ 2 This totals 7.2W at 90°C. Total of all three main MOSFET’s AC loss: 3731fa LTC3731 PACKAGE DESCRIPTIO )2 45A PMAIN ≈ 3(VIN (2Ω)(1000pF ) (2)(3) 1 1⎞ ⎛ + ⎜ ⎟ (400kHz) = 6.3 W ⎝ 5V – 1.8V 1.8V ⎠ This totals 1W at VIN = 8V, 2.25W at VIN = 12V and 6.25W at VIN = 20V. Total of all three synchronous MOSFET’s AC gate loss: (3)Q G VIN VDSSPEC (f) = (6)(15nC ) VIN VDSSPEC This totals 0.08W at VIN = 8V, 0.12W at VIN = 12V and 0.19W at VIN = 20V. The bottom MOSFET does not experience the Miller capacitance dissipation issue that the main switch does because the bottom switch turns on U when its drain is close to ground. The Schottky rectifier loss assuming 50ns nonoverlap time: 2 • 3(0.7V)(15A)(50ns)(4E5) This totals 1.26W. The total output power is (1.3V)(45A) = 58.5W and the total input power is approximately 60W so the % loss of each component is as follows: Main switch’s AC loss (VIN = 12V) 2.25W Main switch’s DC loss Synchronous switch AC loss Synchronous switch DC loss Power path loss 0.87W 0.19W 7.2W 3.7W 3.75% 1.5% 0.3% 12% 6.1% (4E5) The numbers above represent the values at VIN = 12V. It can be seen from this simple example that two things can be done to improve efficiency: 1) Use two MOSFETs on the synchronous side and 2) use a smaller MOSFET for the main switch with smaller CMILLER to better balance the AC loss with the DC loss. A smaller, less expensive MOSFET can actually perform better in the task of the main switch. 3731fa 27 LTC3731 TYPICAL APPLICATIO OPTIONAL FILTER FOR SYNCHRONIZATION 1000pF 0.01µF 1µF 10k VCC SYNC IN 300kHz 1 2 3 4 VCC PLLIN PLLFLTR FCB IN+ 100pF 300pF 6.04k 9.09k 5 6 7 8 9 S1 + LTC3731 BOOST2 IN– DIFFOUT EAIN SGND SENSE1+ SENSE1– SENSE2+ SENSE2– SENSE3– SENSE3+ RUN/SS ITH UVADJ TG2 SW2 VDR BG1 PGND BG2 BG3 SW3 TG3 BOOST3 PHASMD SGND 10 1000pF 11 12 13 14 15 16 ITH 17 S1– S2+ 1000pF S2– S3– 0.01µF 1000pF S3+ 330pF 3.3nF 2.2k VIN 18 18k 12k VIN: 3.3V TO 20V VOUT: 1.5V AT 65A SWITCHING FREQUENCY: 300kHz CIN: SANYO OS-CON 25SP68M COUT: 270µF/2V × 8 PANASONIC SP EEUE0D271R OR 470µF/2.5V ×6 SANYO POSCAP 2R5 TPD470M D1 TO D3: DIODES INC. B340A 28 U Figure 14. 3-Phase 65A Power Supply 10Ω 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 VCC 3731 TA01 VCC PGOOD NC 47k 1Ω M1 VCC 0.1µF VIN M3 1µF 10µF L2 D2 S2+ S2– 0.002Ω 10µF 25V ×5 VCC 5V TO 7V VIN L1 0.002Ω 10µF 6.3V ×3 CLK PGOOD BOOST1 TG1 SW1 0.1µF VOUT 1.5V AT 65A + COUT M2 D1 S1+ S1– + M4 VIN CIN 3.3V TO 20V 68µF 25V VIN 0.1µF M5 L3 D3 S3+ S3– 0.002Ω M6 L1 TO L3: 0.8µH SUMIDA CEP125-0R8 M1, M3, M5: IRF7821W × 2, Si7860DP OR HAT2168 × 2 M2, M4, M6: IRF7832 × 2, Si7892DP × 2 OR HAT2165 × 2 3731fa LTC3731 TYPICAL APPLICATIO SYNC IN 1k 68pF VCC 8.2k 3.3k VOUTS+ 4.7k 330pF S1+ S1– S2+ S2– S3– 0.1µF S3+ 1000pF 1000pF VOUTS– 15k 220pF VCC 1 2 3 4 5 6 7 DIFFOUT EAIN 10Ω×6 1000pF 8 9 10 11 12 13 14 15 16 RUN/SS 357k VIN 121k 100pF 1000pF 1000pF 0.01µF UVADJ VCC 10k CLK1 1 2 3 4 1000pF VOUTS+ VOUTS– DIFFOUT EAIN S4+ S4– S5+ S5– 270pF ITH S6– 100pF S6+ 1000pF 1000pF 10Ω×6 1000pF 10pF 5 6 7 8 9 10 11 12 13 14 15 16 RUN/SS 1.2k 2700pF UVADJ NOTES: V5: 5V TO 7V VIN: 10V TO 14V; VOUT: 2.5V/100A SWITCHING FREQUENCY: 500kHz (V5 = 5V) 17 18 VCC PLLIN PLLFLTR FCB IN+ CLKOUT PGOOD BOOST4 TG4 SW4 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 0.1µF X2 M17,18 D6 S6+ S6– M16 VIN L6 0.002Ω 1µF Cer. M13 0.1µF X2 M11,12 D4 0.1µF 10Ω M10 PGOOD CLKOUT BOOST4 BOOST5 VIN L4 0.002Ω BOOST6 VIN CIN V5 17 18 VCC PLLIN PLLFLTR FCB IN+ IN– CLKOUT PGOOD BOOST1 TG1 LTC3731 BOOST2 TG2 SW2 VDR BG1 PGND BG2 BG3 SW3 TG3 BOOST3 PHASMD SGND2 SW1 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 0.1µF VCC X2 M8,9 D3 S3+ S3– VOUT M7 VIN L3 0.002Ω 1µF Cer. M4 0.1µF X2 M2,3 D1 0.1µF CLK1 PGOOD 10k 1Ω M1 BOOST1 BOOST2 BOOST3 10µF 10µF Cer. 10V U Figure 15. 2.5V/100A Power Supply VCC 1µF 10Ω V5 + VIN L1 0.002Ω DIFFOUT EAIN SGND SENSE1+ SENSE1– SENSE2+ SENSE2– SENSE3– SENSE3+ RUN/SS ITH UVADJ S1+ S1– VIN L2 D2 S2+ S2– + 4.7µF X2 M5,6 0.002Ω + COUT + LTC3731 BOOST5 IN– DIFFOUT EAIN SGND SENSE4+ SENSE4– SENSE5+ SENSE5– SENSE6– SENSE6+ RUN/SS ITH UVADJ TG5 SW5 VDR BG4 PGND BG5 BG6 SW6 TG6 BOOST6 PHASMD SGND2 S4+ S4– VIN L5 D5 S5+ S5– + 4.7µF X2 M14,15 0.002Ω M1, M4, M7, M10, M13, M16: SILICONIX Si7390DP OR HAT2168 M2, M3, M5, M6, M8, M9, M11, M12, M14, M15, M17, M18: SILICONIX Si7356DP OR HAT2165 D1 TO D6: B320A L1 TO L6: TOKO FDH1040: 0.56µH CIN: 10µF/16V CERAMIC × 10 + 270µF/16V SANYO Os-Con COUT: 100µF/6.3V/X5R × 10 + 330µF/4V × 8 3731 F15 3731fa 29 LTC3731 PACKAGE DESCRIPTIO 7.8 – 8.2 0.42 ± 0.03 RECOMMENDED SOLDER PAD LAYOUT 5.00 – 5.60** (.197 – .221) 0.09 – 0.25 (.0035 – .010) 0.55 – 0.95 (.022 – .037) NOTE: 1. CONTROLLING DIMENSION: MILLIMETERS MILLIMETERS 2. DIMENSIONS ARE IN (INCHES) 3. DRAWING NOT TO SCALE *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED .152mm (.006") PER SIDE **DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE 30 U G Package 36-Lead Plastic SSOP (5.3mm) (Reference LTC DWG # 05-08-1640) 12.50 – 13.10* (.492 – .516) 1.25 ± 0.12 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 5.3 – 5.7 7.40 – 8.20 (.291 – .323) 0.65 BSC 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 2.0 (.079) MAX 0° – 8° 0.65 (.0256) BSC 0.22 – 0.38 (.009 – .015) TYP 0.05 (.002) MIN G36 SSOP 0204 3731fa LTC3731 PACKAGE DESCRIPTIO 5.50 ± 0.05 4.10 ± 0.05 3.45 ± 0.05 (4 SIDES) RECOMMENDED SOLDER PAD LAYOUT 5.00 ± 0.10 (4 SIDES) PIN 1 TOP MARK (NOTE 6) 0.75 ± 0.05 0.00 – 0.05 NOTE: 1. DRAWING PROPOSED TO BE A JEDEC PACKAGE OUTLINE M0-220 VARIATION WHHD-(X) (TO BE APPROVED) 2. DRAWING NOT TO SCALE 3. ALL DIMENSIONS ARE IN MILLIMETERS 4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE 5. EXPOSED PAD SHALL BE SOLDER PLATED 6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. U UH Package 32-Lead Plastic QFN (5mm × 5mm) (Reference LTC DWG # 05-08-1693) 0.70 ± 0.05 PACKAGE OUTLINE 0.25 ± 0.05 0.50 BSC BOTTOM VIEW—EXPOSED PAD R = 0.115 TYP 31 32 0.40 ± 0.10 1 2 0.23 TYP (4 SIDES) 3.45 ± 0.10 (4-SIDES) (UH) QFN 0603 0.200 REF 0.25 ± 0.05 0.50 BSC 3731fa 31 LTC3731 RELATED PARTS PART NUMBER LTC1628/LTC3728 LTC1629/LTC3729 LTC1702 LTC1703 LTC1708-PG LT®1709/ LT1709-8 LTC1735 LTC1736 LTC1778 LTC1929/ LTC1929-PG LTC3711 LTC3729 LTC3730 LTC3732 LTC3733 LTC3734/LTC3735 LTC3778 LTC3832 LTC4008 DESCRIPTION 2-Phase, Dual Output Synchronous Step-Down DC/DC Controllers 20A to 200A PolyPhase Synchronous Controllers No RSENSETM 2-Phase Dual Synchronous Step-Down Controller No RSENSE 2-Phase Dual Synchronous Step-Down Controller with 5-Bit Mobile VID Control 2-Phase, Dual Synchronous Controller with Mobile VID High Efficiency, 2-Phase Synchronous Step-Down Switching Regulators with 5-Bit VID High Efficiency, Synchronous Step-Down Switching Regulator High Efficiency, Synchronous Controller with 5-Bit Mobile VID Control No RSENSE Current Mode Synchronous Step-Down Controller 2-Phase Synchronous Controllers No RSENSE Current Mode Synchronous Step-Down Controller with Digital 5-Bit Interface 20A to 200A, 550kHz PolyPhase Synchronous Controller IMVP III 3-Phase Synchronous Controller VRM 9.0/9.1 3-Phase DC/DC Synchronous Step-Down Controller AMD Opteron™ CPU, DC/DC Synchronous Step-Down Controller Intel Pentium M (Centrino™) CPU, DC/DC Synchronous Step-Down Controller Optional RSENSE Current Mode Synchronous Step-Down Controller Low VIN High Power Synchronous Controller 4A Multichemistry Multicell Battery Charger COMMENTS Reduces CIN and COUT, Power Good Output Signal, Synchronizable, 3.5V ≤ VIN ≤ 36V, IOUT up to 20A, 0.8V ≤ VOUT ≤ 5V Expandable from 2-Phase to 12-Phase, Uses All Surface Mount Components, No Heat Sink, VIN up to 36V 550kHz, No Sense Resistor Mobile Pentium® III Processors, 550kHz, VIN ≤ 7V 3.5V ≤ VIN ≤ 36V, VID Sets VOUT1, PGOOD 1.3V ≤ VOUT ≤ 3.5V, Current Mode Ensures Accurate Current Sharing, 3.5V ≤ VIN ≤ 36V Output Fault Protection, 16-Pin SSOP Output Fault Protection, 24-Pin SSOP, 3.5V ≤ VIN ≤ 36V Up to 97% Efficiency, 4V ≤ VIN ≤ 36V, 0.8V ≤ VOUT ≤ (0.9)(VIN), IOUT up to 20A Up to 42A, Uses All Surface Mount Components, No Heat Sinks, 3.5V ≤ VIN ≤ 36V Up to 97% Efficiency, Ideal for Pentium III Processors, 0.925V ≤ VOUT ≤ 2V, 4V ≤ VIN ≤ 36V, IOUT up to 20A Expandable from 2-Phase to 12-Phase, Uses All Surface Mount Components, VIN up to 36V IOUT up to 60A, 0.6V ≤ VOUT ≤ 1.75V, Integrated MOSFET Drivers 1.1V ≤ VOUT ≤ 1.85V, 4.5V ≤ VIN ≤ 32V, SSOP-36 3-Phase Operation, up to 60A, 0.8V ≤ VOUT ≤ 1.55V 25A/40A, 4.5V ≤ VIN ≤ 36V 4V ≤ VIN ≤ 36V, Adjustable Frequency up to 1.2MHz, TSSOP-20 VOUT ≥ 0.6V, IOUT ≤ 20A, 3V ≤ VIN ≤ 8V NiCd, NiMH, Lead Acid, Li-Ion Batteries; 6V ≤ VIN ≤ 28V; 1.19V ≤ VOUT ≤ 28V No RSENSE is a trademark of Linear Technology Corporation. Pentium is a registered trademark of Intel Corporation. Centrino is a trademark of Intel Corporation. Opteron is a trademark of AMD Corporation. 3731fa 32 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● LT/TP 1204 1K • PRINTED IN USA www.linear.com © LINEAR TECHNOLOGY CORPORATION 2003
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