LTC3810-5 60V Current Mode Synchronous Switching Regulator Controller DESCRIPTION FEATURES n n n n n n n n n n n n n n n n The LTC®3810-5 is a synchronous step-down switching regulator controller that can directly step-down voltages from up to 60V, making it ideal for telecom and automotive applications. The LTC3810-5 uses a constant on-time valley current control architecture to deliver very low duty cycles with accurate cycle-by-cycle current limit, without requiring a sense resistor. High Voltage Operation: Up to 60V Large 1Ω Gate Drivers No Current Sense Resistor Required Dual N-Channel MOSFET Synchronous Drive Extremely Fast Transient Response ±0.5% 0.8V Voltage Reference Programmable Output Voltage Tracking/Soft-Start Generates 5.5V Driver Supply from Input Supply Synchronizable to External Clock Selectable Pulse Skip Mode Operation Power Good Output Voltage Monitor Adjustable On-Time/Frequency: tON(MIN) < 100ns Adjustable Cycle-by-Cycle Current Limit Programmable Undervoltage Lockout Output Overvoltage Protection Thermally Enhanced 32-Pin QFN Package A precise internal reference provides 0.5% DC accuracy. A high bandwidth (25MHz) error amplifier provides very fast line and load transient response. Large 1Ω gate drivers allow the LTC3810-5 to drive multiple MOSFETs for higher current applications. The operating frequency is selected by an external resistor and is compensated for variations in VIN and can also be synchronized to an external clock for switching-noise sensitive applications. A shutdown pin allows the LTC3810-5 to be turned off, reducing the supply current to 240μA. APPLICATIONS n n n Integrated bias control generates gate drive power from the input supply during start-up or when an output shortcircuit occurs, with the addition of a small external SOT23 MOSFET. When in regulation, power is derived from the output for higher efficiency. 48V Telecom and Base Station Power Supplies Networking Equipment, Servers Automotive and Industrial Control Systems L, LT, LTC and LTM are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. Protected by U.S. Patents, including 5481178, 5847554, 6304066, 6476589, 6580258, 6677210, 6774611. TYPICAL APPLICATION Efficiency vs Load Current High Efficiency High Voltage Step-Down Converter ION VRNG SS/TRACK SHDN 5pF BOOST Si7450DP TG 0.1μF 200k 10μH VOUT 12V/6A SW 95 VIN = 42V 90 EXTVCC DRVCC 14k INTVCC + MBR1100 SENSE+ ITH 270μF Si7450DP BG VFB 47pF VIN = 24V LTC3810-5 MODE/SYNC 1000pF 22μF ZXMN10A07F NDRV PGOOD + 100k 100 EFFICIENCY (%) 274k VIN 13V TO 60V 85 0 1 2 3 4 LOAD CURRENT (A) 5 6 38105 TA01b SGND SENSE– BGRTN 1μF 1k 38105 TA01 38105fc 1 LTC3810-5 ABSOLUTE MAXIMUM RATINGS PIN CONFIGURATION (Note 1) SW TG BOOST NC NC NC ION NC TOP VIEW 32 31 30 29 28 27 26 25 24 SENSE+ NC 1 VON 2 23 NC VRNG 3 22 NC PGOOD 4 21 NC 33 MODE/SYNC 5 20 SENSE– ITH 6 19 BGRTN VFB 7 18 BG PLL/LPF 8 17 DRVCC INTVCC EXTVCC NDRV UVIN SHDN NC NC 9 10 11 12 13 14 15 16 SS/TRACK Supply Voltages INTVCC, DRVCC....................................... –0.3V to 14V (DRVCC – BGRTN), (BOOST – SW) ........ –0.3V to 14V BOOST (Continuous) ............................. –0.3V to 85V BOOST (≤400ms) .................................. –0.3V to 95V BGRTN ........................................................ –5V to 0V EXTVCC .................................................. –0.3V to 15V (EXTVCC – INTVCC).................................. –12V to 12V (NDRV – INTVCC) Voltage........................... –0.3V to 10V SW, SENSE+ Voltage (Continuous) ................ –1V to 70V SW, SENSE+ Voltage (400ms) ....................... –1V to 80V ION Voltage (Continuous) ........................... –0.3V to 70V ION Voltage (400ms) .................................. –0.3V to 80V SS/TRACK Voltage ....................................... –0.3V to 5V PGOOD Voltage ............................................ –0.3V to 7V VRNG, VON, MODE/SYNC, SHDN, UVIN Voltages ............................................ –0.3V to 14V PLL/LPF, FB Voltages................................. –0.3V to 2.7V TG, BG, INTVCC, EXTVCC RMS Currents .................50mA Operating Temperature Range (Note 2) LTC3810E-5 ......................................... –40°C to 85°C LTC3810I-5 ........................................ –40°C to 125°C Junction Temperature (Notes 3, 7)........................ 125°C Storage Temperature Range................... –65°C to 125°C UH PACKAGE 32-LEAD (5mm × 5mm) PLASTIC QFN TJMAX = 125°C, θJA = 34°C/W EXPOSED PAD (PIN 33) IS SGND, MUST BE SOLDERED TO PCB ORDER INFORMATION LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE LTC3810EUH-5#PBF LTC3810EUH-5#TRPBF 38105 32-Lead (5mm × 5mm) Plastic QFN –40°C to 85°C LTC3810IUH-5#PBF LTC3810IUH-5#TRPBF 38105 32-Lead (5mm × 5mm) Plastic QFN –40°C to 125°C LEAD BASED FINISH TAPE AND REEL PART MARKING PACKAGE DESCRIPTION TEMPERATURE RANGE LTC3810EUH-5 LTC3810EUH-5#TR 38105 32-Lead (5mm × 5mm) Plastic QFN –40°C to 85°C LTC3810IUH-5 LTC3810IUH-5#TR 38105 32-Lead (5mm × 5mm) Plastic QFN –40°C to 125°C Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container. For more information on lead free part marking, go to: http://www.linear.com/leadfree/ For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/ 38105fc 2 LTC3810-5 ELECTRICAL CHARACTERISTICS The l denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C, INTVCC = DRVCC = VBOOST = VON = VRNG = SHDN = UVIN = VEXTVCC = VNDRV = 5V, VMODE/SYNC = VSENSE+ = VSENSE – = VBGRTN = VSW = 0V, unless otherwise specified. SYMBOL Main Control Loop INTVCC IQ PARAMETER IBOOST INTVCC Supply Voltage INTVCC Supply Current INTVCC Shutdown Current BOOST Supply Current VFB Feedback Voltage ΔVFB,LINE VSENSE(MAX) Feedback Voltage Line Regulation Maximum Current Sense Threshold VSENSE(MIN) Minimum Current Sense Threshold IVFB AVOL(EA) fU Feedback Current Error Amplifier DC Open Loop Gain Error Amp Unity-Gain Crossover Frequency MODE/SYNC Threshold MODE/SYNC Current Shutdown Threshold SHDN Pin Input Current UVIN Undervoltage Lockout VMODE/SYNC IMODE/SYNC VSHDN ISHDN VUVIN VVCCUV INTVCC Undervoltage Lockout Linear Regulator Mode External Supply Mode Trickle-Charge Mode Oscillator and Phase-Locked Loop tON On-Time tON(MIN) tOFF(MIN) tON(PLL) IPLL/LPF Driver IBG,PEAK RBG,SINK ITG,PEAK RTG,SINK Minimum On-Time Minimum Off-Time tON Modulation Range by PLL Down Modulation Up Modulation Phase Detector Output Current Sinking Capability Sourcing Capability BG Driver Peak Source Current BG Driver Pull-Down RDS(ON) TG Driver Peak Source Current TG Driver Pull-Down RDS(ON) CONDITIONS MIN l SHDN > 1.5V (Notes 4, 5) SHDN = 0V SHDN > 1.5V (Note 5) SHDN = 0V (Note 4) 0°C to 85°C –40°C to 85°C –40°C to 125°C (I-Grade) 5V < INTVCC < 14V (Note 4) VRNG = 2V, VFB = 0.76V VRNG = 0V, VFB = 0.76V VRNG = INTVCC, VFB = 0.76V VRNG = 2V, VFB = 0.84V VRNG = 0V, VFB = 0.84V VRNG = INTVCC, VFB = 0.84V VFB = 0.8V l l l 4.35 0.796 0.794 0.792 0.792 l 256 70 170 65 (Note 6) VMODE/SYNC Rising MODE/SYNC = 5V TYP 0.75 1.2 3 240 270 0 0.800 0.800 0.800 0.800 0.002 320 95 215 –300 –85 –200 20 100 25 MAX UNITS 14 6 600 400 5 0.804 0.806 0.806 0.808 0.02 384 120 260 V mA μA μA μA V V V V %/V mV mV mV mV mV mV nA dB MHz 150 0.8 0 1.5 0 0.89 0.80 0.10 0.85 1 2 1 0.92 0.82 0.12 V μA V μA V V V UVIN Rising UVIN Falling Hysteresis l l 0.86 0.78 0.07 INTVCC Rising, INDRV = 100μA INTVCC Rising, NDRV = INTVCC = EXTVCC INTVCC Rising, NDRV = INTVCC, EXTVCC = 0 INTVCC Falling l l l 4.05 4.05 8.70 4.2 4.2 9 3.7 4.35 4.35 9.30 V V V V 1.55 515 1.85 605 250 2.15 695 100 350 μs ns ns ns 3.6 1.2 5 1.8 μs μs ION = 100μA ION = 300μA ION = 2000μA ION = 100μA, VPLL/LPF = 0.6V ION = 100μA, VPLL/LPF = 1.8V 2.2 0.6 fPLLIN < fSW fPLLIN > fSW VBG = 0V 0.7 VTG – VSW = 0 0.7 15 –25 μA μA 1 1 1 1 A Ω A Ω 1.5 1.5 38105fc 3 LTC3810-5 ELECTRICAL CHARACTERISTICS The l denotes specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C, INTVCC = DRVCC = VBOOST = VON = VRNG = SHDN = UVIN = VEXTVCC = VNDRV = 5V, VMODE/SYNC = VSENSE+ = VSENSE– = VBGRTN = VSW = 0V, unless otherwise specified. SYMBOL PGOOD Output ΔVFBOV ΔVFB,HYST VPGOOD IPGOOD PG Delay Tracking ISS/TRACK VFB,TRACK VCC Regulators VEXTVCC VINTVCC,1 ΔVEXTVCC,1 ΔVLOADREG,1 VINTVCC,2 ΔVLOADREG,2 INDRV INDRVTO VCCSR ICCSR PARAMETER CONDITIONS MIN TYP MAX UNITS PGOOD Upper Threshold PGOOD Lower Threshold PGOOD Hysterisis PGOOD Low Voltage PGOOD Leakage Current PGOOD Delay VFB Rising VFB Falling VFB Returning IPGOOD = 5mA VPGOOD = 5V VFB Falling 7.5 –7.5 10 –10 1.5 0.3 0 120 12.5 –12.5 3 0.6 2 % % % V μA μs SS/TRACK Source Current Feedback Voltage at Tracking VSS/TRACK > 0.5V VTRACK = 0V, ITH = 1.2V (Note 4) VTRACK = 0.5V, ITH = 1.2V (Note 4) 0.7 1.4 –0.018 0.5 2.5 μA V V EXTVCC Switchover Voltage EXTVCC Rising EXTVCC Hysterisis INTVCC Voltage from EXTVCC VEXTVCC - VINTVCC at Dropout INTVCC Load Regulation from EXTVCC INTVCC Voltage from NDRV Regulator INTVCC Load Regulation from NDRV Current into NDRV Pin Linear Regulator Timeout Enable Threshold Maximum Supply Voltage Maximum Current into NDRV/INTVCC 0.48 l 4.45 0.1 5.2 6V < VEXTVCC < 15V ICC = 20mA, VEXTVCC = 5V ICC = 0mA to 20mA, VEXTVCC = 10V Linear Regulator in Operation ICC = 0mA to 20mA, VEXTVCC = 0 VNDRV – VINTVCC = 3V 5.2 20 210 Trickle Charger Shunt Regulator Trickle Charger Shunt Regulator, INTVCC ≤ 16.7V (Note 8) Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Note 2: The LTC3810E-5 is guaranteed to meet performance specifications from 0°C to 85°C. Specifications over the –40°C to 85°C operating temperature range are assured by design, characterization and correlation with statistical process controls. The LTC3810I-5 is guaranteed to meet performance specifications over the full –40°C to 125°C operating temperature range. Note 3: TJ is calculated from the ambient temperature TA and power dissipation PD according to the following formula: LTC3810-5: TJ = TA + (PD • 34°C/W) 15 10 LTC3810 LTC3810-5 LTC3812-5 Maximum VIN 100V 60V 60V MOSFET Gate Drive 6.35V to 14V 4.5V to 14V 4.5V to 14V UV+ 6.2V 4.2V 4.2V 6V 4V 4V INTVCC UV– 0.4 5.8 150 5.8 60 350 V V V mV % V % μA μA V mA Note 4: The LTC3810-5 is tested in a feedback loop that servos VFB to the reference voltage with the ITH pin forced to a voltage between 1V and 2V. Note 5: The dynamic input supply current is higher due to the power MOSFET gate charging being delivered at the switching frequency (QG • fOSC). Note 6: Guaranteed by design. Not subject to test. Note 7: 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. Note 8: ICC is the sum of current into NDRV and INTVCC. PARAMETER INTVCC 4.7 0.25 5.5 75 0.01 5.5 0.01 40 270 0.52 38105fc 4 LTC3810-5 TYPICAL PERFORMANCE CHARACTERISTICS Load Transient Response Short-Circuit/ Fault Timeout Operation Start-Up INTVCC 5V/DIV VOUT 100mV/DIV VOUT 5V/DIV SS/TRACK 4V/DIV VIN 50V/DIV IOUT 5A/DIV IL 5A/DIV IL 5A/DIV 38105 G01 50μs/DIV VIN = 48V 0A TO 5A LOADSTEP FRONT PAGE CIRCUIT Pulse Skip Mode Operation VOUT SS/TRACK 100mV/DIV VOUT 5V/DIV VFB 0.5V/DIV SS/TRACK 0.5V/DIV VFB 0.5V/DIV IL 5A/DIV IL 5A/DIV 38105 G04 200μs/DIV VIN = 48V FRONT PAGE CIRCUIT Efficiency vs Input Voltage ITH 0.5V/DIV VFB IL 2A/DIV 38105 G05 500μs/DIV VIN = 48V ILOAD = 1A MODE/SYNC = 0V FRONT PAGE CIRCUIT Frequency vs Input Voltage 280 100 IOUT = 5A 95 IOUT = 0.5A 80 20 50 40 30 60 INPUT VOLTAGE (V) 80 38105 G07 VIN = 60V 270 85 80 70 70 VIN = 36V 90 VOUT = 5V Si7850 MOSFETs MODE/SYNC = INTVCC f = 250kHz 75 VOUT = 12V Si7852 MOSFETs f = 250kHz 10 VIN = 12V FREQUENCY (kHz) EFFICIENCY (%) 90 38105 G06 20μs/DIV VIN = 48V IOUT = 100mA MODE/SYNC = INTVCC FRONT PAGE CIRCUIT Efficiency vs Load Current 100 38105 G03 10ms/DIV VIN = 48V RSHORT = 0.1Ω FRONT PAGE CIRCUIT Tracking VOUT 5V/DIV EFFICIENCY (%) 38105 G02 500μs/DIV VIN = 48V ILOAD = 1A MODE/SYNC = 0V FRONT PAGE CIRCUIT Short-Circuit/ Foldback Operation 70 VOUT 10V/DIV INTVCC 0 1 5 2 3 4 LOAD CURRENT (A) 6 IOUT = 0A 260 IOUT = 5A 250 240 7 38105 G08 230 MODE/SYNC = 0V FRONT PAGE CIRCUIT 10 20 50 40 30 60 INPUT VOLTAGE (V) 70 80 38105 G09 38105fc 5 LTC3810-5 TYPICAL PERFORMANCE CHARACTERISTICS Current Sense Threshold vs ITH Voltage 400 300 300 FORCED CONTINUOUS 250 200 150 PULSE SKIP 100 50 0 1 2 3 5 4 VRNG = 2V 1V 0.7V 0.5V 100 –100 100 –200 –300 –400 0 0.5 1.0 2.0 1.5 ITH VOLTAGE (V) On-Time vs VON Voltage 600 660 ON-TIME (ns) ON-TIME (ns) 500 300 640 620 580 100 ION = 300μA 2 1.5 1 VON VOLTAGE (V) 2.5 560 –50 –25 3 ION = 300μA 50 25 75 0 TEMPERATURE (°C) Maximum Current Sense Threshold vs VRNG Voltage 200 100 1.5 150 100 50 0 2 VRNG VOLTAGE (V) 38105 G16 VRNG = INTVCC 0 0.2 0.4 0.6 38105 G15 Reference Voltage vs Temperature 230 0.803 220 0.802 210 200 190 180 –50 0.8 VFB (V) REFERENCE VOLTAGE (V) MAXIMUM CURRENT SENSE THRESHOLD (mV) 300 1 125 200 Maximum Current Sense Threshold vs Temperature 400 0 0.5 100 250 38105 G14 38105 G13 10000 Current Limit Foldback 600 200 0.5 100 1000 ION CURRENT (μA) 38105 G12 On-Time vs Temperature 680 0 10 38105 G11 700 0 10 3.0 2.5 38105 G10 MAXIMUM CURRENT SENSE THRESHOLD (mV) 1000 0 LOAD CURRENT (A) 400 VON = INTVCC 1.4V 200 MAXIMUM CURRENT SENSE THRESHOLD (mV) 0 On-Time vs ION Current 10000 ON-TIME (ns) 350 CURRENT SENSE THRESHOLD (mV) FREQUENCY (kHz) Frequency vs Load Current 0.801 0.800 0.799 0.798 VRNG = INTVCC –25 50 25 0 75 TEMPERATURE (°C) 100 125 38105 G17 0.797 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 125 38105 G18 38105fc 6 LTC3810-5 TYPICAL PERFORMANCE CHARACTERISTICS Driver Peak Source Current vs Temperature 1.75 VBOOST = VINTVCC = 5V Driver Peak Source Current vs Supply Voltage 3.0 VBOOST = VINTVCC = 5V PEAK SOURCE CURRENT (A) 1.50 1.25 RDS(ON) (Ω) PEAK SOURCE CURRENT (A) 1.5 Driver Pull-Down RDS(ON) vs Temperature 1.0 1.00 0.75 0.50 0.5 –50 –25 0 25 50 75 TEMPERATURE (°C) 100 2.0 1.5 1.0 0.5 0.25 –50 –25 125 2.5 50 25 75 0 TEMPERATURE (°C) 100 38105 G19 0 125 4 5 6 7 8 9 10 11 12 13 14 DRVCC/BOOST VOLTAGE (V) 38105 G20 38105 G21 EXTVCC LDO Resistance at Dropout vs Temperature Driver Pull-Down RDS(ON) vs Supply Voltage 1.1 INTVCC Current vs Temperature 4 7 6 0.8 INTVCC CURRENT (mA) RESISTANCE (Ω) 0.9 5 4 3 2 0.7 3 2 1 1 4 5 6 7 8 9 10 11 12 13 14 DRVCC/BOOST VOLTAGE (V) 0 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 INTVCC Shutdown Current vs Temperature 400 125 0 –50 –25 50 25 0 75 TEMPERATURE (°C) 100 125 38105 G24 38105 G23 38105 G22 INTVCC Current vs INTVCC Voltage 3.5 INTVCC = 5V 3.0 300 INTVCC CURRENT (mA) 0.6 INTVCC CURRENT (μA) RDS(ON) (Ω) 1.0 200 100 2.5 2.0 1.5 1.0 0.5 0 –50 –25 0 75 50 25 TEMPERATURE (°C) 0 100 125 38105 G25 0 2 8 6 10 4 INTVCC VOLTAGE (V) 12 14 38105 G26 38105fc 7 LTC3810-5 TYPICAL PERFORMANCE CHARACTERISTICS INTVCC Shutdown Current vs INTVCC Voltage SS/TRACK Pull-Up Current vs Temperature 3 300 SS/TRACK CURRENT (μA) INTVCC CURRENT (μA) 250 200 150 100 2 1 50 0 –50 –25 0 0 2 8 6 10 4 INTVCC VOLTAGE (V) 12 14 50 25 75 0 TEMPERATURE (°C) 125 38105 G28 38105 G27 ITH Voltage vs Load Current Shutdown Threshold vs Temperature 2.2 3.0 2.0 SHUTDOWN THRESHOLD (V) 2.5 ITH VOLTAGE (V) 100 2.0 1.5 1.0 0.5 0 1 4 3 5 2 LOAD CURRENT (A) 6 1.6 1.4 1.2 1.0 0.8 VRNG = 1V FRONT PAGE CIRCUIT 0 1.8 7 38105 G29 0.6 –50 –25 75 50 25 TEMPERATURE (°C) 0 100 125 38105 G30 38105fc 8 LTC3810-5 PIN FUNCTIONS VON (Pin 2): On-Time Voltage Input. Voltage trip point for the on-time comparator. Tying this pin to the output voltage or to an external resistive divider from the output makes the on-time proportional to VOUT. The comparator defaults to 0.7V when the pin is grounded and defaults to 2.4V when the pin is connected to INTVCC. Tie this pin to INTVCC in high VOUT applications to use a lower RON value. VRNG (Pin 3): Sense Voltage Limit Set. The voltage at this pin sets the nominal sense voltage at maximum output current and can be set from 0.5V to 2V by a resistive divider from INTVCC. The nominal sense voltage defaults to 95mV when this pin is tied to ground, and 215mV when tied to INTVCC. PGOOD (Pin 4): Power Good Output. Open-drain logic output that is pulled to ground when the output voltage is not between ±10% of the regulation point. The output voltage must be out of regulation for at least 120μs before the power good output is pulled to ground. MODE/SYNC (Pin 5): Pulse Skip Mode Enable/Sync Pin. This multifunction pin provides pulse skip mode enable/ disable control and an external clock input to the phase detector. Pulling this pin below 0.8V or to an external logic-level synchronization signal disables pulse skip mode operation and forces continuous operation. Pulling this pin above 0.8V enables pulse skip mode operation. For a clock input, the phase-locked loop will force the rising top gate signal to be synchronized with the rising edge of the clock signal.This pin can also be connected to a feedback resistor divider from a secondary winding on the inductor to regulate a second output voltage. ITH (Pin 6): Error Amplifier Compensation Point and Current Control Threshold. The current comparator threshold increases with this control voltage. The voltage ranges from 0V to 2.6V with 1.2V corresponding to zero sense voltage (zero current). VFB (Pin 7): Feedback Input. Connect VFB through a resistor divider network to VOUT to set the output voltage. PLL/LPF (Pin 8): The phase-locked loop’s lowpass filter is tied to this pin. The voltage at this pin defaults to 1.2V when the IC is not synchronized with an external clock at the MODE/SYNC pin. SS/TRACK (Pin 9): Soft-Start/Tracking Input. For soft-start, a capacitor to ground at this pin sets the ramp rate of the output voltage (approximately 0.6s/μF). For coincident or ratiometric tracking, connect this pin to a resistive divider between the voltage to be tracked and ground. SHDN (Pin 12): Shutdown Pin. Pulling this pin below 1.5V will shut down the LTC3810-5, turn off both of the external MOSFET switches and reduce the quiescent supply current to 240μA. UVIN (Pin 13): UVLO Input. This pin is input to the internal UVLO and is compared to an internal 0.8V reference. An external resistor divider is connected to this pin and the input supply to program the undervoltage lockout voltage. When UVIN is less than 0.8V, the LTC3810-5 is shut down. NDRV (Pin 14): Drive Output for External Pass Device of the Linear Regulator for INTVCC. Connect to the gate of an external NMOS pass device and a pull-up resistor to the input voltage VIN. EXTVCC (Pin 15): External Driver Supply Voltage. When this voltage exceeds 4.7V, an internal switch connects this pin to INTVCC through an LDO and turns off the exter nal MOSFET connected to NDRV, so that controller and gate drive are drawn from EXTVCC. INTVCC (Pin 16): Main Supply Pin. All internal circuits except the output drivers are powered from this pin. INTVCC should be bypassed to ground (Pin 10) with at least a 0.1μF capacitor in close proximity to the LTC3810-5. DRVCC (Pin 17): Driver Supply Pin. DRVCC supplies power to the BG output driver. This pin is normally connected to INTVCC. DRVCC should be bypassed to BGRTN (Pin 20) with a low ESR (X5R or better) 1μF-10μF capacitor in close proximity to the LTC3810-5. 38105fc 9 LTC3810-5 PIN FUNCTIONS BG (Pin 18): Bottom Gate Drive. The BG pin drives the gate of the bottom N-channel synchronous switch MOSFET. This pin swings from BGRTN to DRVCC. BGRTN (Pin 19): Bottom Gate Return. This pin connects to the source of the pulldown MOSFET in the BG driver and is normally connected to ground. Connecting a negative supply to this pin allows the synchronous MOSFET ’s gate to be pulled below ground to help prevent false turn-on during high dV/dt transitions on the SW node. See the Applications Information section for more details. SENSE+, SENSE– (Pin 24, Pin 20): Current Sense Comparator Input. The (+) input to the current comparator is normally connected to SW unless using a sense resistor. The (–) input is used to accurately kelvin sense the bottom side of the sense resistor or MOSFET. SW (Pin 25): Switch Node Connection to Inductor and Bootstrap Capacitor. The voltage swing at this pin is –0.7V (a Schottky diode (external) voltage drop) to VIN. TG (Pin 26): Top Gate Drive. The TG pin drives the gate of the top N-channel synchronous switch MOSFET. The TG driver draws power from the BOOST pin and returns to the SW pin, providing true floating drive to the top MOSFET. BOOST (Pin 27): Top Gate Driver Supply. The BOOST pin supplies power to the floating TG driver. BOOST should be bypassed to SW with a low ESR (X5R or better) 0.1μF capacitor. An additional fast recovery Schottky diode from DRVCC to the BOOST pin will create a complete floating charge-pumped supply at BOOST. ION (Pin 31): On-Time Current Input. Tie a resistor from VIN to this pin to set the one-shot timer current and thereby set the switching frequency. SGND (Pin 33): Signal Ground. All small-signal components should connect to this ground and eventually connect to PGND at one point. 38105fc 10 LTC3810-5 FUNCTIONAL DIAGRAM EXTVCC NDRV INTVCC INTVCC 0.8V REF 5V REG VIN INTVCC MODE LOGIC 5.5V + NDRV M3 14 VIN – 9V RUV1 UVIN + – 13 INTVCC INTVCC UV VIN UV RUV2 OFF 4.2V + 16 – EXTVCC 15 + 0.8V MODE/SYNC – 5 + F 270μA – 5.5V + ON 1.4μA PLL-SYNC 8 + – PLL/LPF + VON – tON = 31 VVON (76pF) IION DRV OFF R S Q TG FCNT + ICMP CB M1 26 SW SENSE+ SWITCH LOGIC IREV L1 24 VOUT DRVCC – – 17 SHDN BG OV × CVCC 18 M2 BGRTN + 19 COUT SENSE– 1.4V 20 OVERTEMP SENSE VRNG PGOOD ITH’ 3 CIN 27 25 20k + + BOOST ON 4 FOLDBACK RFB1 FB 0.7V + ITH 0.72V UV 6 – 2.6V VFB 4V 7 CC2 RC CC1 EA + FAULT RUN SHDN – – + + RON ION 4.7V TIMEOUT LOGIC 100nA VIN VIN DB 2 + RFB2 SGND 12 OV – 0.88V 1.5V 0.8V SS/TRACK 9 SHDN 12 38105 FD 38105fc 11 LTC3810-5 OPERATION Main Control Loop The LTC3810-5 is a current mode controller for DC/DC step-down converters. In normal operation, the top MOSFET is turned on for a fixed interval determined by a one-shot timer (OST). When the top MOSFET is turned off, the bottom MOSFET is turned on until the current comparator ICMP trips, restarting the one-shot timer and initiating the next cycle. Inductor current is determined by sensing the voltage between the SENSE– and SENSE+ pins using a sense resistor or the bottom MOSFET onresistance. The voltage on the ITH pin sets the comparator threshold corresponding to the inductor valley current. The fast 25MHz error amplifier EA adjusts this voltage by comparing the feedback signal VFB to the internal 0.8V reference voltage. If the load current increases, it causes a drop in the feedback voltage relative to the reference. The ITH voltage then rises until the average inductor current again matches the load current. The operating frequency is determined implicitly by the top MOSFET on-time and the duty cycle required to maintain regulation. The one-shot timer generates an on time that is proportional to the ideal duty cycle, thus holding frequency approximately constant with changes in VIN. The nominal frequency can be adjusted with an external resistor RON. For applications with stringent constant frequency requirements, the LTC3810-5 can be synchronized with an external clock. By programming the nominal frequency the same as the external clock frequency, the LTC3810-5 PULSE SKIP MODE behaves as a constant frequency part against the load and supply variations. Pulling the SHDN pin low forces the controller into its shutdown state, turning off both M1 and M2. Forcing a voltage above 1.5V will turn on the device. Pulse Skip Mode The LTC3810-5 can operate in one of two modes selectable with the MODE/SYNC pin—pulse skip mode or forced continuous mode (see Figure 1). Pulse skip mode is selected when increased efficiency at light loads is desired (see Figure 2). In this mode, the bottom MOSFET is turned off when inductor current reverses to minimize efficiency loss due to reverse current flow and gate charge switching. At low load currents, ITH will drop below the zero current level (1.2V) shutting off both switches. Both switches will remain off with the output capacitor supplying the load current until the ITH voltage rises above the zero current level to initiate another cycle. In this mode, frequency is proportional to load current at light loads. Pulse skip mode operation is disabled by comparator F when the MODE/SYNC pin is brought below 0.8V, forcing continuous synchronous operation. Forced continuous mode is less efficient due to resistive losses, but has the advantage of better transient response at low currents, approximately constant frequency operation, and the ability to maintain regulation when sinking current. FORCED CONTINUOUS 100 90 PULSE SKIP 80 0A EFFICIENCY (%) 0A DECREASING LOAD CURRENT 0A 0A 70 FORCED CONTINUOUS 60 50 40 30 20 VIN = 12V VIN = 42V 10 0A 0 0.01 0A 38105 F01 0.1 1 10 LOAD (A) 38105 F02 Figure 1. Comparison of Inductor Current Waveforms for Pulse Skip Mode and Forced Continuous Operation Figure 2. Efficiency in Pulse Skip/ Forced Continuous Modes 38105fc 12 LTC3810-5 OPERATION Fault Monitoring/Protection Constant on-time current mode architecture provides accurate cycle-by-cycle current limit protection—a feature that is very important for protecting the high voltage power supply from output short circuits. The cycle-by-cycle current monitor guarantees that the inductor current will never exceed the value programmed on the VRNG pin. Foldback current limiting provides further protection if the output is shorted to ground. As VFB drops, the buffered current threshold voltage ITHB is pulled down and clamped to 1V. This reduces the inductor valley current level to one-sixth of its maximum value as VFB approaches 0V. Foldback current limiting is disabled at start-up. Overvoltage and undervoltage comparators OV and UV pull the PGOOD output low if the output feedback voltage exits a ±10% window around the regulation point after the internal 120μs power bad mask timer expires. Furthermore, in an overvoltage condition, M1 is turned off and M2 is turned on immediately and held on until the overvoltage condition clears. The LTC3810-5 provides two undervoltage lockout comparators—one for the INTVCC/DRVCC supply and one for the input supply VIN. The INTVCC UV threshold is 4.2V to guarantee that the MOSFETs have sufficient gate drive voltage before turning on. The VIN UV threshold (UVIN pin) is 0.8V with 10% hysteresis which allows programming the VIN threshold with the appropriate resistor divider connected to VIN. If either comparator inputs are under the UV threshold, the LTC3810-5 is shut down and the drivers are turned off. Strong Gate Drivers The LTC3810-5 contains very low impedance drivers capable of supplying amps of current to slew large MOSFET gates quickly. This minimizes transition losses and allows paralleling MOSFETs for higher current applications. A 60V floating high side driver drives the top side MOSFET and a low side driver drives the bottom side MOSFET (see Figure 3). The bottom side driver is supplied directly from the DRVCC pin. The top MOSFET drivers are biased from floating bootstrap capacitor, CB, which normally is recharged during each off cycle through an external diode from DRVCC when the top MOSFET turns off. In pulse skip mode operation, where it is possible that the bottom MOSFET will be off for an extended period of time, an internal timeout guarantees that the bottom MOSFET is turned on at least once every 25μs for one on-time period to refresh the bootstrap capacitor. The bottom driver has an additional feature that helps minimize the possibility of external MOSFET shoot-through. When the top MOSFET turns on, the switch node dV/dt pulls up the bottom MOSFET’s internal gate through the Miller capacitance, even when the bottom driver is holding the gate terminal at ground. If the gate is pulled up high enough, shoot-through between the top side and bottom side MOSFETs can occur. To prevent this from occurring, the bottom driver return is brought out as a separate pin (BGRTN) so that a negative supply can be used to reduce the effect of the Miller pull-up. For example, if a –2V supply is used on BGRTN, the switch node dV/dt could pull the gate up 2V before the VGS of the bottom MOSFET has more than 0V across it. VIN DRVCC LTC3810-5 DRVCC + DB CIN BOOST TG CB M1 L SW BG VOUT M2 + COUT BGRTN 38105 F03 0V TO –5V Figure 3. Floating TG Driver Supply and Negative BG Return IC/Driver Supply Power The LTC3810-5’s internal control circuitry and top and bottom MOSFET drivers operate from a supply voltage (INTVCC, DRVCC pins) in the range of 4.5V to 14V. The LTC3810-5 has two integrated linear regulator controllers to easily generate this IC/driver supply from either the high voltage input or from the output voltage. For best efficiency the supply is derived from the input voltage during start-up and then derived from the lower voltage output as soon as the output is higher than 4.7V. Alternatively, the supply can be derived from the input continuously if the output is 38105fc 13 LTC3810-5 OPERATION <4.7V or an external supply in the appropriate range can be used. The LTC3810-5 will automatically detect which mode is being used and operate properly. The four possible operating modes for generating this supply are summarized as follows (see Figure 4): 1. LTC3810-5 generates a 5.5V start-up supply from a small external SOT23 N-channel MOSFET acting as linear regulator with drain connected to VIN and gate controlled by the LTC3810-5’s internal linear regulator controller through the NDRV pin. As soon as the output voltage reaches 4.7V, the 5.5V IC/driver supply is derived from the output through an internal low-dropout regulator to optimize efficiency. If the output is lost due to a short, the LTC3810-5 goes through repeated low duty cycle soft-start cycles (with the drivers shut off in between) to attempt to bring up the output without burning up the SOT23 MOSFET. This scheme eliminates the long start-up times associated with a conventional trickle charger by using an external MOSFET to quickly charge the IC/driver supply capacitors (CINTVCC, CDRVCC). start-up. The MOSFET is sized for proper dissipation and the driver shutdown/restart for VOUT < 4.7V is disabled. This scheme is less efficient but may be necessary if VOUT < 4.7V and a boost network is not desired. 3. Trickle charge mode provides an even simpler approach by eliminating the external MOSFET. The IC/driver supply capacitors are charged through a single high-valued resistor connected to the input supply. When the INTVCC voltage reaches the turn-on threshold of 9V (automatically raised from 4.7V to provide extra headroom for start-up), the drivers turn on and begin charging up the output capacitor. When the output reaches 4.7V, IC/driver power is derived from the output. In trickle-charge mode, the supply capacitors must have sufficient capacitance such that they are not discharged below the 4V INTVCC UV threshold before the output is high enough to take over or else the power supply will not start. 4. Low voltage supply available. The simplest approach is if a low voltage supply (between 4.5V and 14V) is available and connected directly to the IC/driver supply pins. 2. Similar to (1) except that the external MOSFET is used for continuous IC/driver power instead of just for Mode 1: MOSFET for Start-Up Only Mode 2: MOSFET for Continuous Use VIN VIN I > 270μA I < 270μA NDRV NDRV INTVCC + 5.5V LTC3810-5 INTVCC + 5.5V LTC3810-5 VOUT (> 4.7V) EXTVCC Mode 3: Trickle Charge Mode VIN EXTVCC Mode 4: External Supply NDRV INTVCC NDRV + LTC3810-5 EXTVCC 5.5V INTVCC LTC3810-5 VOUT + + – 4.5V to 14V EXTVCC 38105 F04 Figure 4. Operating Modes for IC/Driver Supply 38105fc 14 LTC3810-5 APPLICATIONS INFORMATION The basic LTC3810-5 application circuit is shown on the first page of this data sheet. External component selection is primarily determined by the maximum input voltage and load current and begins with the selection of the sense resistance and power MOSFET switches. The LTC3810-5 uses either a sense resistor or the on-resistance of the synchronous power MOSFET for determining the inductor current. The desired amount of ripple current and operating frequency largely determines the inductor value. Next, CIN is selected for its ability to handle the large RMS current into the converter and COUT is chosen with low enough ESR to meet the output voltage ripple and transient specification. Finally, loop compensation components are selected to meet the required transient/phase margin specifications. Maximum Sense Voltage and VRNG Pin Inductor current is determined by measuring the voltage across a sense resistance that appears between the SENSE– and SENSE+ pins. The maximum sense voltage is set by the voltage applied to the VRNG pin and is equal to approximately: VSENSE(MAX) = 0.173VRNG – 0.026 The current mode control loop will not allow the inductor current valleys to exceed VSENSE(MAX)/RSENSE. In practice, one should allow some margin for variations in the LTC3810-5 and external component values and a good guide for selecting the sense resistance is: RSENSE = VSENSE(MAX) 1.3 •IOUT(MAX) the sense resistor. Using a sense resistor provides a well defined current limit, but adds cost and reduces efficiency. Alternatively, one can eliminate the sense resistor and use the bottom MOSFET as the current sense element by simply connecting the SENSE+ pin to the lower MOSFET drain and SENSE – pin to the MOSFET source. This improves efficiency, but one must carefully choose the MOSFET on-resistance, as discussed below. Power MOSFET Selection The LTC3810-5 requires two external N-channel power MOSFETs, one for the top (main) switch and one for the bottom (synchronous) switch. Important parameters for the power MOSFETs are the breakdown voltage BVDSS, threshold voltage V(GS)TH, on-resistance RDS(ON), input capacitance and maximum current IDS(MAX). When the bottom MOSFET is used as the current sense element, particular attention must be paid to its on-resistance. MOSFET on-resistance is typically specified with a maximum value RDS(ON)(MAX) at 25°C. In this case, additional margin is required to accommodate the rise in MOSFET on-resistance with temperature: RDS(ON)(MAX) = RSENSE ρT The ρT term is a normalization factor (unity at 25°C) accounting for the significant variation in on-resistance with temperature (see Figure 5) and typically varies from 0.4%/°C to 1.0%/°C depending on the particular MOSFET used. An external resistive divider from INTVCC can be used to set the voltage of the VRNG pin between 0.5V and 2V resulting in nominal sense voltages of 60mV to 320mV. Additionally, the VRNG pin can be tied to SGND or INTVCC in which case the nominal sense voltage defaults to 95mV or 215mV, respectively. Connecting the SENSE+ and SENSE– Pins The LTC3810-5 can be used with or without a sense resistor. When using a sense resistor, place it between the source of the bottom MOSFET, M2 and PGND. Connect the SENSE+ and SENSE– pins to the top and bottom of ρT NORMALIZED ON-RESISTANCE 2.0 1.5 1.0 0.5 0 –50 50 100 0 JUNCTION TEMPERATURE (°C) 150 38105 F05 Figure 5. RDS(ON) vs Temperature 38105fc 15 LTC3810-5 APPLICATIONS INFORMATION The most important parameter in high voltage applications is breakdown voltage BVDSS. Both the top and bottom MOSFETs will see full input voltage plus any additional ringing on the switch node across its drain-to-source during its off-time and must be chosen with the appropriate breakdown specification. The LTC3810-5 is designed to be used with a 4.5V to 14V gate drive supply (DRVCC pin) for driving logic-level MOSFETs (VGS(MIN) ≥ 4.5V). For maximum efficiency, on-resistance RDS(ON) and input capacitance should be minimized. Low RDS(ON) minimizes conduction losses and low input capacitance minimizes transition losses. 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 6). VIN VGS MILLER EFFECT a V b QIN CMILLER = (QB – QA)/VDS + VGS +V DS – – 38105 F06 Figure 6. Gate Charge Characteristic The curve is generated by forcing a constant input current into the gate of a common source, current source loaded stage and then plotting the gate voltage versus time. The initial slope is the effect of the gate-to-source and the gate-to-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-to-source 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: Main Switch Duty Cycle = VOUT VIN Synchronous Switch Duty Cycle = VIN – VOUT VIN The power dissipation for the main and synchronous MOSFETs at maximum output current are given by: VOUT 2 IMAX ) (T )RDS(ON) + ( VIN I VIN2 MAX (RDR )(CMILLER ) • 2 1 1 + (f) VCC – VTH(IL) VTH(IL) V –V PBOT = IN OUT (IMAX )2(T )RDS(0N) VIN PTOP = where ρT 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 incudes an additional term for transition losses, which peak at the highest input voltage. For high input voltage low duty cycle applications that are typical for the LTC3810-5, transition losses are the dominate loss term and therefore using higher RDS(ON) device with lower CMILLER usually provides the highest 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. Since there is no transition loss 38105fc 16 LTC3810-5 APPLICATIONS INFORMATION term in the synchronous MOSFET, optimal efficiency is obtained by minimizing RDS(ON)—by using larger MOSFETs or paralleling multiple MOSFETs. Multiple MOSFETs can be used in parallel to lower RDS(ON) and meet the current and thermal requirements if desired. The LTC3810-5 contains large low impedance drivers capable of driving large gate capacitances without significantly slowing transition times. In fact, when driving MOSFETs with very low gate charge, it is sometimes helpful to slow down the drivers by adding small gate resistors (10Ω or less) to reduce noise and EMI caused by the fast transitions. Operating Frequency The choice of operating frequency is a tradeoff between efficiency and component size. Low frequency operation improves efficiency by reducing MOSFET switching losses but requires larger inductance and/or capacitance in order to maintain low output ripple voltage. The operating frequency of LTC3810-5 applications is determined implicitly by the one-shot timer that controls the on-time, tON, of the top MOSFET switch. The on-time is set by the current out of the ION pin and the voltage at the VON pin according to: tON = VVON (76pF) IION 1000 Tying a resistor RON from VIN to the ION pin yields an on-time inversely proportional to VIN. For a step-down converter, this results in approximately constant frequency operation as the input supply varies: f= VOUT [H ] VVON • RON (76pF) Z To hold frequency constant during output voltage changes, tie the VON pin to VOUT or to a resistive divider from VOUT when VOUT > 2.4V. The VON pin has internal clamps that limit its input to the one-shot timer. If the pin is tied below 0.7V, the input to the one-shot is clamped at 0.7V. Similarly, if the pin is tied above 2.4V, the input is clamped at 2.4V. In high VOUT applications, tie VON to INTVCC. Figures 7a and 7b show how RON relates to switching frequency for several common output voltages. Changes in the load current magnitude will cause frequency shift. Parasitic resistance in the MOSFET switches and inductor reduce the effective voltage across the inductance, resulting in increased duty cycle as the load current increases. By lengthening the on-time slightly as current increases, constant frequency operation can be maintained. This is accomplished with a resistive divider from the ITH pin to the VON pin and VOUT. The values required will depend on the parasitic resistances in the specific application. A good starting point is to feed about 25% of the voltage change at the ITH pin to the VON pin as shown in Figure 8. Place capacitance on the VON pin to filter out the ITH variations at the switching frequency. 1000 VOUT = 3.3V VOUT = 1.5V VOUT = 2.5V 100 SWITCHING FREQUENCY (kHz) SWITCHING FREQUENCY (kHz) VOUT = 5V VOUT = 12V VOUT = 5V VOUT = 3.3V 100 10 100 RON (kΩ) 1000 38105 F07a Figure 7a. Switching Frequency vs RON (VON = 0V) 10 100 RON (kΩ) 1000 38105 F07b Figure 7b. Switching Frequency vs RON (VON = INTVCC) 38105fc 17 LTC3810-5 APPLICATIONS INFORMATION Inductor Selection INTVCC 5.5V RVON1 100k VON RVON2 30k CVON 0.01μF 100k LTC3810-5 ITH 38105 F08 Given the desired input and output voltages, the inductor value and operating frequency determine the ripple current: V V IL = OUT 1 OUT VIN f L Figure 8. Correcting Frequency Shift with Load Current Changes Minimum Off-Time and Dropout Operation The minimum off-time tOFF(MIN) is the smallest amount of time that the LTC3810-5 is capable of turning on the bottom MOSFET, tripping the current comparator and turning the MOSFET back off. This time is generally about 250ns. The minimum off-time limit imposes a maximum duty cycle of tON/(tON + tOFF(MIN)). If the maximum duty cycle is reached, due to a dropping input voltage for example, then the output will drop out of regulation. The minimum input voltage to avoid dropout is: VIN(MIN) = VOUT A reasonable starting point is to choose a ripple current that is about 40% of IOUT(MAX). The largest ripple current occurs at the highest VIN. To guarantee that ripple current does not exceed a specified maximum, the inductance should be chosen according to: V VOUT OUT 1 L= f IL(MAX) VIN(MAX) tON + tOFF(MIN) tON A plot of maximum duty cycle vs frequency is shown in Figure 9. 2.0 SWITCHING FREQUENCY (MHz) Lower ripple current reduces core losses in the inductor, ESR losses in the output capacitors and output voltage ripple. Highest efficiency operation is obtained at low frequency with small ripple current. However, achieving this requires a large inductor. There is a tradeoff between component size, efficiency and operating frequency. 1.5 DROPOUT REGION 1.0 Once the value for L is known, 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 more expensive ferrite, molypermalloy or Kool Mμ® cores. A variety of inductors designed for high current, low voltage applications are available from manufacturers such as Sumida, Panasonic, Coiltronics, Coilcraft and Toko. Schottky Diode D1 Selection 0.5 0 0 0.25 0.50 0.75 DUTY CYCLE (VOUT/VIN) 1.0 38105 F09 Figure 9. Maximum Switching Frequency vs Duty Cycle The Schottky diode D1 shown in the front page schematic conducts during the dead time between the conduction of the power MOSFET switches. It is intended to prevent the body diode of the bottom MOSFET from turning on and storing charge during the dead time, which can cause a modest (about 1%) efficiency loss. The diode can be rated for about one-half to one-fifth of the full load current since it is on for only a fraction of the duty cycle. In order for the diode to be effective, the inductance between it and the 38105fc 18 LTC3810-5 APPLICATIONS INFORMATION bottom MOSFET must be as small as possible, mandating that these components be placed adjacently. The diode can be omitted if the efficiency loss is tolerable. Input Capacitor Selection % IRMS,ALUM ≈ In continuous mode, the drain current of the top MOSFET is approximately a square wave of duty cycle VOUT/VIN which must be supplied by the input capacitor. To prevent large input transients, a low ESR input capacitor sized for the maximum RMS current is given by: V V ICIN(RMS) IO(MAX) OUT IN – 1 VIN VOUT by the aluminum capacitors alone, when used together, the percentage of RMS current that will be supplied by the aluminum capacitor is reduced to approximately: 1/2 This formula has a maximum at VIN = 2VOUT, where IRMS = IO(MAX)/2. This simple worst-case condition is commonly used for design because even significant deviations do not offer much relief. Note that the ripple current ratings from capacitor manufacturers 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 placed in parallel to meet size or height requirements in the design. Because tantalum and OS-CON capacitors are not available in voltages above 30V, ceramics or aluminum electrolytics must be used for regulators with input supplies above 30V. Ceramic capacitors have the advantage of very low ESR and can handle high RMS current, but ceramics with high voltage ratings (> 50V) are not available with more than a few microfarads of capacitance. Furthermore, ceramics have high voltage coefficients which means that the capacitance values decrease even more when used at the rated voltage. X5R and X7R type ceramics are recommended for their lower voltage and temperature coefficients. Another consideration when using ceramics is their high Q which, if not properly damped, may result in excessive voltage stress on the power MOSFETs. Aluminum electrolytics have much higher bulk capacitance, but they have higher ESR and lower RMS current ratings. A good approach is to use a combination of aluminum electrolytics for bulk capacitance and ceramics for low ESR and RMS current. If the RMS current cannot be handled 1 1+ (8fCRESR )2 • 100% where RESR is the ESR of the aluminum capacitor and C is the overall capacitance of the ceramic capacitors. Using an aluminum electrolytic with a ceramic also helps damp the high Q of the ceramic, minimizing ringing. Output Capacitor Selection The selection of COUT is primarily determined by the ESR required to minimize voltage ripple. The output ripple (ΔVOUT) is approximately equal to: 1 VOUT IL ESR + 8fCOUT Since ΔIL increases with input voltage, the output ripple is highest at maximum input voltage. ESR also has a significant effect on the load transient response. Fast load transitions at the output will appear as voltage across the ESR of COUT until the feedback loop in the LTC3810-5 can change the inductor current to match the new load current value. Typically, once the ESR requirement is satisfied the capacitance is adequate for filtering and has the required RMS current rating. Manufacturers such as Nichicon, Nippon Chemi-Con and Sanyo should be considered for high performance throughhole capacitors. The OS-CON (organic semiconductor dielectric) capacitor available from Sanyo has the lowest product of ESR and size of any aluminum electrolytic at a somewhat higher price. An additional ceramic capacitor in parallel with OS-CON capacitors is recommended to reduce the effect of their lead inductance. In surface mount applications, multiple capacitors placed in parallel may be required to meet the ESR, RMS current handling and load step requirements. Dry tantalum, special polymer and aluminum electrolytic capacitors are available in surface mount packages. Special polymer capacitors offer very low ESR but have lower capacitance density 38105fc 19 LTC3810-5 APPLICATIONS INFORMATION than other types. Tantalum capacitors have the highest capacitance density but it is important to only use types that have been surge tested for use in switching power supplies. Several excellent surge-tested choices are the AVX, TPS and TPSV or the KEMET T510 series. Aluminum electrolytic capacitors have significantly higher ESR, but can be used in cost-driven applications providing that consideration is given to ripple current ratings and long term reliability. Other capacitor types include Panasonic SP and Sanyo POSCAPs. Output Voltage The LTC3810-5 output voltage is set by a resistor divider according to the following formula: R VOUT = 0.8V 1+ FB1 RFB2 The external resistor divider is connected to the output as shown in the Functional Diagram, allowing remote voltage sensing. The resultant feedback signal is compared with the internal precision 800mV voltage reference by the error amplifier. The internal reference has a guaranteed tolerance of less than ±1%. Tolerance of the feedback resistors will add additional error to the output voltage. 0.1% to 1% resistors are recommended. Input Voltage Undervoltage Lockout A resistor divider connected from the input supply to the UVIN pin (see Functional Diagram) is used to program the input supply undervoltage lockout thresholds. When the rising voltage at UVIN reaches 0.88V the LTC3810 turns on, and when the falling voltage at UVIN drops below 0.8V, the LTC3810 is shut down—providing 10% hysterisis. The input voltage UVLO thresholds are set by the resistor divider according to the following formulas: VIN,FALLING = 0.8V (1 + RUV1/RUV2) and VIN,RISING = 0.88V (1 + RUV1/RUV2) If input supply undervoltage lockout is not needed, it can be disabled by connecting UVIN to INTVCC. Top MOSFET Driver Supply (CB, DB) An external bootstrap capacitor, CB, connected to the BOOST pin supplies the gate drive voltage for the topside MOSFET. This capacitor is charged through diode DB from DRVCC when the switch node is low. When the top MOSFET turns on, the switch node rises to VIN and the BOOST pin rises to approximately VIN + INTVCC. The boost capacitor needs to store about 100 times the gate charge required by the top MOSFET. In most applications 0.1μF to 0.47μF , X5R or X7R dielectric capacitor is adequate. The reverse breakdown of the external diode, DB, must be greater than VIN(MAX). Another important consideration for the external diode is the reverse recovery and reverse leakage, either of which may cause excessive reverse current to flow at full reverse voltage. If the reverse current times reverse voltage exceeds the maximum allowable power dissipation, the diode may be damaged. For best results, use an ultrafast recovery diode such as the MMDL770T1. Bottom MOSFET Driver Return Supply (BGRTN) The bottom gate driver, BG, switches from DRVCC to BGRTN where BGRTN can be a voltage between ground and –5V. Why not just keep it simple and always connect BGRTN to ground? In high voltage switching converters, the switch node dV/dt can be many volts/ns, which will pull up on the gate of the bottom MOSFET through its Miller capacitance. If this Miller current, times the internal gate resistance of the MOSFET plus the driver resistance, exceeds the threshold of the FET, shoot-through will occur. By using a negative supply on BGRTN, the BG can be pulled below ground when turning the bottom MOSFET off. This provides a few extra volts of margin before the gate reaches the turn-on threshold of the MOSFET. Be aware that the maximum voltage difference between DRVCC and BGRTN is 14V. If, for example, VBGRTN = –2V, the maximum voltage on DRVCC pin is now 12V instead of 14V. IC/MOSFET Driver Supplies (INTVCC and DRVCC) The LTC3810-5 drivers are supplied from the DRVCC and BOOST pins (see Figure 2), which have an absolute maximum voltage of 14V. Since the main supply voltage, 38105fc 20 LTC3810-5 APPLICATIONS INFORMATION VIN is typically much higher than 14V a separate supply for the IC power (INTVCC) and driver power (DRVCC) must be used. The LTC3810-5 has integrated bias supply control circuitry that allows the IC/driver supply to be easily generated from VIN and/or VOUT with minimal external components. There are four ways to do this as shown in the simplified schematics of Figure 3 and explained in the following sections. current INDRV is greater than 270μA by using the following formulas: Using the Linear Regulator for INTVCC/DRVCC Supply and VTH is the threshold voltage of the MOSFET. In Mode 1, a small external SOT23 MOSFET, controlled by the NDRV pin, is used to generate a 5.5V start-up supply from VIN. The small SOT23 package can be used because the NMOS is on continuously only during the brief start-up period. As soon as the output voltage reaches 4.7V, the LTC3810-5 turns off the external NMOS and the LTC3810-5 regulates the 5.5V supply from the EXTVCC pin (connected to VOUT or a VOUT derived boost network) through an internal low dropout regulator. For this mode to work properly, EXTVCC must be in the range 4.7V < EXTVCC < 15V. If VOUT < 4.7V, a charge pump or extra winding can be used to raise EXTVCC to the proper voltage, or alternatively, Mode 2 should be used as explained later in this section. If VOUT is shorted or otherwise goes below the minimum 4.5V threshold, the MOSFET connected to VIN is turned back on to maintain the 5.5V supply. However if the output cannot be brought up within a timeout period, the drivers are turned off to prevent the SOT23 MOSFET from overheating. Soft-start cycles are then attempted at low duty cycle intervals to try to bring the output back up (see Figure 10). This fault timeout operation is enabled by choosing the choosing RNDRV such that the resistor The value of RNDRV also affects the VIN(MIN) as follows: FAULT TIMEOUT ENABLED SS/TRACK RNDRV ≤ PMOSFET(MAX) / ICC − VTH 270μA where ( ) ICC = (f) QG(TOP) + QG(BOTTOM) + 3mA VIN(MIN) = VINTVCC(MIN) + (40μA) RNDRV +VT (1) where VINTVCC(MIN) is normally 4.5V for driving logic-level MOSFETs. If minimum VIN is not low enough, consider reducing RNDRV and/or using a Darlington NPN instead of an NMOS to reduce VT to ~1.4V. When using RNDRV equal to the computed value, the LTC3810-5 will enable the low duty cycle soft-start retries only when the desired maximum power dissipation, PMOSFET(MAX), in the MOSFET is exceeded and leave the drivers on continuously otherwise. The shutoff/restart times are a function of the TRACK/SS capacitor value. The external NMOS for the linear regulator should be a standard 3V threshold type (i.e., not a logic-level threshold). The rate of charge of INTVCC from 0V to 5.5V is controlled by the LTC3810-5 to be approximately 75μs regardless of the size of the capacitor connected to the INTVCC pin. The charging current for this capacitor is approximately: 5.5V IC = C 75μs INTVCC DRIVER OFF THRESHOLD DRIVER POWER FROM VOUT DRIVER POWER FROM VIN ISS/TRACK = 1.4μA (SOURCE) DRIVER POWER FROM VIN START-UP ISS/TRACK = 0.1μA (SINK) EXTVCC UV THRESHOLD VOUT SHORT-CIRCUIT EVENT START-UP INTO SHORT-CIRCUIT TG/BG 38105 F10 Figure 10. Fault Timeout Operation 38105fc 21 LTC3810-5 APPLICATIONS INFORMATION The safe operating area (SOA) for the external NMOS should be chosen so that capacitor charging does not damage the NMOS. Excessive values of capacitor are unnecessary and should be avoided. Typically values in the 1μF to 10μF work well. One more design requirement for this mode is the minimum soft-start capacitor value. The fault timeout is enabled when SS/TRACK voltage is greater than 4V. This gives the power supply time to bring the output up before it starts the timeout sequence. To prevent timeout sequence from starting prematurely during start-up, a minimum CSS value is necessary to ensure that VSS/TRACK < 4V until VEXTVCC > 4.7V. To ensure this, choose: CSS > COUT • (2.3 • 10–6)/IOUT(MAX) Mode 2 should be used if VOUT is outside of the 4.7V < EXTVCC < 15V operating range and the extra complexity of a charge pump or extra inductor winding is not wanted to boost this voltage above 4.7V. In this mode, EXTVCC is grounded and the NMOS is chosen to handle the worstcase power dissipation: ( ) ( ) PMOSFET = VIN(MAX) ( f ) QG(TOP) + QG(BOTTOM) + 3mA To operate properly, the fault timeout operation must be disabled by choosing RNDRV > (VIN(MAX) – 5.5V – VTH)/270μA If the required RNDRV value results in an unacceptable value for VIN(MIN) (see Equation 1), fault timeout operation can also be disabled by connecting a 500k to 1Meg resistor from SS/TRACK pin to INTVCC. Using Trickle Charge Mode Trickle charge mode is selected by shorting NDRV and INTVCC and connecting EXTVCC to VOUT. Trickle charge mode has the advantage of not requiring an external MOSFET but takes longer to start up due to slow charge up of CINTVCC and CDRVCC through RPULLUP (tDELAY = 0.77 • RPULLUP • CDRVCC) and usually requires larger INTVCC/ DRVCC capacitor values to hold up the supply voltage during start-up. Once the INTVCC/DRVCC voltage reaches the trickle charge UV threshold of 9V, the drivers will turn on and start discharging CINTVCC/CDRVCC at a rate determined by the driver current IG. In order to ensure proper startup, CINTVCC/CDRVCC must be chosen large enough so that the EXTVCC voltage reaches the switchover threshold of 4.7V before CINTVCC/CDRVCC discharges below the falling UV threshold of 4V. This is ensured if: CINTVCC + CDRVCC > COUT 5.5 • 105 • CSS or IG • larger of IMAX VOUT(REG) Where IG is the gate drive current = (f)(QG(TOP) + QG(BOTTOM)) and IMAX is the maximum inductor current selected by VRNG. For RPULLUP, the value should fall in the following range to ensure proper start-up: Min RPULLUP > (VIN(MAX) – 14V)/ICCSR Max RPULLUP < (VIN(MIN) – 9V)/IQ,SHUTDOWN Using an External Supply Connected to the INTVCC/ DRVCC Pins If an external supply is available between 4.5V and 14V, the supply can be connected directly to the INTVCC/DRVCC pins. In this mode, INTVCC, EXTVCC and NDRV must be shorted together. INTVCC/DRVCC Supply and the EXTVCC Connection The LTC3810-5 contains an internal low dropout regulator to produce the 5.5V INTVCC /DRVCC supply from the EXTVCC pin voltage. This regulator turns on when the EXTVCC pin is above 4.7V and remains on until EXTVCC drops below 4.45V. This allows the IC/MOSFET power to be derived from the output or an output derived boost network during normal operation and from the external NMOS from VIN during start-up or short-circuit. Using the EXTVCC pin in this way results in significant efficiency gains compared to what would be possible when deriving this power continuously from the typically much higher VIN voltage. The EXTVCC connection also allows the power supply to be configured in trickle charge mode in which it starts up with a high valued “bleed” resistor connected from VIN to INTVCC to charge up the INTVCC capacitor. As soon as the output rises above 4.7V the internal EXTVCC regulator 38105fc 22 LTC3810-5 APPLICATIONS INFORMATION takes over before the INTVCC capacitor discharges below the UV threshold. When the EXTVCC regulator is active, the EXTVCC pin can supply up to 50mA RMS. Do not apply more than 15V to the EXTVCC pin. The following list summarizes the possible connections for EXTVCC: 1. EXTVCC grounded. This connection will require INTVCC to be powered continuously from an external NMOS from VIN resulting in an efficiency penalty as high as 10% at high input voltages. 2. EXTVCC connected directly to VOUT. This is the normal connection for 4.7V < VOUT < 15V and provides the highest efficiency. The power supply will start up using an external NMOS or a bleed resistor until the output supply is available. 3. EXTVCC connected to an output-derived boost network. If VOUT < 4.7V. The low voltage output can be boosted using a charge pump or flyback winding to greater than 4.7V. 4. EXTVCC connected to INTVCC. This is the required connection for EXTVCC if INTVCC is connected to an external supply where the external supply is 4.5V < VEXT < 15V. Applications using large MOSFETs with a high input voltage and high frequency of operation may result in a large EXTVCC pin current. Due to the LTC3810-5 thermally enhanced package, maximum junction temperature will rarely be exceeded, however, it is good design practice to verify that the maximum junction temperature rating and RMS current rating are within the maximum limits. Typically, most of the EXTVCC current consists of the MOSFET gates current. In continuous mode operation, this EXTVCC current is: ( ) IEXTVCC = f QG(TOP) + QG(BOTTOM) + 3mA < 50mA The junction temperature can be estimated from the equations given in Note 2 of the Electrical Characteristics as follows: TJ = TA + IEXTVCC • (VEXTVCC – VINTVCC)(34°C/W) < 125°C If absolute maximum ratings are exceeded, consider using an external supply connected directly to the INTVCC pin. FEEDBACK LOOP/COMPENSATION Feedback Loop Types In a typical LTC3810-5 circuit, the feedback loop consists of the modulator, the output filter and load, and the feedback amplifier with its compensation network. All of these components affect loop behavior and must be accounted for in the loop compensation. The modulator and output filter consists of the internal current comparator, the output MOSFET drivers and the external MOSFETs, inductor and output capacitor. Current mode control eliminates the effect of the inductor by moving it to the inner loop, reducing it to a first order system. From a feedback loop point of view, it looks like a linear voltage controlled current source from ITH to VOUT and has a gain equal to (IMAXROUT)/1.2V. It has fairly benign AC behavior at typical loop compensation frequencies with significant phase shift appearing at half the switching frequency. The external output capacitor and load cause a first order roll off at the output at the ROUTCOUT pole frequency, with the attendant 90° phase shift. This roll off is what filters the PWM waveform, resulting in the desired DC output voltage. The output capacitor also contributes a zero at the COUTRESR frequency which adds back the 90° phase and cancels the first order roll off. So far, the AC response of the loop is pretty well out of the user’s control. The modulator is a fundamental piece of the LTC3810-5 design and the external output capacitor is usually chosen based on the regulation and load current requirements without considering the AC loop response. The feedback amplifier, on the other hand, gives us a handle with which to adjust the AC response. The goal is to have 180° phase shift at DC (so the loop regulates), and something less than 360° phase shift (preferably about 300°) at the point that the loop gain falls to 0dB, i.e., the crossover frequency, with as much gain as possible at frequencies below the crossover frequency. Since the modulator/output filter is a first order system with maximum of 90° phase shift (at frequencies below fSW/4) and the feedback amplifier adds another 90° of phase shift, some phase boost is required at the crossover frequency to achieve good phase margin. If the ESR zero is below the crossover frequency, this zero may provide enough phase boost to achieve the desired phase margin and the only 38105fc 23 LTC3810-5 APPLICATIONS INFORMATION requirement of the compensation will be to guarantee that the gain is below zero at frequencies above fSW/4. If the ESR zero is above the crossover frequency, the feedback amplifier will probably be required to provide phase boost. For most LTC3810-5 applications, Type 2 compensation will provide enough phase boost; however some applications where high bandwidth is required with low ESR ceramics and lots of bulk capacitance, Type 3 compensation may be necessary to provide additional phase boost. The two types of compensation networks, “Type 2” and “Type 3” are shown in Figures 11 and 12. When component values are chosen properly, these networks provide a “phase bump” at the crossover frequency. Type 2 uses a single pole-zero pair to provide up to about 60° of phase boost while Type 3 uses two poles and two zeros to provide up to 150° of phase boost. C1 R2 RFB1 FB GAIN (dB) IN PHASE (DEG) C2 –6dB/OCT GAIN –6dB/OCT – OUT RFB2 0 FREQ + VREF –90 –180 PHASE –270 –360 38105 F11 Figure 11. Type 2 Schematic and Transfer Function IN RFB1 R3 FB R2 GAIN (dB) C3 C1 –6dB/OCT – GAIN OUT RFB2 VREF PHASE (DEG) C2 +6dB/OCT –6dB/OCT 0 FREQ + –90 PHASE –180 –270 –360 38105 F12 Figure 12. Type 3 Schematic and Transfer Function Feedback Component Selection Selecting the R and C values for a typical Type 2 or Type 3 loop is a nontrivial task. The applications shown in this data sheet show typical values, optimized for the power components shown. They should give acceptable performance with similar power components, but can be way off if even one major power component is changed significantly. Applications that require optimized transient response will require recalculation of the compensation values specifically for the circuit in question. The underlying mathematics are complex, but the component values can be calculated in a straightforward manner if we know the gain and phase of the modulator at the crossover frequency. Modulator gain and phase can be obtained in one of three ways: measured directly from a breadboard, or if the appropriate parasitic values are known, simulated or generated from the modulator transfer function. Measurement will give more accurate results, but simulation or transfer function can often get close enough to give a working system. To measure the modulator gain and phase directly, wire up a breadboard with an LTC3810-5 and the actual MOSFETs, inductor and input and output capacitors that the final design will use. This breadboard should use appropriate construction techniques for high speed analog circuitry: bypass capacitors located close to the LTC3810-5, no long wires connecting components, appropriately sized ground returns, etc. Wire the feedback amplifier with a 0.1μF feedback capacitor from ITH to FB and a 10k to 100k resistor from VOUT to FB. Choose the bias resistor (RFB2) as required to set the desired output voltage. Disconnect RFB2 from ground and connect it to a signal generator or to the source output of a network analyzer to inject a test signal into the loop. Measure the gain and phase from the ITH pin to the output node at the positive terminal of the output capacitor. Make sure the analyzer’s input is AC coupled so that the DC voltages present at both the ITH and VOUT nodes don’t corrupt the measurements or damage the analyzer. If breadboard measurement is not practical, a SPICE simulation can be used to generate approximate gain/phase curves. Plug the expected capacitor, inductor and MOSFET values into the following SPICE deck and generate an AC plot of VOUT/VITH with gain in dB and phase in degrees. 38105fc 24 LTC3810-5 APPLICATIONS INFORMATION .param rdson=.0135 ;MOSFET rdson .param Vrng=2 ;use 1.4 for INTVCC and 0.7 for ground .param vsnsmax={0.173*Vrng-0.026} .param Imax={vsnsmax/rdson} .param DL=4 ;inductor ripple current *inductor current gl out 0 value={(v(ith)-1.2)*Imax/1.2+DL/2} *output cap cout out out2 270u ;capacitor value resr out2 0 0.018 ;capacitor ESR *load Rout out 0 2 ; load resistor vstim ith 0 0 ac 1 ;ac stimulus .ac dec 100 100 10meg .probe .end Mathematical software such as MATHCAD or MATLAB can also be used to generate plots using the following transfer function of the modulator: VSENSE(MAX) 1+ s • R ESR • COUT • R (2) H(s) = • L 1.2 • RDS(ON) 1+ s • RL • COUT s = j2f With the gain/phase plot in hand, a loop crossover frequency can be chosen. Usually the curves look something like Figure 13. Choose the crossover frequency about 25% of the switching frequency for maximum bandwidth. Although it may be tempting to go beyond fSW/4, remember that significant phase shift occurs at half the switching frequency that isn’t modeled in the above H(s) equation and PSPICE code. Note the gain (GAIN, in dB) and phase GAIN 0 0 PHASE (DEG) *3810-5 modulator gain/phase *2006 Linear Technology *this file simulates a simplified model of *the LTC3810-5 for generating a v(out)/ v(ith) *bode plot GAIN (dB) Refer to your SPICE manual for details of how to generate this plot. –90 PHASE –180 FREQUENCY (Hz) 38105 F13 Figure 13. Transfer Function of Buck Modulator (PHASE, in degrees) at this point. The desired feedback amplifier gain will be –GAIN to make the loop gain at 0dB at this frequency. Now calculate the needed phase boost, assuming 60° as a target phase margin: BOOST = – (PHASE + 30°) If the required BOOST is less than 60°, a Type 2 loop can be used successfully, saving two external components. BOOST values greater than 60° usually require Type 3 loops for satisfactory performance. Finally, choose a convenient resistor value for RFB1 (10k is usually a good value). Now calculate the remaining values: (K is a constant used in the calculations) f = chosen crossover frequency G = 10(GAIN/20) (this converts GAIN in dB to G in absolute gain) TYPE 2 Loop: BOOST K = tan + 45° 2 1 C2 = 2 • f • G • K • RFB1 ( ) C1= C2 K 2 1 K 2 • f • C1 V (R ) RFB2 = REF FB1 VOUT VREF R2 = 38105fc 25 LTC3810-5 APPLICATIONS INFORMATION TYPE 3 Loop: BOOST K = tan2 + 45° 4 1 C2 = 2 • f • G • RFB1 C1= C2 (K 1) K 2 • f • C1 R R3 = FB1 K1 1 C3 = 2f K • R3 V (R ) RB = REF FB1 VOUT VREF R2 = SPICE or mathematical software can be used to generate the gain/phase plots for the compensated power supply to do a sanity check on the component values before trying them out on the actual hardware. For software, use the following transfer function: T(s) = A(s)H(s) where H(s) was given in Equation 2 and A(s) depends on compensation circuit used: Type 2: A (s) = 1+ s • R3 • C2 C2 • C3 s • RFB1 • (C2 + C3) • 1+ s • R3 • C2 + C3 Type 3: A (s) = 1 • s • RFB1 • (C2 + C3) (1+ s • (RFB1 + R3) • C3) • (1+ s • R2 • C1) C1• C2 (1+ s • R3 • C3) • 1+ s • R2 • C1+ C2 For SPICE, replace VSTIM line in the previous PSPICE code with following code and generate a gain/phase plot of V(out)/V(outin): rfb1 outin vfb 52.5k rfb2 vfb 0 10k eithx ithx 0 laplace {0.8-v(vfb)} = {1/(1+s/1000)} eith ith 0 value={limit(1e6*v(ithx),0,2.4)} cc1 ith vfb 4p cc2 ith x1 8p rc x1 vfb 210k rf outin x2 11k ;delete this line for Type 2 cf x2 vfb 120p ;delete this line for Type 2 vstim out outin dc=0 ac=1m Pulse Skip Mode Operation and MODE/SYNC Pin The MODE/SYNC pin determines whether the bottom MOSFET remains on when current reverses in the inductor. Tying this pin above its 0.8V threshold enables pulse skip mode operation where the bottom MOSFET turns off when inductor current reverses. The load current at which current reverses and discontinuous operation begins depends on the amplitude of the inductor ripple current and will vary with changes in VIN. Tying the MODE/SYNC pin below the 0.8V threshold forces continuous synchronous operation, allowing current to reverse at light loads and maintaining high frequency operation. To prevent forcing current back into the main power supply, potentially boosting the input supply to a dangerous voltage level, forced continuous mode of operation is disabled when the TRACK/SS voltage is below the reference voltage during soft-start or tracking. During these two periods, the PGOOD signal is forced low. Table 1 MODE/SYNC PIN CONDITION DC Voltage: 0V to 0.75V Forced Continuous Current Reversal Enabled DC Voltage: ≥ 0.85V Pulse Skip Mode Operation No Current Reversal Feedback Resistors Regulating a Secondary Winding Ext. Clock 0V to ≥ 2V Forced Continuous Current Reversal Enabled 38105fc 26 LTC3810-5 APPLICATIONS INFORMATION + VIN CIN VIN 1N4148 TG • + LTC3810-5 SW R4 FCB R3 T1 1:N • + VOUT2 COUT2 1μF VOUT1 COUT BG SGND PGND 38105 F14 Figure 14. Secondary Output Loop In addition to providing a logic input to force continuous operation, the MODE/SYNC pin provides a mean to maintain a flyback winding output when the primary is operating in pulse skip mode. The secondary output VOUT2 is normally set as shown in Figure 14 by the turns ratio N of the transformer. However, if the controller goes into pulse skip mode and halts switching due to a light primary load current, then VOUT2 will droop. An external resistor divider from VOUT2 to the MODE/SYNC pin sets a minimum voltage VOUT2(MIN) below which continuous operation is forced until VOUT2 has risen above its minimum. R4 VOUT2(MIN) = 0.8V 1+ R3 Fault Conditions: Current Limit and Foldback The maximum inductor current is inherently limited in a current mode controller by the maximum sense voltage. In the LTC3810-5, the maximum sense voltage is controlled by the voltage on the VRNG pin. With valley current control, the maximum sense voltage and the sense resistance determine the maximum allowed inductor valley current. The corresponding output current limit is: ILIMIT = VSNS(MAX) RDS(ON) 1 + ΔIL ρT 2 The current limit value should be checked to ensure that ILIMIT(MIN) > IOUT(MAX). The minimum value of current limit generally occurs with the largest VIN at the highest ambi- ent temperature, conditions that cause the largest power loss in the converter. Note that it is important to check for self-consistency between the assumed MOSFET junction temperature and the resulting value of ILIMIT which heats the MOSFET switches. Caution should be used when setting the current limit based upon the RDS(ON) of the MOSFETs. The maximum current limit is determined by the minimum MOSFET on-resistance. Data sheets typically specify nominal and maximum values for RDS(ON), but not a minimum. A reasonable assumption is that the minimum RDS(ON) lies the same percentage below the typical value as the maximum lies above it. Consult the MOSFET manufacturer for further guidelines. To further limit current in the event of a short-circuit to ground, the LTC3810-5 includes foldback current limiting. If the output falls by more than 50%, then the maximum sense voltage is progressively lowered to about one-tenth of its full value. Be aware also that when the fault timeout is enabled for the external NMOS regulator, an over current limit may cause the output to fall below the minimum 4.5V UV threshold. This condition will cause a linear regulator timeout/restart sequence as described in the Linear Regulator Timeout section if this condition persists. Soft-Start and Tracking The LTC3810-5 has the ability to either soft-start by itself with a capacitor or track the output of another supply. When the device is configured to soft-start by itself, a capacitor should be connected to the TRACK/SS pin. The LTC3810-5 is put in a low quiescent current shutdown state (IQ ~240μA) if the SHDN pin voltage is below 1.5V. The TRACK/SS pin is actively pulled to ground in this shutdown state. Once the SHDN pin voltage is above 1.5V, the LTC3810-5 is powered up. A soft-start current of 1.4μA then starts to charge the soft-start capacitor CSS. Note that soft-start is achieved not by limiting the maximum output current of the controller but by controlling the ramp rate of the output voltage. Current foldback is disabled during this soft-start phase. During the soft-start phase, the LTC3810-5 is ramping the reference voltage until it reaches 0.8V. The force continuous mode is also 38105fc 27 LTC3810-5 APPLICATIONS INFORMATION Output Voltage Tracking To implement the coincident tracking in Figure 15a, connect an additional resistive divider to VOUT1 and connect its midpoint to the TRACK/SS pin of the slave IC. The ratio of this divider should be selected the same as that of the slave IC’s feedback divider shown in Figure 16. In this tracking mode, VOUT1 must be set higher than VOUT2. To implement the ratiometric tracking, the ratio of the divider should be exactly the same as the master IC’s feedback divider. Note that the internal soft-start current will introduce a small error on the tracking voltage depending on the absolute values of the tracking resistive divider. The LTC3810-5 allows the user to program how its output ramps up by means of the TRACK/SS pin. Through this pin, the output can be set up to either coincidentally or ratiometrically track with another supply’s output, as shown in Figure 15. In the following discussions, VOUT1 refers to the master LTC3810-5’s output and VOUT2 refers to the slave LTC3810-5’s output. By selecting different resistors, the LTC3810-5 can achieve different modes of tracking including the two in Figure 15. So which mode should be programmed? While either mode in Figure 15 satisfies most practical applications, there do exist some tradeoffs. The ratiometric mode saves a pair of resistors, but the coincident mode offers better output regulation. This can be better understood with the disabled and PGOOD signal is forced low during this phase. The total soft-start time can be calculated as: tSOFTSTART = 0.8 • CSS/1.4μA When the device is configured to track another supply, the feedback voltage of the other supply is duplicated by a resistor divider and applied to the TRACK/SS pin. Therefore, the voltage ramp rate on this pin is determined by the ramp rate of the other supply output voltage. VOUT1 OUTPUT VOLTAGE OUTPUT VOLTAGE VOUT1 VOUT2 VOUT2 38105 F15 TIME TIME (15a) Coincident Tracking (15b) Ratiometric Tracking Figure 15. Two Different Modes of Output Voltage Tracking VOUT1 VOUT2 R3 R1 TO VFB1 PIN TO TRACK/SS2 PIN R4 R2 VOUT1 R3 TO VFB2 PIN R4 VOUT2 R1 R3 TO VFB1 PIN TO TRACK/SS2 PIN R2 TO VFB2 PIN R4 38105 F16 (16a) Coincident Tracking Setup (16b) Ratiometric Tracking Setup Figure 16. Setup for Coincident and Ratiometric Tracking 38105fc 28 LTC3810-5 APPLICATIONS INFORMATION I I + D1 D2 EA2 TRACK/SS2 0.8V VFB2 – D3 38105 F17 Figure 17. Equivalent Input Circuit of Error Amplifier help of Figure 17. At the input stage of the slave IC’s error amplifier, two common anode diodes are used to clamp the equivalent reference voltage and an additional diode is used to match the shifted common mode voltage. The top two current sources are of the same amplitude. In the coincident mode, the TRACK/SS voltage is substantially higher than 0.8V at steady state and effectively turns off D1. D2 and D3 will therefore conduct the same current and offer tight matching between VFB2 and the internal precision 0.8V reference. In the ratiometric mode, however, TRACK/SS equals 0.8V at steady state. D1 will divert part of the bias current to make VFB2 slightly lower than 0.8V. Although this error is minimized by the exponential I-V characteristic of the diode, it does impose a finite amount of output voltage deviation. Furthermore, when the master IC’s output experiences dynamic excursion (under load transient, for example), the slave IC output will be affected as well. For better output regulation, use the coincident tracking mode instead of ratiometric. The internal oscillator locks to the external clock after the second clock transition is received. When external synchronization is detected, LTC3810-5 will operate in forced continuous mode. If an external clock transition is not detected for three successive periods, the internal oscillator will revert to the frequency programmed by the RON resistor. During the start-up phase, phase-locked loop function is disabled. When LTC3810-5 is not in synchronization mode, PLL/LPF pin voltage is set to around 1.215V. Frequency synchronization is accomplished by changing the internal on-time current according to the voltage on the PLL/LPF pin. The phase detector used is an edge sensitive digital type which provides zero degrees phase shift between the external and internal pulses. This type of phase detector will not lock up on input frequencies close to the harmonics of the VCO center frequency. The PLL hold-in range, ΔfH, is equal to the capture range, ΔfC: ΔfH = ΔfC = ±0.3 fO The output of the phase detector is a complementary pair of current sources charging or discharging the external filter network on the PLL/LPF pin. A simplified block diagram is shown in Figure 18. RLP 2.4V PLL/LPF Phase-Locked Loop and Frequency Synchronization The LTC3810-5 has a phase-locked loop comprised of an internal voltage controlled oscillator and phase detector. This allows the top MOSFET turn-on to be locked to the rising edge of an external source. The frequency range of the voltage controlled oscillator is ±30% around the center frequency fO. The center frequency is the operating frequency discussed in the Operating Frequency section. The LTC3810-5 incorporates a pulse detection circuit that will detect a clock on the MODE/SYNC pin. In turn, it will turn on the phase-locked loop function. The pulse width of the clock has to be greater than 400ns and the amplitude of the clock should be greater than 2V. CLP MODE/SYNC DIGITAL PHASE/ FREQUENCY DETECTOR VCO 38105 F18 Figure 18. Phase-Locked Loop Block Diagram 38105fc 29 LTC3810-5 APPLICATIONS INFORMATION If the external frequency (fMODE) is greater than the oscillator frequency fO, current is sourced continuously, pulling up the PLL/LPF pin. When the external frequency is less than fO, current is sunk continuously, pulling down the PLL/LPF 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 PLL/LPF 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 LTC3810-5 MODE/SYNC pin must be driven from a low impedance source such as a logic gate located close to the pin. 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 = 10kΩ and CLP is 0.01μF to 0.1μF. 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. Although all dissipative elements in the circuit produce losses, four main sources account for most of the losses in LTC3810-5 circuits: 1. DC I2R losses. These arise from the resistances of the MOSFETs, inductor and PC board traces and cause the efficiency to drop at high output currents. In continuous mode the average output current flows through L, but is chopped between the top and bottom MOSFETs. If the two MOSFETs have approximately the same RDS(ON), then the resistance of one MOSFET can simply be summed with the resistances of L and the board traces to obtain the DC I2R loss. For example, if RDS(ON) = 0.01Ω and RL = 0.005Ω, the loss will range from 15mW to 1.5W as the output current varies from 1A to 10A. 2. Transition loss. This loss arises from the brief amount of time the top MOSFET spends in the saturated region during switch node transitions. It depends upon the input voltage, load current, driver strength and MOSFET capacitance, among other factors. The loss is significant at input voltages above 20V and can be estimated from the second term of the PMAIN equation found in the Power MOSFET Selection section. When transition losses are significant, efficiency can be improved by lowering the frequency and/or using a top MOSFET(s) with lower CRSS at the expense of higher RDS(ON). 3. INTVCC/DRVCC current. This is the sum of the MOSFET driver and control currents. Control current is typically about 3mA and driver current can be calculated by: IGATE = f(QG(TOP) + QG(BOT)), where QG(TOP) and QG(BOT) are the gate charges of the top and bottom MOSFETs. This loss is proportional to the supply voltage that INTVCC/ DRVCC is derived from, i.e., VIN for the external NMOS linear regulator, VOUT for the internal EXTVCC regulator, or VEXT when an external supply is connected to INTVCC/DRVCC. 4. CIN loss. The input capacitor has the difficult job of filtering the large RMS input current to the regulator. It must have a very low ESR to minimize the AC I2R loss and sufficient capacitance to prevent the RMS current from causing additional upstream losses in fuses or batteries. Other losses, including COUT ESR loss, Schottky diode D1 conduction loss during dead time and inductor core loss generally account for less than 2% additional loss. When making adjustments to improve efficiency, the input current is the best indicator of changes in efficiency. If you make a change and the input current decreases, then the efficiency has increased. If there is no change in input current, then there is no change in efficiency. 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 load current. 38105fc 30 LTC3810-5 APPLICATIONS INFORMATION When load step occurs, VOUT immediately shifts by an amount equal to ΔILOAD (ESR), where ESR is the effective series resistance of COUT. ΔILOAD also begins to charge or discharge COUT generating a feedback error signal used by the regulator to return VOUT to its steady-state value. During this recovery time, VOUT can be monitored for overshoot or ringing that would indicate a stability problem. VSNS = 320mV, assume a junction temperature of about 55°C above a 70°C ambient (ρ125°C = 1.7): ILIMIT ≥ 320mV 1 + • 2.4A = 7.3A 1.7 • 0.031Ω 2 and double-check the assumed TJ in the MOSFET: 60V − 5V • 7.3A 2 • 1.7 • 0.031Ω = 2.6W 60V Design Example PBOT = As a design example, take a supply with the following specifications: VIN = 12V to 60V, VOUT = 5V ±5%, IOUT(MAX) = 6A, f = 250kHz. First, calculate the timing resistor: TJ = 70°C + 2.6W • 22°C/W = 127°C RON = 5V = 110k 2.4V • 250kHz • 76pF and choose the inductor for about 40% ripple current at the maximum VIN: L= 5V 5V 1 = 7.6μH 250kHz • 0.4 • 6A 60V With a 7.7μH inductor, ripple current will vary from 1.5A to 2.4A (25% to 40%) over the input supply range. Next, choose the bottom MOSFET switch. Since the drain of the MOSFET will see the full supply voltage 60V (max) plus any ringing, choose an 60V MOSFET. The Si7850DP has: BVDSS = 60V RDS(ON) = 31mΩ (max)/25mΩ (nom), δ = 0.007/°C, CMILLER = (8.3nC – 2.8nC)/30V = 183pF, VGS(MILLER) = 3.8V, θJA= 22°C/W. This yields a nominal sense voltage of: VSNS(NOM) = 6A • 1.3 • 0.025Ω = 195mV To guarantee proper current limit at worst-case conditions, increase nominal VSNS by at least 50% to 320mV (by tying VRNG to 2V). To check if the current limit is acceptable at Verify that the Si7850DP is also a good choice for the top MOSFET by checking its power dissipation at current limit and maximum input voltage, assuming a junction temperature of 30°C above a 70°C ambient (ρ100°C = 1.5): 5V • 7.3A 2 (1.5 • 0.031 ) 60V 7.3A 1 1 + 60V 2 • • 2 • 183pF • + • 250kHz 5V 3.8V 3.8V 2 = 0.206W + 1.32W = 1.53W PMAIN = TJ = 70°C + 1.53W • 22°C/W = 104°C The junction temperature will be significantly less at nominal current, but this analysis shows that careful attention to heat sinking on the board will be necessary in this circuit. Since VOUT > 4.7V, the INTVCC voltage can be generated from VOUT with the internal LDO by connecting VOUT to the EXTVCC pin. A small SOT23 MOSFET such as the ZXMN10A07F can be used for the pass device if fault timeout is enabled. Choose RNDRV to guarantee that fault timeout is enabled when power dissipation of M3 exceeds 0.4W (max for 70°C ambient): ICC = 250kHz • 2 • 18nC + 3mA = 12mA RNDRV ≤ 0.4W / 0.012A – 3V = 112k 270µA So, choose RNDRV = 100k. 38105fc 31 LTC3810-5 APPLICATIONS INFORMATION CIN is chosen for an RMS current rating of about 3A at 85°C. The output capacitors are chosen for a low ESR of 0.018Ω to minimize output voltage changes due to inductor ripple current and load steps. The ripple voltage will be only: ΔVOUT(RIPPLE) = ΔIL(MAX) • ESR = 2.4A • 0.018Ω = 43mV However, a 0A to 6A load step will cause an output change of up to: ΔVOUT(STEP) = ΔILOAD • ESR = 6A • 0.018Ω = 108mV An optional 10μF ceramic output capacitor is included to minimize the effect of ESL in the output ripple. The complete circuit is shown in Figure 19. CON 100pF 40.2k 2 60.4k 0.01μF 10k CSS 1000pF RUV1 200k 9 ION BOOST TG VON SW SENSE+ RUV2 14.3k CC2 47pF BG DRVCC SS/TRACK RFB2 1.91k RC 200k • Use an immediate via to connect the components to ground plane including SGND and PGND of LTC3810-5. Use several bigger vias for power components. M3 ZXMN10A07F VIN 12V TO 60V CIN1 68μF 100V CIN2 1μF 100V PGND 27 26 CB 0.1μF M1 Si7852DP 25 24 18 L1 10μH CDRVCC 0.1μF VOUT 5V 6A COUT1 270μF 6.3V M2 Si7852DP 17 16 INTVCC 15 EXTVCC 14 NDRV SGND CC1 5pF • Place CIN, COUT, MOSFETs, D1 and inductor all in one compact area. It may help to have some components on the bottom side of the board. SENSE– 20 19 BGRTN 33 SGND 12 SHDN 13 UVIN SHDN • The ground plane layer should not have any traces and it should be as close as possible to the layer with power MOSFETs. DB BAS19 LTC3810 3 V RNG 4 PGOOD 5 MODE_SYNC 6 ITH 7 V 8 FB PLL/LPF PGOOD 250kHz CLOCK When laying out a PC board follow one of two suggested approaches. The simple PC board layout requires a dedicated ground plane layer. Also, for higher currents, it is recommended to use a multilayer board to help with heat sinking power components. RNDRV 100k RON 110k 31 PC Board Layout Checklist D1 B1100 CVCC 1μF COUT2 10μF 6.3V C5 1μF PGND RFB1 10k 38105 F19 Figure 19. 12V to 60V Input Voltage to 5V/6A Synchronized at 250kHz 38105fc 32 LTC3810-5 APPLICATIONS INFORMATION • Use compact plane for switch node (SW) to improve cooling of the MOSFETs and to keep EMI down. • Place M2 as close to the controller as possible, keeping the PGND, BG and SW traces short. • Use planes for VIN and VOUT to maintain good voltage filtering and to keep power losses low. • Connect the input capacitor(s) CIN close to the power MOSFETs. This capacitor carries the MOSFET AC current. • Flood all unused areas on all layers with copper. Flooding with copper will reduce the temperature rise of power component. You can connect the copper areas to any DC net (VIN, VOUT, GND or to any other DC rail in your system). • Keep the high dV/dt SW, BOOST and TG nodes away from sensitive small-signal nodes. • Connect the INTVCC decoupling capacitor CVCC closely to the INTVCC and SGND pins. When laying out a printed circuit board, without a ground plane, use the following checklist to ensure proper operation of the controller. • Connect the top driver boost capacitor CB closely to the BOOST and SW pins. • Connect the bottom driver decoupling capacitor CDRVCC closely to the DRVCC and BGRTN pins. • Segregate the signal and power grounds. All small signal components should return to the SGND pin at one point which is then tied to the PGND pin close to the source of M2. TYPICAL APPLICATIONS 7V to 60V Input Voltage to 5V/5A with IC Power from 12V Supply and All Ceramic Output Capacitors 12V RON 110k CON 100pF 31 ION 3 4 5 6 7 8 PGOOD RUV1 470k CSS 1000pF 9 VON VRNG SW PGOOD MODE_SYNC ITH RUV2 61.9k CC2 47pF BGRTN SS/TRACK DRVCC BG RFB2 1.91k RC 100k M1 Si7850DP 25 24 L1 4.7μH VOUT 5V 5A 19 18 17 16 INTVCC 15 EXTVCC 14 NDRV SGND CC1 5pF SENSE CIN2 1μF 100V PGND CB 0.1μF – 20 VFB PLL/LPF 33 SGND 12 SHDN 13 UVIN SHDN SENSE+ 26 CIN1 68μF 100V DB BAS19 LTC3810-5 27 BOOST TG 2 VIN 7V TO 60V CDRVCC 0.1μF COUT 47μF 6.3V s3 M2 Si7850DP D1 B1100 CVCC 1μF C5 22μF PGND RFB1 10k 38105 TA03 38105fc 33 LTC3810-5 TYPICAL APPLICATIONS 15V to 60V Input Voltage to 3.3V/5A with Fault Timeout, Pulse Skip and VIN UV Disabled RNDRV 274k RON 71.5k M3 ZVN4210G CON 100pF 31 ION LTC3810-5 27 BOOST TG 2 3 4 5 6 7 8 PGOOD CSS 1000pF 9 VON VRNG SW PGOOD MODE_SYNC ITH VFB PLL/LPF SS/TRACK CC2 47pF RFB2 3.24k RC 200k CB 0.1μF DRVCC CIN2 1μF 100V PGND M1 Si7850DP 25 24 L1 4.7μH 18 17 CDRVCC 0.1μF 16 INTVCC 15 EXTVCC 14 NDRV SGND CC1 5pF DB BAS19 20 SENSE– 19 BGRTN BG 33 SGND 12 SHDN 13 UVIN SHDN SENSE+ 26 VIN 15V TO 60V CIN1 68μF 100V VOUT 3.3V 5A COUT1 270μF 6.3V M2 Si7850DP COUT2 10μF 6.3V D1 B1100 CVCC 1μF C5 1μF PGND RFB1 10.2k 38105 TA04 38105fc 34 LTC3810-5 PACKAGE DESCRIPTION UH Package 32-Lead Plastic QFN (5mm × 5mm) (Reference LTC DWG # 05-08-1693 Rev D) 0.70 p0.05 5.50 p0.05 4.10 p0.05 3.45 p 0.05 3.50 REF (4 SIDES) 3.45 p 0.05 PACKAGE OUTLINE 0.25 p 0.05 0.50 BSC RECOMMENDED SOLDER PAD LAYOUT APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED 5.00 p 0.10 (4 SIDES) BOTTOM VIEW—EXPOSED PAD 0.75 p 0.05 R = 0.05 TYP 0.00 – 0.05 PIN 1 NOTCH R = 0.30 TYP OR 0.35 s 45° CHAMFER R = 0.115 TYP 31 32 0.40 p 0.10 PIN 1 TOP MARK (NOTE 6) 1 2 3.50 REF (4-SIDES) 3.45 p 0.10 3.45 p 0.10 (UH32) QFN 0406 REV D 0.200 REF 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 0.25 p 0.05 0.50 BSC 38105fc 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. 35 LTC3810-5 TYPICAL APPLICATION 13V to 60V Input Voltage to 12V/10A with Trickle Charger Start-Up RNDRV 100k RON 263k CON 100pF 31 ION LTC3810-5 27 BOOST 2 VON 3 VRNG 4 PGOOD 5 MODE_SYNC 6 I TH 7 V FB 8 PLL/LPF PGOOD RUV1 200k CSS 1000pF 9 SS/TRACK 33 SGND 12 SHDN 13 UVIN SHDN RUV2 13.3k CC2 47pF RFB2 1k RC 200k TG SW 26 CIN2 1μF 100V DB BAS19 PGND CB 0.1μF M1 Si7850DP 25 24 SENSE+ L1 10μH – 20 SENSE BGRTN 18 BG DRVCC 17 16 INTV CDRVCC 0.1μF NDRV COUT1 270μF 16V M2 Si7850DP s2 CC EXTVCC VOUT 12V 10A 19 D1 B1100 15 14 SGND CC1 5pF VIN 13V TO 60V CIN1 68μF 100V CVCC 1μF COUT2 10μF 16V C5 22μF PGND RFB1 14k 38105 TA05 RELATED PARTS PART NUMBER ® DESCRIPTION COMMENTS LT 1074HV/LT1076HV Monolithic 5A/2A Step-Down DC/DC Converters VIN up to 60V, TO-220 and DD Packages LTC1735 Synchronous Step-Down DC/DC Controller 3.5V ≤ VIN ≤ 36V, 0.8V ≤ VOUT ≤ 6V, Current Mode, IOUT ≤ 20A LTC1778 No RSENSE™ Synchronous DC/DC Controller 4V ≤ VIN ≤ 36V, Fast Transient Response, Current Mode, IOUT ≤ 20A LT1956 Monolithic 1.5A, 500kHz Step-Down Regulator 5.5V ≤ VIN ≤ 60V, 2.5mA Supply Current, 16-Pin SSOP LT3010 50mA, 3V to 80V Linear Regulator 1.275V ≤ VOUT ≤ 60V, No Protection Diode Required, 8-Lead MSOP LT3430/LT3431 Monolithic 3A, 200kHz/500kHz Step-Down Regulator 5.5V ≤ VIN ≤ 60V, 0.1Ω Saturation Switch, 16-Pin SSOP LT3433 Monolithic Step-Up/Step-Down DC/DC Converter 4V ≤ VIN ≤ 60V, 500mA Switch, Automatic Step-Up/Step-Down, LTC3703 100V Synchronous DC/DC Controller VIN up to 100V, 9.3V to 15V Gate Drive Supply LT3800 High Voltage Synchronous Fixed Frequency Step-Down Regulator Controller VIN up to 60V, IOUT ≤ 20A, Current Mode, Onboard Bias Regulator, Low IQ, TSSOP-16 LTC3810 100V Current Mode Synchronous Step-Down Regulator Controller VIN up to 100V, IOUT ≤ 20A, Constant On-Time, Synchronizable, No RSENSE Required LTC3812-5 No RSENSE High Voltage Synchronous Step-Down Controller VIN up to 60V, IOUT ≤ 20A, Current Mode, Low IQ, External Bias Regulator Control LTC3824 High Voltage Step-Down Controller with 100% Duty Cycle VIN up to 60V, IOUT ≤ 7A, Current Mode, Low IQ, 200kHz to 600kHz Fixed Frequency or Synchronizable, MSOP-10 LT3844 High Voltage Non-Synchronous Programmable Frequency VIN up to 60V, IOUT ≤ 10A, Current Mode, Onboard Bias Regulator, Low IQ, TSSOP-16, Synchronizable Step-Down Regulator Controller LT3845 High Voltage Synchronous Programmable Frequency Step-Down Regulator Controller VIN up to 60V, IOUT ≤ 20A, Current Mode, Onboard Bias Regulator, Low IQ, TSSOP-16, Synchronizable No RSENSE is a registered trademark of Linear Technology Corporation. 38105fc 36 Linear Technology Corporation LT 0608 REV C • PRINTED IN USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com © LINEAR TECHNOLOGY CORPORATION 2007