LTC3703 100V Synchronous Switching Regulator Controller Description Features n n n n n n n n n n n n n n n High Voltage Operation: Up to 100V Large 1Ω Gate Drivers No Current Sense Resistor Required Step-Up or Step-Down DC/DC Converter Dual N-Channel MOSFET Synchronous Drive Excellent Line and Load Transient Response Programmable Constant Frequency: 100kHz to 600kHz ±1% Reference Accuracy Synchronizable up to 600kHz Selectable Pulse-Skip Mode Operation Low Shutdown Current: 50µA Typ Programmable Current Limit Undervoltage Lockout Programmable Soft-Start 16-Pin Narrow SSOP and 28-Pin SSOP Packages The LTC®3703 is a synchronous step-down switching regulator controller that can directly step down voltages from up to 100V, making it ideal for telecom and automotive applications. The LTC3703 drives external N-channel MOSFETs using a constant frequency (up to 600kHz), voltage mode architecture. A precise internal reference provides 1% DC accuracy. A high bandwidth error amplifier and patented line feedforward compensation provide very fast line and load transient response. Strong 1Ω gate drivers allow the LTC3703 to drive multiple MOSFETs for higher current applications. The operating frequency is user programmable from 100kHz to 600kHz and can also be synchronized to an external clock for noise-sensitive applications. Current limit is programmable with an external resistor and utilizes the voltage drop across the synchronous MOSFET to eliminate the need for a current sense resistor. For applications requiring up to 60V operation with logic-level MOSFETS, refer to the LTC3703-5 data sheet. Applications n n n 48V Telecom and Base Station Power Supplies Networking Equipment, Servers Automotive and Industrial Control PARAMETER Maximum VIN MOSFET Gate Drive VCC UV+ VCC UV– L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and ThinSOT and No RSENSE are trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. Protected by U.S. Patents, including 5408150, 5055767, 6677210, 5847554, 5481178, 6304066, 6580258. LTC3703-5 60V 4.5V to 15V 3.7V 3.1V LTC3703 100V 9.3V to 15V 8.7V 6.2V Typical Application VCC 9.3V TO 15V + 22µF 25V BAS19 MODE/SYNC VIN 10k 1000pF 470pF 15k 8.06k 1% 0.1µF 113k 1% 100Ω 2200pF + fSET BOOST LTC3703 TG COMP FB SW IMAX VCC INV RUN/SS GND DRVCC BG BGRTN 100 68µF 0.1µF 8µH 270µF 16V 10Ω VIN = 25V VIN = 50V 95 Si7456DP VOUT 12V 5A + EFFICIENCY (%) 30k Efficiency vs Load Current VIN 15V TO 100V VIN = 75V 90 85 Si7456DP MBR1100 10µF 80 1µF 3703 F01 Figure 1. High Efficiency High Voltage Step-Down Converter 0 1 3 2 LOAD (A) 4 5 3703 F01b 3703fc 1 LTC3703 Absolute Maximum Ratings (Note 1) Supply Voltages VCC, DRVCC ........................................... –0.3V to 15V (DRVCC – BGRTN), (BOOST – SW)........ –0.3V to 15V BOOST.................................................. –0.3V to 115V BGRTN........................................................ –5V to 0V VIN Voltage............................................... –0.3V to 100V SW Voltage (Note 10).................................. –1V to 100V RUN/SS Voltage........................................... –0.3V to 5V MODE/SYNC, INV Voltages........................ –0.3V to 15V fSET, FB, IMAX Voltages................................ –0.3V to 3V Peak Output Current <10µs BG,TG...............................5A Operating Temperature Range (Note 2) LTC3703E.............................................–40°C to 85°C LTC3703I............................................ –40°C to 125°C LTC3703H (Note 9)............................. –40°C to 150°C Junction Temperature (Notes 3, 7) LTC3703E, LTC3703I......................................... 125°C LTC3703H (Note 9)............................................ 150°C Storage Temperature Range.................. –65°C to 150°C Lead Temperature (Soldering, 10 sec.)................... 300°C Pin Configuration TOP VIEW TOP VIEW MODE/SYNC 1 fSET 2 16 VIN 15 B00ST VIN 1 28 BOOST NC 2 27 TG NC 3 26 SW NC 4 25 NC NC 5 24 NC COMP 3 14 TG MODE/SYNC 6 23 NC FB 4 13 SW fSET 7 22 NC IMAX 5 12 VCC COMP 8 FB 9 21 VCC 20 DRVCC INV 6 RUN/SS 7 GND 8 11 DRVCC 10 BG 9 BGRTN GN PACKAGE 16-LEAD NARROW PLASTIC SSOP IMAX 10 19 BG INV 11 18 NC NC 12 17 NC RUN/SS 13 16 NC GND 14 TJMAX = 150°C, θJA = 110°C/W 15 BGRTN G PACKAGE 28-LEAD PLASTIC SSOP TJMAX = 125°C, θJA = 100°C/W Order Information LEAD FREE FINISH TAPE AND REEL PART MARKING LTC3703EGN#PBF LTC3703EGN#TRPBF 3703 LTC3703IGN#PBF LTC3703IGN#TRPBF 3703I LTC3703HGN#PBF LTC3703HGN#TRPBF 3703H LTC3703EG#PBF LTC3703EG#TRPBF LTC3703EG LEAD BASED FINISH TAPE AND REEL PART MARKING LTC3703EGN LTC3703EGN#TR 3703 LTC3703IGN LTC3703IGN#TR 3703I LTC3703HGN LTC3703HGN#TR 3703H LTC3703EG LTC3703EG#TR LTC3703EG Consult LTC Marketing for parts specified with wider operating temperature ranges. PACKAGE DESCRIPTION 16-Lead Narrow Plastic SSOP 16-Lead Narrow Plastic SSOP 16-Lead Narrow Plastic SSOP 28-Lead Plastic SSOP PACKAGE DESCRIPTION 16-Lead Narrow Plastic SSOP 16-Lead Narrow Plastic SSOP 16-Lead Narrow Plastic SSOP 28-Lead Plastic SSOP TEMPERATURE RANGE –40°C to 85°C –40°C to 125°C –40°C to 150°C –40°C to 85°C TEMPERATURE RANGE –40°C to 85°C –40°C to 125°C –40°C to 150°C –40°C to 85°C 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/ 3703fc 2 LTC3703 Electrical Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VCC = DRVCC = VBOOST = VIN = 10V, VMODE/SYNC = VINV = VSW = BGRTN = 0V, RUN/SS = IMAX = open, RSET = 25k, unless otherwise specified. SYMBOL PARAMETER VCC, DRVCC VCC, DRVCC Supply Voltage CONDITIONS VIN VIN Pin Voltage ICC VCC Supply Current VFB = 0V RUN/SS = 0V IDRVCC DRVCC Supply Current (Note 5) RUN/SS = 0V IBOOST BOOST Supply Current (Note 5) TJ ≤ 125°C TJ > 125°C RUN/SS = 0V MIN l TYP 9.3 15 l l UNITS V 100 V 1.7 50 2.5 mA µA 0 0 5 5 µA µA 360 360 0 500 800 5 µA µA µA 0.800 0.808 0.812 V V 0.007 0.05 %/V 0.01 0.1 % 0.81 0.87 V l l MAX Main Control Loop VFB Feedback Voltage (Note 4) l ∆VFB(LINE) Feedback Voltage Line Regulation 9V < VCC < 15V (Note 4) l ∆VFB(LOAD) VMODE/SYNC Feedback Voltage Load Regulation 1V < VCOMP < 2V (Note 4) l MODE/SYNC Threshold MODE/SYNC Rising ∆VMODE/SYNC MODE/SYNC Hysteresis 0.75 20 IMODE/SYNC MODE/SYNC Current VINV Invert Threshold IINV Invert Current 0 ≤ VINV ≤ 15V IVIN VIN Sense Input Current VIN = 100V RUN/SS = 0V, VIN = 10V IMAX IMAX Source Current VIMAX = 0V VOS(IMAX) VIMAX Offset Voltage VRUN/SS Shutdown Threshold IRUN/SS VUV 0.792 0.788 0 ≤ VMODE/SYNC ≤ 15V 1 mV 0 1 µA 1.5 2 V 0 1 µA 100 0 140 1 µA µA 10.5 12 13.5 µA |VSW| – VIMAX at IRUN/SS = 0µA H Grade –25 –25 10 10 55 65 mV mV 0.7 0.9 1.2 V RUN/SS Source Current RUN/SS = 0V 2.5 4 5.5 µA Maximum RUN/SS Sink Current |VSW| – VIMAX ≥ 200mV, VRUN/SS = 3V Undervoltage Lockout VCC Rising VCC Falling RSET = 25k l l 9 17 25 µA 8.0 5.7 8.7 6.2 9.3 6.8 V V 270 300 330 kHz 600 kHz Oscillator fOSC Oscillator Frequency fSYNC External Sync Frequency Range tON(MIN) Minimum On-Time DCMAX Maximum Duty Cycle 100 200 f < 200kHz 89 93 1.5 2 1.5 2 ns 96 % Driver IBG(PEAK) BG Driver Peak Source Current RBG(SINK) BG Driver Pull-Down RDS(ON) ITG(PEAK) TG Driver Peak Source Current RTG(SINK) TG Driver Pull-Down RDS(ON) (Note 8) 1 (Note 8) 1 A 1.5 Ω A 1.5 Ω Feedback Amplifier AVOL Op Amp DC Open Loop Gain (Note 4) fU Op Amp Unity Gain Crossover Frequency (Note 6) IFB FB Input Current 0 ≤ VFB ≤ 3V ICOMP COMP Sink/Source Current 74 85 dB 25 MHz 0 ±5 ±10 1 µA mA 3703fc 3 LTC3703 Electrical Characteristics 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 LTC3703E 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 LTC3703I is guaranteed over the full –40°C to 125°C operating junction temperature range. The LTC3703H is guaranteed over the full –40°C to 150°C operating junction temperature range. Note 3: TJ is calculated from the ambient temperature TA and power dissipation PD according to the following formula: LTC3703: TJ = TA + (PD • 100 °C/W) G Package Note 4: The LTC3703 is tested in a feedback loop that servos VFB to the reference voltage with the COMP pin forced to a voltage between 1V and 2V. Note 5: The dynamic input supply current is higher due to the power MOSFET gate charge 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: RDS(ON) guaranteed by correlation to wafer level measurement. Note 9: High junction temperatures degrade operating lifetimes. Operating lifetime at junction temperatures greater than 125°C is derated to 1000 hours. Note 10: Transient voltages (such as due to inductive ringing) are allowed beyond this range provided that the voltage does not exceed 10V below ground and duration does not exceed 20ns per switching cycle. Typical Performance Characteristics TA = 25°C unless otherwise noted. Efficiency vs Input Voltage Efficiency vs Load Current IOUT = 5A 95 95 EFFICIENCY (%) EFFICIENCY (%) 90 IOUT = 0.5A 85 80 0 10 20 70 30 40 50 60 INPUT VOLTAGE (V) VIN = 45V 90 VIN = 75V 85 IOUT 2A/DIV 80 70 80 VOUT 50mV/DIV VIN = 15V VOUT = 5V f = 250kHz PULSE SKIP ENABLED 75 VOUT = 12V f = 300kHz PULSE SKIP DISABLED 75 70 Load Transient Response 100 100 VIN = 50V 50µs/DIV VOUT = 12V 1A TO 5A LOAD STEP 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 LOAD CURRENT (A) 3703 G02 3703 G01 VCC Current vs VCC Voltage 4 3.5 VCC Shutdown Current vs VCC Voltage VCC Current vs Temperature 100 90 2.0 VFB = 0V 1.5 1.0 80 COMP = 1.5V 3 VCC CURRENT (µA) COMP = 1.5V 2.5 VCC CURRENT (mA) VCC CURRENT (mA) 3.0 2 VFB = 0V 1 70 60 50 40 30 20 0.5 0 3703 G03 10 6 8 10 12 VCC VOLTAGE (V) 14 16 3703 G04 0 –50 –25 0 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G05 0 6 8 12 10 VCC VOLTAGE (V) 14 16 3703 G06 3703fc 4 LTC3703 Typical Performance Characteristics VCC Shutdown Current vs Temperature Reference Voltage vs Temperature 70 Normalized Frequency vs Temperature 0.803 1.20 1.15 55 50 45 40 0.802 NORMALIZED FREQUENCY 60 REFERENCE VOLTAGE (V) VCC CURRENT (µA) 65 0.801 0.800 0.799 30 –50 –25 0 25 50 75 100 125 150 TEMPERATURE (°C) 0.798 –50 –25 0 0.95 0.90 VCC = 10V PEAK SOURCE CURRENT (A) 1.4 2.6 Driver Peak Source Current vs Supply Voltage 3.0 1.6 VCC = 10V 1.2 2.4 RDS(ON) (Ω) 2.2 2.0 1.8 1.6 1.0 0.8 0.6 0.4 1.4 0.2 1.2 1.0 –50 –25 0 25 50 75 0 –50 –25 100 125 150 TEMPERATURE (°C) 0 70 1.0 0.5 0.7 15 3703 G13 8 9 10 11 12 13 14 15 7 DRVCC/BOOST VOLTAGE (V) 8 DRVCC, BOOST = 10V 7 RISE 50 40 30 FALL 20 10 14 6 RUN/SS Pull-Up Current vs Temperature RUN/SS CURRENT (µA) RISE/FALL TIME (ns) 0.8 5 3703 G12 60 1.0 8 9 10 11 12 13 DRVCC/BOOST VOLTAGE (V) 1.5 Rise/Fall Time vs Gate Capacitance 1.1 7 2.0 3703 G11 Driver Pull-Down RDS(ON) vs Supply Voltage 6 2.5 0 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G10 0.9 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G09 Driver Pull-Down RDS(ON) vs Temperature 3.0 2.8 0 3703 G08 Driver Peak Source Current vs Temperature PEAK SOURCE CURRENT (A) 1.00 0.80 –50 –25 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G07 RDS(ON) (Ω) 1.05 0.85 35 0.6 1.10 0 6 5 4 3 2 1 0 6000 2000 4000 8000 GATE CAPACITANCE (pF) 10000 3703 G14 0 –50 –25 0 25 50 75 100 125 150 TEMPERATURE (°C) 1573 G15 3703fc 5 LTC3703 Typical Performance Characteristics RUN/SS Sink Current vs SW Voltage 6 25 5 20 4 3 2 1 0 Max % DC vs RUN/SS Voltage 100 IMAX = 0.3V 90 80 15 MAX DUTY CYCLE (%) RUN/SS SINK CURRENT (µA) RUN/SS PULLUP CURRENT (µA) RUN/SS Pull-Up Current vs VCC Voltage 10 5 0 6 8 10 12 VCC VOLTAGE (V) 14 16 0 0.1 0.2 0.3 0.4 0.5 |SW| VOLTAGE (V) 0.6 0.7 12 1.0 2.0 1.5 RUN VOLTAGE (V) 2.5 Max % DC vs Frequency and Temperature 100 VIN = 10V 95 60 VIN = 75V 40 VIN = 50V VIN = 25V 20 25 50 75 100 125 150 TEMPERATURE (°C) 0 3.0 3703 G18 MAX DUTY CYCLE (%) 80 –45°C 90 25°C 85 90°C 80 150°C 75 0.5 0.75 1.00 1.25 1.50 COMP (V) 1.75 70 2.00 0 100 200 300 400 500 FREQUENCY (kHz) 3703 G20 3703 G19 Shutdown Threshold vs Temperature 125°C 600 700 3703 G21 tON(MIN) vs Temperature 1.4 200 1.2 180 160 1.0 tON(MIN) (ns) SHUTDOWN THRESHOLD (V) 20 –10 0.5 100 DUTY CYCLE (%) IMAX SOURCE CURRENT (µA) 30 % Duty Cycle vs COMP Voltage 13 0.8 0.6 0.4 140 120 100 80 0.2 0 –50 –25 40 3703 G17 IMAX Current vs Temperature 0 50 0 3703 G16 11 –50 –25 60 10 –5 –10 70 60 0 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G22 40 –50 –25 0 25 50 75 100 125 150 TEMPERATURE (°C) 3703 G23 3703fc 6 LTC3703 Pin Functions (GN16/G28) MODE/SYNC (Pin 1/Pin 6): Pulse-Skip Mode Enable/Sync Pin. This multifunction pin provides pulse-skip mode enable/disable control and an external clock input for synchronization of the internal oscillator. Pulling this pin below 0.8V or to an external logic-level synchronization signal disables pulse-skip mode operation and forces continuous operation. Pulling the pin above 0.8V enables pulse-skip mode operation. This pin can also be connected to a feedback resistor divider from a secondary winding on the inductor to regulate a second output voltage. fSET (Pin 2/Pin 7): Frequency Set. A resistor connected to this pin sets the free running frequency of the internal oscillator. See Applications Information section for resistor value selection details. COMP (Pin 3/Pin 8): Loop Compensation. This pin is connected directly to the output of the internal error amplifier. An RC network is used at the COMP pin to compensate the feedback loop for optimal transient response. FB (Pin 4/Pin 9): Feedback Input. Connect FB through a resistor divider network to VOUT to set the output voltage. Also connect the loop compensation network from COMP to FB. IMAX (Pin 5/Pin 10): Current Limit Set. The IMAX pin sets the current limit comparator threshold. If the voltage drop across the bottom MOSFET exceeds the magnitude of the voltage at IMAX, the controller goes into current limit. The IMAX pin has an internal 12µA current source, allowing the current threshold to be set with a single external resistor to ground. See the Current Limit Programming section for more information on choosing RIMAX. INV (Pin 6/Pin 11): Top/Bottom Gate Invert. Pulling this pin above 2V sets the controller to operate in step-up (boost) mode with the TG output driving the synchronous MOSFET and the BG output driving the main switch. Below 1V, the controller will operate in step-down (buck) mode. RUN/SS (Pin 7/Pin 13): Run/Soft-Start. Pulling RUN/SS below 0.9V will shut down the LTC3703, turn off both of the external MOSFET switches and reduce the quiescent supply current to 50µA. A capacitor from RUN/SS to ground will control the turn-on time and rate of rise of the output voltage at power-up. An internal 4µA current source pull-up at the RUN/SS pin sets the turn-on time at approximately 750ms/µF. GND (Pin 8/Pin 14): Ground Pin. BGRTN (Pin 9/Pin 15): Bottom Gate Return. This pin connects to the source of the pull-down 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. BG (Pin 10/Pin 19): Bottom Gate Drive. The BG pin drives the gate of the bottom N-channel synchronous switch MOSFET. This pin swings from BGRTN to DRVCC. DRVCC (Pin 11/Pin 20): Driver Power Supply Pin. DRVCC provides power to the BG output driver. This pin should be connected to a voltage high enough to fully turn on the external MOSFETs, normally 10V to 15V for standard threshold MOSFETs. DRVCC should be bypassed to BGRTN with a 10µF, low ESR (X5R or better) ceramic capacitor. VCC (Pin 12/Pin 21): Main Supply Pin. All internal circuits except the output drivers are powered from this pin. VCC should be connected to a low noise power supply voltage between 9V and 15V and should be bypassed to GND (Pin 8) with at least a 0.1µF capacitor in close proximity to the LTC3703. SW (Pin 13/Pin 26): Switch Node Connection to Inductor and Bootstrap Capacitor. Voltage swing at this pin is from a Schottky diode (external) voltage drop below ground to VIN. TG (Pin 14/Pin 27): 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 15/Pin 28): Top Gate Driver Supply. The BOOST pin supplies power to the floating TG driver. The BOOST pin should be bypassed to SW with a low ESR (X5R or better) 0.1µF ceramic capacitor. An additional fast recovery Schottky diode from DRVCC to BOOST will create a complete floating charge-pumped supply at BOOST. VIN (Pin 16/Pin 1): Input Voltage Sense Pin. This pin is connected to the high voltage input of the regulator and is used by the internal feedforward compensation circuitry to improve line regulation. This is not a supply pin. 3703fc 7 LTC3703 Functional Diagram RSET 2 fSET GN16 OVERCURRENT 12µA 4µA – 5 IMAX RMAX + 50mV – ± + RUN/SS 5 – CSS 0.9V 3.2V 1 ± CHIP SD + UVSD OTSD MODE/SYNC SYNC DETECT EXT SYNC OSC 4 R2 R1 16 12 DB – INV REVERSE CURRENT BOOST TG COMP 0.8V FB VCC + FORCED CONTINUOUS 3 INV + + FB – ÷ % DC LIMIT SW – PWM + DRIVE LOGIC VIN DRVCC BG +MIN– +MAX– BGRTN INV VCC (<15V) 0.76V 0.84V VIN 15 14 CB M1 13 11 M2 10 9 6 L1 OVER TEMP OT SD BANDGAP VCC UVLO 0.8V REFERENCE INTERNAL 3.2V VCC UV SD GND VOUT COUT 8 VCC CVCC 3703 FD Operation (Refer to Functional Diagram) The LTC3703 is a constant frequency, voltage mode controller for DC/DC step-down converters. It is designed to be used in a synchronous switching architecture with two external N-channel MOSFETs. Its high operating voltage capability allows it to directly step down input voltages up to 100V without the need for a step-down transformer. For circuit operation, please refer to the Functional Diagram of the IC and Figure 1. The LTC3703 uses voltage mode control in which the duty ratio is controlled directly by the error amplifier output and thus requires no current sense resistor. The VFB pin receives the output voltage feedback and is compared to the internal 0.8V reference by the error amplifier, which outputs an error signal at the COMP pin. When the load current increases, it causes a 3703fc 8 LTC3703 Operation (Refer to Functional Diagram) drop in the feedback voltage relative to the reference. The COMP voltage then rises, increasing the duty ratio until the output feedback voltage again matches the reference voltage. In normal operation, the top MOSFET is turned on when the RS latch is set by the on-chip oscillator and is turned off when the PWM comparator trips and resets the latch. The PWM comparator trips at the proper duty ratio by comparing the error amplifier output (after being “compensated” by the line feedforward multiplier) to a sawtooth waveform generated by the oscillator. When the top MOSFET is turned off, the bottom MOSFET is turned on until the next cycle begins or, if pulse-skip mode operation is enabled, until the inductor current reverses as determined by the reverse current comparator. MAX and MIN comparators ensure that the output never exceed ±5% of nominal value by monitoring VFB and forcing the output back into regulation quickly by either keeping the top MOSFET off or forcing maximum duty cycle. The operation of its other features—fast transient response, outstanding line regulation, strong gate drivers, short-circuit protection and shutdown/soft-start—are described below. Fast Transient Response The LTC3703 uses a fast 25MHz op amp as an error amplifier. This allows the compensation network to be optimized for better load transient response. The high bandwidth of the amplifier, along with high switching frequencies and low value inductors, allow very high loop crossover frequencies. The 800mV internal reference allows regulated output voltages as low as 800mV without external level shifting amplifiers. Line Feedforward Compensation The LTC3703 achieves outstanding line transient response using a patented feedforward correction scheme. With this circuit the duty cycle is adjusted instantaneously to changes in input voltage, thereby avoiding unacceptable overshoot or undershoot. It has the added advantage of making the DC loop gain independent of input voltage. Figure 2 shows how large transient steps at the input have little effect on the output voltage. VOUT 50mV/DIV VIN 20V/DIV IL 2A/DIV 20µs/DIV VOUT = 12V ILOAD = 1A 25V TO 60V VIN STEP 3703 F02 Figure 2. Line Transient Performance Strong Gate Drivers The LTC3703 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 100V floating high side driver drives the topside MOSFET and a low side driver drives the bottom side MOSFET (see Figure 3). They can be powered from either a separate DC supply or a voltage derived from the input or output voltage (see MOSFET Driver Supplies section). 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 counter guarantees that the bottom MOSFET is turned on at least once every 10 cycles for 10% of the period to refresh the bootstrap capacitor. An undervoltage lockout keeps the LTC3703 shut down unless this voltage is above 8.7V. 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 topside and bottom 3703fc 9 LTC3703 Operation (Refer to Functional Diagram) 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 LTC3703 DRVCC BOOST TG + DB CB 0V SHUTDOWN START-UP L MB VOUT + BGRTN 0V TO –5V VOUT MT SW BG CIN duty cycle control set to 0%. As CSS continues to charge, the duty cycle is gradually increased, allowing the output voltage to rise. This soft-start scheme smoothly ramps the output voltage to its regulated value with no overshoot. The RUN/SS voltage will continue ramping until it reaches an internal 4V clamp. Then the MIN feedback comparator is enabled and the LTC3703 is in full operation. When the RUN/SS is low, the supply current is reduced to 50µA. COUT 3703 F03 Figure 3. Floating TG Driver Supply and Negative BG Return Constant Frequency The internal oscillator can be programmed with an external resistor connected from fSET to ground to run between 100kHz and 600kHz, thereby optimizing component size, efficiency, and noise for the specific application. The internal oscillator can also be synchronized to an external clock applied to the MODE/SYNC pin and can lock to a frequency in the 100kHz to 600kHz range. When locked to an external clock, pulse-skip mode operation is automatically disabled. Constant frequency operation brings with it a number of benefits: inductor and capacitor values can be chosen for a precise operating frequency and the feedback loop can be similarly tightly specified. Noise generated by the circuit will always be at known frequencies. Subharmonic oscillation and slope compensation, common headaches with constant frequency current mode switchers, are absent in voltage mode designs like the LTC3703. Shutdown/Soft-Start The main control loop is shut down by pulling RUN/SS pin low. Releasing RUN/SS allows an internal 4µA current source to charge the soft-start capacitor, CSS. When CSS reaches 0.9V, the main control loop is enabled with the MIN COMPARATOR ENABLED 4V VRUN/SS NORMAL OPERATION CURRENT LIMIT OUTPUT VOLTAGE IN REGULATION 3V RUN/SS SOFT-STARTS OUTPUT VOLTAGE AND INDUCTOR CURRENT 1.4V 0.9V MINIMUM DUTY CYCLE 0V LTC3703 POWER ENABLE DOWN MODE 3703 F04 Figure 4. Soft-Start Operation in Start-Up and Current Limit Current Limit The LTC3703 includes an onboard current limit circuit that limits the maximum output current to a user-programmed level. It works by sensing the voltage drop across the bottom MOSFET and comparing that voltage to a userprogrammed voltage at the IMAX pin. Since the bottom MOSFET looks like a low value resistor during its on-time, the voltage drop across it is proportional to the current flowing in it. In a buck converter, the average current in the inductor is equal to the output current. This current also flows through the bottom MOSFET during its on-time. Thus by watching the drain-to-source voltage when the bottom MOSFET is on, the LTC3703 can monitor the output current. The LTC3703 senses this voltage and inverts it to allow it to compare the sensed voltage (which becomes more negative as peak current increases) with a positive voltage at the IMAX pin. The IMAX pin includes a 12µA pull-up, enabling the user to set the voltage at IMAX with a single resistor (RIMAX) to ground. See the Current Limit Programming section for RIMAX selection. 3703fc 10 LTC3703 (Refer to Functional Diagram) For maximum protection, the LTC3703 current limit consists of a steady-state limit circuit and an instantaneous limit circuit. The steady-state limit circuit is a gm amplifier that pulls a current from the RUN/SS pin proportional to the difference between the SW and IMAX voltages. This current begins to discharge the capacitor at RUN/ SS, reducing the duty cycle and controlling the output voltage until the current regulates at the limit. Depending on the size of the capacitor, it may take many cycles to discharge the RUN/SS voltage enough to properly regulate the output current. This is where the instantaneous limit circuit comes into play. The instantaneous limit circuit is a cycle-by-cycle comparator which monitors the bottom MOSFET’s drain voltage and keeps the top MOSFET from turning on whenever the drain voltage is 50mV above the programmed max drain voltage. Thus the cycle-by-cycle comparator will keep the inductor current under control until the gm amplifier gains control. Pulse-Skip Mode The LTC3703 can operate in one of two modes selectable with the MODE/SYNC pin—pulse-skip mode or forced continuous mode. Pulse-skip mode is selected when increased efficiency at light loads is desired. In this mode, the bottom MOSFET is turned off when inductor current reverses to minimize the efficiency loss due to reverse current flow. As the load is decreased (see Figure 5), the duty cycle is reduced to maintain regulation until its minimum on-time (~200ns) is reached. When the load decreases below this point, the LTC3703 begins to skip cycles to PULSE-SKIP MODE maintain regulation. The frequency drops but this further improves efficiency by minimizing gate charge losses. In forced continuous mode, the bottom MOSFET is always on when the top MOSFET is off, allowing the inductor current to reverse at low currents. This mode is less efficient due to resistive losses, but has the advantage of better transient response at low currents, constant frequency operation, and the ability to maintain regulation when sinking current. See Figure 6 for a comparison of the effect on efficiency at light loads for each mode. The MODE/ SYNC threshold is 0.8V ±7.5%, allowing the MODE/SYNC to act as a feedback pin for regulating a second winding. If the feedback voltage drops below 0.8V, the LTC3703 reverts to continuous operation to maintain regulation in the secondary supply. 100 EFFICIENCY (%) Operation 90 VIN = 25V 80 VIN = 75V 70 60 VIN = 25V 50 VIN = 75V 40 30 20 FORCED CONTINUOUS PULSE SKIP MODE 10 0 10 100 1000 LOAD (mA) 10000 3703 F06 Figure 6. Efficiency in Pulse-Skip/Forced Continuous Modes FORCED CONTINUOUS DECREASING LOAD CURRENT 3703 F05 Figure 5. Comparison of Inductor Current Waveforms for Pulse-Skip Mode and Forced Continuous Operation 3703fc 11 LTC3703 Operation (Refer to Functional Diagram) Buck or Boost Mode Operation The LTC3703 has the capability of operating both as a step-down (buck) and step-up (boost) controller. In boost mode, output voltages as high as 80V can be tightly regulated. With the INV pin grounded, the LTC3703 operates in buck mode with TG driving the main (topside) switch and BG driving the synchronous (bottom side) switch. If the INV pin is pulled above 2V, the LTC3703 operates in boost mode with BG driving the main (bottom side) switch and TG driving the synchronous (topside) switch. Internal circuit operation is very similar regardless of the operating mode with the following exceptions: in boost mode, pulse-skip mode operation is always disabled regardless of the level of the MODE/SYNC pin and the line feedforward compensation is also disabled. The overcurrent circuitry continues to monitor the load current by looking at the drain voltage of the main (bottom side) MOSFET. In boost mode, however, the peak MOSFET current does not equal the load current but instead ID = ILOAD/(1 – D). This factor needs to be taken into account when programming the IMAX voltage. Applications Information Operating Frequency The choice of operating frequency and inductor value is a trade-off between efficiency and component size. Low frequency operation improves efficiency by reducing MOSFET switching losses and gate charge losses. However, lower frequency operation requires more inductance for a given amount of ripple current, resulting in a larger inductor size and higher cost. If the ripple current is allowed to increase, larger output capacitors may be required to maintain the same output ripple. For converters with high step-down VIN to VOUT ratios, another consideration is the minimum on-time of the LTC3703 (see the Minimum On-Time Considerations section). A final consideration for operating frequency is that in noise-sensitive communications systems, it is often desirable to keep the switching noise out of a sensitive frequency band. The LTC3703 uses a constant frequency architecture that can be programmed over a 100kHz to 600kHz range with a single resistor from the fSET pin to ground, as shown in Figure 1. The nominal voltage on the fSET pin is 1.2V, and the current that flows from this pin is used to charge and discharge an internal oscillator capacitor. The value of RSET for a given operating frequency can be chosen from Figure 7 or from the following equation: RSET (kΩ) = 7100 f(kHz)– 25 1000 100 RSET (kΩ) The basic LTC3703 application circuit is shown in Figure 1. External component selection is determined by the input voltage and load requirements as explained in the following sections. After the operating frequency is selected, RSET and L can be chosen. The operating frequency and the inductor are chosen for a desired amount of ripple current and also to optimize efficiency and component size. Next, the power MOSFETs and D1 are selected based on voltage, load and efficiency requirements. CIN is selected for its ability to handle the large RMS currents in the converter and COUT is chosen with low enough ESR to meet the output voltage ripple and transient specifications. Finally, the loop compensation components are chosen to meet the desired transient specifications. 10 1 0 200 400 600 FREQUENCY (kHz) 800 1000 3703 F07 Figure 7. Timing Resistor (RSET) Value 3703fc 12 LTC3703 Applications Information The oscillator can also be synchronized to an external clock applied to the MODE/SYNC pin with a frequency in the range of 100kHz to 600kHz (refer to the MODE/SYNC Pin section for more details). In this synchronized mode, pulse-skip mode operation is disabled. The clock high level must exceed 2V for at least 25ns. As shown in Figure 8, the top MOSFET turn-on will follow the rising edge of the external clock by a constant delay equal to one-tenth of the cycle period. MODE/ SYNC 2V TO 10V tMIN = 25ns 0.8T TG T T = 1/fO L≥ VOUT 1– f ∆IL(MAX) VIN(MAX) VOUT The inductor also has an affect on low current operation when pulse-skip mode operation is enabled. The frequency begins to decrease when the output current drops below the average inductor current at which the LTC3703 is operating at its tON(MIN) in discontinuous mode (see Figure 6). Lower inductance increases the peak inductor current that occurs in each minimum on-time pulse and thus increases the output current at which the frequency starts decreasing. D = 40% 0.1T IL 3703 F08 Figure 8. MODE/SYNC Clock Input and Switching Waveforms for Synchronous Operation Inductor The inductor in a typical LTC3703 circuit is chosen for a specific ripple current and saturation current. Given an input voltage range and an output voltage, the inductor value and operating frequency directly determine the ripple current. The inductor ripple current in the buck mode is: ∆IL = ripple current occurs at the highest VIN. To guarantee that ripple current does not exceed a specified maximum, the inductor in buck mode should be chosen according to: VOUT VOUT 1– (f)(L) VIN Lower ripple current reduces core losses in the inductor, ESR losses in the output capacitors and output voltage ripple. Thus highest efficiency operation is obtained at low frequency with small ripple current. To achieve this however, requires a large inductor. A reasonable starting point is to choose a ripple current between 20% and 40% of IO(MAX). Note that the largest Power MOSFET Selection The LTC3703 requires at least two external N-channel power MOSFETs, one for the top (main) switch and one or more for the bottom (synchronous) switch. The number, type and “on” resistance of all MOSFETs selected take into account the voltage step-down ratio as well as the actual position (main or synchronous) in which the MOSFET will be used. A much smaller and much lower input capacitance MOSFET should be used for the top MOSFET in applications that have an output voltage that is less than 1/3 of the input voltage. In applications where VIN >> VOUT, the top MOSFETs’ “on” resistance is normally less important for overall efficiency than its input capacitance at operating frequencies above 300kHz. MOSFET manufacturers have designed special purpose devices that provide reasonably low “on” resistance with significantly reduced input capacitance for the main switch application in switching regulators. Selection criteria for the power MOSFETs include the “on” resistance RDS(ON), input capacitance, breakdown voltage and maximum output current. 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 3703fc 13 LTC3703 Applications Information breakdown specification. Since many high voltage MOSFETs have higher threshold voltages (typically, VGS(MIN) ≥ 6V), the LTC3703 is designed to be used with a 9V to 15V gate drive supply (DRVCC pin). 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 9). VIN VGS MILLER EFFECT a V b QIN CMILLER = (QB – QA)/VDS + VGS – +V DS – 3703 F09 Figure 9. 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: PMAIN = VOUT 2 IMAX ) (1+ δ)RDS(ON) + ( VIN 2 IMAX VIN (RDR )(CMILLER )• 2 1 1 + (f) VCC – VTH(IL) VTH(IL) V −V PSYNC = IN OUT (IMAX )2 (1+ δ)RDS(0N) VIN where δ is the temperature dependency of RDS(ON), RDR is the effective top driver resistance (approximately 2Ω at VGS = VMILLER), VIN is the drain potential and the change in drain potential in the particular application. VTH(IL) is the data sheet specified typical gate threshold voltage specified in the power MOSFET data sheet at the specified drain current. CMILLER is the calculated capacitance using the gate charge curve from the MOSFET data sheet and the technique described above. Both MOSFETs have I2R losses while the topside N-channel equation includes an additional term for transition losses, which peak at the highest input voltage. For VIN < 25V, the high current efficiency generally improves with larger MOSFETs, while for VIN > 25V, the transition losses rapidly increase to the point that the use of a higher RDS(ON) device with lower CMILLER actually provides higher efficiency. The synchronous MOSFET losses are greatest at high input voltage when the top switch duty factor is low or during a short circuit when the synchronous switch is on close to 100% of the period. 3703fc 14 LTC3703 Applications Information The term (1 + δ) is generally given for a MOSFET in the form of a normalized RDS(ON) vs temperature curve, and typically varies from 0.005/°C to 0.01/°C depending on the particular MOSFET used. Multiple MOSFETs can be used in parallel to lower RDS(ON) and meet the current and thermal requirements if desired. The LTC3703 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 (5Ω or less) to reduce noise and EMI caused by the fast transitions. Schottky Diode Selection The Schottky diode D1 shown in Figure 1 conducts during the dead time between the conduction of the power MOSFETs. This prevents the body diode of the bottom MOSFET from turning on and storing charge during the dead time and requiring a reverse recovery period that could cost as much as 1% to 2% in efficiency. A 1A Schottky diode is generally a good size for 3A to 5A regulators. Larger diodes result in additional losses due to their larger junction capacitance. The diode can be omitted if the efficiency loss can be tolerated. Input Capacitor Selection 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 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 tempera- ture 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, for regulators with input supplies above 30V, choice of input capacitor type is limited to ceramics or aluminum electrolytics. Ceramic capacitors have the advantage of very low ESR and can handle high RMS current, however 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, however, 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 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: % IRMS,ALUM ≈ 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 (∆VOUT) is approximately equal to: 1 ∆VOUT ≤ ∆IL ESR + 8fCOUT 3703fc 15 LTC3703 Applications Information Since ∆IL 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 LTC3703 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 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 LTC3703 output voltage is set by a resistor divider according to the following formula: R1 VOUT = 0.8V 1+ R2 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 ±1%. Tolerance of the feedback resistors will add additional error to the output voltage. 0.1% to 1% resistors are recommended. MOSFET Driver Supplies (DRVCC and BOOST) The LTC3703 drivers are supplied from the DRVCC and BOOST pins (see Figure 3), which have an absolute maximum voltage of 15V. If the main supply voltage, VIN, is higher than 15V a separate supply with a voltage between 9V and 15V must be used to power the drivers. If a separate supply is not available, one can easily be generated from the main supply using one of the circuits shown in Figure 10. If the output voltage is between 10V and 15V, the output can be used to directly power the drivers as shown in Figure 10a. If the output is below 10V, Figure 10b shows an easy way to boost the supply voltage to a sufficient level. This boost circuit uses the LT1613 in a ThinSOT™ package and a chip inductor for minimal extra area (<0.2in2). Two other possible schemes are an extra winding on the inductor (Figure 10c) or a capacitive charge pump (Figure 10d). All the circuits shown in Figure 10 require a start-up circuit (Q1, D1 and R1) to provide driver power at initial start-up or following a short-circuit. The resistor R1 must be sized so that it supplies sufficient base current and zener bias current at the lowest expected value of VIN. When using an existing supply, the supply must be capable of supplying the required gate driver current which can be estimated from: IDRVCC = (f)(QG(TOP) + QG(BOTTOM)) This equation for IDRVCC is also useful for properly sizing the circuit components shown in Figure 10. An external bootstrap capacitor, CB, connected to the BOOST pin supplies the gate drive voltage for the topside MOSFETs. Capacitor CB is charged through external diode, DB, from the DRVCC supply when SW is low. When the topside MOSFET is turned on, the driver places the CB voltage across the gate source of the top MOSFET. The switch node voltage, SW, rises to VIN and the BOOST pin follows. With the topside MOSFET on, the boost voltage is 3703fc 16 LTC3703 Applications Information + C10 1µF 16V 1µF CIN 12V + VIN C9 4.7µF 6.3V VIN LT1613 SHDN GND TG L1 BG FB R17 110k 1% VIN TG DRVCC SW L2 10µH LTC3703 12V SW + R17 1M 1% CIN LTC3703 VCC D2 ZHCS400 VIN VIN + L1 VOUT 10V TO 15V VCC SW COUT DRVCC BG VOUT <10V + COUT BGRTN BGRTN 3703 F10b 3703 F10a Figure 10a. VCC Generated from 10V < VOUT < 15V Figure 10b. VCC Generated from VOUT < 10V VIN (<40V) VIN + OPTIONAL VCC CONNECTION 10V < VSEC < 15V + CIN 1µF CIN 12V 12V VIN VIN LTC3703 VCC TG1 DRVCC SW R1 FCB BG1 GND BGRTN + N T1 1 + VSEC + COUT R2 0.22µF BAT85 LTC3703 1µF VOUT BAT85 TG VCC SW DRVCC BG BAT85 VN2222LL L1 VOUT + COUT BGRTN 3703 F10c 3703 F10d Figure 10c. Secondary Output Loop and VCC Connection Figure 10d. Capacitive Charge Pump for VCC (VIN < 40V) above the input supply: VBOOST = VIN + VDRVCC. The value of the boost capacitor, CB, needs to be 100 times that of the total input capacitance of the topside MOSFET(s). 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 silicon diode such as the BAS19. An internal undervoltage lockout (UVLO) monitors the voltage on DRVCC to ensure that the LTC3703 has sufficient gate drive voltage. If the DRVCC voltage falls below the UVLO threshold, the LTC3703 shuts down and the gate drive outputs remain low. 3703fc 17 LTC3703 Applications Information Bottom MOSFET Source 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 15V. If, for example, VBGRTN = –2V, the maximum voltage on DRVCC pin is now 13V instead of 15V. Current Limit Programming Programming current limit on the LTC3703 is straight forward. The IMAX pin sets the current limit by setting the maximum allowable voltage drop across the bottom MOSFET. The voltage across the MOSFET is set by its onresistance and the current flowing in the inductor, which is the same as the output current. The LTC3703 current limit circuit inverts the negative voltage across the MOSFET before comparing it to the voltage at IMAX, allowing the current limit to be set with a positive voltage. To set the current limit, calculate the expected voltage drop across the bottom MOSFET at the maximum desired current and maximum junction temperature: VPROG = (ILIMIT)(RDS(ON))(1 + δ) where δ is explained in the MOSFET Selection section. VPROG is then programmed at the IMAX pin using the internal 12µA pull-up and an external resistor: RIMAX = VPROG/12µA The current limit value should be checked to ensure that ILIMIT(MIN) > IOUT(MAX) and also that ILIMIT(MAX) is less than the maximum rated current of the inductor and bottom MOSFET. The minimum value of current limit generally occurs with the largest VIN at the highest ambient 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 amount below the typical value as the maximum lies above it. Consult the MOSFET manufacturer for further guidelines. For best results, use a VPROG voltage between 100mV and 500mV. Values outside of this range may give less accurate current limit. The current limit can also be disabled by floating the IMAX pin. FEEDBACK LOOP/COMPENSATION Feedback Loop Types In a typical LTC3703 circuit, the feedback loop consists of the modulator, the external inductor, the output capacitor 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 consists of the internal PWM generator, the output MOSFET drivers and the external MOSFETs themselves. From a feedback loop point of view, it looks like a linear voltage transfer function from COMP to SW and has a gain roughly equal to the input voltage. It has fairly benign AC behavior at typical loop compensation frequencies with significant phase shift appearing at half the switching frequency. The external inductor/output capacitor combination makes a more significant contribution to loop behavior. These components cause a second order LC roll off at the output, with the attendant 180° phase shift. This rolloff is what filters the PWM waveform, resulting in the desired DC output voltage, but the phase shift complicates the loop compensation if the gain is still higher than unity at the pole frequency. Eventually (usually well above the LC pole frequency), the reactance of the output capacitor will 3703fc 18 LTC3703 Applications Information approach its ESR and the rolloff due to the capacitor will stop, leaving 6dB/octave and 90° of phase shift (Figure 11). GAIN (dB) GAIN OUT RB –6dB/OCT 0 FREQ + VREF –90 –180 –270 –360 –90 –180 3703 F13 –270 Figure 13. Type 2 Schematic and Transfer Function –360 Figure 11. Transfer Function of Buck Modulator C1 PHASE (DEG) GAIN (dB) 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 LTC3703 design and the external L and C are 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 at the point that the loop gain falls to 0dB. The simplest strategy is to set up the feedback amplifier as an inverting integrator, with the 0dB frequency lower than the LC pole (Figure 12). This “Type 1” configuration is stable but transient response is less than exceptional if the LC pole is at a low frequency. GAIN – –6dB/OCT OUT 0 FREQ + –90 –180 “Type 3” loops (Figure 14) use two poles and two zeros to obtain a 180° phase boost in the middle of the frequency band. A properly designed Type 3 circuit can maintain acceptable loop stability even when low output capacitor ESR causes the LC section to approach 180° phase shift well above the initial LC roll-off. As with a Type 2 circuit, the loop should cross through 0dB in the middle of the phase bump to maximize phase margin. Many LTC3703 circuits using low ESR tantalum or OS-CON output capacitors need Type 3 compensation to obtain acceptable phase margin with a high bandwidth feedback loop. IN C2 –270 C3 –360 R1 3703 F12 Figure 12. Type 1 Schematic and Transfer Function Figure 13 shows an improved “Type 2” circuit that uses an additional pole-zero pair to temporarily remove 90° of phase shift. This allows the loop to remain stable with 90° more phase shift in the LC section, provided the loop reaches 0dB gain near the center of the phase “bump.” R3 FB R2 C1 – VREF –6dB/OCT GAIN OUT RB PHASE (DEG) PHASE Type 2 loops work well in systems where the ESR zero in the LC roll-off happens close to the LC pole, limiting the total phase shift due to the LC. The additional phase compensation in the feedback amplifier allows the 0dB point to be at or above the LC pole frequency, improving loop bandwidth substantially over a simple Type 1 loop. It has limited ability to compensate for LC combinations where low capacitor ESR keeps the phase shift near 180° for an extended frequency range. LTC3703 circuits using conventional switching grade electrolytic output capacitors can often get acceptable phase margin with Type 2 compensation. GAIN (dB) 3703 F11 VREF – FREQ –6dB/OCT RB –6dB/OCT GAIN PHASE PHASE R1 FB GAIN (dB) R1 FB –12dB/OCT 0 IN C1 R2 PHASE (DEG) IN PHASE (DEG) AV C2 +6dB/OCT –6dB/OCT 0 FREQ + –90 –180 PHASE –270 –360 3703 F14 Figure 14. Type 3 Schematic and Transfer Function 3703fc 19 LTC3703 Applications Information 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 measured directly from a breadboard or can be simulated if the appropriate parasitic values are known. Measurement will give more accurate results, but simulation can often get close enough to give a working system. To measure the modulator gain and phase directly, wire up a breadboard with an LTC3703 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 LTC3703, no long wires connecting components, appropriately sized ground returns, etc. Wire the feedback amplifier as a simple Type 1 loop, with a 10k resistor from VOUT to FB and a 0.1µF feedback capacitor from COMP to FB. Choose the bias resistor, RB, as required to set the desired output voltage. Disconnect RB 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 COMP 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 COMP 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 V(VOUT )/V(COMP) in dB and phase of VOUT in degrees. Refer to your SPICE manual for details of how to generate this plot. *3703 modulator gain/phase *2003 Linear Technology *this file written to run with PSpice 8.0 *may require modifications for other SPICE simulators *MOSFETs rfet mod sw 0.02 ;MOSFET rdson *inductor lext sw out1 10u;inductor value rl out1 out 0.015 ;inductor series R *output cap cout out out2 540u;capacitor value resr out2 0 0.01 ;capacitor ESR *3703 internals = {57*v(comp)} emod mod 0 value ;3703multiplier vstim comp 0 0 ac 1 ;ac stimulus .ac dec 100 1k 1meg .probe .end With the gain/phase plot in hand, a loop crossover frequency can be chosen. Usually the curves look something like Figure 11. Choose the crossover frequency in the rising or flat parts of the phase curve, beyond the external LC poles. Frequencies between 10kHz and 50kHz usually work well. Note the gain (GAIN, in dB) and phase (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. 3703fc 20 LTC3703 Applications Information Finally, choose a convenient resistor value for R1 (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 = 2π • f •G •K •R1 ( ) C1= C2 K 2 −1 K 2π • f •C1 V (R1) RB = REF VOUT − VREF R2 = TYPE 3 Loop: BOOST K = tan2 + 45° 4 1 2π • f •G •R1 C1= C2 (K −1) C2 = K 2π • f •C1 R1 R3 = K −1 1 C3 = 2πf K • R3 V (R1) RB = REF VOUT − VREF R2 = Boost Converter Design The following sections discuss the use of the LTC3703 as a step-up (boost) converter. In boost mode, the LTC3703 can step-up output voltages as high as 80V. These sections discuss only the design steps specific to a boost converter. For the design steps common to both a buck and a boost, see the applicable section in the buck mode section. An example of a boost converter circuit is shown in the Typical Applications section. To operate the LTC3703 in boost mode, the INV pin should be tied to the VCC voltage (or a voltage above 2V). Note that in boost mode, pulse-skip operation and the line feedforward compensation are disabled. For a boost converter, the duty cycle of the main switch is: D= VOUT – VIN VOUT For high VOUT to VIN ratios, the maximum VOUT is limited by the LTC3703’s maximum duty cycle which is typically 93%. The maximum output voltage is therefore: VOUT(MAX) = VIN(MIN) 1–DMAX ≅ 14VIN(MIN) Boost Converter: Inductor Selection In a boost converter, the average inductor current equals the average input current. Thus, the maximum average inductor current can be calculated from: IL(MAX) = IO(MAX) 1−DMAX =IO(MAX) • VO VIN(MIN) Similar to a buck converter, choose the ripple current to be 20% to 40% of IL(MAX). The ripple current amplitude then determines the inductor value as follows: L= VIN(MIN) ∆IL • f •DMAX The minimum required saturation current for the inductor is: IL(SAT) > IL(MAX) + ∆IL/2 Boost Converter: Power MOSFET Selection For information about choosing power MOSFETs for a boost converter, see the Power MOSFET Selection section for the buck converter, since MOSFET selection is similar. 3703fc 21 LTC3703 Applications Information However, note that the power dissipation equations for the MOSFETs at maximum output current in a boost converter are: I PMAIN = DMAX MAX 1–DMAX 2 (1+ δ )RDS(ON) + 1 2 IMAX V (RDR )(CMILLER ) • 2 OUT 1–DMAX 1 1 + ( f) VCC – VTH(IL) VTH(IL) 1 2 PSYNC = – IMAX ) (1+ δ )RDS(ON) ( 1–DMAX Boost Converter: Output Capacitor Selection In boost mode, the output capacitor requirements are more demanding due to the fact that the current waveform is pulsed instead of continuous as in a buck converter. The choice of component(s) is driven by the acceptable ripple voltage which is affected by the ESR, ESL and bulk capacitance as shown in Figure 15. The total output ripple voltage is: 1 ESR ∆VOUT =IO(MAX) + f •COUT 1–DMAX where the first term is due to the bulk capacitance and second term due to the ESR. ∆VCOUT VOUT (AC) ∆VESR RINGING DUE TO TOTAL INDUCTANCE (BOARD + CAP) Figure 15. Output Voltage Ripple Waveform for a Boost Converter The choice of output capacitor is driven also by the RMS ripple current requirement. The RMS ripple current is: I RMS(COUT) ≈ IO(MAX) • VO – VIN(MIN) VIN(MIN) At lower output voltages (less than 30V), it may be possible to satisfy both the output ripple voltage and RMS ripple current requirements with one or more capacitors of a single capacitor type. However, at output voltages above 30V where capacitors with both low ESR and high bulk capacitance are hard to find, the best approach is to use a combination of aluminum and ceramic capacitors (see discussion in Input Capacitor section for the buck converter). With this combination, the ripple voltage can be improved significantly. The low ESR ceramic capacitor will minimize the ESR step, while the electrolytic will supply the required bulk capacitance. Boost Converter: Input Capacitor Selection The input capacitor of a boost converter is less critical than the output capacitor, due to the fact that the inductor is in series with the input and the input current waveform is continuous. The input voltage source impedance determines the size of the input capacitor, which is typically in the range of 10µF to 100µF. A low ESR capacitor is recommended though not as critical as for the output capacitor. The RMS input capacitor ripple current for a boost converter is: IRMS(CIN) = 0.3 • VIN(MIN) L•f •DMAX Please note that the input capacitor can see a very high surge current when a battery is suddenly connected to the input of the converter and solid tantalum capacitors can fail catastrophically under these conditions. Be sure to specify surge-tested capacitors! Boost Converter: Current Limit Programming The LTC3703 provides current limiting in boost mode by monitoring the VDS of the main switch during its on-time and comparing it to the voltage at IMAX. To set the current limit, calculate the expected voltage drop across the MOSFET at the maximum desired inductor current and maximum junction temperature. The maximum inductor current is a function of both duty cycle and maximum load current, so the limit must be set for the maximum 3703fc 22 LTC3703 Applications Information expected duty cycle (minimum VIN) in order to ensure that the current limit does not kick in at loads < IO(MAX): VPROG = IO(MAX) 1–DMAX RDS(ON)(1+ δ) V = OUT IO(MAX) •RDS(ON)(1+ δ) VIN(MIN) GAIN (dB) AV PHASE (DEG) GAIN –12dB/OCT 0 0 –90 PHASE Once VPROG is determined, RIMAX is chosen as follows: –180 RIMAX = VPROG/12µA Note that in a boost mode architecture, it is only possible to provide protection for “soft” shorts where VOUT > VIN. For hard shorts, the inductor current is limited only by the input supply capability. Refer to Current Limit Programming for buck mode for further considerations for current limit programming. Boost Converter: Feedback Loop/Compensation Compensating a voltage mode boost converter is unfortunately more difficult than for a buck converter. This is due to an additional right-half plane (RHP) zero that is present in the boost converter but not in a buck. The additional phase lag resulting from the RHP zero is difficult if not impossible to compensate even with a Type 3 loop, so the best approach is usually to roll off the loop gain at a lower frequency than what could be achievable in buck converter. A typical gain/phase plot of a voltage mode boost converter is shown in Figure 16. The modulator gain and phase can be measured as described for a buck converter or can be estimated as follows: GAIN (COMP-to-VOUT DC gain) = 20Log(VOUT2/VIN) Dominant Pole: fP = VIN 1 • VOUT 2π LC Since significant phase shift begins at frequencies above the dominant LC pole, choose a crossover frequency no greater than about half this pole frequency. The gain of the compensation network should equal –GAIN at this frequency so that the overall loop gain is 0dB here. The 3703 F16 Figure 16. Transfer Function of Boost Modulator compensation component to achieve this, using a Type 1 amplifier (see Figure 12), is: G = 10–GAIN/20 C1 = 1/(2π • f • G • R1) Run/Soft-Start Function The RUN/SS pin is a multipurpose pin that provide a softstart function and a means to shut down the LTC3703. Soft-start reduces the input supply’s surge current by gradually increasing the duty cycle and can also be used for power supply sequencing. Pulling RUN/SS below 0.9V puts the LTC3703 into a low quiescent current shutdown (IQ ≅ 50µA). This pin can be driven directly from logic as shown in Figure 17. Releasing the RUN/SS pin allows an internal 4µA current source to RUN/SS 2V/DIV VOUT 5V/DIV IL 2A/DIV VIN = 50V ILOAD = 2A CSS = 0.01µF 2ms/DIV 3703 F17 Figure 17. LTC3703 Start-Up Operation 3703fc 23 LTC3703 Applications Information charge up the soft-start capacitor CSS. When the voltage on RUN/SS reaches 0.9V, the LTC3703 begins operating at its minimum on-time. As the RUN/SS voltage increases from 1.4V to 3V, the duty cycle is allowed to increase from 0% to 100%. The duty cycle control minimizes input supply inrush current and eliminates output voltage overshoot at start-up and ensures current limit protection even with a hard short. The RUN/SS voltage is internally clamped at 4V. If RUN/SS starts at 0V, the delay before starting is approximately: tDELAY,START = 1V C = (0.25s/µF)CSS 4µA SS plus an additional delay, before the output will reach its regulated value, of: tDELAY,REG ≥ 3V – 1V C = (0.5s/µF)CSS 4µA SS The start delay can be reduced by using diode D1 in Figure 18. 3.3V OR 5V RUN/SS RUN/SS D1 CSS CSS 3703 F18 Figure 18. RUN/SS Pin Interfacing MODE/SYNC Pin (Operating Mode and Secondary Winding Control) The MODE/SYNC pin is a dual function pin that can be used for enabling or disabling pulse-skip mode operation and also as an external clock input for synchronizing the internal oscillator (see next section). Pulse-skip mode is enabled when the MODE/SYNC pin is above 0.8V and is disabled, i.e., forced continuous, when the pin is below 0.8V. In addition to providing a logic input to force continuous operation and external synchronization, the MODE/SYNC pin provides a means to regulate a flyback winding output as shown in Figure 10c. The auxiliary output is taken from a second winding on the core of the inductor, converting it to a transformer. The auxiliary output voltage is set by the main output voltage and the turns ratio of the extra winding to the primary winding as follows: VSEC ≈ (N + 1)VOUT Since the secondary winding only draws current when the synchronous switch is on, load regulation at the auxiliary output will be relatively good as long as the main output is running in continuous mode. As the load on the primary output drops and the LTC3703 switches to pulse-skip mode operation, the auxiliary output may not be able to maintain regulation, especially if the load on the auxiliary output remains heavy. To avoid this, the auxiliary output voltage can be divided down with a conventional feedback resistor string with the divided auxiliary output voltage fed back to the MODE/SYNC pin. The MODE/SYNC threshold is trimmed to 800mV with 20mV of hysteresis, allowing precise control of the auxiliary voltage and is set as follows: R1 VSEC(MIN) ≈ 0.8V 1+ R2 where R1 and R2 are shown in Figure 10c. If the LTC3703 is operating in pulse-skip mode and the auxiliary output voltage drops below VSEC(MIN), the MODE/ SYNC pin will trip and the LTC3703 will resume continuous operation regardless of the load on the main output. Thus, the MODE/SYNC pin removes the requirement that power must be drawn from the inductor primary in order to extract power from the auxiliary winding. With the loop in continuous mode (MODE/SYNC < 0.8V), the auxiliary outputs may nominally be loaded without regard to the primary output load. The following table summarizes the possible states available on the MODE/SYNC pin: Table 1 MODE/SYNC PIN CONDITION DC Voltage: 0V to 0.75V Forced Continuous Current Reversal Enabled DC Voltage: ≥ 0.87V Pulse-Skip Mode Operation No Current Reversal Feedback Resistors Regulating a Secondary Winding Ext. Clock: 0V to ≥ 2V Forced Continuous Current Reversal Enabled 3703fc 24 LTC3703 Applications Information MODE/SYNC Pin (External Synchronization) The internal LTC3703 oscillator can be synchronized to an external oscillator by applying and clocking the MODE/ SYNC pin with a signal above 2VP-P . The internal oscillator locks to the external clock after the second clock transition is received. When external synchronization is detected, LTC3703 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 RSET resistor. The internal oscillator can synchronize to frequencies between 100kHz and 600kHz, independent of the frequency programmed by the RSET resistor. However, it is recommended that an RSET resistor be chosen such that the frequency programmed by the RSET resistor is close to the expected frequency of the external clock. In this way, the best converter operation (ripple, component stress, etc) is achieved if the external clock signal is lost. Fault Conditions: Output Overvoltage Protection (Crowbar) The output overvoltage crowbar is designed to blow a system fuse in the input lead when the output of the regulator rises much higher than nominal levels. This condition causes huge currents to flow, much greater than in normal operation. This feature is designed to protect against a shorted top MOSFET; it does not protect against a failure of the controller itself. The comparator (MAX in the Functional Diagram) detects overvoltage faults greater than 5% above the nominal output voltage. When this condition is sensed the top MOSFET is turned off and the bottom MOSFET is forced on. The bottom MOSFET remains on continuously for as long as the 0V condition persists; if VOUT returns to a safe level, normal operation automatically resumes. Minimum On-Time Considerations (Buck Mode) Minimum on-time tON(MIN) is the smallest amount of time that the LTC3703 is capable of turning the top MOSFET on and off again. It is determined by internal timing delays and the amount of gate charge required to turn on the top MOSFET. Low duty cycle applications may approach this minimum on-time limit and care should be taken to ensure that: tON = VOUT >t VIN • f ON(MIN) where tON(MIN) is typically 200ns. If the duty cycle falls below what can be accommodated by the minimum on-time, the LTC3703 will begin to skip cycles. The output will be regulated, but the ripple current and ripple voltage will increase. If lower frequency operation is acceptable, the on-time can be increased above tON(MIN) for the same step-down ratio. Pin Clearance/Creepage Considerations The LTC3703 is available in two packages (GN16 and G28) both with identical functionality. The GN16 package gives the smallest size solution, however the 0.013" (minimum) space between pins may not provide sufficient PC board trace clearance between high and low voltage pins in higher voltage applications. Where clearance is an issue, the G28 package should be used. The G28 package has four unconnected pins between the all adjacent high voltage and low voltage pins, providing 5(0.0106") = 0.053" clearance which will be sufficient for most applications up to 100V. For more information, refer to the printed circuit board design standards described in IPC-2221 (www.ipc.org). Efficiency Considerations The efficiency of a switching regulator is equal to the output power divided by the input power (x100%). Percent efficiency can be expressed as: %Efficiency = 100% – (L1 + L2 + L3 + ...) where L1, L2, etc. are the individual losses as a percentage of input power. It is often useful to analyze the individual losses to determine what is limiting the efficiency and what change would produce the most improvement. Although all dissipative elements in the circuit produce losses, four main sources usually account for most of the losses in LTC3703 circuits: 1) LTC3703 VCC current, 2) MOSFET gate current, 3) I2R losses, 4) Topside MOSFET transition losses. 3703fc 25 LTC3703 Applications Information 1. VCC supply current. The VCC current is the DC supply current given in the Electrical Characteristics table which powers the internal control circuitry of the LTC3703. Total supply current is typically about 2.5mA and usually results in a small (<1%) loss which is proportional to VCC. 2. DRVCC current is MOSFET driver current. This current results from switching the gate capacitance of the power MOSFETs. Each time a MOSFET gate is switched on and then off, a packet of gate charge QG moves from DRVCC to ground. The resulting dQ/dt is a current out of the DRVCC supply. In continuous mode, IDRVCC = f(QG(TOP) + QG(BOT)), where QG(TOP) and QG(BOT) are the gate charges of the top and bottom MOSFETs. 3. I2R losses are predicted from the DC resistances of MOSFETs, the inductor and input and output capacitor ESR. In continuous mode, the average output current flows through L but is “chopped” between the topside MOSFET and the synchronous MOSFET. If the two MOSFETs have approximately the same RDS(ON), then the resistance of one MOSFET can simply be summed with the DCR resistance of L to obtain I2R losses. For example, if each RDS(ON) = 25mΩ and RL = 25mΩ, then total resistance is 50mΩ. This results in losses ranging from 1% to 5% as the output current increases from 1A to 5A for a 5V output. 4. Transition losses apply only to the topside MOSFET in buck mode and they become significant when operating at higher input voltages (typically 20V or greater). Transition losses can be estimated from the second term of the PMAIN equation found in the Power MOSFET Selection section. The transition losses can become very significant at the high end of the LTC3703 operating voltage range. To improve efficiency, one may consider lowering the frequency and/or using MOSFETs with lower CRSS at the expense of higher RDS(ON). Other losses including CIN and COUT ESR dissipative losses, Schottky conduction losses during dead time, and inductor core losses generally account for less than 2% total additional loss. Transient Response Due to the high gain error amplifier and line feedforward compensation of the LTC3703, the output accuracy due to DC variations in input voltage and output load current will be almost negligible. For the few cycles following a load transient, however, the output deviation may be larger while the feedback loop is responding. Consider a typical 48V input to 5V output application circuit, subjected to a 1A to 5A load transient. Initially, the loop is in regulation and the DC current in the output capacitor is zero. Suddenly, an extra 4A (= 5A – 1A) flows out of the output capacitor while the inductor is still supplying only 1A. This sudden change will generate a (4A) • (RESR) voltage step at the output; with a typical 0.015Ω output capacitor ESR, this is a 60mV step at the output. The feedback loop will respond and will move at the bandwidth allowed by the external compensation network towards a new duty cycle. If the unity-gain crossover frequency is set to 50kHz, the COMP pin will get to 60% of the way to 90% duty cycle in 3µs. Now the inductor is seeing 43V across itself for a large portion of the cycle and its current will increase from 1A at a rate set by di/ dt = V/L. If the inductor value is 10µH, the peak di/dt will be 43V/10µH or 4.3A/µs. Sometime in the next few microseconds after the switch cycle begins, the inductor current will have risen to the 5A level of the load current and the output voltage will stop dropping. At this point, the inductor current will rise somewhat above the level of the output current to replenish the charge lost from the output capacitor during the load transient. With a properly compensated loop, the entire recovery time will be inside of 10µs. Most loads care only about the maximum deviation from ideal, which occurs somewhere in the first two cycles after the load step hits. During this time, the output capacitor does all the work until the inductor and control loop regain control. The initial drop (or rise if the load steps down) is entirely controlled by the ESR of the capacitor and amounts to most of the total voltage drop. To minimize this drop, choose a low ESR capacitor and/or parallel multiple capacitors at the output. The capacitance value accounts for the rest of the voltage drop until the inductor current rises. 3703fc 26 LTC3703 Applications Information With most output capacitors, several devices paralleled to get the ESR down will have so much capacitance that this drop term is negligible. Ceramic capacitors are an exception; a small ceramic capacitor can have suitably low ESR with relatively small values of capacitance, making this second drop term more significant. RLOAD Measurement Techniques Measuring transient response presents a challenge in two respects: obtaining an accurate measurement and generating a suitable transient to test the circuit. Output measurements should be taken with a scope probe directly across the output capacitor. Proper high frequency probing techniques should be used. In particular, don’t use the 6" ground lead that comes with the probe! Use an adapter that fits on the tip of the probe and has a short ground clip to ensure that inductance in the ground path doesn’t cause a bigger spike than the transient signal being measured. Conveniently, the typical probe tip ground clip is spaced just right to span the leads of a typical output capacitor. Now that we know how to measure the signal, we need to have something to measure. The ideal situation is to use the actual load for the test and switch it on and off while watching the output. If this isn’t convenient, a current step generator is needed. This generator needs to be able to turn on and off in nanoseconds to simulate a typical switching logic load, so stray inductance and long clip leads between the LTC3703 and the transient generator must be minimized. Figure 19 shows an example of a simple transient generator. Be sure to use a noninductive resistor as the load element—many power resistors use an inductive spiral pattern and are not suitable for use here. A simple solution IRFZ44 OR EQUIVALENT PULSE GENERATOR 50Ω 0V TO 10V 100Hz, 5% DUTY CYCLE Optimizing Loop Compensation Loop compensation has a fundamental impact on transient recovery time, the time it takes the LTC3703 to recover after the output voltage has dropped due to a load step. Optimizing loop compensation entails maintaining the highest possible loop bandwidth while ensuring loop stability. The feedback component selection section describes in detail the techniques used to design an optimized Type 3 feedback loop, appropriate for most LTC3703 systems. VOUT LTC3703 3703 F19 LOCATE CLOSE TO THE OUTPUT Figure 19. Transient Load Generator is to take ten 1/4W film resistors and wire them in parallel to get the desired value. This gives a noninductive resistive load which can dissipate 2.5W continuously or 50W if pulsed with a 5% duty cycle, enough for most LTC3703 circuits. Solder the MOSFET and the resistor(s) as close to the output of the LTC3703 circuit as possible and set up the signal generator to pulse at a 100Hz rate with a 5% duty cycle. This pulses the LTC3703 with 500µs transients 10ms apart, adequate for viewing the entire transient recovery time for both positive and negative transitions while keeping the load resistor cool. Design Example As a design example, take a supply with the following specifications: VIN = 36V to 72V (48V nominal), VOUT = 12V ±5%, IOUT(MAX) = 10A, f = 250kHz. First, calculate RSET to give the 250kHz operating frequency: RSET = 7100/(250 – 25) = 31.6k Next, choose the inductor value for about 40% ripple current at maximum VIN: L= 12V 12 1– = 10µH (250kHz)(0.4)(10A) 72 With 10µH inductor, ripple current will vary from 3.2A to 4A (32% to 40%) over the input supply range. Next, verify that the minimum on-time is not violated. The minimum on-time occurs at maximum VIN: tON(MIN) = VOUT 12 = 667ns VIN(MIN)(f) 72(250kHz) = which is above the LTC3703’s 200ns minimum on-time. 3703fc 27 LTC3703 Applications Information Next, choose the top and bottom MOSFET switch. Since the drain of each MOSFET will see the full supply voltage 72V (max) plus any ringing, choose a 100V MOSFET to provide a margin of safety. Si7456DP has a 100V BVDSS, RDS(ON) = 25mΩ (max), δ = 0.009/°C, CMILLER = (19nC – 10nC)/50V = 180pF, VGS(MILLER) = 4.7V, θJA = 20°C/W. The power dissipation can be estimated at maximum input voltage, assuming a junction temperature of 100°C (30°C above an ambient of 70°C): 12 (10)2 [1+ 0.009(100 – 25)](0.025) 72 1 1 10 +(72)2 (2)(180pF)• + (250k) 2 10 – 4.7 4.7 = 0.70W + 0.94W = 1.64W PMAIN = And double check the assumed TJ in the MOSFET: TJ = 70°C + (1.64W)(20°C/W) = 103°C Since the synchronous MOSFET will be conducting over twice as long each period (almost 100% of the period in short circuit) as the top MOSFET, use two Si7456DP MOSFETs on the bottom: 72−12 PSYNC = (10)2 [1+ 0.009(100 – 25)] • 72 0.025 = 1.74W 2 TJ = 70°C + (1.74W)(20°C/W) = 105°C Next, set the current limit resistor. Since IMAX = 10A, the limit should be set such that the minimum current limit is >10A. Minimum current limit occurs at maximum RDS(ON). Using the above calculation for bottom MOSFET TJ, the max RDS(ON) = (25mΩ/2) [1 + 0.009 (105-25)] = 21.5mΩ. Therefore, IMAX pin voltage should be set to (10A)(0.0215) = 0.215V. The RSET resistor can now be chosen to be 0.215V/12µA = 18k. CIN is chosen for an RMS current rating of about 5A (IMAX/2) at 85°C. For the output capacitor, two low ESR OS-CON capacitors (18mΩ each) are used to minimize output voltage changes due to inductor current ripple and load steps. The ripple voltage will be: ∆VOUT(RIPPLE) = ∆IL(MAX) (ESR) = (4A)(0.018Ω/2) = 36mV However, a 0A to 10A load step will cause an output voltage change of up to: ∆VOUT(STEP) = ∆ILOAD(ESR) = (10A)(0.009Ω) = 90mV PC Board Layout Checklist When laying out the printed circuit board, the following checklist should be used to ensure proper operation of the LTC3703. These items are also illustrated graphically in the layout diagram of Figure 18. For layout of a boost mode converter, layout is similar with VIN and VOUT swapped. Check the following in your layout: 1. Keep the signal and power grounds separate. The signal ground consists of the LTC3703 GND pin, the ground return of CVCC, and the (–) terminal of VOUT. The power ground consists of the Schottky diode anode, the source of the bottom side MOSFET, and the (–) terminal of the input capacitor and DRVCC capacitor. Connect the signal and power grounds together at the (–) terminal of the output capacitor. Also, try to connect the (–) terminal of the output capacitor as close as possible to the (–) terminals of the input and DRVCC capacitor and away from the Schottky loop described in (2). 2. The high di/dt loop formed by the top N-channel MOSFET, the bottom MOSFET and the CIN capacitor should have short leads and PC trace lengths to minimize high frequency noise and voltage stress from inductive ringing. 3. Connect the drain of the top side MOSFET directly to the (+) plate of CIN, and connect the source of the bottom side MOSFET directly to the (–) terminal of CIN. This capacitor provides the AC current to the MOSFETs. 4. Place the ceramic CDRVCC decoupling capacitor immediately next to the IC, between DRVCC and BGRTN. This capacitor carries the MOSFET drivers’ current peaks. Likewise the CB capacitor should also be next to the IC between BOOST and SW. 3703fc 28 LTC3703 Applications Information 7. For optimum load regulation and true remote sensing, the top of the output resistor divider should connect independently to the top of the output capacitor (Kelvin connection), staying away from any high dV/dt traces. Place the divider resistors near the LTC3703 in order to keep the high impedance FB node short. 5. Place the small-signal components away from high frequency switching nodes (BOOST, SW, TG, and BG). In the layout shown in Figure 20, all the small-signal components have been placed on one side of the IC and all of the power components have been placed on the other. This also helps keep the signal ground and power ground isolated. 8. For applications with multiple switching power converters connected to the same input supply, make sure that the input filter capacitor for the LTC3703 is not shared with other converters. AC input current from another converter could cause substantial input voltage ripple, and this could interfere with the operation of the LTC3703. A few inches of PC trace or wire (L ≅ 100nH) between CIN of the LTC3703 and the actual source VIN should be sufficient to prevent input noise interference problems. 6. A separate decoupling capacitor for the supply, VCC, is useful with an RC filter between the DRVCC supply and VCC pin to filter any noise injected by the drivers. Connect this capacitor close to the IC, between the VCC and GND pins and keep the ground side of the VCC capacitor (signal ground) isolated from the ground side of the DRVCC capacitor (power ground). VCC 1 RSET RC1 CC1 CC2 R2 RC2 CC3 R1 5 6 CSS DB 16 M1 15 BOOST LTC3703 14 3 TG COMP 2 4 RMAX MODE/SYNC VIN VIN 7 8 fSET FB SW IMAX VCC INV RUN/SS GND DRVCC BG BGRTN + CIN CB 13 L1 12 RF 11 10 CDRVCC X5R 9 M2 D1 COUT + + VOUT – CVCC X5R 3703 F18 Figure 20. LTC3703 Buck Converter Suggested Layout 3703fc 29 LTC3703 Typical Applications 36V-72V Input Voltage to 5V/10A Step-Down Converter with Pulse Skip Mode Enabled VCC 9.3V TO 15V + RC1 10k CC1 470pF CC2 1000pF R2 21.5k 1% RC2 100Ω CC3 2200pF R1 113k 1% 22µF 25V 1 16 MODE/SYNC VIN RSET 25k 2 15 fSET BOOST LTC3703 3 14 TG COMP RMAX 20k 4 5 6 CSS 0.1µF 7 8 FB SW IMAX VCC INV RUN/SS GND DRVCC BG BGRTN VIN 36V TO 72V DB BAS19 M1 Si7852DP CB 0.1µF 13 L1 4.7µH 12 11 CIN 68µF 100V ×2 + RF 10Ω M2 Si7852DP 10 CDRVCC 10µF 9 VOUT 5V 10A COUT 270µF 10V ×2 + D1 MBR1100 CVCC 1µF 3703 TA01 Single Input Supply 12V/5A Output Step-Down Converter 100Ω 10k FZT600 * VIN 15V TO 80V 12V + 1 RSET 25k RC1 10k CC1 470pF CC2 1000pF R2 8.06k 1% RC2 100Ω CC3 2200pF R1 113k 1% RMAX 12k 2 4 5 7 8 fSET FB SW IMAX VCC INV RUN/SS GND DB BAS19 + 15 BOOST LTC3703 3 14 TG COMP 6 CSS 0.1µF MODE/SYNC VIN 16 22µF 25V DRV CC BG BGRTN CB 0.1µF 13 M1 Si7852DP CIN 68µF 100V L1 8µH VOUT 12V 5A 12 11 RF 10Ω M2 Si7852DP 10 9 CDRVCC 10µF CMDSH-3 COUT 270µF 16V + D1 MBR1100 CVCC 1µF *OPTIONAL ZENER PROVIDES UNDERVOLTAGE LOCKOUT ON INPUT SUPPLY, VUVLO ≅ 10 + VZ 3703 TA02 3703fc 30 LTC3703 Package Description Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings. GN Package 16-Lead Plastic (Narrow .150 Inch) GNSSOP Package (Reference LTC DWG 05-08-1641 Rev Inch) B) 16-Lead Plastic SSOP# (Narrow .150 (Reference LTC DWG # 05-08-1641 Rev B) .189 – .196* (4.801 – 4.978) .045 ±.005 16 15 14 13 12 11 10 9 .254 MIN .009 (0.229) REF .150 – .165 .229 – .244 (5.817 – 6.198) .0165 ±.0015 .150 – .157** (3.810 – 3.988) .0250 BSC RECOMMENDED SOLDER PAD LAYOUT 1 .015 ±.004 × 45° (0.38 ±0.10) .007 – .0098 (0.178 – 0.249) .0532 – .0688 (1.35 – 1.75) 2 3 4 5 6 7 8 .004 – .0098 (0.102 – 0.249) 0° – 8° TYP .016 – .050 (0.406 – 1.270) NOTE: 1. CONTROLLING DIMENSION: INCHES INCHES 2. DIMENSIONS ARE IN (MILLIMETERS) .008 – .012 (0.203 – 0.305) TYP .0250 (0.635) BSC GN16 REV B 0212 3. DRAWING NOT TO SCALE 4. PIN 1 CAN BE BEVEL EDGE OR A DIMPLE *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE 3703fc 31 LTC3703 Package Description Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings. G Package 28-Lead Plastic SSOP (5.3mm) (Reference LTC DWG # 05-08-1640) 9.90 – 10.50* (.390 – .413) 28 27 26 25 24 23 22 21 20 19 18 17 16 15 1.25 ±0.12 7.8 – 8.2 5.3 – 5.7 0.42 ±0.03 7.40 – 8.20 (.291 – .323) 0.65 BSC 1 2 3 4 5 6 7 8 9 10 11 12 13 14 RECOMMENDED SOLDER PAD LAYOUT 2.0 (.079) MAX 5.00 – 5.60** (.197 – .221) 0° – 8° 0.09 – 0.25 (.0035 – .010) 0.55 – 0.95 (.022 – .037) NOTE: 1. CONTROLLING DIMENSION: MILLIMETERS MILLIMETERS 2. DIMENSIONS ARE IN (INCHES) 3. DRAWING NOT TO SCALE 0.65 (.0256) BSC 0.22 – 0.38 (.009 – .015) TYP 0.05 (.002) MIN G28 SSOP 0204 *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED .152mm (.006") PER SIDE **DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE 3703fc 32 LTC3703 Revision History (Revision history begins at Rev C) REV DATE DESCRIPTION PAGE NUMBER C 05/12 Note 10 Added. 4 3703fc 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. 33 LTC3703 Typical Application 12V to 24V/5A Synchronous Boost Converter + 1 RSET 30.1k 10k CC1 100pF 0.1µF RMAX 15k R1 113k 1% R2 3.92k 1% 2 4 5 7 8 DB CMDSH-3 16 B240A 15 BOOST LTC3703 3 14 TG COMP 6 CSS 0.1F MODE/SYNC VIN 22µF 25V fSET FB SW IMAX VCC INV DRVCC RUN/SS GND BG BGRTN CB 0.1µF 13 M1 Si7892DP COUT + 220µF 35V ×3 L1 3.3µH 12 RF 10Ω 11 M2 Si7892DP 10 CDRVCC 10µF 9 CIN 100µF 16V VIN 10V TO 15V + CVCC 1µF L1: VISHAY IHLPSOSOEZ CIN: OSCON 20SP180M VOUT 24V COUT2 5A 10µF 50V X5R ×2 3703 TA03 COUT1: SANYO 35MV220AX COUT2: UNITED CHEMICON NTS60X5R1H106MT 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 LT1339 High Power Synchronous DC/DC Controller VIN up to 60V, Drivers 10,000pF Gate Capacitance, IOUT ≤ 20A LTC1702A Dual, 2-Phase Synchronous DC/DC Controller 550kHz Operation, No RSENSE, 3V ≤ VIN ≤ 7V, IOUT ≤ 20A 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, Single Inductor ® LTC3703-5 60V Synchronous DC/DC Controller 4V ≤ VIN ≤ 60V, Voltage Mode, 1Ω Logic-Level MOSFET Drivers LT3800 60V Synchronous DC/DC Controller 4V ≤ VIN ≤ 60V, Current Mode, 1.23V ≤ VOUT ≤ 36V 3703fc 34 Linear Technology Corporation LT 0512 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 2003