LTC3856 2-Phase Synchronous Step-Down DC/DC Controller with Diffamp Description Features PolyPhase® Controller Reduces Input and Output Capacitance and Power Supply Induced Noise n Wide V Range: 4.5V to 38V Operation IN n ±0.75%, 0.6V Reference Voltage Accuracy n High Efficiency: Up to 95% n Programmable Burst Mode® Operation or Stage Shedding™ for Highest Light Load Efficiency n Active Voltage Positioning (AVP) n R SENSE or DCR Current Sensing n Programmable DCR Temperature Compensation n Phase-Lockable Fixed Frequency: 250kHz to 770kHz n True Remote Sense Differential Amplifier n Dual N-Channel MOSFET Synchronous Drive n V OUT Range: 0.6V to 5V without Differential Amplifier n V OUT Range: 0.6V to 3.3V with Differential Amplifier n Adjustable Soft-Start or V OUT Tracking n Stackable for Up to 12-Phase Operation n 32-Pin (5mm × 5mm) QFN and 38-Pin TSSOP Packages The LTC®3856 is a single output, dual channel PolyPhase synchronous step-down DC/DC controller that drives all N-channel power MOSFET stages. This device includes a high speed differential amplifier for remote output voltage sense. Power loss and supply noise are minimized by operating the two controller output stages out-of-phase and up to 12-phase operation can be achieved. n The LTC3856 monitors the output current by sensing the voltage drop across the output inductor (DCR) or by using a sense resistor. DCR temperature compensation maintains an accurate current sense threshold over a broad temperature range. A constant-frequency, current mode architecture allows a phase-lockable frequency of up to 770kHz. A wide 4.5V to 38V input supply range encompasses most intermediate bus voltages and battery chemistries. Burst Mode operation, continuous or Stage Shedding modes are supported. A TK/SS pin shared by both channels ramps the output voltage during start-up. Applications n n n n Telecom and Datacom Systems Industrial and Medical Instruments DC Power Distribution Systems Computer Systems L, LT, LTC, LTM, Linear Technology, the Linear logo, PolyPhase, Burst Mode and OPTI-LOOP are registered trademarks and Stage Shedding is a trademark of Linear Technology Corporation. All other trademarks are the property of their respective owners. Protected by U.S. Patents, including 5481178, 5705919, 5929620, 6100678, 6144194, 6177787, 6304066, 6498466, 6580258, 6611131, 6674274. Typical Application Efficiency and Power Loss vs Output Current High Efficiency 1.5V/50A Step-Down Converter DIFFOUT TG1 VIN VFB S 20k ILIM LTC3856 PGOOD CLKOUT PHASMD PLLIN S ITEMP BOOST2 SW2 S S INTVCC DIFFN SENSE2+ DIFFP SENSE2– ITH TK/SS GND AVP ISET 2200pF 1.5k 0.1µF VOUT 1.5V 50A S BG2 EXTVCC S 0.33µH 0.1µF S 70 100 Burst Mode OPERATION S 100µF s8 10 60 50 1 40 30 0 20 S 4.7µF VIN = 12V VOUT = 1.5V 80 SENSE1+ SENSE1– TG2 90 S BG1 MODE FREQ 0.33µH 0.1µF SW1 100 VIN 4.5V TO 20V POWER LOSS (W) RUN 122k S BOOST1 10µF s4 EFFICIENCY (%) 30.1k 10 0 0.1 1 10 LOAD CURRENT (A) –1 100 3856 TA01b S 3856 TA01a 3856f LTC3856 Absolute Maximum Ratings (Note 1) Input Supply Voltage (VIN).......................... 40V to –0.3V Topside Driver Voltages (BOOSTn)............. 46V to –0.3V Switch Voltage (SWn).................................... 40V to –5V INTVCC, RUN, PGOOD, EXTVCC, (BOOSTn – SWn).......................................... 6V to –0.3V SENSEn Voltages....................................... 5.5V to –0.3V MODE, PLLIN, ILIM, TK/SS, AVP, FREQ, ISET Voltages.............................. INTVCC to –0.3V DIFFP, DIFFN, DIFFOUT, PHASMD, ITEMP Voltages...................................... INTVCC to –0.3V ITH, VFB Voltages.................................... INTVCC to –0.3V INTVCC Peak Output Current.................................100mA Operating Junction Temperature Range (Notes 2, 3)............................................. –40°C to 125°C Storage Temperature Range.................... –65°C to 125°C Reflow Peak Body Temperature (UH Package)....... 260°C Lead Temperature (Soldering, 10 sec.) FE Package............................................................. 300°C Pin Configuration TOP VIEW 35 TG1 TG1 4 SW1 SENSE1– TOP VIEW CLKOUT 36 SW1 PLLIN 3 FREQ 37 CLKOUT SENSE1+ RUN 38 PLLIN 2 SENSE1+ 1 RUN SENSE1– FREQ NC 5 34 NC TK/SS 6 33 BOOST1 VFB 7 32 PGND1 ITH 8 31 BG1 VFB 2 23 BG1 30 VIN ITH 3 22 VIN SENSE2+ 13 26 PGND2 SENSE2– 14 25 NC DIFFP 15 24 BOOST2 DIFFN 16 23 TG2 DIFFOUT 17 22 SW2 ISET 18 21 PGOOD ILIM 19 20 MODE FE PACKAGE 38-LEAD PLASTIC TSSOP 19 BG2 SENSE2+ 7 18 BOOST2 SENSE2– 8 17 TG2 9 10 11 12 13 14 15 16 SW2 27 BG2 PGOOD PHASMD 12 20 EXTVCC PHASMD 6 MODE 28 EXTVCC 21 INTVCC 33 ITEMP 5 ILIM 29 INTVCC ISET ITEMP 11 39 DIFFOUT AVP 10 AVP 4 DIFFN 9 24 BOOST1 DIFFP SGND 32 31 30 29 28 27 26 25 TK/SS 1 UH PACKAGE 32-LEAD (5mm s 5mm) PLASTIC QFN TJMAX = 125°C, θJA = 34°C/W EXPOSED PAD (PIN 33) IS SGND/PGND, MUST BE SOLDERED TO PCB TJMAX = 125°C, θJA = 25°C/W EXPOSED PAD (PIN 39) IS SGND/PGND, MUST BE SOLDERED TO PCB 3856f LTC3856 Order Information LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE LTC3856EFE#PBF LTC3856EFE#TRPBF LTC3856FE 38-Lead Plastic TSSOP –40°C to 125°C LTC3856IFE#PBF LTC3856IFE#TRPBF LTC3856FE 38-Lead Plastic TSSOP –40°C to 125°C LTC3856EUH#PBF LTC3856EUH#TRPBF 3856 32-Lead (5mm × 5mm) Plastic QFN –40°C to 125°C LTC3856IUH#PBF LTC3856IUH#TRPBF 3856 32-Lead (5mm × 5mm) Plastic QFN –40°C to 125°C Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container. Consult LTC Marketing for information on non-standard lead based finish parts. 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/ Electrical Characteristics The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C (Note 2). VIN = 15V, VRUN = 5V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS Main Control Loops VIN Input Voltage 4.5 38 V VOUT Output Voltage 0.6 5.0 V VFB Regulated Feedback Voltage ITH Voltage = 1.2V, E-Grade (Note 4) ITH Voltage = 1.2V, I-Grade (Note 4) IFB Feedback Current (Note 4) VREFLNREG Reference Voltage Line Regulation VIN = 4.5V to 38V (Note 4) VLOADREG Output Voltage Load Regulation (Note 4) Measured in Servo Loop, ∆ITH Voltage = 1.2V to 0.7V Measured in Servo Loop, ∆ITH Voltage = 1.2V to 1.6V l l 0.5955 0.593 l l 0.600 0.6045 0.600 0.607 V V –15 –50 nA 0.002 0.02 %/V 0.01 –0.01 0.1 –0.1 % % gm Transconductance Amplifier gm ITH = 1.2V, Sink/Source 5µA (Note 4) 2.0 IQ Input DC Supply Current Normal Mode Shutdown (Note 5) VIN = 15V VRUN = 0V 4.0 40 DFMAX Maximum Duty Factor In Dropout; fOSC = 500kHz UVLO Undervoltage Lockout VINTVCC Ramping Down UVLO Hyst UVLO Hysteresis VOVL Feedback Overvoltage Lockout Measured at VFB l ISENSE+ SENSE+ Pins Bias Current Each Channel, VSENSE1,2 = 3.3V l ITEMP DCR Tempco Compensation Current VITEMP = 0.3V l 9 ITK/SS Soft-Start Charge Current VTK/SS = 0V l 1.0 VRUN RUN Pin On Threshold VRUN Rising l 1.1 VRUNHYS RUN Pin On Hysteresis VSENSE(MAX) Maximum Current Sense Threshold (E-Grade) VFB = 0.5V, VSENSE1,2 = 3.3V ILIM = 0V ILIM = Float ILIM = INTVCC l l l 25 45 68 30 50 75 35 55 82 mV mV mV Maximum Current Sense Threshold (I-Grade) VFB = 0.5V, VSENSE1,2 = 3.3V ILIM = 0V ILIM = Float ILIM = INTVCC l l l 23 43 66 30 50 75 37 57 84 mV mV mV VSENSE(MAX) l 93 94 3.0 3.2 mmho 70 % 3.4 0.6 0.64 mA µA V V 0.66 0.68 V ±1 ±2 µA 10 11 µA 1.25 1.5 µA 1.22 1.35 V 80 mV 3856f LTC3856 Electrical Characteristics The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C (Note 2). VIN = 15V, VRUN = 5V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS TG1,2 tr TG1,2 tf TG Transition Time Rise Time Fall Time (Note 6) CLOAD = 3300pF CLOAD = 3300pF MIN TYP MAX UNITS 25 25 ns ns BG1,2 tr BG1,2 tf BG Transition Time Rise Time Fall Time (Note 6) CLOAD = 3300pF CLOAD = 3300pF 25 25 ns ns TG/BG t1D Top Gate Off to Bottom Gate On Delay Synchronous Switch-On Delay Time CLOAD = 3300pF Each Driver 30 ns BG/TG t2D Bottom Gate Off to Top Gate On Delay Top Switch-On Delay Time CLOAD = 3300pF Each Driver 30 ns tON(MIN) Minimum On-Time (Note 7) 90 ns INTVCC Linear Regulator VINTVCC Internal VCC Voltage 6V < VIN ≤ 38V VLDO INT INTVCC Load Regulation ICC = 0mA to 20mA VEXTVCC EXTVCC Switchover Voltage EXTVCC Ramping Positive VLDO EXT EXTVCC Voltage Drop ICC = 20mA, VEXTVCC = 5V VLDOHYS EXTVCC Hysteresis 4.8 l 4.5 5.0 5.2 V 0.5 2.0 % 4.7 50 V 100 200 mV mV Oscillator and Phase-Locked Loop fNOM Nominal Frequency VFREQ = 1.2V 450 500 550 kHz fLOW Lowest Frequency VFREQ = 0V 210 250 290 kHz fHIGH Highest Frequency VFREQ ≥ 2.4V 700 770 850 kHz RMODE MODE Input Resistance IFREQ Frequency Setting Output Current CLKOUT Phase (Relative to Controller 1) CLKHIGH Clock High Output Voltage CLKLOW Clock Low Output Voltage 250 9 PHASMD = GND; Non Stage Shedding Mode PHASMD = FLOAT; Non Stage Shedding Mode PHASMD = INTVCC; Non Stage Shedding Mode Stage Shedding Mode 10 kΩ 11 60 90 120 180 4 µA Deg Deg Deg Deg 5 V 0 0.2 V 0.1 0.2 V ±2 µA PGOOD Output VPGL PGOOD Voltage Low IPGOOD = 2mA IPGOOD PGOOD Leakage Current VPGOOD = 5V VPG PGOOD Trip Level, Either Controller VFB with Respect to Set Output Voltage VFB Ramping Negative VFB Ramping Positive –10 10 % % 3856f LTC3856 Electrical Characteristics The l denotes the specifications which apply over the full operating junction temperature range, otherwise specifications are at TA = 25°C (Note 2). VIN = 15V, VRUN = 5V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS 0.998 0.997 1 1 1.002 1.003 V/V V/V Differential Amplifier ADA Gain E-Grade I-Grade RIN Input Resistance Measured at DIFFP Input VOS Input Offset Voltage VDIFFP = VDIFFOUT = 1.5V, IDIFFOUT = 100µA PSRR Power Supply Rejection Ratio 4.5V < VIN < 38V ICL Maximum Output Current VOUT(MAX) Maximum Output Voltage l l 80 2 2 IDIFFOUT = 300µA kΩ mV 100 dB 3 mA VINTVCC VINTVCC –1.4 –1.1 V On-Chip Driver TG RUP TG Pull-Up RDS(ON) TG High 2.6 Ω TG RDOWN TG Pull-Down RDS(ON) TG Low 1.5 Ω BG RUP BG Pull-Up RDS(ON) BG High 2.4 Ω BG RDOWN BG Pull-Down RDS(ON) BG Low 1.1 Ω GBW Gain-Bandwidth Product (Note 8) 3 MHz SR Slew Rate (Note 8) 2 V/µs Stage Shedding Mode IISET Programmable Stage Shedding Mode Current 6.5 7.5 8.5 µA AVP (Active Voltage Positioning) VAVP ISINK ISOURCE Maximum VOUT with AVP 2.5 V Sink Current of AVP Pin SENSE+ = 1.2V 250 µA Source Current of AVP Pin SENSE+ = 1.2V 2 mA SENSE+ = 1.2V 120 mV VAVP-VO(MAX) Maximum Voltage Drop VAVP to VO 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 LTC3856 is tested under pulse load conditions such that TJ ≈ TA. The LTC3856E is guaranteed to meet performance specifications from 0°C to 85°C operating junction temperature. Specifications over the –40°C to 125°C operating junction temperature range are assured by design, characterization and correlation with statistical process controls. The LTC3856I is guaranteed to meet performance specifications over the full –40°C to 125°C operating junction temperature range. Note 3: TJ is calculated from the ambient temperature, TA, and power dissipation, PD, according to the following formula: LTC3856UH: TJ = TA + (PD • 34°C/W) LTC3856FE: TJ = TA + (PD • 25°C/W) Note 4: The LTC3856 is tested in a feedback loop that servos VITH to a specified voltage and measures the resultant VFB. Note 5: Dynamic supply current is higher due to the gate charge being delivered at the switching frequency. See the Applications Information section. Note 6: Rise and fall times are measured using 10% and 90% levels. Delay times are measured using 50% levels. Note 7: The minimum on-time condition corresponds to the on inductor peak-to-peak ripple current ≥40% of IMAX (see Minimum On-Time Considerations in the Applications Information section). Note 8: Guaranteed by design. 3856f LTC3856 Typical Performance Characteristics Load Step: Burst Mode Operation Load Step: Forced Continuous Mode VBAT = 3.6V ILOAD ICPO = 200µA 40A/DIV CCPO = 2.2ΩF VBAT = 3.6V ILOAD ICPO = 200µA 40A/DIV CCPO = 2.2ΩF IL1 20A/DIV IL1 20A/DIV IL2 20A/DIV IL2 20A/DIV VOUT 200mV/DIV VOUT 200mV/DIV 3856 G01 100µs/DIV VIN = 12V VOUT = 1.5V ILOAD = 1A TO 40A VIN = 12V VOUT = 1.5V ILOAD = 1A TO 40A Efficiency vs Output Current and Mode Inductor Current at Light Load 100 80 70 60 Stage Shedding MODE 50 40 FORCED CONTINUOUS MODE Burst Mode OPERATION, 5A/DIV DCM OPERATION, 5A/DIV 30 20 VIN = 12V VOUT = 1.5V 10 0 0.1 1 10 LOAD CURRENT (A) VIN = 12V VOUT = 1.5V ILOAD = 400mA 100 VOUT 100mV/DIV VSW1 10V/DIV VSW1 10V/DIV VSW2 10V/DIV VSW2 10V/DIV 10µs/DIV 3856 G04 Stage Shedding Transition, 2-Phase to 1-Phase UNDERSHOOT 35mV VIN = 12V VOUT = 1.5V 1µs/DIV 3856 G03 Stage Shedding Transition, 1-Phase to 2-Phase VOUT 100mV/DIV 3856 G02 VBAT = 3.6V FORCED ICPO = 200µA CONTINUOUS CCPO = 2.2ΩF MODE, 5A/DIV Burst Mode OPERATION 90 EFFICIENCY (%) 100µs/DIV OVERSHOOT 36mV 3856 G05 VIN = 12V VOUT = 1.5V 10µs/DIV 3856 G06 3856f LTC3856 Typical Performance Characteristics Load Step without AVP Load Step with AVP 4.5 4.3 VOUT 50mV/DIV 54mV 50A IL 20A/DIV 50A IL 20A/DIV 25A 3856 G07 100µs/DIV VIN = 12V VOUT = 1.5V VIN = 12V VOUT = 1.5V 4.50 VSENSE (mV) 4.25 4.00 20 ILIM = GND 0 3.75 3.50 –20 3.25 20 25 INPUT VOLTAGE (V) 30 35 –40 40 ILIM = INTVCC 70 60 ILIM = FLOAT 40 ILIM = GND 30 20 10 0 3.1 2.9 10 20 30 40 50 60 70 80 90 100 DUTY CYCLE (%) 3856 G12 5 10 25 20 15 30 INPUT VOLTAGE (V) 35 40 3856 G08 1 1.5 60 ILIM = FLOAT 50 40 ILIM = GND 30 20 10 0 2 ILIM = INTVCC 70 0 3856 G10 Maximum Current Sense Voltage vs Feedback Voltage (Current Foldback) MAXIMUM CURRENT SENSE VOLTAGE (mV) 90 50 0.5 3856 G09 100 80 0 VITH (V) Maximum Current Sense Voltage vs Duty Cycle MAXIMUM CURRENT SENSE VOLTAGE (mV) ILIM = FLOAT 40 2 3 4 1 VSENSE COMMON MODE VOLTAGE (V) 5 3856 G11 TK/SS Pull-Up Current vs Temperature 100 1.5 90 80 1.4 ILIM = INTVCC TK/SS CURRENT (µA) INTVCC VOLTAGE (V) 4.75 15 3.3 80 60 10 3.5 Maximum Current Sense Threshold vs Common Mode Voltage CURRENT SENSE THRESHOLD (mV) 5.00 5 3.7 2.5 ILIM = INTVCC 0 3.9 2.7 80 5.25 0 3856 G07a 100µs/DIV 4.1 Current Sense Threshold vs ITH Voltage INTVCC Line Regulation 3.00 25A QUIESCENT CURRENT (mA) 108mV VOUT 50mV/DIV Quiescent Current vs Input Voltage without EXTVCC 70 60 ILIM = FLOAT 50 40 ILIM = GND 30 20 1.3 1.2 1.1 10 0 0 0.1 0.4 0.3 0.2 0.5 FEEDBACK VOLTAGE (V) 0.6 3856 G13 1.0 –50 –25 0 25 50 75 TEMPERATURE (°C) 100 125 3856 G14 3856f LTC3856 Typical Performance Characteristics Shutdown (RUN) Threshold vs Temperature 1.25 1.15 OFF 1.10 –50 –25 0 25 50 75 TEMPERATURE (°C) 700 0.603 0.602 0.601 0.600 –25 0 25 50 75 100 TEMPERATURE (°C) FREQUENCY (kHz) 3.4 75 100 125 3856 G17 60 500 490 OFF 40 30 20 10 480 50 75 100 TEMPERATURE (°C) 125 5 10 15 20 25 30 INPUT VOLTAGE (V) 35 0 40 0 5 10 15 3856 G19 6 60 5 QUIESCENT CURRENT (mA) 70 50 40 30 20 20 25 INPUT VOLTAGE (V) 3856 G18 Shutdown Current vs Temperature SHUTDOWN CURRENT (µA) 50 Shutdown Current vs Input Voltage 3.2 30 35 40 3856 G20 Quiescent Current vs Temperature without EXTVCC 4 3 2 1 10 0 –50 25 50 3.6 25 0 TEMPERATURE (°C) 510 0 –25 3856 G16 ON –25 VFREQ = GND 300 0 –50 125 520 3.8 3.0 –50 400 Oscillator Frequency vs Input Voltage 4.0 VFREQ = 1.2V 500 100 3856 G15 Undervoltage Lockout Threshold (INTVCC) vs Temperature 600 200 0.599 0.598 –50 100 125 150 VFREQ = INTVCC 800 0.604 INPUT CURRENT (µA) RUN PIN VOLTAGE (V) 1.20 900 FREQUENCY (kHz) REGULATED FEEDBACK VOLTAGE (mV) 0.605 ON UNDERVOLTAGE LOCKOUT THRESHOLD (INTVCC) (V) Oscillator Frequency vs Temperature Regulated Feedback Voltage vs Temperature –25 0 25 50 75 TEMPERATURE (°C) 100 125 0 –50 –25 0 25 50 75 TEMPERATURE (°C) 3856 G21 100 125 3856 G22 3856f LTC3856 Pin Functions (TSSOP/QFN) FREQ (Pin 1/Pin 29): Frequency Setting Pin. A resistor to ground sets the operating frequency of the controller. This pin can also be driven with a DC voltage to vary the frequency of the internal oscillator. RUN (Pin 2/Pin 30): Run Control Input. A voltage above 1.22V on this pin turns on the IC. There is a 1µA pull-up current for this pin. Once the RUN pin rises above 1.22V, an additional 4.5µA pull-up current is added to the pin. SENSE1+, SENSE2+ (Pins 3, 13/Pins 31, 7): Current Sense Comparator Inputs. The (+) inputs to the current comparators are normally connected to DCR sensing networks or current sensing resistors. SENSE1–, SENSE2– (Pins 4, 14/Pins 32, 8): Current Sense Comparator Inputs. The (–) inputs to the current comparators are connected to the outputs. NC (Pins 5, 25, 34) TSSOP Package: No Connections. TK/SS (Pin 6/Pin 1): Output Voltage Tracking and SoftStart Input. When one particular IC is configured to be the master of two ICs, a capacitor to ground at this pin sets the ramp rate for the master IC’s output voltage. When the IC is configured to be the slave of two ICs, the VFB voltage of the master IC is reproduced by a resistor divider and applied to this pin. An internal soft-start current of 1.25µA is charging this pin. VFB (Pin 7/Pin 2): Error Amplifier Feedback Input. This pin receives the remotely sensed feedback voltage from an external resistive divider. ITH (Pin 8/Pin 3): Current Control Threshold and Error Amplifier Compensation Point. Each associated channels’ current comparator tripping threshold increases with ITH control voltage. SGND (Pin 9/Pin 33): Signal Ground and Power Ground. All small-signal components and compensation components should connect to this ground, which in turn connects to PGND at one point. AVP (Pin 10/Pin 4): Active Voltage Positioning Load Slope Programming Pin. A resistor between this pin and the DIFFP pin sets the load slope. ITEMP (Pin 11/Pin 5): Input to the Temperature Sensing Circuit. Connect this pin to an external NTC (negative temperature coefficient) resistor placed near the heat source on the PCB board (e.g., inductors) changes the controller’s current limit with temperature. PHASMD (Pin 12/Pin 6): Connect this pin to SGND, INTVCC, or float this pin to select the phase of CLKOUT to be 60°, 120° and 90°, respectively. DIFFP (Pin 15/Pin 9): Positive Input of Remote Sensing Differential Amplifier. Connect this directly to the remote load voltage. DIFFN (Pin 16/Pin 10): Negative Input of Remote Sensing Differential Amplifier. Connect this pin to the negative terminal of output load capacitors. DIFFOUT (Pin 17/Pin 11): Output of Remote Sensing Differential Amplifier. Connect this pin to VFB through a resistive divider. ISET (Pin 18/Pin 12): Stage Shedding Mode Comparator and Burst Mode Comparator Programming Pin. A resistor to ground programs the threshold of the Stage Shedding mode comparator or Burst Mode comparator threshold and current limit. ILIM (Pin 19/Pin 13): Current Comparator Sense Voltage Range Input. This pin is to be programmed to SGND, FLOAT or INTVCC to set the maximum current sense threshold to one of three different levels for both comparators. MODE (Pin 20/Pin 14): Forced Continuous Mode, Burst Mode Operation or Stage Shedding Mode Selection Pin. Connect this pin to SGND to force IC in continuous mode of operation. Connect to INTVCC to enable Stage Shedding mode operation. Leaving the pin floating enables Burst Mode operation. PGOOD (Pin 21/Pin 15): Power Good Indicator Output. Open-drain logic out that is pulled to ground when the output exceeds the ±10% regulation window, after the internal 20µs power-bad mask timer expires. EXTVCC (Pin 28/Pin 20): External Power Input to an Internal Switch Connected to INTVCC. This switch closes and supplies the IC power, bypassing the internal low dropout regulator, whenever EXTVCC is higher than 4.7V. Do not exceed 6V on this pin and ensure VIN > VEXTVCC at all times. 3856f LTC3856 Pin Functions (TSSOP/QFN) INTVCC (Pin 29/Pin 21): Internal 5V Regulator Output. The control circuits are powered from this voltage. Decouple this pin to PGND with a minimum of 4.7µF low ESR tantalum or ceramic capacitor. the sources of the bottom N-channel MOSFETs, the (–) terminal of CVCC and the (–) terminal of CIN. All small-signal components and compensation components should also connect to this ground. VIN (Pin 30/Pin 22): Main Input Supply. Decouple this pin to PGND with a capacitor (0.1µF to 1µF). TG1, TG2 (Pins 35, 23/Pins 25, 17): Top Gate Driver Outputs. These are the outputs of floating drivers with a voltage swing equal to INTVCC superimposed on the switch nodes voltages. BG1, BG2 (Pins 31, 27/Pins 23, 19): Bottom Gate Driver Outputs. These pins drive the gates of the bottom N-channel MOSFETs between INTVCC and PGND. PGND1, PGND2 (Pins 32, 26) TSSOP Package: Power Ground Pin. Connect this pin closely to the sources of the bottom N-channel MOSFETs, the (–) terminal of CVCC and the (–) terminal of CIN. BOOST1, BOOST2 (Pins 33, 24/Pins 24, 18): Boosted Floating Driver Supplies. The (+) terminal of the bootstrap capacitors connect to these pins. These pins swing from a diode voltage drop below INTVCC up to VIN + INTVCC. SGND/PGND (Exposed Pad Pin 33) QFN Package: Signal Ground and Power Ground. Connect this pin closely to SW1, SW2 (Pins 36, 22/Pins 26, 16): Switch Node Connections to Inductors. Voltage swing at these pins is from a Schottky diode (external) voltage drop below ground to VIN. CLKOUT (Pin 37/Pin 27): Clock output with phase changeable by PHASMD to enable usage of multiple LTC3856 ICs in multiphase systems. PLLIN (Pin 38/Pin 28): External Synchronization Pin. A clock on the pin synchronizes the internal oscillator with the clock on this pin. SGND (Exposed Pad Pin 39) TSSOP Package: The exposed pad must be soldered to the PCB. 3856f 10 LTC3856 FUNCTIONAL Diagram EXTVCC ITEMP MODE PLLIN PHASMD 4.7V FREQ + – TEMPSNS 0.6V MODE/SYNC DETECT VIN F + 5V REG + – INTVCC BURSTEN CLKOUT FCNT OSC S + ICMP + – IREV ISET CB SENSE– L1 VOUT + BG CVCC PGND ILIM RAVP PGOOD SLOPE COMPENSATION DIFFOUT + INTVCC 1 51k ITHB UVLO UV + 0.54V VFB SLEEP – – + – – + + 0.5V RUN 1.25µA + EA SS 40k DIFFN 0.66V SGND RPRE-AVP AVP 1.22V + – 0.55V DIFFP 40k 40k R1 OV ISET + – SENSE1+ SENSE1– + – SENSE2+ SENSE2– 1µA ITH 3856 FD DIFFAMP 40k – + 0.6V REF R2 – SLOPE RECOVERY ACTIVE CLAMP VIN COUT M2 OV ISET TG SENSE+ RUN ISET DB M1 SWITCH LOGIC AND ANTISHOOTTHROUGH – BOOST SW ON R Q 3k CIN INTVCC F PLL-SYNC VIN RC CC1 RUN TK/SS CSS 3856f 11 LTC3856 Operation (Refer to Functional Diagram) Main Control Loop The LTC3856 uses a constant-frequency, current mode step-down architecture. During normal operation, each top MOSFET is turned on each cycle when the oscillator sets the RS latch, and turned off when the main current comparator, ICMP , resets each RS latch. The peak inductor current at which ICMP resets the RS latch is controlled by the voltage on the ITH pin, which is the output of the error amplifier, EA. The VFB pin receives a portion of output voltage feedback signal via the DIFFOUT pin (if DIFFAMP is used) through the external resistive divider and is compared to the internal reference voltage. When the load current increases, it causes a slight decrease in the VFB pin voltage relative to the 0.6V reference, which in turn causes the ITH voltage to increase until each inductor’s average current matches half of the new load current (assuming the two current sensing resistors are equal). In Burst Mode operation, after each top MOSFET has turned off, the bottom MOSFET is turned on until either the inductor current starts to reverse, as indicated by the reverse current comparator, IREV , or the beginning of the next cycle. The main control loop is shut down by pulling the RUN pin low. Releasing RUN allows an internal 1µA current source to pull up the RUN pin. When the RUN pin reaches 1.22V, the main control loop is enabled and the IC is powered up. When the RUN pin is low, all functions are kept in a controlled state. INTVCC/EXTVCC Power Power for the top and bottom MOSFET drivers and most other internal circuitry is derived from the INTVCC pin. When the EXTVCC pin is left open or tied to a voltage less than 4.7V, an internal 5V linear regulator supplies INTVCC power from VIN. If EXTVCC is taken above 4.7V, the 5V regulator is turned off and an internal switch is turned on connecting EXTVCC. Using the EXTVCC pin allows the INTVCC power to be derived from a high efficiency external source such as a switching regulator output. Each top MOSFET driver is biased from the floating bootstrap capacitor, CB, which normally recharges during each off cycle through an external diode when the top MOSFET turns off. If the input voltage, VIN, decreases to a voltage close to VOUT , the loop may enter dropout and attempt to turn on the top MOSFET continuously. The dropout detector detects this and forces the top MOSFET off for about one-twelfth of the clock period plus 100ns every third cycle to allow CB to recharge. However, it is recommended that a load be present or the IC operates at low frequency during the dropout transition to ensure CB is recharged. Shutdown and Start-Up (RUN and TK/SS Pins) The LTC3856 can be shut down using the RUN pin. Pulling the RUN pin below 1.22V shuts down the main control loop for the controller and most internal circuits, including the INTVCC regulator. Releasing the RUN pin allows an internal 1µA current to pull up the pin and enable the controller. Alternatively, the RUN pin may be externally pulled up or driven directly by logic. Be careful not to exceed the absolute maximum rating of 6V on this pin. The start-up of the controller’s output voltage, VOUT , is controlled by the voltage on the TK/SS pin. When the voltage on the TK/SS pin is less than the 0.6V internal reference, the LTC3856 regulates the VFB voltage to the TK/SS pin voltage instead of the 0.6V reference. This allows the TK/SS pin to be used to program a soft-start by connecting an external capacitor from the TK/SS pin to SGND. An internal 1.25µA pull-up current charges this capacitor, creating a voltage ramp on the TK/SS pin. As the TK/SS voltage rises linearly from 0V to 0.6V (and beyond), the output voltage, VOUT , rises smoothly from zero to its final value. Alternatively, the TK/SS pin can be used to cause the start-up of VOUT to track that of another supply. Typically, this requires connecting to the TK/SS pin an external resistor divider from the other supply to ground (see the Applications Information section). When the RUN pin is pulled low to disable the controller, or when INTVCC drops below its undervoltage lockout threshold of 3.2V, the TK/SS pin is pulled low by an internal MOSFET. When in undervoltage lockout, all phases of the controller are disabled and the external MOSFETs are held off. 3856f 12 LTC3856 Operation (Refer to Functional Diagram) Light Load Current Operation (Burst Mode Operation, Stage Shedding or Continuous Conduction) The LTC3856 can be enabled to enter high efficiency Burst Mode operation, Stage Shedding mode or forced continuous conduction mode. To select forced continuous operation, tie the MODE pin to a DC voltage below 0.6V (e.g., SGND). To select Stage Shedding mode of operation, tie the MODE pin to INTVCC. To select Burst Mode operation, float the MODE pin. When the controller is enabled for Burst Mode operation, the peak current in the inductor is set to approximately one-sixth of the maximum sense voltage even though the voltage on the ITH pin indicates a lower value. The peak current can be programmed by the ISET pin. If the average inductor current is higher than the load current, the error amplifier, EA, will decrease the voltage on the ITH pin. When the ITH voltage drops, the internal sleep signal goes high (enabling sleep mode) and the external MOSFETs are turned off. In sleep mode, the load current is supplied by the output capacitor. As the output voltage decreases, the EA’s output begins to rise. When the output voltage drops enough, the sleep signal goes low, and the controller resumes normal operation by turning on the top external MOSFET on the next cycle of the internal oscillator. When a controller is enabled for Burst Mode operation, the inductor current is not allowed to reverse. The reverse current comparator, IREV , turns off the bottom external MOSFET just before the inductor current reaches zero, preventing it from reversing and going negative. Thus, the controller operates in discontinuous operation. In forced continuous operation, the inductor current is allowed to reverse at light loads or under large transient conditions. The peak inductor current is determined by the voltage on the ITH pin, just as in normal operation. In this mode, the efficiency at light loads is lower than in Burst Mode operation. However, continuous mode has the advantages of lower output ripple and less interference with audio circuitry. When the MODE pin is connected to INTVCC, the LTC3856 operates in Stage Shedding mode at light loads. The controller will turn off channel 2 and increase the current gain of the first channel to ensure a smooth transition. The threshold where the controller goes into Stage Shedding mode is where the ITH voltage drops below 0.5V, but it can be programmed by the ISET pin. The inductor current is not allowed to reverse in this mode (discontinuous operation). At very light loads, the current comparator may remain tripped for several cycles and force the external top MOSFET to stay off for the same number of cycles (i.e., skipping pulses). This mode exhibits low output ripple as well as low audio noise and reduced RF interference as compared to Burst Mode operation. It provides a higher low current efficiency than forced continuous mode, but not nearly as high as Burst Mode operation. Multichip Operations (PHASMD and CLKOUT Pins) The LTC3856’s two channels are 180° out-of-phase, providing multiphase operation. This configuration can provide enough power for most of the high current applications. However, for even higher power applications, the LTC3856 can be configured for PolyPhase and multichip operation. The LTC3856 features PHASMD and CLKOUT pins which enable multiple LTC3856s to operate out-of-phase, as shown in Table 1. The CLKOUT signal is out-of-phase with respect to phase 1 of the controller depending on the PHASMD pin setting. In Stage Shedding mode, however, the CLKOUT signal is 180° out-of-phase with respect to phase 1 of the controller. Table 1. PHASMD GND FLOAT INTVCC Phase 1 0° 0° 0° Phase 2 180° 180° 240° CLKOUT 60° 90° 120° Frequency Selection and Phase-Locked Loop (FREQ and PLLIN Pins) The selection of switching frequency is a trade-off between efficiency and component size. Low frequency operation increases efficiency by reducing MOSFET switching losses, but requires larger inductance and/or capacitance to maintain low output ripple voltage. If the PLLIN pin is not being driven by an external clock source, the FREQ pin can be used to program the controller’s 3856f 13 LTC3856 Operation (Refer to Functional Diagram) operating frequency from 250kHz to 770kHz. There is a precision 10µA current flowing out of the FREQ pin enabling the user to program the controller’s switching frequency with a single resistor to SGND. A curve is provided later in the Applications Information section showing the relationship between the voltage on the FREQ pin and switching frequency. A phase-locked loop (PLL) is available on the LTC3856 to synchronize the internal oscillator to an external clock source that is connected to the PLLIN pin. The PLL loop filter network is integrated inside the LTC3856. The phase-locked loop is capable of locking any frequency within the range of 250kHz to 770kHz. The frequency setting resistor should always be present to set the controller’s initial switching frequency before locking to the external clock. Sensing the Output Voltage with a Differential Amplifier The LTC3856 includes a low offset, unity-gain, high bandwidth differential amplifier for applications that require true remote sensing. Sensing the load across the load capacitors directly greatly benefits regulation in high current, low voltage applications, where board interconnection losses can be a significant portion of the total error budget. The LTC3856 differential amplifier has a typical output slew rate of 2V/µs. The amplifier is configured for unity gain, meaning that the difference between DIFFP and DIFFN is translated to DIFFOUT, relative to SGND. Care should be taken to route the DIFFP and DIFFN PCB traces parallel to each other all the way to the terminals of the output capacitor or remote sensing points on the board. In addition, avoid routing these sensitive traces near any high speed switching nodes in the circuit. Ideally, the DIFFP and DIFFN traces should be shielded by a low impedance ground plane to maintain signal integrity. The maximum output voltage when using the differential amplifier is INTVCC – 1.4V (typically 3.6V). The differential amplifier should not be used above this voltage. Power Good (PGOOD Pin) The PGOOD pin is connected to an open drain of an internal N-channel MOSFET. The MOSFET turns on and pulls the PGOOD pin low when either VFB pin voltage is not within ±10% of the 0.6V reference voltage. The PGOOD pin is also pulled low when the RUN pin is below 1.22V or when the LTC3856 is in the soft-start or tracking phase. When the VFB pin voltage is within the ±10% regulation window, the MOSFET is turned off and the pin is allowed to be pulled up by an external resistor to a source of up to 6V. The PGOOD pin will flag power good immediately when VFB is within the regulation window. However, there is an internal 20µs power-bad mask when VFB goes out of the regulation window. Output Overvoltage Protection An overvoltage comparator, OV, guards against transient overshoots (>10%) as well as other more serious conditions that may overvoltage the output. In such cases, the top MOSFET is turned off and the bottom MOSFET is turned on until the overvoltage condition is cleared. Undervoltage Lockout The LTC3856 has two functions that help protect the controller in case of undervoltage conditions. A precision UVLO comparator constantly monitors the INTVCC voltage to ensure that an adequate gate-drive voltage is present. It locks out the switching action when INTVCC is below 3.2V. To prevent oscillation when there is a disturbance on the INTVCC, the UVLO comparator has 600mV of precision hysteresis. Another way to detect an undervoltage condition is to monitor the VIN supply. Because the RUN pin has a precision turn-on reference of 1.22V, one can use a resistor divider to VIN to turn on the IC when VIN is high enough. An extra 4.5µA of current flows out of the RUN pin once the RUN pin voltage passes 1.22V. The RUN comparator itself has about 80mV of hysteresis. One can program additional hysteresis for the RUN comparator by adjusting the values of the resistive divider. For accurate VIN undervoltage detection, VIN needs to be higher than 4.5V. 3856f 14 LTC3856 Applications Information The Typical Application on the first page of this data sheet is a basic LTC3856 application circuit. LTC3856 can be configured to use either DCR (inductor resistance) sensing or low value resistor sensing. The choice between the two current sensing schemes is largely a design trade-off between cost, power consumption and accuracy. DCR sensing is becoming popular because it saves expensive current sensing resistors and is more power efficient, especially in high current applications. However, current sensing resistors provide the most accurate current limits for the controller. Other external component selection is driven by the load requirement, and begins with the selection of RSENSE (if RSENSE is used) and inductor value. Next, the power MOSFETs are selected. Finally, input and output capacitors are selected. Current Limit Programming The ILIM pin is a tri-level logic input which sets the maximum current limit of the controller. When ILIM is either grounded, floated or tied to INTVCC, the typical value for the maximum current sense threshold will be 30mV, 50mV or 75mV, respectively. SENSE+ and SENSE– Pins The SENSE+ and SENSE– pins are the inputs to the current comparators. The common mode input voltage range of the current comparators is 0V to 5V. All SENSE+ pins are high impedance inputs with small currents of less than 1µA. The positive high impedance input to the current comparators allows accurate DCR sensing. All SENSE– pins and DIFFP should be connected directly to VOUT when DCR sensing is used. Care must be taken not to float these pins during normal operation. Filter components mutual to the sense lines should be placed close to the LTC3856, and the sense lines should run close together to a Kelvin connection underneath the current sense element (shown in Figure 1). Sensing current elsewhere can effectively add parasitic inductance and capacitance to the current sense element, degrading the information at the sense terminals and making the programmed current limit unpredictable. If DCR sensing is used (Figure 2b), sense resistor R1 should be placed close to the switching node, to prevent noise from coupling into sensitive small-signal nodes. The capacitor C1 should be placed close to the IC pins. TO SENSE FILTER, NEXT TO THE CONTROLLER Which setting should be used? For the best current limit accuracy, use the 75mV setting. The 30mV setting will allow for the use of very low DCR inductors or sense resistors, but at the expense of current limit accuracy. The 50mV setting is a good balance between the two. VIN INTVCC RS BG PGND SENSE+ SENSE– SGND VIN INTVCC RF ESL VIN LTC3856 BOOST SENSE RESISTOR PLUS PARASITIC INDUCTANCE SW 3856 F01 Figure 1. Sense Lines Placement with Sense Resistor VIN BOOST TG LTC3856 COUT RSENSE VOUT RS VOUT BG RP R1 C1* SGND RF DCR PGND SENSE+ RNTC CF L SW ITEMP CF • 2RF ≤ ESL/RS POLE-ZERO CANCELLATION INDUCTOR TG OPTIONAL TEMP COMP NETWORK R2 SENSE– 3856 F02a FILTER COMPONENTS PLACED NEAR SENSE PINS 3856 F02b (2a) Using a Resistor to Sense Current *PLACE C1 NEAR SENSE+, SENSE– PINS R1||R2 × C1 = L DCR RSENSE(EQ) = DCR R2 R1 + R2 (2b) Using the Inductor DCR to Sense Current Figure 2. Two Different Methods of Sensing Current 3856f 15 LTC3856 Applications Information Low Value Resistors Current Sensing A typical sensing circuit using a discrete resistor is shown in Figure 2a. RSENSE is chosen based on the required output current. The current comparator has a maximum threshold, VSENSE(MAX), determined by the ILIM setting. The input common mode range of the current comparator is 0V to 5V. The current comparator threshold sets the peak of the inductor current, yielding a maximum average output current, IMAX, equal to the peak value less half the peak-to-peak ripple current, ∆IL. To calculate the sense resistor value, use the equation: RSENSE = VSENSE(MAX ) I(MAX ) + ∆IL 2 Because of possible PCB noise in the current sensing loop, the AC current sensing ripple of ∆VSENSE = ∆IL • RSENSE also needs to be checked in the design to get a good signal-to-noise ratio. In general, for a reasonably good PCB layout, a 10mV ∆VSENSE voltage is recommended as a conservative number to start with, either for RSENSE or DCR sensing applications. For previous generation current mode controllers, the maximum sense voltage was high enough (e.g., 75mV for the LTC1628/LTC3728 family) that the voltage drop across the parasitic inductance of the sense resistor represented a relatively small error. For today’s highest current density solutions, however, the value of the sense resistor can be less than 1mΩ and the peak sense voltage can be as low as 20mV. In addition, inductor ripple currents greater than 50% with operation up to 1MHz are becoming more common. Under these conditions the voltage drop across the sense resistor’s parasitic inductance is no longer negligible. A typical sensing circuit using a discrete resistor is shown in Figure 2a. In previous generations of controllers, a small RC filter placed near the IC was commonly used to reduce the effects of capacitive and inductive noise coupled in the sense traces on the PCB. A typical filter consists of two series 10Ω resistors connected to a parallel 1000pF capacitor, resulting in a time constant of 20ns. This same RC filter, with minor modifications, can be used to extract the resistive component of the current sense signal in the presence of parasitic inductance. For example, Figure 3 illustrates the voltage waveform across a 2mΩ sense resistor with a 2010 footprint for the 1.2V/15A converter operating at 100% load. The waveform is the superposition of a purely resistive component and a purely inductive component. It was measured using two scope probes and waveform math to obtain a differential measurement. Based on additional measurements of the inductor ripple current and the on-time and off-time of the top switch, the value of the parasitic inductance was determined to be 0.5nH using the equation: ESL = VESL(STEP) tON • tOFF ∆IL tON + tOFF (1) If the RC time constant is chosen to be close to the parasitic inductance divided by the sense resistor (L/R), the resulting waveform looks resistive again, as shown in Figure 4. For applications using low maximum sense voltages, check the sense resistor manufacturer’s data VESL(STEP) VSENSE 20mV/DIV VSENSE 20mV/DIV 500ns/DIV 3856 F03 Figure 3. Voltage Waveform Measured Directly Across the Sense Resistor 500ns/DIV 3856 F04 Figure 4. Voltage Waveform Measured After the Sense Resistor Filter. CF = 1000pF, RF = 100Ω 3856f 16 LTC3856 Applications Information sheet for information about parasitic inductance. In the absence of data, measure the voltage drop directly across the sense resistor to extract the magnitude of the ESL step and use Equation 1 to determine the ESL. However, do not overfilter. Keep the RC time constant, less than or equal to the inductor time constant to maintain a high enough ripple voltage of ∆VSENSE. The equation generally applies to high density/high current applications where IMAX > 10A and low values of inductors are used. For applications where IMAX < 10A, set RF to 10Ω and CF to 1000pF. This will provide a good starting point. The filter components need to be placed close to the IC. The positive and negative sense traces need to be routed as a differential pair and Kelvin connected to the sense resistor. Inductor DCR Sensing For applications requiring the highest possible efficiency at high load currents, the LTC3856 is capable of sensing the voltage drop across the inductor DCR, as shown in Figure 2b. The DCR of the inductor represents the small amount of DC winding resistance of the copper, which can be less than 1mΩ for today’s low value, high current inductors. In a high current application requiring such an inductor, conduction loss through a sense resistor would cost several points of efficiency compared to DCR sensing. If the external R1|| R2 • C1 time constant is chosen to be exactly equal to the L/DCR time constant, the voltage drop across the external capacitor is equal to the drop across the inductor DCR multiplied by R2/(R1 + R2). R2 scales the voltage across the sense terminals for applications where the DCR is greater than the target sense resistor value. To properly dimension the external filter components, the DCR of the inductor must be known. It can be measured using a good RLC meter, but the DCR tolerance is not always the same and varies with temperature; consult the manufacturers’ data sheets for detailed information. Using the inductor ripple current value from the Inductor Value Calculation and Output Ripple Current section, the target sense resistor value is: RSENSE(EQUIV ) = VSENSE(MAX ) I(MAX ) + ∆IL 2 To ensure that the application will deliver full load current over the full operating temperature range, choose the minimum value for the maximum current sense threshold (VSENSE(MAX)) in the Electrical Characteristics table (25mV, 45mV or 68mV, depending on the state of the ILIM pin). Next, determine the DCR of the inductor. Where provided, use the manufacturer’s maximum value, usually given at 20°C. Increase this value to account for the temperature coefficient of resistance, which is approximately 0.4%/°C. A conservative value for TL(MAX) is 100°C. To scale the maximum inductor DCR to the desired sense resistor value, use the divider ratio: RD = RSENSE(EQUIV ) DCRMAX at TL(MAX ) C1 is usually selected to be in the range of 0.047µF to 0.47µF. This forces R1|| R2 to around 2k, reducing error that might have been caused by the SENSE+ pins’ ±1µA current. TL(MAX) is the maximum inductor temperature. The equivalent resistance R1|| R2 is scaled to the room temperature inductance and maximum DCR: R1|| R2 = L (DCR at 20°C ) • C1 The sense resistor values are: R1 = R1 • RD R1|| R2 ; R2 = RD 1 − RD 3856f 17 LTC3856 Applications Information The LTC3856 also features a DCR temperature compensation circuit by using a NTC temperature sensor. See the Inductor DCR Sensing Temperature Compensation and the ITEMP Pin section for details. The maximum power loss in R1 is related to duty cycle, and will occur in continuous mode at the maximum input voltage: PLOSS (V R1= IN(MAX ) − VOUT R1 )•V OUT Ensure that R1 has a power rating higher than this value. If high efficiency is necessary at light loads, consider this power loss when deciding whether to use DCR sensing or sense resistors. Light load power loss can be modestly higher with a DCR network than with a sense resistor, due to the extra switching losses incurred through R1. However, DCR sensing eliminates a sense resistor, reduces conduction losses and provides higher efficiency at heavy loads. Peak efficiency is about the same with either method. To maintain a good signal-to-noise ratio for the current sense signal, use a minimum ∆VSENSE of 10mV for duty cycles less than 40%. For a DCR sensing application, the actual ripple voltage will be determined by the equation: ∆VSENSE = VIN − VOUT VOUT R1• C1 VIN • fOSC Inductor DCR Sensing Temperature Compensation and the ITEMP Pin Inductor DCR current sensing provides a lossless method of sensing the instantaneous current. Therefore, it can provide higher efficiency for applications of high output currents. However, the DCR of the inductor, which is the small amount of DC winding resistance of the copper, typically has a positive temperature coefficient. As the temperature of the inductor rises, its DCR value increases. The current limit of the controller is therefore reduced. The LTC3856 offers a method to counter this inaccuracy by allowing the user to place an NTC temperature sensing resistor near the inductor to actively correct this error. The ITEMP pin, when left floating, is at a voltage around 5V and DCR temperature compensation is disabled. The ITEMP pin has a constant 10µA precision current flowing out of the pin. By connecting an NTC resistor from the ITEMP pin to SGND, the maximum current sense threshold can be varied over temperature according the following equation: VSENSEMAX( ADJ) = VSENSE(MAX ) • where: 1.8 – VITEMP 1.3 VSENSEMAX(ADJ) is the maximum adjusted current sense threshold at temperature. VSENSE(MAX) is the maximum current sense threshold specified in the Electrical Characteristics table. It is typically 75mV, 50mV or 30mV, depending on the setting ILIM pins. VITEMP is the voltage of the ITEMP pin. The valid voltage range for DCR temperature compensation on the ITEMP pin is between 0.5V to 0.2V, with 0.5V or above being no DCR temperature correction and 0.2V the maximum correction. However, if the duty cycle of the controller is less than 25%, the ITEMP range is extended from 0.5V to 0V. The NTC resistor has a negative temperature coefficient, meaning its value decreases as temperature rises. The VITEMP voltage, therefore, decreases as temperature increases and in turn, the VSENSEMAX(ADJ) will increase to compensate the DCR temperature coefficient. The NTC resistor, however, is nonlinear and the user can linearize its value by building a resistor network with regular resistors. Consult the NTC manufacture data sheets for detailed information. Another use for the ITEMP pins, in addition to NTC compensated DCR sensing, is adjusting VSENSE(MAX) to values between the nominal values of 30mV, 50mV and 75mV for a more precise current limit. This is done by applying a voltage less than 0.5V to the ITEMP pin. VSENSE(MAX) will be varied per the previous equation and the same duty cycle limitations will apply. The current limit can be adjusted using this method either with a sense resistor or DCR sensing. 3856f 18 LTC3856 Applications Information NTC Compensated DCR Sensing For DCR sensing applications where a more accurate current limit is required, a network consisting of an NTC thermistor placed from the ITEMP pin to ground will provide correction of the current limit over temperature. Figure 2b shows this network. Resistors RS and RP will linearize the impedance the ITEMP pin sees. To implement NTC compensated DCR sensing, design the DCR sense filter network per the same procedure mentioned in the previous selection, except calculate the divider components using the room temperature value of the DCR. For a typical application: The resistance of the NTC thermistor can be obtained from the vendor’s data sheet either in the form of graphs, tabulated data or formulas. The approximate value for the NTC thermistor for a given temperature can be calculated from the following equation: 1 − 1 R = RO • exp B • T + 273 TO + 273 Where R = resistance at temperature T, in degrees C RO = resistance at temperature TO , typically 25°C B = B-constant of the thermistor. 1.Set the ITEMP pin resistance to 50k at 25°C. With 10µA flowing out of the ITEMP pin, the voltage on the ITEMP pin will be 0.5V at room temperature. Current limit correction will occur for inductor temperatures greater than 25°C. Figure 5 shows a typical resistance curve for a 100k thermistor and the ITEMP pin network over temperature. 2.Calculate the ITEMP pin resistance and the maximum inductor temperature, which is typically 100°C. Use the following equations: • RS = 20k VITEMP100C VITEMP100C 10µA = 0 . 5V − 1 .33 • RITEMP100C = R2 0.4 IMAX • DCRMAX • • (100 °C − 25 °C) • R1 + R2 100 VSENSE(MAX ) Calculate the values for RP and RS. A simple method is to graph the following RS versus RP equations with RS on the y-axis and RP on the x-axis. RS = RITEMP25C – RNTC25C ||RP RS = RITEMP100C – RNTC100C ||RP Next, find the value of RP that satisfies both equations, which will be the point where the curves intersect. Once RP is known, solve for RS. • NTC RO = 100k • RP = 50k But, the final values should be calculated using the previous equations and checked at 25°C and 100°C. 10000 THERMISTOR RESISTANCE: RO = 100k TO = 25°C B = 4334 for 25°C/100°C 1000 RESISTANCE (k) Starting values for the NTC compensation network are: 100 10 RITMP: RS = 20k RP = 43.2k 100k NTC 0 –40 –20 0 20 40 60 80 100 120 INDUCTOR TEMPERATURE (°C) 3856 F05 Figure 5. Resistance vs Temperature for the ITEMP Pin Network and the 100k NTC 3856f 19 LTC3856 Applications Information After determining the components for the temperature compensation network, check the results by plotting IMAX versus inductor temperature using the following equations: • NTC RO = 100k, B-constant = 3000 to 4000 • RS ≈ 20k • RP ≈ 50k IMAX = VSENSEMAX( ADJ) − ∆ VSENSE 2 0.4 DCRMAX AT 25 ° C • 1 + (TL(MAX ) − 25 °C) • 100 where Typical values for the NTC compensation network are: VSENSEMAX( ADJ) = VSENSE(MAX ) • 1. 8 V − VITMP −A 1.3 VITMP = 10µA • (RS + RP ||RNTC) Use typical values for VSENSE(MAX). Subtracting constant A will provide a minimum value for VSENSE(MAX). These values are summarized in Table 2. Another approach for generating the IMAX versus inductor temperature curve plot is to first use the aforementioned values as a starting point and then adjusting the RS and RP values as necessary. Figure 6 shows a typical curve of IMAX versus inductor temperature. The same thermistor network can be used to correct for temperatures less than 25°C. But, ensure that VITEMP is greater than 0.2V for duty cycles of 25% or more, otherwise temperature correction may not occur at elevated ambients. For the most accurate temperature detection, place the thermistor next to the inductors, as shown in Figure 7. Take care to keep the ITEMP pins away from the switch nodes. RNTC Table 2. Values for VSENSE(MAX) ILIM GND FLOAT INTVCC VSENSE(MAX) Typ 30mV 50mV 75mV A 5mV 5mV 7mV The resulting current limit should be greater than or equal to IMAX for inductor temperatures between 25°C and 100°C. 25 IMAX (A) 20 15 10 CORRECTED IMAX VOUT L1 L2 SW1 SW2 3856 F07 Figure 7. Thermistor Location. Place Thermistor Next to Inductor(s) for Accurate Sensing of the Inductor Temperature, But Keep the ITEMP Pin Away from the Switch Nodes and Gate Drive Traces. Slope Compensation and Inductor Peak Current NOMINAL IMAX UNCORRECTED IMAX RS = 20k RP = 43.2k 5 NTC THERMISTOR: RO = 100k TO = 25°C B = 4334 0 –40 –20 0 20 40 60 80 100 120 INDUCTOR TEMPERATURE (°C) 3856 F06 Figure 6. Worst Case IMAX vs Inductor Temperature Curve with and without NTC Temperature Compensation Slope compensation provides stability in constant-frequency, current mode architectures by preventing subharmonic oscillation at high duty cycles. It is accomplished internally by adding a compensating ramp to the inductor current signal at duty cycles in excess of 40%. Normally, this results in a reduction of maximum inductor peak current for duty cycles greater than 40%. However, the LTC3856 uses a scheme that counteracts this compensating ramp, which allows the maximum inductor peak current to remain unaffected throughout all duty cycles. 3856f 20 LTC3856 Applications Information Inductor Value Calculation and Output Ripple Current The operating frequency and inductor selection are interrelated in that higher operating frequencies allow the use of smaller inductor and capacitor values. A higher frequency generally results in lower efficiency because of MOSFET gate charge and transition losses. In addition to this basic trade-off, the effect of inductor value on ripple current and low current operation must also be considered. The PolyPhase approach reduces both input and output ripple currents while optimizing individual output stages to run at a lower fundamental frequency, enhancing efficiency. The inductor value has a direct effect on ripple current. The inductor ripple current, ∆IL, per individual section N, decreases with higher inductance or frequency and increases with higher VIN or VOUT : ∆IL = VOUT fOSC • L VOUT 1– V IN where fOSC is the individual output stage operating frequency. In a PolyPhase converter, the net ripple current seen by the output capacitor is much smaller than the individual inductor ripple currents due to the ripple cancellation. The details on how to calculate the net output ripple current can be found in Application Note 77. Figure 8 shows the net ripple current seen by the output capacitors for the different phase configurations. The 1.0 VOUT k = where k = 1, 2,...,N – 1 VIN N Power MOSFET and Schottky Diode (Optional) Selection At least two external power MOSFETs must be selected for each power stage: One N-channel MOSFET for the top (main) switch and one or more N‑channel MOSFET(s) for the bottom (synchronous) switch. The number, type and on-resistance of all MOSFETs selected take into account the voltage step-down ratio as well as the actual position (main or synchronous) in which the MOSFET will be used. A much smaller and much lower input capacitance MOSFET should be used for the top MOSFET in applications that have an output voltage that is less than one-third 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. 1-PHASE 2-PHASE 3-PHASE 4-PHASE 6-PHASE 12-PHASE 0.9 0.8 0.7 $IO(P-P) VO/fL output ripple current is plotted for a fixed output voltage as the duty factor is varied between 10% and 90% on the x-axis. The output ripple current is normalized against the inductor ripple current at zero duty factor. The graph can be used in place of tedious calculations. The zero output ripple current is obtained when: 0.6 0.5 0.4 0.3 0.2 0.1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 DUTY FACTOR (VOUT/VIN) 0.8 0.9 3856 F08 Figure 8. Normalized Peak Output Current vs Duty Factor [IRMS = 0.3(IOP-P)] 3856f 21 LTC3856 Applications Information The peak-to-peak MOSFET gate drive levels are set by the voltage, VCC, requiring the use of logic-level threshold MOSFETs in most applications. Pay close attention to the BVDSS specification for the MOSFETs as well; many of the logic-level MOSFETs are limited to 30V or less. Selection criteria for the power MOSFETs include the on-resistance, RDS(ON), input capacitance, input voltage and maximum output current. MOSFET input capacitance is a combination of several components but can be taken from the typical gate charge curve included on most data sheets (Figure 9). The curve is generated by forcing a constant input current into the gate of a common source, current source loaded stage, then plotting the gate voltage versus time. mode, the duty cycles for the top and bottom MOSFETs are given by: Main Switch Duty Cycle = V –V Synchronous Switch Duty Cycle = IN OUT VIN The power dissipation for the main and synchronous MOSFETs at maximum output current are given by: I V PMAIN = OUT MAX VIN N I MILLER EFFECT a QIN CMILLER = (QB – QA)/VDS + VGS – +V DS – 3856 F09 Figure 9. Gate Charge Characteristic 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 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 manufacturer’s 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 (1+ δ )RDS(ON) + 1 1 + •f VCC – VTH(IL) VTH(IL) V b 2 ( VIN )2 MAX (R )(C )• 2N DR MILLER VIN VGS VOUT VIN I V –V PSYNC = IN OUT MAX VIN N 2 (1+ δ )RDS(ON) where N is the number of output stages, δ is the temperature dependency of RDS(ON), RDR is the effective top driver resistance (approximately 2Ω at VGS = VMILLER), VIN is the drain potential and the change in drain potential in the particular application. VTH(IL) is the data sheet specified typical gate threshold voltage specified in the power MOSFET data sheet at the specified drain current. CMILLER is the calculated capacitance using the gate charge curve from the MOSFET data sheet and the technique just described. 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 < 20V, the high current efficiency generally improves with larger MOSFETs, while for VIN > 20V, 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. 3856f 22 LTC3856 Applications Information The term (1 + δ ) is generally given for a MOSFET in the form of a normalized RDS(ON) vs temperature curve, but δ = 0.005/°C can be used as an approximation for low voltage MOSFETs. The optional Schottky diodes conduct during the dead time between the conduction of the two large power MOSFETs. This prevents the body diode of the bottom MOSFET from turning on, storing charge during the dead time and requiring a reverse-recovery period which could cost as much as several percent in efficiency. A 2A to 8A Schottky is generally a good compromise for both regions of operation due to the relatively small average current. Larger diodes result in additional transition loss due to their larger junction capacitance. A Schottky diode in parallel with the bottom FET may also provide a modest improvement in Burst Mode efficiency. CIN and COUT Selection In continuous mode, the source current of each top N-channel MOSFET is a square wave of duty cycle VOUT/ VIN. A low ESR input capacitor sized for the maximum RMS current must be used. The details of a close form equation can be found in Application Note 77. Figure 10 shows the input capacitor ripple current for different phase configurations with the output voltage fixed and input voltage varied. The input ripple current is normalized against the DC output current. The graph can be used in place of tedious calculations. The minimum input ripple current can be achieved when the product of phase number and output voltage, N(VOUT), is approximately equal to the input voltage, VIN, or: VOUT k = where k = 1, 2,...,N – 1 VIN N So, the phase number can be chosen to minimize the input capacitor size for the given input and output voltages. In the graph of Figure 10, the local maximum input RMS capacitor currents are reached when: VOUT 2k – 1 = where k = 1, 2,...,N VIN N These worst-case conditions are commonly used for design because even significant deviations do not offer much relief. Note that capacitor manufacturer’s ripple current ratings are often based on only 2000 hours of life. This makes it advisable to further derate the capacitor or to choose a capacitor rated at a higher temperature than required. Several capacitors may also be paralleled to meet size or height requirements in the design. Always consult the capacitor manufacturer if there is any question. The Figure 10 graph shows that the peak RMS input current is reduced linearly, inversely proportional to the number N of stages used. It is important to note that the efficiency loss is proportional to the input RMS current squared and therefore a 3-stage implementation results in 90% less power loss when compared to a single-phase design. Battery/input protection fuse resistance (if used), PC board trace and connector resistance losses are also RMS INPUT RIPPLE CURRENT DC LOAD CURRENT 0.6 0.5 1-PHASE 2-PHASE 3-PHASE 4-PHASE 6-PHASE 12-PHASE 0.4 0.3 0.2 0.1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 DUTY FACTOR (VOUT/VIN) 0.8 0.9 3856 F10 Figure 10. Normalized Input RMS Ripple Current vs Duty Factor for One to Six Output Stages 3856f 23 LTC3856 Applications Information reduced by the reduction of the input ripple current in a PolyPhase system. The required amount of input capacitance is further reduced by the factor N, due to the effective increase in the frequency of the current pulses. Ceramic capacitors are becoming very popular for small designs but several cautions should be observed. X7R, X5R and Y5V are examples of a few of the ceramic materials used as the dielectric layer, and these different dielectrics have very different effect on the capacitance value due to the voltage and temperature conditions applied. Physically, if the capacitance value changes due to applied voltage change, there is a concomitant piezo effect which results in radiating sound! A load that draws varying current at an audible rate may cause an attendant varying input voltage on a ceramic capacitor, resulting in an audible signal. A secondary issue relates to the energy flowing back into a ceramic capacitor whose capacitance value is being reduced by the increasing charge. The voltage can increase at a considerably higher rate than the constant current being supplied because the capacitance value is decreasing as the voltage is increasing! Nevertheless, ceramic capacitors, when properly selected and used, can provide the lowest overall loss due to their extremely low ESR. The selection of COUT is driven by the required effective series resistance (ESR). Typically once the ESR requirement is satisfied the capacitance is adequate for filtering. The steady-state output ripple (∆VOUT) is determined by: 1 ∆VOUT ≈ ∆IRIPPLE ESR + 8NfCOUT where f = operating frequency of each stage, N = the number of output stages, COUT = output capacitance and ∆IL = ripple current in each inductor. The output ripple is highest at maximum input voltage since ∆IL increases with input voltage. The output ripple will be less than 50mV at maximum VIN with ∆IL = 0.4IOUT(MAX) assuming: COUT required ESR < N • RSENSE and COUT > 1 (8Nf)(RSENSE ) The emergence of very low ESR capacitors in small, surface mount packages makes very small physical implementa- 24 tions possible. The ability to externally compensate the switching regulator loop using the ITH pin allows a much wider selection of output capacitor types. The impedance characteristic of each capacitor type is significantly different than an ideal capacitor and therefore requires accurate modeling or bench evaluation during design. Manufacturers such as Nichicon, Nippon Chemi-Con and Sanyo should be considered for high performance through-hole capacitors. The OS-CON semiconductor dielectric capacitors available from Sanyo and the Panasonic SP surface mount types have a good (ESR)(size) product. Once the ESR requirement for COUT has been met, the RMS current rating generally far exceeds the IRIPPLE(P-P) requirement. Ceramic capacitors from AVX, Taiyo Yuden and Murata offer high capacitance value and very low ESR, especially applicable for low output voltage applications. In surface mount applications, multiple capacitors may have to be paralleled to meet the ESR or RMS current handling requirements of the application. Aluminum electrolytic and dry tantalum capacitors are both available in surface mount configurations. New special polymer surface mount capacitors offer very low ESR also but have much lower capacitive density per unit volume. In the case of tantalum, it is critical that the capacitors are surge tested for use in switching power supplies. Several excellent choices are the AVX TPS, AVX TPSV, the KEMET T510 series of surface mount tantalums or the Panasonic SP series of surface mount special polymer capacitors available in case heights ranging from 2mm to 4mm. Other capacitor types include Sanyo POSCAP, Sanyo OS-CON, Nichicon PL series and Sprague 595D series. Consult the manufacturers for other specific recommendations. Differential Amplifier The LTC3856 has a true remote voltage sense capability. The sensing connections should be returned from the load, back to the differential amplifier’s inputs through a common, tightly coupled pair of PC traces. The differential amplifier rejects common mode signals capacitively or inductively radiated into the feedback PC traces as well as ground loop disturbances. The differential amplifier output signal is divided by a pair of resistors and is compared with the internal, precision 0.6V voltage reference by the 3856f LTC3856 Applications Information error amplifier. The amplifier has an output swing range of 0V to 3.6V. The output uses an NPN emitter follower with 80k feedback resistance. Active Voltage Positioning (AVP) In an application, the AVP scheme modifies the regulated output voltage depending on its current loading. AVP can improve overall transient response and save power consumption. The LTC3856 senses inductor current information by monitoring voltage drops across the sense resistors RSENSE or the DCR sensing network of the two channels. The voltage drops are added together and applied as VPRE-AVP between the AVP and DIFFP pins, which are connected through resistor RPRE-AVP . Then VPRE-AVP is scaled through RAVP and added to output voltage as the compensation for the load voltage drop. Let: ∆V = VSENSE1+ – VSENSE1– ∆V = VSENSE2+ – VSENSE2– then: R AVP ∆VDIFFP,VOUT = 2 • ∆V RPRE-AVP The final load slope is defined by the inductor current sense resistors and the two external resistors previously mentioned. In summary, the load slope is: R AVP R • V/ A SENSE RPRE-AVP Programmable Stage Shedding Mode When the MODE pin is tied to INTVCC, the LTC3856 enters Stage Shedding mode. This means that the second channel will stop switching when ITH is below a certain programmed threshold. This threshold voltage on ITH is programmed according to the following formula: 5 VSHED = 0 . 5 + • ( 0 . 5 − VISET ) 3 The valid range of VISET is between 0V to 0.5V, where VISET is the voltage on the ISET pin. There is a precision 7.5µA flowing out of the ISET pin. Connecting a resistor to SGND sets the VISET voltage. When left floating, VISET voltage will be at INTVCC. The Stage Shedding mode threshold voltage in this case will be 0.5V. There is a 50mV hysteresis for the Stage Shedding mode threshold comparator. Programmable Burst Mode Operation When the MODE pin is floating, the LTC3856 enters Burst Mode operation. This means that both channels will stop switching when ITH is below a certain threshold. The Burst Mode clamp, which sets the current limit when bursting, can be programmed through VISET according to the following formula: VCLAMP = 0.7 + 0.62 (0.5 – VISET) The valid range of VISET is between 0.3V to 0.5V and VISET is the voltage on the ISET pin. There is a precision 7.5µA flowing out of ISET. Connecting a resistor to SGND sets the VISET voltage. When left floating, VISET will be at INTVCC. The Burst Mode clamp voltage in this case will be 0.7V. There is a 50mV hysteresis for the Burst Mode comparator. The recommended value for RAVP is 90Ω to 100Ω. The maximum output voltage at AVP is 2.5V. Therefore, for outputs higher than 2.5V, the AVP function is not supported. The DIFFP pin, however, should always be connected to the output even when AVP or diffamp functions are not used. 3856f 25 LTC3856 Applications Information Soft-Start and Tracking The LTC3856 has the ability to either soft-start by itself with a capacitor or track the output of another external supply. When the controller is configured to soft-start by itself, a capacitor should be connected to its TK/SS pin. The controller is in the shutdown state if its RUN pin voltage is below 1.22V and its TK/SS pin is actively pulled to ground in this shutdown state. Once the RUN pin voltage is above 1.22V, the controller powers up. A soft-start current of 1.25µA then starts to charge the TK/SS soft-start capacitor. Note that soft-start or tracking is achieved not by limiting the maximum output current of the controller but by controlling the output ramp voltage according to the ramp rate on the TK/SS pin. Current foldback is disabled during this phase to ensure smooth soft-start or tracking. The soft-start or tracking range is defined to be the voltage range from 0V to 0.6V on the TK/SS pin. The total soft-start time can be calculated as: t SOFTSTART = 0.6 • CSS 1.25µA Regardless of the mode selected by the MODE pin, the controller always starts in discontinuous mode up to TK/SS = 0.5V. Between TK/SS = 0.5V and 0.54V, it will operate in forced continuous mode and revert to the selected mode once TK/SS > 0.54V. The output ripple is minimized during the 40mV forced continuous mode window ensuring a clean PGOOD signal. When the channel is configured to track another supply, the feedback voltage of the other supply is duplicated by a resistor divider and applied to the TK/SS pin. Therefore, the voltage ramp rate on this pin is determined by the ramp rate of the other supply’s voltage. Note that the small soft-start capacitor charging current is always flowing, producing a small offset error. To minimize this error, select the tracking resistive divider value to be small enough to make this error negligible. In order to track down another channel or supply after the soft-start phase expires, the LTC3856 is forced into continuous mode of operation as soon as VFB is below the undervoltage threshold of 0.54V regardless of the setting on the MODE pin. However, the LTC3856 should always be set in forced continuous mode tracking down when there is no load. After TK/SS drops below 0.1V, the controller operates in discontinuous mode. The LTC3856 allows the user to program how its output ramps up and down by means of the TK/SS pins. Through these pins, the output can be set up to either coincidentally or ratiometrically track another supply’s output, as shown in Figure 11. In the following discussions, VOUT1 refers to the LTC3856’s output as a master and VOUT2 refers to another supply output as a slave. To implement the coincident tracking in Figure 11a, connect an additional resistive divider to VOUT1 and connect its mid-point to the TK/SS pin of the slave controller. The ratio of this divider should be the same as that of the slave controller’s feedback divider shown in Figure 12a. In this tracking mode, VOUT1 must be set higher than VOUT2. To implement the ratiometric tracking in Figure 11b, the ratio of the VOUT2 divider should be exactly the same as the master controller’s feedback divider shown in Figure 12b . By selecting different resistors, the LTC3856 can achieve different modes of tracking including the two in Figure 11. So, which mode should be programmed? While either mode in Figure 11 satisfies most practical applications, some trade-offs exist. The ratiometric mode saves a pair of resistors, but the coincident mode offers better output regulation. Under ratiometric tracking, when the master controller’s output experiences dynamic excursion (under load transient, for example), the slave controller output will be affected as well. For better output regulation, use the coincident tracking mode instead of ratiometric. INTVCC (LDO) and EXTVCC The LTC3856 features a true PMOS LDO that supplies power to INTVCC from the VIN supply. INTVCC powers the gate drivers and much of the LTC3856’s internal circuitry. The LDO regulates the voltage at the INTVCC pin to 5V when VIN is greater than 5.5V. EXTVCC connects to INTVCC through a P-channel MOSFET and can supply the needed power when its voltage is higher than 4.7V. Each of these can supply a peak current of 100mA and must be bypassed to ground with a minimum of 4.7µF ceramic capacitor or other low ESR capacitor. No matter what type of bulk capacitor is used, an additional 0.1µF ceramic capacitor placed directly adjacent to the INTVCC and PGND pins is highly recommended. Good bypassing 3856f 26 LTC3856 Applications Information VOUT1 OUTPUT VOLTAGE OUTPUT VOLTAGE VOUT1 VOUT2 TIME VOUT2 TIME 3856 F11a 3856 F11b (11b) Ratiometric Tracking (11a) Coincident Tracking Figure 11. Two Different Modes of Output Voltage Tracking VOUT1 VOUT2 TO TK/SS2 PIN R3 R4 R1 R2 TO VFB1 PIN TO VFB2 PIN R3 R4 VOUT1 TO TK/SS2 PIN VOUT2 R1 R2 TO VFB1 PIN TO VFB2 PIN R3 R4 3856 F12 (12a) Coincident Tracking Set-Up (12b) Ratiometric Tracking Set-Up Figure 12. Set-Up and Coincident and Ratiometric Tracking is needed to supply the high transient currents required by the MOSFET gate drivers and to prevent interaction between the channels. table. For example, the LTC3856 INTVCC current is limited to less than 42mA from a 38V supply in the UH package and not using the EXTVCC supply: High input voltage applications in which large MOSFETs are being driven at high frequencies may cause the maximum junction temperature rating for the LTC3856 to be exceeded. The INTVCC current, which is dominated by the gate charge current, may be supplied by either the 5V LDO or EXTVCC. When the voltage on the EXTVCC pin is less than 4.7V, the LDO is enabled. Power dissipation for the IC in this case is highest and is equal to VIN • IINTVCC. The gate charge current is dependent on operating frequency as discussed in the Efficiency Considerations section. The junction temperature can be estimated by using the equations given in Note 3 of the Electrical Characteristics TJ = 70°C + (42mA)(38V)(34°C/W) = 125°C To prevent the maximum junction temperature from being exceeded, the input supply current must be checked while operating in continuous conduction mode (MODE = SGND) at maximum VIN. When the voltage applied to EXTVCC rises above 4.7V, the INTVCC LDO is turned off and the EXTVCC is connected to the INTVCC. The EXTVCC remains on as long as the voltage applied to EXTVCC remains above 4.5V. Using the EXTVCC allows the MOSFET driver and control power to be derived from one of switching regulator outputs during normal operation and from the INTVCC when the output is out of regulation (e.g., start-up, 3856f 27 LTC3856 Applications Information short circuit). If more current is required through the EXTVCC than is specified, an external Schottky diode can be added between the EXTVCC and INTVCC pins. Do not apply more than 6V to the EXTVCC pin and make sure that EXTVCC < VIN. Significant efficiency and thermal gains can be realized by powering INTVCC from the output, since the VIN current resulting from the driver and control currents will be scaled by a factor of (duty cycle)/(switcher efficiency). Tying the EXTVCC pin to a 5V supply reduces the junction temperature in the previous example from 125°C to: TJ = 70°C + (42mA)(5V)(34°C/W) = 77°C However, for low voltage outputs, additional circuitry is required to derive INTVCC power from the output. The following list summarizes the four possible connections for EXTVCC: 1.EXTVCC left open (or grounded). This will cause INTVCC to be powered from the internal 5V LDO resulting in an efficiency penalty of up to 10% at high input voltages. 2.EXTVCC connected directly to VOUT . This is the normal connection for a 5V regulator and provides the highest efficiency. 3.EXTVCC connected to an external supply. If a 5V external supply is available, it may be used to power EXTVCC providing it is compatible with the MOSFET gate drive requirements. 4.EXTVCC connected to an output-derived boost network. For 3.3V and other low voltage regulators, efficiency gains can still be realized by connecting EXTVCC to an output-derived voltage that has been boosted to greater than 4.7V. LTC3856 For applications where the main input power is 5V, tie the VIN and INTVCC pins together and tie the combined pins to the 5V input with a 1Ω or 2.2Ω resistor (as shown in Figure 13) to minimize the voltage drop caused by the gate charge current. This will override the INTVCC linear regulator and will prevent INTVCC from dropping too low due to the dropout voltage. Make sure the INTVCC voltage is at or exceeds the RDS(ON) test voltage for the MOSFET, which is typically 4.5V for logic-level devices. Topside MOSFET Driver Supply (CB, DB) External bootstrap capacitors, CB, connected to the BOOST pins supply the gate drive voltages for the topside MOSFETs. Capacitor CB in the Functional Diagram is charged though external diode DB from INTVCC when the SW pin is low. When one of the topside MOSFETs is to be turned on, the driver places the CB voltage across the gate source of the desired MOSFET. This enhances the MOSFET and turns on the topside switch. The switch node voltage, SW, rises to VIN and the BOOST pin follows. With the topside MOSFET on, the boost voltage is above the input supply: VBOOST = VIN + VINTVCC 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 Schottky diode must be greater than VIN(MAX). When adjusting the gate drive level, the final arbiter is the total input current for the regulator. If a change is made and the input current decreases, then the efficiency has improved. If there is no change in input current, then there is no change in efficiency. VIN RVIN 1Ω INTVCC CINTVCC 4.7µF 5V + CIN 3856 F13 Figure 13. Set-Up for a 5V Input 3856f 28 LTC3856 Applications Information Setting Output Voltage Fault Conditions: Current Limit and Current Foldback If the DIFFAMP is not used, the LTC3856 output voltage is set by an external feedback resistive divider carefully placed across the output, as shown in Figure 14. The regulated output voltage is determined by: The LTC3856 includes current foldback to help limit load current when the output is shorted to ground. If the output falls below 50% of its nominal output level, then the maximum sense voltage is progressively lowered from its maximum programmed value to one-third of the maximum value. Foldback current limiting is disabled during the soft-start or tracking up. Under short-circuit conditions with very low duty cycles, the LTC3856 will begin cycle skipping in order to limit the short-circuit current. In this situation the bottom MOSFET will be dissipating most of the power but less than in normal operation. The short circuit ripple current is determined by the minimum ontime tON(MIN) of the LTC3856 (≈ 90ns), the input voltage and inductor value: R VOUT = 0.6 V • 1+ B RA To improve the frequency response, a feedforward capacitor, CFF , may be used. Great care should be taken to route the VFB line away from noise sources, such as the inductor or the SW line. If the diffamp is used, then VFB should be connected to the output of the diffamp, DIFFOUT, as shown in the Typical Application on the first page. VOUT / DIFFOUT ∆IL(SC) = tON(MIN) • VIN L The resulting short-circuit current is: LTC3856 RB CFF VFB RA 1/ 3 VSENSE(MAX ) 1 ISC = – ∆IL(SC) • 2 RSENSE 2 3856 F14 Figure 14. Setting Output Voltage without the DIFFAMP 3856f 29 LTC3856 Applications Information Phase-Locked Loop and Frequency Synchronization The LTC3856 has a phase-locked loop (PLL) comprised of an internal voltage-controlled oscillator (VCO) and a phase detector. This allows the turn-on of the top MOSFET of controller 1 to be locked to the rising edge of an external clock signal applied to the PLLIN pin. The turn-on of the second phase’s top MOSFETs is thus 180° out-of-phase with the external clock, and so on. The phase detector is an edge-sensitive digital type that provides zero degrees phase shift between the external and internal oscillators. This type of phase detector does not exhibit a false lock to harmonics of the external clock. The output of the phase detector is a pair of complementary current sources that charge or discharge the internal filter network. There is a precision 10µA of current flowing out of FREQ pin. This allows the user to use a single resistor to SGND to set the switching frequency when no external clock is applied to the PLLIN pin. The internal switch between the FREQ pin and the integrated PLL filter network is on, allowing the filter network to be pre-charged at the same voltage as of the FREQ pin. The relationship between the voltage on the FREQ pin and operating frequency is shown in Figure 15 and specified in the Electrical Characteristics table. If an external clock is detected on the PLLIN pin, the internal switch mentioned above turns off and isolates the influence of the FREQ pin. Note that the LTC3856 can only be synchronized to an external clock whose frequency is within range of the LTC3856’s internal VCO. This is guaranteed to be between 250kHz and 770kHz. A simplified block diagram is shown in Figure 16. If the external clock frequency is greater than the internal oscillator’s frequency, fOSC, then current is sourced continuously from the phase detector output, pulling up the filter network. When the external clock frequency is 900 2.4V 700 FREQUENCY (kHz) 5V RSET 800 FREQ 600 500 EXTERNAL OSCILLATOR 400 PLLIN DIGITAL SYNC PHASE/ FREQUENCY DETECTOR VCO 300 200 100 0 0 0.5 1 1.5 2 FREQ/PLLFLTR PIN VOLTAGE (V) 2.5 3856 F16 3856 F15 Figure 15. Relationship Between Oscillator Frequency and Voltage at the FREQ Pin Figure 16. Phase-Locked Loop Block Diagram 3856f 30 LTC3856 Applications Information less than fOSC, current is sunk continuously, pulling down the filter network. If the external and internal frequencies are the same but exhibit a phase difference, the current sources turn on for an amount of time corresponding to the phase difference. The voltage on the filter network is adjusted until the phase and frequency of the internal and external oscillators are identical. At the stable operating point, the phase detector output is high impedance and the filter capacitor CLP holds the voltage. Efficiency Considerations Typically, the external clock (on the PLLIN pin) input high threshold is 1.6V, while the input low threshold is 1V. where L1, L2, etc. are the individual losses as a percentage of input power. Minimum On-Time Considerations Minimum on-time, tON(MIN), is the smallest time duration that the LTC3856 is capable of turning on the top MOSFET. It is determined by internal timing delays and the 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(MIN) < VOUT VIN ( f ) If the duty cycle falls below what can be accommodated by the minimum on-time, the controller will begin to skip cycles. The output voltage will continue to be regulated, but the ripple voltage and current will increase. The minimum on-time for the LTC3856 is approximately 90ns, with reasonably good PCB layout, minimum 30% inductor current ripple and at least 10mV ripple on the current sense signal. The minimum on-time can be affected by PCB switching noise in the voltage and current loop. As the peak sense voltage decreases the minimum on-time gradually increases to 130ns. This is of particular concern in forced continuous applications with low ripple current at light loads. If the duty cycle drops below the minimum on-time limit in this situation, a significant amount of cycle skipping can occur with correspondingly larger current and voltage ripple. The percent efficiency of a switching regulator is equal to the output power divided by the input power times 100%. It is often useful to analyze individual losses to determine what is limiting the efficiency and which change would produce the most improvement. Percent efficiency can be expressed as: %Efficiency = 100% – (L1 + L2 + L3 + ...) Although all dissipative elements in the circuit produce losses, four main sources usually account for most of the losses in LTC3856 circuits: 1) IC VIN current, 2) INTVCC regulator current, 3) I2R losses, 4) topside MOSFET transition losses. 1.The VIN current is the DC supply current given in the Electrical Characteristics table, which excludes MOSFET driver and control currents. VIN current typically results in a small (<0.1%) loss. 2.INTVCC current is the sum of the MOSFET driver and control currents. The MOSFET driver current results from switching the gate capacitance of the power MOSFETs. Each time a MOSFET gate is switched from low to high to low again, a packet of charge dQ moves from INTVCC to ground. The resulting dQ/dt is a current out of INTVCC that is typically much larger than the control circuit current. In continuous mode, IGATECHG = f(QT + QB), where QT and QB are the gate charges of the topside and bottom side MOSFETs. Supplying INTVCC power through EXTVCC from an output-derived source will scale the VIN current required for the driver and control circuits by a factor of (duty cycle)/(efficiency). For example, in a 20V to 5V application, 10mA of INTVCC current results in approximately 2.5mA of VIN current. This reduces the mid-current loss from 10% or more (if the driver was powered directly from VIN) to only a few percent. 3.I2R losses are predicted from the DC resistances of the fuse (if used), MOSFET, inductor and current sense resistor. In continuous mode, the average output current flows through L and RSENSE, but is chopped between 3856f 31 LTC3856 Applications Information 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 resistances of L and RSENSE to obtain I2R losses. For example, if each RDS(ON) = 10mΩ, RL = 10mΩ, RSENSE = 5mΩ, then the total resistance is 25mΩ. This results in losses ranging from 2% to 8% as the output current increases from 3A to 15A for a 5V output, or a 3% to 12% loss for a 3.3V output. Efficiency varies as the inverse square of VOUT for the same external components and output power level. The combined effects of increasingly lower output voltages and higher currents required by high performance digital systems is not doubling but quadrupling the importance of loss terms in the switching regulator system! 4.Transition losses apply only to the topside MOSFET(s), and become significant only when operating at high input voltages (typically 15V or greater). Transition losses can be estimated from: Transition Loss = (1.7) VIN2 • IO(MAX) • CRSS • f Other hidden losses such as copper trace and internal battery resistances can account for an additional 5% to 10% efficiency degradation in portable systems. It is very important to include these system level losses during the design phase. The internal battery and fuse resistance losses can be minimized by ensuring that CIN has adequate charge storage and very low ESR at the switching frequency. A 25W supply will typically require a minimum of 20µF to 40µF of capacitance having a maximum of 20mΩ to 50mΩ of ESR. Other losses including Schottky conduction losses during dead time and inductor core losses generally account for less than 2% total additional loss. Checking Transient Response The regulator loop response can be checked by looking at the load current transient response. Switching regulators take several cycles to respond to a step in DC (resistive) load current. When a load step occurs, VOUT shifts by an amount equal to ∆ILOAD (ESR), where ESR is the effective series resistance of COUT . ∆ILOAD also begins to charge or discharge COUT generating the feedback error signal that forces the regulator to adapt to the current change and return VOUT to its steady-state value. During this recovery time VOUT can be monitored for excessive overshoot or ringing, which would indicate a stability problem. The availability of the ITH pin not only allows optimization of control loop behavior but also provides a DC-coupled and AC-filtered closed-loop response test point. The DC step, rise time and settling at this test point truly reflects the closed-loop response. Assuming a predominantly second order system, phase margin and/or damping factor can be estimated using the percentage of overshoot seen at this pin. The bandwidth can also be estimated by examining the rise time at the pin. The ITH external components shown in the Typical Application circuit will provide an adequate starting point for most applications. The ITH series RC-CC filter sets the dominant pole-zero loop compensation. The values can be modified slightly (from 0.5 to 2 times their suggested values) to optimize transient response once the final PC layout is done and the particular output capacitor type and value have been determined. The output capacitors need to be selected because the various types and values determine the loop gain and phase. An output current pulse of 20% to 80% of full-load current having a rise time of 1µs to 10µs will produce output voltage and ITH pin waveforms that will give a sense of the overall loop stability without breaking the feedback loop. Placing a power MOSFET directly across the output capacitor and driving the gate with an appropriate signal generator is a practical way to produce a realistic load step condition. The initial output voltage step resulting from the step change in output current may not be within the bandwidth of the feedback loop, so this signal cannot be used to determine phase margin. This is why it is better to look at the ITH pin signal which is in the feedback loop and is the filtered and compensated control loop response. The gain of the loop will be increased by increasing RC and the bandwidth of the loop will be increased by decreasing CC. If RC is increased by the same factor that CC is decreased, the zero frequency will be kept the same, thereby keeping the phase shift the same in the most critical frequency range of the feedback loop. The output voltage settling behavior is related to the stability of the closed-loop system and will demonstrate the actual overall supply performance. 3856f 32 LTC3856 Applications Information A second, more severe transient is caused by switching in loads with large (>1µF) supply bypass capacitors. The discharged bypass capacitors are effectively put in parallel with COUT , causing a rapid drop in VOUT . No regulator can alter its delivery of current quickly enough to prevent this sudden step change in output voltage if the load switch resistance is low and it is driven quickly. If the ratio of CLOAD to COUT is greater than 1:50, the switch rise time should be controlled so that the load rise time is limited to approximately 25 • CLOAD. Thus a 10µF capacitor would require a 250µs rise time, limiting the charging current to about 200mA. A 2µH inductor will produce 20% ripple current. The peak inductor current will be the maximum DC value plus one half the ripple current, or 11A. The minimum on-time occurs at maximum VIN: V 1.8 V tON(MIN) = OUT = = 1.1µs VINf 5.5V 300kHz ( )( ) With the ILIM pin tied to ground, the RSENSE resistors value can be calculated by using the minimum current sense voltage specification with some accommodation for tolerances: R SENSE = 25mV ≈ 0 . 002Ω 11A Design Example (Using Two Phases) As a design example, assume: VIN = 5V (nominal) VIN = 5.5V (max), VOUT = 1.8V, IMAX = 20A TA = 70°C Choosing 1% resistors: R1 = 10k and R2 = 20k yields an output voltage of 1.80V. The power dissipation on the topside MOSFET can be easily estimated. Using a Siliconix Si4420DY for example; RDS(ON) = 0.013Ω, CRSS = 300pF. At maximum input voltage with TJ (estimated) = 110°C at an elevated ambient temperature: f = 300kHz 1 . 8V 2 10 ) 1 + ( 0 . 005) (110 °C − 25 °C) ( 5 . 5V 2 10 A • 0 . 013Ω + ( 5 . 5V ) (2Ω)(300pF ) 2 PMAIN = The inductance value is chosen first based on a 30% ripple current assumption. The highest value of ripple current occurs at the maximum input voltage. Use a 71.5k resistor from FREQ to ground to set the switching frequency at about 300kHz. The minimum inductance for 30% ripple current is: L≥ VOUT VOUT 1− f ( ∆I) VIN 1.8 V 1.8 V ≥ 1− (300kHz )(30%)(10A ) 5.5V ≥ 1.35µH 1 1 + 5V − 2 . 6 V 2 . 6 V • ( 300kHz ) = 0 . 606 + 0 . 022 = 0 . 628 W The worst-case power dissipated by the synchronous MOSFET under normal operating conditions at elevated ambient temperature and estimated 50°C junction temperature rise is: 5 . 5V − 1 . 8 V 2 10 A ) (1 . 25) ( 0 . 013Ω ) ( 5 . 5V = 1 . 0 9W PSYNC = 3856f 33 LTC3856 Applications Information A short-circuit to ground will result in a folded back current of: I SC 25mV 1 90ns 5.5V 3 = − 0.002Ω 2 2µH ( ) = 4.04A The worst-case power dissipated by the synchronous MOSFET under short-circuit conditions at elevated ambient temperature and estimated 50°C junction temperature rise is: 5 . 5V − 1 . 8 V 2 4 . 04A ) (1 . 25) ( 0 . 013Ω ) ( 5 . 5V = 0 . 18W PSYNC = which is much less than normal, full-load conditions. Incidentally, since the load no longer dissipates power in the shorted condition, total system power dissipation is decreased by over 99%. The duty cycles when the peak RMS input current occurs is at D = 0.25 and D = 0.75 according to Figure 10. Calculate the worst-case required RMS input current rating at the input voltage, which is 5.5V, that provides a duty cycle nearest to the peak. From Figure 10, CIN will require an RMS current rating of: ( )( ) CIN required IRMS = 20A 0.23 = 4.6ARMS The output capacitor ripple current is calculated by using the inductor ripple already calculated for each inductor and multiplying by the factor obtained from Figure 8 along with the calculated duty factor. The output ripple in continuous mode will be highest at the maximum input voltage. From Figure 8, the maximum output current ripple is: VOUT (0.34) fL 1.8 ( 0.34) ∆ICOUTMAX = = 1A (300kHz )(2µH) ∆ICOUT = Note that the PolyPhase technique will have its maximum benefit for input and output ripple currents when the number of phases times the output voltage is approximately equal to or greater than the input voltage. 3856f 34 LTC3856 Applications Information PC Board Layout Checklist When laying out the printed circuit board, the following checklist should be used to ensure proper operation of the IC. These items are also illustrated graphically in the layout diagram of Figure 17. Check the following in the PC layout: 1.Are the signal and power ground paths Kelvin connected? Keep the SGND at one end of a printed circuit path thus preventing MOSFET currents from traveling under the IC. The INTVCC decoupling capacitor should be placed immediately adjacent to the IC between the INTVCC pin and PGND plane. A 1µF ceramic capacitor of the X7R or X5R type is small enough to fit very close to the IC to minimize the ill effects of the large current pulses drawn to drive the bottom MOSFETs. An additional 5µF to 10µF of ceramic, tantalum or other very low ESR capacitance is recommended in order to keep the internal IC supply quiet. The power ground returns to the sources of the bottom N-channel MOSFETs, anodes of the Schottky diodes and (–) plates of CIN, which should have as short lead lengths as possible. 2.Does the IC DIFFP pin connect to the (+) plates of COUT? A 30pF to 300pF feedforward capacitor between the DIFFP and VFB pins should be placed as close as possible to the IC. 3.Are the SENSE– and SENSE+ printed circuit traces for each channel routed together with minimum PC trace spacing? The filter capacitors between SENSE+ and SENSE– for each channel should be as close as possible to the pins of the IC. Connect the SENSE– and SENSE+ pins to the pads of the sense resistor as illustrated in Figure 1. 4.Do the (+) plates of CPWR connect to the drains of the topside MOSFETs as closely as possible? This capacitor provides the pulsed current to the MOSFETs. 5.Keep the switching nodes, SWn, BOOSTn and TGn away from sensitive small-signal nodes (SENSE+, SENSE–, DIFFP, DIFFN, VFB, ITEMP). Ideally the SWn, BOOSTn and TGn printed circuit traces should be routed away and separated from the IC and especially the “quiet” side of the IC. Separate the high dv/dt traces from sensitive small-signal nodes with ground traces or ground planes. 6.Use a low impedance source such as a logic gate to drive the PLLIN pin and keep the lead as short as possible. 7.The 47pF to 330pF ceramic capacitor between the ITH pin and signal ground should be placed as close as possible to the IC. Figure 17 illustrates all branch currents in a 2-phase switching regulator. It becomes very clear after studying the current waveforms why it is critical to keep the high switching current paths to a small physical size. High electric and magnetic fields will radiate from these loops just as radio stations transmit signals. The output capacitor ground should return to the negative terminal of the input capacitor and not share a common ground path with any switched current paths. The left half of the circuit gives rise to the noise generated by a switching regulator. The ground terminations of the synchronous MOSFETs and Schottky diodes should return to the bottom plate(s) of the input capacitor(s) with a short isolated PC trace since very high switched currents are present. External OPTI-LOOP® compensation allows overcompensation for PC layouts which are not optimized, but this is not the recommended design procedure. 3856f 35 LTC3856 Applications Information SW1 L1 RSENSE1 D1 VIN VOUT RIN CIN + + SW2 L2 COUT RL RSENSE2 D2 BOLD LINES INDICATE HIGH, SWITCHING CURRENT LINES. KEEP LINES TO A MINIMUM LENGTH. 3856 F17 Figure 17. Instantaneous Current Path Flow in a Multiple Phase Switching Regulation 3856f 36 LTC3856 Typical Application VIN + VIN 1nF 0.1µF 2.2Ω S 5.6k 100pF 100Ω VIN 100Ω Q1 RJK0305DPB S S CLKOUT 100k, 1% 0.1µF VIN PLLIN TG1 RUN SW1 AVP PHASMD DIFFP DIFFN 100k LTC3856 BOOST1 BG1 INTVCC D1, CMDSH-3 INTVCC 4.7µF TG2 PGOOD SW2 EXTVCC BG2 330µF 2.5V s4 4.7µF 6.3V 22µF Q7 RJK0305DPB Q4 RJK0330DPB L2 0.22µH 0.001Ω Q8 RJK0330DPB SENSE2+ 1nF MODE S 100µF 6.3V + s4 22µF INTVCC 0.1µF VOUT 1.5V/ 50A 0.001Ω VIN Q3 RJK0305DPB D2, CMDSH-3 BOOST2 ISET ILIM GND Q6 RJK0330DPB Q2 RJK0330DPB DIFFOUT INTVCC L1 0.22µH INTVCC ITEMP 30.1k 0.1µF TK/SS VFB S 22µF 22µF Q5 RJK0305DPB 1nF SENSE1+ FREQ ITH 20k SENSE1– 180µF 16V s2 VIN 4.5V TO 14V PGOOD PGND SGND SENSE2– 100Ω 100Ω S 10Ω 10Ω 3856 F18 Figure 18. 1.5V/50A Converter Using Sense Resistors 3856f 37 LTC3856 Package Description FE Package 38-Lead Plastic TSSOP (4.4mm) (Reference LTC DWG # 05-08-1772 Rev A) Exposed Pad Variation AA 4.75 REF 38 9.60 – 9.80* (.378 – .386) 4.75 REF (.187) 20 6.60 ±0.10 4.50 REF 2.74 REF SEE NOTE 4 6.40 2.74 REF (.252) (.108) BSC 0.315 ±0.05 1.05 ±0.10 0.50 BSC RECOMMENDED SOLDER PAD LAYOUT 4.30 – 4.50* (.169 – .177) 0.09 – 0.20 (.0035 – .0079) 0.50 – 0.75 (.020 – .030) NOTE: 1. CONTROLLING DIMENSION: MILLIMETERS 2. DIMENSIONS ARE IN MILLIMETERS (INCHES) 3. DRAWING NOT TO SCALE 1 0.25 REF 19 1.20 (.047) MAX 0o – 8o 0.50 (.0196) BSC 0.17 – 0.27 (.0067 – .0106) TYP 0.05 – 0.15 (.002 – .006) FE38 (AA) TSSOP 0608 REV A 4. RECOMMENDED MINIMUM PCB METAL SIZE FOR EXPOSED PAD ATTACHMENT *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.150mm (.006") PER SIDE 3856f 38 LTC3856 Package Description UH Package 32-Lead Plastic QFN (5mm × 5mm) (Reference LTC DWG # 05-08-1693 Rev D) 0.57 p0.05 5.35 p 0.05 4.20 p0.05 3.45 p0.05 (4 SIDES) PACKAGE OUTLINE 0.23 p 0.05 0.50 BSC RECOMMENDED SOLDER PAD LAYOUT 5.00 p 0.10 (4 SIDES) BOTTOM VIEW—EXPOSED PAD 0.75 p 0.05 0.00 – 0.05 R = 0.115 TYP 0.40 p 0.10 31 32 PIN 1 TOP MARK 1 2 3.45 p 0.10 (4-SIDES) (UH) QFN 0102 0.200 REF NOTE: 1. DRAWING PROPOSED TO INCLUDE JEDEC PACKAGE OUTLINE M0-220 VARIATION WHHD-(X) (TO BE APPROVED) 2. DRAWING NOT TO SCALE 3. ALL DIMENSIONS ARE IN MILLIMETERS 4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE 5. EXPOSED PAD SHALL BE SOLDER PLATED 0.23 p 0.05 0.50 BSC 3856f 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. 39 LTC3856 Typical Application VIN + VIN 330pF 0.1µF 2.2Ω S 2.68k 47pF 200Ω VIN 200Ω Q1 RJK0305DPB S S CLKOUT PLLIN 100k 0.1µF 20k 49.9Ω 100pF 30.1k VIN S TG1 RUN SW1 TK/SS ITH VFB AVP S SENSE1+ FREQ 0.1µF LTC3856 INTVCC ITEMP DIFFP DIFFN 100Ω 100k PGOOD CMDSH-3 INTVCC 100µF 6.3V + s2 TG2 ISET SW2 EXTVCC BG2 ILIM 22µF L2 0.22µH INTVCC 0.1µF 4.7µF 6.3V 22µF Q7 RJK0305DPB CMDSH-3 BOOST2 330µF 2.5V s4 VIN Q3 RJK0305DPB 4.7µF 0.001Ω Q8 RJK0330DPB Q4 RJK0330DPB SENSE2+ 1nF MODE S GND VOUT 1.5V/ 50A 0.001Ω Q6 RJK0330DPB Q2 RJK0330DPB DIFFOUT INTVCC L1 0.22µH INTVCC BOOST1 BG1 PHASMD S 22µF 22µF Q5 RJK0305DPB 1nF SENSE1– 180µF 16V s2 VIN 4.5V TO 14V PGOOD PGND SGND SENSE2– 200Ω 200Ω S 10Ω 10Ω S S 3856 F19 VO_SNS– VO_SNS+ Figure 19. 1.5V/50A Converter with AVP Related Parts PART NUMBER DESCRIPTION COMMENTS LTC3829 3-Phase, Single Output, Synchronous Step-Down Controller with Diffamp and DCR Temperature Compensation Phase-Lockable Fixed 250kHz to 770kHz Frequency, 4.5V ≤ VIN ≤ 38V, 0.8V ≤ VOUT ≤ 5V LTC3860 Dual, Multiphase, Synchronous Step-Down DC/DC Controller with Diffamp and Three-State Output Drive Operates with Power Blocks, DRMOS Devices or External MOSFETs, 3V ≤ VIN ≤ 24V, tON(MIN) = 20ns LTC3855 Dual, Multiphase, Synchronous Step-Down DC/DC Controller with Diffamp and DCR Temperature Compensation Phase-Lockable Fixed Frequency 250kHz to 770kHz, 4.5V ≤ VIN ≤ 38V, 0.8V ≤ VOUT ≤ 12V LTC3853 Triple Output, Multiphase, Synchronous Step-Down DC/DC Controller, RSENSE or DCR Current Sensing and Tracking Phase-Lockable Fixed 250kHz to 750kHz Frequency, 4V ≤ VIN ≤ 24V, VOUT3 Up to 13.5V LTC3850/LTC3850-1/ LTC3850-2 Dual 2-Phase, High Efficiency, Synchronous Step-Down Phase-Lockable Fixed 250kHz to 780kHz Frequency, DC/DC Controller, RSENSE or DCR Current Sensing and Tracking 4V ≤ VIN ≤ 30V, 0.8V ≤ VOUT ≤ 5.25V 3856f 40 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com LT 0510 • PRINTED IN USA LINEAR TECHNOLOGY CORPORATION 2010