LT1339 High Power Synchronous DC/DC Controller U DESCRIPTION FEATURES ■ ■ ■ ■ ■ ■ ■ ■ The LT ®1339 is a high power synchronous current mode switching regulator controller. The IC drives dual N-channel MOSFETs to create a single IC solution for high power DC/DC converters in applications up to 60V. High Voltage: Operation Up to 60V High Current: Dual N-Channel Synchronous Drive Handles Up to 10,000pF Gate Capacitance Programmable Average Load Current Limiting 5V Reference Output with 10mA External Loading Capability Programmable Fixed Frequency Synchronizable Current Mode Operation Up to 150kHz Undervoltage Lockout with Hysteresis Programmable Start Inhibit for Power Supply Sequencing and Protection Adaptive Nonoverlapping Gate Drive Prevents Shoot-Through The LT1339 incorporates programmable average current limiting, allowing accurate limiting of DC load current independent of inductor ripple current. The IC also incorporates user-adjustable slope compensation for minimization of magnetics at duty cycles up to 90%. The LT1339 timing oscillator operating frequency is programmable and can be synchronized up to 150kHz. Minimum off-time operation provides main switch protection. The IC also incorporates a soft start feature that is gated by both shutdown and undervoltage lockout conditions. U APPLICATIONS ■ ■ ■ ■ ■ An output phase reversal pin allows flexibility in configuration of converter types, including inverting and negative topologies. 48V Telecom Power Supplies Personal Computers and Peripherals Distributed Power Converters Industrial Control Systems Lead-Acid Battery Backup Systems Automotive and Heavy Equipment , LTC and LT are registered trademarks of Linear Technology Corporation. U ■ TYPICAL APPLICATION 28V to 5V 20A Buck Converter VBOOST + 5VREF + CBST 1µF CAVG CCT 2200pF 2200pF CT SL/ADJ BG D2 MBR0520 IAVG CSS, 1µF CVC, 1nF + PHASE RVC, 10k VC CREF 0.1µF SGND IRL3103D2 ×2 100 CIN 1500µF 63V ×3 L1 10µH 90 RUN/SHDN SENSE + 70 50 RS 0.005Ω SENSE – RFB1 3k 80 60 RRUN 100k VFB VREF RFB2 1k PGND SS + D1 MBR0520 TS 12VIN LT1339 12V C12VIN 47µF IRL3803 TG RCT 10k C5VREF 1µF + EFFICIENCY (%) SYNC 28V to 5V Efficiency VIN 28V DBST IN5819 + L1 = CTX02-13400-X2 VOUT 0 10 5 15 OUTPUT CURRENT (A) 20 1339 TA03a COUT 5V AT 20A 2200µF 6.3V ×2 1339 TA03 1 LT1339 U U RATI GS W W W W AXI U U ABSOLUTE PACKAGE/ORDER I FOR ATIO (Note 1) Supply Voltages Power Supply Voltage (12VIN)...............– 0.3V to 20V Topside Supply Voltage (VBOOST) VTS – 0.3V to VTS + 20V (VMAX = 75V) Topside Reference Pin Voltage (TS) ......– 0.3V to 60V Input Voltages Sense Amplifier Input Common Mode ...– 0.3V to 60V RUN/SHDN Pin Voltage ...................... – 0.3V to 12VIN All Other Inputs .......................................– 0.3V to 7V Maximum Currents 5V Reference Output Current............................ 65mA Maximum Temperatures Operating Ambient Temperature Range LT1339C............................................. 0°C to 70°C LT1339I ......................................... – 40°C to 85°C Storage Temperature Range ................. – 65°C to 150°C Lead Temperature (Soldering, 10 sec).................. 300°C ORDER PART NUMBER TOP VIEW SYNC 1 20 VBOOST 5VREF 2 19 TG CT 3 18 TS 16 BG IAVG 5 SS 6 15 PGND VC 7 14 PHASE 13 RUN/SHDN SGND 8 VFB 9 12 SENSE – VREF 10 11 SENSE + N PACKAGE 20-LEAD PDIP LT1339CN LT1339CSW LT1339IN LT1339ISW 17 12VIN SL/ADJ 4 SW PACKAGE 20-LEAD PLASTIC SO WIDE TJMAX = 125°C, θJA = 70°C/W (N) TJMAX = 125°C, θJA = 85°C/W (SW) Consult factory for Military grade parts. ELECTRICAL CHARACTERISTICS 12VIN = VBOOST = 12V, VC = 2V, TS = 0V, VFB = VREF = 1.25V, CTG = CBG = 3000pF, TA = 25°C unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS 14 150 20 250 mA µA Supply and Protection I12VIN IBOOST DC Active Supply Current (Note 2) DC Standby Supply Current VRUN/SHDN < 0.5V DC Active Supply Current (Note 2) DC Standby Supply Current VRUN/SHDN < 0.5V VRUN/SHDN Shutdown Rising Threshold ● ● 2.2 0 ● 1.15 1.25 mA µA 1.35 25 V VSSHYST Shutdown Threshold Hysteresis ISS Soft Start Charge Current ● 4 8 14 mV µA VUVLO Undervoltage Lockout Threshold - Falling Undervoltage Lockout Threshold - Rising Undervoltage Lockout Hysteresis ● ● ● 8.20 9.75 9.95 200 9.00 9.35 350 V V mV 4.75 5.00 5.25 3 5 mV/V 10 20 mA mA –2 V/A 5V Reference VREF5 IREF5 5V Reference Voltage Line, Load and Temperature ● 5V Reference Line Regulation 10V ≤ 12VIN ≤ 15V ● 5V Reference Load Range - DC Pulse 5V Reference Load Regulation ISC 2 5V Reference Short-Circuit Current ● ● 0 ≤ IREF5 ≤ 20mA ● – 1.25 45 V mA LT1339 ELECTRICAL CHARACTERISTICS 12VIN = VBOOST = 12V, VC = 2V, TS = 0V, VFB = VREF = 1.25V, CTG = CBG = 3000pF, TA = 25°C unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS ● 1.242 1.235 1.250 1.250 1.258 1.265 V V ● 0.1 0.5 1.0 µA 3200 Error Amplifier VFB Error Amplifier Reference Voltage Measured at Feedback Pin IFB Feedback Input Current gm Error Amplifier Transconductance ● 1200 2000 AV Error Amplifier Voltage Gain ● 1500 3000 V/V IVC Error Amplifier Source Current Error Amplifier Sink Current VFB – VREF = 500mV ● ● 200 280 275 400 µA µA VVC Absolute VC Clamp Voltage Measured at VC Pin 3.5 V VSENSE Peak Current Limit Threshold Average Current Limit Threshold (Note 4) Measured at Sense Inputs Measured at Sense Inputs Average Current Limit Threshold Measured at IAVG Pin 2.5 V 15 V/V VIAVG VFB = VREF ● ● 170 110 190 120 µmho mV mV 130 Current Sense Amplifier AV Amplifier DC Gain Measured at IAVG Pin VOS Amplifier Input Offset Voltage 2V < VCMSENSE < 60V, SENSE+ – SENSE– = 5mV ● IB Input Bias Current Sink (VCMSENSE > 5V) Source (VCMSENSE = 0V) ● ● fO ≤ 150kHz ● ● –5 0.1 mV 45 700 75 1200 µA µA 150 5 kHz % 2.75 2.75 mA mA V Oscillator fO Operating Frequency, Free Run Frequency Programming Error (Note 3) ICT Timing Capacitor Discharge Current LT1339C LT1339I ● ● 2.20 2.10 2.50 2.50 VSYNC SYNC Input Threshold Rising Edge ● 0.8 2.0 fSYNC SYNC Frequency Range fSYNC ≤ 150kHz ● fO 1.4fO 12VIN ≤ 8V VRUN < 0.5V ● ● Output Drivers VTG,BG Undervoltage Output Clamp Standby Mode Output Clamp VTG Top Gate On Voltage Top Gate Off Voltage ● ● tTGR Top Gate Rise Time ● tTGF Top Gate Fall Time ● VBG Bottom Gate On Voltage Bottom Gate Off Voltage ● ● tBGR Bottom Gate Rise Time tBGF Bottom Gate Fall Time The ● denotes specifications which apply over the full operating temperature range. Note 1: Absolute maximum ratings are those values beyond which the life of a device may be impaired. 11.0 0.4 0.7 0.1 V V 11.9 0.4 12.0 0.7 V V 130 200 ns 60 140 ns 11.9 0.4 12.0 0.7 V V ● 70 200 ns ● 60 140 ns 11.0 Note 2: Supply current specification does not include external FET gate charge currents. Actual supply currents will be higher and vary with operating frequency, operating voltages and the type of external FETs used. See Application Information section. Note 3: Test condition: RCT = 16.9k, CCT = 1000pF. Note 4: Test Condition: VCMSENSE = 10V. 3 LT1339 U W TYPICAL PERFORMANCE CHARACTERISTICS Boost Supply Current vs Temperature 12VIN Supply Current vs Temperature 5V REFERENCE SHORT-CIRCUIT CURRENT (mA) 18 17 3.5 I12VIN SUPPLY CURRENT (mA) BOOST SUPPLY CURRENT (mA) 4.0 3.0 2.5 2.0 1.5 16 15 14 13 12 11 1.0 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 10 –50 –25 125 0 25 50 75 50 45 40 35 30 –50 –25 1.252 180 1.251 160 150 100 125 5V Reference Voltage vs Temperature 5.01 5V REFERENCE VOLTAGE (V) 190 170 50 25 75 0 TEMPERATURE (°C) 1339 G03 Reference Voltage vs Temperature REFERENCE VOLTAGE (V) I12VIN SHUTDOWN CURRENT (µA) 125 55 1339 G02 I12VIN Shutdown Current vs Temperature 1.250 1.249 1.248 5.00 4.99 1.247 140 130 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 125 1.246 –50 –25 50 25 75 0 TEMPERATURE (°C) 4.0 3.5 3.0 2.5 2.0 1.5 100 125 1339 G07 50 25 75 0 TEMPERATURE (°C) 2.6 2.4 2.2 2.0 1.8 1.6 1.4 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 125 1339 G08 100 125 1339 G06 Error Amplifier Maximum Source Current vs Temperature ERROR AMPLIFIER SOURCE CURRENT (µA) Ω 4.5 50 25 75 0 TEMPERATURE (°C) 4.98 –50 –25 125 Error Amplifier Transconductance vs Temperature ERROR AMPLIFIER TRANSCONDUCTANCE (m ) Error Amplifier Voltage Gain vs Temperature 1.0 –50 –25 100 1339 G05 1339 G04 ERROR AMPLIFIER VOLTAGE GAIN (kV/V) 100 60 TEMPERATURE (°C) 1339 G01 4 5V Reference Short-Circuit Current vs Temperature 350 325 300 275 250 225 200 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 125 1339 G09 LT1339 U W TYPICAL PERFORMANCE CHARACTERISTICS Soft Start Charge Current vs Temperature RUN/SHDN Rising Threshold vs Temperature 8 7 6 –50 –25 50 25 75 0 TEMPERATURE (°C) 100 26 RUN/SHDN THRESHOLD HYSTERESIS (mV) 1.26 RUN/SHDN RISING THRESHOLD (V) SOFT START CHARGE CURRENT (µA) 9 1.25 1.24 1.23 1.22 1.21 1.20 –50 –25 125 50 25 75 0 TEMPERATURE (°C) 100 1339 G10 60 FALL TIME 40 20 5000 7500 2500 BOTTOM GATE CAPACITANCE (pF) 50 25 75 0 TEMPERATURE (°C) 10000 100 125 1339 G12 160 FULL OPERATING TEMPERATURE RANGE 150 250 140 UPPER LIMIT 200 RISE TIME 150 100 FALL TIME 130 TYPICAL 120 LOWER LIMIT 110 100 50 90 80 0 1000 5000 7500 2500 TOP GATE CAPACITANCE (pF) 1339 G13 10000 0 1 2 3 4 5 VSENSE(CM) (V) 1339 G14 12VIN Supply Current vs Supply Voltage 60 1339 G15 Boost Supply Current vs 12VIN Supply Voltage 30 18 fO = 100kHz TA = 25°C 28 BOOST SUPPLY CURRENT (mA ) 0 1000 21 Average Current Limit Threshold Sense Voltage Tolerance vs Common Mode Voltage VSENSE (mV) TOP GATE TRANSITION TIMES (ns) RISE TIME 22 20 –50 –25 TA = 25°C 12VIN SUPPLY CURRENT (mA ) BOTTOM GATE TRANSITION TIMES (ns) 80 23 125 300 TA = 25°C 100 24 Top Gate Transition Times vs Top Gate Capacitance 160 120 25 1339 G11 Bottom Gate Transition Times vs Bottom Gate Capacitance 140 RUN/SHDN Threshold Hysteresis vs Temperature CBG = 10000pF 26 24 22 CBG = 4700pF 20 18 CBG = 3300pF 16 CBG = 1000pF fO = 100kHz TA = 25°C 16 CTG = 10000pF 14 12 10 CTG = 4700pF 8 CTG = 3300pF 6 CTG = 1000pF 4 14 2 10 12 13 14 11 12VIN SUPPLY VOLTAGE (V) 15 1339 G16 10 12 13 14 11 12VIN SUPPLY VOLTAGE (V) 15 1339 G17 5 LT1339 U W TYPICAL PERFORMANCE CHARACTERISTICS Sense Amplifier Input Bias Current (Source) vs Temperature UVLO Thresholds vs Temperature 10.00 1200 9.75 1100 RISING FALLING 8.75 900 800 700 8.50 600 8.25 500 0 50 25 75 0 25 50 75 100 600 500 UPPER LIMIT 300 200 100 0 600 TYPICAL LOWER LIMIT 1.0 (1.25) 1.5 2.0 0.5 RUN/SHDN INPUT VOLTAGE (V) FULL OPERATING TEMPERATURE RANGE 450 UPPER LIMIT TYPICAL 300 LOWER LIMIT 150 0 2.5 0 2 4 6 8 10 RUN/SHDN SUPPLY VOLTAGE (V) Operating Frequency (Normalized) vs Temperature 100 MAXIMUM DUTY CYCLE (%) IDISCHG = 2.75mA 80 70 60 50 IDISCHG = 2.1mA 40 30 20 FULL OPERATING TEMPERATURE RANGE 10 1 2 4 6 10 20 RCT (kΩ) 40 60 100 1339 G21 6 OPERATING FREQUENCY (NORMALIZED) 1.01 90 0 12 1339 G23 1339 G22 Maximum Duty Cycle vs RCT 1.00 0.99 0.98 –50 –25 100 125 1339 G20 RUN/SHDN Input Current vs Pin Voltage RUN/SHDN INPUT CURRENT (µA) FULL OPERATING TEMPERATURE RANGE .................................................................. RUN/SHDN INPUT CURRENT (nA ) 800 50 25 75 0 TEMPERATURE (°C) 1339 G19 RUN/SHDN Input Current vs Pin Voltage 0 30 –50 –25 125 TEMPERATURE (°C) 1339 G18 400 45 35 TEMPERATURE (°C) 700 50 40 400 –50 –25 125 100 IB(SINK) (µA) 9.25 9.00 VCMSENSE = 10V 55 1000 IB(SOURCE) (µA) V12VIN (V) 60 VCMSENSE = 0V 9.50 8.00 –50 –25 Sense Amplifier Input Bias Current (Sink) vs Temperature 50 25 75 0 TEMPERATURE (°C) 100 125 1339 G24 LT1339 U U U PIN FUNCTIONS SYNC (Pin 1): Oscillator Synchronization Pin with TTLLevel Compatible Input. Input drives internal rising edge triggered one-shot; sync signal on/off times should be ≥1µs (10% to 90% DC at 100kHz). Does not contain internal pull-up. Connect to SGND if not used. 5VREF (Pin 2): 5V Output Reference. Allows connection of external loads up to 10mA DC. (Reference is not available in shutdown.) Typically bypassed with 1µF capacitor to SGND. CT (Pin 3): Oscillator Timing Pin. Connect a capacitor (CCT) to ground and a pull-up resistor (RCT) to the 5VREF supply. Typical values are CT = 1000pF and 10k ≤ RCT ≤ 30k. SL/ADJ (Pin 4): Slope Compensation Adjustment. Allows increased slope compensation for certain high duty cycle applications. Resistive loading of the pin increases effective slope compensation. A resistor divider from the 5VREF pin can tailor the onset of additional slope compensation to specific regions in each switch cycle. Pin can be floated or connected to 5VREF if no additional slope compensation is required. (See Applications Information section for slope compensation details.) IAVG (Pin 5): Average Current Limit Integration. Frequency response characteristic is set using the 50kΩ output impedance and external capacitor to ground. Averaging roll-off typically set at 1 to 2 orders of magnitude under switching frequency. (Typical capacitor value ~1000pF for fO = 100kHz.) Shorting this pin to SGND will disable the average current limit function. SS (Pin 6): Soft Start. Generates ramping threshold for regulator current limit during start-up and after UVLO event by sourcing about 8µA into an external capacitor. VC (Pin 7): Error Amplifier Output. RC load creates dominant compensation in power supply regulation feedback loop to provide optimum transient response. (See Applications Information section for compensation details.) VREF (Pin 10): Bandgap Generated Voltage Reference Decoupling. Connect a capacitor to signal ground. (Typical capacitor value ~0.1µF.) SENSE + (Pin 11): Current Sense Amplifier Inverting Input. Connect to most positive (DC) terminal of current sense resistor. SENSE – (Pin 12): Current Sense Amplifier Noninverting Input. Connect to most negative (DC) terminal of current sense resistor. RUN/SHDN (Pin 13): Precision Referenced Shutdown. Can be used as logic level input for shutdown control or as an analog monitor for input supply undervoltage protection, etc. IC is enabled when RUN/SHDN pin rising edge exceeds 1.25V. About 25mV of hysteresis helps assure stable mode switching. All internal functions are disabled in shutdown mode. If this function is not desired, connect RUN/SHDN to 12VIN (typically through a 100k resistor). See Applications Information section. PHASE (Pin 14): Output Driver Phase Control. If Pin 14 is not connected (floating), the topside driver operates the main switch, with the bottom side driver operating the synchronous switch. Shorting Pin 14 to ground reverses the roles of the output drivers. PHASE is typically shorted to ground for inverting and boost configurations. Positive buck configuration requires the PHASE pin to float. See Applications Information section. PGND (Pin 15): Power Ground. References the bottom side output switch and internal driver control circuits. Connect with low impedance trace to VIN decoupling capacitor negative (ground) terminal. BG (Pin 16): Bottom Side Output Driver. Connects to gate of bottom side external power FET. 12VIN (Pin 17): 12V Power Supply Input. Bypass with at least 1µF to PGND. TS (Pin 18): Boost Output Driver Reference. Typically connects to source of topside external power FET and inductive switch node. SGND (Pin 8): Small-Signal Ground. Connect to negative terminal of COUT. TG (Pin 19): Topside (Boost) Output Driver. Connects to gate of topside external power FET. VFB (Pin 9): Error Amplifier Inverting Input. Used as voltage feedback input node for regulator loop. Pin sources about 0.5µA DC bias current to protect from an open feedback path condition. VBOOST (Pin 20): Topside Power Supply. Bootstrapped via 1µF capacitor tied to switch node (Pin 18) and Schottky diode connected to the 12VIN supply. 7 LT1339 W FUNCTIONAL BLOCK DIAGRA U U VIN VBOOST MAIN SWITCH CT PHASE 12VIN 5VREF TG TS NONOVERLAPPING SWITCH LOGIC BG Q SYNC SWITCH S UVLO CIRCUIT R OSC SL/ADJ ONE SHOT SENSE + RSENSE VOUT + × 15 SENSE – + SYNC + – IC1 CURRENT SENSE AMP 0.5µA – – VFB VC EA + VREF 1.25V 5VREF 2.5V 5V – 8µA REFERENCE 50k SOFT START + + RUN/SHDN AVERAGE CURRENT LIMIT CIRCUIT ENABLE 1.25V – SGND PGND SS IAVG 1339 • BD U OPERATION (Refer to Functional Block Diagram) Basic Control Loop The LT1339 uses a constant frequency, current mode synchronous architecture. The timing of the IC is provided through an internal oscillator circuit, which can be synchronized to an external clock, programmable to operate at frequencies up to 150kHz. The oscillator creates a modified sawtooth wave at its timing node (CT) with a slow charge, rapid discharge characteristic. During typical positive buck operation, the main switch MOSFET is enabled at the start of each oscillator cycle. The main switch stays enabled until the current through the switched inductor, sensed via the voltage across a series 8 sense resistor (RSENSE), is sufficient to trip the current comparator (IC1) and, in turn, reset the RS latch. When the RS latch resets, the main switch is disabled, and the synchronous switch MOSFET is enabled. Shoot-through prevention logic prohibits enabling of the synchronous switch until the main switch is fully disabled. If the current comparator threshold is not obtained throughout the entire oscillator charge period, the RS latch is bypassed and the main switch is disabled during the oscillator discharge time. This “minimum off time” assures adequate charging of the bootstrap supply, protects the main switch, and is typically about 1µs. LT1339 U OPERATION (Refer to Functional Block Diagram) The current comparator trip threshold is set on the VC pin, which is the output of a transconductance amplifier, or error amplifier (EA). The error amplifier integrates the difference between a feedback voltage (on the VFB pin) and an internal bandgap generated reference voltage of 1.25V, forming a signal that represents required load current. If the supplied current is insufficient for a given load, the output will droop, thus reducing the feedback voltage. The error amplifier forces current out of the VC pin, increasing the current comparator threshold. Thus, the circuit will servo until the provided current is equal to the required load and the average output voltage is at the value programmed by the feedback resistors. Average Current Limit The output of the sense amplifier is monitored by a single pole integrator comprised of an external capacitor on the IAVG pin and an internal impedance of approximately 50kΩ. If this averaged value signal exceeds a level corresponding to 120mV across the external sense resistor, the current comparator threshold is clamped and cannot continue to rise in response to the error amplifier. Thus, if average load current requirements exceed 120mV/RSENSE, the supply will current limit and the output voltage will fall out of regulation. The average current limit circuit monitors the sense amplifier output without slope compensation or ripple current contributions, therefore the average load current limit threshold is unaffected by duty cycle. Undervoltage Lockout The LT1339 employs an undervoltage lockout circuit (UVLO) that monitors the 12V supply rail. This circuit disables the output drive capability of the LT1339 if the 12V supply drops below about 9V. Unstable mode switching is prevented through 350mV of UVLO threshold hysteresis. Adaptive Nonoverlapping Output Stage The FET driver output stage implements adaptive nonoverlapping control. This circuitry maintains dead time independent of the type, size or operating conditions of the switch elements. The control circuit monitors the output gate drive signals, insuring that the switch gate (being disabled) is fully discharged before enabling the other switch driver. Shutdown The LT1339 can be put into low current shutdown mode by pulling the RUN/SHDN pin low, disabling all circuit functions. The shutdown threshold is a bandgap referred voltage of 1.25V typical. Use of a precision threshold on the shutdown circuit enables use of this pin for undervoltage protection of the VIN supply and/or power supply sequencing. Soft Start The LT1339 incorporates a soft start function that operates by slowly increasing the internal current limit. This limit is controlled by clamping the VC node to a low voltage that climbs with time as an external capacitor on the SS pin is charged with about 8µA. This forces a graceful climb of output current capability, and thus a graceful increase in output voltage until steady-state regulation is achieved. The soft start timing capacitor is clamped to ground during shutdown and during undervoltage lockout, yielding a graceful output recovery from either condition. 5V Internal Reference Power for the oscillator timing elements and most other internal LT1339 circuits is derived from an internal 5V reference, accessible at the 5VREF pin. This supply pin can be loaded with up to 10mA DC (20mA pulsed) for convenient biasing of local elements such as control logic, etc. Slope Compensation For duty cycles greater than 50%, slope compensation is required to prevent current mode duty cycle instability in the regulator control loop. The LT1339 employs internal slope compensation that is adequate for most applications. However, if additional slope compensation is desired, it is available through the SL/ADJ pin. Excessive slope compensation will cause reduction in maximum load current capability and therefore is not desirable. 9 LT1339 U U W U APPLICATIONS INFORMATION RSENSE generates a voltage that is proportional to the inductor current for use by the LT1339 current sense amplifier. The value of RSENSE is based on the required load current. The average current limit function has a typical threshold of 120mV/RSENSE, or: RSENSE = 120mV/ILIMIT Operation with VSENSE common mode voltage below 4.5V may slightly degrade current limit accuracy. See Average Current Limit Threshold Tolerance vs Common Mode Voltage curve in the Typical Performance Characteristics section for more information. Output Voltage Programming Output voltage is programmed through a resistor feedback network to VFB (Pin 9) on the LT1339. This pin is the inverting input of the error amplifier, which is internally referenced to 1.25V. The divider is ratioed to provide 1.25V at the VFB pin when the output is at its desired value. The output voltage is thus set following the relation: VOUT = 1.25(1 + R2/R1) when an external resistor divider is connected to the output as shown in Figure 1. VOUT R2 LT1339 VFB SGND 9 R1 8 1339 • F01 Figure 1. Programming LT1339 Output Voltage If high value feedback resistors are used, the input bias current of the VFB pin (1µA maximum) could cause a slight increase in output voltage. A Thevenin resistance at the VFB pin of <5k is recommended. the minimum off-time of the PWM controller. This limits maximum duty cycle (DCMAX) to: DCMAX = 1 – (tDISCH)(fO) This relation corresponds to the minimum value of the timing resistor (RCT), which can be determined according to the following relation (RCT vs DCMAX graph appears in the Typical Performance Characteristics section): RCT(MIN) ≈ [(0.8)(10 –3)(1 – DCMAX)] –1 Values for RCT > 15k yield maximum duty cycles above 90%. Given a timing resistor value, the value of the timing capacitor (CCT) can then be determined for desired operating frequency (fO) using the relation: (1/ fO ) − (100) 10−9 CCT ≈ (RCT / 1.85) + −3 1.75 (2.5) 10 − (3.375 / RCT ) A plot of Operating Frequency vs RCT and CCT is shown in Figure 2. Typical 100kHz operational values are CCT = 1000pF and RCT = 16.9k. 160 OSCILLATOR FREQUENCY (kHz) RSENSE Selection for Output Current 140 CCT = 1.0nF 120 CCT = 1.5nF 100 80 60 CCT = 3.3nF 40 CCT = 2.2nF 20 0 0 5 10 20 25 15 TIMING RESISTOR (kΩ) 30 LT1339 • F02 Figure 2. Oscillator Frequency vs RCT, CCT Oscillator Components RCT and CCT Average Current Limit The LT1339 oscillator creates a modified sawtooth wave at its timing node (CT) with a slow charge, rapid discharge characteristic. The rapid discharge time corresponds to The average current limit function is implemented using an external capacitor (CAVG) connected from IAVG to SGND that forms a single pole integrator with the 50kΩ output 10 LT1339 U W U U APPLICATIONS INFORMATION impedance of the IAVG pin. The integrator corner frequency is typically set 1 to 2 orders of magnitude below the oscillator frequency and follows the relation: f–3dB = (3.2)(10– 6)/CAVG The average current limit function can be disabled by shorting the IAVG pin directly to SGND. Soft Start Programming The current control pin (VC) limits sensed inductor current to zero at voltages less than a transistor VBE, to full average current limit at VC = VBE + 1.8V. This generates a 1.8V full regulation range for average load current. An internal voltage clamp forces the VC pin to a VBE – 100mV above the SS pin voltage. This 100mV “dead zone” assures 0% duty cycle operation at the start of the soft start cycle, or when the soft start pin is pulled to ground. Given the typical soft start current of 8µA and a soft start timing capacitor CSS, the start-up delay time to full available average current will be: tSS = (1.5)(105)(CSS) ing capabilities of that supply, causing the system to lock up in an undervoltage state. Input supply start-up protection can be achieved by enabling the RUN/SHDN pin using a resistor divider from the input supply to ground. Setting the divider output to 1.25V when that supply is almost fully enabled prevents the LT1339 regulator from drawing large currents until the input supply is able to provide the required power. If additional hysteresis is desired for the enable function, an external feedback resistor can be used from the LT1339 regulator output. If connection to the regulator output is not desired, the 5VREF internal supply pin can be used. Figure 3 shows a resistor connection on a 48V to 5V converter that yields a 40V VIN start-up threshold for regulator enable and also provides about 10% input referred hysteresis. VIN 48V 300k 390k Boost Supply The VBOOST supply is bootstrapped via an external capacitor. This supply provides gate drive to the topside switch FET. The bootstrap capacitor is charged from 12VIN through a diode when the switch node is pulled low. The diode reverse breakdown voltage must be greater than VIN + 12VIN. The bootstrap capacitor should be at least 100 times greater than the total input capacitance of the topside FET. A capacitor in the range of 0.1µF to 1µF is generally adequate for most applications. Shutdown Function — Input Undervoltage Detect and Threshold Hysteresis The LT1339 RUN/SHDN pin uses a bandgap generated reference threshold of about 1.25V. This precision threshold allows use of the RUN/SHDN pin for both logic-level shutdown applications and analog monitoring applications such as power supply sequencing. Because an LT1339 controlled converter is a power transfer device, a voltage that is lower than expected on the input supply could require currents that exceed the sourc- VOUT 5V OPTION 1 OPTION 2 2 13 10k 5VREF LT1339 RUN/SHDN 1339 • F03 Figure 3. Input Supply Sequencing Programming The shutdown function can be disabled by connecting the RUN/SHDN pin to the 12VIN rail. This pin is internally clamped to 2.5V through a 20k series input resistance and will therefore draw about 0.5mA when tied directly to 12V. This additional current can be minimized by making the connection through an external resistor (100k is typically used). Inductor Selection The inductor for an LT1339 converter is selected based on output power, operating frequency and efficiency requirements. Generally, the selection of inductor value can be reduced to desired maximum ripple current in the inductor (∆I). For a buck converter, the minimum inductor value for a desired maximum operating ripple current can be determined using the following relation: 11 LT1339 U W U U APPLICATIONS INFORMATION (VOUT )(VIN − VOUT) L MIN = (∆I)(fO)(VIN) where fO = operating frequency. Given an inductor value (L), the peak inductor current is the sum of the average inductor current (IAVG)and half the inductor ripple current (∆I), or: (VOUT )(VIN − VOUT) IPK = IAVG + (2)(L)(fO)(VIN) The inductor core type is determined by peak current and efficiency requirements. The inductor core must withstand peak current without saturating, and series winding resistance and core losses should be kept as small as is practical to maximize conversion efficiency. The LT1339 peak current limit threshold is 40% greater than the average current limit threshold. Slope compensation effects reduce this margin as duty cycle increases. This margin must be maintained to prevent peak current limit from corrupting the programmed value for average current limit. Programming the peak ripple current to less than 15% of the desired average current limit value will assure porper operation of the average current limit feature through 90% duty cycle (see Slope Compensation section). Oscillator Synchronization The LT1339 oscillator generates a modified sawtooth waveform at the CT pin between low and high thresholds of about 0.8V (vl) and 2.5V (vh) respectively. The oscillator can be synchronized by driving a TTL level pulse into the SYNC pin. This inputs to a one-shot circuit that reduces the oscillator high threshold to 2V for about 200ns. The SYNC input signal should have minimum high/low times of ≥1µs. Slope Compensation Current mode switching regulators that operate with a duty cycle greater than 50% and have continuous inductor current can exhibit duty cycle instability. While a regulator will not be damaged and may even continue to function 12 SYNC 2.5V (vh) 2V VCT (vl) 0.8V FREE RUN SYNCHRONIZED 1339 F04 Figure 4. Free Run and Synchronized Oscillator Waveforms (at CT Pin) acceptably during this type of subharmonic oscillation, an irritating high-pitched squeal is usually produced. The criterion for current mode duty cycle instability is met when the increasing slope of the inductor ripple current is less than the decreasing slope, which is the case at duty cycles greater than 50%. This condition is illustrated in Figure 5a. The inductor ripple current starts at I1, at the beginning of each oscillator switch cycle. Current increases at a rate S1 until the current reaches the control trip level I2. The controller servo loop then disables the main switch (and enables the synchronous switch) and inductor current begins to decrease at a rate S2. If the current switch point (I2) is perturbed slightly and increased by ∆I, the cycle time ends such that the minimum current point is increased by a factor of (1 + S2/S1) to start the next cycle. On each successive cycle, this error is multiplied by a factor of S2/S1. Therefore, if S2/S1 is ≥ 1, the system is unstable. Subharmonic oscillations can be eliminated by augmenting the increasing ripple current slope (S1) in the control loop. This is accomplished by adding an artificial ramp on the inductor current waveform internal to the IC (with a slope SX) as shown in Figure 5b. If the sum of the slopes S1 + SX is greater than S2, the condition for subharmonic oscillation no longer exists. For a buck converter, the required additional current waveform slope, or “Slope Compensation,” follows the relation: V SX ≥ IN 2DC − 1 L ( ) LT1339 U U W U APPLICATIONS INFORMATION T1 S1 + SX I2 I1 0 S1 S2 S1 S2 OSCILLATOR PERIOD 0 TIME a b 1339 • F05 Figure 5. Inductor Current at DC > 50% and Slope Compensation Adjusted Signal For duty cycles less than 50% (DC < 0.5), SX is negative and is not required. For duty cycles greater than 50%, SX takes on values dependent on S1 and duty cycle. This leads to a minimum inductance requirement for a given VIN and duty cycle of: V L MIN = IN 2DC− 1 SX ( ) The LT1339 contains an internal SX slope compensation ramp that has an equivalent current referred value of: fO 0.084 RSENSE If an inductor smaller than the minimum required for internal slope compensation (calculated above as LMIN) is desired, additional slope compensation is required. The LT1339 provides this capability through the SL/ADJ pin. This feature is implemented by referencing this pin via a resistor divider from the 5VREF pin to ground. The additional slope compensation will be affected at the point in the oscillator waveform (at pin CT) corresponding to the voltage set by the resistor divider. Additional slope compensation can be calculated using the relation: SXADD = (2500)( fO ) (REQ )(RSENSE ) Amp/s where REQ is the effective resistance of the resistor divider. Actual compensation will be somewhat greater due to internal curvature correction circuitry that imposes an exponential increase in the slope compensation waveform, further increasing the effective compensation slope up to 20% for a given setting. 1.45 Amp/s where fO is oscillator frequency. This yields a minimum inductance requirement of: (VIN)(RSENSE)(2DC− 1) L MIN ≥ (0.084)(fO) A down side of slope compensation is that, since the IC servo loop senses an increase in perceived inductor current, the internal current limit functions are affected such that the maximum current capability of a regulator is reduced by the same amount as the effective current referred slope compensation. The LT1339, however, uses a current limit scheme that is independent of slope compensation effects (average current limit). This provides operation at any duty cycle with no reduction in current sourcing capability, provided ripple current peak amplitude is less than 15% of the current limit value. For example, if the supply is set up to current limit at 10A, as long as the peak inductor current is less than 11.5A, duty cycles up to 90% can be achieved without compromising the average current limit value. 1.40 1.35 PEAK/AVG ∆I 1.30 1.25 1.20 1.15 1.10 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 DUTY CYCLE (DC) LT1339 • F06 Figure 6. Maximum Ripple Current (Normalized) vs Duty Cycle for Average Current Limit Design Example: VIN = 20V VOUT = 15V (DC = 0.75) RSENSE = 0.01Ω fO = 100kHz L = 5µH The minimum inductor usable with no additional slope compensation is: 13 LT1339 U W U U APPLICATIONS INFORMATION (20V)(0.01Ω)(1.5 − 1) = 11.9µH LMIN ≥ (0.084)(100000) Since L = 5µH is less than LMIN, additional slope compensation is necessary. The total slope compensation required is: 20V SX ≥ 1.5 − 1 = 2 106 5µH ( ) () Amp/s Subtracting the internally generated slope compensation and solving for the required effective resistance at SL/ADJ yields: REQ ≤ (2500)(fO) = 21.5k 6 (2)10 (RSENSE) − (0.084)(fO) Setting the resistor divider reference voltage at 2V assures that the additional compensation waveform will be enabled at 75% duty cycle. As shown in Figure 7a, using 2 RSL1 45k 5VREF SL/ADJ RSL2 30k Power MOSFET and Catch Diode Selection External N-channel MOSFET switches are used with the LT1339. The positive gate-source drive voltage of the LT1339 for both switches is roughly equivalent to the 12VIN supply voltage, so standard threshold MOSFETs can be used. Selection criteria for the power MOSFETs include the “ON” resistance (RDS(ON)), reverse transfer capacitance (CRSS), maximum drain-source voltage (VDSS) and maximum output current. The power FETs selected must have a maximum operating VDSS exceeding the maximum VIN. VGS voltage maximum must exceed the 12VIN supply voltage. Once voltage requirements have been determined, RDS(ON) can be selected based on allowable power dissipation and required output current. In an LT1339 buck converter, the average inductor current is equal to the DC load current. The average currents through the main and synchronous switches are: LT1339 4 RSL1 = 45k and RSL2 = 30k sets the desired reference voltage and has a REQ of 18k, which meets both design requirements. Figure 7b shows the slope compensation effective waveforms both with and without the SL/ADJ external resistors. 1339 • F07a Figure 7a. External Slope Compensation Resistors 2.5V IMAIN = (ILOAD)(DC) ISYNC = (ILOAD)(1 – DC) The RDS(ON) required for a given conduction loss can be calculated using the relation: 2V PLOSS = (ISWITCH)2(RDS(ON)) 0.8V DC = 0.75 (0.084 + 0.139)(fO) RSENSE (0.084)(fO) RSENSE In high voltage applications (VIN > 20V), the topside switch is required to slew very large voltages. As VIN increases, transition losses increase through a square relation, until it becomes the dominant power loss term in the main switch. This transition loss takes the form: PTR ≈ (k)(VIN)2(IMAX)(CRSS)(fO) where k is a constant inversely related to the gate drive current, approximated by k = 2 in LT1339 applications. 1339 • F07b Figure 7b. Slope Compensation Waveforms 14 LT1339 U W U U APPLICATIONS INFORMATION The maximum power loss terms for the switches are thus: PMAIN = (DC)(IMAX)2(1 + δ)(RDS(ON)) + 2(VIN)2(IMAX)(CRSS)(fO) PSYNC = (1 – DC)(IMAX)2(1 + δ)(RDS(ON)) The (1 + δ) term in the above relations is the temperature dependency of RDS(ON), typically given in the form of a normalized RDS(ON) vs Temperature curve in a MOSFET data sheet. In some applications, parasitic FET capacitances couple the negative going switch node transient onto the bottom gate drive pin of the LT1339, causing a negative voltage in excess of the Absolute Maximum Rating to be imposed on that pin. Connection of a catch Schottky (rated to about 1A is typically sufficient) from this pin to ground will eliminate this effect. CIN and COUT Supply Decoupling Capacitor Selection The large currents typical of LT1339 applications require special consideration for the converter input and output supply decoupling capacitors. Under normal steady state operation, the source current of the main switch MOSFET is a square wave of duty cycle VOUT/VIN. Most of this current is provided by the input bypass capacitor. To prevent large input voltage transients and avoid bypass capacitor heating, a low ESR input capacitor sized for the maximum RMS current must be used. This maximum capacitor RMS current follows the relation: (IMAX )(VOUT (VIN – VOUT )) 1/ 2 IRMS ≈ VIN which peaks at a 50% duty cycle, when IRMS = IMAX/2. Capacitor ripple current ratings are often based on only 2000 hours (three months) lifetime; it is advisable to derate either the ESR or temperature rating of the capacitor for increased MTBF of the regulator. The output capacitor in a buck converter generally has much less ripple current than the input capacitor. Peak-topeak ripple current is equal to that in the inductor (∆IL), typically a fraction of the load current. COUT is selected to reduce output voltage ripple to a desirable value given an expected output ripple current. Output ripple (∆VOUT) is approximated by: ∆VOUT ≈ ∆IL{ESR + [(4)(fO) • COUT]–1} where fO = operating frequency. Efficiency Considerations and Heat Dissipation High output power applications have inherent concerns regarding power dissipation in converter components. Although high efficiencies are achieved using the LT1339, the power dissipated in the converter climbs to relatively high values when the load draws large amounts of power. Even at 90% efficiency, an application that provides 500W to the load has conversion loss of 55W. I2R dissipation through the switches, sense resistor and inductor series resistance create substantial losses under high currents. Generally, the dominant I2R loss is evident in the FET switches. Loss in each switch is proportional to the conduction time of that switch. For example, in a 48V to 5V converter the synchronous FET conducts load current for almost 90% of the cycle time and thus, requires greater consideration for dissipating I2R power. Gate charge/discharge current creates additional current drain on the 12V supply. If powered from a high voltage input through a linear regulator, the losses in that regulator device can become significant. A supply solution bootstrapped from the output would draw current from a lower voltage source and reduce this loss component. Transition losses are significant in the topside switch FET when high VIN voltages are used. Transition losses can be estimated as: PTLOSS ≈ 2(VIN)2(IMAX)(CRSS)(fO) Since the conduction time in the main switch of a 48V to 5V converter is small, the I2R loss in the main switch FET is also small. However, since the FET gate must switch up past the 48V input voltage, transition loss can become a significant factor. In such a case, it is often prudent to take the increased I2R loss of a smaller FET in order to reduce CRSS and thus, the associated transition losses. Gate Drive Buffers The LT1339 is designed to drive relatively large capacitive loads. However, in certain applications, efficiency improvements can be realized by adding an external buffer stage to drive the gates of the FET switches. When the 15 LT1339 U W U U APPLICATIONS INFORMATION switch gates load the driver outputs such that rise/fall times exceed about 100ns, buffers can sometimes result in efficiency gains. Buffers also reduce the effect of back injection into the bottom side driver output due to coupling of switch node transitions through the switch FET CMILLER. Paying the Physicists In high power synchronous buck configurations, certain physical characteristics of the external MOSFET switches can impact conversion efficiency. As the input voltage approaches about 30V, the bottom MOSFETs will begin to exhibit “phantom turn-on.” This phenomenon is caused by coupling of the instantaneous voltage step on the bottom side switch drain through CMILLER to the device gate, yielding internal localized gate-source voltages above the turn-on threshold of the FET. This generates a shootthrough blip that ultimately eats away at efficiency numbers. In Figure 8 a negative prebias circuit is added to the bottom side gate. The addition of this ∼3V of negative offset to the bottom gate drive provides additional offstate voltage range to prevent phantom turn-on. TS 3.3V 12VIN ZTX649 1µF LT1339 BG ZTX749 10k D1N914 PGND 1339 F08 Figure 8. Bottom Side Driver Negative Prebias Circuit not available for high voltages, so as input voltage continues to increase, they can no longer be used. Because this necessitates the use of discrete FETs and Schottkys, interdigitation of a number of smaller devices is required to minimize parasitic inductances. This technique is also used in the 48V to 5V, 50A converter shown in the Typical Applications section. This type of prebias circuit is used in the 48V to 5V, 50A converter pictured in the Typical Applications section. Optimizing Transient Response—Compensation Component Values As currents increase beyond the 10A to 15A range, the bottom side FET body diode experiences hard turn-on during switch dead time due to local current loop inductance preventing the timely transfer of charge to the Schottky catch diode. The charge current required to commutate this body diode creates a high dV/dt Schottky avalanche when the diode charge is finally exhausted (due to an effective inductor current discontinuity at the moment the body diode no longer requires charge). This generates an increased turn-on power burst in the topside switch, causing additional conversion efficiency loss. This effect of this parasitic inductance can be reduced by using FETKEY TM MOSFETs, which have parallel catch Schottky diodes internal to their packages. FETKEY MOSFETs are The dominant compensation point for an LT1339 converter is the VC pin (Pin 7), or error amplifier output. This pin is connected to a series RC network, RVC and CVC. The infinite permutations of input/output filtering, capacitor ESR, input voltage, load current, etc. make for an empirical method of optimizing loop response for a specific set of conditions. Loop response can be observed by injecting a step change in load current. This can be achieved by using a switchable load. With the load switching, the transient response of the output voltage can be observed with an oscilloscope. Iterating through RC combinations will yield optimized response. Refer to LTC Application Note 19 in 1990 Linear Applications Handbook, Volume 1 for more information. FETKEY is a trademark of International Rectifier Corporation. 16 C11 0.1µF + + C12 100pF + C10 0.1µF C9 1800pF 5% NPO + + + + C14 3300pF R9 12k C1: SANYO 63MV680GX C2: WIMA SMD4036/1.5/63/20/TR C6: KEMET T510X477M006AS (X8) L1: GOWANDA 50-318 T1: GOWANDA 50-319 + R5 2.49k 1% 12V VIN 48V 10 7 6 5 3 4 2 1 17 C15 0.1µF 8 SGND VREF VC SS IAVG CT 11 18 19 20 15 PGND 12 SENSE – 16 BG 14 PHASE 13 RUN/SHDN 9 VFB SENSE + TS TG 5VREF SL/ADJ VBOOST SYNC D2 MURS120 C2 1.5µF 63V 12VIN + U1 LT1339 C5 1µF C1 680µF 63V R6, 100Ω D5 BAT54 R10 10k 1% R8 301k 1% R7 100Ω 4 3 2 1 4 3 2 1 VCC1 OUT1 VCC2 GND1 IN2 OUT2 VCC1 IN1 U3, LTC1693-2 GND2 5 6 7 8 5 6 7 8 C7 1µF VCC2 OUT2 GND2 OUT1 IN2 GND1 IN1 U2, LTC1693-2 + + C13 1µF + D4 MBR0530T1 C8 1µF D3 MURS120 Q1 MTD20N06HD R1 0.04Ω Q3 MTD20N06HD 13:2 T1 D1 MURS120 48V to 1.8V 2-Transistor Synchronous Forward Converter 3 2 1 8 7 6 5 R2 5.1Ω + Q4 Si4420 X2 4 C3 4700pF 25V 3 2 1 8 7 6 5 L1 1.5µH + Q2 Si4420 X2 4 C6 470µF 6.3V X8 1339 TA05 + C4 0.1µF R4 1.24k 1% R3 549Ω 1% VOUT 1,8V 20A LT1339 TYPICAL APPLICATIONS 17 U C1 1.2µF 100V CER 68µF 20V AVX TSPE 10k P + 100k 0.1µF P 3.9k GND1 IN1 PHASE JP3 W2 T1 2 W3 2 7 5 6 18 1 RUN/SHDN 12VIN 20 2.2µF 19 OUT1 VCC1 470Ω OUT2 IN2 VCC2 LTC1693-1 GND2 JP2 100k 14 13 17 1 8 3 4 12V 5VOUT SHORT JP3, OPEN JP2 3.3VOUT, SHORT JP2, OPEN JP3 BAS21 BAS21 BAS21 13k MMBD914LT1 C2 1.2µF 100V CER COILCRAFT DO1608-105 36k +VIN –VIN INPUT 36V TO 75V +VIN +VIN BAT54 2.2µF 10Ω 5 10 P W4, 7T 6 x 26AWG W5, 10T 2 x 26AWG W1, 10T 32AWG, W2, 15T 32AWG W1, 10T 2 x 26AWG T2 T2 T1 8 15 W4 W4 4.7nF 7 VFB BG 4.7k 4.7k 9 2MIL POLY FILM 2MIL POLY FILM 2.4k 1µF BAT54 + OUT1 IN1 T2 P 2 7 5 6 85 90 95 100k + C5 330µF 6.3V 0 1 1 5 2 REF 6 8 48VIN 72VIN 8 9 10 4.42k 1% –VOUT 9.31k 1% BAS21 10Ω SEC HV 1339 TA06 SHORT JP1 FOR 5VOUT 0.01µF 1k 0.47µF 50V 3.01k 1% +VOUT MMFT3904 7 LT1431CS8 36VIN –VOUT OUTPUT 5V/10A +VOUT 2k 3.1V 3 4 5 6 7 OUTPUT CURRENT COLL 4 2 0.22µF 1µF 4.7µF 25V 1k –VOUT FZT600 + +VOUT 3 C3, C4, C5: SANYO OS-CON C4 330µF 6.3V 470Ω GND1 OUT2 IN2 GND2 VCC2 LTC1693-1 VCC1 CNY17-3 4 1 3 8 SUD30N04-10 W1 470Ω BAT54 1nF C3 330µF 6.3V 4.8µH PANASONIC ETQP AF4R8H 10Ω 470Ω 16 3.3Ω T1 PHILIPS EFD20-3F3 CORE LP = 720µH (AI = 1800) T2 ER11/5 CORE AI = 960µH 6 10Ω SEC HV SUD30N04-10 1nF 4.7nF 4.7nF W3 LT1339 W5 W1 0.1µF W3, 10T 32AWG, W4, 10T 32AWG 2.2nF 2.2nF 4 12 0.025Ω 1/2W W1, 18T BIFILAR 31AWG W3, 6T BIFILAR 31AWG 1µF 4.53k 3 11 10Ω P IRF1310NS MURS120 FMMT718 FMMT718 TS 470Ω SENSE + CT W2 SL/ADJ T2 SGND 47Ω PGND MMBD914LT1 TG SYNC SENSE – IAVG VBOOST 5VREF MURS120 VREF IRF1310NS SS 10Ω VC 0.1µF V+ GND-F +VIN EFFICIENCY RTOP COMP GND-S 18 RMID 48V to 5V Isolated Synchronous Forward DC/DC Converter LT1339 TYPICAL APPLICATIONS U LT1339 U TYPICAL APPLICATIONS 5V to 28V DC/DC Synchronous Boost Converter Limits Input Current at 60A (DC) 12V + DBST MBR0530 VBOOST SYNC + C5VREF Q2 FMMT720 TG CT TS 12VIN SL/ADJ CCT CAVG 2200pF 2200pF 12L + CVC, 1500pF VFB CREF, 0.1µF RR1 100k PHASE RUN/SHDN SENSE – VREF RFB2, 1.2k D2 MBR0520 L1 40µH PGND SGND RFB1, 27k Q4 FMMT720 BG VC RVC, 7.5k IRF3205 ×4 1µF SS D1 IR30BQ060 ×8 Q3 FMMT619 +C IAVG LT1339 CSS, 10µF IRF3205 ×2 1µF RCT 10k 1µF + C12VIN 47µF Q1 FMMT619 + CBST 5VREF VOUT 28V COUT 2200µF 35V ×6 RSS1 100Ω RS 0.002Ω RSS2, 100Ω SENSE + CIN 2200µF 6.3V ×4 L1 = 12T 4X12 ON 77439-A7 VIN 5V AT 60A + 1339 TA04 U PACKAGE DESCRIPTION Dimensions in inches (millimeters) unless otherwise noted. N Package 20-Lead PDIP (Narrow 0.300) (LTC DWG # 05-08-1510) 0.130 ± 0.005 (3.302 ± 0.127) 0.300 – 0.325 (7.620 – 8.255) 0.009 – 0.015 (0.229 – 0.381) ( 0.020 (0.508) MIN +0.035 0.325 –0.015 +0.889 8.255 –0.381 1.040* (26.416) MAX 0.045 – 0.065 (1.143 – 1.651) ) 0.065 (1.651) TYP 0.125 (3.175) MIN 0.005 (0.127) MIN 0.100 ± 0.010 (2.540 ± 0.254) 20 19 18 17 16 15 14 13 12 11 1 2 3 4 5 6 7 8 9 10 0.255 ± 0.015* (6.477 ± 0.381) 0.018 ± 0.003 (0.457 ± 0.076) N20 1197 *THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS. MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm) SW Package 20-Lead Plastic Small Outline (Wide 0.300) (LTC DWG # 05-08-1620) 0.291 – 0.299** (7.391 – 7.595) 0.010 – 0.029 × 45° (0.254 – 0.737) 0.093 – 0.104 (2.362 – 2.642) 0.496 – 0.512* (12.598 – 13.005) 0.037 – 0.045 (0.940 – 1.143) 20 19 18 17 16 15 14 13 12 11 0° – 8° TYP 0.009 – 0.013 (0.229 – 0.330) NOTE 1 0.016 – 0.050 (0.406 – 1.270) 0.050 (1.270) TYP 0.014 – 0.019 (0.356 – 0.482) TYP NOTE: 1. PIN 1 IDENT, NOTCH ON TOP AND CAVITIES ON THE BOTTOM OF PACKAGES ARE THE MANUFACTURING OPTIONS. THE PART MAY BE SUPPLIED WITH OR WITHOUT ANY OF THE OPTIONS *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE 0.394 – 0.419 (10.007 – 10.643) NOTE 1 0.004 – 0.012 (0.102 – 0.305) 1 2 3 4 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. 5 6 7 8 9 10 S20 (WIDE) 0396 19 LT1339 U TYPICAL APPLICATION 48V to 5V 50A DC/DC Converter with Input Supply Start-Up Protection 12V RCT 10k 5VREF VBOOST VIN 48V + DBST IN5819 LT1339 SYNC 50mA C12VIN 47µF Q1 + CBST CT + CCT TG CAVG, 2200pF CSS, 10µF CVC, 2200pF D3 MMSZ4684 12VIN CBG, 1µF IAVG SS PGND RFB2 1k RFB1 3k RR1 22k RR3 51k PHASE SGND RUN/SHDN VFB VREF D2 MBR0520 Q4 RVC, 4.7k CREF 0.1µF D1 Q3 BG VC IRFZ44 ×2 Q2 SL/ADJ 2200pF + 1µF TS C5VREF 1µF CIN 1500µF 63V, × 6 RBG 10k D4 IN914 IRFZ44 ×4 L1 40µH RR2 1.2k RS 0.002Ω SENSE – SENSE + D1 = IR30BQ060 × 8 Q1, Q3 = FMMT619; Q2, Q4 = FMMT720 L1 = Kool Mµ®, 12T 4X12 ON 77439-A7 Kool Mµ IS A REGISTERED TRADEMARK OF MAGNETICS, INC. COUT 2200µF 6.3V, × 4 + VOUT 5V AT 50A 1339 TA01 48V to 5V Efficiency 100 95 EFFICIENCY (%) 90 85 80 75 70 65 60 55 50 0 10 30 40 20 OUTPUT CURRENT (AMPS) 50 LT1339 • TA02 RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LT1158 Half-Bridge N-Channel MOSFET Driver Current Limit Protection, 100% of Duty Cycle LT1160 Half-Bridge N-Channel MOSFET Driver Up to 60V Input Supply, No Shoot-Through LT1162 Dual Half-Bridge N-Channel MOSFET Driver VIN to 60V, Good for Full-Bridge Applications LT1336 Half-Bridge N-Channel MOSFET Driver Smooth Operation at High Duty Cycle (95% to 100%) LTC ® 1530 High Power Step-Down Switching Regulator Controller Excellent for 5V to 3.xV Up to 50A LTC1435A High Efficiency, Low Noise Current Mode Step-Down DC/DC Converter Drives Synchronous N-Channel MOSFETs LTC1438 Dual High Efficiency, Low Noise Synchronous Step-Down Controller Tight 1% Reference LT1680 High Power DC/DC Current Mode Step-Up Controller High Side Current Sense, Up to 60V Input 20 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 ● FAX: (408) 434-0507 ● www.linear-tech.com 1339fa LT/TP 0299 2K REV A • PRINTED IN THE USA LINEAR TECHNOLOGY CORPORATION 1997