Synchronizable, High-Frequency Current- and Voltage-Mode PWM Controllers for Isolated Supplies

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1 ; Rev 0; 4/03 Synchronizable, High-Frequency Current- and General Description The pulse-width-modulated (PWM) controllers for forward/flyback isolated DC-to-DC converters provide maximum flexibility to power-supply designers and reduce external component count. These controllers allow common PC board layout for currentmode (MAX8540) and voltage-mode (MAX8541) designs. Both controllers feature adjustable switching frequency and external synchronization from 200kHz to 1MHz. Active-high and active-low enable, undervoltage protection (UP), and overvoltage protection (OP) reduce external component count. Maximum duty cycle is adjustable, and the feed-forward function scales the maximum duty cycle with input voltage to limit the maximum volt-seconds applied to the transformer primary. The MAX8540 allows the user to select the value of slope compensation to further optimize magnetics design. The MAX8541 features useradjustable ramp magnitude for the PWM comparator. A cycle-by-cycle current-limit function controls the peak primary current during overload and short circuit. Both controllers can be set to latch off or to hiccup when a short circuit is detected. The number of current-limited cycles to initiate the hiccup mode and number of cycles skipped are user selectable to allow startup with high-capacitance loads and protect the converter against sustained short circuits. The feature 9Ω internal gate drivers for low-power applications and are compatible with external gate drivers for high-power applications. Both devices are available in the space-saving 16-pin QSOP package. The MAX8541 E kit evaluates the MAX8540 and the MAX8541 to speed designs. Design examples are also available in application notes: 50W oltage-mode Forward Converter Design with the MAX8541 and 50W Current-Mode Forward Converter Design with the MAX8540. Applications Isolated DC-to-DC Modules (Bricks) Cellular Base Stations Telecom and Network Systems High-Performance Off-Line AC/DC Converters Features 200kHz to 1MHz Adjustable Switching Frequency Synchronization to External Clock Programmable, Constant Maximum olt-second Simplifies Transformer Design Programmable Hiccup/Skip Cycles or Latch-Mode Protection Clean Startups with High-Capacitance Loads Programmable Under/Overvoltage Protection Current-Mode, Adjustable Slope Compensation (MAX8540) oltage-mode, Adjustable Ramp Magnitude (MAX8541) 10mA, 5 Regulator 75m to 1.25m Adjustable Current Limit Reduces External Components Internal Gate Driver for Low-Power Applications External Gate Driver for High-Power Applications Ordering Information PART TEMP RANGE PIN-PACKAGE MAX8540EEE -40 C to +85 C 16 QSOP MAX8541EEE -40 C to +85 C 16 QSOP TOP IEW O U FREQ/SYNC SS MAXDTY Pin Configurations MAX8540EEE CC 15 DR 14 GND 13 SKTON 12 CS SKTOFF EN 7 10 ILIM SCOMP 8 9 OPTO Functional Diagrams and Typical Operating Circuit appear at end of data sheet. QSOP Pin Configurations continued at end of data sheet. Maxim Integrated Products 1 For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at , or visit Maxim s website at

2 ABSOLUTE MAXIMUM RATINGS CC to GND to +20 OPTO, U, O, EN, PRAMP, ILIM, to GND to +6 SCOMP, FREQ, CS, SKTON, SKTOFF, SS, MAXDTY to GND to DR to GND to CC Continuous Power Dissipation (T A = +70 C) 16-Pin QSOP (derate 8.3mW/ C above +70 C)...667mW Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS Operating Temperature Range C to +85 C Junction Temperature C Storage Temperature Range C to +150 C Lead Temperature (soldering, 10s) C ( CC = 12, C = 1µF, U = O = OPTO, ILIM = 2, R FREQ/SYNC = 32.4kΩ, C SS = 0.1µF, R MAXDTY = 97.6kΩ, EN = 0, R SCOMP = 68kΩ, R PRAMP = 25kΩ, C SKTON = 0.01µF, C SKTOFF = 0.1µF, CS = 0.6, C DR = 10pF, T A = 0 C to +85 C, unless otherwise noted. Typical values are at T A = +25 C.) CC PARAMETER CONDITIONS MIN TYP MAX UNITS Operating oltage Range (Note 1) Undervoltage Lockout CC rising CC falling Undervoltage Lockout Hysteresis Supply Current is active, No switching I = 0 Switching with no load Shutdown Current EN = ma Output oltage I = Load Regulation I = 0 to 10 ma m Line Regulation CC = 8.4 to m Pulldown Resistor in Shutdown EN = Ω UNDEROLTAGE/OEROLTAGE (U/O) ULO Threshold U rising, 120m typical hysteresis U falling Input Bias Current µa OLO Threshold EN O rising, 130m typical hysteresis O falling Input Low Threshold IL 1.2 Input High Threshold IH 2.6 Pullup Current EN = µa CURRENT LIMIT ILIM Range CS Current-Limit to DR Turn-Off Delay Includes leading-edge blanking time ns CS Cycle-by-Cycle Threshold Accuracy when ILIM = ±10 % oltage ILIM = ma 2

3 ELECTRICAL CHARACTERISTICS (continued) ( CC = 12, C = 1µF, U = O = OPTO, ILIM = 2, R FREQ/SYNC = 32.4kΩ, C SS = 0.1µF, R MAXDTY = 97.6kΩ, EN = 0, R SCOMP = 68kΩ, R PRAMP = 25kΩ, C SKTON = 0.01µF, C SKTOFF = 0.1µF, CS = 0.6, C DR = 10pF, T A = 0 C to +85 C, unless otherwise noted. Typical values are at T A = +25 C.) PARAMETER CONDITIONS MIN TYP MAX UNITS ILIM Leakage Current µa Hiccup Skip Off-Time C SKTOFF = 0.1µF (Note 3) 90 ms Hiccup Skip Off-Charging µa Hiccup Skip On-Time C SKTON = 0.01µF (Note 3) 9 ms Hiccup Skip On-Charging Current Hiccup SKTOFF oltage Threshold OPTO µa Input Bias Current OPTO = µa Minimum Input oltage Minimum voltage for duty-cycle control 0.6 Maximum Input oltage Maximum voltage for duty-cycle control 2.6 DUTY CYCLE Maximum Duty Cycle SOFT-START R MAXDTY = 24.3kΩ, U = R MAXDTY = 130kΩ, U = U = 1.3, R MAXDTY = 97.6kΩ 60 Internally programmed limit for maximum duty cycle at all frequencies Source Current SS = µa Pulldown Resistance in Shutdown I SS = 10mA, E N = Ω Time 440 ms/µf FREQUENCY Initial Accuracy R FREQ = 32.4kΩ khz Switching Frequency Range SCOMP (MAX8540) Slope Compensation PRAMP (MAX8541) Ramp oltage Amplitude DR (MOSFET DRIER) Rise Time R FRE Q = 48.7kΩ 200 R FRE Q = 8.87kΩ 1000 R SCOMP = 14kΩ 1.5 R SCOMP = 204kΩ 0.1 R PRAMP = 12.4kΩ 2.5 R PRAMP = 21kΩ 1 R PRAMP = 42kΩ 0.5 C DR = 500pF, 10% to 90% of CC 30 C DR = 2000pF, 10% to 90% of CC 57 % khz ns 3

4 ELECTRICAL CHARACTERISTICS (continued) ( CC = 12, C = 1µF, U = O = OPTO, ILIM = 2, R FREQ/SYNC = 32.4kΩ, C SS = 0.1µF, R MAXDTY = 97.6kΩ, EN = 0, R SCOMP = 68kΩ, R PRAMP = 25kΩ, C SKTON = 0.01µF, C SKTOFF = 0.1µF, CS = 0.6, C DR = 10pF, T A = 0 C to +85 C, unless otherwise noted. Typical values are at T A = +25 C.) Fall Time PARAMETER CONDITIONS MIN TYP MAX UNITS C DR = 500pF, 90% to 10% of CC 27 C DR = 2000pF, 90% to 10% of CC 53 On-Resistance Pullup 9 Ω On-Resistance Pulldown 7 Ω SYNC (EXTERNAL FREQUENCY SYNCHRONIZATION) Frequency Range Frequency syncs ±30% of frequency set by external R on FREQ pin ns MHz FREQ Input Threshold (Note 4) 2 3 THERMAL SHUTDOWN Thermal Shutdown T A rising, 20 C hysteresis 170 C ELECTRICAL CHARACTERISTICS ( CC = 12, C = 1µF, U = O = 2, R FREQ/SYNC = 32.4kΩ, C SS = 0.1µF, R MAXDTY = 97.6kΩ, EN = 0, R SCOMP = 68kΩ, R PRAMP = 25kΩ, C SKTON = 0.01µF, C SKTOFF = 0.1µF, OPTO = 2, ILIM = 4, CS = 0.6, C DR = 10pF, T A = -40 C to +85 C, unless otherwise noted.) (Note 5) CC PARAMETER CONDITIONS MIN TYP MAX UNITS Operating oltage Range (Note 1) Undervoltage Lockout CC rising CC falling Undervoltage Lockout Hysteresis 0.9 Supply Current = is active, No switching 4.2 I = 0 Switching with no load 6.3 Shutdown Current EN = ma Output oltage I = Load Regulation I = 0 to 10mA 50 m Line Regulation CC = 8.4 to m Shutdown Resistor EN = 3 30 Ω UNDEROLTAGE/OEROLTAGE (U/O) ULO Threshold U falling, 120m typical hysteresis U rising Input Bias Current µa OLO Threshold O falling, 130 m typical hysteresis O rising ma 4

5 ELECTRICAL CHARACTERISTICS (continued) ( CC = 12, C = 1µF, U = O = 2, R FREQ/SYNC = 32.4kΩ, C SS = 0.1µF, R MAXDTY = 97.6kΩ, EN = 0, R SCOMP = 68kΩ, R PRAMP = 25kΩ, C SKTON = 0.01µF, C SKTOFF = 0.1µF, OPTO = 2, ILIM = 4, CS = 0.6, C DR = 10pF, T A = -40 C to +85 C, unless otherwise noted.) (Note 5) EN Input Threshold PARAMETER CONDITIONS MIN TYP MAX UNITS IL 1.2 IH 2.6 Pullup Current EN = µa CURRENT LIMIT ILIM Range CS Current Limit to DR Delay Includes leading-edge blanking time 150 ns CS C ycl e- b y- C ycl e Thr eshol d ol tag e Accuracy when ILIM = ±10 % ILIM = ILIM Leakage Current µa Hiccup Skip Off-Charging Current µa Hiccup Skip On-Charging Current µa Hiccup SKTOFF oltage Threshold DUTY CYCLE Duty-Cycle Range U = % Maximum Duty Cycle Internal programmed max duty at all frequencies % SOFT-START Source Current SS = µa Pulldown Resistance in Shutdown I SS = 10mA, EN = 3 30 Ω FREQUENCY Initial Accuracy R FREQ = 32.4kΩ khz SYNC (EXTERNAL FREQUENCY SYNCHRONIZATION) Frequency Range Frequency syncs ±30% of frequency set by external R on FREQ pin M H z FREQ Input Threshold (Note 4) 2 3 Note 1: This is the CC operating range after clearing the rising ULO. Note 2: Guaranteed by design. Note 3: See the SKTON and SKTOFF section. Note 4: The minimum FREQ pulse must be 200ns in duration with a minimum magnitude of 3 plus F of the external diode and have a maximum duty cycle of 55%. Note 5: Specifications to -40 C are guaranteed by design and not production tested. 5

6 ( CC = 12, T A = +25 C, unless otherwise specified.) ICC (ma) CC NO-LOAD SWITCHING CURRENT vs. TEMPERATURE EN = T A ( C) MAX8540 toc01 ICC (µa) SHUTDOWN CC CURRENT vs. TEMPERATURE EN = T A ( C) Typical Operating Characteristics MAX8540 toc02 () ERENCE OLTAGE vs. TEMPERATURE T A ( C) MAX8540 toc MAXIMUM DUTY CYCLE vs. TEMPERATURE MAX8540 toc FREQUENCY vs. TEMPERATURE MAX8540 toc CURRENT-SENSE THRESHOLD vs. TEMPERATURE MAX8540 toc06 DMAX (%) R FREQ = NONE R FREQ = 36.5kΩ T A ( C) FREQUENCY (khz) R FREQ = 10kΩ R FREQ = 20kΩ R FREQ = 50kΩ T A ( C) CS (m) T A ( C) DELAY TIME (ns) CURRENT-LIMIT DELAY TIME vs. TEMPERATURE T A ( C) MAX8540 toc07 O/U OLTAGE () O/U THRESHOLD OLTAGE vs. TEMPERATURE U O T A ( C) MAX8540 toc08 6

7 Typical Operating Characteristics (continued) ( CC = 12, T A = +25 C, unless otherwise specified.) FREQUENCY (khz) FREQUENCY vs. INPUT OLTAGE R FREQ = 10kΩ R FREQ = 20kΩ 200 R FREQ = 50kΩ INPUT OLTAGE () MAX8540 toc10 TIME (ms) SKTON/SKTOFF TIME vs. CAPACITANCE CAPACITANCE (µf) MAX8540 toc11 DR CS PROGRAMABLE LATCH-OFF DELAY 4ms/div MAX8540 toc12 C SKTON = 0.01µF 2/div () ERENCE OLTAGE vs. LOAD CURRENT LOAD CURRENT (ma) MAX8540 toc13 () ERENCE OLTAGE vs. CC CC () MAX8540 toc14 LATCH-OFF OERCURRENT WAEFORMS MAX8540 toc15 HICCUP-MODE OERCURRENT WAEFORMS MAX8540 toc16 DR DR SKTON 1/div SKTON 1/div SKTOFF 5 SKTOFF 1/div C SKTON = 0.01µF C SKTON, C SKTFOF = 0.01µF 10ms/div 4ms/div 7

8 MAX8540 PIN MAX8541 NAME O 3 3 U 4 4 FREQ/ SYNC FUNCTION Pin Description 5 Reference oltage Output. Bypass to ground with a 1µF capacitor. is pulled to GND during shutdown. System Input Overvoltage Monitoring. The O threshold is with 130m hysteresis. Connect to the center of a resistor-divider from the system input to GND to set the overvoltage trip point (see the Overvoltage Threshold section). System Input Undervoltage Monitoring and Feed-Forward Input. The U threshold is 1.25 with 120m hysteresis. Connect to the center of a resistor-divider from the system input to GND to set the undervoltage trip point (see the Undervoltage Threshold section). This input can be used as a disable input by pulling it below 1.2. U remains active during shutdown. P r og r am m ab l e Fr eq uency and S ync Inp ut. C onnect a r esi stor i n p ar al l el w i th RC ( 10kΩ, 0.01µF) fr om FRE Q/S Y N C to GN D to set the sw i tchi ng fr eq uency or ap p l y an exter nal cl ock si g nal thr oug h a d i od e to synchr oni ze to an exter nal fr eq uency. 5 5 SS S oft- S tar t C ap aci tor C onnecti on. C onnect a cap aci tor fr om S S to GN D to set the soft- star t ti m e p er i od. 6 6 MAXDTY 7 7 EN 8 SCOMP 8 PRAMP 9 9 OPTO ILIM SKTOFF Programmable Maximum Duty-Cycle Input. Connect a resistor from MAXDTY to GND to set the maximum duty cycle for minimum system input voltages. The maximum duty cycle is inversely proportional to the system input voltage. The higher the input voltage, the less the maximum duty cycle. The maximum duty cycle is internally limited to 80% at any switching frequency. MAXDTY is high impedance during shutdown. Bypass MAXDTY with a 2200pF capacitor. Active-Low Enable Input. Drive EN to GND to enable the IC. Drive high to place the IC in shutdown mode. Programmable Slope Compensation Input. Connect a resistor from SCOMP to GND to set the slope compensation. Programmable oltage-mode Control-Ramp Input. Connect a resistor from PRAMP to GND to set the magnitude of the voltage ramp. Isol ated Feed b ack Inp ut. C onnect to an op tocoup l er for an i sol ated p ow er conver ter or connect to the outp ut of a vol tag e- er r or am p l i fi er for a noni sol ated p ow er conver ter for a feed b ack- er r or si g nal. Current-Limit Threshold Input. Connect to the center of a resistor-divider from to GND to set the current-limit threshold voltage. C ur r ent- Li m i t O ff- Ti m e Inp ut. C onnect a cap aci tor fr om S KTOFF to GN D to set the cur r ent- l i m i t off- ti m e. P ul l S KTO FF to RE F thr oug h a 10kΩ r esi stor to l atch off the IC after an over cur r ent event CS Current-Sense Input. Provides current-sense feedback for cycle-by-cycle current limit and is also the current-mode input for the MAX8540. Connect a current-sense resistor from CS to GND SKTON Current-Limit On-Time Input. Connect a capacitor to ground to set the current-limit on-time GND Ground DR Gate Drive for External N-Channel Power MOSFET. Connect to the gate of an external MOSFET for low-power applications. Connect to the input of an external gate driver for high-power applications CC oltage Supply for the IC. Operating input voltage range is 7.6 to 18. Bypass CC with a ceramic capacitor to GND. 8

9 Detailed Description Overvoltage Threshold The include an overvoltage protection (OP) feature that turns off the external MOSFET when the input voltage exceeds the user-set threshold. Connect a resistor-divider from the system input to GND with O connected to the center to set the OP trip point. The threshold voltage for O is (typ): IN( MAX) = R1 + R2 R2 where O is the O threshold, IN(MAX) is the overvoltage trip point, R1 is the resistor from the system input to O, and R2 is the resistor from O to GND. Undervoltage Threshold The also include an undervoltage (U) sensing input. The IC holds the external MOSFET low until U reaches its threshold (1.25 typ). Once the threshold has been reached, the circuit enters soft-start and brings the output into regulation. Connect a resistordivider from the system input to GND with U at the center to set the undervoltage protection (UP) trip point. R3 + R4 IN( MIN) = U R4 where U is the U threshold, IN(MIN) is the U trip point, R3 is the resistor from the system input to U, and R4 is the resistor from U to GND. An alternate method used in the application circuits for setting the O and U trip points is demonstrated in Figure 1. Use 36.5kΩ for the bottom resistor (RC). RA and RB are calculated as follows: O IN( MIN) RB = RC U IN( MAX) RC IN( MIN) RA = U RB RC where IN(MIN) is the U trip point, IN(MAX) is the O trip point, U is the U threshold (1.25 typ), and O is the O threshold (3.021 typ). RA should consist of two equal-value resistors in series to protect against single-point failure. O 1 Table 1. Typical Specifications of U/O and the Actual On/Off Hysteresis of Input oltage U OLTAGE SPECIFICATIONS () IN OFF WINDOW (LTP) () MIN TYP MAX IN ON WINDOW (UTP) () MIN TYP MAX O OLTAGE SPECIFICATIONS () IN OFF WINDOW (UTP) () MIN TYP MAX Switching Frequency and Synchronization The oscillator operates in two modes: stand-alone or synchronized (sync). A single input, FREQ/SYNC, doubles as the attachment point for the frequency-programming resistor and as the synchronization input. The mode recognition is automatic, based on the signal applied to FREQ/SYNC. In stand-alone mode, an external resistor connected from FREQ/SYNC to GND sets the operating frequency. A 1.25 source is internally applied to FREQ/SYNC and the oscillator frequency is proportional to the current out of FREQ/SYNC through the programming resistor. IN ON WINDOW (LTP) () MIN TYP MAX Assume that at U/O is scaled to for a 48 bus. Table 2. Switching Frequency Selection R FREQ/SYNC (kω) SWITCHING FREQUENCY (khz)

10 The also synchronize with an external oscillator. Drive FREQ/SYNC with a square wave through a series diode with a positive pulse width of at least 200ns and a minimum pulse amplitude of 3, plus the F of the external diode. Alternatively, a 1.5 level-shifted external clock can be applied without the series diode. The maximum duty cycle of the external signal allowed is 55%. The synchronize to frequencies between 200kHz and 1MHz; however, the signal must be within ±30% of the frequency set by the external resistor at FREQ/SYNC. Maximum Duty Cycle Set the maximum duty cycle at the minimum system input voltage ( IN(MIN) ) connecting a resistor from MAXDTY to GND. The maximum duty cycle is inversely proportional to the voltage at U. As the voltage on U increases, the duty cycle decreases. The maximum duty cycle is internally limited to 80% at all switching frequencies. The MAXDTY resistor is determined as: IN 36 TO 76 C1 C2 C3 RA RB RC O U MAX8541 D R MAX ( ) MAXDTY = 60 where D MAX is the desired maximum duty cycle. The range of valid resistor values for R MAXDTY is from 24.3kΩ to 130kΩ. N-Channel MOSFET Driver The DR output drives an N-channel MOSFET in lowpower applications. In high-power applications, the gate driver internal to the may not be capable of driving the external MOSFET efficiently and an external gate driver may be required. In this situation, connect DR to the input of the external gate driver. Slope Compensation (MAX8540) The MAX8540 is a current-mode device and requires slope compensation for proper operation. To provide slope compensation, connect a resistor from SCOMP to GND (R SCOMP ). The value of R SCOMP is determined as follows. For applications using a synchronous rectifier in the output, set the slope compensation equal to the negative slope of the output inductor. R SCOMP is equal to: R SCF = N L1 SCOMP OUT R CS dramp RSUM = dt 2 SCF 3 Figure 1. A Method to Set U and O Thresholds where d RAMP /dt = 2.5(f S ), R SUM = 25kΩ, N is the turns ratio of the primary to secondary, L1 is the output inductance, OUT is the output voltage, f S is the switching frequency, and R CS is the current-sense resistance. For applications where a diode is used in the output instead of the synchronous rectifier, the slope compensation resistor is then equal to: R SCF N OUT + = L1 SCOMP where d RAMP /dt = 2.5(f S ),R SUM = 25kΩ, N is the turns ratio of the primary to secondary, L1 is the output inductance, OUT is the output voltage, F is the diode voltage, f S is the switching frequency, and R CS is the currentsense resistance. oltage-ramp Amplitude (MAX8541) The MAX8541 is a voltage-mode device and features adjustable voltage ramp. Connect a resistor from PRAMP to GND (R PRAMP ) to set the voltage-ramp magnitude, M. M dramp RSUM = dt 2 SCF = 125. F R CS 25kΩ RPRAMP 10

11 where R PRAMP is in kω. The ramp-voltage magnitude is independent of frequency. The range of values for R PRAMP is from 12.4kΩ to 42kΩ. Soft-Start The soft-start feature allows converters built using the to apply power to the load in a controllable soft ramp, thus reducing startup surges and stresses. It also determines power-up sequencing when several converters are used. Upon power turn-on, the soft-start pin acts as a current sink to discharge any capacitance connected to it. Once the voltage at CC has exceeded its lockout value, softstart then charges the external capacitor (C SS ), allowing the converter output voltage to ramp up. Full output voltage is reached in approximately 440ms/µF. Current Limit The utilize two current-limit schemes: cycle-by-cycle current limit and short-circuit current limit. Set the current-limit threshold using a resistor-divider from to GND with ILIM connected to the center. The current-limit threshold is determined as: ILIM = R5 R5 + R6 where R5 is the resistor from ILIM to GND and R6 is the resistor from to ILIM. Use 240kΩ for R16 and vary R23 to change the threshold. The CS signal provides feedback on the current ramp through the main external MOSFET. The voltage on CS is monitored by the IC. The cycle-by-cycle current limit abbreviates the on-time of the external MOSFET in the event that the voltage at CS is greater than the threshold voltage set by ILIM. The current-limit feature protects against a hard short or overcurrent fault at the output by one of two selected protection modes: by latching off the output, or pulsing the output to reduce the average output current (hiccup mode). To select latched mode, connect SKTOFF to. In this mode, if the hard short exists for the time period set by the capacitance at SKTON, the output is latched off. To unlatch the output, toggle EN or cycle the input power to CC. To select hiccup mode, connect capacitors to SKTON and SKTOFF to program the hiccup mode on- and offtimes. When a cycle-by-cycle event is detected, the IC charges the capacitor at SKTON. The capacitor continues to charge as long as the CS voltage is greater than the ILIM threshold voltage. Once the voltage on SKTON reaches its threshold voltage, the begin skipping switching cycles for a time determined by the capacitance connected to SKTOFF. Once this time period has elapsed, the IC begins to switch for the time period set by the capacitance connected to SKTON. This process continues until the output short is removed. See the SKTON and SKTOFF section for details on setting the hiccup-mode periods. Connect SKTOFF to and SKTON to GND to disable the latched-mode and hiccup-mode protection, and operate continuously in cycle-by-cycle current-limit. PMW Comparator The PWM comparator of the MAX8540 transforms the optocoupled error voltage ( OPTO ) into a duty cycle by comparing the opto feedback-error voltage with a summed voltage. The summed voltage is the sum of the programmable slope compensation and the current-sense voltages. When the summed voltage exceeds the opto feedback error voltage, the gatedrive logic turns off the external MOSFET. The PWM comparator in the MAX8541 compares OPTO with the programmable voltage ramp. When the voltage ramp exceeds OPTO, the gate-driver logic turns off the external MOSFET. SKTON and SKTOFF The capacitance, C SKTON, determines the time period allowed before the short-circuit current limit initiates. Once the CS voltage exceeds the ILIM threshold, the capacitor at SKTON begins to charge. The capacitor continues to charge until the SKTON threshold voltage is reached or the overcurrent event is removed. This feature allows for the higher currents required during startup with high-capacitance loads. Set C SKTON to allow sufficient time for startup. The required capacitance at SKTON is determined as: C SKTON = t ON / 10 3 where t ON is in ms and C SKTON is in µf. The allowable range for C SKTON is 100pF to 0.01µF. The capacitance at SKTOFF determines the time period that the external MOSFET is turned off during an overcurrent event. Once the SKTON time period is exceeded, the SKTOFF capacitor charges. Once SKTOFF reaches its threshold, the IC begins to switch again. C SKTOFF is determined as: C SKTOFF = t OFF / 10 3 where t OFF is in ms and C SKTOFF is in µf. The allowable range for C SKTOFF is 1000pF to 1µF. 11

12 Pull SKTOFF to through a 10kΩ pullup resistor to enable the latch-off feature. In this mode, once the SKTON time has elapsed, the IC is latched off. The circuit remains off until EN is toggled, or the input power is toggled. Soft-Start Capacitor Selection During startup, the capacitor at soft-start is charged using a 5µA current source. Once the voltage at softstart reaches the threshold voltage (2 typ), the IC switches normally. Use a low-esr ceramic capacitor placed as close as possible to the IC at soft-start. The value is determined as follows: C SS tss = 530 where t SS is the desired soft-start period in ms and C SS is in µf. Applications Information Refer to the following application notes for the application circuits and applications information: 50W Current-Mode Forward Converter Design with the MAX8540 and 50W oltage- Mode Forward Converter Design with the MAX8541. Pin Configurations (continued) TOP IEW O U FREQ/SYNC SS MAXDTY EN PRAMP MAX8541EEE QSOP 16 9 CC 15 DR 14 GND 13 SKTON 12 CS 11 SKTOFF 10 ILIM OPTO Chip Information TRANSISTOR COUNT: 2704 PROCESS: BiCMOS 12

13 O U CC CC ULO COMPARATOR OEROLTAGE COMPARATOR UNDEROLTAGE COMPARATOR TEMP OK ENABLE CLK MAX8540 SS_RESET Functional Diagrams 5 ERENCE ENABLE DRIE LOGIC CC DR 1.25 EN SKTOFF SKTON SHORT-CIRCUIT TIMER 1.2 CS SLOPE COMPENSATION SCOMP PWM COMPARATOR CS 80% MAX OPTO ILIM GND SS SS_RESET 5µA OSC DECODER RAMP CLK MAX TON MAXDTY FREQ/SYNC Figure 2. MAX8540 Functional Diagram 13

14 O U CC CC ULO COMPARATOR OEROLTAGE COMPARATOR UNDEROLTAGE COMPARATOR TEMP OK ENABLE CLK Functional Diagrams (continued) MAX8541 SS_RESET 5 ERENCE ENABLE DRIE LOGIC CC DR 1.25 EN SKTOFF SKTON SHORT-CIRCUIT TIMER 1.2 CLK OLTAGE RAMP PRAMP PWM COMPARATOR CS 80% MAX OPTO ILIM GND SS SS_RESET 5µA OSC DECODER RAMP CLK MAX TON MAXDTY FREQ/SYNC Figure 3. MAX8541 Functional Diagram 14

15 INPUT 36 TO 76 OPTIONAL SYNCHRONIZATION MAX8515 O U IN PGND OUT FB GND CC IN Typical Operating Circuit OUTPUT 2.5 AT 20A FREQ/SYNC SS U1 MAX8540 DR CS ILIM SCOMP MAXDTY SKTOFF SKTON OFF OPTO EN GND ON 15

16 Package Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to QSOP.EPS PACKAGE OUTLINE, QSOP.150",.025" LEAD PITCH F 1 1 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 16 Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.