LTC4236 Dual Ideal Diode-OR and Single Hot Swap Controller with Current Monitor Description Features Ideal Diode-OR and Inrush Current Control for Redundant Supplies nn Low Loss Replacement for Power Schottky Diodes nn Enables Safe Board Insertion into a Live Backplane nn 2.9V to 18V Operating Range nn Current Monitor Output nn Controls N-Channel MOSFETs nn Limits Peak Fault Current in ≤ 1µs nn Adjustable Current Limit with Foldback nn Adjustable Start-Up and Current Limit Fault Delay nn 0.5µs Ideal Diode Turn-On and Turn-Off Time nn Smooth Switchover without Oscillation nn Fault, Power Good and Diode Status Outputs nn LTC4236-1: Latch Off After Fault nn LTC4236-2: Automatic Retry After Fault nn 28-Pin 4mm x 5mm QFN Package The LTC®4236 offers ideal diode-OR and Hot Swap functions for two power rails by controlling external N-channel MOSFETs. MOSFETs acting as ideal diodes replace two high power Schottky diodes and the associated heat sinks, saving power and board area. A Hot Swap control MOSFET allows a board to be safely inserted and removed from a live backplane by limiting inrush current. The supply output is also protected against short-circuit faults with a fast acting foldback current limit and electronic circuit breaker. nn The LTC4236 regulates the forward voltage drop across the ideal diode MOSFETs to ensure smooth current transfer from one supply to the other without oscillation. The ideal diode MOSFETs turn on quickly to reduce the load voltage droop during supply switchover. If the input supply fails or is shorted, a fast turn-off minimizes reverse current transients. A current sense amplifier translates the voltage across the sense resistor to a ground referenced signal. The LTC4236 provides adjustable start-up delay, turn-on/-off control, and reports fault and power good status for the supply. Applications Redundant Power Supplies High Availability Systems and Servers nn Telecom and Network Infrastructure nn nn L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear Technology Corporation. All other trademarks are the property of their respective owners. Protected by U.S. Patents, including 7920013, 8022679. Typical Application Ideal Diode-OR with Hot Swap Application Smooth Supply Switchover SiR158DP 12V 0.1µF SiR158DP 12V 0.003Ω + 0.1µF 0.1µF 13.7k CPO1 IN1 DGATE1 CPO2 IN2 SiR158DP D2SRC IN2 DGATE2 REG SENSE+ CS+ SENSE– HGATE OUT ON 12V 7A CLOAD 15k FB 2k IN1 1V/DIV IN1 IN2 1V/DIV IIN1 2A/DIV 2k LTC4236 EN INTVCC 0.1µF GND D2OFF IIN2 2A/DIV FAULT PWRGD DSTAT1 DSTAT2 DTMR IMON FTMR 0.1µF 200ms/DIV 4236 TA01b ADC 0.1µF 4236 TA01a 4236f For more information www.linear.com/LTC4236 1 LTC4236 Pin Configuration SENSE– 1 SENSE+ 2 CS+ 3 PWRGD FB OUT HGATE CPO1 TOP VIEW DGATE1 28 27 26 25 24 23 22 FAULT 21 DSTAT1 20 DSTAT2 IN1 4 19 ON 29 INTVCC 5 18 D2OFF 17 NC GND 6 IN2 7 16 NC D2SRC 8 15 REG IMON EN FTMR 9 10 11 12 13 14 DTMR Supply Voltages IN1, IN2................................................... –0.3V to 24V INTVCC...................................................... –0.3V to 7V REG............................SENSE+ – 5V to SENSE+ + 0.3V Input Voltages ON, D2OFF, EN ....................................... –0.3V to 24V FTMR, DTMR..........................–0.3V to INTVCC + 0.3V FB............................................................. –0.3V to 7V SENSE+, SENSE–, CS+, D2SRC............... –0.3V to 24V Output Voltages IMON........................................................ –0.3V to 7V FAULT, PWRGD, DSTAT1, DSTAT2............ –0.3V to 24V CPO1, CPO2 (Notes 3, 4)........................ –0.3V to 35V DGATE1, DGATE2 (Notes 3, 4)................ –0.3V to 35V HGATE (Note 5)...................................... –0.3V to 35V OUT........................................................ –0.3V to 24V Average Currents FAULT, PWRGD, DSTAT1, DSTAT2..........................5mA INTVCC................................................................10mA Operating Ambient Temperature Range LTC4236C................................................. 0°C to 70°C LTC4236I..............................................–40°C to 85°C Storage Temperature Range................... –65°C to 150°C CPO2 (Notes 1, 2) DGATE2 Absolute Maximum Ratings UFD PACKAGE 28-LEAD (4mm × 5mm) PLASTIC QFN TJMAX = 125°C, θJA = 43°C/W (NOTE 6) EXPOSED PAD (PIN 29) PCB GND CONNECTION OPTIONAL Order Information LEAD FREE FINISH TAPE AND REEL PART MARKING PACKAGE DESCRIPTION TEMPERATURE RANGE LTC4236CUFD-1#PBF LTC4236CUFD-1#TRPBF 42361 28-Lead (4mm x 5mm) Plastic QFN 0°C to 70°C LTC4236CUFD-2#PBF LTC4236CUFD-2#TRPBF 42362 28-Lead (4mm x 5mm) Plastic QFN 0°C to 70°C LTC4236IUFD-1#PBF LTC4236IUFD-1#TRPBF 42361 28-Lead (4mm x 5mm) Plastic QFN –40°C to 85°C LTC4236IUFD-2#PBF LTC4236IUFD-2#TRPBF 42362 28-Lead (4mm x 5mm) Plastic QFN –40°C to 85°C Consult LTC Marketing for parts specified with wider operating temperature ranges. 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/. Some packages are available in 500 unit reels through designated sales channels with #TRMPBF suffix. 2 4236f For more information www.linear.com/LTC4236 LTC4236 Electrical Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS Supplies VIN Input Supply Range l IIN Input Supply Current l VINTVCC Internal Regulator Voltage VINTVCC(UVL) Internal VCC Undervoltage Lockout 2.9 18 V 2.7 4 mA I = 0, –500µA l 4.5 5 5.5 V INTVCC Rising l 2.1 2.2 2.3 V l 30 60 90 mV l 2 15 28 mV ∆VINTVCC(HYST) Internal VCC Undervoltage Lockout Hysteresis Ideal Diode Control ΔVFWD(REG) Forward Regulation Voltage (VINn – VSENSE+) ΔVDGATE External N-Channel Gate Drive (VDGATE1 – VIN1) and (VDGATE2 – VD2SRC) IN < 7V, ΔVFWD = 0.15V; I = 0, –1µA IN = 7V to 18V, ΔVFWD = 0.15V; I = 0, –1µA l l 5 10 7 12 14 14 V V ΔVDGATE(ST) Diode MOSFET On Detect Threshold (VDGATE1 – VIN1) and (VDGATE2 – VD2SRC) DSTAT Pulls Low, ΔVFWD = 50mV l 0.3 0.7 1.1 V ID2SRC D2SRC Pin Current D2SRC = 0V l –90 –130 µA ICPO(UP) CPOn Pull-Up Current CPO = IN = D2SRC = 2.9V CPO = IN = D2SRC = 18V l l –100 –90 –130 –120 µA µA IDGATE(FPU) DGATEn Fast Pull-Up Current ΔVFWD = 0.2V, ΔVDGATE = 0V, CPO = 17V IDGATE(FPD) DGATEn Fast Pull-Down Current ΔVFWD = –0.2V, ΔVDGATE = 5V IDGATE2(DN) DGATE2 Off Pull-Down Current D2OFF = 2V, ΔVDGATE2 = 2.5V l tON(DGATE) DGATEn Turn-On Delay ΔVFWD = 0.2V , CDGATE = 10nF tOFF(DGATE) DGATEn Turn-Off Delay ΔVFWD = –0.2V, CDGATE = 10nF tPLH(DGATE2) D2OFF Low to DGATE2 High –60 –50 –1.5 A 1.5 50 A 100 200 µA l 0.25 0.5 µs l 0.2 0.5 µs l 50 100 µs mV mV Hot Swap Control ΔVSENSE(TH) Current Limit Sense Voltage Threshold (VSENSE+ – VSENSE–) FB = 1.3V FB = 0V l l 22.5 5.8 25 8.3 27.5 10.8 VSENSE+(UVL) SENSE+ Undervoltage Lockout SENSE+ Rising l 1.8 1.9 2 V ∆VSENSE+(HYST) SENSE+ Undervoltage Lockout Hysteresis l 10 50 90 mV ISENSE+ SENSE+ Pin Current SENSE+ = 12V l 0.3 0.8 1.3 mA ISENSE– SENSE– Pin Current SENSE– = 12V l 10 40 100 µA ICS+ CS+ Pin Current CS+ = 12V, ∆VSENSE = 0V l ±1 µA ΔVHGATE External N-Channel Gate Drive (VHGATE – VOUT) IN < 7V, I = 0, –1µA IN = 7V to 18V, I = 0, –1µA l l 5 10 14 14 V V 7 12 ΔVHGATE(H) Gate High Threshold (VHGATE – VOUT) l 3.6 4.2 4.8 V IHGATE(UP) External N-Channel Gate Pull-Up Current Gate Drive On, HGATE = 0V l –7 –10 –13 µA IHGATE(DN) External N-Channel Gate Pull-Down Current Gate Drive Off, OUT = 12V, HGATE = OUT + 5V l 1 2 4 mA IHGATE(FPD) External N-Channel Gate Fast Pull-Down Current Fast Turn-Off, OUT = 12V, HGATE = OUT + 5V l 100 200 350 mA tPHL(SENSE) Sense Voltage (SENSE+ – SENSE–) High to HGATE Low ∆VSENSE = 200mV, CHGATE = 10nF l 0.5 1 µs tOFF(HGATE) ON Low to HGATE Low EN High to HGATE Low SENSE+ Low to HGATE Low SENSE+ UVLO l l l 10 20 10 20 40 20 µs µs µs 100 150 ms 10 20 µs tD(HGATE) ON High, EN Low to HGATE Turn-On Delay DTMR = INTVCC l tP(HGATE) ON to HGATE Propagation Delay ON = Step 0.8V to 2V l 50 4236f For more information www.linear.com/LTC4236 3 LTC4236 Electrical Characteristics The l denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. VIN = 12V, unless otherwise noted. SYMBOL PARAMETER CONDITIONS MIN TYP MAX UNITS VD2OFF(H,TH) D2OFF Pin High Threshold D2OFF Rising l 1.21 1.235 1.26 V VD2OFF(L,TH) D2OFF Pin Low Threshold D2OFF Falling ΔVD2OFF(HYST) D2OFF Pin Hysteresis l 1.19 1.215 1.24 l 10 20 30 VIN(TH) ON, FB Pin Threshold Voltage l 1.21 1.235 1.26 V ΔVON(HYST) ΔVFB(HYST) ON Pin Hysteresis l 40 80 120 mV FB Pin Hysteresis l 10 20 30 mV VON(RESET) ON Pin Fault Reset Threshold Voltage ON Falling l 0.57 0.6 0.63 V Input Leakage Current (ON, FB, D2OFF) V = 5V l IIN(LEAK) VEN(TH) 0 ±1 µA EN Pin Threshold Voltage EN Rising l 1.185 1.235 1.284 V l 60 110 200 mV l –7 –10 –13 µA l 1.198 1.235 1.272 V Inputs Voltage Rising V mV ΔVEN(HYST) EN Pin Hysteresis IEN(UP) EN Pull-Up Current VTMR(H) FTMR, DTMR Pin High Threshold VTMR(L) FTMR, DTMR Pin Low Threshold l 0.15 0.2 0.25 V IFTMR(UP) FTMR Pull-Up Current FTMR = 1V, In Fault Mode l –80 –100 –120 µA FTMR = 2V, No Faults l 1.3 2 2.7 µA l 0.07 0.15 0.23 % –8 –10 –12 µA EN = 1V IFTMR(DN) FTMR Pull-Down Current DRETRY Auto-Retry Duty Cycle IDTMR(UP) DTMR Pull-Up Current DTMR = 0.6V l IDTMR(DN) DTMR Pull-Down Current DTMR = 1.5V l 1 5 10 mA ∆VDTMR(TH) DTMR Pin Threshold Voltage (VDTMR – VINTVCC) tD(HGATE) Start-Up Delay l –0.1 –0.3 –0.5 V tRST(ON) ON Low to FAULT High l 20 40 µs tPG(FB) FB Low to PWRGD High l 20 40 µs Outputs IOUT OUT Pin Current OUT = 11V, IN = 12V, ON = 2V OUT = 13V, IN = 12V, ON = 2V l l 40 2.5 100 4 µA mA VOL Output Low Voltage (FAULT, PWRGD, DSTAT1, DSTAT2) I = 1mA I = 3mA l l 0.15 0.4 0.4 1.2 V V VOH Output High Voltage (FAULT, PWRGD) I = –1µA l IOH Input Leakage Current (FAULT, PWRGD, DSTAT1, DSTAT2) V = 18V l 0 ±1 µA IPU Output Pull-Up Current (FAULT, PWRGD) V = 1.5V l –7 –10 –13 µA ΔVREG Floating Regulator Voltage (VSENSE+ – VREG) IREG = ±1µA l 3.6 4.1 4.6 V ΔVSENSE(FS) Input Sense Voltage Full Scale (VSENSE+ – VSENSE–) SENSE+ = 12V l 25 INTVCC – 1 INTVCC – 0.5 V Current Monitor VIMON(OS) IMON Input Offset Voltage ∆VSENSE = 0V l GIMON IMON Voltage Gain ΔVSENSE = 20mV and 5mV l 99 VIMON(MAX) IMON Maximum Output Voltage ΔVSENSE = 70mV, 5V ≤ SENSE+ ≤ 18V ΔVSENSE = 35mV, SENSE+ = 2.9V l l 3.5 2.7 VIMON(MIN) IMON Minimum Output Voltage ΔVSENSE = 200µV l RIMON(OUT) IMON Output Resistance ΔVSENSE = 200µV l 4 15 mV 100 20 ±150 µV 101 V/V 5.5 2.9 V V 40 mV 27 kΩ 4236f For more information www.linear.com/LTC4236 LTC4236 Electrical Characteristics Note 1: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to any Absolute Maximum Rating condition for extended periods may affect device reliability and lifetime. Note 2: All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to GND unless otherwise specified. Note 3: An internal clamp limits the DGATE1 and CPO1 pins to a minimum of 10V above and a diode below IN1. Driving these pins to voltages beyond the clamp may damage the device. Note 4: An internal clamp limits the DGATE2 and CPO2 pins to a minimum of 10V above and a diode below D2SRC. Driving these pins to voltages beyond the clamp may damage the device. Note 5: An internal clamp limits the HGATE pin to a minimum of 10V above and a diode below OUT. Driving this pin to voltages beyond the clamp may damage the device. Note 6: Thermal resistance is specified when the exposed pad is soldered to a 3" x 5" , four layer, FR4 board. 4236f For more information www.linear.com/LTC4236 5 LTC4236 Typical Performance Characteristics SENSE+ Current vs Voltage IN Supply Current vs Voltage OUT Current vs Voltage 1.4 3.5 3 1.2 3 2.5 1 2 VOUT = 0V 1.5 VOUT = 3.3V 1 0 0.8 0.6 0.4 VOUT = 12V 0.5 3 9 VIN (V) 6 12 15 0 18 0 3 6 4236 G01 9 12 15 –0.5 18 VOUT = VIN VIN = 12V VOUT = VIN VCPO – VIN (V) ∆VHGATE (V) ∆VHGATE (V) VIN = 2.9V 10 8 6 0 –2 –4 –6 IHGATE (µA) –8 –10 4 –12 12 0 14 10 3 6 9 VIN (V) 12 15 VIN = 2.9V 4 VIN = 2.9V 2 0 –20 –40 –60 –80 –100 –120 –140 IDGATE (µA) 8 4236 G07 0 3 6 9 VIN (V) –60 –80 –100 –120 –140 ICPO (µA) FAULT, PWRGD, DSTAT1, DSTAT2 Output Low Voltage vs Current 1 10 4 –40 –20 4236 G06 VSENSE+ = VIN – 0.15V 6 0 0 4236 G05 OUTPUT LOW VOLTAGE (V) ∆VDGATE (V) VIN = 18V 6 –2 18 12 8 ∆VDGATE (V) VIN = 18V 4 Diode Gate Voltage vs IN Voltage VSENSE+ = VIN – 0.15V 4236 G03 0 4236 G04 Diode Gate Voltage vs Current 18 6 2 2 15 10 8 6 12 9 VOUT (V) CPO Voltage vs Current 4 6 6 3 12 12 8 –2 0 4236 G02 10 0 1 Hot Swap Gate Voltage vs IN Voltage 14 12 1.5 0 VSENSE+ (V) Hot Swap Gate Voltage vs Current 14 2 0.5 0.2 0 VIN = 12V, VSENSE+ = 11.5V 2.5 IOUT (mA) VSENSE+ = VIN – 0.5V ISENSE+ (mA) IIN (mA) 3.5 TA = 25°C, VIN = 12V, unless otherwise noted. 12 15 18 4236 G08 0.8 0.6 VIN = 2.9V 0.4 VIN = 12V 0.2 0 0 1 2 3 CURRENT (mA) 4 5 4236 G09 4236f For more information www.linear.com/LTC4236 LTC4236 Typical Performance Characteristics Current Limit Delay vs Sense Voltage Current Limit Threshold Foldback 100 15 10 5 10 1 VIN = 2.9V 20 10 VIN = 12V 0 –10 –20 –30 0 0.2 0.4 0.6 0.8 1.0 FB VOLTAGE (V) 1.2 0.1 1.4 4236 G10 0 –40 –50 80 120 40 160 200 SENSE VOLTAGE (VSENSE+ – VSENSE –) (mV) IMON PROPAGATION DELAY (µs) 1 0 IMON VOLTAGE GAIN (V/V) 2 20 10 30 40 50 SENSE VOLTAGE (VSENSE+ – VSENSE –) (mV) VIN = 2.9V 100 VIN = 12V 99.5 99 –50 –25 25 50 0 TEMPERATURE (°C) 4236 G13 75 100 100 80 60 40 20 0 4236 G14 Ideal Diode Start-Up Waveform on IN Power-Up 100ms HGATE Start-Up Delay with DTMR Pin Connected to INTVcc ON 5V/DIV SENSE+ 10V/DIV HGATE 10V/DIV OUT 10V/DIV HGATE 10V/DIV OUT 10V/DIV PWRGD 10V/DIV PWRGD 10V/DIV 10V/DIV 10ms/DIV 4236 G16 20ms/DIV 4236 G17 1 3 4 5 2 SENSE VOLTAGE (VSENSE+ – VSENSE –) (mV) Adjustable HGATE Start-Up Delay with 0.1µF Capacitor at DTMR pin ON 5V/DIV CPO 0 4236 G15 IN 10V/DIV DGATE 100 120 100.5 VIN = 2.9V 3 75 IMON Propagation Delay vs Sense Voltage 101 VIN = 12V 25 50 0 TEMPERATURE (°C) 4236 G12 IMON Voltage Gain vs Temperature 5 4 –25 4236 G11 IMON Voltage vs Sense Voltage IMON VOLTAGE (V) 40 CHGATE = 10nF INPUT OFFSET VOLTAGE (µV) 20 0 Current Sense Amplifier Input Offset Voltage vs Temperature 30 25 CURRENT LIMIT DELAY (µs) CURRENT LIMIT SENSE VOLTAGE VSENSE+ – VSENSE– (mV) 30 0 TA = 25°C, VIN = 12V, unless otherwise noted. 20ms/DIV 4236 G18 4236f For more information www.linear.com/LTC4236 7 LTC4236 Pin Functions CPO1, CPO2: Charge Pump Output. Connect a capacitor from CPO1 or CPO2 to the corresponding IN1 or D2SRC pin. The value of this capacitor is approximately 10× the gate capacitance (CISS) of the external MOSFET for ideal diode control. The charge stored on this capacitor is used to pull up the ideal diode MOSFET gate during a fast turn-on. Leave this pin open if fast ideal diode turnon is not needed. CS+: Positive Current Sense Input for Current Sense Amplifier. Connect this pin to the input of the current sense resistor. The voltage between CS+ and SENSE– is translated to a ground referenced signal at IMON pin. DGATE1, DGATE2: Ideal Diode MOSFET Gate Drive Output. Connect this pin to the gate of an external N-channel MOSFET for ideal diode control. An internal clamp limits the gate voltage to 12V above and a diode voltage below IN1 or D2SRC. During fast turn-on, a 1.5A pull-up charges DGATE from CPO. During fast turn-off, a 1.5A pull-down discharges DGATE1 to IN1 and DGATE2 to D2SRC. D2OFF: Control Input. A rising edge above 1.235V turns off the external ideal diode MOSFET in the IN2 supply path and a falling edge below 1.215V allows the MOSFET to be turned on. Connect this pin to an external resistive divider from IN1 to make IN1 the higher priority input supply when IN1 and IN2 are equal. D2SRC: Ideal Diode MOSFET Gate Drive Return. Connect this pin to the source of the external N-channel MOSFET switch in the IN2 power path. The gate fast pull-down current returns through this pin when DGATE2 is discharged. DSTAT1: Diode MOSFET Status Output. Open drain output that pulls low when the MOSFET gate drive voltage between DGATE1 and IN1 exceeds 0.7V indicating that the MOSFET diode path is on. Otherwise it goes high impedance. It requires an external pull-up resistor to a positive supply. Leave open if unused. 8 DSTAT2: Diode MOSFET Status Output. Open drain output that pulls low when the MOSFET gate drive voltage between DGATE2 and D2SRC exceeds 0.7V indicating that the MOSFET diode path is on. Otherwise it goes high impedance. It requires an external pull-up resistor to a positive supply. Leave open if unused. DTMR: Debounce Timer Capacitor Terminal. Connect this pin to either INTVCC for fixed 100ms delay or an external capacitor to ground for adjustable start-up delay (123ms/µF) when EN toggles low. EN: Enable Input. Ground this pin to enable Hot Swap control. If this pin is pulled high, the Hot Swap MOSFET is not allowed to turn on. A 10µA current source pulls this pin up to a diode below INTVCC. Upon EN going low when ON is high, there is a start-up delay for debounce as configured at the DTMR pin, after which the fault is cleared. FAULT: Overcurrent Fault Status Output. Output that pulls low when the fault timer expires during an overcurrent fault. Otherwise it is pulled high by a 10µA current source to a diode below INTVCC. It may be pulled above INTVCC using an external pull-up. Leave open if unused. FB: Foldback and Power Good Comparator Input. Connect this pin to an external resistive divider from OUT. If the voltage falls below 1.215V, the PWRGD pin pulls high to indicate the power is bad. If the voltage falls below 0.9V, the output power is considered bad and the current limit is reduced. Tie to INTVCC to disable foldback. FTMR: Fault Timer Capacitor Terminal. Connect a capacitor between this pin and ground to set a 12ms/µF duration for current limit before the external Hot Swap MOSFET is turned off. The duration of the off time is 8s/µF, resulting in a 0.15% duty cycle. GND: Device Ground. 4236f For more information www.linear.com/LTC4236 LTC4236 Pin Functions HGATE: Hot Swap MOSFET Gate Drive Output. Connect this pin to the gate of the external N-channel MOSFET for Hot Swap control. An internal 10µA current source charges the MOSFET gate. An internal clamp limits the gate voltage to 12V above and a diode voltage below OUT. During an undervoltage generated turn-off, a 2mA pull-down discharges HGATE to ground. During an output short or INTVCC undervoltage lockout, a fast 200mA pull-down discharges HGATE to OUT. IN1, IN2: Positive Supply Input and Ideal Diode MOSFET Gate Drive Return. Connect this pin to the power input side of the external ideal diode MOSFET. The 5V INTVCC supply is generated from IN1, IN2 and OUT via an internal diode-OR. The voltage sensed at this pin is used to control DGATE. The gate fast pull-down current returns through IN1 pin when DGATE1 is discharged. INTVCC: Internal 5V Supply Decoupling Output. This pin must have a 0.1µF or larger capacitor to GND. An external load of less than 500µA can be connected at this pin. An undervoltage lockout threshold of 2.2V will turn off both MOSFETs. IMON: Current Sense Monitoring Output. This pin voltage is proportional to the sense voltage across the current sense resistor with a voltage gain of 100. An internal 20k resistor is connected from this pin to ground. ON: ON Control Input. A rising edge above 1.235V turns on the external Hot Swap MOSFET and a falling edge below 1.155V turns it off. Connect this pin to an external resistive divider from SENSE+ to monitor the supply undervoltage condition. Pulling the ON pin below 0.6V resets the fault latch after an overcurrent fault. Tie to INTVCC if unused. OUT: Hot Swap MOSFET Gate Drive Return. Connect this pin to the output side of the external MOSFET. The gate fast pull-down current returns through this pin when HGATE is discharged. PWRGD: Power Status Output. Output that pulls low when the FB pin rises above 1.235V and the MOSFET gate drive between HGATE and OUT exceeds 4.2V. Otherwise it is pulled high by a 10µA current source to a diode below INTVCC. It may be pulled above INTVCC using an external pull-up. Leave open if unused. REG: Internal Regulated Supply for Current Sense Amplifier. A 0.1µF or larger capacitor should be tied from REG to SENSE+. This pin is not designed to drive external circuits. SENSE+: Positive Current Sense Input. Connect this pin to the diode-OR output of the external ideal diode MOSFETs and input of the current sense resistor. The voltage sensed at this pin is used for monitoring the current limit and also to control DGATE for forward voltage regulation and reverse turn-off. This pin has an undervoltage lockout threshold of 1.9V that will turn off the Hot Swap MOSFET. SENSE–: Negative Current Sense Input. Connect this pin to the output of the current sense resistor. The current limit circuit controls HGATE to limit the voltage between SENSE+ and SENSE– to 25mV or less depending on the voltage at the FB pin. 4236f For more information www.linear.com/LTC4236 9 LTC4236 Block Diagram IN1 SENSE+ SENSE – IN2 CS+ 0.9V 200Ω HGATE 12V REG 4.1V FOLDBACK FB – +CM + – CL GATE DRIVER IMON OUT 20k 10µA CHARGE PUMP 2 f = 2MHz CHARGE PUMP 1 f = 2MHz CPO1 100µA CPO2 100µA DGATE1 + – 12V + GD2 – + – GD1 15mV DGATE2 12V 15mV D2SRC INTVCC 5V LDO RST PG1 0.6V – + EN INTVCC 1.235V + – – + TM1 – + TM2 INTVCC 10µA EN 100µA 1.235V FTMR 0.2V FAULT RESET PG2 DSTAT1 LOGIC DSTAT2 FB 1.9V 1.235V 4.2V HGATE OUT 0.7V – + DGATE1 IN1 0.7V – + DGATE2 D2SRC INTVCC 10µA PWRGD 0.3V 1.235V DTMR GND – + 10µA INTVCC 10µA SENSE+ INTVCC 2µA 2.2V – + – + HGATE ON – + ON UVLO2 – + ON – + UVLO1 – + 1.235V DOFF DGATE2 OFF – + 1.235V + – – + D2OFF 0.2V – – + TM3 – + TM4 FAULT DSTAT1 DSTAT2 EXPOSED PAD 10 4236 BD For more information www.linear.com/LTC4236 4236f LTC4236 Operation The LTC4236 functions as an input supply diode-OR with inrush current limiting and overcurrent protection by controlling the external N-channel MOSFETs (MD1, MD2 and MH) on a supply path. This allows boards to be safely inserted and removed in systems with a backplane powered by redundant supplies. The LTC4236 has a single Hot Swap controller and two separate ideal diode controllers, each providing independent control for the two input supplies. When the LTC4236 is first powered up, the gates of the external MOSFETs are held low, keeping them off. As the DGATE2 pull-up can be disabled by the D2OFF pin, DGATE2 will pull high only when the D2OFF pin is pulled low. The gate drive amplifier (GD1, GD2) monitors the voltage between the IN and SENSE+ pins and drives the respective DGATE pin. The amplifier quickly pulls up the DGATE pin, turning on the MOSFET for ideal diode control, when it senses a large forward voltage drop. With the ideal diode MOSFETs acting as input supply diode-OR, the SENSE+ pin voltage rises to the highest of the supplies at the IN1 and IN2 pins. An external capacitor connected at the CPO pin provides the charge needed to quickly turn on the ideal diode MOSFET. An internal charge pump charges up this capacitor at device power-up. The DGATE pin sources current from the CPO pin and sinks current into the IN1, D2SRC and GND pins. When the DGATE1 to IN1 or DGATE2 to D2SRC voltage exceeds 0.7V, the respective DSTAT pin pulls low to indicate that the ideal diode MOSFET is turned on. Pulling the ON pin high and EN pin low initiates a debounce timing cycle that can be a fixed 100ms or adjustable delay as configured at the DTMR pin. After this timing cycle, a 10µA current source from the charge pump ramps up the HGATE pin. When the Hot Swap MOSFET turns on, the inrush current is limited at a level set by an external sense resistor (RS) connected between the SENSE+ and SENSE– pins. An active current limit amplifier (CL) servos the gate of the MOSFET to 25mV or less across the current sense resistor depending on the voltage at the FB pin. Inrush current can be further reduced, if desired, by adding a capacitor from HGATE to GND. When FB voltage rises above 1.235V and the MOSFET’s gate drive (HGATE to OUT voltage) exceeds 4.2V, the PWRGD pin pulls low. The high side current sense amplifier (CM) provides accurate monitoring of current through the current sense resistor. The sense voltage is amplified by 100 times and level shifted from the positive rail to a ground-referred output at the IMON pin. The output signal is analog and may be used as is or measured with an ADC. When the ideal diode MOSFET is turned on, the gate drive amplifier controls DGATE to servo the forward voltage drop (VIN – VSENSE+) across the MOSFET to 15mV. If the load current causes more than 15mV of voltage drop, the gate voltage rises to enhance the MOSFET. For large output currents, the MOSFET’s gate is driven fully on and the voltage drop is equal to ILOAD•RDS(ON) of the MOSFET. In the case of an input supply short-circuit when the MOSFETs are conducting, a large reverse current starts flowing from the load towards the input. The gate drive amplifier detects this failure condition and turns off the ideal diode MOSFET by pulling down the DGATE pin. In the case where an overcurrent fault occurs on the supply output, the current is limited with foldback. After a delay set by 100µA charging the FTMR pin capacitor, the fault timer expires and pulls the HGATE pin low, turning off the Hot Swap MOSFET. The FAULT pin is also latched low. At this point, the DGATE pin continues to pull high and keeps the ideal diode MOSFET on. Internal clamps limit both the DGATE1 and CPO1 to IN1, and DGATE2 and CPO2 to D2SRC voltages to 12V. The same clamps also limit the DGATE and CPO pins to a diode voltage below the IN1 or D2SRC pins. Another internal clamp limits the HGATE to OUT voltage to 12V and also clamps the HGATE pin to a diode voltage below the OUT pin. Power to the LTC4236 is supplied from either the IN or OUT pins, through an internal diode-OR circuit to a low dropout regulator (LDO). That LDO generates a 5V supply at the INTVCC pin and powers the LTC4236’s internal low voltage circuitry. 4236f For more information www.linear.com/LTC4236 11 LTC4236 Applications Information Internal VCC Supply High availability systems often employ parallel-connected power supplies or battery feeds to achieve redundancy and enhance system reliability. Power ORing diodes are commonly used to connect these supplies at the point of load at the expense of power loss due to significant diode forward voltage drop. The LTC4236 minimizes this power loss by using external N-channel MOSFETs as the pass elements, allowing for a low voltage drop from the supply to the load when the MOSFETs are turned on. When an input source voltage drops below the output common supply voltage, the appropriate MOSFET is turned off, thereby matching the function and performance of an ideal diode. By adding a current sense resistor and a Hot Swap MOSFET after the parallel-connected ideal diode MOSFETs, the LTC4236 enhances the ideal diode performance with inrush current limiting and overcurrent protection (see Figure 1). This allows the board to be safely inserted and removed from a live backplane without damaging the connector. The LTC4236 operates with an input supply from 2.9V to 18V. The power supply to the device is internally regulated at 5V by a low dropout regulator (LDO) with an output at the INTVCC pin. An internal diode-OR circuit selects the highest of the supplies at the IN and OUT pins to power the device through the LDO. The diode-OR scheme permits the device’s power to be kept alive by the OUT voltage when the IN supplies have collapsed or shut off. An undervoltage lockout circuit prevents all of the MOSFETs from turning on until the INTVCC voltage exceeds 2.2V. A 0.1µF capacitor is recommended between the INTVCC and GND pins, close to the device for bypassing. No external supply should be connected at the INTVCC pin so as not to affect the LDO’s operation. A small external load of less than 500µA can be connected at the INTVCC pin. MD1 SiR158DP VIN1 12V Z1 SMAJ15A VIN2 12V RS 0.003Ω MD2 SiR158DP MH SiR158DP Z2 SMAJ15A C3 0.1µF C2 0.1µF R2 13.7k R1 2k CPO1 IN1 DGATE1 CPO2 C5 0.1µF RHG 1k CHG 10nF C4 0.1µF D2SRC IN2 DGATE2 REG SENSE+ CS+ SENSE– ON GND INTVCC CARD CONNECTOR C1 0.1µF D2OFF VSENSE+ R5 100k HGATE OUT R3 2k FAULT PWRGD DSTAT1 DSTAT2 EN IMON FTMR DTMR CDT 0.1µF CFT 0.1µF CL 680µF R4 15k FB LTC4236 BACKPLANE CONNECTOR + RH 10Ω 12V 7A R6 100k R7 100k R8 100k ADC 4236 F01 Figure 1. Card Resident Diode-OR with Hot Swap Application 12 4236f For more information www.linear.com/LTC4236 LTC4236 Applications Information Turn-On Sequence The board power supply at the OUT pin is controlled with external N-channel MOSFETs (MD1, MD2 and MH) in Figure 1. The ideal diode MOSFETs connected in parallel on the supply side function as a diode-OR, while MH on the load side acts as a Hot Swap MOSFET controlling the power supplied to the output load. The sense resistor RS monitors the load current for overcurrent detection. The HGATE capacitor CHG controls the gate slew rate to limit the inrush current. Resistor RHG with CHG compensates the current control loop, while RH prevents high frequency oscillations in the Hot Swap MOSFET. During a normal power-up, the ideal diode MOSFETs turn on first. As soon as the internally generated supply, INTVCC, rises above its 2.2V undervoltage lockout threshold, the internal charge pump is allowed to charge up the CPO pins. Because the ideal diode MOSFETs are connected in parallel as a diode-OR, the SENSE+ pin voltage approaches the highest of the supplies at the IN1 and IN2 pins. The MOSFET associated with the lower input supply voltage will be turned off by the corresponding gate drive amplifier. Before the Hot Swap MOSFET can be turned on, EN must remain low and ON must remain high for a debounce cycle as configured at the DTMR pin, to ensure that any contact bounces during the insertion have ceased. At the end of the debounce cycle, the internal fault latch is cleared. The Hot Swap MOSFET is then allowed to turn on by charging up HGATE with a 10µA current source from the charge pump. The voltage at the HGATE pin rises with a slope equal to 10µA/CHG and the supply inrush current flowing into the load capacitor CL is limited to: I INRUSH = CL •10µA CHG The OUT voltage follows the HGATE voltage when the Hot Swap MOSFET turns on. If the voltage across the current sense resistor RS becomes too high based on the FB pin voltage, the inrush current will be limited by the internal current limiting circuitry. Once the MOSFET gate overdrive exceeds 4.2V and the FB pin voltage is above 1.235V, the PWRGD pin pulls low to indicate that the power is good. Once OUT reaches the input supply voltage, HGATE continues to ramp up. An internal 12V clamp limits the HGATE voltage above OUT. When the ideal diode MOSFET is turned on, the gate drive amplifier controls the gate of the MOSFET to servo the forward voltage drop across the MOSFET to 15mV. If the load current causes more than 15mV of drop, the MOSFET gate is driven fully on and the voltage drop is equal to ILOAD • RDS(ON). Turn-Off Sequence The external MOSFETs can be turned off by a variety of conditions. A normal turn-off for the Hot Swap MOSFET is initiated by pulling the ON pin below its 1.155V threshold (80mV ON pin hysteresis), or pulling the EN pin above its 1.235V threshold. Additionally, an overcurrent fault that exceeds the fault timer period also turns off the Hot Swap MOSFET. Normally, the LTC4236 turns off the MOSFET by pulling the HGATE pin to ground with a 2mA current sink. All of the MOSFETs turn off when INTVCC falls below its undervoltage lockout threshold (2.2V). The DGATE pin is pulled down with a 100µA current to one diode voltage below the IN1 or D2SRC pins, while the HGATE pin is pulled down to the OUT pin by a 200mA current. When D2OFF is pulled high above 1.235V, the ideal diode MOSFET in the IN2 power path is turned off with DGATE2 pulled low by a 100µA current. The gate drive amplifier controls the ideal diode MOSFET to prevent reverse current when the input supply falls below SENSE+. If the input supply collapses quickly, the gate drive amplifier turns off the ideal diode MOSFET with a fast pull-down circuit. If the input supply falls at a more modest rate, the gate drive amplifier controls the MOSFET to maintain SENSE+ at 15mV below IN. Board Presence Detect with EN If ON is high when the EN pin goes low, indicating a board presence, the LTC4236 initiates a timing cycle as configured at the DTMR pin for contact debounce. It defaults to internal 100ms delay if DTMR is tied to INTVCC. If an external capacitor CDT is connected from the DTMR pin to GND, the delay is given by charging the capacitor to 1.235V with 4236f For more information www.linear.com/LTC4236 13 LTC4236 Applications Information a 10µA current. Thereafter, the capacitor is discharged to ground by a 5mA current. For a given debounce delay, the equation for setting the external capacitor CDT value is: CDT = tDB •0.0081 [µF/ms] Upon board insertion, any bounces on the EN pin restart the timing cycle. When the debounce timing cycle is done, the internal fault latch is cleared. If the EN pin remains low at the end of the timing cycle, HGATE is charged up with a 10µA current source to turn on the Hot Swap MOSFET. OUT 10V/DIV HGATE 10V/DIV ILOAD 20A/DIV 200µs/DIV If the EN pin goes high, indicating a board removal, the HGATE pin is pulled low with a 2mA current sink after a 20µs delay, turning off the Hot Swap MOSFET without clearing any latched fault. Figure 2. Overcurrent Fault on 12V Output OUT 10V/DIV Overcurrent Fault The LTC4236 features an adjustable current limit with foldback that protects the external MOSFET against short circuits or excessive load current. The voltage across the external sense resistor RS is monitored by an active current limit amplifier. The amplifier controls the gate of the Hot Swap MOSFET to reduce the load current as a function of the output voltage sensed by the FB pin during active current limit. A graph in the Typical Performance Characteristics shows the current limit sense voltage versus FB voltage. An overcurrent fault occurs when the output has been in current limit for longer than the fault timer period configured at the FTMR pin. Current limiting begins when the sense voltage between the SENSE+ and SENSE– pins reaches 8.3mV to 25mV depending on the FB pin voltage. The gate of the Hot Swap MOSFET is brought under control by the current limit amplifier and the output current is regulated to limit the sense voltage to less than 25mV. At this point, the fault timer starts with a 100µA current charging the FTMR pin capacitor. If the FTMR pin voltage exceeds its 1.235V threshold, the external MOSFET turns off with HGATE pulled to ground by 2mA and FAULT pulls low. After the Hot Swap MOSFET turns off, the FTMR pin capacitor is discharged with a 2µA pull-down current until its threshold reaches 0.2V. This is followed by a cool-off period of 14 timing cycles as described in the FTMR Pin Functions. Figure 2 shows an overcurrent fault on the 12V output. 14 4236 F02 HGATE 10V/DIV ILOAD 20A/DIV 5µs/DIV 4236 F03 Figure 3. Severe Short-Circuit on 12V Output In the event of a severe short-circuit fault on the 12V output as shown in Figure 3, the output current can surge to tens of amperes. The LTC4236 responds within 1µs to bring the current under control by pulling the HGATE to OUT voltage down to zero volts. Almost immediately, the gate of the Hot Swap MOSFET recovers rapidly due to the charge stored in the RHG and CHG network and current is actively limited until the fault timer expires. Due to parasitic supply lead inductance, an input supply without any bypass capacitor may collapse during the high current surge and then spike upwards when the current is interrupted. Figure 9 shows the input supply transient suppressors comprising of Z1, RSNUB1, CSNUB1 and Z2, RSNUB2, CSNUB2 for the two supplies if there is no input capacitance. FTMR Pin Functions An external capacitor CFT connected from the FTMR pin to GND serves as fault timing when the supply output is 4236f For more information www.linear.com/LTC4236 LTC4236 Applications Information in active current limit. When the voltage across the sense resistor exceeds the foldback current limit threshold (from 25mV to 8.3mV), FTMR pulls up with 100µA. Otherwise, it pulls down with 2µA. The fault timer expires when the 1.235V FTMR threshold is exceeded, causing the FAULT pin to pull low. For a given fault timer period, the equation for setting the external capacitor CFT value is: CFT = tFT • 0.083 [µF/ms] After the fault timer expires, the FTMR pin capacitor pulls down with 2µA from the 1.235V FTMR threshold until it reaches 0.2V. Then, it completes 14 cooling cycles consisting of the FTMR pin capacitor charging to 1.235V with a 100µA current and discharging to 0.2V with a 2µA current. At that point, the HGATE pin voltage is allowed to start up if the fault has been cleared as described in the Resetting Fault section. When the latched fault is cleared during the cool-off period, the FAULT pin pulls high. The total cool-off time for the MOSFET after an overcurrent fault is: tCOOL = CFT • 8 [s/µF] After the cool-off period, the HGATE pin is only allowed to pull up if the fault has been cleared for the latchoff part. For the auto-retry part, the latched fault is cleared automatically following the cool-off period and the HGATE pin voltage is allowed to restart. Resetting Fault (LTC4236-1) For the latchoff part, an overcurrent fault is latched after the fault timer expires and the FAULT pin is asserted low. Only the Hot Swap MOSFET is turned off and the ideal diode MOSFETs are not affected. To reset a latched fault and restart the output, pull the ON pin below 0.6V for more than 100µs and then high above 1.235V. The fault latch resets and the FAULT pin de-asserts on the falling edge of the ON pin. When ON goes high again and the cool-off cycle has completed, a debounce timing cycle is initiated before the HGATE pin voltage restarts. Toggling the EN pin high and then low again also resets a fault, but the FAULT pin pulls high at the end of the debounce cycle before the HGATE pin voltage starts up. Bringing all the supplies below the INTVCC undervoltage lockout threshold (2.2V) shuts off all the MOSFETs and resets the fault latch. A debounce cycle is initiated before a normal start-up when any of the supplies is restored above the INTVCC UVLO threshold. Auto-Retry after a Fault (LTC4236-2) For the auto-retry part, the latched fault is reset automatically at the end of the cool-off period as described in the FTMR Pin Functions section. At the end of the cool-off period, the fault latch is cleared and FAULT pulls high. The HGATE pin voltage is allowed to start up and turn on the Hot Swap MOSFET. If the output short persists, the supply powers up into a short with active current limiting until the fault timer expires and FAULT again pulls low. A new cool-off cycle begins with FTMR ramping down with a 2µA current. The whole process repeats itself until the output short is removed. Since tFT and tCOOL are a function of FTMR capacitance CFT, the auto-retry cycle is equal to 0.15%, irrespective of CFT. Figure 4 shows an auto-retry sequence after an overcurrent fault. FTMR 2V/DIV FAULT 10V/DIV HGATE 20V/DIV OUT 10V/DIV 100ms/DIV 4236 F04 Figure 4. Auto-Retry Sequence After a Fault Monitor Undervoltage Fault The ON pin functions as a turn-on control and an input supply monitor. A resistive divider connected between the supply diode-OR output (SENSE+) and GND at the ON pin monitors the supply for undervoltage condition. The undervoltage threshold is set by proper selection of the resistors at the ON rising threshold voltage (1.235V). For Figure 1, if R1 = 2k, R2 = 13.7k, the input supply undervoltage threshold is set to 9.7V. 4236f For more information www.linear.com/LTC4236 15 LTC4236 Applications Information An undervoltage fault occurs if the diode-OR output supply falls below its undervoltage threshold. If the ON pin voltage falls below 1.155V but remains above 0.6V, the Hot Swap MOSFET is turned off by a 2mA pull-down from HGATE to ground. The Hot Swap MOSFET turns back on instantly without the debounce cycle when the diode-OR output supply rises above its undervoltage threshold. However, if the ON pin voltage drops below 0.6V, it turns off the Hot Swap MOSFET and clears the fault latch. The Hot Swap MOSFET turns back on only after a debounce cycle when the diode-OR output supply is restored above its undervoltage threshold. During the undervoltage fault condition, FAULT will not be pulled low but PWRGD will be pulled high as HGATE is pulled low. The ideal diode function controlled by the ideal diode MOSFET is not affected by the undervoltage (UV) fault condition. Power Good Monitor Internal circuitry monitors the MOSFET gate overdrive between the HGATE and OUT pins. Also, the FB pin that connects to OUT through a resistive divider is used to determine a power good condition. The power good comparator drives high when the FB pin rises above 1.235V, and drives low when FB falls below 1.215V. The power good status for the input supply is reported via an open-drain output, PWRGD. It is normally pulled high by an external pull-up resistor or the internal 10µA pull-up. 12V The PWRGD pin pulls low when the FB power good comparator is high and the HGATE drive exceeds 4.2V. The PWRGD pin goes high when the HGATE is turned off by the ON or EN pins, or when the FB power good comparator drives low, or when INTVCC enters undervoltage lockout. Current Sense Monitor The current through the external sense resistor is monitored by LTC4236’s current sense amplifier at the CS+ and SENSE– pins (see Figure 5). The amplifier uses auto-zeroing circuitry to achieve an offset below 150µV over temperature, sense voltage and input supply voltage. The frequency of the auto-zero clock is 10kHz. An internal resistor RIN is connected between the amplifier’s negative input terminal and CS+ pin. The sense amplifier loop forces the negative input terminal to have the same potential as SENSE– and that develops a potential across RIN to be the same as the sense voltage VSENSE. A corresponding current, VSENSE/RIN, will flow through RIN. The high impedance inputs of the sense amplifier will not conduct this input current, allowing it to flow through an internal MOSFET to a resistor ROUT connected between the IMON and GND pins. The IMON output voltage is equal to (ROUT/RIN) • VSENSE. The resistor ratio ROUT/RIN defines the voltage gain of the sense amplifier and is set to 100 with RIN = 200Ω and ROUT = 20k. Full scale input sense voltage to the sense amplifier is 25mV, corresponding to an output of 2.5V. For input supply voltages greater than 0.1µF REG LTC4236 SENSE+ CS+ VSENSE SENSE– RIN 200Ω 0.1µF 10µF 5V HGATE REF+ I LOAD IMON VOUT LOAD IN ROUT 20k GND 0.1µF ROUT VOUT = ––––– • VSENSE = 100 • VSENSE R IN VCC SCL LTC2451 REF – GND 2-WIRE I2C INTERFACE SDA 4236 F05 Figure 5. High Side Current Monitor with LTC2451 ADC 16 4236f For more information www.linear.com/LTC4236 LTC4236 Applications Information 5V, the output clamps at 3.5V if the allowable input sense voltage range is exceeded. IMON Output Filtering A capacitor connected in parallel with ROUT will give a low pass response. This will reduce unwanted noise at the output, and may also be useful as a charge reservoir to keep the output steady while driving a switching circuit such as an ADC (see Figure 5). This output capacitor COUT in parallel with ROUT will create a pole in the output response at: fC = 1 2 • π •ROUT •COUT REG Pin Bypassing The LTC4236 has an internally regulated supply near SENSE+ for internal bias of the current sense amplifier. It is not intended for use as a supply or bias pin for external circuitry. A 0.1µF capacitor should be connected between the REG and SENSE+ pins. This capacitor should be located very near to the device and close to the REG pin for the best performance. REG and IMON Start-Up The start-up current of the current sense amplifier when the LTC4236 is powered on consists of two parts: the first is the current necessary to charge the REG bypass capacitor, which is nominally 0.1µF. Since the REG voltage charges to approximately 4.1V below the SENSE+ voltage, this can require a significant amount of start-up current. The second source is the output current that flows into ROUT, which upon start-up may temporarily drive the IMON output high for less than 2ms. This is a temporary condition which will cease when the sense amplifier settles into normal closed-loop operation. CPO and DGATE Start-Up The CPO pin voltage is initially pulled up to a diode below the IN1 or D2SRC pin when first powered up (see Figure 1). However, for application with back-to-back MOSFETs in IN2 power path, CPO2 starts off at 0V since D2SRC is near ground (see Figure 8). CPO starts ramping up 7µs after INTVCC clears its undervoltage lockout level. Another 40µs later, DGATE also starts ramping up with CPO. The CPO ramp rate is determined by the CPO pull-up current into the combined CPO and DGATE pin capacitances. An internal clamp limits the CPO pin voltage to 12V above the IN1 or D2SRC pin, while the final DGATE pin voltage is determined by the gate drive amplifier. An internal 12V clamp limits the DGATE1 and DGATE2 pin voltages above IN1 and D2SRC respectively. CPO Capacitor Selection The recommended value of the capacitor between the CPO1 and IN1, and CP02 and D2SRC pins is approximately 10× the input capacitance CISS of the ideal diode MOSFET. A larger capacitor takes a correspondingly longer time to charge up by the internal charge pump. A smaller capacitor suffers more voltage drop during a fast gate turn-on event as it shares charge with the MOSFET gate capacitance. MOSFET Selection The LTC4236 drives N-channel MOSFETs to conduct the load current. The important features of the MOSFETs are on-resistance RDS(ON), the maximum drain-source voltage BVDSS and the threshold voltage. The gate drive for the ideal diode and Hot Swap MOSFET is guaranteed to be greater than 5V when the supply voltages at IN1 and IN2 are between 2.9V and 7V. When the supply voltages at IN1 and IN2 are greater than 7V, the gate drive is guaranteed to be greater than 10V. The gate drive is limited to 14V. An external Zener diode can be used to clamp the potential from the MOSFET’s gate to source if the rated breakdown voltage is less than 14V. The maximum allowable drain-source voltage BVDSS must be higher than the supply voltage including supply transients as the full supply voltage can appear across the MOSFET. If an input or output is connected to ground, the full supply voltage will appear across the MOSFET. The RDS(ON) should be small enough to conduct the maximum load current, and also stay within the MOSFET’s power rating. 4236f For more information www.linear.com/LTC4236 17 LTC4236 Applications Information Supply Transient Protection When the capacitances at the input and output are very small, rapid changes in current during input or output short-circuit events can cause transients that exceed the 24V absolute maximum ratings of the IN and OUT pins. To minimize such spikes, use wider traces or heavier trace plating to reduce the power trace inductance. Also, bypass locally with a 10µF electrolytic and 0.1µF ceramic, or alternatively clamp the input with a transient voltage suppressor (Z1, Z2). A 100Ω, 0.1µF snubber damps the response and eliminates ringing (See Figure 9). Design Example As a design example for selecting components, consider a 12V system with a 7A maximum load current for the two supplies (see Figure 1). First, select the appropriate value of the current sense resistor RS for the 12V supply. Calculate the sense resistor value based on the maximum load current ILOAD(MAX) and the lower limit for the current limit sense voltage threshold ΔVSENSE(TH)(MIN). RS = ΔVSENSE(TH)(MIN) ILOAD(MAX) = 22.5mV = 3.2mΩ 7A Choose a 3mΩ sense resistor with a 1% tolerance. Next, calculate the RDS(ON) of the ideal diode MOSFET to achieve the desired forward drop at maximum load. Assuming a forward drop, ΔVFWD of 30mV across the MOSFET: RDS(ON) ≤ ΔVFWD ILOAD(MAX) = 30mV = 4.2mΩ 7A The SiR158DP offers a good choice with a maximum RDS(ON) of 1.8mΩ at VGS = 10V. The input capacitance CISS of the SiR158DP is about 4980pF. Slightly exceeding the 10× recommendation, a 0.1µF capacitor is selected for C2 and C3 at the CPO pins. Next, verify that the thermal ratings of the selected Hot Swap MOSFET are not exceeded during power-up or an overcurrent fault. 18 Assuming the MOSFET dissipates power due to inrush current charging the load capacitor CL at power-up, the energy dissipated in the MOSFET is the same as the energy stored in the load capacitor, and is given by: ECL = 1 • CL • VIN2 2 For CL = 680µF, the time it takes to charge up CL is calculated as: CL • VIN 680µF • 12V = = 8ms IINRUSH 1A tCHARGE = The inrush current is set to 1A by adding capacitance CHG at the gate of the Hot Swap MOSFET. CHG = CL • IHGATE(UP) IINRUSH = 680µF • 10µA = 6.8nF 1A Choose a practical value of 10nF for CHG. The average power dissipated in the MOSFET is calculated as: PAVG = ECL tCHARGE 2 = 1 680µF • (12V ) • = 6W 2 8ms The MOSFET selected must be able to tolerate 6W for 8ms during power-up. The SOA curves of the SiR158DP provide 45W (1.5A at 30V) for 100ms. This is sufficient to satisfy the requirement. The increase in junction temperature due to the power dissipated in the MOSFET is ΔT = PAVG • ZthJC where ZthJC is the junction-to-case thermal impedance. Under this condition, the SiR158DP data sheet indicates that the junction temperature will increase by 3°C using ZthJC = 0.5°C/W (single pulse). Next, the power dissipated in the MOSFET during an overcurrent fault must be safely limited. The fault timer capacitor (CFT) is used to prevent power dissipation in the MOSFET from exceeding the SOA rating during active current limit. A good way to determine a suitable value for CFT is to superimpose the foldback current limit profile shown in the Typical Performance Characteristics on the MOSFET data sheet’s SOA curves. 4236f For more information www.linear.com/LTC4236 LTC4236 Applications Information For the SiR158DP MOSFET, this exercise yields the plot in Figure 6. 100 IDM LIMITED ID – DRAIN CURRENT (A) 10 ⎛ 9.7V ⎞ R2 = ⎜ – 1⎟ • 2k = 13.7k ⎝ 1.235V ⎠ 1ms ID LIMITED 10ms LIMITED BY RDS(ON)* It remains to select the values for the FB pin resistive divider in order to set a power good threshold of 10.5V. Keeping in mind the FB pin’s ±1µA leakage current, choose a value of 2k for the bottom resistor R3. Calculating the top resistor R4 value yields: 100ms 1 1s 0.1 TA = 25°C, SINGLE PULSE MOSFET POWER DISSIPATION CURVE RESULTING FROM FOLDBACK ACTIVE CURRENT LIMIT 0.01 0.01 10s ⎛ VOUT(PG) ⎞ R4 = ⎜ – 1⎟ • R3 ⎝ VFB(TH) ⎠ DC BVDSS LIMITED 0.1 1 10 VDS – DRAIN-TO-SOURCE VOLTAGE (V) ⎛ VIN(UV) ⎞ R2 = ⎜ – 1⎟ • R1 ⎝ VON(TH) ⎠ 100 4236 F06 * VGS > MINIMUM VGS AT WHICH RDS(ON) IS SPECIFIED Figure 6. SiR158DP SOA with Design Example MOSFET Power Dissipation Superimposed As can be seen, the LTC4236’s foldback current limit profile roughly coincides with the 100ms SOA contour. Since this SOA plot is for an ambient temperature of 25°C only, a maximum fault timer period of much less than 100ms should be considered, such as 10ms or less. Selecting a 0.1µF ±10% value for CFT yields a maximum fault timer period of 1.75ms which should be small enough to protect the MOSFET during any overcurrent fault scenario. Next, select the values for the resistive divider at the ON pin that defines the undervoltage threshold of 9.7V for the 12V supply at SENSE+. Since the leakage current for the ON pin can be as high as ±1µA, the total resistance in the divider should be low enough to minimize the resulting offset error. Calculate the bottom resistor R1 based on the following equation to obtain less than ±0.2% error due to leakage current. ⎛ VON(TH) ⎞ ⎛ 1.235V ⎞ R1= ⎜ • 0.2% = 2.4k • 0.2% = ⎜ ⎟ ⎝ 1µA ⎟⎠ ⎝ I IN(LEAK) ⎠ Choose R1 to be 2k to achieve less than ±0.2% error and calculating R2 yields: ⎛ 10.5V ⎞ – 1⎟ • 2k = 15k R4 = ⎜ ⎝ 1.235V ⎠ The subsequent offset error due to the FB pin leakage current will be less than ±0.2%. The final components to consider are a 0.1µF bypass (C1) at the INTVCC pin and a 0.1µF capacitor (C4) connected between the REG and SENSE+ pins. PCB Layout Considerations To achieve accurate current sensing, a Kelvin connection for the sense resistor is recommended. The PCB layout should be balanced and symmetrical to minimize wiring errors. In addition, the PCB layout for the sense resistor and the power MOSFET should include good thermal management techniques for optimal device power dissipation. A recommended PCB layout is illustrated in Figure 7. Connect the IN and OUT pin traces as close as possible to the MOSFETs’ terminals. Keep the traces to the MOSFETs wide and short to minimize resistive losses. The PCB traces associated with the power path through the MOSFETs should have low resistance. The suggested trace width for 1oz copper foil is 0.03" for each ampere of DC current to keep PCB trace resistance, voltage drop and temperature rise to a minimum. Note that the sheet resistance of 1oz copper foil is approximately 0.5mΩ/square, and voltage drops due to trace resistance add up quickly in high current applications. 4236f For more information www.linear.com/LTC4236 19 LTC4236 Applications Information VIA TO GND PLANE • •• Z1 MD1 PowerPAK SO-8 IN1 W • CURRENT FLOW TO LOAD IN2 W S D D G S D D S S D D S G D D S • VIA TO IN1 VIA TO DGATE1 VIA TO C2 (CPO1) ••• RS • S D S D S D G D • CURRENT FLOW TO LOAD RH • MD2 PowerPAK SO-8 • Z2 MH PowerPAK SO-8 W OUT TRACK WIDTH W: 0.03" PER AMPERE ON 1oz Cu FOIL C2 28 27 26 25 24 23 • VIA TO C4 (REG) VIA TO DGATE2 VIA TO GND PLANE 1 22 2 21 3 20 • C1 4 • 6 19 18 17 7 16 8 15 C4 • VIA TO GND PLANE LTC4236UFD 5 VIA TO SENSE+ 9 10 11 12 13 14 • C3 4236 F07 Figure 7. Recommended PCB Layout for Power MOSFETs and Sense Resistor It is also important to place the bypass capacitor C1 for the INTVCC pin, as close as possible between INTVCC and GND. Also place C2 near the CPO1 and IN1 pins, C3 near the CPO2 and D2SRC pins, and C4 near the REG and SENSE+ pins. The transient voltage suppressors Z1 and Z2, when used, should be mounted close to the LTC4236 using short lead lengths. Power Prioritizer Figure 8 shows an application where the IN1 supply is passed to the output on the basis of priority, rather than simply allowing the highest voltage to prevail. This is achieved by connecting a resistive divider from IN1 at the D2OFF pin to suppress the turn-on of the back-to-back ideal diode MOSFETs, MD2 and MD3 in the IN2 power path. In this application, the 5V primary supply (VIN1) is passed to the output whenever it is available; power is drawn 20 from the 12V backup supply (VIN2) only when the primary supply is unavailable. As long as VIN1 is above the 4.7V threshold set by the R6-R7 divider at the D2OFF pin, MD2 and MD3 are turned off, allowing VIN1 to be connected to the output through MD1. The common source terminals of MD2 and MD3 are connected to D2SRC pin, which allows the body-diode of MD2 to reverse block the current flow from the higher backup supply (VIN2) to the output. If the primary supply fails and VIN1 drops below 4.3V, D2OFF is allowed to turn on MD2 and MD3, and connect the VIN2 to the output. When VIN1 returns to a viable voltage, MD2 and MD3 turn off, and the output is connected to VIN1. Adding R5 in the R6-R7 divider and bypassing it with DSTAT2 pin control allows the D2OFF pin hysteresis to be increased from 20mV to 100mV. The resistive divider at the ON pin sets the SENSE+ undervoltage threshold to 4.1V. 4236f For more information www.linear.com/LTC4236 LTC4236 Applications Information MD1 SiR818DP VIN1 5V PRIMARY SUPPLY Z1 SMAJ15A VIN2 + MD2 SiR818DP RS 0.004Ω MD3 SiR818DP MH SiR818DP Z2 SMAJ15A 12V BACKUP BATTERY RH 10Ω C2 0.1µF C3 0.1µF R2 4.64k R1 2k CPO1 IN1 DGATE1 IN2 CPO2 RHG 1k CHG 10nF C4 0.1µF D2SRC DGATE2 REG SENSE+ CS+ SENSE – HGATE R4 4.87k FB LTC4236 R3 2k FAULT PWRGD DSTAT1 D2OFF ADC IMON R6 20k R5 2.2k GND INTVCC C5 0.1µF EN CL 470µF OUT ON R7 56.2k 12V 5A + DTMR C1 0.1µF DSTAT2 FTMR CFT 0.1µF CDT 0.1µF 4236 F08 Figure 8. 2-Channel Power Prioritizer MD1 SiR158DP VIN1 12V Z1 SMAJ15A VIN2 12V Z2 SMAJ15A RSNUB1 100Ω CSNUB1 0.1µF R1 10k RHG 1k CHG 10nF C4 0.1µF C3 0.1µF CPO1 IN1 DGATE1 CPO2 D2SRC IN2 DGATE2 REG ON SENSE+ CS+ SENSE– C1 0.1µF D2OFF D4 R3 2k IMON FTMR CDT 0.1µF CFT 0.1µF R6 2.7k D3 FAULT PWRGD DSTAT1 DSTAT2 DTMR VSENSE+ R5 2.7k OUT FB CARD CONNECTOR GND CL 220µF R4 15k HGATE LTC4236 INTVCC 12V 10A + RH 10Ω EN BACKPLANE CONNECTOR MH SiR158DP RSNUB2 100Ω CSNUB2 0.1µF C2 0.1µF PWREN RS 0.002Ω MD2 SiR158DP R7 2.7k D2 R8 2.7k D1 ADC 4236 F09 D1, D2, D3: GREEN LED LN1351C D4: RED LED LN1261CAL Figure 9. 12V, 10A Card Resident Application 4236f For more information www.linear.com/LTC4236 21 LTC4236 Typical Application Plug-In Card 3.3V Prioritized Power Supply at IN1 MD1 SiR818DP VMAIN 3.3V Z1 SMAJ13A VAUX 3.3V RS 0.004Ω MD2 SiR818DP MH SiR818DP Z2 SMAJ13A R2 2.21k R1 2k C3 0.1µF CPO1 IN1 DGATE1 CPO2 D2SRC IN2 RHG 1k CHG 10nF C4 0.1µF DGATE2 REG SENSE+ CS+ SENSE – ON C5 0.1µF LTC4236 CARD CONNECTOR R9 20k C6 0.1µF IMON GND DTMR INTVCC C1 0.1µF R8 2.2k 22 HGATE OUT VSENSE+ R5 10k R3 2k R6 10k R7 10k FAULT PWRGD DSTAT1 R10 28.7k D2OFF CL 100µF R4 2.37k FB EN BACKPLANE CONNECTOR + RH 10Ω C2 0.1µF 3.3V 5A ADC DSTAT2 FTMR CFT 0.1µF 4236 TA02 4236f For more information www.linear.com/LTC4236 LTC4236 Package Description Please refer to http://www.linear.com/product/LTC4236#packaging for the most recent package drawings. UFD Package 28-Lead Plastic QFN (4mm × 5mm) (Reference LTC DWG # 05-08-1712 Rev B) 0.70 ±0.05 4.50 ±0.05 3.10 ±0.05 2.50 REF 2.65 ±0.05 3.65 ±0.05 PACKAGE OUTLINE 0.25 ±0.05 0.50 BSC 3.50 REF 4.10 ±0.05 5.50 ±0.05 RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED 4.00 ±0.10 (2 SIDES) 0.75 ±0.05 R = 0.05 TYP PIN 1 NOTCH R = 0.20 OR 0.35 × 45° CHAMFER 2.50 REF R = 0.115 TYP 27 28 0.40 ±0.10 PIN 1 TOP MARK (NOTE 6) 1 2 5.00 ±0.10 (2 SIDES) 3.50 REF 3.65 ±0.10 2.65 ±0.10 (UFD28) QFN 0506 REV B 0.200 REF 0.00 – 0.05 0.25 ±0.05 0.50 BSC BOTTOM VIEW—EXPOSED PAD NOTE: 1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X). 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 0.15mm ON ANY SIDE 5. EXPOSED PAD SHALL BE SOLDER PLATED 6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE 4236f For more information www.linear.com/LTC4236 23 LTC4236 Typical Application 12V, 5A Backplane Resident Ideal Diode-OR Application with Inrush Current Limiting VIN1 12V VIN2 12V MD1 SiR158DP BULK SUPPLY BYPASS CAPACITOR RS 0.004Ω MD2 SiR158DP MH SiR158DP + BULK SUPPLY BYPASS CAPACITOR RH 10Ω C2 0.1µF CPO1 IN1 DGATE1 CPO2 D2SRC IN2 DGATE2 REG SENSE+ CS+ SENSE – HGATE OUT R2 13.7k R4 15k FB FAULT PWRGD DSTAT1 DSTAT2 EN ON R1 2k CL 1000µF RHG 1k CHG 10nF C4 0.1µF C3 0.1µF 12V 5A C5 0.1µF LTC4236 R3 2k BACKPLANE D2OFF GND INTVCC DTMR IMON FTMR CFT 0.1µF C1 0.1µF PLUG-IN CARD ADC 4236 TA03 Related Parts PART NUMBER DESCRIPTION COMMENTS LTC4210 Single Channel Hot Swap Controller Operates from 2.7V to 16.5V, Active Current Limiting, TSOT23-6 LTC4211 Single Channel Hot Swap Controller Operates from 2.5V to 16.5V, Multifunction Current Control, MSOP-8, SO-8 or MSOP-10 LTC4215 Single Channel Hot Swap Controller Operates from 2.9V to 15V, I2C Compatible Monitoring, SSOP-16 or QFN-24 LTC4216 Single Channel Hot Swap Controller Operates from 0V to 6V, Active Current Limiting, MSOP-10 or DFN-12 LTC4218 Single Channel Hot Swap Controller Operates from 2.9V to 26.5V, Active Current Limiting, SSOP-16 or DFN-16 LTC4221 Dual Channel Hot Swap Controller Operates from 1V to 13.5V, Multifunction Current Control, SSOP-16 LTC4222 Dual Channel Hot Swap Controller Operates from 2.9V to 29V, I2C Compatible Monitoring, SSOP-36 or QFN-32 LTC4223 Dual Supply Hot Swap Controller Controls 12V and 3.3V, Active Current Limiting, SSOP-16 or DFN-16 LTC4224 Dual Channel Hot Swap Controller Operates from 1V to 6V, Active Current Limiting, MSOP-10 or DFN-10 LTC4227 Dual Ideal Diode and Single Hot Swap Controller Operates from 2.9V to 18V, Controls Three N-Channels, SSOP-16 or QFN-20 LTC4228 Dual Ideal Diode and Hot Swap Controller Operates from 2.9V to 18V, Controls Four N-Channels, SSOP-28 or QFN-28 LTC4229 Ideal Diode and Hot Swap Controller Operates from 2.9V to 18V, Controls Two N-Channels, SSOP-24 or QFN-24 LTC4235 Dual 12V Ideal Diode-OR and Single Hot Swap Controller with Current Monitor Operates from 9V to 14V, Controls Three N-Channels, QFN-20 LTC4352 Low Voltage Ideal Diode Controller Operates from 0V to 18V, Controls N-Channel, MSOP-12 or DFN-12 LTC4353 Dual Low Voltage Ideal Diode Controller Operates from 0V to 18V, Controls Two N-Channels, MSOP-16 or DFN-16 LTC4355 Positive High Voltage Ideal Diode-OR and Monitor Operates from 9V to 80V, Controls Two N-Channels, SO-16, DFN-14 or MSOP-16 LTC4357 Positive High Voltage Ideal Diode Controller 24 Linear Technology Corporation Operates from 9V to 80V, Controls N-Channel, MSOP-8 or DFN-6 1630 McCarthy Blvd., Milpitas, CA 95035-7417 For more information www.linear.com/LTC4236 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com/LTC4236 4236f LT 1215 • PRINTED IN USA LINEAR TECHNOLOGY CORPORATION 2015