SLUS513A − MAY 2003 − REVISED JULY 2004 FEATURES D 12-V, −12-V, 3.3-V, 5-V Main Power Switching D D D D D D D D D D and Auxiliary 3.3-V Power Switching 12-V, −12-V And Auxiliary 3.3-V Power FETs Hot-Swap Protection and Control of All Supplies Overcurrent Protection for All Supplies Isolation of Any Load Fault in One Slot from Any Other Slot Undervoltage Monitoring for the Main 12-V, 3.3-V, 5-V and Auxiliary 3.3-V Supplies Power Fault Latching Overtemperature Shutdown I2C Interface for Power Control, Power Status, Slot Control And Slot Status Compliant To PCI And PCI-X Hot Plug Specifications One TPS2341 Supports Two Slots DESCRIPTION The TPS2341 contains main supply power control, auxiliary supply power control, power FETs for 12-V, −12-V and auxiliary 3.3-V supplies, and a serial interface for communications with and control of slots. Each TPS2341 contains supply control and switching for two slots. The main power control circuits start with all supplies off and hold all supplies off until power to the TPS2341 is valid on all positive supplies. When power is requested, the control circuit applies constant current to the gates of the power !"# $"%&! '#( '"! ! $#!! $# )# # #* "# '' +,( '"! $!#- '# #!#&, !&"'# #- && $##( FETs, allowing each FET to ramp the load voltage linearly. Each main supply can be programmed for a desired ramp rate by selecting a gate capacitor for the power FET for that supply. The power control circuits also monitor load current and latch off that slot if the load current exceeds a programmed maximum value. In addition, once the 12-V, the 5-V, and the 3.3-V FET are fully enhanced, the load voltage is monitored. If the load voltage drops out of specification limit after these FETs are fully enhanced, the slot latches off. This feature provides another level of protection from load fault. The auxiliary power control circuit provides power to the 3VAUXx pins through the 3.3-V main supply when it is above 3.0 V, and through the 3.3-V standby input supply when the 3.3-V main supply drops below 3.0 V. The TPS2341 contains power FETs for 12 V at 500 mA, −12 V at 100 mA, and auxiliary 3.3 V at 375 mA for each slot. These power FETs are short-circuit protected, slew rate controlled, and over-temperature protected. The serial interface communicates with a slot controller using the I2C serial protocol. The interface communicates with the slot, and mechanical switches with individual, dedicated lines. The interface operates from the 3.3-V auxiliary power, but inputs are 5-V tolerant. Mechanical switch inputs have internal pull-up and hysteresis. The serial interface controls slot power, and monitors board, power fault, and switch input status. Copyright 2003, Texas Instruments Incorporated www.ti.com 1 SLUS513A − MAY 2003 − REVISED JULY 2004 absolute maximum ratings over operating free-air temperature (unless otherwise noted)† Input voltage range: P12VIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.5 V to 15 V M12VIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −15.0 V to 0.5 V All others . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.5 V to 6 V Output voltage range: P12VO, 5V3VG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.5 V to VP12VIN +0.5 V P12VG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.5 V to 28 V M12VO, M12VG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VM12VIN−0.5 V to 0.5 V Output current pulse: P12VO (DC internally limited) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 A M12VO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.8 A Operating virtual temperature range, TJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −40°C to 125°C Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −55°C to 150°C Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C † 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 under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. NOTE: All voltages are respect to DGND. electrical characteristics over recommended operating temperature range, P12VINA = P12VINB = 12 V, V5IN = 5 V, V3IN = 3.3 V, DIGVCC = 3.3 V, M12VINA = M12VINB = −12 V, 3VSTBYIN = 3.3 V, all outputs unloaded, −40°C to 85°C, TA = TJ (unless otherwise noted) 5-V/3.3-V Supply PARAMETER TEST CONDITIONS MIN TYP MAX 35 42 49 mV 34 42 49 mV 41 52 60 mV ROCSET = 6.04 kΩ 37 52 62 mV After P12VG and 5V3VG good 4.3 4.65 4.86 V 75 100 ns 5VOC input threshold voltage 5VOC Input threshold voltage ROCSET = 6.04 kΩ, 3VOC Input threshold voltage 3VOC input threshold voltage ROCSET = 6.04 kΩ, 5VISA, 5VISB voltage fault threshold TA = TJ = 25°C ROCSET = 6.04 kΩ TA = TJ = 25°C 5VISA, 5VISB voltage fault minimum captured pulse 5VSA, 5VSB input bias current PWRENx = high −100 5VISA, 5VISB input bias current PWRENx = high 5VISA, 5VISB bleed current PWRENx = low, 3VISA, 3VISB voltage fault threshold After P12VG and 5V3VG good 250 5VISx = 5 V PWRENx = high 3VISA, 3VISB input bias current PWRENx = high 3VISA, 3VISB bleed current 10 20 2.70 2.86 3.05 V 75 100 ns PWRENx = low, −100 3VISx = 3.3 V P12VIN = 12V 5V3VGA, 5V3VGB turn-off time C5V3VG = 0.022 µF, 5V3VG falling from 90% to 10% www.ti.com µA A 5 10 20 mA 20 25 µA 200 5V3VGA, 5V3VGB good threshold mA 14 5V3VGA, 5V3VGB discharge current 2 100 250 5V3VGA, 5V3VGB charge current A µA 5 3VISA, 3VISB voltage fault minimum captured pulse time 3VSA, 3VSB input bias current 100 UNIT 9.5 11 1 mA 11.5 V µs SLUS513A − MAY 2003 − REVISED JULY 2004 electrical characteristics over recommended operating temperature range, P12VINA = P12VINB = 12 V, V5IN = 5 V, V3IN = 3.3 V, DIGVCC = 3.3 V, M12VINA = M12VINB = −12 V, 3VSTBYIN = 3.3 V, all outputs unloaded, −40°C to 85°C, TA = TJ (unless otherwise noted) (continued) +12-V Supply / −12-V Supply PARAMETER +12-V Internal N-channel MOSFET on-resistance −12-V Internal N-channel MOSFET on-resistance TEST CONDITIONS PWREN = HIGH, TA = TJ = 25°C ID = 0.5 A PWREN = HIGH, ID = 0.5 A ID = 0.1 A PWREN = HIGH, TA = TJ = 25°C PWREN = HIGH, +12-V overcurrent threshold −12-V overcurrent threshold P12VOA, P12VOB fault threshold voltage ROCSET = 6.04 kΩ, ID = 0.1 A TA = TJ = 25°C ROCSET = 6.04 kΩ ROCSET = 6.04 kΩ, TA = TJ = 25°C MIN 0.3 Ω 0.4 Ω Ω 0.9 0.79 0.94 1.09 A 0.73 0.94 1.12 A 0.20 0.24 0.28 A 0.18 0.24 0.30 A After P12VG and 5V3VG good 9.50 10.30 11.15 V 75 100 ns −20 −13 −23 M12VGA, M12VGB gate discharge current 200 Derived from charge pump µA mA 14 µA 2 9 17.5 19.0 20.5 PWREN = HIGH to M12VO = −10.4 V, CM12VG = 0.022 µF, RL = 120 Ω CM12VO = 50 µF 15 20 PWREN = HIGH to P12VO = 11.4 V, C12PVG = 0.022 µF, RL = 24 Ω CP12VO = 200 µF 30 75 PWREN = LOW to P12VO = 0.6 V, CP12VG = 0.022 µF 1.5 3.5 µs PWREN = LOW to M12VO = −0.6 V, CM12VG = 0.022 µF 1.5 3.5 µs P12VGA, P12VGB, discharge current 100 P12VGA, P12VGB good threshold Turn-off time 0.18 0.75 UNIT ROCSET = 6.04 kΩ M12VGA, M12VGB gate charge current Turn-on time MAX 0.5 P12VOA, P12VOB voltage fault minimum captured pulse time P12VGA, P12VGB, charge current TYP mA V ms M12VOA, M12VOB bleed current −20 P12VOA, P12VOB bleed current 10 mA noise filter PARAMETER TEST CONDITIONS MIN TYP MAX UNIT Ignored spike from overcurrent 250 ns Latched spike from overcurrent 500 ns www.ti.com 3 SLUS513A − MAY 2003 − REVISED JULY 2004 electrical characteristics over recommended operating temperature range, P12VINA = P12VINB = 12 V, V5IN = 5 V, V3IN = 3.3 V, DIGVCC = 3.3 V, M12VINA = M12VINB = −12 V, 3VSTBYIN = 3.3 V, all outputs unloaded, −40°C to 85°C, TA = TJ (unless otherwise noted) (continued) input/output control PARAMETER TEST CONDITIONS MIN P12VIN = 12 V TYP P12VINA, P12VINB supply current PWRENx = LOW, V5IN supply current V5IN = 5 V V3IN supply current V3IN = 3.3 V M12VINA, M12VINB supply current PWRENx = LOW, 3VSTBYIN supply current 3VSTBYIN = 3.3 V 200 DIGVCC supply current DIGVCC = 3.3 V 200 MAX UNIT 2 mA 1 1000 M12VIN −12 V 250 Overcurrent fault response time V3IN start-up threshold voltage µA A 500 960 2.6 2.8 3.05 2.35 2.55 2.80 4.1 4.4 4.65 V5IN stop threshold voltage 3.75 4.00 4.35 P12VIN start-up threshold voltage 10.1 10.8 11.3 9.5 10.0 11.0 MIN TYP MAX 0.7 1.0 1.3 0.6 1.0 1.4 0.3 1.0 2.0 1.15 1.5 1.85 1.0 1.5 2.0 V3IN stop threshold voltage V5IN start-up threshold voltage P12VIN stop threshold voltage ns V 3.3 VAUX PARAMETER TEST CONDITIONS Load applied for > 1 ms, V3IN slow overcurrent shutdown TA = TJ = 25°C Load applied for > 1 ms V3IN slow overcurrent fault response time V3IN fast overcurrent shutdown Load applied for < 100 µs, TA = TJ = 25°C Load applied for < 100 µs UNIT A ms A 5 10 35 µs 3VSTBYIN overcurrent shutdown 20 40 60 mA 3VSTBYIN overcurrent fault response time 10 25 50 µs V3IN fast overcurrent fault response time V3IN to 3VAUXA, 3VAUXB main switch on-resistance I3VAUXx = −500 mA 300 425 mΩ 3VSTBYIN to 3VAUXA, 3VAUXB standby switch on-resistance I3VAUXx = −10 mA 10 20 Ω 2.5 2.9 V 3VSTBYIN undervoltage lockout 2.0 V3IN to 3VAUXA, 3VAUXB turn-on slew rate 5 3VSTBYIN to 3VAUXA, 3VAUXB turn-on slew rate 3VAUXA, 3VAUXB turn-on time from SWA/SWB from SWx < 0.8 V, C3VAUXx = 150 µF 3VAUXA, 3VAUXB turn-off time from SWA/SWB from SWx > 2 V 3 10 V3IN to 3VSTBYIN crossover time 100 3VSTBYIN to V3IN crossover threshold ms 2.5 3VSTBYIN to V3IN crossover time 2.8 3VSTBYIN to V3IN crossover hysteresis 3VAUXA, 3VAUXB bleed current V/ms 0.1 3VAUXx = 3 V 2.9 µss 3.0 V 50 mV 150 µA ac switching characteristics PARAMETER fMAX operating clock frequency Recommended input rise and fall times 4 TEST CONDITIONS 0 ≤ TA ≤ 70°C 10% to 90% of DIGVCC www.ti.com MIN TYP MAX UNIT 0 100 400 kHz 0.2 1 ns SLUS513A − MAY 2003 − REVISED JULY 2004 electrical characteristics over recommended operating temperature range, P12VINA = P12VINB = 12 V, V5IN = 5 V, V3IN = 3.3 V, DIGVCC = 3.3 V, M12VINA = M12VINB = −12 V, 3VSTBYIN = 3.3 V, all outputs unloaded, −40°C to 85°C, TA = TJ (unless otherwise noted) (continued) dc electrical characteristics MIN TYP MAX Input threshold voltage (SDA, SCL) PARAMETER TEST CONDITIONS 0.8 1.4 2.0 High-level input threshold voltage (SWA, SWB, PGOOD) 1.9 2.4 2.8 Low-level input threshold voltage (SWA, SWB, PGOOD) 0.4 0.8 1.2 Input hysteresis (SWA, SWB, PGOOD) 1.0 1.6 2.0 Address and enable threshold voltage (ADDR1, ENA, ENB) 0.4 1.0 1.5 UNIT V Address and enable hysteresis voltage (ADDR1, ENA, ENB) 200 mV Address and enable floating voltage when not externally driven (ADDR1, ENA, ENB) 1.65 V 50 kΩ Address and enable Thevenin equivalent impedance (ADDR1, ENA, ENB) Test mode threshold voltage (ADDR1) 1.75 Test mode hysteresis voltage (ADDR1) 2.50 2.80 200 High-level output voltage (all digital outputs, except IRQ# and SDA) IL = −4 mA Low-level output voltage (all digital outputs) IL = 4 mA 3.3 V pull-up resistance (SWA, SWB, PGOOD) DIGVCC − 0.4 V mV DIGVCC − 0.2 V 0.2 0.4 30 200 kΩ MIN MAX UNIT Input voltage, P12VINA, P12VINB 10.8 13.2 Input voltage, V5IN 4.75 5.25 3.1 3.5 −13.2 −10.8 recommended operating conditions Input voltage, DIGVCC Input voltage, M12VINA, M12VINB Input voltage, 3VSTBYIN 3.1 3.5 Load current, P12VOA, P12VOB 0 500 Load current, M12VOA, M12VOB 0 100 Load current, 3VAUXA, 3VAUXB 0 375 www.ti.com V mA 5 SLUS513A − MAY 2003 − REVISED JULY 2004 Terminal Functions TERMINAL NAME NO. I/O DESCRIPTION 3VAUXA 36 O 3VAUXB 35 O 3VISA 30 I 3VISB 7 I 3VSA 31 I 3VSB 6 I Connect to the source side of the 3.3-V FET switch. This pin in conjunction with the 3VIS pin senses the current to the 3.3-V load by sensing the voltage drop across a sense resistor. A 0.01-µF bypass capacitor to AGND is recommended. 3VSTBYIN 37 P 3.3Vaux standby voltage supply input. A 0.1-µF bypass capacitor to PWRGND2 is recommended. 5V3VGA 33 O 5V3VGB 5 O Gate drive for the 5-V and 3.3-V FET switches. Ramp rate is programmed by external capacitance connected to this pin. The capacitor is charged with a 20-µA current source and discharged with a switch to PWRGND. The output UV circuitry is disabled until the voltage on this pin is greater than 11 V and the voltage on P12VGx is greater than 20 V. 5VISA 29 I 5VISB 8 I 5VSA 28 I 5VSB 9 I ADDR1 17 I AGND 11 G Ground pin for the internal analog section. AUX_GOODA 27 O AUX_GOODB 19 O Output power good indicator for the 3.3-VAUXx ouptut. This pin is driven to DIGVCC when the internal N-channel MOSFET connected between V3IN and 3VAUXA (or 3VAUXB for slot B) is fully enhanced. DIGVCC 24 P Power pin for the digital section, connect to 3VSTBYIN. A 0.1-µF bypass capacitor from DIGVCC to DIGGND is recommended. DGND 23 G Ground pin for the internal digital section. ENA 15 I ENB 16 I IRQ# 18 O Interrupt output. Open drain pulls low upon any fault detection or if SWA or SWB changes state. M12VGA 41 O A capacitor connected from this pin to M12VOA programs the ramp rate of the −12-V switched output. The capacitor is charged with a 20-µA current source and discharged with a switch to PWRGND. M12VGB 48 O A capacitor connected from this pin to M12VOB programs the ramp rate of the −12-V switched output. The capacitor is charged with a 20-µA current source and discharged with a switch to PWRGND. M12VIN 2 P M12VIN 39 P M12VINA 40 P M12VINB 1 P M12VOA 38 O M12VOB 3 O OCSET 6 10 I 3.3Vaux voltage supply outputs. A 0.010.01-µF F bypass capacitor to PWRGND2 is recommended. Connect to the load side of the sense resistor. See definition for 3VS. This pin has a switched FET to PWRGND to discharge any output load capacitance when the output is turned off. A 0.01-µF bypass capacitor to AGND is recommended. Connect to the load side of the sense resistor. See definition for 5VS. 5VIS is also used to sense the output voltage for the 5-V UV circuit. This pin has a switched FET to PWRGND to discharge any output load capacitance when the output is turned off. A 0.01-µF bypass capacitor to AGND is recommended. Connect to the source of the 5-V FET switch. This pin in conjunction with the 5VIS pin senses the current to the 5-V load by sensing the voltage drop across the sense resistor. A 0.01-µF bypass capacitor to AGND is recommended. Hard-wired I2C address pin. This pin represents the least significant bit (LSB) of a device’s I2C address. Tie to DGND for a logic 0 or allow to float for a logic 1. Tie ADDR1 to DIGVCC for test mode fault mask. Hardware enable pins. Use these pins to enable the device without I2C communication. Pull ENA high to enable slot A. Pull ENB high to enable slot B. Pull ENA low to disable slot A hardware control and revert to I2C control. Transitioning ENA from high to low also clears the slot A main fault latch. Pull ENB low to disable slot B hardware control and revert to I2C control. Transitioning ENB from high to low also clears the slot B main fault latch. −12-V input voltage to the device. M12VIN, M12VINA and M12VINB must be tied together and are internally connected by a high-resistance path. The heat conduction pad on the back of the package is also connected to M12VIN. A 0.1-µF bypass capacitor from M12VIN to PWRGND is recommended. −12-V input voltage to the device and the −12-V power FET. M12VINA, and M12VINB and M12VIN must be tied together and are internally connected by a high-resistance path. The heat conducting pad on the back of the package is also connected to M12VIN. A 0.1-µF bypass capacitor from M12VIN to PWRGND is recommended. −12-V Switched output. This pin has a switched FET to PWRGND to discharge any output load capacitance when the output is turned off. A 0.01-µF bypass capacitor to PWRGND is recommended. A resistor connected between this pin and AGND sets the overcurrent threshold of the internal switches. The +12-V and −12-V switches are set for the maximum permissible currents per the PCI specification when a 1%, 6.04-kΩ resistor is used. A 0.1-µF bypass capacitor from OCSET to ANAGND is recommended. www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 Terminal Functions TERMINAL NAME NO. I/O DESCRIPTION P12VGA 42 O Gate drive for the 12-V internal N-channel MOSFET for slot A. Connect a capacitor from this pin to PWRGND1 to program the ramp rate. The capacitor is charged with a 5−µΑ current source and discharged with a switch. The output undervoltage circuitry is disabled until the voltage on this pin is greater than 20 V and the voltage on 5V3VGA is greater than 11 V. P12VGB 47 O Gate drive for the 12-V internal N-channel MOSFET for slot B. Connect a capacitor from this pin to PWRGND2 to program the ramp rate. The capacitor is charged with a 5-µΑ current source and discharged with a switch. The output undervoltage circuitry is disabled until the voltage on this pin is greater than 20 V and the voltage on 5V3VGB is greater than 11 V. P12VINA 44 P 12-V input to the device and the 12-V power FET for slot A. A 0.1-µF bypass capacitor from P12VINA to PWRGND1 is recommended. P12VINB 45 P 12-V input to the device and the 12-V power FET for slot B. A 0.1-µF bypass capacitor from P12VINB to PWRGND2 is recommended. P12VOA 43 O 12-V switched output for slot A. This pin has a switched FET to ground to discharge any output load capacitance when the output is turned off. A 0.01-µF bypass capacitor to PWRGND1 is recommended. P12VOB 46 O 12-V switched output for slot B. This pin has a switched FET to ground to discharge any output load capacitance when the output is turned off. A 0.01-µF bypass capacitor to PWRGND2 is recommended. PGOOD 20 I Power good input. PGOOD has hysteresis so that it can be used as a power-on reset, driven from a slow-rising RC. PGOOD also has a 100-kΩ pull-up to DIGVCC. PGOOD_OUTA 22 O PGOOD_OUTB 21 O PWRGND1 4 G PWRGND2 34 G SCL 13 I SDA 14 I/O SWA 25 I Slot A switch input. Low indicates the slot is populated. This input has hysteresis and a 100-kΩ pull-up to DIGVCC, requiring only a capacitor to ground for debouncing mechanical noise. SWB 12 I Slot B switch input. Low indicates the slot is populated. This input has hysteresis and a 100-kΩ pull-up to DIGVCC, requiring only a capacitor to ground for debouncing mechanical noise. V3IN 32 P 3.3-V input to the device. A 0.1-µF bypass capacitor from V3IN to PWRGND is recommended. V5IN 26 P 5-V input to the device. A 0.1-µF bypass capacitor from V5IN to PWRGND is recommended. Output power good indicator for the main slot outputs. This pin is driven to DIGVCC when the voltage on P12VGA (or P12VGB for slot B) is greater than 20 V and the voltage on 5V3VGA (or 5V3VGB for slot B) is greater than 11 V. Ground pin for the power analog section. Serial clock line for the I2C bus. Serial data line for the I2C bus. AVAILABLE OPTIONS PACKAGE TA HTQFP (PHP) −40°C to 85°C TPS2341PHP www.ti.com 7 SLUS513A − MAY 2003 − REVISED JULY 2004 M12VGB P12VGB P12VOB P12VINB P12VINA P12VOA P12VGA M12VGA M12VINA M12VIN M12VOA 3VSTBYIN PHP PACKAGE (TOP VIEW) 48 47 46 45 44 43 42 41 40 39 38 37 M12VINB M12VIN M12VOB PWRGND1 5V3VGB 3VSB 3VISB 5VISB 5VSB OCSET AGND SWB 1 36 2 35 3 34 4 33 5 32 6 31 7 30 8 29 9 28 10 27 11 26 12 25 3VAUXA 3VAUXB PWRGND2 5V3VGA V3IN 3VSA 3VISA 5VISA 5VSA AUX_GOODA V5IN SWA SCL SDA ENA ENB ADDR1 IRQ# AUX_GOODB PGOOD PGOOD_OUTB PGOOD_OUTA DGND DIGVCC 13 14 15 16 17 18 19 20 21 22 23 24 The heat-conduction pad on the underside of the package is electrically connected to M12VINA. Either connect the heat-conducting pad to −12 VIN or leave unconnected. Do not connect the heat-conducting pad to any other power plane or to a ground. 8 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 FUNCTIONAL BLOCK DIAGRAM V3IN 32 3VSTBYIN 37 36 3VAUXA OVERCURRENT SENSE TO SECOND SLOT FROM GOOD INPUTS AUX FAULT LATCH S Q R + 2.9 V 5 µA Q SR CONTROL 2.5 ms TURN−OFF DELAY SWA 25 27 AUX_GOODA 5 µA THERMAL SHUTDOWN + 20 V 42 P12VGA 44 P12VINA OC SENSE 20 µA 43 P12VOA + 5V3VGA 33 11 V 3VSA 31 + MAIN FAULT LATCH 3VISA 30 5VSA 28 38 M12VOA 41 M12VGA OC SENSE S Q R Q 20 µA + 5VISA 29 P12VO 5VIS 3VIS P12VINA V5IN 3VIN OUTPUTS GOOD 40 M12VINA INPUTS GOOD 22 PGOOD_OUTA ENA 15 TWO ITERATIONS ONE ITERATION PGOOD 20 18 100 µA IRQ# TO SECOND SLOT OCSET 10 CURRENT LIMIT THRESHOLD PWRENA AUXFLTA FLTA IMASKA PWRENB AUXFLTB FLTB IMASKB SDA 14 SERIAL TO PARALLEL CONVERTER SCL 13 11 4 34 26 17 24 23 AGND PWRGND1 PWRGND2 V5IN ADDR1 DIGVCC DGND www.ti.com 2 39 M12VIN M12VIN UDG−01152 9 SLUS513A − MAY 2003 − REVISED JULY 2004 TYPICAL CHARACTERISTICS Refer to the typical application diagram (Figure 13) for circuit component values for Figures 1 through 9. MAIN SWITCH RAMPUP VOLTAGE vs TIME 3.5 15 +12 V 3.3-V MAIN SWITCH UNDERVOLTAGE FAULT RESPONSE vs TIME 3VIN 3.0 +5 V +3.3 V 5 0 −5 V3VOUT − Output Voltage − V VLOAD − Output Voltage − V 10 2.5 2.0 1.5 3VOUT 1.0 PGOOD_OUTA 0.5 −10 0 −12 V −0.5 −15 T − Time − 1 ms / div T − Time − 10 ms / div Figure 2. Figure 1. 12-V OUTPUT AND INRUSH CURRENT vs TIME +12 V Gate 0.20 +12 V Inrush Current 15 0.15 +12 V Output 10 0.10 5 PGOOD_OUTA 0 0.05 V5VOUT − Output Votlage − V +5 V Output I12LOAD − Inrush Current − A V12VOUT − Output Voltage − V 20 12 6 0.25 CLOAD = 300 µF 5 10 4 8 3 6 PGOOD_OUTA 2 4 1 2 0 5V Load Current −1 −2 0 −2 +5 V Output −5 10 0 −0.05 −3 −6 T − Time − 10 ms / div T − Time − 10 µs / div Figure 3. Figure 4. www.ti.com −4 I5VOUT − Load Currentt − A 25 5-V OUTPUT OVERLOAD RESPONSE vs TIME SLUS513A − MAY 2003 − REVISED JULY 2004 TYPICAL CHARACTERISTICS Refer to the typical application diagram (Figure 13) for circuit component values for Figures 1 through 9. −12-V SHORTED LOAD STARTUP VOLTAGE AND LOAD CURRENT vs TIME 3VAUX OUTPUT RAMP-UP VOLTAGE AND INRUSH CURRENT vs TIME 0.30 3.5 1.4 0 0.25 3.0 1.2 −2 0.20 2 0.15 −12 V Load Current −6 0.10 0.05 −8 −10 0 −12 −0.05 3VAUXA Output 2.5 SWA Input 2.0 AUX_GOODA 1.5 −14 −0.10 0.8 0.6 3VAUXA Inrush Current 1.0 0.5 0.4 0.2 0 −12 V Gate Voltage 1.0 I3VAUXALOAD − Load Current − A −4 IM12LOAD − Load Current − A V3VAUXA − Output Voltage − V VM12VOUT − Output Voltage − V −12 V Output 0 CLOAD = 150 µF −0.5 T − Time − 1 ms / div −0.2 T − Time − 500 µs / div Figure 5. Figure 6. 3VSTBYIN TO V3IN OUTPUT VOLTAGE V3IN TO 3VSTBYIN OUTPUT VOLTAGE CROSSOVER RESPONSE vs TIME CROSSOVER RESPONSE vs TIME 4.0 4.0 3.5 3.0 3.0 V3VAUXA − Output Voltage − V V3VAUXA − Output Voltage − V 3VAUXA Output 3.5 2.5 2.0 1.5 1.0 0.5 3VAUXA Output 2.5 2.0 1.5 1.0 0.5 AUX_GOODA AUX_GOODA 0 0 −0.5 −0.5 T − Time − 5 µs / div T − Time − 10 µs / div Figure 7. Figure 8. www.ti.com 11 SLUS513A − MAY 2003 − REVISED JULY 2004 TYPICAL CHARACTERISTICS Refer to the typical application diagram (Figure 13) for circuit component values for Figures 1 through 9. 3VAUX OUTPUT OVERLOAD RESPONSE vs TIME 3.5 3VAUXA Output 1.2 AUX_GOODA 2.5 1.0 2.0 0.8 1.5 1.0 0.6 3VAUXA Load Current 0.5 0.4 0.2 0 I3VAUXALOAD − Load Current −A V3VAUXA − Voltage Amplitude − V 3.0 1.4 0 −0.5 −0.2 T − Time − 10 ms / div Figure 9. 12 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION The functional block diagram shows the TPS2341 with detailed information on the analog functions. For clarity, the analog circuits for only one slot are shown in detail. +12-V Supply Control The TPS2341 integrates an N-channel power MOSFET for the +12-V supply between pins P12VINA and P12VOA. The switch has a nominal on resistance of 180 mΩ and shuts down the slot upon detecting an overcurrent condition. The in-rush current of the supply is controlled in an open-loop fashion by charging an external capacitor tied directly to the internal N-channel MOSFET gate with a constant current source. This results in a linear voltage ramp on the gate and also on the P12VOA output due to the source follower connection of the switch. The switch turns on when the logic declares the input supplies are valid, slot is healthy and the enable from the I2C serial interface is active. The P12VOA output voltage is monitored for an undervoltage fault once the +12-V, +5-V and +3.3-V switches are fully enhanced. The switch shuts off upon a disable command from the I2C serial interface or a fault on the slot. An internal resistor connects between the P12VOA and PWRGND1 upon disable and bleeds off any residual charge on the output. Slot B functions independently and in the same manner as slot A with the input supply connected to P12VINB and the load connected to P12VOB. −12-V Supply Control The TPS2341 integrates an N-channel power MOSFET for the −12-V supply between pins M12VINA and M12VOA. The switch has a nominal on resistance of 500 mΩ and shuts down the slot upon detecting an overcurrent condition. The in-rush current of the supply is controlled in a closed-loop fashion by charging an external Miller capacitor tied between the N-channel MOSFET gate and drain with a constant current source. This results in a linear voltage ramp on the drain (M12VOA) pin. The switch turns on when the logic declares the input supplies are valid, slot is healthy and the enable from the I2C serial interface is active. The M12VOA output voltage is not monitored for an undervoltage fault. The switch shuts off upon a disable command from the I2C serial interface or a fault on the slot. An internal resistor connects between the M12VOA and PWRGND1 upon disable and bleeds off any residual charge on the output. Slot B functions independently and in the same manner as slot A with the input supply connected to M12VINB and the load connected to M12VOB. www.ti.com 13 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION +5-V and +3.3-V Supply Controls The TPS2341 provides the control circuitry for external N-channel power MOSFETs on the +5-V and +3.3-V supplies. The switches share a common gate capacitor for slew rate control and have independent overcurrent detection circuitry. A source side sense resistor provides a differential sense voltage to pins 5VSA and 5VISA that is compared to a threshold voltage for the +5-V supply overcurrent fault. The +3.3-V supply operates similarly and a fault on either supply shuts down the slot. The in-rush current of the supply is controlled in a open-loop fashion by charging an external capacitor tied directly to the N-channel MOSFET gate with a constant current source. This results in a linear voltage ramp on the gate and also on the load due to the source follower connection of the switch. The switch turns on when the logic declares the input supplies are valid, slot is healthy and the enable from the I2C serial interface is active. The 3VISA and 5VISA pins are monitored for an undervoltage fault once the +12-V, +5-V and +3.3-V switches are fully enhanced. The switch shuts off upon a disable command from the I2C serial interface or a fault on the slot. An internal resistor connects between 3VISA and PWRGND1 and also between 5VISA and PWRGND1 upon disable and bleeds off any residual charge on the output. Slot B functions independently and in the same manner as slot A. 3VAUX Supply Control The TPS2341 integrates the power FETs for the 3.3 V auxiliary outputs providing power from V3IN when the main supply is above 3 V and from the 3VSTBYIN supply when V3IN is below 3 V. The 3VAUX circuit differs from the main circuits in regard to slew rate control. The main circuits slew rate is programmable by an external capacitor while the 3VAUX slew rate is fixed. The 3VAUX outputs turn on and slew up upon the application of 3VSTBYIN and SW. The slew rate is slow enough to allow charging a large bulk capacitor (up to 150 µF) without tripping the overload comparator. After the main supply inputs are active, the 3VAUX switch connected to 3VSTBYIN shuts off and the switch connected to V3IN turns on in a rapid break-before-make fashion. Upon the undervoltage failure of the V3IN or one of the positive main supplies, the V3IN switch shuts off and the 3VSTBYIN switch turns on in a rapid break-before-make fashion. A high on the SW input shuts off the active switch. The V3IN switch has slew rate control slow enough to allow charging the bulk capacitance in the event that 3VSTBYIN and the main supplies become active together. The V3IN switches have two overcurrent thresholds. The slow overcurrent threshold trips when the load current exceeds 1 A for longer than 1 ms. The 3VAUX outputs can accomodate a transient current due to a load device enable or charge up to 150 µF of bulk capacitance without tripping a nuisance fault. The fast overcurrent threshold trips when the load current exceeds 1.5 A for longer than 10 µs. This threshold captures a direct short on the 3VAUX output. The 3VSTBYIN switches detect an overcurrent condition when the load current exceeds 40 mA for 25 µs. The main and standby faults are cleared by disabling the 3VAUX slot with the SW input or by removing the input supply voltage. 14 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Fault Logic The main supply switches require the inputs to be healthy before turning on. The slot is shut down upon an overload condition or output undervoltage condition and all switches shut off upon a device overtemperature condition. The switch starts to turn on when the P12VINA, V5IN and V3IN supply inputs are above the undervoltage thresholds, the PGOOD input is active and the PWRENA (or PWRENB for slot B) control output from the I2C serial interface is active. The P12VOA, P5VISA and P3VISA pins monitor the load for an undervoltage fault once the +12-V, +5-V and +3.3-V switches are fully enhanced. The +12-V, +5-V, +3.3-V and −12-V load currents are monitored for an overload condition continuously upon slot enable. The device overtemperature sensor is always active, cannot be masked with the test mode fault mask, and shuts down all switches upon sensing excessive internal die temperature. The main load faults are latched and can be cleared by cycling the slot enable with the I2C serial interface (if operating in serial mode), by transitioning slot enable from high to low (if operating in hardware enable mode), or by dropping and then raising power to the TPS2341. The 3.3VAux standby switch requires only the 3VSTBYIN supply to be healthy before turning on. An overload condition shuts down the slot standby switch. The latched fault can be cleared by toggling the SWA (or SWB for slot B) input or by cycling the standby supply voltage. The 3.3VAux main switch requires the main supply voltages to be within specifications before turning on. The slot 3.3VAux main switch shuts off upon an overload condition and all switches shut off upon the device over temperature condition. The latched fault can be cleared by cycling the SWA (or SWB for slot B) 3.3VAux disable pin or removal and assertion of input supply voltage. The I2C serial interface can be used to determine the offending fault. Polling the STATUS READ register determines which slot caused the fault and differentiates between the main supply switches or the 3.3VAux switches. The slot STATUS register indicates an undervoltage fault, thermal shutdown, overload fault or commanded disable occurred. The OVERLOAD register isolates an overload condition to the individual supply switch. Operation Without I2C The TPS2341 can be used in a system without I2C, although some of the diagnostic capabilities of the TPS2341 are lost. Slot main power is applied by applying a rising edge to the PGOOD input and then applying a rising edge to the appropriate slot enable input ENx. Slot main power status is observed at the PGOOD_OUTx output. In the event of a loss of power on any main input, the TPS2341 resets to all slots off. Main slot power restarts on the next rising edge of ENx after power is recovered. In a system without I2C, the interrupt output IRQ# is not meaningful and should not be connected. SDA should be pulled up to 3.3 V. SCL and ADDR1 should be grounded. www.ti.com 15 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Interrupt Service Request The TPS2341 generates an interrupt by asserting the IRQ# output. Any of the following conditions causes an interrupt: D D D D The SWx input changes state. An auxiliary or main output over-current fault occurs. A main input/output under-voltage condition occurs. Thermal shutdown of the TPS2341 occurs. The status registers (see Table 1) can be read to determine the cause of the interrupt and to identify the slot causing the interrupt. Slot level control of an interrupt is possible through the interrupt mask in register 00h. For example, setting mask bits zero and two to logic 1 and logic 0, respectively, enables a slot A interrupt but disables a slot B interrupt. These mask bits only affect the IRQ# output pin, the internal IRQ bits in register 10h still acknowledge the fault. Resetting the Interrupt A SWx input state change causes an interrupt that is cleared by setting bit 4 (SW interrupt reset) of register 00h to logic 1. This bit must then be set to logic 0 to rearm the interrupt. An interrupt that is caused by an overload on the auxiliary channel will be cleared along with the fault when the SWx input pin is brought high (disable) or the PGOOD input pin is brought low. An interrupt that is caused by an overload on the main channel or a main input/output undervoltage condition will be cleared along with the fault when the ENx input pin is brought low and the ENx bit in register 00h is brought low. This interrupt is also cleared when the PGOOD input is brought low. I2C Operation The TPS2341 communicates with the master controller using the I2C serial protocol. The SCL pin, which is the clock, and the SDA pin, which is the bi-directional data, are used for transferring data to and from the device. The TPS2341 implements a 7-bit addressing scheme with the upper six bits internally defined 010000 and the least significant bit user programmable with the ADDR1 pin. The data protocol recognizes a START pulse as a high-to-low transition on the SDA pin when the SCL pin is high. The rising edge of the SCL pin clocks a logic-high into (or out of) the device when SDA is high and a logic-low when the SDA pin is low. An ACKNOWLEDGE handshake occurs as the device receiving the 8-bit word pulls the SDA pin low when the SCL pin is clocked the ninth time. Another 8-bit word followed by an ACKNOWLEDGE bit can immediately begin depending upon the read or write cycle protocol. The write cycle protocol begins with a START bit, contains three 8-bit words, each followed by an ACKNOWLEDGE bit and ends with a STOP bit. The first 8-bit word is the device address which must match the internally defined upper 6 bits and externally defined least significant bit with a low LSB (A0) to indicate a write cycle. Following a good device address word, the second 8-bit word selects the internal register that the control device would like to place data into. The third 8-bit word is the actual data to be placed into the selected registers. 16 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 SCL Stop Bit Clock ’1’ Clock ’0’ Clock ’1’ Clock ’1’ Start Bit SDA R/W Bit Write Cycle Register Address Data from Master to TPS2341 Stop Bit Device Address R/W=0 D7 D6 D5 D4 D3 D2 D1 D0 Ack Bit R7 R6 R5 R4 R3 R2 R1 R0 Ack Bit Start Bit A7 A6 A5 A4 A3 A2 A1 A0 Ack Bit SDA R/W Bit R/W Bit Read Cycle Device Address R/W=1 Data from TPS2341 to Master Ack Bit Stop Bit Register Address D7 D6 D5 D4 D3 D2 D1 D0 Ack Bit A7 A6 A5 A4 A3 A2 A1 A0 Start Bit Device Address R/W=0 R7 R6 R5 R4 R3 R2 R1 R0 Ack Bit Start Bit A7 A6 A5 A4 A3 A2 A1 A0 Ack Bit SDA UDG−02155 Figure 10. I2C Signal Timing www.ti.com 17 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION I2C Operation (continued) The read cycle protocol begins with a START bit, followed by two 8-bit words, another START bit, another two 8-bit words and ends with a STOP bit. The first two 8-bit words are similar to the write cycle, with a low LSB for the device address, and instruct the device which internal register will be polled. A START bit after the second word interrupts the write cycle after the internal register is defined. The next 8-bit word following the second START bit is once again the device address, however, the LSB (A0) is now high indicating the device is expected to return the data from the selected internal register. After the ACKNOWLEDGE bit, the TPS2341 drives the SDA line and return the 8-bits of data from the internal register. Table 1. Register DefinitionS REGISTER 00h 10h 18 ASSIGNMENT BIT Control Write READ/ WRITE W DEFINITION 0 Slot A Int_Mask 1: Allow Slot A interrupts to set IRQ# active 0: Mask Slot A interrupts on IRQ# 1 Slot A Enable 1: Enable Slot A main switches 0: Disable Slot A main switches 2 Slot B Int_Mask 1: Allow Slot B interrupts to set IRQ# active 0: Mask Slot B interrupts on IRQ# 3 Slot B Enable 1: Enable Slot B main switches 0: Disable Slot B main switches 4 SW Interrupt Reset 1: Reset interrupt request from SWA or SWB edge transition 0: Clear reset 5 Spare a; data stored here is visible on read 11h, bit 5 6 Spare b; data stored here is visible on read 11h, bit 6 7 Spare c; data stored here is visible on read 11h, bit 7 Status Read R 0 Slot A PGood 1: Slot A main switches active and healthy 0: Slot A main switches not healthy 1 Slot A Aux_Good 1: Slot A 3.3-V Aux main active and healthy 0: Slot A 3.3-V Aux not healthy 2 Slot A IRQ 1: Slot A interrupt request active 0: Slot A interrupt request inactive 3 Slot B PGood 1: Slot B main switches active and healthy 0: Slot B main switches not healthy 4 Slot B Aux_Good 1: Slot B 3.3-V Aux main active and healthy 0: Slot B 3.3-V Aux not healthy 5 Slot B IRQ 1: Slot B interrupt request active 0: Slot B interrupt request inactive 6 PGOOD_INPUT 1: PGOOD input pin is high 0: PGOOD input pin is low 7 0 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Table 1. Register Definitions (continued) 11h 12h Control Read R 0 Slot A Int_Mask 1: Slot A allows interrupts to set IRQ# active 0: Slot A masks interrupts on IRQ# 1 Slot A Enable 1: Slot A main switches enable active 0: Slot A main switches enable inactive 2 Slot B Int_Mask 1: Slot B allows interrupts to set IRQ# active 0: Slot B masks interrupts on IRQ# 3 Slot B Enable 1: Slot B main switches enable active 0: Slot B main switches enable inactive 4 SW Interrupt Reset 1: Reset Interrupt request from SWA or SWB edge transition 0: Clear reset 5 Spare a; Data stored from write 00h, bit 5 6 Spare b; Data stored from write 00h, bit 6 7 Spare c; Data stored from write 00h, bit 7 Slot A Status R 0 Slot A enable 1: Slot A main switches enable active 0: Slot A main switches enable inactive 1 Input undervoltage fault 1: Input undervoltage fault active 0: Input undervoltage fault inactive 2 Slot A output undervoltage fault 1: Slot A output undervoltage fault active 0: Slot A output undervoltage fault inactive 3 Slot A overload fault 1: Slot A overload fault active 0: Slot A overload fault inactive 4 Thermal shutdown fault 1: Thermal shutdown fault active 0: Thermal shutdown fault inactive 5 SWA input 1: SWA input active; after rising edge delay 0: SWA input inactive; no falling edge delay 6 Slot A PGOOD 1: Slot A main switches active and healthy 0: Slot A main switches not healthy 7 Slot A Main Fault 1: Slot A main fault active 0: Slot A main fault inactive www.ti.com 19 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Table 1. Register Definitions (continued) REGISTER 13h 14h 20 ASSIGNMENT BIT Slot A Overload READ/ WRITE R DEFINITION 0 Slot A +3V Overload 1: Slot A +3.3-V overload active 0: Slot A +3.3-V overload inactive 1 Slot A +5V Overload 1: Slot A +5-V overload active 0: Slot A +5-V overload inactive 2 Slot A +12-V Overload 1: Slot A +12-V overload active 0: Slot A +12-V overload inactive 3 Slot A −12-V Overload 1: Slot A −12-V overload active 0: Slot A −12-V overload inactive 4 Slot A 3VSTBYIN Overload 1: Slot A 3.3-VAux standby overload active 0: Slot A 3.3-VAux standby overload inactive 5 Slot A 3VMAIN overload 1: Slot A 3.3-VAux main overload active 0: Slot A 3.3-VAux main overload inactive 6 Slot A 3VAUX standby switch on 1: Slot A 3.3-VAux standby switch active 0: Slot A 3.3-Vaux standby switch inactive 7 Slot A 3VAUX main switch on 1: Slot A 3.3VAux main switch active 0: Slot A 3.3VAux main switch inactive Slot B Status R 0 Slot B enable 1: Slot B main switches enable active 0: Slot B main switches enable inactive 1 Input undervoltage fault 1: Input undervoltage fault active 0: Input undervoltage fault inactive 2 Slot B output undervoltage fault 1: Slot B output undervoltage fault active 0: Slot B output undervoltage fault inactive 3 Slot B overload fault 1: Slot B overload fault active 0: Slot B overload fault inactive 4 Thermal shutdown fault 1: Thermal shutdown fault active 0: Thermal shutdown fault inactive 5 SWA input 1: SWA input active; after rising edge delay 0: SWA input inactive; no falling edge delay 6 Slot B PGOOD 1: Slot B main switches active and healthy 0: Slot B main switches not healthy 7 Slot B Main Fault 1: Slot B main fault active 0: Slot B main fault inactive www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Table 1. Register Definitions (continued) 15h Slot B Overload R 0 Slot B +3V Overload 1: Slot B +3.3-V overload active 0: Slot B +3.3-V overload inactive 1 Slot B +5V Overload 1: Slot B +5-V overload active 0: Slot B +5-V overload inactive 2 Slot B +12-V Overload 1: Slot B +12-V overload active 0: Slot B +12-V overload inactive 3 Slot B −12-V Overload 1: Slot B −12-V overload active 0: Slot B −12-V overload inactive 4 Slot B 3VSTBYIN Overload 1: Slot B 3.3-VAux standby overload active 0: Slot B 3.3-VAux standby overload inactive 5 Slot B 3VMAIN overload 1: Slot B 3.3-VAux main overload active 0: Slot B 3.3-VAux main overload inactive 6 Slot B 3VAUX standby switch on 1: Slot B 3.3-VAux standby switch active 0: Slot B 3.3-Vaux standby switch inactive 7 Slot B 3VAUX main switch on 1: Slot B 3.3VAux main switch active 0: Slot B 3.3VAux main switch inactive www.ti.com 21 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Test Mode Functions for Address Bit The TPS2341 address pin (ADDR1) provides two functions. The input provides the I2C serial interface with a unique address when two TPS2341 devices share the same address bank and also provides a means of disabling faults. Three different voltage levels are used to define the status of the input signal. Upon pulling the address pin low, the serial interface address bit is set low. The serial interface address bit is set high if the address pin is allowed to float or is driven to one-half the voltage at DIGVCC. Upon pulling ADDR1 to DIGVCC the internal test mode is invoked which masks the overload and undervoltage faults and does not shut down the slots when the thresholds are exceeded. This is intended to be used for board development only to avoid nuisance faults from improperly sized bulk capacitance or excessive switching loads. Caution must be taken to never exceed the maximum dissipation or absolute maximum conditions of the device while the device self-protection is disabled. Table 2. I2C Device Address Decode BIT DEFINITION A0 R/W bit 0: Write data from master to TPS2341 1: Read data from TPS2341 to master A1 Device address bit 1 (LSB) compared with pin ADDR1 A2 0 internally defined A3 0 internally defined A4 0 internally defined A5 0 internally defined A6 1 internally defined A7 0 internally defined Table 3. Test Mode Functions for Adddress Bits 22 BIT VOLTAGE LEVEL (V) ADDRESS FUNCTION TEST MODE FUNCTION < 0.8 Low OFF 0.8 < VA1 < 2.5 High A1 OFF > 2.5 High Mask fault active www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Layout Considerations It is important to use good layout practices regarding device placement and etch routing of the backplane/system board to optimize the performance of the hot plug circuit. Some of the key considerations are listed here: D Decoupling capacitors should be located close to the device. D Any protection devices (e.g. zener clamps) should be located close to the device. D To reduce insertion loss across the hot plug interface, use wide traces for the supply and return current paths. A power plane can be used for the supply return or PWRGND nodes. D Additional copper placed at the land patterns of the sense resistors and pass FETs can significantly reduce the thermal impedance of these devices, reducing temperature rise in the module and improving overall reliability. D Because typical values for current sense resistors can be very low (6 mΩ typical), board trace resistance between elements in the supply current paths becomes significant. To achieve maximum accuracy of the overload thresholds, good Kelvin connections to the resistors should be used for the current sense inputs to the device. The current sense traces should connect symmetrically to the sense resistor land pattern, in close proximity to the element leads, not upstream or downstream from the device. D For best noise immunity, provide separate ground planes for the analog, digital, and power circuitry. These ground planes should tie together at a single point in the system. LOAD CURRENT PATH LOAD CURRENT PATH 3VSA 3VISA 3VSA 3VISA SENSE RESISTOR TPS2341 TPS2341 UDG−02154 Figure 11. Connecting the Sense Resistors These recommended layouts provide force-and-sense (Kelvin) connection to the current sense resistor to minimize circuit board trace resistance. www.ti.com 23 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Thermal Model The TPS2341 is packaged in the HTQFP-48 PowerPadt quad flat-pack package. The PowerPad package is a thermally enhanced standard size device package designed to eliminate the use of bulky heatsinks and slugs traditionally used in thermal packages. This package can be easily mounted using standard printed circuit board (PCB) assembly techniques, and can be removed and replaced using standard repair procedures. The PowerPad package is designed so that the leadframe die pad is exposed on the bottom of the device. This provides an extremely low thermal resistance between the die and the thermal pad. The thermal pad can be soldered directly to the PCB for heatsinking. In addition, through the use of thermal vias, the thermal pad can be directly connected to a power/ground plane or special heat sink structure designed into the PCB. On the TPS2341, the die substrate is internally connected to the −12 V input supply. and therefore the power plane or heatsink connected to the thermal pad on the bottom of the device must also connect to the −12 V input supply (recommended) or float independent of any supply (acceptable). The thermal performance can be modeled by determining the thermal resistance between the die and the ambient environment. Thermal resistances are measures of how effectively an object dissipates heat. Typically, the larger the device, the more surface area available for power dissipation and the lower the object’s thermal resistance. Figure 12 illustrates the thermal path and resistances from the die, TJ through the printed circuit board to the ambient air. Die PD (Watts) Die Junction Temperature TJ θJC Copper Trace Die Case Temperature ÉÉ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎ ÉÉÉÉÉÉÉ ÎÎÎ ÉÉÉ ÎÎÎ ÎÎÎÎÎÎÎÎÎÎ ÎÎÎ ÎÎ ÏÏ ÎÎÎÎ ÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎ ÏÏ ÎÎ ÎÎÎÎ ÎÎ ÎÎÎÎ ÎÎÎÎ ÎÎ ÎÎÎÎ ÎÎ ÎÎÎÎ ÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎÎ TPS2341 48HTQFP PowerPADt Via Thermal Via θCP Solder PCB Pad Temperature TP θPH PCB Heatsink Temperature TH θHA Heatsink/Copper Plane Ambient Air Temperature −12 VIN or Floating TC TA UDG−02156 Figure 12. PowerPADt Thermal Model Technical Brief PowerPADt Thermally Enhanced Package (SLMA002) can be used as a guide to model the TPS2341 thermal resistance. The following example assumes the conditions as described in the technical brief. The TPS2341, mounted to a copper pad with solder on a PCB and two ounce traces, should exhibit a thermal resistance from junction temperature to ambient temperature of 29_C/W. 24 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION Table 4. TPS2341 Continuous Maximum Load Power Consumption (All Drivers On) SUPPLY DRIVER +12 V @ 0.5 A −12 V @ 100 mA +3VAux @ 375 mA RDS(on) (Ω) POWER PER SLOT (W) TOTAL POWER (W) 0.5 0.1 0.2 0.9 0.01 0.02 0.425 0.06 0.12 +12 V @ 3 mA 0.04 0.08 +5 V @1 mA 0.005 +3 V @ 0.5 mA 0.002 −12 V @ 0.25 mA 0.003 0.006 3VSTBY @ 0.2 mA 0.001 DIGVCC @ 0.2 mA 0.001 Total Power Consumption 0.435 T RISE + P TOTAL q JA + (0.435 W) ǒ29 deg CńWǓ (1) = 12.7 _C T J + T A ) T RISE + 50 C ) 12.7 O (2) = 62.7_C This example indicates that with the ambient air at 50°C the TPS2341 junction temperature rises to 63°C which is below the absolute maximum junction temperature of 85°C and ensures the device operates properly and within design specifications. The transient power consumption must also be considered for the conditions during initial ramp-up of the output supplies, however, this varies significantly depending upon output load impedance for each application and each supply. Refer to Technical Briefs PowerPADtThermally Enhanced Package (TI Literature No. SLMA003) and PowerPADt Made Easy (TI Literature No. SLMA004) for more information. www.ti.com 25 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION C14 0.01 µF C12 0.01 µF +5 V Q1 IRF7413 C7 0.1 µF C15 0.01 µF C13 0.01 µF RS1 6 mΩ +5 V OUTB Q2 IRF7413 +3.3 V RS2 6 mΩ +3.3 V OUTB C20 0.1 µF C10 0.1 µF C9 0.1 µF C8 0.1 µF ROC 6.04 kΩ +12 V OUTB C23 0.01 µF C1 0.056 µF +3.3V AUXOUT B −12 V C23 0.01 µF +12 V SWB −12V OUT B GND SCL 13 SCL 2 1 C22 0.01 µF M12VINB 3 M12VIN 4 M12VOB 5 PWRGND1 3VSB 6 5V3VGB 7 3VISB 8 5VISB AGND 9 5VSB 10 OCSET 11 SWB 12 M12VGB 48 14 SDA P12VGB 47 15 ENA P12VOB 46 16 ENB P12VINB 45 17 ADDR1 P12VINA 44 18 IRQ# P12VOA 43 19 AUX_GOODB P12VGA 42 C4 0.027 µF C3 0.015 µF SDA RIRQ# 3.3 kΩ TPS2341 48HTQFP PowerPADt IRQ# AUX_GOODB 20 PGOOD M12VGA 41 21 PGOOD_OUTB M12VINA 40 22 PGOOD_OUTA M12VIN 39 23 DGND M12VOA 38 24 DIGVCC 3VSTBYIN 37 C6 0.015 µF +12V OUT A C5 0.027 µF PGOOD C26 0.01 µF PGOOD_OUTB PGOOD_OUTA SWA V5IN AUX_GOODA 5VSA 5VISAn 3VISA 3VSA V3IN 5V3VGA PWRGND2 3VAUXB 8VAUXA −12V OUT A 25 26 27 28 29 30 31 32 33 34 35 36 C25 0.01 µF 3VSTBYIN +3.3V AUXOUT A C24 0.01 µF SWA AUX_GOODA Q3 IRF7413 RS3 6 mΩ Q4 IRF7413 +5V OUT A RS4 6 mΩ +3.3 V OUT A C11 0.1 µF C17 0.01 µF C16 0.01 µF C2 0.056 µF C18 0.01 µF C19 0.01 µF UDG−02152 Figure 13. Typical Applications Diagram 26 www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 Determining Component Values Load Conditions Table 5. Load Conditions for Determining Component Values SUPPLY DRIVER ILOAD (A) ITRAP (A) CLOAD (µF) SR (V/s) +12 V 0.5 0.94 300 250 (1) +5 V 5 7.0 3000 200 +3.3 V 7.6 10.0 3000 200 −12 V 0.1 0.19 150 200 +3.3 Vaux +3.3 Vaux(1) 0.375 1.0 150 5000 0.02 0.04 150 100 +3.3Vaux turn-on from stand-by power. +3.3-V Supply Overload Trip Point Desired ITRIP (nom) ≅ 10 A R SENSE + V RTRIP (nom) I TRIP (nom) I TRIP(min) + I TRIP(max) + + 52 mV + 0.0052 W NChoose 5 mW, 2% sense resistor 10 A V TRIP (min) R SENSE (max) V TRIP (max) R SENSE (min) + 44 mV + 8.63 A 5.1 mW + 60 mV + 12.2 A 4.9 mW (3) (4) (5) Gate Capacitance IINRUSH ≤ 8.6 A ICLOAD = IINRUSH − ILOAD = 8.6 A − 7.6 A = 1 A from i = C dV/dt for the load capacitance and charge current: ∆T = ∆V (C/i) mF ǒ3000 Ǔ + 9.9 ms 1A + 3.3 V (6) from i = C dV/dt for the gate capacitance and charge current: C = i × ( ∆T/∆V) ǒ Ǔ + 25 mA 9.9 ms using the maximum gate capacitance and charge current 3.3 V (7) = 0.075 µF ∴ choose 0.1 µF, 10% capacitor. The nominal load turn-on time is calculated in equation (8). DT + DV (Cńi) + 3.3 V mF ǒ0.1 Ǔ + 16.5 ms 20 mA SR + 3.3 V + 200 Vńs 16.5 ms (8) (9) www.ti.com 27 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION +5-V Supply Overload Trip Point Desired ITRIP (nom) ≅ 7 A R SENSE + V RTRIP (nom) I TRIP(min) + I TRIP(max) + I TRIP (nom) + 42 mV + 0.006 W NChoose 6 mW, 2% sense resistor. 7A V TRIP (min) R SENSE (max) V TRIP (max) R SENSE (min) + 35 mV + 5.72 A 6.12 mW + 48 mV + 8.16 A 5.88 mW (10) (11) (12) Gate Capacitance IINRUSH ≤ 5.72 A ICLOAD = IINRUSH − ILOAD = 5.72 A − 5 A = 720 mA from the chosen gate capacitance (shared with the 3.3-V MOSFET). I CLOAD + C (DVńDT) + 3000 mF ǒ200VńsǓ + 600 mA (max) (13) IINRUSH = ICLOAD + ILOAD = 600 mA + 5 A = 5.6 A The nominal load turn on time is calculated in equation (14). DT + DV (Cńi) + 5 V 28 mF ǒ0.1 Ǔ + 25 ms 20 mA (14) www.ti.com SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION +12-V Supply Gate Capacitance IINRUSH ≤ 0.79 A from a minimum +12-V overcurrent threshold voltage. ICLOAD = IINRUSH − ILOAD = 0.79 A − 0.5 A = 290 mA from i = C dV/dt for the load capacitance and charge current: ∆T = ∆V (C/i) 300 mF ǒ290 Ǔ + 12.4 ms mA + 12 V (15) from i = C dV/dt for the gate capacitance and charge current: C = i × ( ∆T/∆V) ǒ Ǔ + 14 mA 12.4 ms using the maximum gate capacitance and charge current 12 V (16) = 0.014 µF ∴ choose 0.02 µF, 10% capacitor. The nominal load turn-on time is calculated in equation (17). DT + DV (Cńi) + 12 V mF ǒ0.02 Ǔ + 48 ms 5 mA SR + 12 V + 250 Vńs 48 ms (17) (18) −12-V Supply Gate Capacitance IINRUSH ≤ 150 mA from minimum −12-V overcurrent threshold voltage. ICLOAD = IINRUSH − ILOAD = 150 mA − 100 mA = 50 mA from i = C dV/dt for the load capacitance and charge current: ∆T = ∆V (C/i) mF ǒ150 Ǔ + 36 ms 50 mA + 12 V (19) from i = C dV/dt for the gate capacitance and charge current: C = i × ( ∆T/∆V) ǒ Ǔ + 25 mA 36 ms using the maximum gate capacitance and charge current 12 V (20) = 0.075 µF ∴ choose 0.1 µF, 10% capacitor. The nominal load turn-on time is calculated in equation (21). DT + DV (Cńi) + 12 V mF ǒ0.1 Ǔ + 60 ms 20 mA (21) SR + 12 V + 200 Vńs 60 ms (22) www.ti.com 29 SLUS513A − MAY 2003 − REVISED JULY 2004 APPLICATION INFORMATION +3.3-V Auxiliary Supply Inrush Current IINRUSH = C dV/dt + ILOAD for the load capacitance + 150 mF V Ǔ ) 375 mA + 1125 mA ǒ15ms (23) The nominal load turn-on time is calculated in equation (24). T + DV + 3.3 V + 660 ms dV 5V 1 ms dt ǒ Ǔ ǒ Ǔ (24) Standby Inrush Current IINRUSH = C dV/dt + ILOAD for the load capacitance ǒ Ǔ + 150 mF 0.1 V ) 20 mA + 35 mA 1 ms (25) The nominal load turn-on time is calculated in equation (26). T + DV + 3.3 V + 33 ms dV 0.1 V 1 ms dt ǒ Ǔ ǒ Ǔ (26) Thermal Shutdown Under normal operating consitions, the power dissipation in the TS2341 is low enough that the junction temperature (TJ) is not more than 15°C above air temperature (TA). However, in the case of a load that exceeds PCI specifications (but remains under the TPS2341 overcurrent threshold) power dissipation can be higher. To prevent any damage from an out-of-specification load or severe rise in ambient temperature, the TPS2341 contains two independent thermal shutdown circuits, one for each main supply slot. The highest power dissipation in the TPS2341 is from the 12-V power FET so that TPS2341 temperature sense elements are integrated closely with these FETs. These sensors indicate when the temperature at these transistors exceeds approximately 150°C, due either to average device power dissipation, 12-V power FET power dissipation, or a combination of both. When excessive junction temperature is detected in one slot, that slot’s fault latch is set and remains set until the junction temperature drops by approximately 10°C and the slot is then restarted through the serial interface or supply dropping. The other slot is not affected by this event. Digital Circuits The I2C serial interface is available once DIGVCC is stable. However, data in the main power registers is accurate only if the main supply voltages are within specification. Data in the AUXFAULTx register is accurate only if the 3VSTBYIN supply voltage is within specifications. 30 www.ti.com PACKAGE OPTION ADDENDUM www.ti.com 4-Mar-2005 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty TPS2341PHP ACTIVE HTQFP PHP 48 250 None CU NIPDAU Level-3-220C-168 HR TPS2341PHPR ACTIVE HTQFP PHP 48 1000 None CU NIPDAU Level-3-220C-168 HR Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - May not be currently available - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. None: Not yet available Lead (Pb-Free). Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Green (RoHS & no Sb/Br): TI defines "Green" to mean "Pb-Free" and in addition, uses package materials that do not contain halogens, including bromine (Br) or antimony (Sb) above 0.1% of total product weight. (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDECindustry standard classifications, and peak solder temperature. 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