TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 PRECISION ADJUSTABLE CURRENT LIMITED POWER DISTRIBUTION SWITCH WITH 4.5V TO 18V INPUT VOLTAGE, 3A OUTPUT CURRENT SYNCHRONOUS BUCK REGULATOR Check for Samples: TPS65281, TPS65281-1 FEATURES 1 INTEGRATED POWER DISTRIBUTION SWITCH • • • • • • • • Operating Input Voltage Range: 2.5 V to 6.5 V Adjustable Current Limit: 75 mA - 2.7 A (typical) ±6% Current-Limit Accuracy at 1.7 A (typical) Over Current Latch-Off Protection (TPS65281) and Over Current Auto-Recovery (TPS65281-1) Reverse Input-Output Voltage Protection Built-In Soft-Start Integrated Back-to-Back Power MOSFETs With 100-mΩ On-Resistance Over Temperature Protection xxx xxx xxx xxx xxx xxx xxx xxx xxx • • • • • • • • INTEGRATED BUCK CONVERTER Wide Input Voltage Range: 4.5 V to 18 V Maximum Continuous 3-A Output Current Feedback Reference Voltage: 0.8 V ±1 % Adjustable 300-kHz to 1.4-MHz Switching Frequency Adjustable Soft Start and Tracking With Built-In 1-ms Internal Soft-Start Time Cycle-by-Cycle Current Limit Output Over-voltage Protection 16-Lead QFN (RGV) 4-mm x 4-mm Package APPLICATIONS • • • • • USB Ports and Hubs Digital TV Set-Top Boxes VOIP Phones Tablet PC DESCRIPTION/ORDERING INFORMATION The TPS65281/TPS65281-1 incorporates an N-channel back-to-back power MOSFET switch and a monolithic buck converter. The device is intended to provide a total power distribution solution for digital TV, set-top boxes, tablet PC and VOIP phones etc applications, where precision current limiting is required or heavy capacitive load or short circuit are encountered. A 100-mΩ independent power distribution switch limits the output current to a programmable current limit threshold between typical 75 mA and 2.7 A by using an external resistor. The current limit accauracy as tight as ±6% can be achieved at higher current limit setting. TPS65281 provides circuit breaker functionality by latching off the power switch during over-current or reverse-voltage situations. TPS65281-1 limits output current to a safe level by using a constant current mode when the output load exceeds the current limit threshold. An internal reverse-voltage comparator disables the power switch when the output voltage is driven higher than the input to protect the device on the input side of the switch in normal operation. The nFAULT output asserts low under over-current and reverse-voltage conditions. Back-to-back power MOSFETs structure prevents the reverse current injection from an active load at output port during shutdown of power switch. 1 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2012, Texas Instruments Incorporated TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com The buck DC/DC converter integrates power MOSFETs for optimized power efficiency and reduced external component count. A wide 4.5-V to 18-V input supply range to buck encompasses most intermediate bus voltages operating off 5-V, 9-V, 12-V or 15-V power bus. Constant frequency peak current mode control simplifies the compensation and provides fast transient response. The buck can be precisely sequenced and ramp up in order to align with other rails in the system with the soft-start pin. With SS pin floating, the built-in 1ms soft-start time prevents in-rush current. Cycle-by-cycle over current protection and hiccup operation limit MOSFET power dissipation in short circuit or over loading fault conditions. The switching frequency of the converter can be programmed from 300 kHz to 1.4 MHz with an external resistor at ROSC pin. With ROSC pin connecting to V7V pin, floating, or grounding, a default fixed switching frequency can be selected to reduce an external resistor. The TPS65281/TPS65281-1 is available in a 16-lead thermally enhanced QFN (RGV) 4-mm x 4-mm thin package. ORDERING INFORMATION (1) TA PACKAGE (2) ORDERABLE PART NUMBER TPS65281RGVR –40°C to 85°C 16-Pin QFN (RGV) TPS65281RGVT TPS65281-1RGVR TPS65281-1RGVT (1) (2) 2 TOP-SIDE MARKING TPS65281 TPS65281-1 For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI web site at www.ti.com. Package drawings, thermal data, and symbolization are available at www.ti.com/packaging. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. TYPICAL APPLICATION C7 47nF L1 4.7uH +5V C6 4.7nF R3 40.2kΩ C5 22uF 13 14 9 10 SW_IN C4 10uF 7 AGND VIN USB Data 8 USB Port TPS65281 EN EN_SW 6 USB fault signal 5 RLIM USB control signal 4 1 2 SS 16 nFAULT ROSC C2 1uF V7V 3 15 Enable R5 100kΩ SW_OUT PGND COMP VIN 6V~18V C1 10uF FB BST LX 11 12 R4 7.68kΩ C3 4.7nF R2 20kΩ R1 10kΩ Figure 1. 12-V Power Bus L1 4.7uH C7 47nF +3.3V C6 4.7nF R3 40.2kΩ C5 22uF 13 9 SW_IN 11 10 FB R5 100kΩ SW_OUT 8 AGND 7 C1 10uF 14 VIN USB Data C4 10uF USB Port TPS65281 EN_SW 5 USB fault signal USB control signal 4 1 C3 4.7nF 6 RLIM EN ROSC nFAULT 3 16 V7V SS C2 1uF COMP 15 Enable PGND 2 VIN 5V LX BST 12 R4 12.7kΩ R2 20kΩ R1 10kΩ Figure 2. 5-V Power Bus Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 3 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com FUNCTION BLOCK DIAGRAM V7V 15 14 LDO 5V VIN Voltage Reference Current Bias Preregulator HS current sensing 1 .25 M CS 12 1 .25 M EN BST 16 enable buffer HS driver Current Sensing (0 .1 V/A) COMP FB 11 Buck Controller 2 PWM comparator LX V7V slope comp 10 LS driver 0 .8 V SS 1 error amplifer CS LS current sensing V7 V 10 uA ROSC SW_IN 3 1 ms Internal Soft Start 13 Oscillotor BUCK POWER SWITCH 9 PGND 7 AGND UVLO POR reverse voltage comparator 8 CS SW_OUT current sensing Charge Pump 1. 25M 4 ms Degl . Time Driver Current Limit 1. 25M EN_SW 5 4 6 RLIM nFAULT 10ms Degl . Time enable buffer 4 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 PIN OUT RGV PACKAGE (TOP VIEW) BST LX FB SW_IN 12 11 10 9 PGND 13 8 SW_OUT VIN 14 7 AGND Thermal Pad 1 2 3 4 RLIM 5 EN_SW ROSC EN 16 COMP 6 nFAULT SS V7V 15 Exposed thermal pad must be soldered to PCB for optimal thermal performance. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 5 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com TERMINAL FUNCTIONS NAME NO. DESCRIPTION SS 1 Soft-start and tracking input for buck converter. An internal 5-µA current source is connected to this pin. An external soft-start can be programmed by connecting a capacitor between this pin and ground. Leave the pin floating to have a default 1-ms of soft-start time. This pin allows the start-up of buck output to track an external voltage using an external resistor divider at this pin. COMP 2 Error amplifier output and Loop compensation pin for buck. Connect a series RC to compensate the control loop of buck converter. ROSC 3 Oscillator clock frequency control pin. Connect the pin to ground for a fixed 300-kHz switching frequency. Connect the pin to V7V or float the pin for a fixed 600-kHz switching frequency. Other switch frequencies between 300 kHz to 1.4 MHz can be programmed using a resistor connected from this pin to ground. A internal 10-µA pull-up current develops a voltage to be used in oscillator. Directly applying the voltage to the ROSC pin can linearly adjust the switching frequency. RLIM 4 Power switch current limit control pin. An external resistor used to set current limit threshold of power switch. Recommended 15 kΩ ≤ RLIM ≤ 232 kΩ. EN_SW 5 Enable pin of power switch. Logic high turns on power switch. Forcing the pin below 0.4 V shuts down power switch. Not recommend floating this pin, though there is a 2.5-MΩ pull-up resistor connecting this pin. nFAULT 6 Active low open drain output, asserted in conditions when over-current happens for more than 10 ms or reverse-voltage of power switch for more than 4 ms. AGND 7 Analog ground common to buck controller and power switch controller. It must be routed separately from high current power grounds to the (-) terminal of bypass capacitor of internal V7V LDO output. SW_OUT 8 Power switch output pin SW_IN 9 Power switch input pin FB 10 Feedback sensing pin for buck output voltage. Connect this pin to the resistor divider of buck output. The feedback reference voltage is 0.8 V±1%. LX 11 Switching node connection to the internal power FETs, inductor and bootstrap capacitor for buck converter. The voltage swing at this pin is from a diode voltage below the ground up to VIN voltage. BST 12 Bootstrapped supply to the high side floating gate driver in buck converter. Connect a capacitor (recommend 47 nF) from BST pin to LX pin. PGND 13 Power ground connection. Connect PGND pin as close as practical to the (-) terminal of input ceramic capacitor. VIN 14 Input power supply for buck. Connect VIN pin as close as practical to the (+) terminal of a input ceramic capacitor (suggest 10 µF). V7V 15 Internal LDO output. The internal gate driver for low side power MOSFET and control cirduits are powered from this voltage. Decouple this pin to power ground with a minimum 1-µF ceramic capacitor. The output voltage level of LDO is regulated to typical 6.3 V for optimal conduction on-resistances of internal power MOSFETs. EN 16 Enable for buck converter and the device. Logic high enables buck converter and bias supply to power switches. Forcing the pin below 0.4 V shuts down the entire device, reducing the quiescent current to approximate typical 7 µA. Not recommend floating this pin. The device can be automatically started up with connecting EN pin to VIN though a 10 kΩ resistor. Power PAD 6 Exposed pad beneath the IC. Connect to the ground. Always solder power pad to the board, and have as many thermal vias as possible on the PCB to enhance power dissipation. There is no ground or any other electric signal downbonded to the pad inside the IC package. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 ABSOLUTE MAXIMUM RATINGS (1) over operating free-air temperature range (unless otherwise noted) VIN –0.3 to 18 V LX (Maximum withstand voltage transient < 20ns) –1.0 to 18 V BST referenced to LX pin –0.3 to 7 V SW_IN, SW_OUT –0.3 to 7 V EN, EN_SW, nFAULT, V7V, ROSC, RLIM –0.3 to 7 V SS, COMP, FB –0.3 to 3.6 V AGND, PGND –0.3 to 0.3 V TJ Operating virtual junction temperature range –40 to 125 °C TSTG Storage temperature range –55 to 150 °C (1) 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. RECOMMENDED OPERATING CONDITIONS over operating free-air temperature range (unless otherwise noted) MIN NOM MAX UNIT VIN Input operating voltage 4.5 18 V TA Ambient temperature –40 85 °C ELECTROSTATIC DISCHARGE (ESD) PROTECTION (1) MIN Human body model (HBM) MAX UNIT 4000 V Charge device model (CDM) 500 V Machine model (MM) 200 V (1) SW_OUT pin human body model (HBM) ESD protection rating 4 kV, and machine model (MM) rating 200V. THERMAL INFORMATION TPS65281/TPS65281-1 THERMAL METRIC (1) RGV UNITS 16 PINS θJA Junction-to-ambient thermal resistance (2) 36.5 θJCtop Junction-to-case (top) thermal resistance (3) 42.7 θJB Junction-to-board thermal resistance (4) 14.7 ψJT Junction-to-top characterization parameter (5) 0.5 ψJB Junction-to-board characterization parameter (6) 14.8 θJCbot Junction-to-case (bottom) thermal resistance (7) 3.3 (1) (2) (3) (4) (5) (6) (7) °C/W For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953. The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as specified in JESD51-7, in an environment described in JESD51-2a. The junction-to-case (top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific JEDECstandard test exists, but a close description can be found in the ANSI SEMI standard G30-88. The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB temperature, as described in JESD51-8. The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted from the simulation data for obtaining θJA, using a procedure described in JESD51-2a (sections 6 and 7). The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted from the simulation data for obtaining θJA , using a procedure described in JESD51-2a (sections 6 and 7). The junction-to-case (bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88. Spacer Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 7 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com ELECTRICAL CHARACTERISTICS TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) PARAMETER TEST CONDITIONS MIN TYP MAX UNIT INPUT SUPPLY VIN Input voltage range IDDSDN Shutdown supply current EN = EN_SW = low 4.5 IDDQ_NSW Switching quiescent current with no load at DCDC output EN = high, EN_SW = low, FB = 6 V With Buck not switching 0.8 mA IDDQ_SW Switching quiescent current with no load at DCDC output, Buck switching EN = high, EN_SW = low, FB = 5 V With Buck switching 13 mA UVLO VIN under voltage lockout 7 V 20 µA Rising VIN 4.10 4.30 4.50 Falling VIN 3.85 4.10 4.35 V 6.47 V 1400 kHz Hysteresis V7V 18 0.2 Internal biasing supply V7V load current = 0 A, VIN = 12 V 6.17 Switching frequency range Set by external resistor ROSC 300 6.32 OSCILLATOR fSW_BK fSW Programmable frequency ROSC = 51 kΩ 510 ROSC = 140 kΩ 1400 ROSC floating or connected to V7V 600 ROSC connected to ground 270 kHz BUCK CONVERTER VCOMP = 1.2 V, TJ = 25°C 0.792 0.8 0.808 VCOMP = 1.2 V, TJ = -40°C to 125°C 0.784 0.8 0.816 VFB Feedback voltage VLINEREG Line regulation - DC IOUT = 2 A 0.5 %/V VLOADREG Load regulation - DC IOUT = 0.3 A - 2.7 A 0.5 %/A Gm_EA Error amplifier trans-conductance (1) -2 µA < ICOMP < 2 µA 500 µs Gm_SRC COMP voltage to inductor current Gm (1) ILX = 0.5 A 20 A/V VENH EN high level input voltage VENL EN low level input voltage ISS Soft-start charging current tSS_INT Internal soft-start time ILIMIT Buck peak inductor current limit Rdson_HS On resistance of high side FET in buck Rdson_LS On resistance of low side FET in buck 2 V 0.4 4.7 SS pin open 0.5 V 1 V µA 1.5 ms 4 A V7V = 6.3 V, with bond wire resistance 90 mΩ VIN = 12 V, with bond wire resistance 70 mΩ POWER DISTRIBUTION SWITCH VSW_IN Power switch input voltage range VUVLO_SW RDSON_SW 2.5 Input under-voltage lock out Power switch NDMOS on-resistance tD_on Turn-on delay time from EN_SW turns high tD_off Turn-off delay time from EN_SW turns low tr Output rise time tf Output fall time IOS Current limit threshold (maximum DC current delivered to load) and short circuit current, SW_OUT connect to ground tIOS Response time to short circuit (1) 8 6 V VSW_IN rising 2.15 2.25 2.35 V VSW_IN falling 2.08 2.13 2.28 Hysteresis 120 VSW_IN = 5 V, ISW_OUT = 0.5 A, including bond wire resistance 100 VSW_IN = 2.5 V, ISW_OUT = 0.5 A, includes bond wire resistance 100 mΩ VSW_IN = 5 V, CL = 22 µF, RL = 100 Ω (see Figure 3) 1.4 2 ms 1.2 2 ms 1.3 1.5 ms 5 10 ms RLIM = 14.3 kΩ 1.65 1.76 1.87 RLIM = 20 kΩ 1.18 1.26 1.34 RLIM = 50 kΩ 0.47 0.5 0.53 RLIM shorted to SW_IN or open 1.12 1.2 1.28 VSW_IN = 5 V V mV 2 A us Specified by design. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 ELECTRICAL CHARACTERISTICS (continued) TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) PARAMETER TEST CONDITIONS tDEGLITCH(OCP) Switch over current fault deglitch Fault assertion or de-assertion due to overcurrent condition VL_nFAULT nFAULT pin output low voltage InFAULT = 1 mA VEN_SWH EN_SW high level input voltage EN_SW high level input voltage VEN_SWL EN_SW high level input voltage EN_SW low level input voltage RDIS Discharge resistance VSW_IN = 5 V, EN_SW = 0 V MIN TYP MAX 7 10 13 80 UNIT ms mV 2 V 0.4 100 V Ω THERMAL SHUTDOWN TTRIP_BUCK Thermal protection trip point THYST_BUCK Thermal protection hysteresis Rising temperature TTRIP_SW Power switch thermal protection trip point in current limit (TPS65281-1 only) THYST_SW 160 Rising temperature Hysteresis 50% 50% tD_on tr tD_off tf °C 20 °C 145 °C 10 °C VEN_SWx 90% VOUT_SWx 10% 90% 10% Figure 3. Power Switches Test Circuit and Voltage Waveforms Figure 4. Response Time to Short Circuit Waveform Figure 5. Output Voltage vs Current Limit Threshold Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 9 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com TYPICAL CHARACTERISTICS TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) Vout_Buck Vout_Buck EN EN nFAULT SW_OUT nFAULT SW_OUT Figure 6. Power Up by EN Pin Figure 7. Power Down by EN Pin Vout_Buck Vout_Buck EN EN nFAULT nFAULT SW_OUT SW_OUT Figure 8. Power Up by VIN (EN pin connects to VIN with a 10-kΩ resistor) Figure 9. Power Down by VIN Iout _Buck Vout_Buck Vout_Buck LX Figure 10. VOUT Ripple and LX 10 Submit Documentation Feedback Figure 11. Load Transient Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 TYPICAL CHARACTERISTICS (continued) TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) 5.1 5.08 Output Voltage (V) 5.06 5.04 5.02 5 4.98 4.96 4.94 4.92 4.9 5 7 9 11 13 15 17 19 Input Voltage (V) Figure 12. Buck Load Regulation Figure 13. Buck Line Regulation 2 1.8 1.6 Frequency (MHz) 1.4 1.2 1 0.8 0.6 0.4 0.2 0 0.00 50.00 100.00 150.00 200.00 250.00 Rosc (kW) Figure 14. Oscillator Frequency vs Rosc Voltage Figure 15. Buck Efficiency Vout_Buck LX SS IL IL Figure 16. Buck Hiccup Response to Hard-Short Circuit Figure 17. Zoom In Buck Output Hard Short Response Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 11 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com TYPICAL CHARACTERISTICS (continued) TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) Vout_Buck Vout_Buck EN_SW EN_SW nFAULT nFAULT SW_OUT SW_OUT Figure 18. Power Switch Turn On Delay and Rise Time Figure 19. Power Switch Turn Off Delay and Fall Time Vout_Buck ISW _OUT nFAULT EN_SW SW_OUT nFAULT ISW_OUT SW_OUT Figure 20. Power Switch Hard Short (Latch Off Version) Figure 21. Power Switch Starts up to Short Circuit (Latch Off Version) EN_SW nFAULT ISW _OUT Vout_Buck ISW _OUT SW_OUT nFAULT SW_OUT Figure 22. Power Switch No Load to 2-Ω Resistor (Latch Off Version) 12 Figure 23. Power Switch Response Time (TIOS) to Output Hard Short Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 TYPICAL CHARACTERISTICS (continued) TJ = 25°C, VIN = 12 V, fSW = 600 kHz, RnFAULT = 100 kΩ (unless otherwise noted) Vout_Buck EN nFAULT nFAULT SW_OUT SW_OUT ISW_OUT ISW_OUT Figure 24. Power Switch Hard Short (Auto-Recovery Version) Figure 25. Power Switch Starts Up to Short Circuit (Auto-Recovery Version) ISW _OUT Vout_Buck nFAULT SW_OUT SW_IN Vsw_out Isw_out nFAULT Figure 26. Power Switch Recover from Over Current (Auto-Recovery Version) Figure 27. Power Switch Reverse Voltage Protection Response Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 13 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com OVERVIEW TPS65281/TPS65281-1 PMIC integrates a current-limited, power distribution switch using N-channel MOSFETs for applications where short circuits or heavy capacitive loads will be encountered and provide a precision current limit protection. Additional device features include over termperature protection and reverse-voltage protection. The device incorporates an internal charge pump and gate drive circuitry necessary to drive the N-channel MOSFET. The charge pump supplies power to the driver circuit and provide the necessary voltage to pull the gate of the MOSFET above the source. The charge pump operates from input voltage of power switch as low as 2.5 V and requires little supply current. The driver incorporates circuitry that controls the rise and fall times of output voltage to limit large current and voltage surges and provides built-in soft-start functionality. TPS65281-1 device limits output current to a safe level by using a constant current mode when the output load exceeds the current limit threshold. TPS65281 device lacthes off when the load exceeds the current limit threshold. The device asserts the nFAULT signal during over current or reverse voltage faulty condition. TPS65281/TPS65281-1 PMIC also integrates a synchronous step-down converter with a fixed 5-V output voltage to provide the power for power switches in the USB ports. The synchronous buck converter incorporates a 90-mΩ high side power MOSFET and 70-mΩ low side power MOSFET to achieve high efficiency power conversion. The converter supports an input voltage range from 4.5 V to 18 V. The converter operates in continuous conduction mode with peak current mode control for simplified loop compensation. The switching clock frequency can be programmed from 300 kHz to 1.4 MHz from the ROSC pin connection. The peak inductor current limit threshold is internally set at 4 A typical. The device builds in an internal 1-ms soft-start time to reduce inrush current during power-up. POWER SWITCH DETAILED DESCRIPTION Over Current Condition The TPS65281/TPS65281-1 responds to over-current conditions on power switches by limiting the output currents to the IOCP_SW level, which is fixed internally. The load current is less than the current-limit threshold and the device does not limit current. During normal operation the N-channel MOSFET is fully enhanced, and VSW_OUT = VSW_IN - (ISW_OUT x Rdson_SW). The voltage drop across the MOSFET is relatively small compared to VSW_IN, and VSW_OUT ≈ VSW_IN. When an over current condition is detected, the device maintains a constant output current and reduces the output voltage accordingly. During current-limit operation, the N-channel MOSFET is no longer fully enhanced and the resistance of the device increases. This allows the device to effectively regulate the current to the current-limit threshold. The effect of increasing the resistance of the MOSFET is that the voltage drop across the device is no longer negligible (VSW_IN ≠ VSW_OUT), and VSW_OUT decreases. The amount that VSW_OUT decreases is proportional to the magnitude of the overload condition. The expected VSW_OUT can be calculated by IOS × RLOAD, where IOS is the current-limit threshold and RLOAD is the magnitude of the overload condition. Three possible overload conditions can occur as summarized in Table 1. Table 1. Possible Overload Conditions CONDITIONS BEHAVIORS Short circuit or partial short circuit present when the device is powered up or enabled The output voltage is held near zero potential with respect to ground and the TPS65281 ramps output current to IOCP_SW. The TPS65281-1 will limit the current to IOS until the overload condition is removed or the device begins to thermal cycle. The TPS65281 limits the current to IOS until the overload condition is removed or the internal deglitch time (10 ms typical) is reached and the device is turned off. The device will remain off until power is cycled or the device enable is toggled. Gradually increasing load (<100 A/s) from normal operating current to IOS The current rises until current limit. Once the threshold has been reached, the device switches into its current limiting at IOS. The TPS65281-1 will limit the current to IOS until the overload condition is removed or the device begins to thermal cycle. The TPS65281 limits the current to IOS until the overload condition is removed or the internal deglitch time (10 ms typical) is reached and the device is turned off. The device will remain off until power is cycled or the device enable is toggled. Short circuit, partial short circuit or fast transient overload occurs while the device is enabled and powered on The device responds to the over-current condition within time tIOS (see Figure 5).The current sensing amplifier is overdriven during this time, and needs time for loop response. Once tIOS has passed, the current sensing amplifier recovers and limits the current to IOS. The TPS65281-1 will limit the current to IOS until the overload condition is removed or the device begins to thermal cycle. The TPS65281 limits the current to IOS until the overload condition is removed or the internal deglitch time (10 ms typical) is reached and the device is turned off. The device will remain off until power is cycled or the device enable is toggled. 14 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 The TPS65281-1 thermal cycles if an overload condition is present long enough to activate thermal limiting in any of the above cases. The power switch turns off when the junction temperature exceeds 145°C (typical) while in current limit. The device remains off until the junction temperature cools 10°C (typical) and then restarts. The TPS65281-1 cycles on and off until the overload is removed. Reverse Current and Voltage Protection A power switch in the TPS65281/TPS65281-1 incorporates two back-to-back N-channel power MOSFETs as to prevent the reverse current flowing back the input through body diode of MOSFET when power switches are off. The reverse-voltage protection feature turns off the N-channel MOSFET whenever the output voltage exceeds the input voltage by 135 mV (typical) for 4 ms (typical). This prevents damage to devices on the input side of the TPS65281/TPS65281-1 by preventing significant current from sinking into the input capacitance of power switch or buck output capacitance. The TPS65281-1 device allows the N-channel MOSFET to turn on once the output voltage goes below the input voltage for the same 4-ms deglitch time. The TPS65281 device keeps the power switch turned off even if the reverse-voltage condition is removed and do not allow the N-channel MOSFET to turn on until power is cycled or the device enable is toggled. The reverse-voltage comparator also asserts the nFAULT output (active-low) after 4 ms. nFAULT Response The nFAULT open-drain output is asserted (active low) during an over current, over temperature or reversevoltage condition. The TPS65281-1 asserts the nFAULT signal until the fault condition is removed and the device resumes normal operation. The TPS65281 asserts the nFAULT signal during a fault condition and remains asserted while the part is latched-off. The nFAULT signal is de-asserted once device power is cycled or the enable is toggled and the device resumes normal operation. The TPS65281/TPS65281-1 is designed to eliminate false nFAULT reporting by using an internal delay deglitch circuit for over current (10 ms typical) and reverse-voltage (4 ms typical) conditions without the need for external circuitry. This ensures that nFAULT is not accidentally asserted due to normal operation such as starting into a heavy capacitive load. Deglitching circuitry delays entering and leaving fault conditions. Over temperature conditions are not deglitched and assert the FAULT signal immediately. Under-Voltage Lockup (UVLO) The under-voltage lockout (UVLO) circuit disables the power switch until the input voltage reaches the UVLO turn-on threshold. Built-in hysteresis prevents unwanted on/off cycling due to input voltage drop from large current surges. Enable and Output Discharge The logic enable EN_SW controls the power switch, bias for the charge pump, driver, and other circuits. The supply current from power switch driver is reduced to less than 1 µA when a logic low is present on EN_SW. A logic high input on EN_SW enables the driver, control circuits, and power switch. There is 2.5-MΩ pull-up resistor connecting to EN_SW pin. After power switch is turned on, the resistor is switched to 1.25 MΩ. The enable input is compatible with both TTL and CMOS logic levels. Floating the pin is not recommended. When enable is de-asserted, the discharge function is active. The output capacitor of power switch is discharged through an internal NMOS that has a discharge resistance of 100 Ω. Hence, the output voltage drops down to zero. The time taken for discharge is dependent on the RC time constant of the resistance and the output capacitor. Power Switch Input and Output Capacitance Input and output capacitance improves the performance of the device. The actual capacitance should be optimized for the particular application. The output capacitor of buck should be placed as close to the SW_IN and AGND if the integrated buck supply the power to power switch. For the application which input to power switch is from another supply, a 0.1-µF or greater ceramic bypass capacitor between SW_IN and AGND is recommended as close to the device as possible for local noise de-coupling. This precaution reduces ringing on the input due to power-supply transients. Additional capacitance may be needed on the input to reduce voltage overshoot from exceeding the absolute maximum voltage of the device during heavy transient conditions. This is especially important during bench testing when long, inductive cables are used to connect the input of power switches in the evaluation board to the bench power-supply. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 15 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com Placing a high-value electrolytic capacitor on the output pin is recommended when large transient currents are expected on the output. Programming the Current-Limit Threshold The over-current threshold is user programmable via an external resistor. The TPS65281/TPS65281-1 uses an internal regulation loop to provide a regulated voltage on the RLIM pin. The current-limit threshold is proportional to the current sourced out of RLIM. The recommended 1% resistor range for RLIM is 5 kΩ ≤ RLIM ≤232 kΩ to ensure stability of the internal regulation loop. Many applications require that the minimum current limit is above a certain current level or that the maximum current limit is below a certain current level, so it is important to consider the tolerance of the over-current threshold when selecting a value for RLIM. The following equations and Figure 28 can be used to calculate the resulting over-current threshold for a given external resistor value (RLIM). The traces routing the RLIM resistor to the TPS65281/TPS65281-1 should be as short as possible to reduce parasitic effects on the current-limit accuracy. RLIM can be selected to provide a current-limit threshold that occurs 1) above a minimum load current or 2) below a maximum load current. Current-Limit Threshold Equations (IOS): æ 22980 × V ö Iosmax = ç ÷ (mA) è RLIM0.94 × KW ø (1) æ 23950 × V ö Iosnom = ç ÷ (mA) è RLIM0.977 × KW ø æ 25230 × V ö Iosmin = ç ÷ (mA) è RLIM1.016 × KW ø (2) (3) Where 15 kΩ ≤ RLIM ≤ 232 kΩ. While the maximum recommended value of RLIM is 232 kΩ, there is one additional configuration that allows for a lower current-limit threshold. The RLIM pin may be connected directly to SW_IN to provide a 1.2 A (typ) currentlimit threshold. Additional low-ESR ceramic capacitance may be necessary from SW_IN to AGND in this configuration to prevent unwanted noise from coupling into the sensitive RLIM circuitry. 60 Current Limit Resistor (kΩ) 50 40 30 20 10 0 0 0.5 1 1.5 2 2.5 3 3.5 4 Current Limit Threshold (A) Figure 28. Current Limit Threshold (IOS) vs Current Limit Resistor (RLIM) 16 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 Constant-Current vs. Latch-Off Operation and Impact on Output Voltage Both the constant-current device (TPS65281-1) and latch-off device (TPS65281) operate identically during normal operation, i.e. the load current is less than the current-limit threshold and the devices are not limiting current. During normal operation the N-channel MOSFET is fully enhanced, and VSW_OUT = VSWIN - (ISW_OUT x rDS(on)). The voltage drop across the MOSFET is relatively small compared to VSW_IN, and VSW_OUT ≈ VSW_IN. Both the constant-current device (TPS65281-1) and latch-off device (TPS65281) operate identically during the initial onset of an over-current event. Both devices limit current to the programmed current-limit threshold set by RLIM by operating the N-channel MOSFET in the linear mode. During current-limit operation, the N-channel MOSFET is no longer fully-enhanced and the resistance of the device increases. This allows the device to effectively regulate the current to the current-limit threshold. The effect of increasing the resistance of the MOSFET is that the voltage drop across the device is no longer negligible (VSW_IN ≠ VSW_OUT), and VSW_OUT decreases. The amount that VSW_OUT decreases is proportional to the magnitude of the overload condition. The expected VSW_OUT can be calculated by IOCP_SW × RLOAD, where IOCP_SW is the current-limit threshold and RLOAD is the magnitude of the overload condition. For example, if IOCP_SW is programmed to 1 A and a 1-Ω overload condition is applied, the resulting VOUT is 1 V. While both the constant-current device (TPS65281-1) and latch-off device (TPS65281) operate identically during the initial onset of an overcurrent event, they behave differently if the overcurrent event lasts longer than the internal delay deglitch circuit (10 ms typical). The constant-current device (TPS65281-1) asserts the FAULT flag after the deglitch period and continues to regulate the current to the current-limit threshold indefinitely. In practical circuits, the power dissipation in the package will increase the die temperature above the overtemperature shutdown threshold (145°C typical), and the device will turn off until the die temperature decreases by the hysteresis of the thermal shutdown circuit (10°C typical). The device will turn on and continue to thermal cycle until the overload condition is removed. The constant-current devices resume normal operation once the overload condition is removed. The latch-off device (TPS65281) asserts the FAULT flag after the deglitch period and immediately turns off the device. The device remains off regardless of whether the overload condition is removed from the output. The latch-off device remains off and do not resume normal operation until the surrounding system either toggles the enable or cycles power to the device. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 17 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com UNIVERSAL SERIAL BUS (USB) POWER-DISTRIBUTION REQUIREMENTS One application for this device is for current limiting in universal serial bus (USB) applications. The original USB interface was a 12-Mb/s or 1.5-Mb/s, multiplexed serial bus designed for low-to-medium bandwidth PC peripherals (e.g., keyboards, printers, scanners, and mice). As the demand for more bandwidth increased, the USB 2.0 standard was introduced increasing the maximum data rate to 480-Mb/s. The four-wire USB interface is conceived for dynamic attach-detach (hot plug-unplug) of peripherals. Two lines are provided for differential data, and two lines are provided for 5-V power distribution. USB data is a 3.3-V level signal, but power is distributed at 5 V to allow for voltage drops in cases where power is distributed through more than one hub across long cables. Each function must provide its own regulated 3.3 V from the 5-V input or its own internal power supply. The USB specification classifies two different classes of devices depending on its maximum current draw. A device classified as low-power can draw up to 100 mA as defined by the standard. A device classified as high-power can draw up to 500 mA. It is important that the minimum current-limit threshold of the current-limiting power-switch exceed the maximum current-limit draw of the intended application. The latest USB standard should always be referenced when considering the currentlimit threshold. The USB specification defines two types of devices as hubs and functions. A USB hub is a device that contains multiple ports for different USB devices to connect and can be self-powered (SPH) or bus-powered (BPH). A function is a USB device that is able to transmit or receive data or control information over the bus. A USB function can be embedded in a USB hub. A USB function can be one of three types included in the list below. • Low-power, bus-powered function • High-power, bus-powered function • Self-powered function SPHs and BPHs distribute data and power to downstream functions. The TPS65281 has higher current capability than required for a single USB port allowing it to power multiple downstream ports. Self-Powered and Bus-Powered HUBs A SPH has a local power supply that powers embedded functions and downstream ports. This power supply must provide between 4.75 V and 5.25 V to downstream facing devices under full-load and no-load conditions. SPHs are required to have current-limit protection and must report over-current conditions to the USB controller. Typical SPHs are desktop PCs, monitors, printers, and stand-alone hubs. A BPH obtains all power from an upstream port and often contains an embedded function. It must power up with less than 100 mA. The BPH usually has one embedded function, and power is always available to the controller of the hub. If the embedded function and hub require more than 100 mA on power up, the power to the embedded function may need to be kept off until enumeration is completed. This is accomplished by removing power or by shutting off the clock to the embedded function. Power switching the embedded function is not necessary if the aggregate power draw for the function and controller is less than 100 mA. The total current drawn by the bus-powered device is the sum of the current to the controller, the embedded function, and the downstream ports, and it is limited to 500 mA from an upstream port. Low-Power Bus-Powered and High-Power Bus-Powered Functions Both low-power and high-power bus-powered functions obtain all power from upstream ports. Low-power functions always draw less than 100 mA; high-power functions must draw less than 100 mA at power up and can draw up to 500 mA after enumeration. If the load of the function is more than the parallel combination of 44 Ω and 10 µF at power up, the device must implement inrush current limiting. 18 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 USB Power Distribution Requirements USB can be implemented in several ways regardless of the type of USB device being developed. Several powerdistribution features must be implemented. SPHs must: • Current limit downstream ports • Report over-current conditions BPHs must: • Enable/disable power to downstream ports • Power up at < 100 mA • Limit inrush current (< 44 Ω and 10 µF) Functions must: • Limit inrush currents • Power up at < 100 mA The feature set of the TPS65281 meets each of these requirements. The integrated current limiting and overcurrent reporting is required by self-powered hubs. The logic-level enable and controlled rise times meet the need of both input and output ports on bus-powered hubs and the input ports for bus-powered functions. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 19 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com BUCK DC/DC CONVERTER DETAILED DESCRIPTION Output Voltage The TPS65281/TPS65281-1 regulates output voltage set by a feedback resistor divider to 0.8-V reference voltage. This pin should be directly connected to middle of resistor divider. It is recommended to use 1% tolerance or better divider resistors.Great care should be taken to route the FB line away from noise sources, such as the inductor or the LX switching node line. Start with 40.2 kΩ for the R1 resistor and use Equation 4 to calculate R2. 0.8V R2 = R1 × ( ) VOUT - 0.8V (4) Vout=5V R1 40.2kΩ 10 - FB EA + C1 4.7 nF 0.8V R2 7.7kΩ Reference 2 COMP Figure 29. Buck Feedback Resistor Divider Switching Frequency Selection The selection of switching frequency is a tradeoff between efficiency and component size. Low frequency operation increases efficiency by reducing MOSFET switching losses, but requires larger inductance and capacitance to maintain low output ripple voltage. The switching frequency of the TPS65281/TPS65281-1 buck controller can be selected with the connection at ROSC pin. The ROSC pin can be connected to AGND, tied to V7V, open or programmed through an external resistor. Tying ROSC pin to AGND selects 300 kHz, while tying ROSC ping to V7V or floating ROSC pin selects 600 kHz. Placing a resistor between ROSC and AGND allows the buck switching frequency to be programmed between 300 kHz to 1.4 MHz, as shown in Figure 14. The programmed clock frequency by an external resistor can be calculated with the following equation: fSW = 10 x ROSC (5) Soft-Start Time The start-up of buck output is controlled by the voltage on the SS pin. When the voltage on the SS pin is less than the internal 0.8-V reference, the TPS65281/TPS65281-1 regulates the internal feedback voltage to the voltage on the SS pin instead of 0.8 V. The SS pin can be used to program an external soft-start function or to allow output of the buck to track another supply during start-up. The device has an internal pull-up current source of 4.7 µA that charges an external soft-start capacitor to provide a linear ramping voltage at SS pin. The TPS65281 will regulate the internal feedback voltage according to the voltage on the SS pin, allowing VOUT to rise smoothly from 0 V to its final regulated value. The total soft-start time will be approximately: æ 0.8 × V ö Tss = Css × ç ÷ è 4.7 × uA ø (6) 20 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 Internal V7V Regulator The TPS65281/TPS65281-1 features an internal P-channel low dropout linear regulator (LDO) that supplies power at the V7V pin from the VIN supply. V7V powers the gate drivers and much of the TPS65281/ TPS65281-1’s internal circuitry. The LDO regulates V7V to 6.3 V of over drive voltage on the power MOSFET for the best efficiency performance. The LDO can supply a peak current of 50 mA and must be bypassed to ground with a minimum 1-µF ceramic capacitor. The capacitor placed directly adjacent to the V7V and PGND pins is highly recommended to supply the high transient currents required by the MOSFET gate drivers. Short Circuit Protection During the PWM on-time, the current through the internal high side switching MOSFET is sampled. The sampled current is compared to a nominal 5-A over-current limit. If the sampled current exceeds the over-current limit reference level, an internal over-current fault counter is set to 1 and an internal flag is set. Both internal high side and low side power MOSFETs are immediately turned off and will not be turned on again until the next switching cycle. If the over-current condition persists for eight sequential clock cycles, the over-current fault counter overflows indicating an over-current fault condition exists. The buck regulator is shut down and stays turned off for 10 ms. If the over-current condition clears prior to the counter reaching eight consecutive cycles, the internal flag and counter are reset. The protection circuitry attempts to recover from the over-current condition after 10-ms power down time. The internal over-current flag and counter are reset. A normal soft-start cycle is attempted and normal operation continues if the over-current fault condition has cleared. If the over-current fault counter overflows during soft-start, the converter shuts down and this hiccup mode operation repeats. Vout Current limit threshold IL 8 clock cycles VLX 10ms Figure 30. DC/DC Over-Current Protection Inductor Selection The higher operating frequency allows the use of smaller inductor and capacitor values. A higher frequency generally results in lower efficiency because of MOSFET gate charge losses. In addition to this basic trade-off, the effect of the inductor value on ripple current and low current operation must also be considered. The ripple current depends on the inductor value. The inductor ripple current, iL, decreases with higher inductance or higher frequency and increases with higher input voltage, VIN. Accepting larger values of iL allows the use of low inductances, but results in higher output voltage ripple and greater core losses. Use Equation 7 to calculate the value of the output inductor. LIR is a coefficient that represents inductor peak-topeak ripple to DC load current. It is suggested to use 0.1 ~ 0.3 for most LIR applications. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 21 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com Actual core loss of the inductor is independent of core size for a fixed inductor value, but it is dependent on the inductance value selected. As inductance increases, core losses decrease. Unfortunately, increased inductance requires more turns of wire and therefore copper losses will increase. Ferrite designs have very low core loss and are preferred for high switching frequencies, so design goals can concentrate on copper loss and preventing saturation. Ferrite core material saturates hard, which means that inductance collapses abruptly when the peak design current is exceeded. It results in an abrupt increase in inductor ripple current and consequent output voltage ripple. Do not allow the core to saturate. It is important that the RMS current and saturation current ratings are not exceeding the inductor specification. The RMS and peak inductor current can be calculated from Equation 9 and Equation 10. V - Vout Vout L = in × IO × LIR Vin × fsw (7) DiL = Vin - Vout Vout × L Vin × fsw (8) Vout × (Vinmax - Vout ) 2 ) Vinmax × L × fsw 2 iLrms = IO + 12 Di ILpeak = IO + L 2 ( (9) (10) For this design example, use LIR = 0.3, and the inductor is calculated to be 5.40 µH with VIN = 12 V, VOUT = 5 V and fSW = 600 kHz. Choose a 4.7 µH standard inductor, the peak to peak inductor ripple is about 34% of 3-A DC load current. Output Capacitor Selection There are two primary considerations for selecting the value of the output capacitor. The output capacitors are selected to meet load transient and output ripple’s requirements. Equation 11 gives the minimum output capacitance to meet the transient specification. For this example, LO = 4.7 µH, ΔIOUT = 3 A – 0.0 A = 3 A and ΔVOUT = 500 mV (10% of regulated 5 V). Using these numbers gives a minimum capacitance of 17 µF. A standard 22 µF ceramic capacitor is used in the design. Co > DIOUT 2 × L Vout × DVout (11) The selection of COUT is driven by the effective series resistance (ESR). Equation 12 calculates the minimum output capacitance needed to meet the output voltage ripple specification. Where fSW is the switching frequency, ΔVOUT is the maximum allowable output voltage ripple, and ΔiL is the inductor ripple current. In this case, the maximum output voltage ripple is 50 mV (1% of regulated 5 V). From Equation 8, the output current ripple is 1 A. From Equation 12, the minimum output capacitance meeting the output voltage ripple requirement is 4.6 µF with 3-mΩ esr resistance. 1 1 Co > × 8 × fsw DVout - esr DiL (12) After considering both requirements, for this example, one 22 µF 6.3 V X7R ceramic capacitor with 3 mΩ of ESR will be used. Input Capacitor Selection A minimum 10 µF X7R/X5R ceramic input capacitor is recommended to be added between VIN and GND. These capacitors should be connected as close as physically possible to the input pins of the converters, as they handle the RMS ripple current shown in Equation 13. For this example, IOUT = 2 A, VOUT = 5 V, minimum Vin_min = 9.6 V. Tthe input capacitors must support a ripple current of 1 A RMS. Iinrms = Iout × 22 Vout (Vinmin - Vout ) × Vinmin Vinmin Submit Documentation Feedback (13) Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 The input capacitance value determines the input ripple voltage of the regulator. The input voltage ripple can be calculated using Equation 14. Using the design example values, Iout_max = 2 A, CIN = 10 µF, fSW = 600 kHz, yields an input voltage ripple of 83 mV. I × 0.25 DVin = out max Cin × fsw (14) To prevent large voltage transients, a low ESR capacitor sized for the maximum RMS current must be used. Bootstrap Capacitor Selection The external bootstrap capacitor connected to the BST pins supply the gate drive voltages for the topside MOSFETs. The capacitor between BST pin and LX pin is charged through an internal diode from V7V when the LX pin is low. When high side MOSFETs are to be turned on, the driver places the bootstrap voltage across the gate-source of the desired MOSFET. This enhances the top MOSFET switch and turns it on. The switch node voltage, LX, rises to VIN and the BST pin follows. With the internal high side MOSFET on, the bootstrap voltage is above the input supply: VBST = VIN + V7V. The selection on bootstrap capacitance is related with internal high side power MOSFET gate capacitance. A 0.047-μF ceramic capacitor is recommended to be connected between the BST to LX pin for proper operation. It is recommended to use a ceramic capacitor with X5R or better grade dielectric. The capacitor should have 10-V or higher voltage rating. Loop Compensation The integrated buck DC/DC converter in TPS65281 incorporates a peak current mode. The error amplifier is a trans-conductance amplifier with a gain of 500 µA/V. A typical type II compensation circuit adequately delivers a phase margin between 60° and 90°. Cb adds a high frequency pole to attenuate high frequency noise when needed. To calculate the external compensation components, follow these steps: 1. Select switching frequency, fSW, that is appropriate for application depending on L and C sizes, output ripple and EMI. Switching frequency between 500 kHz and 1 MHz gives the best trade off between performance and cost. To optimize efficiency, a lower switching frequency is desired. 2. Set up cross over frequency, fc, which is typically between 1/5 and 1/20 of fSW. 3. RC can be determined by: 2p × fc × Vo × Co RC = gM × Vref × gmps (15) where gm is the error amplifier gain (500 µA/V) and gmps is the power stage voltage to current conversion gain (20 A/V). 1 fp = CO × RL × 2p . 4. Calculate CC by placing a compensation zero at or before the dominant pole, R × Co CC = L RC (16) 5. Optional Cb can be used to cancel the zero from the ESR associated with CO. Re sr × Co Cb = RC Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 (17) 23 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com SW _IN Buck Output : +5V iL R ESR RL Current Sense I/V Converter gmps = 10 A / V Co R1 C1 40.2 kW 4.7 nF Vfb COMP EA g M = 500µs Rc Vref = 0. 8V R2 7.7 kW Cb Cc Figure 31. DC/DC Loop Compensation 24 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 APPLICATION INORMATION Thermal Shutdown The device implements an internal thermal shutdown to protect itself if the junction temperature exceeds 160°C. The thermal shutdown forces the buck converter to stop switching when the junction temperature exceeds thermal trip threshold. Once the die temperature decreases below 140°C, the device reinitiates the power up sequence. The thermal shutdown hysteresis is 20°C. Power Dissipation and Junction Temperature The total power dissipation inside TPS65281/TPS65281-1 should not exceed the maximum allowable junction temperature of 125°C. The maximum allowable power dissipation is a function of the thermal resistance of the package, θJA, and ambient temperature. The analysis below gives an approximation in calculating junction temperature based on the power dissipation in the package. However, it is important to note that thermal analysis is strongly dependent on additional system level factors. Such factors include air flow, board layout, copper thickness and surface area, and proximity to other devices dissipating power. Good thermal design practice must include all system level factors in addition to individual component analysis. To calculate the temperature inside the device under continuous load, use the following procedure. 1. Define the total continuous current through the buck converter (including the load current through power switches). Make sure the continuous current does not exceed the maximum load current requirement. 2. From the graphs below, determine the expected losses (Y axis) in Watts for the buck converter inside the device. The loss PD_BUCK depends on the input supply and the selected switching frequency. Please note, the data is measured in the provided evaluation board (EVM). 3. Determine the load current IOUT through the power switch. Read RDS(on) of the power switch from the Electrical Characteristics table. 4. The power loss through power switches can be calculated by: PD_PW = RDS(on) × IOUT (18) 5. The Dissipating Rating Table provides the thermal resistance, θJA, for specific packages and board layouts. 6. The maximum temperature inside the IC can be calculated by: TJ = PD_BUCK + PD_PW × θJA + TA (19) Where: TA = Ambient temperature (°C) θJA = Thermal resistance (°C/W) PD_BUCK = Total power dissipation in buck converter (W) PD_PW = Total power dissipation in power switches (W) Figure 32. Buck Power Loss vs Output Current VIN = 12 V, fSW = 600 kHz Figure 33. Buck Power Loss vs Output Current VIN = 12 V, fSW = 300 kHz Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 25 TPS65281, TPS65281-1 SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 www.ti.com Auto-Retry Functionality Some applications require that an over-current condition disables the part momentarily during a fault condition and re-enables after a pre-set time. This auto-retry functionality can be implemented with an external resistor and capacitor shown in Figure 34. During a fault condition, nFAULT pulls low disabling the part. The part is disabled when EN is pulled low, and nFAULT goes high impedance allowing CRETRY to begin charging. The part reenables when the voltage on EN_SW reaches the turn-on threshold, and the auto-retry time is determined by the resistor/capacitor time constant. The part will continue to cycle in this manner until the fault condition is removed. C7 47nF L1 4.7uH +5V C6 4.7nF R3 40.2kΩ C5 22uF 13 14 9 SW_IN 11 10 FB RFAULT 100kΩ SW_OUT PGND AGND VIN USB Data 8 C4 10uF 7 USB Port TPS65281 EN_SW C3 4.7nF USB fault signal 5 USB control signal CRETRY 0.1uF 4 2 1 6 RLIM EN ROSC 16 nFAULT SS Enable V7V 3 15 C2 1uF COMP VIN 5.5V~18V C1 10uF LX BST 12 R4 7.68kΩ R2 20kΩ R1 10kΩ Figure 34. Auto Retry Functionality Some applications require auto-retry functionality and the ability to enable/disable with an external logic signal. Figure 35 shows how an external logic signal can drive EN_SW through RFAULT and maintain auto-retry functionality. The resistor/capacitor time constant determines the auto-retry time-out period. C7 47nF L1 4.7uH +5V C6 4.7nF R3 40.2kΩ C5 22uF 13 C1 10uF 14 9 11 10 FB SW_IN USB Data SW_OUT 8 AGND 7 VIN C4 10uF USB Port TPS65281 6 5 RFAULT 100kΩ external logic signal & driver CRETRY 0.1uF 4 1 C3 4.7nF RLIM EN_SW ROSC EN 3 16 nFAULT SS C2 1uF V7V COMP 15 Enable PGND 2 VIN 5.5V~18V LX BST 12 R4 7.68kΩ R2 20kΩ R1 10kΩ Figure 35. Auto Retry Functionality With External Enable Signal 26 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 TPS65281, TPS65281-1 www.ti.com SLVSBH7B – JULY 2012 – REVISED DECEMBER 2012 PCB Layout Recommendation When laying out the printed circuit board, the following guidelines should be used to ensure proper operation of the IC. These items are also illustrated graphically in the layout diagram of Figure 36. • There are several signal paths that conduct fast changing currents or voltages that can interact with stray inductance or parasitic capacitance to generate noise or degrade the power supplies performance. To help eliminate these problems, the VIN pin should be bypassed to ground with a low ESR ceramic bypass capacitor with X5R or X7R dielectric. This capacitor provides the AC current into the internal power MOSFETs. Connect the (+) terminal of the input capacitor as close as possible to the VIN pin, and connect the (-) terminal of the input capacitor as close as possible to the PGND pin. Care should be taken to minimize the loop area formed by the bypass capacitor connections, the VIN pins, and the power ground PGND connections. • Since the LX connection is the switching node, the output inductor should be located close to the LX pin, and the area of the PCB conductor minimized to prevent excessive capacitive coupling. Keep the switching node, LX, away from all sensitive small-signal nodes. • Connect V7V decoupling capacitor (connected close to the IC), between the V7V and the power ground PGND pin. This capacitor carries the MOSFET drivers’ current peaks. • Place the output filter capacitor of the buck converter close to SW_IN pins and AGND pin. Try to minimize the ground conductor length while maintaining adequate width. • The AGND pin should be separately routed to the (-) terminal of V7V bypass capacitor to avoid switching grounding path. A ground plane is recommended connecting to this ground path. • The compensation should be as close as possible to the COMP pins. The COMP and ROSC pins are sensitive to noise so the components associated to these pins should be located as close as possible to the IC and routed with minimal lengths of trace. • Flood all unused areas on all layers with copper. Flooding with copper will reduce the temperature rise of the power components. You can connect the copper areas to PGND, AGND, VIN or any other DC rail in your system. • There is no electric signal internal connected to thermal pad in the device. Nevertheless connect the exposed pad beneath the IC to ground. Always solder the thermal pad to the board, and have as many vias as possible on the PCB to enhance power dissipation. PGND VOUT_BUCK Top Side Power Ground Area output inductor boot capacitor SW_IN FB LX BST SW_OUT PGND Input bypass capacitor VIN output capacitor VIN AGND V7V nFAULT EN EN_SW Bottom Side Power Ground Area power switch VOUT output capacitor AGND EN_SW RLIM ROSC SS COMP nFAULT LDO capacitor Bottom Side Analog Ground Area Top Side Analog Ground Area Thermal VIA Signal VIA Thermal VIA Signal VIA Figure 36. 2-Layers PCB Layout Recommendation Diagram Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated Product Folder Links: TPS65281 TPS65281-1 27 PACKAGE OPTION ADDENDUM www.ti.com 20-Jan-2013 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Qty Drawing Eco Plan Lead/Ball Finish MSL Peak Temp Samples (3) (Requires Login) (2) TPS65281-1RGVR ACTIVE VQFN RGV 16 2500 TBD Call TI TPS65281RGVR ACTIVE VQFN RGV 16 3000 Green (RoHS & no Sb/Br) CU NIPDAU TPS65281RGVT ACTIVE VQFN RGV 16 250 TBD Call TI Call TI Level-2-260C-1 YEAR Call TI (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 - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. 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. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. 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