TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 High-Power, High-Efficiency PoE PD and DC-to-DC Controller FEATURES DESCRIPTION • • The TPS23785B is a combined Power over Ethernet (PoE) powered device (PD) interface and currentmode DC-to-DC controller optimized specifically for non-isolated converters. The PoE interface supports the IEEE 802.3at standard. 1 Powers up to 30-W (Input) PDs DC-to-DC Control Optimized for Non-Isolated Converters Supports High-Efficiency Topologies Complete PoE Interface Enhanced Classification per IEEE 802.3at with Status Flag Adapter ORing Support Robust 100-V, 0.5-Ω Hotswap MOSFET –40°C to 125°C Junction Temperature Range Industry Standard PowerPAD™ TSSOP-24 2 • • • • • • • The TPS23785B supports a number of input voltage ORing options including highest voltage, external adapter preference, and PoE preference. These features allow the designer to determine which power source will carry the load under all conditions. The PoE interface features the two-event, physicallayer classification necessary for compatibility with high-power midspan power sourcing equipment (PSE) per IEEE 802.3at. The detection signature pin can also be used to force power from the PoE source off. Classification can be programmed to any of the defined types with a single resistor. APPLICATIONS • • • • • IEEE 802.3at Compliant Devices Video and VoIP Telephones RFID Readers Surveillance Cameras Wireless Access Points From Ethernet Pairs 1,2 Typical Application Diagram T1 COUT DVC1 RVC M2 CIZ RCS CVC CVB RCTL DT RDT BLNK GATE CS GAT2 TLV431 RFBU M1 RFBL VDD1 VDD RT2P TPS23785B RBLNK RFRS RAPD1 RAPD2 Adapter DA T2P VOUT CIN VC VB RTN COM ARTN DEN NC CLS PAD VSS APD CTL FRS RCLS From Ethernet Pairs 3,4 0.1uF 58V RDEN Type 2 PSE Indicator 1 2 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. PowerPAD is a trademark of Texas Instruments. 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 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com DESCRIPTION (CONT.) The DC-to-DC controller features two complementary gate drivers with programmable dead time. This simplifies design for highly-efficient flyback topologies utilizing secondary synchronous rectification. The second gate driver may be disabled if desired for single MOSFET topologies. The controller also features internal softstart, bootstrap startup source, current-mode compensation, and a 78% maximum duty cycle. A programmable and synchronizable oscillator allows design optimization for efficiency and eases use of the controller to upgrade existing power supply designs. Accurate programmable blanking, with a default period, simplifies the usual current-sense filter design trade-offs. 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. PRODUCT INFORMATION DUTY CYCLE POE UVLO ON / HYST. (V) CONVERTER UVLO ON / HYST. (V) PACKAGE MARKING 0–78% 35 / 4.5 15 / 6.5 TSSOP-24 PowerPAD™ TPS23785B TPS23785BPWP (1) (1) For the most current package and ordering information, see the Package Option Addendum at the end of this document, or consult your TI salesperson. ABSOLUTE MAXIMUM RATINGS (1) (2) Voltage with respect to VSS unless otherwise noted. Over recommended operating junction temperature range. VALUE Input voltage range ARTN (2), COM (2), DEN, RTN (3), VDD, VDD1 –0.3 to 100 CLS (4) -0.3 to 6.5 [APD, BLNK (4), CTL, DT (4), FRS (4), VB COM] Voltage range Sinking current (4) ] to [ARTN, –0.3 to 6.5 [P1, P2 (4)] to [ARTN,COM] –0.3 to 6.5 CS to [ARTN,COM] –0.3 to VB [ARTN, COM] to RTN T2P (4), VC to [ARTN, COM] GATE (4), GAT2 (4) to [ARTN, COM] UNIT V –2 to 2 –0.3 to 19 –0.3 to VC+0.3 RTN Internally limited T2P 20 mA Sourcing current VB Average Sourcing or sinking current GATE, GAT2 25 mARMS Human body model (HBM) 2 kV ESD rating Charged device model (CDM) 500 Machine model (MM) 50 ESD – system level (contact/air) at RJ-45 (5) Operating junction temperature range, TJ (1) (2) (3) (4) (5) 2 Internally limited V 8 / 15 kV –40 to Internally limited °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. ARTN and COM tied to RTN. IRTN = 0 for VRTN > 80V. Do not apply voltage to these pins ESD per EN61000-4-2. A power supply containing the TPS23785B was subjected to the highest test levels in the standard. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 RECOMMENDED OPERATING CONDITIONS (1) Voltage with respect to VSS (unless otherwise noted) MIN Input voltage range Sinking current NOM MAX ARTN, COM, RTN, VDD, VDD1 0 T2P (2), VC to [ARTN, COM] 0 18 [APD, CTL, DT, FRS (3), P1, P2] to [ARTN, COM] 0 VB CS to [ARTN, COM] 0 2 57 T2P V 2 Continuous RTN current (TJ ≤ 125°C) (4) 825 Sourcing current VB 0 Capacitance VB 0.08 RBLNK 2.5 mA 5 μF 0 Synchronization pulse width input (when used) 350 kΩ 25 Operating junction temperature range, TJ (1) (2) (3) (4) UNIT ns –40 125 °C ARTN and COM tied to RTN. T2P current is limited. Pulse voltage applied for synchronization. This is the minimum current-limit value. Viable systems will be designed for maximum currents below this value with reasonable margin. IEEE 802.3at permits 600mA continuous loading. THERMAL INFORMATION TPS23785B THERMAL METRIC (1) TSSOP UNITS 24 PINS θJA Junction-to-ambient thermal resistance (2) 32.6 θJCtop Junction-to-case (top) thermal resistance (3) 16.9 θJB Junction-to-board thermal resistance (4) 17.9 (5) ψJT Junction-to-top characterization parameter ψJB Junction-to-board characterization parameter (6) 7.4 θJCbot Junction-to-case (bottom) thermal resistance (7) 1.8 (1) (2) (3) (4) (5) (6) (7) 0.2 °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 Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 3 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com ELECTRICAL CHARACTERISTICS Unless otherwise noted: CS=COM=APD=CTL=RTN=ARTN, GATE and GAT2 float, RFRS= 68.1 kΩ, RBLNK= 249 kΩ, DT = VB, T2P open, CVB= CVC= 0.1 μF, RDEN= 24.9 kΩ, RCLS open, 0 V ≤ (VDD, VDD1) ≤ 57 V, 0 V ≤ VC ≤ 18 V, –40°C ≤ TJ ≤ 125°C. P1 = P2 = VB. Typical specifications are at 25°C. CONTROLLER SECTION ONLY [VSS = RTN and VDD= VDD1] or [VSS= RTN=VDD], all voltages referred to [ARTN, COM]. PARAMETER TEST CONDITIONS MIN TYP MAX 14.3 15 15.7 6.2 6.5 6.8 UNIT VC VCUV VCUVH tST UVLO VC rising Hysteresis (1) Operating current VC = 12 V, CTL = VB, RDT = 75 kΩ 0.74 0.96 1.24 Bootstrap startup time, CVC = 22 μF VDD1 = 19.2 V, VC(0) = 0 V 49 81 166 VDD1 = 35 V, VC(0) = 0 V 44 75 158 VDD1 = 19.2 V, VC = 13.9 V 1.7 3.4 5.5 VDD1 = 48 V, VC = 0 V 2.7 4.8 6.8 6.5 V ≤ VC ≤ 18 V, 0 ≤ IVB ≤ 5 mA 4.8 5.10 5.25 227 253 278 76% 78% 80% 2 2.2 2.4 Startup current source - IVC V mA ms mA VB Voltage V FRS Switching frequency CTL = VB, measure GATE RFRS = 68.1 kΩ kHz DMAX Duty cycle CTL= VB, measure GATE VSYNC Synchronization Input threshold 0% duty cycle threshold VCTL ↓ until GATE stops 1.3 1.5 1.7 V Softstart period Interval from switching start to VCSMAX 1.9 3.9 6.2 ms 70 100 145 kΩ BLNK = RTN 35 55 78 RBLNK = 49.9 kΩ 38 55 70 RDT = 24.9 kΩ, GAT2 ↓ to GATE ↑ 40 50 62.5 RDT = 24.9 kΩ, GATE ↓ to GAT2 ↑ 40 50 62.5 V CTL VZDC Input resistance BLNK Blanking delay (In addition to t1) ns DT CTL = VB, CGATE = 1 nF, CGAT2 = 1 nF, measure GATE, GAT2 tDT1 tDT2 Dead time See Figure 1 for tDTx definition tDT1 RDT = 75 kΩ, GAT2 ↓ to GATE ↑ 120 150 188 tDT2 RDT = 75 kΩ, GATE ↓ to GAT2 ↑ 120 150 188 (1) 4 ns The hysteresis tolerance tracks the rising threshold for a given device. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 PARAMETER TEST CONDITIONS MIN TYP MAX UNIT CS VCSMAX Maximum threshold voltage VCTL = VB, VCS rising until GATE duty cycle drops 0.5 0.55 0.6 V t1 Turnoff delay VCS = 0.65 V 24 40 70 ns VSLOPE Internal slope compensation voltage Peak voltage at maximum duty cycle, referenced to CS 120 155 185 mV ISL_EX Peak slope compensation current VCTL = VB, ICS at maximum duty cycle Bias current (sourcing) DC component of ICS Source current 30 42 54 1 2.5 4.3 VCTL = VB, VC = 12 V, GATE high, pulsed measurement 0.37 0.6 0.95 Sink current VCTL = VB, VC = 12 V, GATE low, pulsed measurement 0.7 1 1.4 Source current VCTL = VB, VC = 12 V, GAT2 high, RDT = 24.9 kΩ, pulsed measurement 0.37 0.6 0.95 Sink current VCTL = VB, VC = 12 V, GAT2 low, RDT = 24.9 kΩ, pulsed measurement 0.7 1 1.4 1.43 1.5 1.57 0.29 0.31 0.33 μA GATE A GAT2 A APD VAPDEN VAPDH APD threshold voltage VAPD rising Hysteresis (2) V APD leakage current (source or sink) VC = 12 V, VAPD = VB 1 μA Leakage current Source or sink 1 μA P1, P2 (2) The hysteresis tolerance tracks the rising threshold for a given device. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 5 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com ELECTRICAL CHARACTERISTICS – PoE AND CONTROL [VDD = VDD1] or [VDD1 = RTN], VC = RTN, COM = RTN = ARTN, all voltages referred to VSS unless otherwise noted PARAMETER DETECTION (DEN) TEST CONDITIONS MIN TYP MAX UNIT (VDD = VDD1 = RTN = VSUPPLY positive) Measure ISUPPLY Detection current Detection bias current VPD_DIS VDD = 1.6 V 62 64.3 66.5 VDD = 10 V 399 406 414 5.6 10 μA 4 5 V 0.1 5 μA 1.8 2.1 2.4 RCLS = 243 Ω (Class 1) 9.9 10.4 10.9 RCLS = 137 Ω (Class 2) 17.6 18.5 19.4 RCLS = 90.9 Ω (Class 3) 26.5 27.7 29.3 42 VDD = 10 V, float DEN, measure ISUPPLY, Note: Not during Mark state Hotswap disable threshold DEN leakage current CLASSIFICATION (CLS) 3 VDEN = VDD = 57 V, float VDD1 and RTN, measure IDEN μA (VDD = VDD1 = RTN = VSUPPLY positive) 13 V ≤ VDD ≤ 21 V, Measure ISUPPLY RCLS = 1270 Ω (Class 0) Classification current, applies to both cycles ICLS mA RCLS = 63.4 Ω (Class 4) 38 39.7 Classification mark resistance 5.6 V ≤ VDD ≤ 9.4 V 7.5 9.7 12 Classification regulator lower threshold Regulator turns on, VDD rising 11.2 11.9 12.6 Hysteresis (1) 1.55 1.65 1.75 Classification regulator upper threshold Regulator turns off, VDD rising 21 22 23 VCU_H Hysteresis (1) 0.5 0.75 1 VMSR Mark state reset VDD falling 3 4 5 V Leakage current VDD = 57 V, VCLS = 0 V, DEN = VSS, measure ICLS 1 μA 0.75 Ω VCL_ON VCL_H VCU_OFF PASS DEVICE (RTN) kΩ V V (VDD1 = RTN) On resistance 0.25 0.43 Current limit VRTN = 1.5 V, VDD = 48 V, pulsed measurement 850 970 1100 mA Inrush limit VRTN = 2 V, VDD: 0 V → 48 V, pulsed measurement 100 140 180 mA Foldback voltage threshold VDD rising 11 12.3 13.6 V VDD rising 33.9 35 36.1 4.4 4.55 4.76 UVLO VUVLO_R VUVLO_H UVLO threshold Hysteresis (1) V T2P tT2P ON characteristic Perform classification algorithm, VT2P-RTN = 1 V, CTL = ARTN Leakage current VT2P = 18 V, CTL = VB Delay From start of switching to T2P active 2 mA 10 μA 5 9 15 ms 135 145 155 °C THERMAL SHUTDOWN Turnoff temperature Hysteresis (1) (2) 6 TJ rising (2) 20 °C The hysteresis tolerance tracks the rising threshold for a given device. These parameters are specified by design and are not production tested. Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 GATE Timing Diagram hi 50% GAT2 lo hi 50% time lo tDT1 tDT2 Figure 1. GATE and GAT2 Timing and Phasing Diagram DEVICE INFORMATION TPS28785B PWP PACKAGE (TOP VIEW) P1 P2 CTL VB CS COM GATE VC GAT2 ARTN RTN VSS (pad) 1 2 3 4 5 6 7 8 9 10 11 12 Thermal Pad 24 23 22 21 20 19 18 17 16 15 14 13 N/C N/C T2P FRS BLNK APD DT CLS N/C DEN VDD VDD1 N/C = Leave Pin Unused PAD = VSS Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 7 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Functional Block Diagram VC VDD1 f f Oscillator FRS CTL 50kW Control D Q CK 1 + 0.75V CLRB GATE DT COM GAT2 f ARTN t2 Converter Thermal Monitor + ss CTL - 0.55V T2P Logic Switch Matrix T2P ARTN BLNK ARTN VDD Ref Global Cvtr. Enable enb enb + ARTN 42mA (pk) 3.69kW CS VB Deadtime 50kW 3.9ms Softstart CONV. OFF Reg uvlo, fpd 11.9V & pa, sa, den 10.3V 2.5V Class Logic & Regulator CLS uvlo T2 State Eng. t2 22V & 21.25V 12.3V VSS DEN 4V 35V & 30.5V R Q uvlo Common Circuits and PoE Thermal Monitor VSS S H L 1 ILIM + 0 - Hotswap MOSFET RTN 50mW den Submit Documentation Feedback EN fpd sa 8 CONV. OFF 400ms 1.5V &1.2V ARTN APD 4V Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 PIN FUNCTIONS NAME PIN TYPE DESCRIPTION P1 1 I Tie this pin to VB. P2 2 I Tie this pin to VB. CTL 3 I This is the control loop input to the PWM (pulse width modulator), typically driven by output regulation feedback (e.g. optocoupler). Use VB as a pullup for CTL. VB 4 O 5.1 V bias rail for dc/dc control circuits and the feedback optocoupler. Typically bypass with a 0.1 μF to ARTN. CS 5 I/O DC/DC converter switching MOSFET current sense input. See RCS in the Typical Application Diagram. COM 6 – Gate driver return, connect to ARTN and RTN. GATE 7 O Gate drive output for the main dc/dc converter switching MOSFET. VC 8 I/O DC/DC converter bias voltage. Connect a 0.47 μF (minimum) ceramic capacitor to ARTN at the pin, and a larger capacitor to power startup. GAT2 9 O Gate drive output for a second dc/dc converter switching MOSFET. ARTN 10 – ARTN is the dc/dc converter analog return. Tie to RTN and COM on the circuit board. RTN 11 – RTN is the output of the PoE hotswap MOSFET. VSS 12 – Connect to the negative power rail derived from the PoE source. VDD1 13 I Source of dc/dc converter startup current. Connect to VDD for many applications. VDD 14 I Connect to the positive PoE input power rail. VDD powers the PoE interface circuits. Bypass with a 0.1 μF capacitor and protect with a TVS. DEN 15 I/O N/C 16 – Do not connect this pin. CLS 17 I Connect a resistor from CLS to VSS to program classification current. 2.5 V is applied to the program resistor during classification to set class current. DT 18 I Connect a resistor from DT to ARTN to set the GATE to GAT2 dead time. Tie DT to VB to disable GAT2 operation. APD 19 I Raising VAPD-VARTN above 1.5 V disables the internal hotswap switch, turns class off, and forces T2P active. This forces power to come from a external VDD1-RTN adapter. Tie APD to ARTN when not used. BLNK 20 I Connect to ARTN to utilize the internally set current-sense blanking period, or connect a resistor from BLNK to ARTN to program a more accurate period. FRS 21 I Connect a resistor from FRS to ARTN to program the converter switching frequency. FRS may be used to synchronize the converter to an external timing source. T2P 22 O Active low output that indicates a PSE has performed the IEEE 802.3at type 2 hardware classification, or APD is active. T2P pulls current to ARTN N/C 23 – Do not connect this pin. N/C 24 – Do not connect this pin. Pad – Connect a 24.9 kΩ resistor from DEN to VDD to provide the PoE detection signature. Pulling this pin to VSS during powered operation causes the internal hotswap MOSFET to turn off. Connect to VSS. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 9 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Detailed Pin Description See the Typical Application Diagram for component reference designators (RCS for example), and the Electrical Characteristics table for values denoted by reference (VCSMAX for example). Electrical Characteristic values take precedence over any numerical values used in the following sections. APD APD forces power to come from an external adapter connected from VDD1 to RTN by opening the hotswap switch, disabling the CLS output, and enabling the T2P output. A resistor divider is recommended on APD when it is connected to an external adapter. The divider provides ESD protection, leakage discharge for the adapter ORing diode, and input voltage qualification. Voltage qualification assures the adapter output voltage is high enough that it can support the PD before the PoE current is cut off. Select the APD divider resistors per Equation 1 where VADPTR-ON is the desired adapter voltage that enables the APD function as adapter voltage rises. RAPD1 = RAPD2 ´ VADPTR_OFF = (VADPTR_ON R APD1 + R APD2 R APD2 - VAPDEN ´ (VAPDEN ) VAPDEN - VAPDH ) (1) SLVA306A (or most recent) provides a sample calculation. Place the APD pull-down resistor adjacent to the APD pin. APD should be tied to ARTN when not used. BLNK Blanking provides an interval between GATE going high and the current-control comparators on CS actively monitoring the input. This delay allows the normal turn-on current transient (spike) to subside before the comparators are active, preventing undesired short duty cycles and premature current limiting. Connect BLNK to ARTN to obtain the internally set blanking period. Connect a resistor from BLNK to ARTN for a more accurate, programmable blanking period. The relationship between the desired blanking period and the programming resistor is defined by Equation 2. RBLNK (kW ) = tBLNK (ns ) (2) Place the resistor adjacent to the BLNK pin when it is used. 10 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 CLS A resistor from CLS to VSS programs the classification current per the IEEE standard. The PD power ranges and corresponding resistor values are listed in Table 1. The power assigned should correspond to the maximum average power drawn by the PD during operation. High-power PSEs may perform two-event classification if Class 4 is advertised by the PD. The TPS23785B presents the same (resistor-programmed) class each cycle per the standard. Table 1. Class Resistor Selection PD INPUT POWER RESISTOR (Ω) CLASS MINIMUM (W) MAXIMUM (W) 0 0.44 12.95 1270 1 0.44 3.84 243 2 3.84 6.49 137 3 6.49 12.95 90.9 4 12.95 25.5 63.4 NOTES Minimum may be reduced by pulsed loading. Serves as a catch-all default class. Not allowed for IEEE 802.3-2008. Use to indicate a Type 2 PD (high power) per IEEE 802.3at. CS The CS (current-sense) input for the dc/dc converter should be connected to the high side of the switching MOSFET’s current sense resistor (RCS). The current-limit threshold, VCSMAX, defines the voltage on CS above which the GATE ON time will be terminated regardless of the voltage on CTL. The TPS23785B provides internal slope compensation (150 mV, VSLOPE), an output current for additional slope compensation, a peak current limiter, and an off-time pull-down to this pin. Routing between the current-sense resistor and the CS pin should be short to minimize cross-talk from noisy traces such as the gate drive signal. CTL CTL (control) is the voltage-control loop input to the PWM (pulse width modulator). Pulling VCTL below VZDC (zero duty cycle voltage) causes GATE to stop switching. Increasing VCTL above VZDC raises the switching MOSFET programmed peak current. The maximum (peak) current is requested at approximately VZDC + (2 × VCSMAX). The ac gain from CTL to the PWM comparator is 0.5 V/V. The total internal divider resistance from CTL to ARTN is approximately 100 kΩ. Use VB as a pull up source for CTL. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 11 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com DEN DEN (detection and enable) is a multifunction pin for PoE detection and inhibiting operation from PoE power. Connect a 24.9 kΩ resistor from DEN to VDD to provide the PoE detection signature. DEN is pulled to VSS for VVDD-VSS below the classification voltage range, and goes to a high-impedance state when VVDD-VSS is outside of the detection range. Pulling DEN to VSS during powered operation causes the internal hotswap MOSFET and class regulator to turn off, while the reduced detection resistance prevents the PD from properly re-detecting. DT Dead-time programming sets the delay between GATE and GAT2 to synchronize MOSFET ON times as shown in Figure 1. GAT2 should turn the second MOSFET on when it transitions high. GAT2 should transition low before GATE goes high and transition high after GATE goes low. The maximum GATE ON time is reduced by the programmed dead-time period. The dead time period is specified with 1 nF of capacitance on GATE and GAT2. Different loading on these pins will change the effective dead time. A resistor connected from DT to ARTN sets the delay between GATE and GAT2 per Equation 3. RDT (kW ) = tDT (ns ) 2 (3) Connect DT to VB to set the dead time to 0 and turn GAT2 off. FRS Connect a resistor from FRS (frequency and synchronization) to ARTN to program the converter switching frequency. Select the resistor per the following relationship. RFRS (kW) = 17250 fSW (kHz) (4) The converter may be synchronized to a frequency above its maximum free-running frequency by applying short ac-coupled pulses into the FRS pin. The FRS pin is high impedance. Keep the connections short and apart from potential noise sources. Special care should be taken to avoid crosstalk when synchronizing circuits are used. GATE Gate drive output for the dc/dc converter’s main switching MOSFET. GATE’s phase turns the main switch on when it transitions high, and off when it transitions low. GATE is held low when the converter is disabled. 12 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 GAT2 GAT2 is the second gate drive output for the dc/dc converter. GAT2 turns the second switch on when it transitions high. GAT2 drives a secondary FET used as a synchronous rectifier in a flyback converter. See the DT Pin Description for GATE to GAT2 timing. Connecting DT to VB disables GAT2 in a high-impedance condition. GAT2 is low when the converter is disabled. RTN, ARTN, COM RTN is internally connected to the drain of the PoE hotswap MOSFET, while ARTN is the quiet analog reference for the dc/dc controller return. COM serves as the return path for the gate drivers and should be tied to ARTN on the circuit board. The ARTN / COM / RTN net should be treated as a local reference plane (ground plane) for the dc/dc control and converter primary. RTN and (ARTN/COM) may be separated by several volts for special applications. T2P T2P (Type 2 PSE) is an active low output that indicates [ (VAPD > 1.5 V) OR (type 2 hardware classification observed) ]. T2P is valid after both a delay of tT2P from the start of converter switching, and [VCTL ≤ (VB – 1 V)]. Once T2P is valid, VCTL will not affect it. T2P will become invalid if the converter goes back into softstart, overtemperature, or is held off by the PD during CIN recharge (inrush). T2P is referenced to ARTN and drives the diode side of an optocoupler. T2P should be left open or tied to ARTN if not used. VB VB is an internal 5.1V regulated dc/dc controller supply rail that is typically bypassed by a 0.1 μF capacitor to ARTN. VB should be used to bias the feedback optocoupler. VC VC is the bias supply for the dc/dc controller. The MOSFET gate drivers run directly from VC. VB is regulated down from VC, and is the bias voltage for the rest of the converter control. A startup current source from VDD1 to VC is controlled by a comparator with hysteresis to implement the converter bootstrap startup. VC must be connected to a bias source, such as a converter auxiliary output, during normal operation. A minimum 0.47 μF capacitor, located adjacent to the VC pin, should be connected from VC to COM to bypass the gate driver. A larger total capacitance is required for startup to provide control power between the time the converter starts switching and the availability of the converter auxiliary output voltage. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 13 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com VDD VDD is the positive input power rail that is derived from the PoE source (PSE). VDD should be bypassed to VSS with a 0.1 μF capacitor as required by the IEEE standard. A transient suppressor diode (TVS), a special type of Zener diode, such as SMAJ58A should be connected from VDD to VSS to protect against over-voltage transients. VDD1 VDD1 is the dc/dc converter startup supply. Connect to VDD for many applications. VDD1 may be isolated by a diode from VDD to support PoE priority operation. VSS VSS is the PoE input-power return side. It is the reference for the PoE interface circuits, and has a current-limited hotswap switch that connects it to RTN. VSS is clamped to a diode drop above RTN by the hotswap switch. A local VSS reference plane should be used to connect the input bypass capacitor, TVS, RCLS, and the PowerPad. This plane becomes the main heatsink for the TPS23785B. VSS is internally connected to the PowerPAD. PowerPAD™ The PowerPAD must be connected to VSS on the circuit board. It should be tied to a large VSS copper area on the PCB to provide a low resistance thermal path to the circuit board. It is recommended that a clearance of 0.025” be maintained between VSS, RTN, and various control signals to high-voltage signals such as VDD and VDD1. 14 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 TYPICAL CHARACTERISTICS DETECTION BIAS CURRENT vs VOLTAGE PoE CURRENT LIMIT vs TEMPERATURE 970 8 Pulsed Current Measurement 7 960 PoE − Current Limit − mA IVDD − Bias Current − µA 6 25°C 5 125°C 4 3 2 950 940 930 −40°C 920 1 0 0 2 4 6 8 910 −40 10 (VVDD − VVSS) − PoE Voltage − V 20 40 60 80 100 G001 Figure 2. Figure 3. CONVERTER START TIME vs TEMPERATURE CONVERTER STARTUP CURRENT vs VVDD1 6 120 G002 VVC = 13.9V CVC = 22 µF o TJ = -40 C 140 5 IVC − Source Current − mA VVDD1 = 19.2 V Converter Start Time − ms 0 TJ − Junction Temperature − °C 160 120 100 80 VVDD1 = 35 V 60 o TJ = 25 C 4 o TJ = 125 C 3 2 1 40 20 −40 −20 0 −20 0 20 40 60 80 TJ − Junction Temperature − °C Figure 4. Copyright © 2012, Texas Instruments Incorporated 100 5 120 10 15 20 25 30 35 40 45 50 55 60 VVDD1-RTN − V G003 Figure 5. Submit Documentation Feedback 15 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com TYPICAL CHARACTERISTICS (continued) CONTROLLER BIAS CURRENT vs TEMPERATURE CONTROLLER BIAS CURRENT vs VOLTAGE 3000 3500 GATE and GAT2 Open VVC = 12 V 3000 IC − Controller Bias Current − mA 2500 IVC − Sinking −mA GATE and GAT2 Open TJ = 25°C 2000 937 kHz 484 kHz 1500 245 kHz 100 kHz 1000 500 937 kHz 2500 484 kHz 2000 245 kHz 100 kHz 1500 1000 500 50 kHz 0 −40 VCTL = 0 V 50 kHz VCTL = 0 V 0 −20 0 20 40 60 80 100 9 120 TJ - Junction Temperature - °C 10 11 12 13 14 15 16 G005 Figure 6. Figure 7. SWITCHING FREQUENCY vs TEMPERATURE SWITCHING FREQUENCY vs PROGRAM CONDUCTANCE 1200 600 17 18 VC − Controller Bias Voltage − V G006 1200 RFRS = 34.6 kΩ (484 kHz) 1100 300 1000 RFRS = 17.35 kΩ (937 kHz) 900 RFRS = 69.8 kΩ (245 kHz) RFRS = 347 kΩ (50 kHz) 200 800 RFRS = 173 kΩ (100 kHz) 700 100 Switching Frequency − kHz 400 1000 Switching Frequency − kHz Switching Frequency − kHz 500 Ideal 800 600 Typical 400 200 0 −40 600 −20 0 20 40 60 80 TJ - Junction Temperature - °C 100 120 G007 0 0 10 20 30 40 50 Programmed Resistance (106 / RFRS) − Ω−1 Figure 8. 16 Submit Documentation Feedback 60 G008 Figure 9. Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 TYPICAL CHARACTERISTICS (continued) MAXIMUM DUTY CYCLE vs TEMPERATURE CURRENT SLOPE COMPENSATION VOLTAGE vs TEMPERATURE 79 155 78 RFRS = 347 kW (50 kHz) 154 RFRS = 69.8 kW (245 kHz) 76 153 VSLOPE − mVPP Maximum Duty Cycle − % 77 75 RFRS = 34.6 kW (484 kHz) 74 RFRS = 26.7 kW (623 kHz) 73 152 151 RFRS = 21.5 kW (766 kHz) 72 150 70 −40 −20 0 20 40 60 80 100 149 −40 120 TJ - Junction Temperature - °C 0 20 40 60 G009 Figure 10. Figure 11. CURRENT SLOPE COMPENSATION CURRENT vs TEMPERATURE BLANKING PERIOD vs TEMPERATURE Blanking Period − ns 45 40 G010 105 260 95 255 RBLNK = 100 kΩ 250 85 RBLNK = 249 kΩ 245 75 240 RBLNK = RTN RBLNK = 49.9 kΩ 55 −20 0 20 40 60 80 TJ − Junction Temperature − °C Figure 12. Copyright © 2012, Texas Instruments Incorporated 100 120 265 45 −40 30 −40 100 115 65 35 80 TJ − Junction Temperature − °C 50 ISLOPE − µAPP −20 235 230 −20 0 20 40 60 80 100 120 TJ - Junction Temperature - °C 120 Blanking Period − ns RFRS = 17.3 kW (937 kHz) 71 G012 G011 Figure 13. Submit Documentation Feedback 17 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com TYPICAL CHARACTERISTICS (continued) DEAD TIME vs DEAD TIME RESISTANCE (RDT ) 450 18 900 400 14 800 350 10 300 6 250 2 200 −2 150 −6 100 −10 50 −14 0 −18 400 700 Dead Time - ns Difference From Computed − ns Blanking Period − ns BLANKING PERIOD vs Blanking Resistance (RBLNK) Ideal 600 500 400 Typical 300 200 100 0 50 100 150 200 250 300 350 0 RBLNK − kW 0 50 100 150 200 250 300 Dead Time Resistance - kW Figure 14. 350 400 Figure 15. T2P DELAY TIME vs TEMPERATURE 11 T2P Delay Time - ms 10 9 8 7 6 -40 -20 0 20 40 60 80 Temperature - °C 100 120 Figure 16. 18 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 DETAILED DESCRIPTION Introduction The TPS23785B is based on the TPS23754 platform with a secondary gate drive output that is out-of-phase with the primary gate drive. The secondary gate drive output can be used directly or through an isolating transformer to drive a synchronous rectifier. See the Typical Application Diagram for a schematic. PoE OVERVIEW The following text is intended as an aid in understanding the operation of the TPS23785B but not as a substitute for the IEEE 802.3at standard. The IEEE 802.3at standard is an update to IEEE 802.3-2008 clause 33 (PoE), adding high-power options and enhanced classification. Generally speaking, a device compliant to IEEE 802.32008 is referred to as a type 1 device, and devices with high power and enhanced classification will be referred to as type 2 devices. Standards change and should always be referenced when making design decisions. The IEEE 802.3at standard defines a method of safely powering a PD (powered device) over a cable by power sourcing equipment (PSE), and then removing power if a PD is disconnected. The process proceeds through an idle state and three operational states of detection, classification, and operation. The PSE leaves the cable unpowered (idle state) while it periodically looks to see if something has been plugged in; this is referred to as detection. The low power levels used during detection are unlikely to damage devices not designed for PoE. If a valid PD signature is present, the PSE may inquire how much power the PD requires; this is referred to as classification. The PSE may then power the PD if it has adequate capacity. Type 2 PSEs are required to do type 1 hardware classification plus a (new) data-layer classification, or an enhanced type 2 hardware classification. Type 1 PSEs are not required to do hardware or data link layer (DLL) classification. A type 2 PD must do type 2 hardware classification as well as DLL classification. The PD may return the default, 13W current-encoded class, or one of four other choices. DLL classification occurs after power-on and the ethernet data link has been established. Shutdown Classify Detect 6.9 Maximum Input Voltage Must Turn On byVoltage Rising Lower Limit Operating Range Must Turn Off by Voltage Falling Classification Upper Limit Classification Lower Limit Detection Upper Limit Detection Lower Limit IEEE 802.3-2005 Once started, the PD must present the maintain power signature (MPS) to assure the PSE that it is still present. The PSE monitors its output for a valid MPS, and turns the port off if it loses the MPS. Loss of the MPS returns the PSE to the idle state. Figure 17 shows the operational states as a function of PD input voltage. The upper half is for IEEE 802.3-2008, and the lower half shows specific differences for IEEE 802.3at. The dashed lines in the lower half indicate these are the same (e.g., Detect and Class) for both. Normal Operation 42.5 0 30 37 57 PI Voltage (V) 42 Normal Operation 250ms Transient Class-Mark Transition 20.5 Lower Limit 13W Op. 10.1 14.5 Mark T2 Reset Range IEEE 802.3at 2.7 Figure 17. Operational States for PD Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 19 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com The PD input, typically an RJ-45 eight-lead connector, is referred to as the power interface (PI). PD input requirements differ from PSE output requirements to account for voltage drops and operating margin. The standard allots the maximum loss to the cable regardless of the actual installation to simplify implementation. IEEE 802.3-2008 was designed to run over infrastructure including ISO/IEC 11801 class C (CAT3 per TIA/EIA568) that may have had AWG 26 conductors. IEEE 802.3at type 2 cabling power loss allotments and voltage drops have been adjusted for 12.5 Ω power loops per ISO/IEC11801 class D (CAT5 or higher per TIA/EIA-568, typically AWG #24 conductors). Table 2 shows key operational limits broken out for the two revisions of the standard. Table 2. Comparison of Operational Limits STANDARD POWER LOOP RESISTANCE (max) PSE OUTPUT POWER (min) PSE STATIC OUTPUT VOLTAGE (min) PD INPUT POWER (max) POWER ≤ 12.95 W STATIC PD INPUT VOLTAGE POWER > 12.95 W IEEE 802.3-2008 802.3at (Type 1) 20 Ω 15.4 W 44 V 12.95 W 37 V–57 V N/A 802.3at (Type 2) 12.5 Ω 30 W 50 V 25.5 W 37 V–57 V 42.5 V–57 V The PSE can apply voltage either between the RX and TX pairs (pins 1 - 2 and 3 - 6 for 10baseT or 100baseT), or between the two spare pairs (4 - 5 and 7 - 8). Power application to the same pin combinations in 1000baseT systems is recognized in IEEE 802.3at. 1000baseT systems can handle data on all pairs, eliminating the spare pair terminology. The PSE may only apply voltage to one set of pairs at a time. The PD uses input diode bridges to accept power from any of the possible PSE configurations. The voltage drops associated with the input bridges create a difference between the standard limits at the PI and the TPS23785B specifications. A compliant type 2 PD has power management requirements not present with a type 1 PD. These requirements include the following: 1. Must interpret type 2 hardware classification 2. Must present hardware class 4 3. Must implement DLL negotiation 4. Must behave like a type 1 PD during inrush and startup 5. Must not draw more than 13 W for 80 ms after PSE applies operating voltage (power-up) 6. Must not draw more than 13 W if it has not received a type 2 hardware classification or received permission through DLL 7. Must meet various operating and transient templates 8. Optionally monitor for the presence or absence of an adapter (assume high power). As a result of these requirements, the PD must be able to dynamically control its loading, and monitor T2P for changes. In cases where the design needs to know specifically if an adapter is plugged in and operational, the adapter should be individually monitored, typically with an optocoupler. 20 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Threshold Voltages The TPS23785B has a number of internal comparators with hysteresis for stable switching between the various states. Figure 18 relates the parameters in the Electrical Characteristics section to the PoE states. The mode labeled idle between classification and operation implies that the DEN, CLS, and RTN pins are all high impedance. The state labeled Mark, which is drawn in dashed lines, is part of the new type 2 hardware class state machine. Functional State PD Powered Idle Classification Mark VDD-VSS Detection VCL_H VMSR VCL_ON VCU_H VUVLO_H VCU_OFF VUVLO_R Note: Variable names refer to Electrical Characteristic Table parameters Figure 18. Threshold Voltages Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 21 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com PoE Startup Sequence 50 mA/div The waveforms of Figure 19 demonstrate detection, classification, and startup from a PSE with type 2 hardware classification. The key waveforms shown are VVDD-VVSS, VRTN-VVSS, and IPI. IEEE 802.3at requires a minimum of two detection levels, two class and mark cycles, and startup from the second mark event. VRTN to VSS falls as the TPS23785B charges CIN following application of full voltage. Subsequently, the converter starts up, drawing current as seen in the IPI waveform. Cvtr. Starts Inrush IPI Class VVDD-VSS 10 V/div Mark Detect VRTN-VSS t - Time - 25 ms/div Figure 19. Startup Detection The TPS23785B drives DEN to VSS whenever VVDD-VVSS is below the lower classification threshold. When the input voltage rises above VCL-ON, the DEN pin goes to an open-drain condition to conserve power. While in detection, RTN is high impedance, and almost all the internal circuits are disabled. An RDEN of 24.9 kΩ (1%), presents the correct signature. It may be a small, low-power resistor since it only sees a stress of about 5 mW. A valid PD detection signature is an incremental resistance ( ΔV / ΔI ) between 23.75 kΩ and 26.25 kΩ at the PI. The detection resistance seen by the PSE at the PI is the result of the input bridge resistance in series with the parallel combination of RDEN and internal VDD loading. The input diode bridge’s incremental resistance may be hundreds of ohms at the very low currents drawn when 2.7 V is applied to the PI. The input bridge resistance is partially cancelled by the TPS23785B's effective resistance during detection. The type 2 hardware classification protocol of IEEE 802.3at specifies that a type 2 PSE drops its output voltage into the detection range during the classification sequence. The PD is required to have an incorrect detection signature in this condition, which is referred to as the mark event (see Figure 19). After the first mark event, the TPS23785B will present a signature less than 12 kΩ until it has experienced a VVDD-VVSS voltage below the mark reset (VMSR). This is explained more fully under Hardware Classification. 22 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Hardware Classification Hardware classification allows a PSE to determine a PD’s power requirements before powering, and helps with power management once power is applied. Type 2 hardware classification permits high power PSEs and PDs to determine whether the connected device can support high-power operation. A type 2 PD presents class 4 in hardware to indicate it is a high-power device. A type 1 PSE will treat a class 4 device like a class 0 device, allotting 13 W if it chooses to power the PD. A PD that receives a 2 event class understands that it is powered from a high-power PSE and it may draw up to 25.5 W immediately after the 80 ms startup period completes. A type 2 PD that does not receive a 2-event hardware classification may choose to not start, or must start in a 13 W condition and request more power through the DLL after startup. The standard requires a type 2 PD to indicate that it is underpowered if this occurs. Startup of a high-power PD under 13 W implicitly requires some form of powering down sections of the application circuits. The maximum power entries in Table 1 determine the class the PD must advertise. The PSE may disconnect a PD if it draws more than its stated Class power, which may be the hardware class or a lower DLL-derived power level. The standard permits the PD to draw limited current peaks that increase the instantaneous power above the Table 1 limit, however the average power requirement always applies. The TPS23785B implements two-event classification. Selecting an RCLS of 63.4 Ω provides a valid type 2 signature. TPS23785B may be used as a compatible type 1 device simply by programming class 0–3 per Table 1. DLL communication is implemented by the ethernet communication system in the PD and is not implemented by the TPS23785B. The TPS23785B disables classification above VCU_OFF to avoid excessive power dissipation. CLS voltage is turned off during PD thermal limit or when APD or DEN are active. The CLS output is inherently current limited, but should not be shorted to VSS for long periods of time. Figure 20 shows how classification works for the TPS23785B. Transition from state-to-state occurs when comparator thresholds are crossed (see Figure 17 and Figure 18). These comparators have hysteresis, which adds inherent memory to the machine. Operation begins at idle (unpowered by PSE) and proceeds with increasing voltage from left to right. A 2-event classification follows the (heavy lined) path towards the bottom, ending up with a latched type 2 decode along the lower branch that is highlighted. This state results in a low T2P during normal operation. Once the valid path to type 2 PSE detection is broken, the input voltage must transition below the mark reset threshold to start anew. Mark Reset Idle Class UVLO Falling Class Between Ranges Mark Class Between Ranges Mark Class Between Ranges Mark Detect Mark Reset TYPE 2 PSE Hardware Class UVLO Rising Operating T2P open-drain TYPE 1 PSE Hardware Class UVLO Rising Operating T2P low UVLO Falling Figure 20. Two-Event Class Internal States Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 23 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Inrush and Startup 802.3at has a startup current and time limitation, providing type 2 PSE compatibility for type 1 PDs. A type 2 PSE limits output current to between 400 mA and 450 mA for up to 75 ms after power-up (applying “48 V” to the PI) in order to mirror type 1 PSE functionality. The type 2 PSE will support higher output current after 75 ms. The TPS23785B implements a 140 mA inrush current, which is compatible with all PSE types. A high-power PD must control its converter startup peak and operational currents drawn to below 400 mA for 80 ms. The TPS23785B’s internal softstart permits control of the converter startup, however the application circuits must assure that their power draw does not cause the PD to exceed the current/time limitation. This requirement implicitly requires some form of powering down sections of the application circuits. T2P becomes valid within tT2P after switching starts, or if an adapter is plugged in while the PD is operating from a PSE. Maintain Power Signature The MPS is an electrical signature presented by the PD to assure the PSE that it is still present after operating voltage is applied. A valid MPS consists of a minimum dc current of 10 mA (or a 10 mA pulsed current for at least 75 ms every 225 ms) and an ac impedance lower than 26.25 kΩ in parallel with 0.05 μF. The ac impedance is usually accomplished by the minimum operating CIN requirement of 5 μF. When either APD or DEN is used to force the hotswap switch off, the dc MPS will not be met. A PSE that monitors the dc MPS will remove power from the PD when this occurs. A PSE that monitors only the ac MPS may remove power from the PD. 24 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Startup and Converter Operation The internal PoE UVLO (Under Voltage Lock Out) circuit holds the hotswap switch off before the PSE provides full voltage to the PD. This prevents the converter circuits from loading the PoE input during detection and classification. The converter circuits will discharge CIN, CVC, and CVB while the PD is unpowered. Thus VVDD-VRTN will be a small voltage just after full voltage is applied to the PD, as seen in Figure 19. The PSE drives the PI voltage to the operating range once it has decided to power up the PD. When VVDD rises above the UVLO turnon threshold (VUVLO-R, ~35 V) with RTN high, the TPS23785B enables the hotswap MOSFET with a ~140 mA (inrush) current limit as seen in Figure 21. Converter switching is disabled while CIN charges and VRTN falls from VVDD to nearly VVSS, however the converter startup circuit is allowed to charge CVC (the bootstrap startup capacitor). Converter switching is allowed if the PD is not in inrush, OTSD is not active, and the VC UVLO permits it. Once the inrush current falls about 10% below the inrush current limit, the PD current limit switches to the operational level (~970 mA). Continuing the startup sequence shown in Figure 21, VVC continues to rise until the startup threshold (VCUV, ~15 V or ~9 V) is exceeded, turning the startup source off and enabling switching. The VB regulator is always active, powering the internal converter circuits as VVC rises. There is a slight delay between the removal of charge current and the start of switching as the softstart ramp sweeps above the VZDC threshold. VVC falls as it powers both the internal circuits and the switching MOSFET gates. If the converter control bias output rises to support VVC before it falls to VCUV – VCUVH (~8.5 V or ~5.5 V), a successful startup occurs. T2P in Figure 19 becomes active within tT2P from the start of switching, indicating that a type 2 PSE or an adapter is plugged in. 10 5 V/div 99 88 200 mA/div T2P @ output Inrush I PI 7 66 10 V/div 5 PI Powered V C -RTN Switching starts 44 2 V/div 33 VOUT 2 11 50 V/div V DD -RTN 0 t - Time - 10 ms/div Figure 21. Power Up and Start If VVDD- VVSS drops below the lower PoE UVLO (VUVLO-R - VUVLO-H, ~30.5 V), the hotswap MOSFET is turned off, but the converter will still run. The converter will stop if VVC falls below the converter UVLO (VCUV – VCUVH, ~8.5 V or ~5.5 V), the hotswap is in inrush current limit, 0% duty cycle is demanded by VCTL (VCTL < VZDC, ~1.5 V), or the converter is in thermal shutdown. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 25 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com PD Hotswap Operation IEEE 802.3at has taken a new approach to PSE output limiting. A type 2 PSE must meet an output current vs. time template with specified minimum and maximum sourcing boundaries. The peak output current may be as high as 50 A for 10 μs or 1.75 A for 75 ms. This makes robust protection of the PD device even more important than it was in IEEE 802.3-2008. I PI CIN completes charge while converter operates 10 V/div 500 mA/div The internal hotswap MOSFET is protected against output faults and input voltage steps with a current limit and deglitched (time-delay filtered) foldback. An overload on the pass MOSFET engages the current limit, with VRTNVVSS rising as a result. If VRTN rises above ~12 V for longer than ~400 μs, the current limit reverts to the inrush value, and turns the converter off. The 400 μs deglitch feature prevents momentary transients from causing a PD reset, provided that recovery lies within the bounds of the hotswap and PSE protection. Figure 22 shows an example of recovery from a 16 V PSE rising voltage step. The hotswap MOSFET goes into current limit, overshooting to a relatively low current, recovers to ~950 mA full current limit, and charges the input capacitor while the converter continues to run. The MOSFET did not go into foldback because VRTN-VVSS was below 12 V after the 400 μs deglitch. V RTN-VSS 20 V/div 16 V Input step VRTN < 12 V @ 400 ms Recovery from PI dropout V VDD-VSS t - Time - 200 ms/div Figure 22. Response to PSE Step Voltage The PD control has a thermal sensor that protects the internal hotswap MOSFET. Conditions like startup or operation into a VDD to RTN short cause high power dissipation in the MOSFET. An over-temperature shutdown (OTSD) turns off the hotswap MOSFET and class regulator, which are restarted after the device cools. The hotswap MOSFET will be re-enabled with the inrush current limit when exiting from an over-temperature event. Pulling DEN to VSS during powered operation causes the internal hotswap MOSFET to turn off. This feature allows a PD with Option three ORing per Figure 23 to achieve adapter priority. Care must be taken with synchronous converter topologies that can deliver power in both directions. The hotswap switch will be forced off under the following conditions: 1. VAPD above VAPDEN (~1.5 V) 2. VDEN < VPD-DIS when VVDD– VVSS is in the operational range 3. PD over-temperature 4. (VVDD– VVSS) < PoE UVLO (~30.5 V). 26 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Converter Controller Features The TPS23785B dc/dc controller implements a typical current-mode control as shown in the Functional Block Diagram. Features include oscillator, over-current and PWM comparators, current-sense blanker, dead-time control, softstart, and gate driver. In addition, an internal slope-compensation ramp generator, frequency synchronization logic, thermal shutdown, and startup current source with control are provided. There is an offset of VZDC (~1.5 V) and 2:1 resistor divider between the CTL pin and the PWM. A VCTL below VZDC will stop converter switching, while voltages above (VZDC + (2 × VCSMAX)) will not increase the requested peak current in the switching MOSFET. Bootstrap Topology The internal startup current source and control logic implement a bootstrap-type startup as discussed in Startup and Converter Operation. The startup current source charges CVC from VDD1 when the converter is disabled (either by the PD control or the VC control) to store enough energy to start the converter. Steady-state operating power must come from a converter (bias winding) output or other source. Loading on VC and VB must be minimal while CVC charges, otherwise the converter may never start. The optocoupler will not load VB when the converter is off for most situations, however care should be taken in ORing topologies where the output is powered when PoE is off. The converter will shut off when VC falls below its lower UVLO. This can happen when power is removed from the PD, or during a fault on a converter output rail. When one output is shorted, all the output voltages fall including the one that powers VC. The control circuit discharges VC until it hits the lower UVLO and turns off. A restart will initiate as described in Startup and Converter Operation if the converter turns off and there is sufficient VDD1 voltage. This type of operation is sometimes referred to as hiccup mode which provides robust output short protection by providing time-average heating reduction of the output rectifier. The bootstrap control logic disables most of the converter controller circuits except the VB regulator and internal reference. Both GATE and GAT2 (assuming GAT2 is enabled) will be low when the converter is disabled. FRS, BLNK, and DT will be at ARTN while the VC UVLO disables the converter. While the converter runs, FRS, BLNK, and DT will be about 1.25 V. The startup current source transitions to a resistance as (VVDD1 – VVC) falls below 7 V, but will start the converter from adapters within tST. The lower test voltage for tST was chosen based on an assumed adapter tolerance, but is not meant to imply a hard cutoff exists. Startup takes longer and eventually will not occur as VDD1 decreases below the test voltage. The bootstrap source provides reliable startup from widely varying input voltages, and eliminates the continual power loss of external resistors. The startup current source will not charge above the maximum recommended VVC if the converter is disabled and there is sufficient VDD1 to charge higher. Current Slope Compensation and Current Limit Current-mode control requires addition of a compensation ramp to the sensed inductive (transformer or inductor) current for stability at duty cycles near and over 50%. The TPS23785B has a maximum duty cycle limit of 78%, permitting the design of wide input-range flyback converters with a lower voltage stress on the output rectifiers. While the maximum duty cycle is 78%, converters may be designed that run at duty cycles well below this for a narrower, 36 V to 57 V PI range. The TPS23785B provides a fixed internal compensation ramp that suffices for most applications. The TPS23785B provides internal, frequency independent, slope compensation (150 mV, VSLOPE) to the PWM comparator input for current-mode control-loop stability. This voltage is not applied to the current-limit comparator whose threshold is 0.55 V (VCSMAX). If the provided slope is not sufficient, the effective slope may be increased by addition of RS per Figure 27. The additional slope voltage is provided by (ISL-EX × RS). There is also a small dc offset caused by the ~2.5 μA pin current. The peak current limit does not have duty cycle dependency unless RS is used. This makes it easier to design the current limit to a fixed value. See Current Slope Compensation for more information. The internal comparators monitoring CS are isolated from the IC pin by the blanking circuits while GATE is low, and for a short time (blanking period) just after GATE switches high. A 440 Ω (max) equivalent pull down on CS is applied while GATE is low. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 27 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Blanking - RBLNK The TPS23785B provides a choice between internal fixed and programmable blanking periods. The blanking period is specified as an increase in the minimum GATE on time over the inherent gate driver and comparator delays. The default period (see the Electrical Characteristics table) is selected by connecting BLNK to RTN, and the programmable period is set with RBLNK. The TPS23785B blanker timing is precise enough that the traditional R-C filters on CS can be eliminated. This avoids current-sense waveform distortion, which tends to get worse at light output loads. There may be some situations or designers that prefer an R-C approach. The TPS23785B provides a pull-down on CS during the GATE off time to improve sensing when an R-C filter must be used. The CS input signal should be protected from nearby noisy signals like GATE drive and the switching MOSFET drain. Dead Time The TPS23785B features two switching MOSFET gate drivers to ease implementation of high-efficiency topologies such as a flyback converter with synchronous driver that is hard-driven by the control circuit. In these cases, there is a need to assure that both driven MOSFETs are not on at the same time. The DT pin programs a fixed time period delay between the turn-off of one gate driver until the turn-on of the next. This feature is an improvement over the repeatability and accuracy of discrete solutions while eliminating a number of discrete parts on the board. Converter efficiency is easily tuned with this one repeatable adjustment. The programmed dead time is the same for both GATE-to-GAT2 and GAT2-to-GATE transitions. The dead time is triggered from internal signals that are several stages back in the driver to eliminate the effects of gate loading on the period, however the observed and actual dead-time will be somewhat dependent on the gate loading. The turnoff of GAT2 coincides with the start of the internal clock period. DT may be used to disable GAT2, which goes to a high-impedance state. GATE’s phase turns the main switch on when it transitions high, and off when it transitions low. Likewise, GAT2’s phase turns the second switch on when it transitions high, and off during the dead time. The signal phasing is shown in Figure 1. Use of the two gate drives is shown in Figure 24 and the Typical Application Diagram. FRS and Synchronization The FRS pin programs the (free-running) oscillator frequency, and may also be used to synchronize the TPS23785B converter to a higher frequency. The internal oscillator sets the maximum duty cycle at 78% and controls the slope-compensation ramp circuit. Synchronization may be accomplished by applying a short pulse (TSYNC) of magnitude VSYNC to FRS as shown in Figure 26. The synchronization pulse terminates the potential on-time period, and the off-time period does not begin until the pulse terminates. T2P, Startup and Power Management T2P (type 2 PSE) is an active-low multifunction pin that indicates if: [(PSE = Type_2) + (VAPD > 1.5 V) + (VCTL < 4 V) × (pd current limit ≠ Inrush)] (5) The term with VCTL prevents an optocoupler connected to the secondary-side from loading VC before the converter is started. The APD terms allow the PD to operate from an adapter at high-power if a type 2 PSE is not present, assuming the adapter has sufficient capacity. Applications must monitor the state of T2P to detect power source transitions. Transitions could occur when a local power supply is added or dropped or when a PSE is enabled on the far end. The PD may be required to adjust the load appropriately. The usage of T2P is demonstrated in the Typical Application Diagram. In order for a type 2 PD to operate at less than 13 W the first 80 ms after power application, the various delays must be estimated and used by the application controller to meet the requirement. The bootup time of many applications processors may be long enough to eliminate the need to do any timing. 28 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Thermal Shutdown The dc/dc controller has an OTSD that can be triggered by heat sources including the VB regulator, GATE driver, bootstrap current source, and bias currents. The controller OTSD turns off VB, the GATE driver, and forces the VC control into an under-voltage state. Adapter ORing Many PoE-capable devices are designed to operate from either a wall adapter or PoE power. A local power solution adds cost and complexity, but allows a product to be used if PoE is not available in a particular installation. While most applications only require that the PD operate when both sources are present, the TPS23785B supports forced operation from either of the power sources. Figure 23 illustrates three options for diode ORing external power into a PD. Only one option would be used in any particular design. Option 1 applies power to the TPS23785B PoE input, option 2 applies power between the TPS23785B PoE section and the power circuit, and option 3 applies power to the output side of the converter. Each of these options has advantages and disadvantages. Many of the basic ORing configurations and discussion contained in application note Advanced Adapter ORing Solutions using the TPS23753 (literature number SLVA306), apply to the TPS23785B. The IEEE standards require that the Ethernet cable be isolated from ground and all other system potentials. The adapter must meet a minimum 1500 Vac dielectric withstand test between the output and all other connections for ORing options 1 and 2. The adapter only needs this isolation for option 3 if it is not provided by the converter. Adapter ORing diodes are shown for all the options to protect against a reverse voltage adapter, a short on the adapter input pins, and damage to a low-voltage adapter. ORing is sometimes accomplished with a MOSFET in option 3. -- RCLS D1 C1 From Spare Pairs or Transformers VPOE DEN CLS Low Voltage Output VDD1 RDEN + VDD From Ethernet Transformers Optional for PoE Priority Power Circuit VSS TPS23785B RTN Adapter Option 1 Adapter Option 2 Adapter Option 3 Figure 23. Adapter ORing Diodes Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 29 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Using DEN to Disable PoE The DEN pin may be used to turn the PoE hotswap switch OFF by pulling it to VSS while in the operational state, or to prevent detection when in the idle state. A low on DEN forces the hotswap MOSFET OFF during normal operation. Additional information is available in the Advanced Adapter ORing Solutions using the TPS23753 (literature number SLVA306) application report. ORing Challenges Preference of one power source presents a number of challenges. Combinations of adapter output voltage (nominal and tolerance), power insertion point, and which source is preferred determine solution complexity. Several factors adding to the complexity are the natural high-voltage selection of diode ORing (the simplest method of combining sources), the current limit implicit in the PSE, and PD inrush and protection circuits (necessary for operation and reliability). Creating simple and seamless solutions is difficult if not impossible for many of the combinations. However the TPS23785B offers several built-in features that simplify some combinations. Several examples will demonstrate the limitations inherent in ORing solutions. Diode ORing a 48 V adapter with PoE (option 1) presents the problem that either source might be higher. A blocking switch would be required to ensure which source was active. A second example is combining a 12 V adapter with PoE using option 2. The converter will draw approximately four times the current at 12 V from the adapter than it does from PoE at 48 V. Transition from adapter power to PoE may demand more current than can be supplied by the PSE. The converter must be turned off while CIN capacitance charges, with a subsequent converter restart at the higher voltage and lower input current. A third example is use of a 12 V adapter with ORing option 1. The PD hotswap would have to handle four times the current, and have 1/16 the resistance (be 16 times larger) to dissipate equal power. A fourth example is that MPS is lost when running from the adapter, causing the PSE to remove power from the PD. If ac power is then lost, the PD will stop operating until the PSE detects and powers the PD. 30 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 APPLICATION INFORMATION The TPS23785B supports many power supply topologies that require a single PWM gate drive or two complementary gate drives and will operate with current-mode control. The Typical Application Diagram and Figure 24 provide an example of a synchronous-rectification flyback that uses the second gate driver to control M2, the active element in the clamp. The TPS23785B may be used in topologies that do not require GAT2, which may be disabled to reduce its idling loss. Selecting a converter topology along with a design procedure is beyond the scope of this applications section. Examples to help in programming the TPS23785B are shown below. Additional special topics are included to explain the ORing capabilities, frequency dithering, and other design considerations. From Ethernet Pairs 1,2 For more specific converter design examples refer to the following application notes: • Designing with the TPS23753 Powered Device and Power Supply Controller, SLVA305 • Advanced Adapter ORing Solutions using the TPS23753, SLVA306A T1 DVC1 VT2P_OUT VB M2 ROB CIZ GAT2 RFBU VB GATE CS CCTL RCTL M1 TLV431 RFBL RCS CVC T2 CVB BLNK RTN, COM ARTN DT TPS23785B COUT2 RT2P_OUT RT2P COUT1 VDD1 VDD T2P RBLNK RFRS RAPD1 RAPD2 Adapter DA VOUT LOUT VC RDT DEN NC CLS PAD VSS APD CTL FRS RCLS 0.1uF From Ethernet Pairs 3,4 58V RDEN CIN CIO Figure 24. Example of Isolated Converter with TPS23785B Input Bridges and Schottky Diodes Using Schottky diodes instead of PN junction diodes for the PoE input bridges and DVDD will reduce the loss of this function by about 30%. There are however some things to consider when using them. The IEEE standard specifies a maximum backfeed voltage of 2.8 V. A 100 kΩ resistor is placed between the unpowered pairs and the voltage is measured across the resistor. Schottky diodes often have a higher reverse leakage current than PN diodes, making this a harder requirement to meet. Use conservative design for diode operating temperature, select lower-leakage devices where possible, and match leakage and temperatures by using packaged bridges to help with this. Schottky diode leakage current and lower dynamic resistance can impact the detection signature. Setting reasonable expectations for the temperature range over which the detection signature is accurate is the simplest solution. Increasing RDEN slightly may also help meet the requirement. Schottky diodes have proven less robust to the stresses of ESD transients, failing as a short or becoming leaky. Care must be taken to provide adequate protection in line with the exposure levels. This protection may be as simple as ferrite beads and capacitors. A general recommendation for the input rectifiers are 1 A or 2 A, 100 V rated discrete or bridge diodes. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 31 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Protection, D1 A TVS, D1, across the rectified PoE voltage per Figure 25 must be used. An SMAJ58A, or a part with equivalent or better performance, is recommended for general indoor applications. If an adapter is connected from VDD1 to RTN, as in ORing option 2 above, voltage transients caused by the input cable inductance ringing with the internal PD capacitance can occur. Adequate capacitive filtering or a TVS must limit this voltage to be within the absolute maximum ratings. Outdoor transient levels or special applications require additional protection. Use of diode DVDD for PoE priority may dictate the use of additional protection around the TPS23785B. ESD events between the PD power inputs, or the inputs and converter output, cause large stresses in the hotswap MOSFET if DVDD becomes reverse biased and transient current around the TPS23785B is blocked. The use of CVDD and DRTN in Figure 25 provides additional protection should over-stress of the TPS23785B be an issue. An SMAJ58A would be a good initial selection for DRTN. Individual designs may have to tune the value of CVDD. VDD1 CIN VDD RDEN DEN CLS COM ARTN VSS RTN RCLS D1 58V C 1 0.1?F DVDD D RTN 58V From Spare Pairs or Transformers From Ethernet Transformers C VDD 0.01?F Figure 25. Example of Added ESD Protection for PoE Priority Capacitor, C1 The IEEE 802.3at standard specifies an input bypass capacitor (from VDD to VSS) of 0.05 μF to 0.12 μF. Typically a 0.1 μF, 100 V, 10% ceramic capacitor is used. Detection Resistor, RDEN The IEEE 802.3at standard specifies a detection signature resistance, RDEN between 23.75 kΩ and 26.25 kΩ, or 25 kΩ ± 5%. Choose an RDEN of 24.9 kΩ. Classification Resistor, RCLS Connect a resistor from CLS to VSS to program the classification current according to the IEEE 802.3at standard. The class power assigned should correspond to the maximum average power drawn by the PD during operation. Select RCLS according to Table 1. For a high power design, choose class 4 and RCLS = 63.4 Ω. APD Pin Divider Network, RAPD1, RAPD2 The APD pin can be used to disable the TPS23785B internal hotswap MOSFET giving the adapter source priority over the PoE source. An example calculation is provided, see literature number SLVA306A. 32 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Setting Frequency (RFRS) and Synchronization The converter switching frequency is set by connecting RFRS from the FRS pin to ARTN. The frequency may be set as high as 1 MHz with some loss in programming accuracy as well as converter efficiency. Synchronization at high duty cycles may become more difficult above 500 kHz due to the internal oscillator delays reducing the available on-time. As an example: 1. Assume a desired switching frequency (fSW) of 250 kHz. 2. Compute RFRS: 17250 17250 RFRS (k W ) = = = 69 fSW (kHz) 250 (a) (b) Select 69.8 kΩ. VSYNC TSYNC RFRS FRS 47pF VSYNC TSYNC 1000pF RTN ARTN COM 47pF Synchronization Pulse RFRS FRS RT Synchronization Pulse RTN ARTN COM The TPS23785B may be synchronized to an external clock to eliminate beat frequencies from a sampled system, or to place emission spectrum away from an RF input frequency. Synchronization may be accomplished by applying a short pulse (TSYNC) of magnitude VSYNC to FRS as shown in Figure 26. RFRS should be chosen so that the maximum free-running frequency is just below the desired synchronization frequency. The synchronization pulse terminates the potential on-time period, and the off-time period does not begin until the pulse terminates. The pulse at the FRS pin should reach between 2.5 V and VB, with a minimum width of 22 ns (above 2.5 V) and rise/fall times less than 10 ns. The FRS node should be protected from noise because it is high-impedance. An RT on the order of 100 Ω in the isolated example reduces noise sensitivity and jitter. 1:1 Figure 26. Synchronization Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 33 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Current Slope Compensation The TPS23785B provides a fixed internal compensation ramp that suffices for most applications. RS (see Figure 27) may be used if the internally provided slope compensation is not enough. Most current-mode control papers and application notes define the slope values in terms of VPP/TS (peak ramp voltage / switching period), however the electrical characteristics table specifies the slope peak (VSLOPE) based on the maximum (78%) duty cycle. Assuming that the desired slope, VSLOPE-D (in mV/period), is based on the full period, compute RS per the following equation where VSLOPE, DMAX, and ISL-EX are from the electrical characteristics table with voltages in mV, current in μA, and the duty cycle is unitless (e.g., DMAX = 0.78). é æ VSLOPE (mV) ö ù ê VSLOPE_D (mV) - ç ÷ú DMAX è ø ûú ëê ´ 1000 RS (W) = ISL_EX (mA) (6) RTN COM ARTN GATE CS RS CS RCS Figure 27. Additional Slope Compensation CS may be required if the presence of RS causes increased noise, due to adjacent signals like the gate drive, to appear at the CS pin. 34 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Blanking Period, RBLNK Selection of the blanking period is often empirical because it is affected by parasitics and thermal effects of every device between the gate-driver and output capacitors. The minimum blanking period prevents the current limit and PWM comparators from being falsely triggered by the inherent current spike that occurs when the switching MOSFET turns on. The maximum blanking period is bounded by the output rectifier's ability to withstand the currents experienced during a converter output short. If blanking beyond the internal default is desired choose RBLNK using RBLNK (kΩ) = tBLNK (ns). 1. For a 100 ns blanking interval (a) RBLNK (kΩ) = 100 (b) Choose RBLNK = 100 kΩ. The blanking interval can also be chosen as a percentage of the switching period. 1. Compute RBLNK as follows for 2% blanking interval in a switcher running at 250 kHz. BIanking_Interval(%) 2 RBLNK (k W ) = ´ 10 4 = ´ 10 4 = 80 f (kHz) 250 SW (a) (b) Select RBLNK = 80.6 kΩ. Dead Time Resistor, RDT The required dead time period depends on the specific topology and parasitics. The easiest technique to obtain the optimum timing resistor is to build the supply and tune the dead time to achieve the best efficiency after considering all corners of operation (load, input voltage, and temperature). A good initial value is 100 ns. Program the dead time with a resistor connected from DT to ARTN per Equation 3. 1. Choose RDT as follows assuming a tDT of 100 ns: t (ns) 100 RDT (kW) = DT = = 50 2 2 (a) (b) Choose RDT = 49.9 kΩ Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 35 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Estimating Bias Supply Requirements and CVC The bias supply (VC) power requirements determine the CVC sizing and frequency of hiccup during a fault. The first step is to determine the power/current requirements of the power supply control, then use this to select CVC. The control current draw will be assumed constant with voltage to simplify the estimate, resulting in an approximate value. First determine the switching MOSFET gate drive power. 1. Let VQG be the gate voltage swing that the MOSFET QG is rated to (often 10 V). æ VC PGATE = VC ´ fSW ´ ç QGATE ´ ç VQG è ö æ VC ÷÷ PGAT2 = VC ´ fSW ´ çç QGATE2 ´ VQG ø è ö ÷÷ ø (a) (b) Compute gate drive power if VC is 12 V, QGATE is 17 nC, and QGAT2 is 8 nC. 12 PGATE = 12 V ´ 250 kHz ´ 17 nC ´ = 61.2 mW 10 12 PG AT2 = 12 V ´ 250 kHz ´ 8 nC ´ = 28.8 mW 10 (c) PDRIVE = 61.2 mW + 28.8 mW = 90 mW (d) This illustrates why MOSFET QG should be an important consideration in selecting the switching MOSFETs. 2. Estimate the required bias current at some intermediate voltage during the CVC discharge. For the TPS23785B, 12 V provides a reasonable estimate. Add the operating bias current to the gate drive current. P 90 mW IDRIVE = DRIVE = = 7.5 mA V 12 V C (a) (b) ITOTAL = IDRIVE + IOPERATING = 7.5 mA + 0.92 mA = 8.42 mA 3. Compute the required CVC based on startup within the typical softstart period of approximately 4 ms. CVC1 + CVC2 = TSTARTUP ´ ITOTAL 4 ms ´ 8.42 mA = = 5.18 mF VCUVH 6.5 V (a) (b) For this case, a standard 10 μF electrolytic plus a 0.47 μF should be sufficient. 4. Compute the initial time to start the converter when operating from PoE. (a) Using a typical bootstrap current of 4 mA, compute the time to startup. C ´ VCUV 10.47 mF ´ 15 V TST = VC1 = = 39 ms IVC 4 mA (b) 5. Compute the fault duty cycle and hiccup frequency (C VC1 + CVC2 ) ´ VCUVH (10 mF + 0.47 mF) ´ 6.5 V TRECHARGE = = = 17 m s IVC 4 mA (a) (C VC1 + CVC2 ) ´ VCUVH (10 mF + 0.47 mF) ´ 6.5V TDISCHARGE = = = 8.08 ms ITOTAL 8.42 m A (b) (a) Note that the optocoupler current is 0 mA because the output is in current limit. (b) Also, it is assumed IT2P is 0 mA. TDISCHARGE 8.08 ms Duty Cycle: D = = = 32% T + T 8.08 ms + 17 ms DISCHARGE RECHARGE (c) 1 1 Hiccup Frequency: F = = = 39.9 Hz T + T 8.08 ms + 17 ms DISCHARGE RECHARGE (d) 6. With the TPS23785B, the voltage rating of CVC1 and CVC2 should be 25 V minimum. 36 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Switching Transformer Considerations and RVC Care in design of the transformer and VC bias circuit is required to obtain hiccup overload protection. Leadingedge voltage overshoot on the bias winding may cause VC to peak-charge, preventing the expected tracking with output voltage. Some method of controlling this is usually required. This may be as simple as a series resistor, or an R-C filter in front of DVC1. Good transformer bias-to-output-winding coupling results in reduced overshoot and better voltage tracking. RVC as shown in Figure 28 helps to reduce peak charging from the bias winding. This becomes especially important when tuning hiccup mode operation during output overload. Typical values for RVC will be between 10 Ω and 100 Ω. ARTN RVC DVC1 T1 Bias Winding CVC VC Figure 28. RVC Usage Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 37 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com T2P Pin Interface The T2P pin is an active low, open-drain output indicating a high power source is available. An optocoupler is typically used to interface with the T2P pin to signal equipment on the secondary side of the converter of T2P status. Optocoupler current-gain is referred to as CTR (current transfer ratio), which is the ratio of transistor collector current to LED current. To preserve efficiency, a high-gain optocoupler ( 250% ≤ CTR ≤ 500%, or 300% ≤ CTR ≤ 600% ) along with a high-impedance (e.g., CMOS) receiver are recommended. Design of the T2P optocoupler interface can be accomplished as follows: 1. T2P ON characteristic: IT2P = 2 mA minimum, VT2P = 1 V 2. Let VC = 12 V, VOUT = 5 V, RT2P-OUT = 10 kΩ, VT2P-OUT (low) = 400 mV max V - VT2P-OUT (low) 5 - 0.4 IRT2P-OUT = OUT = = 0.46 m A R 10000 T2P-OUT (a) 3. The optocoupler CTR will be needed to determine RT2P. A device with a minimum CTR of 300% at 5 mA LED bias current is selected. CTR will also vary with temperature and LED bias current. The strong variation of CTR with diode current makes this a problem that requires some iteration using the CTR versus IDIODE curve on the optocoupler data sheet. (a) Using the (normalized) curves, a current of 0.4 mA to 0.5 mA is required to support the output current at the minimum CTR at 25°C. (a) Pick an IDIODE. For example one around the desired load current. (b) Use the optocoupler datasheet curve to determine the effective CTR at this operating current. It is usually necessary to apply the normalized curve value to the minimum specified CTR. It might be necessary to ratio or offset the curve readings to obtain a value that is relative to the current that the CTR is specified at. (c) If IDIODE × CTRI_DIODE is substantially different from IRT2P_OUT, choose another IDIODE and repeat. (b) This manufacturer’s curves also indicate a –20% variation of CTR with temperature. The approximate forward voltage of the optocoupler diode is 1.1 V from the data sheet. 100 100 IRT2P @ IMIN ´ = 0.5 mA ´ = 0.625 mA 100 - D CTRTEMP 100 - 20 (c) VFLED = 1.1 V V - VT2P - VFLED 12 - 1 - 1.1 RT2P = C = = 15.48 kW IRT2P 0.625 mA (d) Select a 15.4 kΩ resistor. Even though the minimum CTR and temperature variation were considered, the designer might choose a smaller resistor for a little more margin. VOUT VC RT2P RT2P_OUT Type 2 PSE Indicator Low = T2 T2P From TPS23785B Figure 29. T2P Interface 38 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated TPS23785B www.ti.com SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 Softstart Converters require a softstart on the voltage error amplifier to prevent output overshoot on startup. Figure 30 shows a common implementation of a secondary-side softstart that works with the typical TL431 error amplifier. The softstart components consist of DSS, RSS, and CSS. They serve to control the output rate-of-rise by pulling VCTL down as CSS charges through ROB, the optocoupler, and DSS. This has the added advantage that the TL431 output and CIZ are preset to the proper value as the output voltage reaches the regulated value, preventing voltage overshoot due to the error amplifier recovery. The secondary-side error amplifier will not become active until there is sufficient voltage on the secondary. The TPS23785B provides a primary-side softstart which persists long enough (~4 ms) for secondary side voltage-loop softstart to take over. The primary-side currentloop softstart controls the switching MOSFET peak current by applying a slowly rising ramp voltage to a second PWM control input. The PWM is controlled by the lower of the softstart ramp or the CTL-derived current demand. The actual output voltage rise time is usually much shorter than the internal softstart period. Initially the internal softstart ramp limits the maximum current demand as a function of time. Either the current limit, secondary-side softstart, or output regulation assume control of the PWM before the internal softstart period is over. Figure 21 shows a smooth handoff between the primary and secondary-side softstart with minimal output voltage overshoot. From Regulated Output Voltage ROB RSS CIZ DSS CSS RFBU RFBL TLV431 Figure 30. Error Amplifier Soft Start Thermal Considerations and OTSD Sources of nearby local PCB heating should be considered during the thermal design. Typical calculations assume that the TPS23785B is the only heat source contributing to the PCB temperature rise. It is possible for a normally operating TPS23785B device to experience an OTSD event if it is excessively heated by a nearby device. Copyright © 2012, Texas Instruments Incorporated Submit Documentation Feedback 39 TPS23785B SLUSB90A – DECEMBER 2012 – REVISED DECEMBER 2012 www.ti.com Frequency Dithering for Conducted Emissions Control The international standard CISPR 22 (and adopted versions) is often used as a requirement for conducted emissions. Ethernet cables are covered as a telecommunication port under section 5.2 for conducted emissions. Meeting EMI requirements is often a challenge, with the lower limits of Class B being especially hard. Circuit board layout, filtering, and snubbing various nodes in the power circuit are the first layer of control techniques. A more detailed discussion of EMI control is presented in Practical Guidelines to Designing an EMI Compliant PoE Powered Device With Isolated Flyback, TI literature number SLUA469. Additionally, IEEE802.3at sections 33.3 and 33.4 have requirements for noise injected onto the Ethernet cable based on compatibility with data transmission. Occasionally, a technique referred to as frequency dithering is utilized to provide additional EMI measurement reduction. The switching frequency is modulated to spread the narrowband individual harmonics across a wider bandwidth, thus lowering peak measurements. The circuit of Figure 31 modulates the switching frequency by feeding a small ac signal into the FRS pin. These values may be adapted to suit individual needs. 10kW 49.9kW VB + - 6.04kW TL331IDBV 4.99kW 0.01mF 10kW 301kW 1mF To FRS ARTN Figure 31. Frequency Dithering REVISION HISTORY Changes from Original (December 2012) to Revision A • 40 Page Changed PRODUCT INFORMATION table. ........................................................................................................................ 2 Submit Documentation Feedback Copyright © 2012, Texas Instruments Incorporated PACKAGE OPTION ADDENDUM www.ti.com 24-Jan-2013 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Qty Drawing Eco Plan Lead/Ball Finish (2) MSL Peak Temp Op Temp (°C) Top-Side Markings (3) (4) TPS23785BPWP ACTIVE HTSSOP PWP 24 60 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR -40 to 125 TPS23785B TPS23785BPWPR ACTIVE HTSSOP PWP 24 2000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR -40 to 125 TPS23785B (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. (4) Only one of markings shown within the brackets will appear on the physical device. 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Addendum-Page 1 Samples PACKAGE MATERIALS INFORMATION www.ti.com 26-Jan-2013 TAPE AND REEL INFORMATION *All dimensions are nominal Device TPS23785BPWPR Package Package Pins Type Drawing SPQ HTSSOP 2000 PWP 24 Reel Reel A0 Diameter Width (mm) (mm) W1 (mm) 330.0 16.4 Pack Materials-Page 1 6.95 B0 (mm) K0 (mm) P1 (mm) 8.3 1.6 8.0 W Pin1 (mm) Quadrant 16.0 Q1 PACKAGE MATERIALS INFORMATION www.ti.com 26-Jan-2013 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) TPS23785BPWPR HTSSOP PWP 24 2000 367.0 367.0 38.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest issue. 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