M81709FP

M81709FP Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 HVIC High Voltage Half-Bridge Driver 600 Volts/±2A 16 9 D E RECOMMENDED MOUNT PAD T R AC S 1 8 DETAIL "A" DETAIL "B" DETAIL "A" H J PIN NUMBER 1 2 3 4 5 6 7 8 LO GND VCC2 NC NC VS VB HO 9 10 11 12 13 14 15 16 NC NC NC HIN NC LIN GND NC B N DETAIL "B" E G FxU Q P K L M Description: M81709FP is a high voltage Power MOSFET and IGBT module driver for half-bridge applications. Features: £ Shoot Through Interlock £ Output Current ±2A £ Half-Bridge Driver £ SOP-16 Package Applications: £ HID Ballast £ PDP £ MOSFET Driver £ IGBT Driver £ Inverter Module Control Ordering Information: M81709FP is a ±2A, 600 Volt HVIC, High Voltage Half-Bridge Driver 7 VB VREG HV LEVEL SHIFT UV DETECT FILTER INTER LOCK PULSE GEN UV DETECT FILTER LIN 14 VREG/VCC LEVEL SHIFT DELAY RQ R S 8 HO HIN 12 VREG/VCC LEVEL SHIFT 6 VS 3 VCC 1 LO 2 GND GND 15 Outline Drawing and Circuit Diagram Dimensions A B C D E F G H J K Inches 0.31±0.01 0.41±0.004 0.21±0.004 0.12 0.05 0.02±0.002 0.004 0.07 0.01±0.004 0.05 Millimeters 7.8±0.3 10.1±0.1 5.3±0.1 2.10 1.27 0.4±0.05 0.1 1.8 0.1±0.1 1.25 Dimensions L M N P Q R S T U Inches 0.024±0.008 0.1±0.002 8° 0.03 0.023 0.05 Min. 0.30 0.029 0.098 Dia. Millimeters 0.6±0.2 0.2±0.05 8° 0.755 0.605 1.27 Min. 7.62 0.76 0.25 Dia. 6/05 1 Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M81709FP HVIC, High Voltage Half-Bridge Driver 600 Volts/±2A Absolute Maximum Ratings, Ta = 25°C unless otherwise specified Characteristics High Side Floating Supply Absolute Voltage High Side Floating Supply Offset Voltage High Side Floating Supply Voltage (VBS = VB – VS) High Side Output Voltage Low Side Fixed Supply Voltage Low Side Output Voltage Logic Input Voltage (HIN, LIN) Allowable Offset Voltage Transient Package Power Dissipation (Ta = 25°C, On Board) Linear Derating Factor (Ta > 25°C, On Board) Junction to Case Thermal Resistance Junction Temperature Operation Temperature Storage Temperature Symbol VB VS VBS VHO VCC VLO VIN dVs/dt Pd Kθ Rth(j-c) Tj Topr Tstg M81709FP -0.5 ~ 624 VB-24 ~ VB+0.5 -0.5 ~ 24 VS-0.5 ~ VB+0.5 -0.5 ~ 24 -0.5 ~ VCC+0.5 -0.5 ~ VCC+0.5 ±50 0.9 9.0 50 -20 ~ 125 -20 ~ 100 -40 ~ 125 Units Volts Volts Volts Volts Volts Volts Volts V/ns Watts mW/°C °C/W °C °C °C Recommended Operating Conditions Characteristics High Side Floating Supply Absolute Voltage High Side Floating Supply Offset Voltage High Side Floating Supply Voltage High Side Output Voltage Low Side Fixed Supply Voltage Logic Supply Voltage Logic Input Voltage Symbol VB VS VBS VHO VCC VLO VIN HIN, LIN VB > 10V VB = VB – VS Test Conditions Min. VS+10 -5 10 VS 10 0 0 Typ. — — — — — — — Max. VS+20 500 20 VB 20 VCC VCC Units Volts Volts Volts Volts Volts Volts Volts Electrical Characteristics Ta = 25°C, VCC = VBS (= VB – VS) = 15V unless otherwise specified Characteristics Floating Supply Leakage Current VBS Standby Current VCC Standby Current High Level Output Voltage Low Level Output Voltage High Level Input Threshold Voltage Low Level Input Threshold Voltage High Level Input Bias Current Low Level Input Bias Current VBS Supply UV Reset Voltage VBS Supply UV Hysteresis Voltage VBS Supply UV Filter Time VCC Supply UV Reset Voltage 2 Symbol IFS IBS ICC VOH VOL VIH VIL IIH IIL VBSuvr VBSuvh tVBSuv VCCuvr Test Conditions VB = VS = 600V HIN = LIN = 0V HIN = LIN = 0V IO = 0A, LO, HO IO = 0A, LO, HO HIN, LIN HIN, LIN VIN = 5V VIN = 0V Min. — — 0.2 13.8 — 2.1 0.6 — — 8.0 0.3 — 8.0 Typ. — 0.2 0.5 14.4 — 3.0 1.5 25 — 8.9 0.7 7.5 8.9 Max. 1.0 0.5 1.0 — 0.1 4.0 2.0 75 1.0 9.8 — — 9.8 Units µA mA mA Volts Volts Volts Volts µA µA Volts Volts µs Volts 6/05 Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M81709FP HVIC, High Voltage Half-Bridge Driver 600 Volts/±2A Electrical Characteristics Ta = 25°C, VCC = VBS (= VB – VS) = 15V unless otherwise specified Characteristics VCC Supply UV Hysteresis Voltage VCC Supply UV Filter Time Output High Level Short Circuit Pulsed Current Output Low Level Short Circuit Pulsed Current Output High Level ON Resistance Output Low Level ON Resistance High Side Turn-On Propagation Delay High Side Turn-Off Propagation Delay High Side Turn-On Rise Time High Side Turn-Off Fall Time LowSide Turn-On Propagation Delay Low Side Turn-Off Propagation Delay Low Side Turn-On Rise Time Low Side Turn-Off Fall Time Delay Matching, High Side and Low Side Turn-On Delay Matching, High Side and Low Side Turn-Off Symbol VCCuvh tVCCuv IOH IOL ROH ROL tdLH(HO) tdHL(HO) trH tfH tdLH(LO) tdHL(LO) trL tfL ΔtdLH ΔtdHL VO = 0V, VIN = 5V, PW < 10µs VO = 15V, VIN = 0V, PW < 10µs IO = -200mA, ROH = (VOH – VO)/IO IO = 200mA, ROL = VO /IO CL = 1000pF between HO – VS CL = 1000pF between HO – VS CL = 1000pF between HO – VS CL = 1000pF between HO – VS CL = 1000pF between LO – GND CL = 1000pF between LO – GND CL = 1000pF between LO – GND CL = 1000pF between LO – GND | tdLH(HO) – tdLH(LO) | | tdHL(HO) – tdHL(LO) | Test Conditions Min. 0.3 — — — — — 100 100 — — 100 100 — — — — Typ. 0.7 7.5 2.5 2.5 10 2.5 135 135 20 15 135 135 20 15 — — Max. — — — — 13 3.0 170 170 35 25 170 170 35 25 30 30 Units Volts µs A A Ω Ω ns ns ns ns ns ns ns ns ns ns THERMAL DERATING FACTOR CHARACTERISTICS 2.0 PACKAGE POWER DISSIPATION, Pd, (WATTS) 1.5 1.0 0.5 0 0 25 50 75 100 125 TEMPERATURE, (°C) FUNCTION TABLE (X : HORL) HIN LIN VBS UV VCC UV L L H H L H H H H L H H H H H H X L L H X H L H L X H L H X H L HO L L H L L L L L LO L H L L L H L L Behavorial State LO = HO = Low LO = High HO = High LO = HO = Low HO = Low, VBS UV Tripped LO = High, VBS UV Tripped LO = Low, VCC UV Tripped HO = LO = Low, VCC UV Tripped NOTE: “L” state of VBS UV, VCC UV means that UV trip voltage. In the case of both input signals (HIN and LIN) are “H”, output signals (HO and LO) become “L”. 6/05 3 Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M81709FP HVIC, High Voltage Half-Bridge Driver 600 Volts/±2A TIMING DIAGRAM 1. Input/Output Timing Diagram HIGH ACTIVE – When input signal (HIN or LIN) is “H”, then output signal (HO or LO) is “H”. In the case of both input signals (HIN and LIN) are “H”, then output signals (HO and LO) become “L”. HIN LIN HO LO 2. VCC(VBS) Supply Under Voltage Lockout Timing Diagram When VCC supply voltage keeps lower UV trip voltage (VCCuvt = VCCuvr – VCCuvh) for VCC supply UV filter time, output signal becomes “L”. And then, when VCC supply voltage is higher than UV reset voltage, output signal LO becomes “H”. VCC VCCuvt tVCCuv LO LIN When VCC supply voltage keeps lower UV trip voltage (VCCuvt = VCCuvr – VCCuvh) for VCC supply UV filter time, output signal becomes “L”. And then, when VCC supply voltage is higher than UV reset voltage, input signal (LIN) is “L”; output signal HO becomes “H”. VBS(H) LIN(L) VCC VCCuvt tVCCuv HO HIN When VBS supply voltage keeps lower UV trip voltage (VBSuvt = VBSuvr – VBSuvh) for VBS supply UV filter time, output signal becomes “L”. And then, VBS supply voltage is higher than UV reset voltage, output signal HO keeps “L” until next input signal HIN is “H”. VBS VBSuvt tVBSuv HO HIN VBSuvh VBSuvr VCCuvh VCCuvr VCCuvh VCCuvr 3. Allowable Supply Voltage Transient It is recommended supplying VCC first and supplying VBS second. In the case of shutting off supply voltage, shut off VBS firstly and shut off VCC second. At the time of starting VCC and VBS, power supply should be increased slowly. If it is increased rapidly, output signal (HO or LO) may be “H”. 4 6/05