M63954P HVIC Half-Bridge Driver Description: M63954P is a high voltage integrated circuit designed for electronic ballast, Power MOSFET and IGBT module driver for half-bridge applications. e1 9 E 16 c Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 Features: □ 600V Floating Supply Voltage 8 0 1 D A2 b1 □ Built-In Oscillator A1 A □ Half-Bridge Driver L SEATING PLANE □ ±500mA Output Current □ DIP–16 Package b2 □ Built-In Regulator b e 1 16 CNT VCO 2 15 OV CVCO 3 14 GND RVCO 4 13 LO M63954P VREG AB 5 12 VCC ABTH 6 11 HVCC LNTH 7 10 HO LN 8 9 Application: The M63954P is designed for use in electronic ballasts for fluorescent lamps. HGND Outline Drawing and Pin Diagram Dimensions A A1 A2 b Inches 0.18 Max. 0.02 Min. 0.13 0.02±0.004 Millimeters Dimensions Inches Millimeters 4.5 Max. D 0.75±0.01 19.0±0.2 0.51 Min. E 0.25±0.01 6.3±0.15 3.3 e 0.10 2.54 0.5±0.1 e1 0.31 7.62 b1 0.06+0.01/-0.004 1.5+0.3/-0.1 L 0.12 Min. 3.0 Min. b2 0.04+0.01/-0.004 1.0+0.3/-0.1 u 0° – 15° 0° – 15° c 0.01 0.27+0.07/-0.05 1 Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M63954P HVIC Half-Bridge Driver Absolute Maximum Ratings, Ta = 25°C unless otherwise specified Ratings Symbol High Side Floating Supply Offset Voltage HGND High Side Floating Supply Voltage HVCC Test Conditions HGND = GND M63954P Units 600 Volts -0.5 ~ 20 Volts Low Side Fixed Supply Voltage VCC -0.5 ~ 20 Volts OV Input Voltage VOV -0.5 ~ VCC+0.5 Volts AB Input Voltage VAB -0.5 ~ VCC+1.0 Volts AB Input Current IAB 2 mA VABTH -0.5 ~ VCC+0.5 Volts VLN -0.5 ~ VCC+1.0 Volts ABTH Input Voltage LN Input Voltage LN Input Current ILN 2 mA LNTH Input Voltage VLNTH -0.5 ~ VCC+0.5 Volts VCO Input Voltage VVCO -0.5 ~ VCC+0.5 Volts High Side Output Current IHO ±500 mA Low Side Output Current ILO ±500 mA Package Power Dissipation Pt Ta = 25°C, On Board 1.67 W Linear Derating Factor KU Ta > 25°C, On Board 13.3 mW/°C Junction Temperature Tj 150 °C Operation Temperature Topr -20 ~ 80 °C Storage Temperature Tstg -40 ~ 125 °C Output Frequency, RVCO1 = 15kΩ, RVCO2 = 39kΩ, CVCO = 100pF Oscillation Frequency 2 VCO Input Voltage Min. Typ. Max. Units 50kHz 0.33VREG — 50 — kHz 60kHz 0.42VREG — 60 — kHz Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M63954P HVIC Half-Bridge Driver Electrical Characteristics, HGND = GND, HVCC = VCC = 15V, Ta = 25°C, unless otherwise specified Characteristics Symbol Test Conditions Min. Typ. Max. Units 13 15 17 Volts 13 15 17 Volts General High Side Floating Supply Voltage Low Side Fixed Supply Voltage HVCC HVCC – HGND VCC Internal Supply Voltage VREG VCC = 15V, No Load 6.9 7.2 7.5 Volts Standby Current ICC1 VCC = 15V, CNT = 5V, OV = 5V — 0.75 1 mA ON Suspension Oscillate Current ICC2 VCC = 15V, CNT = 0V — 2 4 mA ON Oscillation Current (50kHz) ICC3 VCC = 15V, RVCO1 = 15kΩ, 2 5 8 mA ON Oscillation Current (115kHz) ICC4 RVCO2 = 39kΩ CVCO = 100pF, 2 8 12 mA VVCO = 0.33 VREG VVCO = 0.42 VREG UV Voltage VCC UV Reset Voltage VUVr 9.0 10.0 11.0 Volts VCC UV Trip Voltage VUVt 5.5 6.5 7.5 Volts tUV 14 — 100 µs OV Protection Vth VOV 3.4 3.6 3.8 Volts OV Response Delay Time tOV 30 — 150 µs OV Input Leak Current IOV -0.5 -0.08 — µA — — 250 kHz — — 125 kHz UV Response Delay Time OV Voltage VOV = 0V VCO Voltage VCO Frequency Set Up Limit fVCO Output Frequency Set Up Limit fO VCO Input Voltage Limit VVCO VCO Input Leak Current IVCO LO, HO 1.5 — VREG-1.5 Volts VVCO = 0V -2 -0.66 — µA CVCO Input Voltage VCVCO VREG = 7.2V 5.5 5.55 5.6 Volts CVCO Input Leak Current ICVCO VCVCO = 0V, VVCO > VCVCO -2 -0.66 — µA IrRVCO VCVCO = 0V, VREG = 7.2V, VRVCO = 10V — — 0.5 µA VSRVCO VCVCO = 6V, VREG = 7.2V, IRVCO = 10mA — — 500 mV RVCO Leak Current RVCO Saturation Voltage 3 Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M63954P HVIC Half-Bridge Driver Electrical Characteristics, HGND = GND, HVCC = VCC = 15V, Ta = 25°C, unless otherwise specified Characteristics Symbol Test Conditions Min. Typ. Max. Units 1 — VCC-1.5 Volts Connection Detect LN Input Voltage Limit VLN LNTH Input Voltage Limit VLNTH 1 — VCC-1.5 Volts LN Offset Voltage VLNIO -50 — 50 mV ILN VLN < VLNTH -1.0 -0.22 — µA LNTH Input Leak Current ILNTH VLN > VLNTH, VCC < VUVr -1.0 -0.22 — µA LNTH Input Hysteresis Current ILNTHh VLN > VLNTH, VLNTH = 5V LN Input Leak Current LN Response Delay Time 20 40 80 µA tLN 14 — 100 µs VAB 0 — VREG-1.5 Volts Abnormal Detect AB Input Voltage Limit ABTH Input Voltage Limit VABTH 0 — VREG-1.5 Volts AB Offset Voltage VABIO -50 — 50 mV IAB VAB < VABTH -0.5 -0.08 — µA ABTH Input Leak Current IABTH VAB > VABTH -0.5 -0.08 — µA AB Response Delay Time tAB 30 — 150 µs CNT Input Threshold Voltage VCNT 3.4 3.6 3.8 Volts CNT Input Hysteresis Voltage VCNTh 0.8 1.0 1.2 Volts -0.5 -0.08 — µA 30 — 150 µs — — 2.0 µA AB Input Leak Current External CNT CNT Input Leak Current ICNT CNT Response Delay Time tCNT VCNT = 0V Driver Floating Supply Leak Current IRFC VHGND = 600V Dead Time tDEAD C = 1000pF 1.0 — 1.9 µs HO Output Voltage VHOH1 IHO = 0mA 14.0 14.4 — Volts LO Output Voltage 4 VHOH2 IHO = -20mA 10 13 — Volts VHOH3 IHO = -200mA 1.0 5.5 — Volts VHOL1 IHO = 0mA — 5 100 mV VHOL2 IHO = 20mA — 0.5 1.0 Volts VHOL3 IHO = 200mA — 6 12 Volts VLOH1 ILO = 0mA 14.0 14.4 — Volts VLOH2 ILO = -20mA 10 13 — Volts VLOH3 ILO = -200mA 1.0 5.5 — Volts VLOL1 ILO = 0mA — 5 100 mV VLOL2 ILO = 20mA — 0.5 1.0 Volts VLOL3 ILO = 200mA — 6 12 Volts Output Rise Time tr Amplitude 10% → 90%, C = 1000pF — 50 120 ns Output Fall Time tf Amplitude 90% → 10%, C = 1000pF — 50 120 ns Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M63954P HVIC Half-Bridge Driver THERMAL DERATING FACTOR CHARACTERISTICS (TYPICAL) VREG VS. VCC CHARACTERISTIC ICC VS. VCC CHARACTERISTIC 2.0 INTERNAL SUPPLY VOLTAGE, VREG, (VOLTS) 6 OSCILLATION CURRENT, ICC, (mA) 1.67 1.5 On Circuit Board 1.25 1.0 0.93 0.7 0.5 No Circuit Board 0 0 25 50 75 100 125 50kHz 4 3 Oscillation Suspension 2 Standby 1 0 150 8 1.3 tDEAD2 1.2 1.1 18 -200 mA 10 5 INTERNAL SUPPLY VOLTAGE, VREG, (VOLTS) 4 ICC3 ICC2 1 0 -50 ICC1 0 50 100 AMBIENT TEMPERATURE, Ta, (°C) 18 200 mA 6 4 2 150 0 mA 20 mA 0 23 8 13 18 23 LOW SIDE FIXED SUPPLY VOLTAGE, VCC, (VOLTS) VUV VS. Ta CHARACTERISTIC VREG VS. Ta CHARACTERISTIC ICC4 2 13 8 LOW SIDE FIXED SUPPLY VOLTAGE, VCC, (VOLTS) ICC VS. Ta CHARACTERISTIC 5 23 Low Side Output Current 0 mA 15 8 6 18 VLOL VS. VCC CHARACTERISTIC -20 mA 23 13 10 Low Side Output Current LOW SIDE FIXED SUPPLY VOLTAGE, VCC, (VOLTS) 3 6.5 LOW SIDE FIXED SUPPLY VOLTAGE, VCC, (VOLTS) 0 1.0 13 50kHz 8 "LO" OUTPUT VOLTAGE, VLOL, (VOLTS) "LO" OUTPUT VOLTAGE, VLOH, (VOLTS) tDEAD1 8 7.0 6.0 23 20 1.4 DEAD TIME, tDEAD, (µs) 18 Oscillation Suspension VLOH VS. VCC CHARACTERISTIC tDEAD VS. VCC CHARACTERISTIC 1.5 OSCILLATION CURRENT,ICC, (mA) 13 7.5 LOW SIDE FIXED SUPPLY VOLTAGE, VCC, (VOLTS) AMBIENT TEMPERATURE, Ta, (°C) 7.35 12 7.30 10 VUVr UNDER VOLTAGE, VUV, (VOLTS) POWER DISSIPATION, Pt, (WATTS) 115kHz 5 8.0 Oscillation Suspension 7.25 7.20 7.15 7.10 50kHz 7.05 7.00 -50 0 50 100 AMBIENT TEMPERATURE, Ta, (°C) 150 8 VUVt 6 4 2 0 -50 0 50 100 150 AMBIENT TEMPERATURE, Ta, (°C) 5 Powerex, Inc., 200 Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 M63954P HVIC Half-Bridge Driver tDEAD VS. Ta CHARACTERISTIC 16 DEAD TIME, tDEAD, (µs) 1.7 1.6 1.5 tDEAD1 1.4 1.3 tDEAD2 1.2 1.1 0 50 100 10 14 -0 mA 12 -20 mA 10 8 6 -200 mA 4 2 0 -50 150 0 DEAD TIME LO 100 OUTPUT RISE TIME FALL TIME 90% 10% tDEAD 50 8 200 mA 6 4 2 0 mA 0 -50 150 90% HO, LO 0 90% 10% 10% tDEAD tr tf 90% 10% BLOCK DIAGRAM CVCO CVCO VCO 2 RVCO1 RVCO2 4 3 RVCO 11 HVCC – + + – – SQ RQ DEAD TIME LEVEL SHIFT SQ R 10 HO + – 0.348•VREG 9 HGND 0.773•VREG 13 LO 1 VREG VREG VREG START LN 8 LNTH 7 – + DELAY QS DELAY + – 5 AB DELAY + – 15 OV 6 ABTH R VCC 12 UV DELAY QS R 1/2 VREG 14 GND CNT 12 6 + – DELAY 20 mA 50 100 AMBIENT TEMPERATURE, Ta, (°C) AMBIENT TEMPERATURE, Ta, (°C) AMBIENT TEMPERATURE, Ta, (°C) HO “LOL” OUTPUT VOLTAGE, VLOL, (VOLTS) “LOH” OUTPUT VOLTAGE, VLOH, (VOLTS) 1.8 1.0 -50 VLOL VS. Ta CHARACTERISTIC VLOH VS. Ta CHARACTERISTIC 1.9 150