Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch DESCRIPTION Monolithic temperature and overload protected power switch based on MOSFET technology in a 5 pin plastic envelope, configured as a single high side switch. BUK200-50X QUICK REFERENCE DATA SYMBOL PARAMETER IL Nominal load current (ISO) SYMBOL PARAMETER VBG IL Tj RON Continuous off-state supply voltage Continuous load current Continuous junction temperature On-state resistance MIN. UNIT 3.5 A MAX. UNIT 50 10 150 100 V A ˚C mΩ APPLICATIONS General controller for driving lamps, motors, solenoids, heaters. FEATURES Vertical power DMOS switch Low on-state resistance 5 V logic compatible input with hysteresis Overtemperature protection self resets with hysteresis Overload protection against short circuit load with output current limiting; latched - reset by input High supply voltage load protection Supply undervoltage lock out Status indication for overload protection activated Diagnostic status indication of open circuit load Very low quiescent current Voltage clamping for turn off of inductive loads ESD protection on all pins Reverse battery and overvoltage protection with external ground resistor PINNING - SOT263 PIN FUNCTIONAL BLOCK DIAGRAM BATT STATUS POWER MOSFET INPUT CONTROL & PROTECTION CIRCUITS LOAD GROUND Fig.1. Elements of the TOPFET HSS. PIN CONFIGURATION SYMBOL DESCRIPTION tab 1 Ground 2 Input I 3 Battery (+ve supply) S 4 Status 5 Load TOPFET HSS L G 1 2345 leadform 263-01 Fig. 2. tab B Fig. 3. connected to pin 3 April 1995 1 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X LIMITING VALUES Limiting values in accordance with the Absolute Maximum System (IEC 134) SYMBOL PARAMETER CONDITIONS MIN. MAX. UNIT VBG Battery voltages Continuous off-state supply voltage 0 50 V -VBG Reverse battery voltages1 Repetitive peak supply voltage External resistors: RG ≥150 Ω; RI = RS ≥ 4.7 kΩ, - 32 V Continuous reverse supply voltage δ ≤ 0.1 RG ≥150 Ω; RI = RS ≥ 4.7 kΩ -VBG - 16 V IL Continuous load current Tmb ≤ 115 ˚C - 10 A PD Tstg Total power dissipation Storage temperature Tmb ≤ 25 ˚C - -55 62.5 175 W ˚C Tj Continuous junction temperature2 - 150 ˚C Tsold Lead temperature - 250 ˚C -5 -5 5 5 mA mA - during soldering Input and status II IS Continuous input current Continuous status current - II Repetitive peak input current δ ≤ 0.1 -20 20 mA IS Repetitive peak status current δ ≤ 0.1 -20 20 mA - 1.2 J MIN. MAX. UNIT - 2 kV Inductive load clamping EBL Non-repetitive clamping energy Tmb = 150 ˚C prior to turn-off ESD LIMITING VALUE SYMBOL PARAMETER CONDITIONS VC Electrostatic discharge capacitor voltage Human body model; C = 250 pF; R = 1.5 kΩ THERMAL CHARACTERISTICS SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT - 1.5 2 K/W - 60 75 K/W Thermal resistance3 Rth j-mb Junction to mounting base Rth j-a Junction to ambient in free air 1 Reverse battery voltage is allowed only with external input and status resistors to limit the currents to a safe value. 2 For normal continuous operation. A higher Tj is allowed as an overload condition but at the threshold Tj(TO) the over temperature trip operates to protect the switch. 3 Of the output Power MOS transistor. April 1995 2 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X STATIC CHARACTERISTICS Tmb = 25 ˚C unless otherwise stated SYMBOL PARAMETER CONDITIONS VBG Clamping voltages Battery to ground VBL -VLG Battery to load Negative load to ground VBG Supply voltage Operating range1 MIN. TYP. MAX. UNIT IG = 1 mA 50 55 65 V IL = IG = 1 mA IL = 1 mA 50 12 55 17 65 21 V V 5 - 40 V battery to ground - Currents VBG = 13 V 2 IL IB Nominal load current Quiescent current3 VBL = 0.5 V; Tmb = 85 ˚C VIG = 0 V; VLG = 0 V 3.5 - 0.1 2 A µA IG IL Operating current4 Off-state load current5 VIG = 5 V; IL = 0 A VBL = 13 V; VIG = 0 V 1.5 - 2.2 0.1 4 1 mA µA RON Resistances On-state resistance6 VBG = 13 V; IL = 5 A; tp = 300 µs - 77 100 mΩ RON On-state resistance VBG = 5 V; IL = 1 A; tp = 300 µs - 116 150 mΩ MIN. TYP. MAX. UNIT INPUT CHARACTERISTICS Tmb = 25 ˚C; VBG = 13 V SYMBOL PARAMETER CONDITIONS II Input current VIG = 5 V 35 60 100 µA VIG VIG(ON) Input clamping voltage Input turn-on threshold voltage II = 200 µA 6 - 7 2.1 8 2.4 V V VIG(OFF) ∆VIG Input turn-off threshold voltage Input turn-on hysteresis 1.5 - 1.7 0.4 - V V 1 On-state resistance is increased if the supply voltage is less than 9 V. Refer to figure 8. 2 Defined as in ISO 10483-1. 3 This is the continuous current drawn from the battery when the input is low and includes leakage current to the load. 4 This is the continuous current drawn from the battery with no load connected, but with the input high. 5 The measured current is in the load pin only. 6 The supply and input voltage for the RON tests are continuous. The specified pulse duration tp refers only to the applied load current. April 1995 3 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X PROTECTION FUNCTIONS AND STATUS INDICATIONS Truth table for normal, open-circuit load and overload conditions and abnormal supply voltages. FUNCTIONS SYMBOL THRESHOLD INPUT STATUS OUTPUT Normal on-state 1 1 1 Normal off-state 0 1 0 Open circuit load1 1 0 1 Open circuit load 0 1 0 Over temperature2 1 0 0 Over temperature3 0 0 0 Short circuit load4 1 0 0 Short circuit load 0 1 0 VBG(TO) Low supply voltage5 X 1 VBG(LP) High supply voltage6 X 1 IL(OC) Tj(TO) VBL(TO) CONDITION TRUTH TABLE MIN. TYP. MAX. UNIT 50 200 350 mA 150 175 - ˚C 8.5 10.3 12 V 0 3 4 5 V 0 40 45 50 V For input ‘0’ equals low, ‘1’ equals high, ‘X’ equals don’t care. For status ‘0’ equals low, ‘1’ equals open or high. For output switch ‘0’ equals off, ‘1’ equals on. STATUS CHARACTERISTICS Tmb = 25 ˚C. The status output is an open drain transistor, and requires an external pull-up circuit to indicate a logic high. SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT VSG VSG Status clamping voltage Status low voltage IS = 100 µA IS = 50 µA; VBG = 13 V 6 - 7 0.7 8 0.8 V V IS Status leakage current VSG = 5 V - 0.1 1 µA IS Status saturation current7 VSS = 5 V; RS = 0 Ω; VBG = 13 V - 9 - mA VSS = 5 V - 100 - kΩ Application information RS External pull-up resistor8 1 In the on-state, the switch detects whether the load current is less than the quoted open load threshold current. This is for status indication only. Typical hysteresis equals 80 mA. The thresholds are specified for supply voltage within the normal working range. 2 After cooling below the reset temperature the switch will resume normal operation. The reset temperature is lower than the trip temperature by typically 10 ˚C. 3 If the overtemperature protection has operated, status remains low to indicate the overtemperature condition even if the input is taken low, providing the device has not cooled below the reset temperature. 4 After short circuit protection has operated, the input voltage must be toggled low for the switch to resume normal operation. 5 Undervoltage sensor causes the device to switch off. Typical hysteresis equals 0.5 V. 6 Overvoltage sensor causes the device to switch off to protect the load. Typical hysteresis equals 1.1 V. 7 In a fault condition with the pull-up resistor short circuited while the status transistor is conducting. 8 The pull-up resistor also protects the status pin during reverse battery conditions. April 1995 4 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X DYNAMIC CHARACTERISTICS Tmb = 25 ˚C; VBG = 13 V SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT -VLG Inductive load turn-off Negative load voltage1 VIG = 0 V; IL = 5 A; tp = 300 µs 15 20 25 V td sc Short circuit load protection2 Response time VIG = 5 V; RL ≤ 10 mΩ VIG = 5 V - 90 - µs IL Load current prior to turn-off t < td sc - 35 - A Overload protection3 Load current limiting IL(lim) VBL = 8.5 V; tp = 300 µs 23 33 43 A MIN. TYP. MAX. UNIT SWITCHING CHARACTERISTICS Tmb = 25 ˚C, VBG = 13 V, for resistive load RL = 13 Ω. SYMBOL PARAMETER CONDITIONS During turn-on to VIG = 5 V td on dV/dton Delay time Rate of rise of load voltage to 10% VL - 16 1 2.5 µs V/µs t on Total switching time to 90% VL - 40 - µs td off During turn-off Delay time to VIG = 0 V to 90% VL - 30 - µs dV/dtoff t off Rate of fall of load voltage Total switching time to 10% VL - 1.2 50 2.5 - V/µs µs MIN. TYP. MAX. UNIT CAPACITANCES Tmb = 25 ˚C; f = 1 MHz; VIG = 0 V SYMBOL PARAMETER CONDITIONS Cig Input capacitance VBG = 13 V - 15 20 pF Cbl Output capacitance VBL = VBG = 13 V - 330 460 pF Csg Status capacitance VSG = 5 V - 11 15 pF 1 For a high side switch, the load pin voltage goes negative with respect to ground during the turn-off of an inductive load. This negative voltage is clamped by the device. 2 The load current is self-limited during the response time for short circuit load protection. Response time is measured from when input goes high. 3 If the load resistance is low, but not a complete short circuit, such that the on-state voltage remains less than VBL(TO), the device remains in current limiting until the overtemperature protection operates. April 1995 5 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X IL / A 20 BUK200-50X VBG / V = VBL IB II I VBG IS S 15 TOPFET HSS 5 IL L 10 VLG G VSG IG RS 6 7 B LOAD VIG 13 5 0 0 Normalised Power Derating PD% 2 1.5 Fig.7. Typical on-state characteristics, Tj = 25 ˚C. IL = f(VBL); parameter VBG; tp = 250 µs Fig.4. High side switch measurements schematic. (current and voltage conventions) 120 1 VBL / V 0.5 150 RON / mO BUK200-50X 110 100 90 100 80 70 60 50 40 50 30 20 10 0 0 20 40 60 80 100 Tmb / C 120 0 140 1 Fig.5. Normalised limiting power dissipation. PD% = 100⋅PD/PD(25 ˚C) = f(Tmb) 15 IL / A 10 VBG / V 100 Fig.8. Typical on-state resistance, Tj = 25 ˚C. RON = f(VBG); conditions: IL = 5 A; tp = 300 µs BUK200-50X 200 RON / mOhm BUK200-50X VBG = 5V 150 13 V 10 100 typ. 5 50 0 0 0 20 40 60 80 Tmb / C 100 120 -60 140 20 60 Tj / C 100 140 180 Fig.9. Typical on-state resistance, tp = 300 µs. RON = f(Tj); parameter VBG; condition IL = 1 A Fig.6. Limiting continuous on-state load current. IL = f(Tmb); conditions: VIG = 5 V, VBG = 13 V April 1995 -20 6 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch 5 BUK200-50X BUK200-50X IG / mA 100 uA IL BUK200-50X CLAMPING 10 uA 4 1 uA 3 OPERATING VIG = 3 V 2 100 nA HIGH VOLTAGE 1 10 nA QUIESCENT VIG = 0 V 0 1 nA 0 20 10 30 VBG / V 40 60 50 -60 IG / mA 20 60 Tj / C 100 140 180 Fig.13. Typical off-state leakage current. IL = f(Tj); conditions: VBL = 13 V = VBG; VIG = 0 V. Fig.10. Typical supply characteristics, 25 ˚C. IG = f(VBG); parameter VIG 3 -20 BUK200-50X 200 II / uA BUK200-50X VBG / V = 150 VBG / V = 5 2 7 13 100 13 1 50 50 0 0 -60 -20 20 60 Tj / C 100 140 0 180 Fig.11. Typical operating supply current. IG = f(Tj); parameter VBG; condition VIG = 5 V IB 100 uA 2 4 VIG / V 6 8 Fig.14. Typical input characteristics, Tj = 25 ˚C. II = f(VIG); parameter VBG BUK200-50X 100 II / uA BUK200-50X 80 10 uA 60 1 uA 40 100 nA 20 0 10 nA -60 -20 20 60 Tj / C 100 140 180 0 30 20 50 40 VBG / V Fig.12. Typical supply quiescent current. IB = f(Tj); condition VBG = 13 V, VIG = 0 V, VLG = 0 V April 1995 10 Fig.15. Typical input current, Tj = 25 ˚C. II = f(VBG); condition VIG = 5 V 7 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X VIG / V 3.0 BUK200-50X IS 10 uA BUK200-50X 2.5 1 uA VIG(ON) 2.0 100 nA 1.5 VIG(OFF) 10 nA 1.0 -60 -20 20 60 Tj / C 100 140 -60 180 VIG / V 20 60 Tj / C 100 140 180 Fig.19. Typical status leakage current. IS = f(Tj); conditions VSG = 5 V, VIG = VBG = 0 V Fig.16. Typical input threshold voltages. VIG = f(Tj); conditions VBG = 13 V, IL = 50 mA 8.0 -20 BUK200-50X 1000 IS / uA BUK200-50X 800 7.5 600 400 7.0 200 0 6.5 -60 -20 20 60 Tj / C 100 140 180 0 IS / mA 0.4 0.6 0.8 1 1.2 VSG / V 1.4 1.6 1.8 2 Fig.20. Typical status low characteristic, Tj = 25 ˚C. IS = f(VSG); conditions VIG = 5 V, VBG = 13 V, IL = 0 A Fig.17. Typical input clamping voltage. VIG = f(Tj); conditions II = 200 µA, VBG = 13 V 20 0.2 BUK200-50X 1 VSG / V BUK200-50X 0.8 15 0.6 10 0.4 5 0.2 0 0 0 2 4 6 8 10 -60 VSG / V Fig.18. Typical status characteristic, Tj = 25 ˚C. IS = f(VSG); conditions VIG = VBG = 0 V April 1995 -20 20 60 Tj / C 100 140 180 Fig.21. Typical status low voltage, VSG = f(Tj). conditions IS = 50 µA, VIG = 5 V, VBG = 13 V, IL = 0 A 8 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X VSG / V 8.0 BUK200-50X VBG(LP) / V 46 BUK200-50X off 45 7.5 44 on 7.0 43 42 6.5 -60 -20 20 60 Tj / C 100 140 180 -60 IL(OC) / mA BUK200-50X 400 20 60 Tj / C 100 140 180 Fig.25. Supply typical overvoltage thresholds. VBG(LP) = f(Tj); conditions VIG = 5 V; IL = 50 mA Fig.22. Typical status clamping voltage, VSG = f(Tj). conditions IS = 100 µA, VBG = 13 V 500 -20 VBG / V 65 BUK200-50X max. 60 IG = 300 1 mA typ. 200 10 uA 55 100 min. 50 0 -60 -20 20 60 Tj / C 100 140 180 -60 Fig.23. Low load current detection threshold. IL(OC) = f(Tj); conditions VIG = 5 V; VBG = 13 V 5 VBG(TO) / V -20 20 60 Tj / C 100 140 180 Fig.26. Typical battery to ground clamping voltage. VBG = f(Tj); parameter IG BUK200-50X 20 4 IL / A BUK200-50X 15 on 3 10 off 2 5 1 0 0 -60 -20 20 60 Tj / C 100 140 -24 180 Fig.24. Supply typical undervoltage thresholds. VBG(TO) = f(Tj); conditions VIG = 3 V; IL = 50 mA April 1995 -20 -16 -12 VLG / V -8 -4 0 Fig.27. Typical negative load clamping characteristic. IL = f(VLG); conditions VIG = 0 V, tp = 300 µs, 25 ˚C 9 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch VLG / V -10 BUK200-50X BUK200-50X IL / A 0 BUK200-50X IL = -12 -5 1 mA -14 -10 -16 5A -18 -15 tp = 300 us -20 -22 -20 -60 -20 20 60 Tj / C 100 140 -1.1 180 VBL / V -0.7 -0.5 VBL / V -0.3 -0.1 Fig.31. Typical reverse diode characteristic. IL = f(VBL); conditions VIG = 0 V, Tj = 25 ˚C Fig.28. Typical negative load clamping voltage. VLG = f(Tj); parameter IL; condition VIG = 0 V. 65 -0.9 BUK200-50X 1000 Cbl / pF BUK200-50X IL = tp = 300 us 2.5 A 60 1 mA 100 uA 55 50 100 -60 -20 20 60 Tj / C 100 140 0 180 40 30 50 VBL / V Fig.32. Typical output capacitance. Tmb = 25 ˚C Cbl = f(VBL); conditions f = 1 MHz, VIG = 0 V Fig.29. Typical battery to load clamping voltage. VBL = f(Tj); parameter IL; condition IG = 5 mA. 0 20 10 IG / mA BUK200-50X 50 IL / A BUK200-50X VBL(TO) typ. current limiting 40 -50 tp = 30 -100 50 us i.e. before short circuit load trip 300 us 20 -150 10 0 -200 -1 -0.8 -0.6 -0.4 -0.2 0 0 VBG / V Fig.30. Typical reverse battery characteristic. IG = f(VBG); conditions IL = 0 A, Tj = 25 ˚C April 1995 2 4 6 8 10 12 VBL / V 14 16 18 20 Fig.33. Typical overload characteristic, Tmb = 25 ˚C. IL = f(VBL); condition VBG = 13 V; parameter tp 10 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch 45 BUK200-50X IL(LIM) / A BUK200-50X VBL(TO) / V 15 40 14 35 13 BUK200-50X 12 30 11 25 10 20 9 15 8 10 7 5 6 0 5 -60 -20 20 60 100 Tmb / C 140 180 -60 VBL(TO) / V 20 60 100 Tmb / C 140 180 Fig.36. Typical short circuit load threshold voltage. VBL(TO) = f(Tmb); condition VBG = 13 V Fig.34. Typical overload current, VBL = 8.5 V. IL = f(Tmb); conditions VBG = 13 V; tp = 300 µs 12 -20 BUK200-50X 10 Zth j-mb / (K/W) BUK200-50X D= 11 1 0.5 0.2 10 0.1 0.05 0.1 PD 0.02 9 tp 0 0.01 100n 8 0 10 20 VBG / V 30 40 Fig.35. Typical short circuit load threshold voltage. VBL(TO) = f(VBG); condition Tmb = 25 ˚C April 1995 1u D= T 10u 100u 1m t/s 10m 100m tp T t 1 10 Fig.37. Transient thermal impedance. Zth j-mb = f(t); parameter D = tp/T 11 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X MECHANICAL DATA Dimensions in mm 4.5 max Net Mass: 2 g 10.3 max 1.3 3.6 2.8 5.9 min mounting base 15.8 max 5 m in 2.4 max R 0. (2) 3.5 max not tinned 5.6 9.75 0. 5 0.6 min (4 x) 0.6 R 1 2 3 4 5 in 5 m 0.5 (1) 1.7 2.4 4.5 (4 x) 0.4 (1) M 0.9 max 8.2 (5 x) NOTES (1) (2) positional accuracy of the terminals is controlled in this zone only. terminal dimensions in this zone are uncontrolled. Fig.38. SOT263 leadform 263-01; pin 3 connected to mounting base. Note 1. Refer to mounting instructions for TO220 envelopes. 2. Epoxy meets UL94 V0 at 1/8". April 1995 12 Rev 1.000 Philips Semiconductors Product specification PowerMOS transistor TOPFET high side switch BUK200-50X DEFINITIONS Data sheet status Objective specification This data sheet contains target or goal specifications for product development. Preliminary specification This data sheet contains preliminary data; supplementary data may be published later. Product specification This data sheet contains final product specifications. Limiting values Limiting values are given in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of this specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information Where application information is given, it is advisory and does not form part of the specification. Philips Electronics N.V. 1996 All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, it is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent or other industrial or intellectual property rights. LIFE SUPPORT APPLICATIONS These products are not designed for use in life support appliances, devices or systems where malfunction of these products can be reasonably expected to result in personal injury. Philips customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such improper use or sale. April 1995 13 Rev 1.000