FSAM10SH60 FSAM10SH60 SPMTM (Smart Power Module) General Description Features FSAM10SH60 is an advanced smart power module (SPM) that Fairchild has newly developed and designed to provide very compact and high performance ac motor drives mainly targeting high speed low-power inverter-driven application like washing machines. It combines optimized circuit protection and drive matched to low-loss IGBTs. Highly effective short-circuit current detection/protection is realized through the use of advanced current sensing IGBT chips that allow continuous monitoring of the IGBTs current. System reliability is further enhanced by the built-in over-temperature monitoring and integrated under-voltage lock-out protection. The high speed built-in HVIC provides opto-coupler-less IGBT gate driving capability that further reduce the overall size of the inverter system design. In addition the incorporated HVIC facilitates the use of singlesupply drive topology enabling the FSAM10SH60 to be driven by only one drive supply voltage without negative bias. Inverter current sensing application can be achieved due to the divided nagative dc terminals. * UL Certified No. E209204 * 600V-10A 3-phase IGBT inverter bridge including control ICs for gate driving and protection * Divided negative dc-link terminals for inverter current sensing applications * Single-grounded power supply due to built-in HVIC * Typical switching frequency of 15kHz * Built-in thermistor for over-temperature monitoring * Inverter power rating of 0.5kW / 100~253 Vac * Isolation rating of 2500Vrms/min. * Very low leakage current due to using ceramic substrate * Adjustable current protection level by varying series resistor value with sense-IGBTs Applications * AC 100V ~ 253V 3-phase inverter drive for small power (0.5kW) ac motor drives * Home appliances applications requiring high switching frequency operation like washing machines drive system * Application ratings: - Power : 0.5 kW / 100~253 Vac - Switching frequency : Typical 15kHz (PWM Control) - 100% load current : 3.3A (Irms) - 150% load current : 5.0A (Irms) for 1 minute External View Top View Bottom View 60mm 31mm Fig. 1. (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Integrated Power Functions * 600V-10A IGBT inverter for 3-phase DC/AC power conversion (Please refer to Fig. 3) Integrated Drive, Protection and System Control Functions * For inverter high-side IGBTs: Gate drive circuit, High voltage isolated high-speed level shifting Control circuit under-voltage (UV) protection Note) Available bootstrap circuit example is given in Figs. 14 and 15. * For inverter low-side IGBTs: Gate drive circuit, Short-circuit (SC) protection Control supply circuit under-voltage (UV) protection * Temperature Monitoring: System over-temperature monitoring using built-in thermistor Note) Available temperature monitoring circuit is given in Fig. 15. * Fault signaling: Corresponding to a SC fault (Low-side IGBTs) or a UV fault (Low-side control supply circuit) * Input interface: 5V CMOS/LSTTL compatible, Schmitt trigger input Pin Configuration Top View (1) VCC(L) (2) com(L) (3) IN(UL) (4) IN(VL) (5) IN(WL) (6) com(L) (7) FO (8) CFOD (9) CSC (24) VTH (25) RTH (26) NU (27) NV (28) NW (10) RSC (11) IN(UH) (12) VCC(UH) (29) U (13) VB(U) (14) VS(U) (30) V (15) IN(VH) (16) com(H) (17) VCC(VH) Case Temperature (TC) Detecting Point (31) W (18) VB(V) (19) VS(V) Ceramic Substrate (20) IN(WH) (21) VCC(WH) (32) P (22) VB(W) (23) VS(W) Fig. 2. (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Pin Descriptions Pin Number 1 Pin Name VCC(L) 2 COM(L) Low-side Common Supply Ground 3 IN(UL) Signal Input for Low-side U Phase 4 IN(VL) Signal Input for Low-side V Phase 5 IN(WL) Signal Input for Low-side W Phase 6 COM(L) Low-side Common Supply Ground 7 VFO 8 CFOD Capacitor for Fault Output Duration Time Selection 9 CSC Capacitor (Low-pass Filter) for Short-Circuit Current Detection Input 10 RSC 11 IN(UH) 12 VCC(UH) 13 VB(U) High-side Bias Voltage for U Phase IGBT Driving 14 VS(U) High-side Bias Voltage Ground for U Phase IGBT Driving 15 IN(VH) Signal Input for High-side V Phase 16 COM(H) High-side Common Supply Ground 17 VCC(VH) High-side Bias Voltage for V Phase IC 18 VB(V) High-side Bias Voltage for V Phase IGBT Driving 19 VS(V) High-side Bias Voltage Ground for V Phase IGBT Driving 20 IN(WH) 21 VCC(WH) 22 VB(W) High-side Bias Voltage for W Phase IGBT Driving 23 VS(W) High-side Bias Voltage Ground for W Phase IGBT Driving 24 VTH Thermistor Bias Voltage 25 RTH Series Resistor for the Use of Thermistor (Temperature Detection) 26 NU Negative DC-Link Input for U Phase 27 NV Negative DC-Link Input for V Phase 28 NW 29 U Output for U Phase 30 V Output for V Phase 31 W Output for W Phase 32 P Positive DC-Link Input (c)2003 Fairchild Semiconductor Corporation Pin Description Low-side Common Bias Voltage for IC and IGBTs Driving Fault Output Resistor for Short-Circuit Current Detection Signal Input for High-side U Phase High-side Bias Voltage for U Phase IC Signal Input for High-side W Phase High-side Bias Voltage for W Phase IC Negative DC-Link Input for W Phase Rev. D, August 2003 FSAM10SH60 Internal Equivalent Circuit and Input/Output Pins Bottom View (22) V B(W ) (21) V C C(W H ) VC C COM (20) IN (W H ) (32) P VB IN OUT VS (31) W (23) V S(W ) (18) V B(V ) VB (17) V C C(VH ) VC C (16) C O M (H ) COM (15) IN (VH ) IN OUT VS (30) V (19) V S(V ) (13) V B(U ) (12) V C C(UH ) VB VC C OUT COM (11) IN (U H ) IN VS (29) U (14) V S(U ) (10) R SC (9) C SC C (S C ) (8) C FO D C (F O D ) (7) V FO VF O O U T (W L) (28) N W (6) C O M (L) (5) IN (W L) IN (W L) (4) IN (VL) IN (V L) (3) IN (U L) IN (U L) (2) C O M (L) C O M (L) (1) V C C(L) VC C O U T (V L) (27) N V O U T (U L) (26) N U THE RM ISTO R (25) R T H (24) V T H Note: 1) Inverter low-side is composed of three sense-IGBTs including freewheeling diodes for each IGBT and one control IC which has gate driving, current sensing and protection functions. 2) Inverter power side is composed of four inverter dc-link input pins and three inverter output pins. 3) Inverter high-side is composed of three normal-IGBTs including freewheeling diodes and three drive ICs for each IGBT. Fig. 3. (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Absolute Maximum Ratings (TJ = 25C, Unless Otherwise Specified) Inverter Part Item Symbol VPN Condition Applied between P- NU, NV, NW Rating 450 Unit V VPN(Surge) Applied between P- NU, NV, NW 500 V 600 V A Supply Voltage Supply Voltage (Surge) Collector-Emitter Voltage VCES Each IGBT Collector Current IC TC = 25C 10 Each IGBT Collector Current IC TC = 100C 8 A Each IGBT Collector Current (Peak) ICP TC = 25C, Instantaneous Value (Pulse) 20 A Collector Dissipation PC TC = 25C per One Chip Operating Junction Temperature TJ (Note 1) 42 W -20 ~ 125 C Note: 1. It would be recommended that the average junction temperature should be limited to TJ 125C (@TC 100C) in order to guarantee safe operation. Control Part Item Control Supply Voltage Symbol Condition VCC Applied between VCC(UH), VCC(VH), VCC(WH) - COM(H), VCC(L) - COM(L) Rating 20 Unit V 20 V V High-side Control Bias Voltage VBS Applied between VB(U) - VS(U), VB(V) - VS(V), VB(W) VS(W) Input Signal Voltage VIN Applied between IN(UH), IN(VH), IN(WH) - COM(H) IN(UL), IN(VL), IN(WL) - COM(L) -0.3~VCC+0.3 Fault Output Supply Voltage VFO Applied between VFO - COM(L) -0.3~VCC+0.3 V Fault Output Current IFO Sink Current at VFO Pin 5 mA Current Sensing Input Voltage VSC Applied between CSC - COM(L) -0.3~VCC+0.3 V Total System Item Self Protection Supply Voltage Limit (Short-Circuit Protection Capability) Module Case Operation Temperature Symbol Condition VPN(PROT) VCC = VBS = 13.5 ~ 16.5V TJ = 25C, Non-repetitive, less than 6s TC Storage Temperature TSTG Isolation Voltage VISO (c)2003 Fairchild Semiconductor Corporation Note Fig.2 60Hz, Sinusoidal, AC 1 minute, Connection Pins to Heat-sink Plate Rating 400 Unit V -20 ~ 100 C -20 ~ 125 C 2500 Vrms Rev. D, August 2003 Thermal Resistance Item Junction to Case Thermal Resistance Contact Thermal Resistance Symbol Condition Rth(j-c)Q Each IGBT under Inverter Operating Condition Min. Typ. - Max. 2.93 Unit C/W Rth(j-c)F Each FWDi under Inverter Operating Condition - - 3.71 C/W Rth(c-h) Ceramic Substrate (per 1 Module) Thermal Grease Applied (Note 3) - - 0.06 C/W Typ. - Max. 2.8 Unit V Note: 2. For the measurement point of case temperature(TC), please refer to Fig. 2. 3. The thickness of thermal grease should not be more than 100um. Electrical Characteristics (TJ = 25C, Unless Otherwise Specified) Inverter Part Item Collector - Emitter Saturation Voltage Symbol VCE(SAT) VCC = VBS = 15V VIN = 0V Condition IC = 10A, TJ = 25C Min. - FWDi Forward Voltage VFM VIN = 5V - - 2.3 V Switching Times tON VPN = 300V, VCC = VBS = 15V IC = 10A, TJ = 25C VIN = 5V 0V, Inductive Load (High, Low-side) - 0.37 - us - 0.12 - us - 0.53 - us - 0.2 - us (Note 4) - 0.1 - us VCE = VCES, TJ = 25C - - 250 uA tC(ON) tOFF tC(OFF) trr Collector - Emitter Leakage Current ICES IC = 10A, TJ = 25C Note: 4. tON and tOFF include the propagation delay time of the internal drive IC. tC(ON) and tC(OFF) are the switching time of IGBT itself under the given gate driving condition internally. For the detailed information, please see Fig. 4. (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Absolute Maximum Ratings 1 0 0 % IC VCE IC IC V IN V IN (O N ) FSAM10SH60 t rr VCE V IN t ON t C (O N ) t OFF V IN(OFF) (a) Turn-on tC(OFF) (b) Turn-off Fig. 4. Switching Time Definition VCE : 100V/div. VCE : 100V/div. IC : 5A/div. time : 100ns/div. (a) Turn-on IC : 5A/div. time : 100ns/div. (b) Turn-off Fig. 5. Experimental Results of Switching Waveforms Test Condition: Vdc=300V, Vcc=15V, L=500uH (Inductive Load), TJ=25C (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 (TJ = 25C, Unless Otherwise Specified) Control Part Item Symbol Quiescent VCC Supply Cur- IQCCL VCC = 15V rent IN(UL, VL, WL) = 5V IQCCH VCC = 15V IN(UH, VH, WH) = 5V Condition VCC(L) - COM(L) VCC(UH), VCC(VH), VCC(WH) COM(H) - - 130 uA Quiescent VBS Supply Current IQBS VBS = 15V IN(UH, VH, WH) = 5V VB(U) - VS(U), VB(V) -VS(V), VB(W) - VS(W) - - 420 uA Fault Output Voltage VFOH VSC = 0V, VFO Circuit: 4.7k to 5V Pull-up 4.5 - - V VFOL VSC = 1V, VFO Circuit: 4.7k to 5V Pull-up - - 1.1 V Short-Circuit Trip Level Sensing Voltage of IGBT Current Supply Circuit UnderVoltage Protection Fault Output Pulse Width VSC(ref) VSEN Typ. Max. Unit 26 mA VCC = 15V (Note 5) 0.45 0.51 0.56 V RSC = 56 , RSU = RSV = RSW = 0 and IC = 15A (Note Fig. 7) 0.45 0.51 0.56 V UVCCD Detection Level 11.5 12 12.5 UVCCR Reset Level 12 12.5 13 V UVBSD Detection Level 7.3 9.0 10.8 V UVBSR Reset Level 8.6 10.3 12 V CFOD = 33nF (Note 6) 1.4 1.8 2.0 ms tFOD ON Threshold Voltage VIN(ON) OFF Threshold Voltage VIN(OFF) ON Threshold Voltage VIN(ON) OFF Threshold Voltage VIN(OFF) Resistance of Thermistor Min. - RTH High-Side Low-Side V Applied between IN(UH), IN(VH), IN(WH) - COM(H) - - 0.8 V 3.0 - - V Applied between IN(UL), IN(VL), IN(WL) - COM(L) - - 0.8 V 3.0 - - V @ TTH = 25C (Note 7 and Fig. 6) - 50 - k @ TTH = 100C (Note 7 and Fig. 6) - 3.4 - k Note: 5. Short-circuit current protection is functioning only at the low-sides. It would be recommended that the value of the external sensing resistor (RSC) should be selected around 56 in order to make the SC trip-level of about 15A at the shunt resistors (RSU,RSV,RSW) of 0 . For the detailed information about the relationship between the external sensing resistor (RSC) and the shunt resistors (RSU,RSV,RSW), please see Fig. 7. 6. The fault-out pulse width tFOD depends on the capacitance value of CFOD according to the following approximate equation : CFOD = 18.3 x 10-6 x tFOD[F] 7. TTH is the temperature of thermistor itself. To know case temperature (TC), please make the experiment considering your application. Recommended Operating Conditions Item Symbol Condition Values Min. - Typ. 300 Max. 400 Unit Supply Voltage VPN Applied between P - NU, NV, NW Control Supply Voltage VCC Applied between VCC(UH), VCC(VH), VCC(WH), COM(H), VCC(L) - COM(L) 13.5 15 16.5 V High-side Bias Voltage VBS Applied between VB(U) - VS(U), VB(V) - VS(V), VB(W) - VS(W) 13.5 15 16.5 V Blanking Time for Preventing Arm-short tdead For Each Input Signal 3 - - us fPWM TC 100C, TJ 125C - 15 - kHz PWM Input Signal V Input ON Threshold Voltage VIN(ON) Applied between IN(UH), IN(VH), IN(WH) COM(H), IN(UL), IN(VL), IN(WL) - COM(L) 0 ~ 0.65 V Input OFF Threshold Voltage VIN(OFF) Applied between IN(UH), IN(VH), IN(WH) COM(H), IN(UL), IN(VL), IN(WL) - COM(L) 4 ~ 5.5 V (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Electrical Characteristics FSAM10SH60 R-T Curve 70 60 Resistance [k] 50 40 30 20 10 0 20 30 40 50 60 70 80 90 100 110 120 130 o Temperature TTH [ C] Fig. 6. R-T Curve of The Built-in Thermistor 120 110 100 90 (1) RSC [] 80 (2) 70 60 50 40 30 20 10 0.00 0.02 0.04 0.06 0.08 0.10 0.12 0.14 RSU,RSV,RSW [ ] Fig. 7. RSC Variation by change of Shunt Resistors ( RSU, RSV, RSW) for Short-Circuit Protection (1) @ around 100% Rated Current Trip (IC *=* 10A),, (2) @ around 150% Rated Current Trip (IC *=* 15A) (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 Item Mounting Torque Limits Condition Mounting Screw: M4 (Note 8 and 9) Ceramic Flatness Unit Recommended 10Kg*cm Min. 8 Typ. 10 Max. 12 Kg*cm Recommended 0.98N*m 0.78 0.98 1.17 N*m 0 - +120 um - 35 - g Note Fig.8 Weight (+) (+) (+) Datum Line Fig. 8. Flatness Measurement Position of The Ceramic Substrate Note: 8. Do not make over torque or mounting screws. Much mounting torque may cause ceramic cracks and bolts and Al heat-fin destruction. 9. Avoid one side tightening stress. Fig.9 shows the recommended torque order for mounting screws. Uneven mounting can cause the SPM ceramic substrate to be damaged. 2 1 Fig. 9. Mounting Screws Torque Order (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Mechanical Characteristics and Ratings FSAM10SH60 Time Charts of SPMs Protective Function Input Signal Internal IGBT Gate-Emitter Voltage P3 Control Supply Voltage P2 P5 UV detect UV reset P6 P1 Output Current P4 Fault Output Signal P1 : Normal operation - IGBT ON and conducting current P2 : Under-Voltage detection P3 : IGBT gate interrupt P4 : Fault signal generation P5 : Under-Voltage reset P6 : Normal operation - IGBT ON and conducting current Fig. 10. Under-Voltage Protection (Low-side) Input Signal P3 P5 VBS UV detect UV reset P2 P6 P1 Output Current Fault Output Signal P4 P1 : Normal operation - IGBT ON and conducting current P2 : Under-Voltage detection P3 : IGBT gate interrupt P4 : No fault signal P5 : Under-Voltage reset P6 : Normal operation - IGBT ON and conducting current Fig. 11. Under-Voltage Protection (High-side) (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 P5 Input Signal P6 Internal IGBT Gate-Em itter Voltage SC Detection P1 P4 P7 Output Current P2 SC Reference Voltage (0.5V) Sensing Voltage RC Filter Delay Fault Output Signal P3 P8 P1 : Normal operation - IGBT ON and conducting current P2 : Short-Circuit current detection P3 : IGBT gate interrupt / Fault signal generation P4 : IGBT is slowly turned off P5 : IGBT OFF signal P6 : IGBT ON signal - but IGBT cannot be turned on during the fault Output activation P7 : IGBT OFF state P8 : Fault Output reset and normal operation start Fig. 12. Short-Circuit Current Protection (Low-side Operation only) (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 5V-Line SPM R PF R PL R PH 4.7k 4.7k 4.7k 100 IN(UH) , IN (VH) , IN(WH) 100 CPU IN (UL) , IN (VL) , IN (WL) 100 VFO C PF 1nF 1nF C PL C PH 0.47nF 1.2nF COM Note: 1) It would be recommended that by-pass capacitors for the gating input signals, IN(UL), IN(VL), IN(WL), IN(UH), IN(VH) and IN(WH) should be placed on the SPM pins and on the both sides of CPU and SPM for the fault output signal, VFO, as close as possible. 2) The logic input is compatible with standard CMOS or LSTTL outputs. 3) RPLCPL/RPHCPH/RPFCPF coupling at each SPM input is recommended in order to prevent input/output signals' oscillation and it should be as close as possible to each of SPM pins. Fig. 13. Recommended CPU I/O Interface Circuit These Values depend on PW M Control Algorithm One-Leg Diagram of SPM 15V-Line 20 P D BS 22uF 0.1uF Vcc VB IN HO COM VS Inverter Output Vcc 470uF 0.1uF IN OUT COM N Note: It would be recommended that the bootstrap diode, DBS, has soft and fast recovery characteristics. Fig. 14. Recommended Bootstrap Operation Circuit and Parameters (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 15V line 5V line RBS D BS (22) V B(W) (21) V CC(W H) RPH RS C BS G ating W H C B SC (20) IN (W H) (23) V S(W) C PH RBS D BS (18) V B(V) (17) V CC(VH) G ating VH RPH RS (16) C OM (H) CBS CBSC (19) V S(V) C PH C P U (15) IN (VH) D BS RBS (13) V B(U) (12) V CC(UH) R PH RS C BS G ating U H C PH C B SC (14) V S(U) RSC 5V line RF RS RPL R PL R PL RPF G ating VH G ating U H (9) C SC (8) C FOD C FO D (7) V FO (6) C OM (L) RS (5) IN (W L) RS (4) IN (VL) RS (3) IN (UL) (2) C OM (L) C B PF C PL CPL C PL CPF (1) V CC(L) CSP15 VCC O UT C OM IN W (31) VS VB VCC O UT C OM IN VS M V (30) VB VCC C D CS O UT Vdc C OM IN U (29) VS (10) R SC R C SC C SC Fault G ating W H (11) IN (UH) P (32) VB C (SC ) O UT(W L) C (FO D) N W (28) RSW VFO IN (WL) O UT(VL) IN (VL) N V (27) R SV IN (UL) C OM(L) O UT(UL) VCC N U (26) CSPC15 RSU 5V line V TH (24) THER M ISTOR R TH (25) R TH Tem p. M onitoring C S PC 05 C S P0 5 R FW W -Phase C urrent V-Phase Current R FV R FU U -Phase C urrent C FW C FV C FU Note: 1) RPLCPL/RPHCPH /RPFCPF coupling at each SPM input is recommended in order to prevent input signals' oscillation and it should be as close as possible to each SPM input pin. 2) By virtue of integrating an application specific type HVIC inside the SPM, direct coupling to CPU terminals without any opto-coupler or transformer isolation is possible. 3) VFO output is open collector type. This signal line should be pulled up to the positive side of the 5V power supply with approximately 4.7k resistance. Please refer to Fig. 15. 4) CSP15 of around 7 times larger than bootstrap capacitor CBS is recommended. 5) VFO output pulse width should be determined by connecting an external capacitor(CFOD) between CFOD(pin8) and COM(L)(pin2). (Example : if CFOD = 33 nF, then tFO = 1.8 ms (typ.)) Please refer to the note 6 for calculation method. 6) Each input signal line should be pulled up to the 5V power supply with approximately 4.7k resistance (other RC coupling circuits at each input may be needed depending on the PWM control scheme used and on the wiring impedance of the system's printed circuit board). Approximately a 0.22~2nF by-pass capacitor should be used across each power supply connection terminals. 7) To prevent errors of the protection function, the wiring around RSC, RF and CSC should be as short as possible. 8) In the short-circuit protection circuit, please select the RFCSC time constant in the range 3~4 s. 9) To enhance the noise immunity, CSC pin should be connected to the external circuit through a series resistor, RCSC, which is approximately 390. RCSC should be connected to CSC pin as close as possible. 10)Each capacitor should be mounted as close to the pins of the SPM as possible. 11) To prevent surge destruction, the wiring between the smoothing capacitor and the P&N pins should be as short as possible. The use of a high frequency noninductive capacitor of around 0.1~0.22 uF between the P&N pins is recommended. 12)Relays are used at almost every systems of electrical equipments of home appliances. In these cases, there should be sufficient distance between the CPU and the relays. It is recommended that the distance be 5cm at least. Fig. 15. Typical Application Circuit (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 FSAM10SH60 Detailed Package Outline Drawings SPM32-AA 28x2.00 0.30=(56.0) (2.00) MAX1.05 MAX1.00 2.00 0.30 0.60 0.10 0.60 0.10 0.40 0.40 28.0 0.30 #23 36.05 0.50 O4.30 (34.80) 31.0 0.50 13.6 0.30 (3.30) +0.10 #24 19.860.30 0.70 -0.05 #32 ) (3 ~5 (17.00) #1 7.20 0.5 (46.60) 12.30 0.5 53.0 0.30 60.0 0.50 3x7.62 0.30=(22.86) 3x4.0 0.30=(12.0 ) 11.0 0.30 (3.70) 2.00 0.30 (3.50) MAX1.00 MAX8.20 (10.14) 0.80 0.80 1.300.10 1.300.10 0.40 0.600.10 MAX3.20 MAX2.50 MAX1.60 Dimensions in Millimeters (c)2003 Fairchild Semiconductor Corporation Rev. D, August 2003 TRADEMARKS The following are registered and unregistered trademarks Fairchild Semiconductor owns or is authorized to use and is not intended to be an exhaustive list of all such trademarks. ACExTM FACT Quiet SeriesTM ActiveArrayTM FAST BottomlessTM FASTrTM CoolFETTM FRFETTM CROSSVOLTTM GlobalOptoisolatorTM DOMETM GTOTM EcoSPARKTM HiSeCTM E2CMOSTM I2CTM TM EnSigna ImpliedDisconnectTM FACTTM ISOPLANARTM Across the board. Around the world.TM The Power FranchiseTM Programmable Active DroopTM LittleFETTM MICROCOUPLERTM MicroFETTM MicroPakTM MICROWIRETM MSXTM MSXProTM OCXTM OCXProTM OPTOLOGIC OPTOPLANARTM PACMANTM POPTM Power247TM PowerTrench QFET QSTM QT OptoelectronicsTM Quiet SeriesTM RapidConfigureTM RapidConnectTM SILENT SWITCHER SMART STARTTM SPMTM StealthTM SuperSOTTM-3 SuperSOTTM-6 SuperSOTTM-8 SyncFETTM TinyLogic TINYOPTOTM TruTranslationTM UHCTM UltraFET VCXTM DISCLAIMER FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS. LIFE SUPPORT POLICY FAIRCHILD'S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein: 2. A critical component is any component of a life 1. Life support devices or systems are devices or support device or system whose failure to perform can systems which, (a) are intended for surgical implant into be reasonably expected to cause the failure of the life the body, or (b) support or sustain life, or (c) whose support device or system, or to affect its safety or failure to perform when properly used in accordance with instructions for use provided in the labeling, can be effectiveness. reasonably expected to result in significant injury to the user. PRODUCT STATUS DEFINITIONS Definition of Terms Datasheet Identification Product Status Definition Advance Information Formative or In Design This datasheet contains the design specifications for product development. Specifications may change in any manner without notice. Preliminary First Production This datasheet contains preliminary data, and supplementary data will be published at a later date. Fairchild Semiconductor reserves the right to make changes at any time without notice in order to improve design. No Identification Needed Full Production This datasheet contains final specifications. Fairchild Semiconductor reserves the right to make changes at any time without notice in order to improve design. Obsolete Not In Production This datasheet contains specifications on a product that has been discontinued by Fairchild semiconductor. The datasheet is printed for reference information only. Rev. I5