PD - 90713C IRHM7230 IRHM8230 REPETITIVE AVALANCHE AND dv/dt RATED ® HEXFET TRANSISTOR N CHANNEL MEGA HARD RAD 200Volt, 0.40Ω Ω , MEGA RAD HARD HEXFET International Rectifier’s RAD HARD technology HEXFETs demonstrate excellent threshold voltage stability and breakdown voltage stability at total radiaition doses as high as 1x106 Rads(Si). Under identical pre- and post-irradiation test conditions, International Rectifier’s RAD HARD HEXFETs retain identical electrical specifications up to 1 x 105 Rads (Si) total dose. No compensation in gate drive circuitry is required. These devices are also capable of surviving transient ionization pulses as high as 1 x 1012 Rads (Si)/Sec, and return to normal operation within a few microseconds. Since the RAD HARD process utilizes International Rectifier’s patented HEXFET technology, the user can expect the highest quality and reliability in the industry. RAD HARD HEXFET transistors also feature all of the well-established advantages of MOSFETs, such as voltage control, very fast switching, ease of paralleling and temperature stability of the electrical parameters. They are well-suited for applications such as switching power supplies, motor controls, inverters, choppers, audio amplifiers and high-energy pulse circuits in space and weapons environments. Product Summary Part Number IRHM7230 IRHM8230 BVDSS 200V 200V n n n n n n n n n n n n n Radiation Hardened up to 1 x 106 Rads (Si) Single Event Burnout (SEB) Hardened Single Event Gate Rupture (SEGR) Hardened Gamma Dot (Flash X-Ray) Hardened Neutron Tolerant Identical Pre- and Post-Electrical Test Conditions Repetitive Avalanche Rating Dynamic dv/dt Rating Simple Drive Requirements Ease of Paralleling Hermetically Sealed Electrically Isolated Ceramic Eyelets Parameter VGS EAS IAR EAR dv/dt TJ T STG Continuous Drain Current Continuous Drain Current Pulsed Drain Current Max. Power Dissipation Linear Derating Factor Gate-to-Source Voltage Single Pulse Avalanche Energy Avalanche Current Repetitive Avalanche Energy Peak Diode Recovery dv/dt Operating Junction Storage Temperature Range Lead Temperature Weight www.irf.com ID 9.0A 9.0A Features: Absolute Maximum Ratings ID @ VGS = 12V, TC = 25°C ID @ VGS = 12V, TC = 100°C IDM PD @ TC = 25°C RDS(on) 0.40Ω 0.40Ω Pre-Irradiation IRHM7230, IRHM8230 9.0 6.0 36 75 0.60 ±20 330 9.0 7.5 5.0 -55 to 150 Units A W W/°C V mJ A mJ V/ns o C 300 (0.063 in. (1.6mm) from case for 10s) 9.3 (typical) g 1 10/14/98 Pre-Irradiation IRHM7230, IRHM8230 Devices Electrical Characteristics @ Tj = 25°C (Unless Otherwise Specified) Parameter Min Typ Max Units BVDSS Drain-to-Source Breakdown Voltage ∆BV DSS/∆T J Temperature Coefficient of Breakdown Voltage RDS(on) Static Drain-to-Source On-State Resistance VGS(th) Gate Threshold Voltage gfs Forward Transconductance IDSS Zero Gate Voltage Drain Current 200 — — V — 0.27 — V/°C — — 2.0 3.0 — — — — — — — — 0.40 0.49 4.0 — 25 250 Ω IGSS IGSS Qg Q gs Q gd td(on) tr td(off) tf LD Gate-to-Source Leakage Forward Gate-to-Source Leakage Reverse Total Gate Charge Gate-to-Source Charge Gate-to-Drain (‘Miller’) Charge Turn-On Delay Time Rise Time Turn-Off Delay Time Fall Time Internal Drain Inductance — — — — — — — — — — — — — — — — — — — 8.7 100 -100 50 10 20 35 80 60 46 — LS Internal Source Inductance — 8.7 — Ciss C oss C rss Input Capacitance Output Capacitance Reverse Transfer Capacitance — — — 1100 250 65 — — — V S( ) Ω µA nA nC ns nH Test Conditions VGS = 0V, ID = 1.0mA Reference to 25°C, ID = 1.0mA VGS = 12V, ID = 6.0A VGS = 12V, ID = 9.0A VDS = VGS, ID = 1.0mA VDS > 15V, IDS = 6A VDS= 0.8 x Max Rating,VGS=0V VDS = 0.8 x Max Rating VGS = 0V, TJ = 125°C VGS = 20V VGS = -20V VGS =12V, ID =9.0A VDS = Max Rating x 0.5 VDD = 100V, ID = 9.0A, RG = 7.5Ω Measured from drain Modified MOSFET symlead, 6mm (0.25 in) bol showing the internal from package to center inductances. of die. Measured from source lead, 6mm (0.25 in) from package to source bonding pad. pF VGS = 0V, VDS = 25V f = 1.0MHz Source-Drain Diode Ratings and Characteristics Parameter Min Typ Max Units IS ISM Continuous Source Current (Body Diode) Pulse Source Current (Body Diode) — — — — 9.0 36 A VSD t rr Q RR Diode Forward Voltage Reverse Recovery Time Reverse Recovery Charge — — — — — — 1.6 460 5.0 V ns µC ton Forward Turn-On Time Test Conditions Modified MOSFET symbol showing the integral reverse p-n junction rectifier. Tj = 25°C, IS = 9.0A, VGS = 0V Tj = 25°C, IF =9.0A, di/dt ≤ 100A/µs VDD ≤ 50V Intrinsic turn-on time is negligible. Turn-on speed is substantially controlled by LS + LD. Thermal Resistance Parameter RthJC RthCS RthJA 2 Junction-to-Case Case-to-Sink Junction-to-Ambient Min Typ Max Units — — — — 1.67 0.21 — — 48 Test Conditions °C/W Typical socket mount www.irf.com Radiation Characteristics IRHM7230, IRHM8230 Devices Radiation Performance of Rad Hard HEXFETs International Rectifier Radiation Hardened HEXFETs are tested to verify their hardness capability. The hardness assurance program at International Rectifier comprises three radiation environments. Every manufacturing lot is tested in a low dose rate (total dose) environment per MIL-STD-750, test method 1019 condition A. International Rectifier has imposed a standard gate condition of 12 volts per note 6 and a VDS bias condition equal to 80% of the device rated voltage per note 7. Pre- and post- irradiation limits of the devices irradiated to 1 x 105 Rads (Si) are identical and are presented in Table 1, column 1, IRHM7230. Post-irradiation limits of the devices irradiated to 1 x 106 Rads (Si) are presented in Table 1. Low Dose Rate VSD High dose rate testing may be done on a special request basis using a dose rate up to 1 x 1012 Rads (Si)/ Sec (See Table 2). International Rectifier radiation hardened HEXFETs have been characterized in heavy ion Single Event Effects (SEE) environments. Single Event Effects characterization is shown in Table 3. IRHM7230 IRHM8230 Parameter BVDSS VGS(th) IGSS IGSS IDSS RDS(on)1 Table 1, column 2, IRHM8230. The values in Table 1 will be met for either of the two low dose rate test circuits that are used. Both pre- and post-irradiation performance are tested and specified using the same drive circuitry and test conditions in order to provide a direct comparison. 100K Rads (Si) 1000K Rads (Si) Units Test Conditions Min Max Min Max Drain-to-Source Breakdown Voltage 200 Gate Threshold Voltage 2.0 Gate-to-Source Leakage Forward — Gate-to-Source Leakage Reverse — Zero Gate Voltage Drain Current — Static Drain-to-Source — On-State Resistance One Diode Forward Voltage — — 4.0 100 -100 25 0.40 200 1.25 — — — — — 4.5 100 -100 25 0.53 nA Ω VGS = 0V, ID = 1.0mA VGS = VDS, ID = 1.0mA VGS = 20V VGS = -20 V VDS=0.8 x Max Rating, VGS =0V VGS = 12V, ID = 6A 1.6 — 1.6 V TC = 25°C, IS = 9A, VGS = 0V Table 2. High Dose Rate V µA 1011 Rads (Si)/sec 1012 Rads (Si)/sec Parameter VDSS Drain-to-Source Voltage IPP di/dt L1 Min Typ Max Min Typ Max Units Test Conditions — — 160 — — 160 V Applied drain-to-source voltage during gamma-dot — 20 — — 20 — A Peak radiation induced photo-current — — 160 — — 8.0 A/µsec Rate of rise of photo-current 1.0 — — 20 — — µH Circuit inductance required to limit di/dt Table 3. Single Event Effects Ion LET (Si) (MeV/mg/cm2) Cu www.irf.com 28 Fluence (ions/cm2) 3x 105 Range (µm) ~43 VDSBias (V) 180 VGS Bias (V) -5 3 IRHM7230, IRHM8230 Devices Fig 1. Typical Response of Gate Threshhold Voltage Vs. Total Dose Exposure Fig 3. Typical Response of Transconductance Vs. Total Dose Exposure 4 Post-Irradiation Fig 2. Typical Response of On-State Resistance Vs. Total Dose Exposure Fig 4. Typical Response of Drain to Source Breakdown Vs. Total Dose Exposure www.irf.com IRHM7230, IRHM8230 Devices Post-Irradiation Fig 5. Typical Zero Gate Voltage Drain Current Vs. Total Dose Exposure Fig 6. Typical On-State Resistance Vs. Neutron Fluence Level Fig 8a. Gate Stress of VGSS Equals 12 Volts During Radiation Fig 7. Typical Transient Response of Rad Hard HEXFET During 1x1012 Rad (Si)/Sec Exposure www.irf.com Fig 8b. VDSS Stress Equals 80% of BVDSS During Radiation Fig 9. High Dose Rate (Gamma Dot) Test Circuit 5 Radiation Characterstics IRHM7230, IRHM8230 Devices Note: Bias Conditions during radiation: VGS = 12 Vdc, VDS = 0 Vdc Fig 10. Typical Output Characteristics Pre-Irradiation Fig 11. Typical Output Characteristics Post-Irradiation 100K Rads (Si) Fig 12. Typical Output Characteristics Post-Irradiation 300K Rads (Si) Fig 13. Typical Output Characteristics Post-Irradiation 1 Mega Rads(Si) 6 www.irf.com Radiation Characterstics IRHM7230, IRHM8230 Devices Note: Bias Conditions during radiation: VGS = 0 Vdc, VDS = 160 Vdc Fig 14. Typical Output Characteristics Pre-Irradiation Fig 16. Typical Output Characteristics Post-Irradiation 300K Rads (Si) www.irf.com Fig 15. Typical Output Characteristics Post-Irradiation 100K Rads (Si) Fig 17. Typical Output Characteristics Post-Irradiation 1 Mega Rads (Si) 7 IRHM7230, IRHM8230 Devices Fig 18. Typical Output Characteristics Fig 20. Typical Transfer Characteristics 8 Pre-Irradiation Fig 19. Typical Output Characteristics Fig 21. Normalized On-Resistance Vs. Temperature www.irf.com Pre-Irradiation IRHM7230, IRHM8230 Devices 30 Fig 22. Typical Capacitance Vs. Drain-to-Source Voltage Fig 24. Typical Source-Drain Diode Forward Voltage www.irf.com Fig 23. Typical Gate Charge Vs. Gate-to-Source Voltage Fig 25. Maximum Safe Operating Area 9 Pre-Irradiation IRHM7230, IRHM8230 Devices V DS VGS RD D.U.T. RG + -V DD 12V Pulse Width ≤ 1 µs Duty Factor ≤ 0.1 % Fig 27a. Switching Time Test Circuit VDS 90% 10% VGS Fig 26. Maximum Drain Current Vs. Case Temperature td(on) tr t d(off) tf Fig 27b. Switching Time Waveforms Fig 28. Maximum Effective Transient Thermal Impedance, Junction-to-Case 10 www.irf.com IRHM7230, IRHM8230 Devices Pre-Irradiation 1 5V L VD S D R IV E R D .U .T RG + - VD D IA S 12V 20V A 0 .0 1 Ω tp Fig 29a. Unclamped Inductive Test Circuit V (B R )D S S tp Fig 29c. Maximum Avalanche Energy Vs. Drain Current IAS Current Regulator Same Type as D.U.T. Fig 29b. Unclamped Inductive Waveforms 50KΩ QG 12V .2µF .3µF 12 V QGS D.U.T. QGD + V - DS VGS VG 3mA Charge Fig30a. Basic Gate Charge Waveform www.irf.com IG ID Current Sampling Resistors Fig 30b. Gate Charge Test Circuit 11 Pre-Irradiation IRHM7230, IRHM8230 Devices Total Dose Irradiation with VGS Bias. See Figures 18 through 30 for pre-radiation 12 volt VGS applied and VDS = 0 during irradiation per MIL-STD-750, method 1019, codition A. Total Dose Irradiation with VDS Bias. VDS = 0.8 rated BVDSS (pre-radiation) applied and VGS = 0 during irradiation per MlL-STD-750, method 1019, condition A. This test is performed using a flash x-ray source operated in the e-beam mode (energy ~2.5 MeV), 30 nsec pulse. All Pre-Irradiation and Post-Irradiation test conditions are identical to facilitate direct comparison for circuit applications. curves Repetitive Rating; Pulse width limited by maximum junction temperature. Refer to current HEXFET reliability report. VDD = 25V, Starting TJ = 25°C, Peak IL = 9.0A, RG =25Ω ISD ≤ 9.0A, di/dt ≤ 120A/µs, VDD ≤ BVDSS, TJ ≤ 150°C Suggested RG = 7.5Ω Pulse width ≤ 300 µs; Duty Cycle ≤ 2% Case Outline and Dimensions — TO-254AA .1 2 ( .0 0 5 ) 1 3 .8 4 ( .5 4 5 ) 1 3 .5 9 ( .5 3 5 ) 3.7 8 ( .14 9 ) 3.5 3 ( .13 9 ) -A - 2 0 .3 2 ( .8 0 0 ) 2 0 .0 7 ( .7 9 0 ) 1 7 .4 0 ( .6 8 5 ) 1 6 .8 9 ( .6 6 5 ) 3 1 .4 0 ( 1 .2 3 5 ) 3 0 .3 9 ( 1 .1 9 9 ) 6 .6 0 ( .2 6 0 ) 6 .3 2 ( .2 4 9 ) 1 2 -B 1 .2 7 ( .05 0 ) 1 .0 2 ( .04 0 ) 1 3 .84 ( .5 4 5 ) 1 3 .59 ( .5 3 5 ) LEG END 1 - C O L L E C TO R W 2 - E M ITTE R 3 - G A TE 3 -C- 3X 3 .81 ( .1 5 0 ) 2X 1 .1 4 ( .0 45 ) 0 .8 9 ( .0 35 ) .5 0 ( .0 2 0 ) .2 5 ( .0 1 0 ) 1 2 3 3 .8 1 ( .1 5 0 ) M C A M B M C N O TE S : 1 . D IM E N S IO N IN G & TO L E R A N C IN G P E R A N S I Y 1 4 .5 M , 1 98 2 . 2 . A L L D IM E N S IO N S A R E S H O W N IN M ILL IM E TE R S ( IN C H E S ). LEGEND 1- DRAIN 2- SOURCE 3- GATE LEGEND 1- DRAIN 2- SOURCE 3- GATE Conforms to JEDEC Outline TO-254AA Dimensions in Millimeters and ( Inches ) CAUTION BERYLLIA WARNING PER MIL-PRF-19500 Package containing beryllia shall not be ground, sandblasted, machined, or have other operations performed on them which will produce beryllia or beryllium dust. Furthermore, beryllium oxide packages shall not be placed in acids that will produce fumes containing beryllium. 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