SYMBOLS & CODES EXPLAINED j p 7 e 4 . { i a i ( i . . [A G n LINE TYPE [DEVICE Vp. BVdss (BVgss _| \ass Igss@ ND] COMMON SOURCE/ Rds | MAX. | IN STRUC|Y200 (EO No. No. [DISS @ | | Id Ig |Vgs=0O8 we pi Vgs /Vds gfs Yos Cis FREE |MAX|-TURE | s/a jAD @25C |ld=0 |Vds | Vds>Vp!& mhos. AIR [TEMP T0200/D E w) | (vy | ty) Vv} | tA) | A A Vv MAX ee C Ser. v- Matched Type, also listed in STRUCTURE Section 13, Category 6 A typical afg D ~ Diffused @ Phototransistor, also listed in Pulsed E Epitaxial tooe bonr ae ; % High Frequency (Yes) Ge GermaniumPE 5 (i- Yes PE Planar Epitaxial PL Planar eet tg: . # Junction Type A With infinite heat sink A_y - Y, * Insulated Gate (MOS Type) T Above 28C; For additional is 9 _ Matched pair or dual information, consult manufacturer. + Not at given test conditions A Switching, other uses % Maximum Zw Chopper, Other uses + * Pulsed D Noise figure 8db or below VgglCut off} mi fT = Plastic Package A. Vogt Threshold) Vv H Hometaxial % Typical % Maximum $ Tetrode # Mini A Not given at test conditions % Insulated Gate (MNOS Type} - imimum R [_# = Mini T Rosion) # Vps * A Depletion Mode, Type A $ Depletion-Enhancement Mode, Type B x Enhancement Mode, Type C a A - BYv T- sv bso DSX A pss @ Ves = Qand Vos Vp Ves 790 Minimum Typical Pulsed ON e+ P+ , (Output Shorted) Not given at test conditions Typical Cass Cag0 g-c igs JJunction $Storage AAmbient CCase A Phototransistor Device A Tetrode Device % Composite Type BYngo ! Lo mE al ks esaleain M wa Re aay alg we TYPE No. fT - 40 # g0c * 45C $ 100c # 50 D Free Air Zz 60C y Typical Vatue 75C A- > 100C Symbols indicate temperature at which derating starts. A Q With infinite heat sink Following symbols indicate temp W Power at which derating starts: Output f- 40% (- ec % gor * 45C ~- 70C A Pulsed #- 50% $$ - 100C %_ min * 0-65C A Ambient @ 70-80 C Case # 85-100C J Junction # 110-125C S Storage 130-135C ~ 140-165C 170-200C v Over 200C D - te . $ Minimum # Pulsed or Peak a T At temperature 25C Case D- 1, # Pulsed $ Minimum aE t sraucly indicated Maximum tyt % * Ton t, # ~ ts QD ~ AtVog < Max. Veg (see mfr. spec.) FT - ttt * Tote # Icex ky A - rs * = Ton * Toft 1 cer CEO) CES @ AtTemp. 25C Case Vv Typical Value # Pulsed $ Typical tT AtTemp. > 25C # Rated max. operating frequency f # BV __ or punch-through t <b x a Gain bandwidth product (ft) Q- BV ces * Pulsed A- 1 * Maximum frequency of oscillation g BV BVsoisus) B-1 Q Figure of merit (frequency for CER $ Minimum B unity power gain) op A Minimum Z- Maximum 7 At Temp. 25C Case fon a $ Minimum ~~ "fe * ~ Available to # Pulsed selected range $ ~ Tetrode Typical narrower than # Radiation Resistant Device (Also see top of reverse side of card.)IN ORDER OF (1) MIN. DERATING FACTOR TYPE | ceo |icbo @ fae | MAX.| tr EO No. MAX V. SAT. -TURE | s/a |AD @25C RES. TO200/D E 40355 : : 0 1150 100nd 10m | 55 Z 100MEA Riis |G MT 1070 : : : 14 Z | 50nd |5.0 |5.0m 185 |15G8 | x77 |AD TRL2254S : : : 0 |225 10u 10%|500m 35 Z| 20MsA TOS TRL2754S : 0/275 10u 10Z|500m 35 Z| 20M8A TOS TRL3504 : 0 {350 10m | 10%|500m 35 20MEA TO5 TRL4504 : : : 0 |450 10m | 104/500m 20M5A TOS TRLS504 . : : : 10m 500m 20M5A TO5 TRL7014 : : : : 10% |500m 20M5A TOS 2014 : : : : : ; 104|1.0 20M5A TOS TRM2504S : : : : : 104] 1.0 20M5A TOS 14S : : : : 10Z| 1.0 20M5A TO5 TRM4014 : : : : 7OM5A TOS TRM5014 : : : : : : : 20M8a TOS TRM6014 : : : : 104] 1.0 20M5A r TOS 7504 : : : : 104] 1.0 20M5A TO5 . . . u 11CB2 . : 10/150 @|100 13k . . MD14 ; : O7u 11CB5 . . 10G|150 Z| 20 13k8 : 5 MD14 11CB8 : : 100/150 Z| 20 13k8 O7u MD14 7C13 : 200 | 75 20Mt R45 07013 ; 10/200 20Mt R46 . : m . u 8 xC713 . . ; 0D |.75 1.2Mt ([2. ; TOs ST6510 , , 106].15 TOS $T7200 . . , 1.0 ; TO61 B3746 : , 10m | 3 TO18 15 : : : 10% |500m 20MSA MD14 TRL6O15 : : : : 10% |500m 20M5A MD 14 TRL7505 : : : 10%|500m 20MSA MD14 TRM2255S : : : : 10D) 1.0 20MSA MDt4 TRM2755S : : : : 104] 1.0 20M5A MD14 TRM3505 : : : : 102} 1.0 20M5A MD14 TRM4015S : : : 10B| 1.0 20M5A MD 14 TRMSO15S : : : : 109) 1.0 20M8A MD14 TRM7015 : : : 1.0 20MSA MD14 USA55191 5OM8A| 27 |300nd 28C118 : : 70M8 SYMBOLS AND CODES 91 D.A.T.A. EXPLAINED IN INTERPRETER 91