2N3675 -2N3765 Numerical Index =| MAXIMUM RATINGS ELECTRICAL CHARACTERISTICS a ~ ~ - EE] | REPLACE | PAGE Po |S} Ti | Vee | Voce |-2 tre @ Ie Versan @ Ie #/ tole TRE JE (S| ment | numaer | USE = 8 2 elm |B) 2/2 =| @25C | S| C | (volts) | (volts) | | (min) (max) S} (volts) s 3 5|s 2N3675 |S|]N PMS 8.8W | C |} 200 90 55 ]0 12 60 1.0A 0.8 1L.0A L.OM | T 2N3676 |S|N PMS | 8.8W]C | 200 90 90 {GO} 12) 60} 1.0A 0.8} L.0A 1L.OM4T 2N3677 | S| P CHP | 0.4w | A | 200 30 20 |o 5.0M | T 2N3678 | SIN HSS 0.8W | A | 200 75 55 | 0 40 | 120 | 0.15A 0.4} 0.154 250M |] T 2N3679 | Unijunction Transistor, see Table on Page 1-174 2N3680 | S|N DFA 0.3W | A {| 200 60 50 | O | 150 | 600 1Lo* 0.7 10M 300 /E 60M | T 2N3681 |S |N RFA 0.2W ] A | 200 10 7.0 ]0 20 | 220 2.0M 0.37 4.0M 20 ]E 1.06 |T 2N3682 | S|N RFA | 0.36W | A | 200 40 15 | 0 40] 120 10M 45 ]E 600M | T 2N3683 | S|N RFA Q.2W | A | 200 30 12/0 20 | 150 8.0M 30 ]E 1.06 }T 2N3684 thru Field Effect Transistors, see Table on Page 1-166 2N3687 2N3688 |S |N REC O.2wWw } A 1125 40 40 ]0 30 4.0M 400M | T 2N3689 |S] N RFC | 0.2w | A | 125 40 40,0] 30 4.0M 400M | T 2N3690 |} S|N RFC 0.2W | A] 125 40 40 ]0 30 4.0M 400M | T 2N3691 |S} N | MPS6512 5-109] AFC 0.2W | A | 125 35 20 ]0 40 | 160 10M 0.7 LOM 40 ]/E 200M | T 2N3692 |S} N | MPS6513 5-109} AFC 0.2W | A] 125 35 20 | O | 100 | 400 10M 0.7 10M 100 FE 200M 4 T 2N3693 )}S}N REC O.2W } A) 125 45 45 10 40 | 160 10M 200M ) T 2N3694 |S |N RFC O.2W | A] 125 45 45 | 0 4100 j 400 LOM 200M | T 2N3695 ghra 3 Field Effect Transistors, see Table on Page 1-166 N369. 2N3700 |S | N RFA O.5w | A | 200 140 80 | 0 | 100 | 300 1 0.154 0.2 | O.15A 80 |E 100M | T 2n3701 | 8 | N RFA | 0.5w]A|200| 140 | 80/0 | 40|120]0.15a | 0.2|0.15a | 30/8 | 8om|T 2N3702 |S | P AFC 0.3w | A | 150 40 25 |0 60 | 300 50M 0.25 50M 100M | T 2N3703 | Sj P AFC | 0.3W 7A | 150 50 30 |O | 30] 150 50M { 0.25 50M 100M | 2N3704 |S |N AFC | 0.36W {A | 150 50 30 | 0 | 100 | 300 50M 0.6 O.1A 100M | T 2N3705 |S |N AFC | 0,36W | A {150 50 30 | 0 50 | 150 50M 0.8 O.1A 100M | T 2N3706 |S |N AFC { 0.36W | A 1150 40 20 | 0 30 | 600 50M 1.0 O.1A 100M {[ T 2N3707 |S |N AFC | 0,25W | A | 150 30 30 | 0 | 100 j 400 O.1M 1.0 LOM 100 | E 2N3708 |S] N AFC | 0.25W | A | 150 30 30 10 45 | 660 1.0M 1.0 10M 45 /E 2N3709 |S]N AFC | 0.25W | A | 150 30 30 ]0 45 | 165 1.0M 1.0 10M 45 /E 2N3710 |S} N AFC | 0.25W | A | 150 30 30 10 90 | 330 1.0M 1.0 10M S0/E aNn3711 )S)N AFC ] 0.25W |} A ] 150 30 30 | O 1180 | 660 1.0M 1.0 10M 180 )E 2N3712 |S | N RFC 0.8W 1A | 200 150 150 | 0 30 | 150 30M 2.0 50M 25 |/E 40M] T 2N3713 |S |N 7-125 | HPA 150w | C | 200 80 60 | 0 25 75 1.04 1.0 5.0A 25 |E 30K | E 2N3714 |S |N 7-125 | HPA 150W | C } 200 100 80 | 0 25 75 1.0A 1.0 5.0A 25 /E 30K | E 2N3715 |S | N 7-125 | HPA 150W | C } 200 80 60 | 0 50 | 150 1,0A 0.8 5,04 25 /E 30K { E 2N3716 |S |N 7-125] HPA L50W | C } 200 100 80 | 0 50 | 150 1.04 0.8 5.0A 25 |[E 30K | E 2N3717 | S| N HPA 7.5W | C | 200 60 60 |S |2.0 | 100 O.5A 1.0 O.5A 250M | T 2N3718 |S |N HPA 10W | Cc | 200 60 60 7S | 2.0 | 100 O.5A 1.0 O.5A 250M | T 2N3719 |S7]P 7-129 PHS 6.0W | C | 200 40 40 10 25 | 180 1.0A LS O.3A 60M | T 2N3720 | S| P 7-129] PHA 6.0W | C | 200 60 60 | 0 25 | 180 1.0A L.5 3.0A 60M | T 2N3721 |S|N AFC O.2w }A |}125 18 18/0 60 | E 2N3722 |S |N MSS 0.8W | A | 200 80 60 | 0 40 | 150 O.1A 0,22 O.1A 300M [T 2N3723 |S] N HSS 0.8W | A | 200 100 80 | 0 40 | 150 O.1A 0.25 10M 300M | T 2N3724 | S/N HSS | 0.8W | A | 200 50 30 ]0 ; 607150] O.1A 0.2] O.1A 300M | T 2N3724A} S| N 8-257 | HSS lw jA 50 30 | 0 60 | 150 100M 0.2 100M 2N3725 |S|N HSS 0.8W ] A | 200 80 50 | 0 60 | 150 Q.1A 0.26 O.1A 300M) T 2N3725A) S | N 8-257] HSS W fA 80 50] 0 60 | 150 100M 0.26 100M 3/E 2N3726 |S] P DFA 0.4w | A | 200 45 45 | 0 |135 | 350 1.0M 0.25 50M 135 ]E 200M | T 2N3727 |S | P DFA 0.4w | A { 200 45 45 | 0 1135 | 350 L.0M 0.25 50M 135 }E 200M | T 2N3728 |S|N DFA | 0.45wW | A | 200 60 30 | 0 80 | 280 | 0.154 0.221) 0.154 50 |E 250M | T 2N3729 | S|N DFA | 0.45w | A | 200 60 30 | 0 80 | 280 | 0.154 0.22 10.154 SO TE 250M | T 2N3730 |G] P 8-259] LPA 10w | A | 100 200 200 |S 2N3731 |G] P 8-259] LPA 5.0W | A | 100 320 320 15 15 6.0A 2N3732 | G| P 8-259 , LPA 3,0W | A | 100 100 100 {$s 35 | 500 O.7A 1.0M | T 2N3733 |S | N 9-82 HPA 23wW | Cc } 200 65 40 |0 LO | 150 | 0.254 1.0 1.0A 250M | T 2N3734 |S |N 8-259] HSS 1,0W | A | 200 50 30 | O 30 | 120 1.04 0.2 10M 300M | T 2N3734A] S | N 8-259| HSS] 1.OW]A 50 30 | 0} 30]120] 1.0A 0.9} 1.0A | 2.5]E 2N3735 | S| N 8-259] HSS 1.0Ww | A | 200 75 50] 0 20 80 1.0A 0.2 LOM 250M | T 2N3735A| S | N 8-259] HSS LOW sA 75 50/0 20 80 1.04 0.9 1.0A 2.5/E 2N3736 {S| N 8-259] HSS O.5wW | A | 200 50 30 1)0 30 | 120 1,04 0.2 10M 300M | T 2N3736A) S| N 8-259] HSS O.SW TA 50 30] 0 30 | 120 L.OA 0.9 LOA 2.5) 2N3737 }SIN 8-259 | HSS O.5W ) A | 200 75 50 790 20 80 L.OA 0.2 10M 250M | T 2N3737A) S| N 8-259] HSS O.SW IA 75 50 | 0 20 80 1.04 0.9 1.04 2.575 2N3738 |S] N 7-133 | LPA 20W | Cc | 175 250 225/10 40 | 200 O.1A 2.5] 0.25A 35 ]E 15M{T 2N3739 | S|N 7-133 | LPA 20W | C | 175 325 300 | 0 40 | 200 O.1A 2.510.254 35) E LSM] T 2N3740 | S| P 7-137 | LPA 25w ;C | 200 60 60/0 30 | 100 | 0.25Aa 0.6 1.04 25/E 4.0M} T 2N3741 |S] P 7-137 | LPA 25W }C | 200 80 80 40 30 | 100 | 0.25A 0.6 1.0A 25]E 4.0M|T 2N3742 | S| N 8-265] VID 1.0W | A [200 | 300 | 300 | 0 | 20 | 200 30M 1.0 10M 20]; E 30M | T 2N3743 |S | P 8-269] vin] 1.ow}A}200} 300 | 300]0] 25 } 250 30M 5.0 10M 30] E 30M | T 2N3744 |S) N HPA 30W | C } 200 60 40] 0 20 60 1.04 0.25 1.0A 20/5 30M | T 2N3745 | S| N HPA 30W | C | 200 80 60/0} 20] 60}; 1.0A] 0.25] 1.04 20], E 30M | T 2N3746 1 S[N HPA 30W | C | 200 100 80) 0 20 60 L.OA 0,25 1L.OA 20} E 30M] T 2N3747 | S| N HPA 30W | C | 200 60 4010 40 | 120 1.0A 0.25 1.0A 40]/E 40M | T 2N3748 |S |N HPA 30w | C | 200 80 60 | 0 40 | 120 L.0A 0.25 1.04 40] E 40M | T 2N3749 | S| N HPA 30W | Cc | 200 100 80 | 0 40 | 120 1.0A 0.25 1L.0A 40/E 40M | T 2N3750 1S | N HPA 30W | C 1 200 60 40 ]0 ]100 | 300} 1.0A } 0.25] 1.0A |] 100] E 50M | T 2N3751 |S] N HPA 30W | C | 200 80 60 |O f100] 300] 1.0A] 0.25] 1.0A] 100] E 50M | T Onaga Sy N HPA 30w } C | 200 100 80 | 0] 100 |) 300 1.0A 0.25 1.0A 100) E 50M | T N thru Thyristors, see Table on Page 1-154 2N3761 2N3762 | S| P 8-273] HSS 1.0W | A | 200 40 40] 0 30 | 120 1.04 o.1 10M 180M {| T 2N3763 | S| P 8-273] HSS 1.0W | A | 200 60 60 | 0 20 80 1.0A 0.1 10M 150M} T 2N3764 |S] P 8-273] HSS O.5W | A | 200 40 4010 30 | 120 1.0A O.1 10M 180M | T 2N3765 |S | P 8-273 | HSS O.5wW fA | 200 60 60 | 0 20 80 1.0A O.1 10M 150M | T 1-142Power Transistors SILICON POWER TRANSISTOR SELECTOR GUIDE (continued) Type Veto hee @ Ne Voce sat) @ Ne & \y - PNP Volts (Max) Min/Max Amp Volts (Mex) Amp | Amp 3.0 AMP (Timay = 200C) a Lo: 01 he O21 oS 6,15 Po = 6.0W : 1.5. 0.48 fr 3.0 MHz Go noe 0.195. *7 60 MHz : 0.6" 1,0: 0,325 80. Au O26 0.6 100 6.4125 Case 31 40 30/150 0.25 0.6 1.0 0.1 Solid Header 2N4238 60 30/150 0.25 0.6 1.0 0.1 , 2N4239 80 30/150 0.25 0.6 1.0 0.1 4.0 AMP (Tomax) = 200C) Po =10W | I J Case 31 tf; 4.0 MHz 2N4877 60 20/100 4.0 1.0 4.0 0.4 (T0-5) Pp =20W 2N3054* 60 25/100 0.5 1.0 0.5 0. 05 tf; 10 MHz 2N3766 60 40/160 0.5 1.0 0.5 0. 05 2N3767 80 40/160 0.5 1,0 0.5 0.05 : 0.280 0.8" 1,0 0.125 Pp = 25W 2b: . . : 16 *f 1.0 MHz gk : : st f 3.0 MHz ONag00. 1b 20/100. O68. : Te: . by ont, 4.0 MHz BO i af A0 : Case 80 re 2N4910 40 20/100 0.8 0.6 1,0 0.4 (10-66) 2N4911 60 20/100 O.5 0.6 1.0 0.1 2N4912 80 20/100 .5 0.6 1.0 0.1 MJ4101** 40 25/100 1.5 1,0 1.5 0,15 2N4231 40 25/100 1.5 0.7 1.5 0.15 = 35 . Po = 2 He 2N4232 60 25/100 1.5 0.7 1.5 0,15 mT" 2N4233 | 80 25/100 1.5 0.7 1.5 0.15 5.0 AMP (Tacmax) = 200C) o2N4905 Pp = 87.5W 5 -2N4006 f+ 4.0 MHz Case 11 r 2N4913 40 25/100 2.5 1.0 2.5 0.25 . 2N4914 60 25/100 2.5 1.0 2.5 0.25 2N4915 80 25/100 2.5 1.0 2.5 0.25 2N5067 40 20/80 1.0 0.4 1.0 O.1 2N5068 60 20/80 1.0 0.4 1,0 0.1 2N5069 80 20/80 1.0 0.4 1.0} 9.3 Pp=li7Ww 2N1724 80 20/90 2.0 1.0 2.0 0.2 - fy 10 MHz 2N1725 80 50/150 2.0 1,0 2.0 0.2 Case 9 (T0-61) 7.5 AMP (Tucan = 200C) 2N3445 60 20/60 3.9 1.5 3.0 0.3 Pp = 115 W 2N3446 80 20/60 3.0 1.5 3,0 0.3 f- 10 MHz 2N3447 60 40/120 3.0 1.5 5.0 0.5 Case 11 2N3448 80 40/120 5.0 1.5 5.0 0.5 (T0-3) Pp =117W fy 1.0 MHz 2N3232 60 15/75 3.0 2.5 3.0 0.2 Case l (70-3) 2N3487 60 20/60 3.0 1.2 3.0 0.3 2N3488 80 20/60 3.0 1,2 3.0 0.3 Po = 117W 2N3489 100 15/45 3.0 1.2 3.0 0.3 fr 10 MHz 2N3490 60 40/120 5.0 1.0 3.0 0.3 Case 9 2N3491 80 40/120 5.0 1.0 3.0 0.3 (70-61) 2N3492 100 30/90 5.0 1.0 3.0 0.3 II\QQKL},]} WN A QGV,. WC X DK QQ) WW Ql |'"M)NWWWWWD oe F AGDA nz i|I\){Power Transistors 2N3740 (siicon) Ves = 60-80V Cc = 2N3/4] P, = 25W = Medium-power PNP transistors, ideal for use as Sani drivers, switches and direct replacement of germani- = um medium-power devices, feature low saturation CASE 80 voltage and excellent safe area limits. Complement to (TO-66) NPN 2N3766 (2N3740) 2N3767 (2N38741) MAXIMUM RATINGS Rating Symbol | 2N3740|2N3741| Unit Collector-Base Voltage Vos 60 80 Vde Emitter-Base Voltage VB 7.0 7.0 Vde Collector-Emitter Voltage Voro 60 80 Vde Collector Current (Continuous) See Figure 2 To 4.0 Adc Collector Current (Peak) See Figure 2 Io 4.0 Adc Base Current ly 2.0 Adc Total Device Dissipation @ To= 25C Ph 25 Watts Derate Above 25C 0.143 w/C Operating and Storage Junction Ty Tate -65 to +200 c Temperature Range FIGURE 1 POWER - TEMPERATURE DERATING CURVE 25 aA a E 2 = 3 p ce 15 a. Z mY = 10 = So a. Rn) ~~ 0 0 25 50 75 100 125 150 175 200 To, TEMPERATURE (C) Safe Area Curves are indicated by Figure 2. Both limits are applicable and must be observed. 7-1372N3740, 2N3741 (continued) ELECTRICAL CHARACTERISTICS (at Ts = 25C unless otherwise noted) Power Transistors f Characteristics [Figure No. | Symbol | Min | Max | Unit | OFF CHARACTERISTICS Collector-Emitter Sustaining Voltage* Vv * Vde (ig = 100 mAdc, I, = 0) 2N3740 CEO(sus) 60 _ 2N3741 80 _ Emitter Base Cutoff Current TBO mAdc (Veg = 7.0 Vdc) Both Types _ 0.5 Collector Cutoff Current logy mAdc Vor = 60 Vdc, Vor = 1.5 Vdc) 2N3740 ~~ 0.1 Vor = 80 Vdc, VBE =1.5 Vdc) 2N3741 _ o.1 Vor = 40 Vdc, Vge = 1.5 Vde, To = 150 C) 2N3740 _ 1.0 Wor = 60 Vdc, VaeE = 1.5 Vde, Te = 150 C) 2N3741 _ 1.0 Collector-Emitter Cutoff Current Ingo mAdc Vor = 40 Vdc, iB =0) 2N3740 _ 1.0 Vop = 60 Vde, bB = 0) 2N3741 _ 1.0 Collector Base Cutoff Current lego mAdc Voy = 60 Vdc, I; = 0) 2N3740 _ O12 Von = 80 Vdc, Ip = 0) 2N3741 _ 0.1 ON CHARACTERISTICS DC Current Gain rE 7 (Ig = 100 mAde, Vor = 1.0 Vde) Both Types 40 _ Mg = 250 mAdc, Vor = 1.0 Vdc) Both Types 30 100 Ug = 500 mAde, Yor = 1.0 Vdc) Both Types 20 _ Mg =1.0 Ade, Vor = 1.0 Vde) Both Types 10 _ Collector-Emitter Saturation Voltage Vor(sat) Vdc My =1.0 Adc, ib = 125 mAdc) Both Types _ 0.6 Base-Emitter Voltage 3,4,9,10 Var Vdc (lg = 250 mAdc, Vog = 1.0 Vde) Both Types _ 1.0 TRANSIENT CHARACTERISTICS Current-Gain-Bandwidth Product fp MHz Ug = 100 mAdc, Vog = 10 Vdc, f = 1.0 MHz) Both Types 4.0 Common Base Output Capacitance Cob pF (Vo = 10 Vac, I, = 0, f = 100 kHz) Both Types _ 100 Smali-Signal Current Gain hte ~ Mg = 50 mAdc, Vor = 10 Vdc, f = 1.0 kHz) Both Types 25 *PULSE TEST: PW< 300 us, Duty Cycles 2.0% FIGURE 2 ACTIVE REGION SAFE OPERATING AREA Ty = 200C SECONDARY BREAKDOWN LIMITATION Io, COLLECTOR CURRENT (AMP) THERMAL LIMITATION -EMITTER DISSIPATION IS LIMIT FOR: SIGNIFICANT ABOVE Io = 2.0 AMP)} 2N3740 PULSE DUTY CYCLE << 10% 2N3741 10 20 30 50 70 10 20 Voce, COLLECTOR-EMITTER VOLTAGE (VOLTS) 30 50 70 100 7-138 The safe operating area curves indicate lc Vce limits of the transistor which must be observed for reliable operation. Collector load lines for specific circuits must fall below the limits indicated by the applicable curve. The data of Figure 2 is based upon Tyipk} = 200C; Te is variable depending upon conditions. Pulse curves are valid for duty cycles to 10% pro- vided Tyipi) = 200C. Typ) may be calculated from the data in Figure 7 . At high case tempera- tures, thermal limitations will reduce the power which can be handled to values less than the limita- tions imposed by secondary breakdown.Power 2N3740, 2N3741 (continued) LARGE SIGNAL CHARACTERISTICS FIGURE 3 TRANSCONDUCTANCE 1000 700 500 4 = 55C 300 200 T) = +25C 100 T= +100C 50 30 20 Ty == +175C Ic, COLLECTOR CURRENT (mA) 3 0 0.2 0.4 06 08 1a 12 Vee, BASE-EMITTER VOLTAGE (VOLTS) FIGURE 4 INPUT ADMITTANCE 100 50 20 10 Ty = -55 5.0 Ty = +25C 2.0 1.0 Ty = + 100C 05 Ip, BASE CURRENT (mA) 02 0.1 0.05 0 Ty = F175 0.2 04 06 08 1.0 12 Vee, BASE-EMITTER VOLTAGE (VOLTS) Transistors 10 oor nm oO ee R Ic, COLLECTOR CURRENT (mA) 0.05 0.02 0.01 02 o eo - 8 wa @G&@ a2 Ic, COLLECTOR CURRENT (mA) 2 eof ef am ht 0.02 O01 100 94 OFF REGION CHARACTERISTICS FIGURE 5 TRANSCONDUCTANCE 5.01 Vg = BYceq ~ 20 Ty = +100C 8 Ol 0.2 03 0.4 0.5 0.6 Vee, BASE-EMITTER VOLTAGE (VOLTS) FIGURE 6 EFFECTS OF BASE-EMITTER RESISTANCE Ty= + 28C 20K 10K 100K Rag. EXTERNAL BASE-EMITTER RESISTANCE (OHMS) FIGURE 7 THERMAL RESPONSE eor ano 2 Ro 0.1 0.07 2 a 0.03 9.02 nt), TRANSIENT THERMAL RESISTANCE, NORMALIZED O01 0.01 0.02 0.03 0.05 01 02 03 05 10 2. Vr DUTY CYCLE, D= 0 30 50 10 t, TIME (ms) 7-139 20 D CURVES APPLY FOR POWER PULSE TRAIN SHOWN READ TIME At ty Tyipty To = Prot) Buclt 30.50 100 200 300 500 1000hee, DC CURRENT GAIN Veg, COLLECTOR-EMITTER VOLTAGE (VOLTS) VOLTAGE (VOLTS) Power Transistors 2N3740, 2N3741 (continued) FIGURE 8 CURRENT GAIN Ty = +175C Ty = +25C 100 200 Ic, COLLECTOR CURRENT (mA) 500 1000 SATURATION REGION CHARACTERISTICS FIGURE 9 COLLECTOR SATURATION REGION Ic = 250 mA ta, BASE CURRENT (mA) le = 1000 mA FIGURE 10 ON VOLTAGES FIGURE 11 TEMPERATURE COEFFICIENTS +10 @lcilp = 10 +0.5- vc for Veetsat} (4+100C to +175C) a (55C to +25C) Vaz @ Vee = 2.0 aff | To compute saturation voltages : V__ (sat) @ operating Ty = V_ (sar) @ +25C + Oy_ (operating Ty ~25C) .5- Use appropriate Gy for voltage of interest. | Use appropriate curve for temperature range of interest. T Ove for Vee | eannmet | | (55C to +175} 4 ee Oy, TEMPERATURE COEFFICIENTS (mV/C) b an Voe(sat} i Io, COLLECTOR CURRENT (AMP) 7-140 100-200 300 400 500) 600) 700 800) 900 1000 Ic, COLLECTOR CURRENT (mA)Power Transistors 2N3740, 2N3741 (continued) DYNAMIC CHARACTERISTICS FIGURE 12TURN-ON TIME FIGURE 14 CAPACITANCE mT = $25 == T= +150C Veo = 24V t, TIME (ss) CAPACITANCE (pF) Veo = 24V, Vob = 0 10 2 30) 50 70100 200 300 2.0 50 10 20 fc, COLLECTOR CURRENT (mA) Vp, REVERSE VOLTAGE (VOLTS) FIGURE 13 STORAGE TIME FIGURE 15 FALL TIME _- 7, = 425C ~ T= +150 wT = 25C = T= +150 t,, STORAGE TIME (y:8) ty, FALL TIME (118) 0 20-30 50 70 100 200 300 500 700 1000 1a 2 30 50 70 100 200 300 = 500 700 1000 Ic, COLLECTOR CURRENT {mA) Ic, COLLECTOR CURRENT (mA) 7-141Switching and General Purpose Transistors 2N3724, 2N3725 2N4013, 2N4014 (continued) ELECTRICAL CHARACTERISTICS (1, = 25C unless otherwise noted) Characteristic Symbol | Min | Max | Unit ON CHARACTERISTICS (continued) Collector-Emitter Saturation Voltage* Vor(sat)* Vdc a, = 10 mAdc, Ig = 1.0 mAdc) - 0, 25 I. = mAdc, I, = mAdc N 2N - . Cc 100 B 10 mA 2N3724, 2N4013 0.20 2N3725, 2N4014 - 0.26 Mp = 300 mAdc, I3e 30 mAdc) 2N3724, 2N4013 - 0.32 2N3725, 2N4014 - 0.40 (lg = 500 mAdc, I, = 50 mAdc) 2N3724, 2N4013 - 0. 42 2N3725, 2N4014 - 0. 52 de = 800 mAdc, I, = 80 mAdc) 2N3724, 2N4013 - 0. 65 2N3725, 2N4014 - 0. 80 (I, = 1.0 Ade, I,, = 100 mAde) 2N3724, 2N4013 - 0.75 2N3725, 2N4014 - 0.95 Base-Emitter Saturation Voltage* Vv * Vdc (I, = 10 mAde, Tg = 1.0 mAde) BE(sat) - 0.76 (a mAdc, I, = mAdc - . c 100 B 10 mA 0. 86 Co = 300 mAdc, I, = 30 mAdc) - 11 Gy = 500 mAdc, Ip 50 mAdc) 0.9 1.2 dg = 800 mAdc, Int 80 mAdc) - 1.5 My = 1,0 Ade, 1, = 100 mAdc) - 1.7 SMALL-SIGNAL CHARACTERISTICS Current-GainBandwidth Product fp MHz a, = 50 mAdc, Vor = 10 Vdc, f = 100 MHz) 300 - Output Capacitance Cob pF (Vop = 10 Vdc, Ip = 0, f = 140 kHz) 2N3724, 2N4013 - 12 2N3725, 2N4014 - 10 Input Capacitance Ciy pF (Var = 0.5 Vdc, Ine 0, f = 140 kHz) - 55 SWITCHING CHARACTERISTICS Turn-On Time ton - 35 ns (Vaan = 30 Vde, Vip = 3,8 Vdc 5 cc > "BE (aff) ; _ Delay Time Ig = 500 mAde, I; = 50 mAdc) a *0 ns Rise Time (See Figure 1) t. - 30 ns Turn-Off Time tote - 60 ns (Vog = 30 Vde, I, = 500 mAdc, Storage Time ~ . t - 50 ns 31 =lp2 = 50 mAdc) s Fall Time (See Figure 1) 2N3724, 2N4013 te - 25 ns 2N3725, 2N4014 - 30 * Pulse Test: Pulse Width = 300 us, Duty Cycle = 1.0%. FIGURE 1 SWITCHING TIMES TEST CIRCUIT +30Vv < > 15 -3.8V > 1.0 PF ( (o TO SAMPLING OSCILLOSCOPE 1.0k e 4 7 | Zin & 100 k22 TL t< 1.0 ns Vin = 19-7 1.0 BF 100 PULSE GENERATOR . t,. tp < 1.0ns 62 PW. ~ 1.0 ps Zin = 80.Q + == D.C. < 2.0% - ~ 8-258