Numerical Index 2N2968- 2N3064 aie MAXIMUM RATINGS ELECTRICAL CHARACTERISTICS | =| REPLACE. | PAGE Po {E/T | Vee | Yor |= hee @ Ie Vexsan @ le 2/4 |2 TPE JE 7S] Ment | numper| USE 5 el he |B] oT el z)a @ 25C |S} C | (volts) | (volts) | 5 | (min) (max) >| (volts) s 3 3/2 2N2968 S}P BMS 150M 1A | 140 30 10 | 0 i5 100* 0.6 10M 8.0M |T 2N2969 S}P BMS 150M | A | 140 30 to | 0 15 100% 0.6 10M 8.0M | T 2n2970 |S|P BMs | 150M] A | 140 30 20/0} 10 100* | 0.8 LOM 4.0m | T 2N2971 S|P BMS 150M | A | 140 30 20190 10 100%* 0.8 10M 4,0M | T 2N2972 S|N 11-27] DFA | 0.25W |] A | 200 45 45 1|0 60 | 240 10* 0.35 1.0M 60M | T 2N2973 | S}N 11-27] DFA | 0.25W | A | 200 45 45 | 0 | 150 | 600 ioe } 0.35] 1.0M 60M | 'T 2n2974 |S|N 11-27] DFA | 0.25w | A | 200 45 4510] 60 | 240 lox | 0.35] 1.0M 60M | T 2n2975 |S|N 11-27] DFA | 0.25w | A | 200 45 45 | 0 | 150 } 600 Loe | 0.35 | L.0M 60M | T 2N2976 |S|N 11-27] pra | 250M | A | 200 45 4510 | 60 | 240 lox | 0.35 | 1.0M 60M | T 2n2977 | S|N 11-27] DFA | 250m | A | 200 45 45 | 0 [150 | 600 tox | 0.35 | 1.om 60M | T 2n2978 |S|N 11-27{ DFA | 250M ] A | 200 60 60 |o | 60 | 240 toe | 0.35 | 1.0m 60M | T 2N2979 | S}N 11-27] DFA | 0.25W | A | 200 60 60 | 0 } 150 | 600 10% | 0.35} 1.0M 60M | T 2n2980 |S |N{2n2060A] 11-6 | pra] 0.25w fA | 200 | 100 60/0] 25] 75 10* 1.2 50M | 50 /E 60M | T 2N2981 S| N | 2N2223 11-6 DFA { 0.25W | A | 200 100 60 | 0 50 | 200 LOM 1.2 50M 40 ]E 50M }T 2N2982 |S |N|2N2223A] 11-6 | DFA|0.25W]A|200 | 100 60 |0 | 50 | 200 10M 1.2 50M | 40 [E 50M | T 2N2983 | S|N LPA]| 1.0Ww/]A [175] 155 solo]} 20] 60] soom 0.6| 1.0A 2015 60m | T 2N2984 |S|N tPA | 1.0W]A]175 | 185 |] 120}0} 20] 60] 500M 0.8] 200M 20) E 60M } T 2N2985 |S|N upA| 1.0w]A}175] 155] 80/0] 40/120] Soom} 0.8] 200M] 40]/E 60M | T 2N2986 |S|N LPA} 1.0W{A]|175] 185 | 120]0] 40] 120] Soom] 0.8] 200M] 40 ]E 60M | T 2n2987 | S|N LPA} 1.0W] A | 200 95 8o}o] 25] 75} 200M] 0.8] 200M 25/8 30M | T 2N2988 S|N LPA 1.0W | A | 200 155 100 | 0 25 75 200M 0.8 200M 25 /E 30M | T 2N2989 Ss{N LPA L.ow | A | 200 95 80 | 0 60 | 120 200M 0.8 200M 50 |E 30M | T 2n2990 | S|N tPA | 1.0w]A|200} 155 | 100]0 | 60] 120/ 200M 0.8{ 200M] 50]/E 30M | T 2n2991_ |[S|N Lea |_2.0w | a | 200 95 so}o} 25] 75 | 200m} 0.8{ 200M 25 {E 30M | T 2N: S|N LPA 2.0W | A ; 200 155 100 [0 20 1.0M 0.8 200M 25 ,E 30M | T S]N LPA 2.0W | A ; 200 95 80} 0 60 | 120 200M 0.8 200M 50 |E 30M | T SIN LPA 2.0W 1A {200 155 100 | 0 60 | 120 200M 0.8 200M 50 ,E 30M | T S|N HPA L5W ]A | 175 120 100 | 0 25 90 0.24 1.7 0,2A 30] E 10M | T G] P | 2N3283 9-51 RFA 75M | A | 100 15 10 | 0 25 | 500 4.0M 35; E 400M | T G| P | 2N3279 9-49 | RFA 75M | A | 100 30 15 ]0 |] 40] 500] 4.0m 50 ]E | 400M {Tr G| P | 2N3284 9-51 RFA 75M | A | 100 13 1210 15 | 300 3.0M 20 ,E 600M | T G | P | 2n3283 9-51 | RFA 75M | A | 100 15 10 ;o]} 10 3.0M Is JE | 1.46 ]T Thyristors, see Table on Page 1-154 2N3008 2N3009 SIN 8-181] HSS 360M | A | 200 40 15 | 0 30 | 120 30M 0.18 30M 350M | T 2n3010 |S|N 8~183| Hss | 300m [A | 200 is | 6.0 ]o] 25 | 125 lom | 0.25 10M 600M | T 2N3011 |s|N 8-185 | HSS | 360M | A | 200 30 12 {0 | 30 | 120 10M 0.2 10M 400M | T 2N3012 S| P | MM2894 8-328 | MSS 360M A } 200 12 12 +0 30 | 120 30M 0.15 LOM 400M | T 2N3013 S|N 8~187} HSS 360M | A | 200 40 15 | 0 30 | 120 30M 0.18 30M 350M | T 2n3014 |S|N 8~187| HSS | 360M | A | 200 40 20 |o | 30 | 120 30M | 0.18 10M 350M | T 2N3015 Ss ,N 8-187] HSS 800M | A | 200 60 30 | 0 30 | 120 150M 0.4 150M 250M | T 2n3016 | S|N HFA { 3.33W |c]150 | 100 5010] 607150] 1.0A } 0.75] 1.0A 200M | T 2N3017 | stn HFA | 3.33W/c {150 | 100 50 fo | 60} 150} 2.04 | 0.75 | 5.04 200M | T 2N3018 S| N HFA 25W | Cc | 150 100 50 |} 0 60 | 150 LOA 0.75 5.0A 200M | T 2N3019 S|N 8-189] RFA O.8W |) A | 200 140 80 | O | 100 | 300 | 0,15A 0.2 | O.1L5A 80 /E 100M | T 2N3020 S|N 8~189] RFA 0.8W } A ; 200 140 80] 0 40 | 120] 0.154 0.2 {0.154 30 |E 80M | T 2N3021 |S] P 7+99 | PHS 2sw|c | 175 30 30 {o] 20] 60] 1.0a 1.5 | 3.0A 60M | T 2N3022 stp 7-99 PHS 25W 1c 175 45 45 |90 20 60 LOA 1.5 3.04 60M | T 2N3023 $|P 7-99 PHS 25W |} c 4175 60 60 | 0 20 60 1.0A 1.5 3.0A 60M | T 2N3024 |S|P 7-99 | PHS 25w {Cc | 175 30 30/0 | 501180] 1.04 1.0] 3.0A 60M | T 2N3025 |S] P 7-99 | PHS 25w | c | 175 45 45 |o | 504180] 1.0A 1.0 { 3.04 60M | T 2N3026 |S|P 7-99 | PHS 25w | c | 175 60 60 }0 | 50/180] 1.04 1.0] 3.0A 60M | T 2N3027 thru Thyristors, see Table on Page 1-154 2N3032 2N3033 | s|N spp} 300M{A 1/175] 100 | 100]R 1.0] 100M 2N3034 SIN SPP 300M | A {175 70 70 |R 1.0 100M 2N3035 |S|N SPP | 300M | A } 175 50 50 ]R 1.0} 1OOM 2N3036 SUN AFA 800M | A | 200 120 80 [0 50 { 150 150M 0.25 150M 4O1E 50M | T 2n3037 |S |N AFA | 360m |A [175] 120 | 70/0 [| 40 | 120 0.2, tom! 30/e | som] T 2N3038 |S|N AFA} 360M {A }175 | 100 60 ]0 | 80 | 240 0.2 10M 60 | E 50M | T 2n3039 1S] P ara| 360m {fA ]175| 50] 35 ]0] 20] 80 20;E | 50M/T 2n3040 |s | P AFA | 360M | A | 175 40 30 {0 | 40 | 160 0.2 lom | 40 /E 50M | T 2N3043 {S| N 11-29 | pra | 250m | A | 200 45 45 | 0 | 100 | 300 1.0 1oM | 130] E 30M | T 2N3044 |S] N 11-29] DFA} 250M] A | 200 45 45 } 0 | 100 } 300 1.0 1OM | 130) 30M | T 2N3045 | S|N 11-29] AFA | 250M |A {200 45 45 |0 | 100 | 300 1.0 tom | 130] 30m | T 2N3046 [S| N 11-29) DFA | 250M {A | 200 45 45 |o | 50 | 200 1.0 10M 65 | E 30M | T 2n3047 |S] N 11-29] DFA | 250m [A | 200 45 45 10 | 50 | 200 1.0 10M 65 |E 30M | T 2N3048 | S|N 11-29] AFA | 250M] A | 200 45 45 |o | 50 | 200 1.0 LOM 65 [E 30M | T 2N3049 |S} P 11-31] pra | 250M | A | 200 25 20 |o {| 20 | 120 0.2 10M 30 |E 60M | T 2N3050 |S|P 11-31] DFA | 250M | A | 200 25 20 ]}0 } 20} 120 0.2 LOM 30] E 60M | T 2N3051 S| P APA 250M | A | 175 25 20 | 0 20 | 120 0.2 10M B0]E 60M | T 2N3052 S|N RSS 250M 1A [175 35 15 10 25 | 130 10M 0.25 LOM 200M | T 2N3053 {S| N 8-191] HSS | 5.0W | c | 200 60 40 |0 | 50 | 250] 0.15 1.4] 0.154 loom | T 2N3054 |S|N LPA 25w | c | 200 90 60 |R] 25} 100] 0.5 1.0} 0.54 25 |E 30K | E 2N3055 |S] N 7-104) LPA} 115W]c }200} 100 70)R | 20] 70] 4.08 1.1) 4,04 1S) E 20K | E 2N3056 1S|N RFA} 0.4w|A |200 | 100 60 ]}0 | 40 ]120 | 0.154 | 0.25 | 0.154 30] E 80M | T 2N3056A |S |N RFA| 0.4W |A {200 | 140 80 ]o | 40] 120 | 0.15a 0.2 | 0.154 30 |E 80M | T 2N3057 |S|N RFA} 0.4W | A {200 | 100 60 {0 |100 | 300 {0.15a | 0.25 | O.15A 80] | loom | T 2N3057A 1S | N RFA| 0.4W]A]200 | 140 80 | 0 | 100 | 300 | 0.15a 0.2} 0.154 80]E | loom | T 2n3058 |s|P AFA | 400M|A |200{ 6.0 | 6.0 |0[ 401120} 100N 40 /E 2n3059 |s|P AFA | 400M | A | 200 10 10 | 0 | 100 | 300 1o* 100 | E 2n3060 |S|P AFA | 400M | A | 200 70 60/0 | 30] 90] 1.0m 30] E 2N3061 |S} P AFA | 400M | A | 200 70 60|0] 60/180] L.om 60 | E 2n3062 | 8 | P AFA | 400M | A } 200 90 80/01 20] 80] L.om 20 | E 2N3063 S|P AFA 400M | A | 200 90 80 | 0 50 | 150 1.0M 50/,E ang064 |[s|P AFA | 400M fA [200 | 110 | too fo} 15 | 45 | 1.0m is |e 1-135Power Transistors 2N3021 thru 2N3026 (continued) ELECTRICAL CHARACTERISTICS (At 25C unless otherwise specified) Characteristics Symbol Min Max Unit Emitter-Base Cutoff Current lgBO mAdc (Vpr = 4 Vde) 1 Colector-Emitter Cutoff Current Iopx mAde (VCE = 25 Vdc, Vpg ~ 2 Vde) 2N3021, 2N3024 ~~ 0.2 (Vcg = 40 Vde, VpR = 2 Vde) 2N3022, 2N3025 _ 0,2 (Voge = 54 Vdc, Vee = 2 Vdc) 2N3023, 2N3026 _ 0.2 Weg = 15 Vde, Vpr = 2 Vde, Tc = 150C) 2N3021, 2N3024 _ 2 Ver = 25 Vdc, Vpp = 2 Vde, Tc = 150C) 2N3022, 2N3025 _ 2 (VEE = 35 Vdc, Vgp = 2 Vde, Te = 150C) 2N3023, 2N3026 _ 2 Collector- Emitter Breakdown Voltage* BVopos Vdc (Ig = 100 mAdc, Ip = 0) 2N3021, 2N3024 30 ~ (ig = 56 mAde, Ip = 0) 2N3022, 2N3025 45 (Ig = 20 mAdc, Ip = 0) 2N3023, 2N3026 60 _ DC Current Gain hp _ (Ig = 1.0 Ade, Vog = 2 Vdc) 2N3021, 2N3022, 2N3023 20 60 2N3024, 2N3025, 2N3026 50 180 Colector-Emitter Saturation Voltage Vor (sat) Vdc (ig = 3 Adc, Ip = 0.3 Adc) 2N3021, 2N3022, 2N3023 _- 1.5 2N3024, 2N3025, 2N3026 _ 1.0 Base-Emitter Saturation Voltage Ver (sat) Vde {Ig = 3 Adc, Ip = 0.3 Adc) _ 1.5 Small Signal Current Gain hee _ (Ig = 0.5 Adc, Veg = 15 Vde, f = 30 MHz) 2 ~ Switching Times tatty 100 ns (lg = 1 Adc, Ipy = Igg - 100 mAde) ts _ 100 te _ 5 *Perform tests using sweep method to prevent heating. 25 a POWER-TEMPERATURE DERATING CURVE THESE TRANSISTORS ARE ALSO SUBJECT TO SAFE AREA CURVES AS INDICATED BOTH LIMITS ARE APPLICABLE AND MUST BE OBSERVED wn Pp, POWER DISSIPATION (WATTS) 0 25 75 125 5 Te, CASE TEMPERATURE (C) SAFE OPERATING AREAS 2N3021, 2N3024 2N3022, 2N3025 2N3023, 2N3026 Ss as oc Sms 500 ws @ Io = 100 ma ic, COLLECTOR CURRENT (AMP} BYcro @ Ie == 50 mA BVcto @ Ie = 20 mA 0 10 20 30(0 10 20 30 40 50 9 10 20 30 40 50 60 Vee, COLLECTOR EMITTER VOLTAGE (VOLTS) The Safe Operating Area Curves indicate Ic- Vce limits below which the devices will not go into secondary breakdown. As the safe operatin, 2 . areas sho independent of temperature and duty cycle. these curves can be used as long as the average power derating curve js also taken into consideration to fnsure are operation below the maximum junction temperature. 7-100Power Transistors 2N3021 thru 2N3026 (continued) Veerusnys COLLECTOR -EMITTER SATURATION VOLTAGE (VOLTS) Veet: COLLECTOR-EMITTER SATURATION VOLTAGE (VOLTS) Vecteaty, BASE-EMITTER SATURATION VOLTAGE (VOLTS) 1y, BASE CURRENT (mA) BASE-EMITTER SATURATION VOLTAGE VARIATIONS a a 1.2 0.8 06 == = 40C ___ 25C --= 150C 10 20 40 60 80 100 200 400 600 700 1, BASE CURRENT (mA) COLLECTOR-EMITTER SATURATION VOLTAGE VARIATIONS, 2N3021 thru 2N3023 ! l I = _40 25C 1 150 c= O34 1 2 4 6 8 10 20 40 60 80 100 200 400 600 800 1000 ty, BASE CURRENT (mA) SATURATION VOLTAGE VARIA 2N3024 thru 2N3026 14 1.2 \ 19 = = 40C 25C 08 = 150C 06 0.4 0.2 = 0.3 1 2 4 6 8 10 20 40 60 80 100 200 400 600 800 1000 ly BASE CURRENT (ma) BASE CURRENT VOLTAGE VARIATIONS COLLECTOR CURRENT vs BASE-EMITTER VOLTAGE 150C 25C lg, COLLECTOR CURRENT (AMPS) 0.2 0.4 06 08 1.0 12 14 0.2 0.4 0.6 0.8 1.0 12 14 Vee. BASE-EMITTER VOLTAGE (VOLTS) Veg BASE-EMITTER VOLTAGE (VOLTS} 7-101Power Transistors 2N3021 thru 2N3026 (continued) CURRENT GAIN VARIATIONS, 2N3021 thru 2N3023 z & 5 0.1 0.2 0.4 0.6 08 1 2 4 lc, COLLECTOR CURRENT (AMP) CURRENT GAIN VARIATIONS, 2N3024 thru 2N3026 z & 5 O.1 0.2 04 0.6 08 1 2 4 Ic, COLLECTOR CURRENT (AMP) RISE TIME FACTOR ACTIVE REGION TIME CONSTANT RISE TIME (0 90%) t, = 4 6, R Bo = hge AT EDGE OF SATURATION Br = Ic IN SATURATION / 1, (BASE ON CURRENT) R, RISE TIME FACTOR (NORMALIZED t,/+ 46+) T,, ACTIVE REGION TIME CONSTANT (nsec) 0.1 0.4 0.6 08 1 2 3 Bo Be Ic, COLLECTOR CURRENT (AMP) SWITCHING TIME EQUATIONS Using charge control theory and data given with this transistor, switching times for a wide variety of conditions can be readily computed. 7-1022N3021 thru 2N3026 (continued) 10 TYPICAL SWITCHING TIMES Power Transistors fe = 104g, = 10 tn JUNCTION CAPACITANCE VARIATIONS 220 Vec = 30 V Vou == 0 -V 80 Pe z = a eo 2 <x e 60 = = 3 5 40 z 80 0 2 60 0 40 0.2 0.5 1.0 20 30 01 02 0406 1 2 4 6810 20 Ic, COLLECTOR CURRENT (AMP) REVERSE JUNCTION VOLTAGE (VOLTS) 50,000 TOTAL CONTROL CHARGE VARIATION , ic ho 10 Veg = 12 V Veo 950 Cc 30,000 Ts pete rt 20,000 10,000 5000 2N3024 2N3026 3000 Q,, TOTAL CONTROL CHARGE (pico-coulombs} 2000 crepe Ly Total Control Charge. When a transistor is held in a conductive state by a current, Ip:, a charge, Qs, is developed in the active region. A charge, Qs, of opposite polarity, equal in magnitude, can be stored on an external capacitor, C, to neutralize the in- ternal charge and considerably reduce the turn-off time of the transistor. Given Qr from Figure 16A, the external C for mini- mum turn-off in any circuit is: C Qr/V, where V is shown Ot 0.2 0.5 1 2 3 tc, COLLECTOR CURRENT (AMP) TURN-ON TIME TEST CONDITIONS V,, ADJUSTED TO Ig, USING CURRENT PROBE. 12 V t, OF INPUT < 10ns SCOPE < 5 ns In = 100 mA in the circuit above and is I, INPUT PULSE Vin 0 en 5 10% 90% -lhyv INPUT PULSE +9V 10% Vin O 90% -ilv Vin = TURN-OFF TIME TEST CONDITIONS ,, ADJUSTED TO f,, USING 12V CURRENT PROBE. T, < 10 ns PULSE WIDTH >> 10 ys Ia: = 100 mA 120 Vine + OV 4 Ry OUTPUT PULSE ad tg IS MEASURED FROM 10% POINT OF V,, OUTPUT PULSE "TX 30% 10% le 0 tf, t. IS MEASURED FROM 90% POINT OF V,,Power Transistors 2N3021 thru 2N3026 (siticon) Vce = 30-60 V Ic =3A Pp = 25W PNP silicon power transistors for ClassC power amp- CASE 1 lifiers, high-current core switching and high-speed 3) Switching. and amplifier applications. MAXIMUM RATINGS Junction Operating Temperature Range = Synba] SORE | A | REET ver Collector-Base Voltage Vop 30 45 60 Volts Collector-Emitter Voltage Vcr 30 45 60 Volts Emitter-Base Voltage Ves 4 4 4 Volts Collector Current Ic 3 3 3 Amp Base Current Ip 0.5 0.5 0.5 Amp Power Dissipation Pp 25 25 25 Watts ~ -65 to+175 > |] c 7-99