ALPHANUMERIC INDEX CROSS-REFERENCE The following table represents an index and cross-reference guide for all low-frequency power transistors which are either manufactured directly by Motorola or for which Motorola manufactures a suitable equivalent. Where the Motorola part num- ber differs from the industry part number, the Moto- rola device is a form, fit and function replacement for the industry type number however, subtle differences in characteristics and/or specifications may exist. Motorola Motorola Motorola Motorola Industry Direct Similar Page Industry Direct Similar Page Part Number Replacement Replacement Number Part Number Repfacement Replacement Number 1SI10A-100 MJ16078 3-782 2N3441 2N3441 3-13 2N1487 2N587? 3-120 2N3442 2N3442 3-15 2N1488 2N5878 3-120 2N3445 2N3447 3-18 2N 1489 2N5877 3-120 2N3446 2N3448 3-18 2N1490, 2N5878 3-120 2N3447 2N3447 3-18 2N1702 2N5877 3-120 2N3448 2N3448 3-18 2N3016 2N5337 3-97 2N3583 2N3583 3-20 2N3021 2N3789 3-56 2N3584 2N3584 3-20 2N3022 2N3789 3-56 2N3585 2N3585 3-20 2N3023 2N3789 3-86 2N3667 2N5881 3-123 2N3024 2N378t 3-56 2N3713 2N5881 3-123 2N3025 2N3791 3-56 2N3714 2N3714 3-26 2N3026 2N3791 3-56 2N3715 2N3715 3-26 2N3054 2N3054 3-2 2N3715JAN 2N3715JAN 3-26 2N3054A 2N3054A 3-2 2N3715JTX 2N3715JTX 3-26 2N3055 2N3055, 3-6 2N3718NTXY 2N37 15JTXY 3-26 2N3055A 2N3055A 39 2N3716 2N3716 3-26 2N3055H 2N3055A 3-9 2N3716JAN 2N3716JAN 3-26 2N3055JAN 2N5302JAN 3-83 2N3716NTX 2N3716JTX 3-26 2N3055SD 2N3055A 39 2N37 16JTXV 2N3716STXV 3-26 2N3055UB 2N30554 39 2N3719 2N3719 3-32 2N3076 2N6249 3-164 2N3720 2N3720 3-32 2N3079 2N6308 3-181 2N3738 2N3738 3-37 2N3080 2N6543 3-215 2N3739 2N3739 3-37 2N3171 2N3789 3-56 2N3739JAN 2N3739JAN 3-37 2N3172 2N3789 3-56 2N3739JTX 2N3739JTX 3-3? 2N3173 2N3790 3-56 2N3739.TXV 2N3739JTXV 3-37 2N3174 MJ15016 3-9 2N3740 2N3740 3-41 2N3183 2N3789 3-56 2N3740A, 2N3740 3-41 2N3184 2N3789 3-56 2N3740JAN 2N3740JAN 3-44 2N3185 2N3790 3-56 2N3740JTX 2N3740JTX 3-43 2N3186 MJ15016 3-9 2N3740JTXV 2N3740JTXV 3-41 2N3195, 2N3789 3-56 2N3741 2N3741 3-41 2N3196 2N3790 3-56 2N3741A 2N3741A 3-41 2N3198 MJ15016 39 2N3741 JAN 2N3741JAN 3-41 2N3202 2N3719 3-32 2N3741JTX 2N3741JTX 341 2N3203 2N3720 3-32 2N3741TXV 2N3741JTXV 3-41 2N3204 2N6303 3-32 2N3766 2N3766 3-44 2N3232 2N5877 3-120 2N3766JAN 2N3766JAN 3-44 2N3233 2N5882 3-123 2N3766JTX 2N3766JTX 3-44 2N3234 2N5760 3-116 2N3766JTXV 2N3766JTXV 3-44 2N3235, 2N3055 36 2N3767 2N3767 3-44 2N3236 2N5882 3-123 2N3767JAN 2N3767JAN 3-44 2N3237 2N5302 3-93 2N3767JTX 2N3767JTX 3-44 2N3238 2N5882 3-123 2N37E7ITXV 2N3767JTXV 3-44 2N3239 2N5882 3-123 2N3771 2N3771 3-48 2N3240 2N5882 3-123 2N3772 2N3772 3-48 2N3419 2N5336 3-97 2N3773, 2N3773 3-52 2N3420 2N5336 3-97 2N3788 2N6543 3-215 2N3421 2N5336 3-97 2N3789 2N3789 3-56 1-2TABLE 3 METAL TO-213 (Formerly TO-66) t= % PIN 1. BASE 1 2. EMITTER CASE. COLLECTOR CASE 80-02 (TO-213AA) Resistive Switching IcCont | VcEO{(sus) . . ts te fr Pp (Case) Amps Volts Device Type hre @ Ic BS BS @Ic MHz Watts Max Min NPN PNP Min/Max Amp Max Max Amp Min @ 25C 1 80 2N4912 20/100 0.5 0.6 typ | 0.3 typ 0.5 3 25 175 2N3583 2N6420 40/200 0.5 2typ | 0.23 typ 0.5 10 35 225 2N3738 40/200 0.1 3 typ 0.3 typ 0.1 10 20 300 2N3739 40/200 0.1 3 typ 0.3 typ 0.1 10 20 2 225 2N6211 10/100 1 2.5 0.6 4 20 35 250 2N3584 2N6421 25/100 1 4 3 1 10 35 300 2N6212 10/100 1 2.5 0.6 1 20 35 2N3585 2N6422 25/100 1 4 3 1 10 35 2N4240 30/150 0.76 6 3 0.75 18 35 350 2N6213 10/100 1 2.5 0.6 1 20 35 3 140 2N3441 25/100 0.5 0.2 25 4 60 2N37'40.- 30/100 0.25 1.3 typ |0.27 typ| 0.25 4 25 2N3054,A 25/100 0.5 1 typ 0.3 typ 0.5 3 75 2N3766. 40/160 0.5 0.9 typ | 0.09 typ 0.5 10 20 2N62944# 2N62964##4 750/18k 2 0.9 typ | 0.7 typ 2 4 50 80 2N37'41 30/100 0.25 1.3 typ |0.27 typ} 0.25 4 25 2N3767 40/160 0.5 0.9 typ | 0.09 typ 0.5 10 20 2N6295## 2N6297## 750/18k 2 0.9 typ | 0.7 typ 2 4 50 5 80 2N4233A 25/100 1.5 0.5 typ | 0.2 typ 1.5 4 75 7 60 2N6317 20/100 2.5 1 0.8 2.5 4 90 80 2N5428 60/240 2 2 0.2 2 30 40 2N6318 20/100 2.5 i 0.8 2.5 4 90 100 2N5429 30/120 2 2 0.2 2 30 40 2N5430 60/240 2 2 0.2 2 30 40 8 60 2N630044 aNeiosny 750/18k 4 1.5 typ | 1.5 typ 4 4# 75 80 2N6201## 2NGZO94# 750/18k 4 1.5 typ | 1.5 typ 4 4# 75 # |hfel @ 1 MHz, ## Darlington [] JAN, JTX, JTXV Available 2-9MOTOROLA 2N3740 PY m SEMICONDUCTOR 2N3741,A POWER TRANSISTORS MEDIUM-POWER PNP TRANSISTORS PNP SILICON 60-80 VOLTS . ideal for use as drivers, switches and medium-power amplifier 25 WATTS applications. These devices feature: Low Saturation Voltage 0.6 VCE (sat) @ Ic = 1.0 Amp High Gain Characteristics he E@ Ic = 250 mA: 30-100 Excellent Safe Area Limits (See Figure 2) Low Collector Cutoff Current 100 nA (Max) 2N3740, 2N3741A. Complementary to NPN 2N3766 (2N3740) and 2N3767 (2N3741) MAXIMUM RATINGS . 2N3741 : Rating Symbol 2N3740 2N3741A Unit Collector-Emitter Voltage VcEO 60 80 Vde Emitter-Base Voltage VEeB 7.0 7.0 Vdc Collector-Base Voltage vce 60 80 Vde Collector Current Continuous 'c 4.0 Adc = Peak (Note 1) 10 Base Current 'g 2.0 Adc Total Device Dissipation @ T = 25C Po 25 Watts Derate above 25C 0.143 w/c Operating and Storage Junction TS. Tstg -65 to +200 9% Temperature Range STYLE 1: s Note 1: See Figure 2 PIN , BASE ER " . 0 FIGURE 7 POWER-TEMPERATURE DERATING CURVE CASE: COLLECTOR e 20 5 NY & = 15 ~ = ~~ 8 oa 10 oN w = So * 5.0 2 0 0 25 50 6 100 125 150 175 200 Tc TEMPERATURE (9C) Alt JEDEC Dimensions and and Notes Apply. Safe Area Curves are indicated by Figure 2. CASE 80-02 Both limits are applicable and must be observed. TO-213AA indicates JEDEC Registered Data. (TO-66) 3-412N3740, 2N3741,A *ELECTRICAL CHARACTERISTICS (Tc = 25C unless otherwise noted) Characteristic [ Symbol [ Min | Max Unit | OFF CHARACTERISTICS Cotlector-E mitter Sustaining Vottage VCEO (sus) @ Vde (Ic = 100 mAdc, Ig = 0) 2N3740, 60 ~ 2N3741, 2N3741A 80 = Emitter Base Cutoff Current lEBo (Veg = 7.0 Vde) 2N3740, 2N3741 - 0.5 mAdc 2N3741A 100 nAdc Collector Cutoff Current IcEXx (Vce = 60 Vdc, Vee (off) = 1.5 Vde) 2N3740 _ 100 uAdc - 100 nAdc (VcE = 80 Vde, Vee (off) = 1.5 Vdel 2N3741 - 100 uAdc 2N3741A 100 nAdc (VcE = 40 Vdc, VBE (off) = 1-5 Vde, Te = 150C) 2N3740 - 1.0 mAdc - 0.5 (VcE = 60 Vdc, Vee (oft) = 1.5 Vde, Te = 150C) 2N3741 = 1.0 mAdc 2N3741A = 0.5 Coltlector-E mitter Cutoff Current IcEO (VcE = 40 Vde, Ig = 0) 2N3740 1.0 mAdc - 1.0 uAdc (Voce = 60 Vdc, tg = 0} 2N3741 - 1.0 mAdc 2N3741A - 1.0 uAdc Collector Base Cutoff Current IcBOo (Vcgp = 60 Vdc, IE = 0) 2N3740 = 100 nAdc _ 100 nAdc (Vcpg = 80 Vdc, ig = 0} 2N3741 - 100 uAdc 2N3741A - 100 nAdc ON CHARACTERISTICS DC Current Gain hee) _ (Ic = 100 mAdc, VcE = 1.0 Vde} 40 - (le = 250 mAdc, Veg = 1.0 Vdc} 30 100 (Ic = 500 mAdc, VcE = 1.0 Vdc) 20 _ (I = 1.0 Adc, Voge = 1.0 Vde) 10 - Collector-E mitter Saturation Voltage Vce (sat}() - 0.6 Vde (Ig = 1.0 Ade, |g = 125 mAdc) Base-Emitter Voltage VBE(1) - 1.0 Vdc (I = 250 mAdc, VcE = 1.0 Vdc) TRANSIENT CHARACTERISTICS Current-GainBandwidth Product fr MHz (Ig = 100 mAdc, Veg = 10 Vde, f = 1.0 MHz} 3.0 ~ 4.ot = Common Base Output Capacitance Cob ~ 100 pF (Vcg = 10 Vdc, Ic = 0, f = 100 kHz} Small-Signal Current Gain hfe 25 - - (I = 50 mMAde, Veg = 10 Vdc, f = 1.0 kHz) Indicates JEDEC Registered Data. Tt Motorola guarantees this value in addition to the JEDEC registered data shown. Pulse Test: Pulse Width S300 us, Duty Cycle <2.0%. FIGURE 2 ACTIVE REGION SAFE OPERATING AREA 10 70 _ 50 = = = 30 = 3 20 = 3 = 10 5 3 07 Ty = 200C B05 SECONDARY BREAKDOWN LIMITATION 2 4, THERMAL LIMITATION " -EMITTER DISSIPATION IS LIMIT FOR: 02 SIGNIFICANT ABOVE Ic = 2,0 AMP)} 2N3740 PULSE DUTY CYCLE =< 10% 2N374L 0.1 1.0 20 30 50 7.0 10 20 30 50. 70 100 Voce, COLLECTOR-EMITTER VOLTAGE (VOLTS) 3-42 The Safe Operating Area Curves indicate Ic - Vcg limits below which the device will not enter secondary breakdown. Collector load lines for specific circuits must fall within the applicable Safe Area to avoid causing a catastrophic failure. To insure operation below the maximum Ty, power-temperature derating must be ob- served for both steady state and pulse power conditions.hee, DC CURRENT GAIN Voce, COLLECTOR-EMITTER VOLTAGE (VOLTS) VOLTAGE (VOLTS) 2N3740, 2N3741,A FIGURE 3 CURRENT GAIN y= +175C 100 Ic, COLLECTOR CURRENT (mA) SATURATION REGION CHARACTERISTICS FIGURE 4 COLLECTOR SATURATION REGION 500mA 1000 A Ip, BASE CURRENT (mA) FIGURE 5 ON VOLTAGES FIGURE 6 TEMPERATURE COEFFICIENTS +10 T T +100C to + 175C Voe{sat) @ Io/la = 10 SE Ave for Vor (sa y BE{ sat) +0.5 Nc CE(sat] +25 C to +100 55C to +25C Vor @ Vee = 2.0V g T tT To compute saturation valtages : L V_. tsar) @ operating Ty = V_ (a4) @ +25C + Bv_ (operating Ty 25C) Gy, TEMPERATURE COEFFICIENTS (m/ C) 0.5f- Use appropriate @y for voltage of interest. | Use appropriate curve for temperature range of interest. | | ~10+-++ t ~ 58C to +175 Ava for Veg | Vee(sat} @ be/lp = 10 15 t 2.0 Q 109. 200-300 400 4500 600 700) 800): 900s: 1000 Ie, COLLECTOR CURRENT (AMP) ic, COLLECTOR CURRENT (mA) 3-43