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 1-2ALPHANUMERIC INDEX CROSS-REFERENCE (Continued) Motorola Motorola Motorola Motorola Industry Direct Similar Page Industry Direct Similar Page Part Number Replacement Replacernent Number Part Number Replacement Replacement Number BDT63A BOW41 3-328 BDW51C 2N5882 3-123 BDT63B BDw42 3-328 BDW52 2N3791 3-56 BDT63C BOW43 3-328 BOW52A 2N3792 3-56 BOT64 BDW44 3-328 BDW52B 2N3792 3-56 BDT64A BDW45 3-328 BDW52C 2N5880 3-123 BOT64B BDW46 3-328 BDW53 TIP120 3-1098 BDT64C BDW47 3-328 BDW53A TIP120 3-1098 BDT65 BOW40 3-328 BDW53B TIP121 3-1098 BDT65A Bow41 3-328 BDW53C BOX53C 3-338 BDT65B BDW42 3-328 BDWS53D BDX53D 3-338 BDT6SC BDW43 3-328 BDW54 TIP125 3-1098 BDT91 BD807 3-316 BDW54A TIP125 3-1098 BDT92 BD808 3-318 BOW54B TIP126 3-1098 BDT93 BD809 3-316 BDWS54C BDX54C 3-338 BDT94 BD810 3-318 BDW54D BDX54D 3-338 BDV64 BDV64 3-324 BDW55 BD135 3-268 BOVE4A BOVEdA 3-324 BDW56 BD136 3-260 BDV64B BDV64B 3-324 BDW57 BD137 3-258 BDV64C BDV64B 3-324 BDW58 BD138 3-260 BOV65 BDV65 3-324 BDW59 BD139 3-258 BOVE5A BDVE5A 3-324 BDW60 BD140 3-260 BDV65B BDV65B 3-324 BOW63 BDX53 3-338 BOV65C BOV65B 3-324 BDW63A BDX53A 3-338 BDV66C MJH11018 3-1034 BDW63B BDX53B 3-338 BDVE66C MJH11017 3-1034 BDW63C BDX53C 3-338 BDV6ED MJH11019 3-1034 BDW63D BDX53D 3-338 BDV67D MJH11020 3-1034 BDWw4 BDX54 3-338 BOV91 MJE3055T 3-904 BDW64A BDX54A 3-338 BDV92 TIP34B 3-1077 BDW64B BDX54B 3-338 BDV93 TIP34C 3-1077 BOW64C BOX54C 3-338 BDV94 TIP2955 3-1108 BDW73 BD895 3-320 BDV95 TIP33B 31077 BOW73A 8D897 3-320 BOV9E TIP33C 3-1077 BDW73B BD899 3-320 BDW21 2N3714 3-26 BDW73C BD901 3-320 BOW21A 2N3714 3-26 BDW73D BDX33D 3-334 BOW21B 2N3714 3-26 BOW?74 BD896 3.322 BDW21C 2N5882 3-123 BDW74A BD898 3-322 BDW22 2N3789 3-56 BDW74B BD900 3-322 BDW22A 2N3789 3-56 BDW74C BD902 3-322 BDW22B 2N3790 3-56 BDW74D BDX34D 3-334 BDW22C 2N5880 3-123 BDW83 BDV65 3-324 BDW23 BDX53 3-338 BDW83A BOVES 3-324 BDW23A BDX53A 3-338 BOW83B BDVE5A 3-324 BOW23B BDX53B 3-338 BDW83C BDV65B 3-324 BOW23C BDX53C 3-338 BDW84 BDVE4 3-324 BDW24 BDX54 3-338 BDW84A BDV64 3-324 BDW24A BDX54A 3-338 Bows4B BDV64A 3-324 BDW24B BDX54B 3-338 BDW84C BDV64B 3-324 BDW24C BDX54C 3-338 BDW93 BOW39 3-328 BDW39 BDW39 3-328 BDW93A BDW40 3-328 Bow40 BOWw40 3-328 BOWS3B BDW4} 3-328 BDW41 Bbwa41 3-328 BOW93C B8DW42 3-328 BDW42 BDW42 3-328 BDW94 BDW44 3-328 BDW44 BOW44 3-328 BDW94A BDW45 3-328 BDw4s BDW45 3-328 BDW94B BDW46 3-328 BDW46 BDW46 3-328 BDW94C BDw4?7 3-328 Bpw47 BOW47 3-328 BDX10 2N3055A 3-9 BOWS} 2N3715 3-26 BDX10-4 2N3055A 39 BDW51A 2N3715 3-26 BDX10-6 2N3055A 3-9 BDW51B 2N3716 3-26 BDX10-7 2N3055A 3-9 *Consult Motorola if a direct replacement is necessary. 1-25TABLE 1 METAL TO-204, TQ-204AE (continued) Resistive Switching icCont | VCEO{(sus) . ts tt fr Pp (Case) Amps Volts Device Type hrE @ic | as us | @ig | MHz | Watts Max Min NPN PNP Min/Max Amp Max Max Amp Min @ 25C 10 250 MJ15011 MJ15012 20/100 2 200 300 MJ30414## 250 min 2.5 175 325 MJ413 20/80 0.5 2.5 125 MJ423 30/90 1 2.5 125 MJ431 15/35 2.5 25 125 350 BU3234# 150 min 6 7.5 typ | 5.2 typ 6 175 MJ3042#4 250 min 2.5 175 MJ13014 8/20 5 2 0.5 5 150 MJ100024# 3/300 5 2.5 1 5 10# 150 MJ100064#4 30/300 5 1.5 0.5 5 10# 150 400 BU323A4# 450 min 6 7.5typ | 5.2 typ 6 175 MJ100074## 30/300 5 1.5 0.5 5 10# 150 MJ1001244 100/2k 6 15 15 6 175 MJ13015 8/20 5 2 0.5 5 150 600 MJ100144# 10/250 10 2.5 0.8 10 175 700 MJ8504 7.5 min 1.5 4 2 5 175 800 MJ8505 7.5 min 1.5 4 2 5 176 MJ16018 4min 5 4.5 typ | 0.2 typ 5 160 950* MJ12010 4.2 min 5 1 5 100 12 60 2N6057## 2N6050## 750/18k 6 1.6 typ | 1.5 typ 6 4# 150 80 2NEO5B4# | 2NGOSI## =| 750/18k 6 1.6 typ | 1.5 typ 6 4# 150 100 2N60594## 2N6052## 750/18k 6 1.6 typ | 1.5 typ 6 4# 150 15 60 2N3055 MJ2955 20/70 4 0.7 typ | 0.3 typ 4 2.5 115 2N3055A MJ2955A 20/70 4 0.8 115 2N6576## 2k/20k 4 2 7 10 10-2004 120 2N5881 2N5879 20/100 6 1 0.8 6 4 160 80 2N5882 2N5880 20/100 6 1 0.8 6 4 160 30 2N6577## 2k/20k 4 2 7 10 10-2004 120 120 MJ15015 MJ15016 20/70 4 1 180 2N6578## 2k/20k 4 2 7 10 10-200# 120 140 MJ15001 MJ15002 25/150 4 2 200 150 MJ110184##4 MAI11017#4 100 min 15 3# 178 200 BUX41 8 min 8 1.5 0.4 8 8 120 2N6249 10/50 10 3.5 1 10 2.5 175 MJ11020#4# MJ110194# 100 min 15 34 175 250 MJ11022## MJ110214# 100 min 15 a4 175. 275 2N6250 8/50 10 3.5 1 10 2.5 175 300 2N6546 6/30 10 4 0.7 10 6 to 24 175 325 BUX13 8 min 8 2.5 0.8 8 8 150 400 BUX48 8 min 10 2 0.4 10 175 2N6547 6/30 10 4 0.7 10 6 to 24 175 MJ13090 8 min 10 2.5 0.5 10 175 MJ16110 6/20 16 0.8 typ | 0.1 typ 10 175 450 BUX48A 8 min 8 2 0.4 10 178 MJ16010 5 min 15 1.2 typ | 0.2 typ 10 178 * ViBR)CEX. # Ihfel @ 1 MHz, ## Darlington (continued) | JAN, JTX, JTXV Available 2-5Vee. COLLECTOR-EMITTER VOLTAGE (VOLTS) hee. DC CURRENT GAIN V, VOLTAGE (VOLTS) 2N3055 NPN/MJ2955 PNP NPN 2N3055 PNP MJ2955 FIGURE 3 DC CURRENT GAIN =4.0V 0.1 02 03 a5 67 4 20 Ip, COLLECTOR CURRENT {AMP} 206 100 50 30 hee, DC CURRENT GAIN 20 o4 02 03 05 0.7 10 20 630 50 7.0 10 Ic, COLLECTOR CURRENT (AMP) FIGURE 4 COLLECTOR SATURATION REGION 20 08 0.4 50 10 $0 100 Ig. BASE CURRENT (mA) VBE @VcE=4.0V = 10 0.4 0.2 03 a5 07 10 20 34 Ic, COLLECTOR CURRENT (AMPERES) Ty = 259 2.0 Ty = 25C 0.8 a4 Vce, COLLECTOR-EMITTER VOLTAGE (VOLTS) 100 50 610 20 50 200 500 1000 2000 5000 Ip, BASE CURRENT (mA) FIGURE 5 ON VOLTAGES 5.0 7.0 10 20 Ty = 25C pot bad @vce+40Vv 0.8 V, VOLTAGE (VOLTS) 04 VcE(sat) @ ic/lg = 10 03 0.5 10 2.0 3.0 0.1 02 Ic, COLLECTOR CURRENT (AMP)MOTORO = SEMICONDUCTOR a TECHNICAL DATA NPN PNP 2N3055A MJ2955A MJ15015 MJ15016 fT = 0.8 MHz (Min) NPN = 2.2 MHz (Min} PNP 120 V, Respectively @ Safe Operating Area Rated to 60 V and COMPLEMENTARY SILICON HIGH-POWER TRANSISTORS @ Current-Gain Bandwidth-Product @ Ic = 1.0 Adc . PowerBase complementary transistors designed for high power audio, stepping motor and other linear applications. These devices can also be used in power switching circuits such as relay or solenoid drivers, de-to-de converters, inverters, or for inductive loads requiring higher safe operating area than the 2N3055 and MJ2955. 15 AMPERE COMPLEMENTARY SILICON POWER TRANSISTORS 60, 120 VOLTS 115, 180 WATTS *MAXIMUM RATINGS 2N3055A | MJ15015 Rating Symbol | MJ2955A | MJ15016 Unit Collector-Emitter Voltage VCEO 60 120 Vde Collector-Base Voltage VcBo 100 200 Vde Collector-Emitter Voltage Base VCEV 100 200 Vdc _ Reversed Biased fo 4 Emitter-Base Voltage VEBO 7.0 Vde { ~~ c Coliector Current Continuous le _ 15 Adc f T- we Base Current lp 7.0 Adc E Total Device Dissipation @ Tc = 25C Pp 115 180 Watts +||-p 2m K Derate above 25C 0.65 1.03 w/c $0.13 (0.005) Operating and Storage Junction Ty. Tstg -65 to +200 c Temperature Range TT THERMAL CHARACTERISTICS G R Characteristic Symbol Max Max Unit T Thermal Resistance, Junction to Case 8c. 1.52 0.98 c/w F {-0-] STYLE Indicates JEDEC Registered Data (2N3055A) +]eorsin0 Gr] v@] PNY BE 2. EMITTER Notes. CASE COLLECTOR FIGURE 1 ~ POWER DERATING 1, DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 200 2. CONTROLLING DIMENSION: INCH. = 3. ALL RULES AND NOTES ASSOCIATED WITH z REFERENCED TO-2044A OUTIINE SHALL APPLY, oe & a 150 8 INQ a MJ15015 S M1506 = 100 3 < he a = 2N3055A < 80 MJ2955A > = a L s~ 75 0 0 26 50 100 125 15 175 200 CASE 1-05 a Tc, CASE TEMPERATURE (C) TO-204AA (TO-3) 3-9NPN 2N3055A, MJ15015 PNP MJ2955A, MJ15016 ELECTRICAL CHARACTERISTICS (1 = 25C unless otherwise noted). Characteristic [ Symbol f Min [ Max [ Unit | OFF CHARACTERISTICS (1) *Collector-Emitter Sustaining Voltage 2N3055A, MJ2955A VCEO (sus) 60 - Vde (I = 200 mAdc, Ip = 0) MJ15015, MJ15016 120 - Collector Cutoff Current IcEO mAdc (VcE = 30 Vde, Vge(oft) = 0 Vde) 2N3055A, MJ2955A, _ 0.7 (VcE = 60 Vdc, VBE (off) = 0 Vdc) MJ15015, MJ15016 = G.t *Collector Cutoff Current 2N3055A, MJ2955A, IcEv _ 5.0 mAdc (VCEV = Rated Value, Vge (off) = 1.5 Vde) MJ15015, MJ15016 - 1.0 Collector Cutoff Current 2N3055A, MJ2955A IcEV = 30 mAdc iVcEv = Rated Value, VBE{off) = 1.5 Vde, MJ15015, MJ15016 - 6.0 Tc = 150C) *Emitter Cutoff Current 2N3055A, MJ2955A lego - 5.0 mAdc (Vep = 7.0 Vdc, Ic = 0) MJ15015, MJ15016 - 0.2 *SECOND BREAKDOWN Second Breakdown Collector Current with Base Forward Biased Is/b Adc (t = 0.5 s non-repetitive) 2N3055A, MJ2955A 1.95 _ (VceE = 60 Vdc) MJ15015, MJ15016 3.0 = *ON CHARACTERISTICS (1) DC Current Gain hee _ (ig = 4.0 Adc, Veg = 2.0 Vde) 10 70 {Ic = 4.0 Adc, Vcg = 4.0 Vdc) 20 70 (Ig = 10 Ade, Veg = 4.0 Ve) 5.0 - Collector-Emitter Saturation Voltage VcE(sat} Vde (cg = 4.0 Ade, Ig = 400 mAdc) - 14 (Ig = 10 Ade, Ig = 3.3 Adc} - 3.0 (Ic = 15 Adc, Ip = 7.0 Adc) - 5.0 Base-Emitter On Voltage VBE lon) 0.7 18 Vde (Ig = 4.0 Ade, Voge = 4.0 Vde) *DYNAMIC CHARACTERISTICS Current-GainBandwidth Product 2N3055A, MJ15015 fr 08 6.0 MHz (Ig = 1.0 Adc, Veg = 4.0 Vac, f = 1.0 MHz) MJ2955A, MJ15016 2.2 18 Output Capacitance Cob 60 600 pF (Vcp = 10 Vac, tg = 0, f = 1.0 MH2) *SWITCHING CHARACTERISTICS (2N3055A only} RESISTIVE LOAD Delay Time tg - 05 us Rise Time (Voc = 30 Vde, Ic = 4.0 Adc, tr _ 40 Kus 7 tpi = Ip2 = 0.4 Adc, Storage Time tp = 25 us Duty Cycle < 2%) ts -_ 3.0 BS Falt Time tf _ 6.0 us (1) Pulse Test: Pulse Width = 300 us, Duty Cycle < 2%. *Indicates JEDEC Registered Data (2N3055A) 3-10hee, OC CURRENT GAIN V, VOLTAGE (VOLTS) FIGURE 2 DC CURRENT GAIN 0.2 0.3 0.5 07 1 2 T. y= 150C 3 NPN 2N3055A, MJ15015 PNP MJ2955A, MJ15016 5 Ip, COLLECTOR CURRENT (AMP) FIGURE 4 ON VOLTAGES 1 | YBe%sat) @ 0.57- VeE(sat) @ e/g = 0 02 03 07 BE(on) Vee =4V 1 2 3 7 Ic, COLLECTOR CURRENT (AMP} 7 10 FIGURE 6 SWITCHING TIMES TEST CIRCUIT (Circuit shown is for NPN) -11V tr, te < 10 ns Buty Cycle = 1.0% 302 Voc +30V IN6GO73 -~5V 10 15 20 Scope fy, CURRENT-GAIN-BANDWIDTH PRODUCT (MHz) Vee. COLLECTOR-EMITTER VOLTAGE (VOLTS) t, TIME {us} FIGURE 3 COLLECTOR SATURATION REGION Hi & nN > NR a he Ss = S = 0 0.005 0.0' 0.02 0.05 860.1 0.2 05 1 2 5 1g. BASE CURRENT (AMP) FIGURE 5 CURRENT-GAIN-BANDWIDTH PRODUCT 10 s Mi15016 N > MJ15015 > = 0.2 a3 0.5 1.0 2.0 Ip, COLLECTOR CURRENT (AMPS) FIGURE 7 TURN-ON TIME td 02 03 0.6 1 3 5 Ic, COLLECTOR CURRENT (AIMP)t, TIME {us} 40,000 tc, COLLECTOR CURRENT {uA} Je, COLLECTOR CURRENT (AMPS) NPN 2N3055A, MJ15015 PNP MJ2955A, MJ15016 FIGURE 8 TURN-OFF TIMES owe ws 01 0.7 0.5 0.3 0.2 Ot 0.5 1 2 Ig. COLLECTOR CURRENT (AMPS} 5 7 10 NPN FIGURE 10 2N3055A, MJ15015 =30V 1000 100 REVERSE 0.1 0.01 40.2 +0.1 0 -0.1 -0.2 -0.3 -04 ~05 VBE. BASE-EMITTER VOLTAGE (VOLTS) FIGURE 12 FORWARD BIAS SAFE OPERATING AREA 2N3055A, MJ2955A 20 27 ee = ee Bonding Wire Limit <= = Thermal Limit Tc = 25C (Single Pulse) Second Breakdown Limit 10 20 60 100 Vog. COLLECTOR-EMITTER VOLTAGE (VOLTS) There are two limitations on the power handling ability of a transistor: average junction temperature and second breakdown. Safe Operating area curves indicate {-VcE limits of the transistor that must be observed for reliable operation; i.., the transistor must not be subjected to greater C, CAPACITANCE {pF} COLLECTOR CUT-OFF REGION FIGURE 9 CAPACITANCES MJ1SO16 10 2.0 5.0 10 20 50 100-200 500 Vr. REVERSE VOLTAGE (VOLTS) 1000 PNP FIGURE 11 MJ2955A, M.115016 1000 Vce=30V - & int Ty= 150C a at r > 2 = 10 e a 3 = 01 = 0. 8 Ss o 0.001 -0.2 ~0.1 0 40.1 0.2 = 40.3 +0.4 +0.5 VBE. BASE-EMITTER VOLTAGE (VOLTS} FIGURE 13 - FORWARD BIAS SAFE OPERATING AREA MJ15015, MJ15016 20 a = =z & 50 =z in rs x 2 3S o S wy a Qo > 05 <a + <= Bonding Wire Limit ~ = Thermal Limit @ To = 25C (Single x Second Breakdown Limit 0.2 15 20 30 60 100 126 Vee, COLLECTOR-EMITTER VOLTAGE (VGLTS) dissipation than the curves indicate. The data of Figures 12 and 13 is based on Tc = 25C: TJipk) is variable depending on power level. Second breakdown pulse {limits are valid for duty cycles to 10% but must be derated for temperature according to Figure 1.Audio GENERAL DESIGN CURVES FOR POWER AUDIO OUTPUT STAGES Viariceo Required on Output and Driver Transistors Output Transistor Peak Collector Current versus versus Output Power for 4, 8 and 18 Ohm Load Output Power tor 4, 8 and 16 Ohm Loads 500 300 100 70 50 30 Vipriceo (Volts) Peak Output Current (Amps) 10 30 50 100 300 500 1000 10 30 50 100 300 500 1000 Output Power (Watts) Output Power (Watts) Another important parameter that must be considered before selecting the output transistors is the safe- operating area these devices must withstand. For a complete discussion on these see Application Notes AN484A and AN485. TABLE 1 RECOMMENDED POWER TRANSISTORS FOR AUDIO/SERVO LOADS 4 RMS Pp fr Power Watts hFe@ le MHz ISB Output NPN PNP Case | @ 25C |) VcEo | Min/Max | Amps Typ Volts/Amps To 25W MJE15030 MJE15031 TO-220 | 50W 150 V 20 min 4A 70 14/3.6 25 to BOW 2N3055A MJ2955A TO-204 | 120W 120 V 20/70 4A 3 60/2 MJ15001 MJ15002 TO-204 | 200W 140 V 25/150 4A 3 40/5 50 to 100W MJ15015 MJ15016 TO-204 | 180W 120 V 20/70 4A 3 60/3 MJ15003 MJ15004 TO-204 | 250W 140 V 25/150 5A 3 100/14 MJ15018 MJ15019 TO-204 | 150W 200 30 min 1A 20 50/3 MJ 15020 MJ15020 TO-204 | 150W 250 30 min 1A 20 50/3 Over 100W MJ15024 MJ15025 TO-204 | 250W 250 V 15/60 8A 8 80/2.2 The Power Transistors shown are provided for reference only and show device capability. The final choice of the Power Transistors used is left to the circuit designer and depends upon the particular safe-operating area required and the mounting and heat sinking configuration used. 5-3