ALPHANUMERIC INDEX CROSS-REFERENCE (Continued) Motorola Motorola Motorola Motorola Industry Direct Similar Page (ndustry Direct Similar Page Part Number Replacement Replacement Number Part Number Replacement Replacement Number 2N6410 MJE200 3-866 2N6531 TIP102 3-1091 2N6411 MJE210 3-866 2N6532 TIP102 3-1091 2N6412 MJE180 3-862 2N6534 2N6301 3-147 2N6413 MJE181 3-862 2N6535 TIPTO2 3-1091 2N6414 MJE170 3-862 2N6536 TIP102 3-1091 2N6415 MJE171 3-862 2N6542 2N6543 3-215 2N6416 MJE243 3-870 2N6543 2N6543 3-215 2N6417 MJE243 3-870 2N6544 2N6545 3-221 2N6418 MJE253 3-870 2N6545 2N6545 3-221 2N6419 MJE253 3-870 2N6546 2N6546 3-225 2N6420 2N6420 3-20 2N6546JAN 2N6546JAN 3-225 2N6421 2N6421 3-20 2N6546JTX 2N6546JTX 3-225 2N6422 2N6422 3-20 2N6547 2N6547 3-225 2N6423 2N6212 3-161 2N6547JAN 2N6547JAN 3-225 2N6424 2N6212 3-161 2N6547JTX 2N6547JTX 3-225 2N6425 2N6212 3-161 2N6548 MJE80C 3-888 2N6436 2N6436 3-203 2N6549 MJE80 3-888 2N6437 2N6437 3-203 2N6551 2N4923 3-79 2N6437JAN 2N6437JAN 3-203 2N6552 2N4923 3-79 2N6437JTX 2N6437JTX 3-203 2N6553 2N4923 3-79 2N6437JTXV 2N6437 JTXV 3-203 2N6554 2N4919 3-75 2N6438 2N6438 3-203 2N6555 2N4919 3-75 2N6438JAN 2N6438JAN 3-203 2N6556 2N4919 3-75 2N6438JTX 2N6438JTX 3-203 2N6557 MJE340 3-876 2NGA3BSTXV ANGA3BIT XV 3-203 2N6558 MJE340 3-876 2N6465 MJE15030 3-972 2N6559 MJE340 3-876 2N6466 MJE15030 3-972 2N6569 2N3055 3-6 2N6467 MJE15037 3-972 2N6573 2N6546 3-225 2N6468 MJE15031 3-972 2N6574 2N6546 3-225 2N6469 2N5879 3-123 2N6575 2N6547 3-225 2N6470 2N5831 3-123 2N6576 2N6576 3-229 2N6471 2N5881 3-123 2N6577 2N6577 3-229 2N6472 2N5882 3-123 2N6578 2N6578 3-229 2N6473 MJE15028 3-972 2N6609 2N6609 3-52 2N6474 MJE15028 3-972 2N6648 2N6648 3-195 2N6475 MJE15029 3-972 2N6648JAN 2N6648JAN 3-195 2N6476 MJE15029 3-972 2N6648JTX 2N6648JTX 3-195 2N6477 MJE15028 3-972 2N6648JTXV 2N6648UTXV 3-195 2N6478 MJE15030 3-972 2N6649 2N6054 3-147 2N6486 2N6486 3-207 2N6649JAN 2N6649JAN 2N6487 2N6487 3-207 2N6649JTX 2N6649JTX _ 2N6488 2N6488 3-207 2N6649JTXV 2NG649JTXV _ 2N6489 2N6489 3-207 2N6650JAN 2N6650JAN _ 2N6490 2N6490 3-207 2N66SQJTX 2N6650JTX _ 2N6491 2N6491 3-207 2N6E650JTXV 2N6650JTXV _ 2N6492 2N6055 3-147 2N6666 2N6667 3-232 2N6493 2N6056 3147 2N666?7 2N6667 3-232 2N6494 2N6056 3-147 2N6668 2N6668 3-232 2N6495 2N5428 3-101 2N6671JAN 2N6671JAN - 2N6496 2N6339 3-188 2N6671JTX 2N6671JTX _ 2N6497 2N6497 3-211 2N6671JTXV 2N6671JTXV _ 2N6498 2N6498 3-211 2N6673JAN 2N6673JAN _ 2N6499 MJE13005 3-944 2N6673JTX 2N6673JTX _ 2N6500 2N5430 3-101 2NEB73ITXV 2NBB73NTXV _ 2N6510 2N6306 3-181 2N6676 MJ16010 3-758 2N6511 2N6306 3-181 2N6677 MJ16010 3-758 2N6512 2N6545 3-221 2N6678 MJ16010 3-758 2N6513 2N6545 3-221 2N6833 2N6833 3-236 2N6514 2N6545 3-221 2N6834 2N6834 3-236 2N6530 TIP101 3-1091 2N6835 MJ16006 3-742 *Consult Motorola if a direct replacement is necessary. 1-8TABLE 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 2-5TABLE 14 SWITCHMODE POWER TRANSISTORS (continued) Resistive Switching VcEO{sus)| IcCont VcEV Device Type ts tt fr | Pp {Case} Volts Amps Volts NPN unless hre @li MS BS @l | MHz Watts Case Min Max Min otherwise noted | Min/Max | Amp | Max | Max | Amp | Min | @ 25C JEDEC/MOT 400 8 850 2N6545*% 7/35 5 4 1 5 6 TO-204/1 800 MJE5742# 200/400 4 8typ | 2 typ 6 TO-220/221A 800 MJE16080 5 min 8 2 0.5 5 80 TO-220/221A 850 BUW12 6 min 6 4 0.8 5 125 TO-218/340 850 BUX84 30 min 01 3.5 1.4 1 4 50 TO-220/221A 700 MJE13007* 6/30 5 3 0.7 5 4 TO-220/221A 650 MJ13080% 8 min 5 1.5 0.5 5 TO-204/1 650 MJE16106 6/25 8 2 typ 10.1 typ 5 100 TO-220/221A 650 MJH16106 6/25 8 2 typ 10.1 typ 5 125 TO-218/340 450 MJ6503-PNP* 15 min 2 2 0.5 4 TO-204/1 450 MJE5852-PNP* | 15 min 2 2 0.5 4 TO-220/221A 6 900 BU326A 30 typ 0.6 3.5 1** 2.5 6 90 TO-204/1 900 BU426A 30 typ 0.6 2typ |O.5typ] 2.5 6 typ 113 TO-218/340D 5 850 2N6543* 7/35 3 4 0.8 3 6 TO-204/1 850 BUW11 6 min 3 4 0.8 3 125 TO-218/340 650 MJ13070* 8 min 3 1.5 0.5 3 TO-204/1 650 MJE13070* 8 min 3 1.5 0.5 3 TO-220/221A 4 700 MJE13005* 6/30 3 3 0.7 3 4 TO-220/221A 15 700 MJE13003* 5/25 1 4 0.7 1 5 TO-225AA/77R 0.5 400 MJ4647-PNP 20 min 0.5 0.72* 0.05 40 TO-205AD/79 375 6 800 BU326 30 typ 0.6 3.5 1** 2.5 6 90 TO-204/1 800 BU426 30 typ 0.6 2typ |O.5typ}| 2.5 6 typ 113 TO-218/340D 350 40 450 MJ10022##%& 50/600 10 2.5 0.9 20 TO-204/197 20 450 MJ10000# * 40/400 10 3 1.8 10 10** TO-204/1 450 MJ10004##* 40/400 10 1.5 0.8 10 10** TO-204/1 15 375 2N6251 6/50 10 3.5 1 10 2.5 TO-204/1 10 450 MJ10002#* 30/300 5 2.5 1 5 10** TO-204/1 450 MJ10006##* 30/300 5 1.5 0.5 5 10** TO-204/1 400 MJ13014% 8/20 5 2 0.5 5 TO-204/1 8 700 2N6308 12/60 3 1.6 0.4 5 5 TO-204/1 700 MJE5741# 200/400 4 8typ | 2typ 6 TO-220/221A 400 MJE5851-PNP 15 min 2 2 05 4 TO-220/221A 2 400 2N6213-PNP 10/100 1 2.5 0.6 1 4 TO-213AA/80 325 30 400 BUV23 8 min 16 1.8 0.4 16 8 250 TO-204/197 15 400 BUX13 8 min 8 2.5 0.8 8 150 TO-204/1 5 350 2N6235 25/125 1 3.5 0.5 1 20 TO-213AA/80 300 15 650 2N6546% 6/30 10 4 0.7 10 |6to 24 TO-204/1 12 600 MJE13008%* 6/30 8 3 0.7 8 4** TO-220/221A 8 600 2N6307 15/75 3 1.6 0.4 3 5 TO-204/1 600 MJE13006* 6/30 5 0.? 5 4 TO-220/221A 600 MJE5740 200/400 4 8 typ | 2 typ 6 TO-220/221A 350 MJE5850-PNP* | 15 min 2 2 0.5 4 TO-220/221A 400 2N6498 10/75 2.5 1.8 0.8 2.5 5 TO-220/221A 600 MJE13004* 6/30 3 3 0.7 3 4 TO-220/221A 2 500 2N3585 25/100 1 4 3 1 10 TO-213AA/80 500 2N6422-PNP 25/100 1 4 3 1 10 TO-213AA/80 350 2N6212-PNP 10/100 1 2.5 0.6 1 4 TO-213AA/80 1.5 600 MJE13002* 5/25 1 4 0.7 1 5 TO-225AA/77R w Designers Data Sheet characterization (continued) # Darlington ## Darlington with speed-up diode * tort ** Ife] @ 1 MHz 2-29MOTOROLA Se 2N6546 = SeMicOuucToR anssas Designe Data Sheet 15 AMPERE NPN SILICON POWER TRANSISTORS SWITCHMODE SERIES 300 and 400 VOLTS NPN SILICON POWER TRANSISTORS 175 WATTS The 2N6546 and 2N6547 transistors are designed for high-voltage, high-speed, power switching in inductive circuits where fall time is critical. They are particularly suited for 115 and 220 volt line op- Designers Data for erated switch-mode applications such as: Worst Case Conditions 5 hing Requl The Designers Data Sheet per- @ Switchi egula Itehing Regulators mits the design of most circuits @ PWM Inverters and Motor Controls entirely from the information pre- @ Solenoid and Relay Drivers sented, Limit data -- representing Deflection Circuits device characteristics boundaries Specification Features are given to facilitate worst case High Temperature Performance Specified for: design. Reversed Biased SOA with Inductive Loads Switching Times with Inductive Loads Saturation Voltages j,-~_+ | Leakage Currents + PB ~ t C SEATING -T- | pLane E el[.b 2PL aK . [41401310008 @ [Tv @[o @ *MAXIMUM RATINGS Fy Rating Symbol} 2N6546 } 2N6547} Unit Collector-Emitter Voltage VCEO(sus} 300 400 Vdc Coilector-Emitter Voltage VCE X (sus) 350 450 Vde Collector-Emitter Voltage VcCEV 650 850 Vde Emitter Base Voltage VeEB 9.0 Vdc Collector Current ~ Continuous le 15 Adc eqs - a Peak (1) tom 30 i$ ]6.0.13 10.005) |r} v9 | Base Current - Cantinuaus ip 10 Adc Peak (1) | 20 NOTES BM 1. DIMENSIONING AND TOLERANCING PER ANSI Emitter Current Continuous le 25 Adc Y14.5M, 1982. Peak (1) em 50 2. CONTROLLING DIMENSION: INCH 3. ALL RULES AND NOTES ASSOCIATED WITH Total Power Dissipation @ To= 25C Pp 175 Watts REFERENCED T0-204AA OUTLINE SHALL APPLY. @ Te = 100C 100 Hitimaetas io . 9, 2, _MILLIMETERS _ INCHES Derate above 25C 1.0 w/c WN MAX | MN | MAX | Operating and Storage Junction T 5,7 stg ~65 to +200 C jos 39.37 1.550 | STYLE 1 Temperature Range ie | 7 : on [ gee \ PIN 1 BASE c_ 4 9.280 | 0,325 THERMAL CHARACTERISTICS | D4 0038 ; 0343 | 2. EMITTER ro 4 t CASE COLLECTOR Characteristic Symbol Max Unit e 140 1177 4 0,055 0970 y | F .. 30.15 85C 1.187 BSC | Thermal Resistance, Junction to Case Rasc 1.0 cw | G [ 10.92 BSC oaso esc | H 1 Maximum Lead Temperature for Soldering Th 275 C ry : 688 a Debs BSL j Purposes: 1/8 from Case for 5 Seconds x. 1118; 12.79 | 0.440 i 0.480 | a [| 384] 419 [ois | 9165 "Indicates JEDEC Registered Data RT 2667 aus a : (1) Pulse Test: Pulse Width = 5.0 ms, Duty Cycle & 10%. ut 483 ; 533 ) 9.190 | 0710 | Vv [38a [7419 | 0151, 0.165 | CASE 1-06 TO-204AA (TO-3} 3-2252N6546, 2N6547 ELECTRICAL CHARACTERISTICS (T- = 25C unless otherwise noted.) L Characteristic | Symbol Min I Max Unit ] OFF CHARACTERISTICS (1) Collector-Emitter Sustaining Voltage VCEO (sus) Vde (le = 100 mA, tg = 0) 2N6546 300 - 2N6547 400 Cottector-Emitter Sustaining Voltage VCE X (sus) Vde (Ig = 8.0 A, Velamp = Rated VEX. Te = 100C) 2N6546 350 - 2N6547 450 ig = 18 A, Velamp = Rated Veeg 100 V, 2N6546 200 - Te = 100C) 2N6547 300 = Collector Cutoff Current 'cEV mAdc (Vcevy = Rated Value, Vee (off) = 1.5 Vdc} - 1.0 (Vcey = Rated Value, Vge (off) = 1.5 Vde, Tc = 100C) - 4.0 Collector Cutoff Current ICER = 5.0 mAdc (VceE = Rated Vcey. Ree = 50 &, Te = 100C) Emitter Cutoff Current JEBO - 1.0 mAdc (Veg = 9.0 Vdc, Ic = 0} SECOND BREAKDOWN Second Breakdown Collector Current with base forward biased Sib 0.2 a Adc t= 1.0 (non-repetitive) (Voge = 100 Vdc} ON CHARACTERISTICS (1} OC Current Gain hee (1 = 5.0 Adc, Vee = 2.0 Vdel 12 60 (IC =10 Adc, Vee = 2.0 Vde) 6.0 30 Collector-Emitter Saturation Voltage VCE {sat] Vde {Ie = 10 Adc, Ig = 2.0 Adc} 15 {Ic = 15 Adc, tg = 3.0 Adc) - 5.0 (Ig = 10 Adc, Ig = 2.0 Ade, Te = 100C) - 2.5 Base-Emitter Saturation Voltage VBE (sat) Vdc (Io = 10 Adc, Ig = 2.0 Ade} - 16 (IC = 10 Adc, Ig = 2.0 Adc, Tc = 100C - 16 DYNAMIC CHARACTERISTICS Current-Gain Bandwidth Product fy 60 28 MHz (1 = 500 mAdc, Veg = 10 Vdc, frest = 1.0 MHz) Output Capacitance Cob 125 500 pF (Vog = 10 Vde, Ie = 0, frest = 1.0 MH2) SWITCHING CHARACTERISTICS Resistive Load 4 _ : Delay Time (Vee = 250 V, Io = 10, lg 0.05 uS Rise Time Ig1 = 1B2=2.0A, ty= 100us, ty _ 1.0 uS Storage Time Duty Cycle < 2.0%} ts _ 4.0 MS Fall Time tt = 0.7 us Inductive Load, Clamped Storage Time (lg = 10 A(pk}, Velamp = Rated Vcex.!g1 = 2.04, ts - 5.0 us Fall Time VBE(off} = 5-0 Vde, To = 100C} tf - 1.5 us Fypical Storage Time (1 = 10 Alp), Velamp = Rated Vcex, 181 22.04, ts 2.0 us Fall Time VBEloff) = 5.0 Vdc, Te = 25C) Y 0.09 us *Indicates JEDEC Registered Data. (1) Puse Test: Pulse Width = 300 us, Duty Cyc e = 2%. 3-2262N6546, 2N6547 TYPICAL ELECTRICAL CHARACTERISTICS FIGURE 1 DC CURRENT GAIN Ty = 180C z < oO e al a oe >? 3 2 a wa -5C = Vce=20V ~VcE=10V 02 03 05 1.0 20 30 5.0 7.0 10 20 Ic, COLLECTOR CURRENT (AMP) FIGURE 3 ON VOLTAGE a e = a 2 ws oO < = a o > = lo: rtd VCE (sat) I/Ig = 5 to Li. 02 03 G5 10 20 30 6.0 70 10 20 Ig, COLLECTOR CURRENT (AMP) FIGURE 5 TURN-ON TIME | Vgc = 250 || Ip/ig = 6.0 Ty = 259C Nees = 300! T - x anal} imepel = : i ; Sale tne be =e 100/-} td VBElott} = 8.0 _ i : i= - 50 pT 30 | it __ . 0.02 0.1 02 0.5 1.0 2.0 5.0 10 20 ic, COLLECTOR CURRENT (AMP) FIGURE 2 COLLECTOR SATURATION REGION N o Ty = 25C > nN eS Ea 5 a Vee, COLLECTOR-EMITTER VOLTAGE (VOLTS) o 0.07 0.1 02 03 05 07 1.0 20 3.0 5.0 7.0 'c, COLLECTOR CURRENT (AMP) FIGURE 4 TEMPERATURE COEFFICIENTS 2.5 ; hee @ Voe = 2.0 V 29+ *APPLIES FOR Iclig = ~EcE =" * 1.0 25C to 150C OVC for VCE (sa1) -559C to 25C to 150C 15 Ove for VBE : to 2506 Nn o 2.5 02 03 05 07 1.0 20 3.0 5.0 7.0 10 20 ic, COLLECTOR CURRENT (AMP) oy, TEMPERATURE COEFFICIENTS {mv /C) FIGURE 6 TURN-OFF TIME te Voc = 250 V . Ic/lg = .0 5.0k 'B1 = IB2 Ty = 2500 3.0k 20k o = 1, TIME (ns) 100 0.02 0.05 01 02 05 1.0 2.0 Ic, COLLECTOR CURRENT (AMP) 3-2272N6546, 2N6547 MAXIMUM RATED SAFE OPERATING AREAS FIGURE 7 FORWARD BIAS SAFE OPERATING AREA 50 ns 20 = 10 = = 5.0 Ee Z 20 & = 10 2 2 05 To , oa) 7 BONGING WIRE LIM ONE meee mm ee THERMAL LIMIT Gg 0 (SINGLE PULSE) 3 _ SECOND BREAKDOWN LIMIT 3 tt = 0.02 O.01_ CURVES APPLY BELOW RATED Vcogg 2N6547 0.005 5.0 7.0 10 20 30 50 70 100 200 300 400 Vce, COLLECTOR-EMITTER VOLTAGE (VOLTS) FIGURE 9 POWER DERATING 100 ye ~ +- i ow 4 _ SECOND BREAKDOW = 80 pen arn 4 2 hen a 2 z THERMAL = 5 80 DERATING 4 9 ! faa tc a 40 a oS & 2 20 0 0 40 80 120 160 200 Te, CASE TEMPERATURE (0C) FIGURE 10 10 0? 05 03 a2 O41 0.07 0.02 SINGLE PULSE t>+-= ++ +} i ! i 1 0.01 00) 0.02 0.06 1 G2 05 1.0 2 rit), TRANSIENT THERMAL RESISTANCE (NORMALIZED) A guy CYCLE, 0 =17 19 oe FIGURE 8 REVERSE BIAS SAFE OPERATING AREA wy TURN OFF LOAD t UN { 1 BOUNDARY FOR bNesa7 _. ~ 4- aoe FOR 2N6546. VcEg ANO = rel-Voex ARE 100 VOLTS LESS ae + = ; 5 f 5 a & & s a Q : : ua i | FE pa. Loy tlt 4} 4 3 Veetott) 84 ' voeaisusit i oy . 6 (sus oo 40 Te 100C Tr sus! a tT | t | YCEX(sus) pp-F : | 1 | t 0 L i i | | | 0 700 200 300 400 500 Vee, COLLECTOR EMITTER VOLTAGE VOLTS) There are two limitations on the powe~ handling ability of a transistor: average junction temperature and second breakdown. Safe operating area curves indicate IC-VCE limits of the transistor that must be observed for reliable operation; i.e., the transistor must not be subjected to greater dissipation than the curves indicate. The data of Figure 7 is based on Tc = 25C; TJ(pk) is variable depending on power level. Second breakdown pulse limits are valid for duty cycles to 10% but must be derated when Tc 2 25C. Second breakdown limitations do not derate the same as thermal limitations. Allowable current at the voltages shown on Figure 7 may be found at any case temperature by using the appropriate curve on Figure 9. TJ(pk) may be calculated from the data in Figure 10. At high case temperatures, thermal limitations will reduce the power that can be handled to values tess than the limitations imposed by second breakdown. THERMAL RESPONSE mt vararener es res a = Zeacity = ft) Rage i Rage = 1.09 CAV Max B 4 0 CURVES APPLY FOR POWER ar PULSE TRAIN SHOWN H | READ TIME AT ty " oe Titpk) > TC > Pipk) ZyJCit) i 800 0 5.0 10 100 200 + TIME isi 20 3-228