IGP50N60TXKSA1

IGBT, 50 A, 2 V, 333 W, 600 V, TO-220, 3 Pins

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Manufacturer: INFINEON
Product type: Single IGBTs
DC Collector Current:50A; Collector Emitter Saturation Voltage Vce(on):2V; Power Dissipation Pd:333W; Collector Emitter Voltage V(br)ceo:600V; Transistor Case St; Available until stocks are exhausted
MSL: -
SVHC: No SVHC (25-Jun-2025)
No. of Pins: 3Pins
Product Range: -
Power Dissipation: 333W
Transistor Mounting: Through Hole
Transistor Case Style: TO-220
Operating Temperature Max: 175°C
Continuous Collector Current: 50A
Collector Emitter Voltage Max: 600V
Collector Emitter Saturation Voltage: 2V

Delivery and price
Units per pack	500
Price	1.16 €
Current stock	500+
Lead time	30 days

Datasheet

IGP50N60T 

TRENCHSTOP™ Series 

## Cinfineon 

## Low Loss IGBT : IGBT in TRENCHSTOP™ and Fieldstop technology 

@ ww GS Gee 

## **Features:** 

- Very low _V_ CE(sat) 1.5V (typ.) 

- Maximum Junction Temperature 175°C 

- Short circuit withstand time 5s 

- Designed for : 

   - Frequency Converters 

   - Uninterrupted Power Supply 

- TRENCHSTOP™ and Fieldstop technology for 600V applications offers : 

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C<br>G<br>E<br>PG-TO220-3<br>**----- End of picture text -----**<br>


   - very tight parameter distribution 

   - high ruggedness, temperature stable behavior 

   - very high switching speed 

   - low _V_ CE(sat) 

- Positive temperature coefficient in _V_ CE(sat) 

- Low EMI 

- Low Gate Charge 

- Qualified according to JEDEC[1] for target applications 

- Pb-free lead plating; RoHS compliant 

- Complete product spectrum and PSpice Models : http://www.infineon.com/igbt/ 

|**Type**|**_V_CE**|**_I_C**|**_V_CE(sat****_),Tj=25°C_**|**_T_j,max**|**Marking**|**Package**|
|---|---|---|---|---|---|---|
|IGP50N60T|600 V|50 A|1.5 V|175C|G50T60|PG-TO220-3|



|**Maximum Ratings **||||
|---|---|---|---|
|**Parameter**|**Symbol**<br>~~a~~|**Value**<br>~~a~~|**Unit**<br>~~a~~|
|Collector-emitter voltage,_T_j≥ 25C|_V_C E|600|V|
|DC collector current, limited by_T_jmax<br>_T_C= 25C, value limited by bondwire<br>_T_C= 100C|_I_C<br>~~fo~~<br>~~ee~~|90<br>64<br>~~fo~~<br>~~ee~~|A<br>~~fo~~<br>~~ee~~<br>~~PF~~|
|Pulsed collector current,_t_plimited by _T_jmax|_I_Cpul s<br>~~ee~~|150<br>~~ee~~||
|Turn off safe operatingarea,_V_CE= 600V,_T_j= 175C,_t_p= 1µs|_-_<br>~~ee~~<br>~~PF~~|150<br>~~ee~~<br>~~PF~~||
|Gate-emitter voltage|_V_G E<br>~~PF~~<br>~~eee~~|20<br>~~PF~~<br>~~eee~~|V<br>~~PF~~<br>~~eee~~|
|Short circuit withstand time2) <br>_V_GE= 15V,_V_CC400V,_T_j 150C|_t_SC<br>~~eee~~<br>~~Ff~~|5<br>~~eee~~<br>~~Ff~~|s<br>~~eee~~<br>~~Ff~~|
|Power dissipation_T_C= 25C|_P_t ot<br>~~PF~~<br>~~ee~~|333<br>~~PF~~<br>~~eee~~|W<br>~~PF~~<br>~~eee~~|
|Operating junction temperature|_T_ j <br>~~ee~~<br>~~ee ee~~|-40...+175<br>~~eee~~<br>~~ee~~|C<br>~~eee~~<br>~~ee~~<br>~~ee~~|
|Storage temperature|_T_stg<br>~~ee ~~<br>~~ee ee~~<br>~~ee ee~~|-55...+150<br> ~~eee~~<br>~~ee~~<br>~~ee~~||
|Solderingtemperature, 1.6mm(0.063 in.)from case for 10s|-<br>~~ee ee~~<br>~~ee ee~~|260<br>~~ee~~<br>~~ee~~||



- 1 J-STD-020 and JESD-022 

- 2) Allowed number of short circuits: <1000; time between short circuits: >1s. 

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## IGP50N60T 

## **Thermal Resistance** 

|**Thermal Resistance**|||||
|---|---|---|---|---|
|**Parameter**|**Symbol**|**Conditions**|**Max. Value**|**Unit**|
|**Characteristic**|||||
|IGBT thermal resistance,<br>junction – case|_R_t hJC||0.45|K/W|
|Thermal resistance,<br>junction – ambient|_R_t hJA||62||



## **Electrical Characteristic,** at _T_ j = 25 C, unless otherwise specified 

|**Electrical Characteristic,**at_T_j= 25|C, unless ot|herwise specified|||||
|---|---|---|---|---|---|---|
|**Parameter**|**Symbol**|**Conditions**||**Value**||**Unit**|
||||**min.**|**Typ. **|**max.**||
|**Static Characteristic**|||||||
|Collector-emitter breakdown voltage|_V_( BR )C ES|_V_G E=0V,_I_C=0.2mA|600|-|-|V|
|Collector-emitter saturation voltage|_V_C E( sat )|_V_G E= 15V,_I_C=50A<br>_T_j=25C<br>_T_j=175C|-<br>-|1.5<br>1.9|2.0<br>-||
|Gate-emitter threshold voltage|_V_G E( t h)|_I_C=0.8mA,_V_C E=_V_G E|4.1|4.9|5.7||
|Zero gate voltage collector current|_I_CE S|_V_C E=600V,<br>_V_G E=0V<br>_T_j=25C<br>_T_j=175C|-<br>-|-<br>-|40<br>3500|µA|
|Gate-emitter leakage current|_I_GE S|_V_C E=0V,_V_G E=20V|-|-|100|nA|
|Transconductance|_g_fs|_V_C E=20V,_I_C=50A|-|31|-|S|
|Integratedgate resistor|_RG int_|||-||Ω|
|**Dynamic Characteristic**|||||||
|Input capacitance|_C_i ss|_V_C E=25V,<br>_V_G E=0V,<br>_f_=1MHz|-|3140|-|pF|
|Output capacitance|_C_os s||-|200|-||
|Reverse transfer capacitance|_C_rs s||-|93|-||
|Gate charge|_Q_Gat e|_V_C C=480V,_I_C=50A<br>_V_G E=15V|-|310|-|nC|
|Internal emitter inductance<br>measured 5mm(0.197 in.)from case|_L_E|PG-TO-220-3-1<br>PG-TO-247-3-21|-<br>-|7<br>13|-<br>-|nH|
|Short circuit collector current1)|_I_C( SC )|_V_G E=15V,_t_SC5s<br>_V_C C= 400V,<br>_T_j 150C|-|458.3|-|A|



> 1) Allowed number of short circuits: <1000; time between short circuits: >1s. 

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## IGP50N60T 

## **Switching Characteristic, Inductive Load,** at _T_ j=25 C 

|**Parameter**|**Symbol**|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**Typ. **|**max.**||
|**IGBT Characteristic**|||||||
|Turn-on delaytime|_t_d( o n)|_T_j=25C,<br>_V_C C=400V,_I_C=50A,<br>_V_G E=0/15V,_r_G=7,<br>_L_=103nH,_C_=39pF<br>_L_,_C_from Fig. E<br>Energy losses include<br>“tail” and diode reverse<br>recovery.<br>Diode from IKW50N60T|-|26|-|ns|
|Rise time|_t_r||-|29|-||
|Turn-off delaytime|_t_d( of f)||-|299|-||
|Fall time|_t_f||-|29|-||
|Turn-on energy|_E_o n||-|1.2|-|mJ|
|Turn-off energy|_E_o ff||-|1.4|-||
|Total switchingenergy|_E_t s||-|2.6|-||



## **Switching Characteristic, Inductive Load,** at _T_ j=150 C 

|**Parameter**|**Symbol**|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**Typ.**|**max.**||
|**IGBT Characteristic**|||||||
|Turn-on delaytime|_t_d( o n)|_T_j=175C,<br>_V_C C=400V,_I_C=50A,<br>_V_G E=0/15V,_r_G=7,<br>_L_=103nH,_C_=39pF<br>_L_,_C_from Fig. E<br>Energy losses include<br>“tail” and diode reverse<br>recovery.<br>Diode from IKW50N60T|-|27|-|ns|
|Rise time|_t_r||-|33|-||
|Turn-off delaytime|_t_d( of f)||-|341|-||
|Fall time|_t_f||-|55|-||
|Turn-on energy|_E_o n||-|1.8|-|mJ|
|Turn-off energy|_E_o ff||-|1.8|-||
|Total switchingenergy|_E_t s||-|3.6|-||



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140A<br>120A<br>100A<br>T C=80°C<br>80A<br>T C=110°C<br>60A<br>40A Ic<br>20A Ic<br>0A<br>100Hz 1kHz 10kHz 100kHz<br>COLLECTOR CURRENT<br>,<br>I C<br>**----- End of picture text -----**<br>


_f_ , SWITCHING FREQUENCY 

**Figure 1. Collector current as a function of switching frequency** ( _T_ j  175C, _D =_ 0.5, _V_ CE = 400V, _V_ GE = 0/15V, _r_ G = 7) 

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300W<br>250W<br>200W<br>150W<br>100W<br>50W<br>0W<br>25°C 50°C 75°C 100°C 125°C 150°C<br>POWER DISSIPATION<br>tot,<br>P<br>**----- End of picture text -----**<br>


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T C, CASE TEMPERATURE<br>**----- End of picture text -----**<br>


**Figure 3. Power dissipation as a function of case temperature** ( _T_ j  175C) 

## IGP50N60T 

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t p=2µs<br>100A<br>10µs<br>10A 50µs<br>1ms<br>1A DC 10ms<br>1V 10V 100V 1000V<br>COLLECTOR CURRENT<br>,<br>I C<br>**----- End of picture text -----**<br>


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V CE, COLLECTOR-EMITTER VOLTAGE<br>**----- End of picture text -----**<br>


**Figure 2. Safe operating area** ( _D =_ 0, _T_ C = 25C, _T_ j 175C; _V_ GE=0/15V) 

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**----- Start of picture text -----**<br>
90A<br>80A<br>70A<br>60A<br>50A<br>40A<br>30A<br>20A<br>10A __  I cmax<br>---  max. current limited by bondwire<br>0A<br>25°C 50°C 75°C 100°C 125°C 150°C<br>**----- End of picture text -----**<br>


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T C, CASE TEMPERATURE<br>**----- End of picture text -----**<br>


**Figure 4. Collector current as a function of** 

**case temperature** ( _V_ GE  15V, _T_ j  175C) 

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## IGP50N60T 

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**----- Start of picture text -----**<br>
120A 120A<br>100A V GE =20V 100A V GE =20V<br>15V 15V<br>80A 13V 80A 13V<br>11V 11V<br>60A 9V 60A 9V<br>7V 7V<br>40A 40A<br>20A 20A<br>0A 0A<br>0V 1V 2V 3V 0V 1V 2V 3V 4V<br>V CE, COLLECTOR-EMITTER VOLTAGE V CE, COLLECTOR-EMITTER VOLTAGE<br>Figure 5. Typical output characteristic  Figure 6. Typical output characteristic<br>( T j = 25°C)  ( T j = 175°C)<br>2.5V<br>80A I C =100A<br>2.0V<br>60A<br>1.5V IC =50A<br>40A<br>1.0V I C =25A<br>20A T J =175°C<br>0.5V<br>25°C<br>0A<br>0V 2V 4V 6V 8V 0.0V<br>0°C 50°C 100°C 150°C<br>V GE, GATE-EMITTER VOLTAGE T J, JUNCTION TEMPERATURE<br>COLLECTOR CURRENT COLLECTOR CURRENT<br>,  ,<br>I C I C<br>EMITT SATURATION VOLTAGE<br>-<br>COLLECTOR CURRENT<br>,<br>I C<br>COLLECTOR<br>CE(sat),<br>V<br>**----- End of picture text -----**<br>


**Figure 7. Typical transfer characteristic** (VCE=20V) 

**Figure 8. Typical collector-emitter saturation voltage as a function of junction temperature** ( _V_ GE = 15V) 

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t<br>d(off)<br>100ns t f t r<br>t<br>d(on)<br>10ns<br>0A 20A 40A 60A 80A<br>SWITCHING TIMES<br>t,<br>**----- End of picture text -----**<br>


## _IC_ , COLLECTOR CURRENT 

**Figure 9. Typical switching times as a function of collector current** (inductive load, _T_ J=175°C, _V_ CE = 400V, VGE = 0/15V, _r_ G = 7Ω, Dynamic test circuit in Figure E) 

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t<br>d(off)<br>100ns<br>t f<br>t r<br>t<br>d(on)<br>10ns<br>25°C 50°C 75°C 100°C 125°C 150°C<br>SWITCHING TIMES<br>t,<br>**----- End of picture text -----**<br>


## _T_ J, JUNCTION TEMPERATURE 

**Figure 11. Typical switching times as a function of junction temperature** (inductive load, _V_ CE = 400V, VGE = 0/15V, _I_ C = 50A, _r_ G=7Ω, Dynamic test circuit in Figure E) 

## IGP50N60T 

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**----- Start of picture text -----**<br>
t d(off)<br>100ns<br>t f<br>t r<br>t<br>d(on)<br>10ns<br>     <br>SWITCHING TIMES<br>t,<br>**----- End of picture text -----**<br>


## _R_ G, GATE RESISTOR 

## **Figure 10. Typical switching times as a function of gate resistor** (inductive load, _T_ J = 175°C, 

_V_ CE= 400V, VGE = 0/15V, _I_ C = 50A, Dynamic test circuit in Figure E) 

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**----- Start of picture text -----**<br>
7V<br>6V<br>max.<br>typ.<br>5V<br>4V min.<br>3V<br>2V<br>1V<br>0V<br>-50°C 0°C 50°C 100°C 150°C<br>EMITT TRSHOLD VOLTAGE<br>-<br>GATE<br>GE(th ) ,<br>V<br>**----- End of picture text -----**<br>


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T J, JUNCTION TEMPERATURE<br>**----- End of picture text -----**<br>


**Figure 12. Gate-emitter threshold voltage as a function of junction temperature** ( _I_ C = 0.8mA) 

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## IGP50N60T 

## TRENCHSTOP™ Series 

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**----- Start of picture text -----**<br>
*)  E on  and  E ts  include losses<br>6.0mJ    due to diode recovery<br>E ts*<br>5.0mJ<br>4.0mJ<br>3.0mJ<br>E off<br>2.0mJ<br>1.0mJ E on*<br>0.0mJ<br>  <br>SWITCHING ENERGY LOSSES<br>,<br>E<br>**----- End of picture text -----**<br>


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**----- Start of picture text -----**<br>
*   due to diode recovery )  E on and  E ts include losses  E ts *<br>8.0mJ<br>6.0mJ<br>E on*<br>4.0mJ<br>E off<br>2.0mJ<br>0.0mJ<br>0A 20A 40A 60A 80A<br>SWITCHING ENERGY LOSSES<br>,<br>E<br>**----- End of picture text -----**<br>


## _IC_ , COLLECTOR CURRENT 

**Figure 13. Typical switching energy losses as a function of collector current** (inductive load, _T_ J = 175°C, _V_ CE = 400V, VGE = 0/15V, _r_ G = 7Ω, Dynamic test circuit in Figure E) 

## _R_ G, GATE RESISTOR 

**Figure 14. Typical switching energy losses as a function of gate resistor** (inductive load, _T_ J = 175°C, _V_ CE = 400V, VGE = 0/15V, _I_ C = 50A, Dynamic test circuit in Figure E) 

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*)  E on and  E ts include losses<br>   due to diode recovery<br>E ts*<br>3.0mJ<br>2.0mJ<br>E off<br>1.0mJ E on*<br>0.0mJ<br>25°C 50°C 75°C 100°C 125°C 150°C<br>SWITCHING ENERGY LOSSES<br>,<br>E<br>**----- End of picture text -----**<br>


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*)  E on and  E ts include losses<br>    due to diode recovery<br>4mJ<br>3mJ E on *<br>E ts*<br>2mJ<br>E off<br>1mJ<br>0mJ<br>300V 350V 400V 450V 500V 550V<br>SWITCHING ENERGY LOSSES<br>,<br>E<br>**----- End of picture text -----**<br>


## _T_ J, JUNCTION TEMPERATURE 

## **Figure 15. Typical switching energy losses** 

## **as a function of junction temperature** 

(inductive load, _V_ CE = 400V, VGE = 0/15V, _I_ C = 50A, _r_ G = 7Ω, Dynamic test circuit in Figure E) 

_VCE_ , COLLECTOR-EMITTER VOLTAGE 

## **Figure 16. Typical switching energy losses as a function of collector emitter voltage** 

(inductive load, _T_ J = 175°C, _V_ GE = 0/15V, _I_ C = 50A, _r_ G = 7Ω, Dynamic test circuit in Figure E) 

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## TRENCHSTOP™ Series 

## IGP50N60T 

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15V<br>120V<br>480V<br>10V<br>5V<br>0V<br>0nC 100nC 200nC 300nC<br>EMITTER VOLTAGE<br>-<br>GATE<br>,<br>GE<br>V<br>**----- End of picture text -----**<br>


_Q_ GE, GATE CHARGE 

**Figure 17. Typical gate charge** ( _I_ C=50 A) 

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**----- Start of picture text -----**<br>
C  iss<br>1nF<br>C oss<br>100pF<br>C rss<br>0V 10V 20V 30V 40V<br>CAPACITANCE<br>c,<br>**----- End of picture text -----**<br>


_V_ CE, COLLECTOR-EMITTER VOLTAGE 

**Figure 18. Typical capacitance as a function of collector-emitter voltage** ( _V_ GE=0V, _f_ = 1 MHz) 

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800A<br>700A<br>600A<br>500A<br>400A<br>300A<br>200A<br>100A<br>0A<br>12V 14V 16V 18V<br>COLLECTOR CURRENT<br>, short circuit<br>I C(sc)<br>**----- End of picture text -----**<br>


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**----- Start of picture text -----**<br>
12µs<br>10µs<br>8µs<br>6µs<br>4µs<br>2µs<br>0µs<br>10V 11V 12V 13V 14V<br>SHORT CIRCUIT WITHSTAND TIME<br>t SC,<br>**----- End of picture text -----**<br>


_V_ GE, GATE-EMITTETR VOLTAGE 

**Figure 19. Typical short circuit collector current as a function of gateemitter voltage** 

( _V_ CE  400V, _T_ j  150C) 

_V_ GE, GATE-EMITETR VOLTAGE 

**Figure 20. Short circuit withstand time as a** 

- **function of gate-emitter voltage** ( _V_ CE=400V _,_ start at _T_ J _=_ 25°C, _T_ Jmax<150°C) 

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## IGP50N60T 

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**----- Start of picture text -----**<br>
D =0.5<br>10 -1K/W 0.2<br>0.1<br>R , ( K / W )  , ( s )<br>0.18355 7.425*10 [-2]<br>0.05 *<br>0.12996  8.34 10 [-3 ]<br>0.09205 7.235*10 [-4]<br>0.03736 1.035*10 [-4]<br>0.00703 4.45*10 [-5]<br>-2 0.02 R 1 R 2<br>10 K/W<br>0.01<br>C 1=1/ R 1 C 2=2/ R 2<br>single pulse<br>1µs 10µs 100µs 1ms 10ms 100ms<br>t P, PULSE WIDTH<br>TRANSIENT THERMAL IMPEDANCE<br>,<br>thJC<br>Z<br>**----- End of picture text -----**<br>


**Figure 21. IGBT transient thermal impedance** ( _D = t_ p / _T_ ) 

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## IGP50N60T 

## TRENCHSTOP™ Series 

## PG-TO220-3 

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## Cinfineon ~~,~~ 

**Figure A. Definition of switching times** 

## IGP50N60T 

## TRENCHSTOP™ Series 

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**----- Start of picture text -----**<br>
i,v<br>di F /dt t r r =t S + t F<br>“a Q r r =Q S + Q F<br>t<br>a r r<br>I F t S t F<br>I Q S Q F 10%  I r r m t<br>r r m 90%  I di r r /dt V R<br>r r m<br>Figure C. Definition of diodes<br>switching characteristics<br>1 2 n<br>r1 r 2 r n<br>T (t)j<br>p(t) r1 r 2 r n<br>T C<br>**----- End of picture text -----**<br>


**Figure D. Thermal equivalent circuit** 

**Figure B. Definition of switching losses** 

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**Published by Infineon Technologies AG 81726 Munich, Germany © 2015 Infineon Technologies AG All Rights Reserved.** 

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## **Information** 

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## **Warnings** 

Due to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office. 

The Infineon Technologies component described in this Data Sheet may be used in life-support devices or systems and/or automotive, aviation and aerospace applications or systems only with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support, automotive, aviation and aerospace device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered. 

Rev. 2.8   19.05.2015 

12 

IFAG IPC TD VLS

Updated at June 9, 2026

Infineon Technologies is a globally recognized leader in semiconductor solutions, renowned for driving innovation in power management, energy efficiency, and modern mobility. With a strong legacy of engineering excellence, the company provides highly reliable components designed to meet the rigorous demands of industrial, automotive, and advanced commercial applications. The core of our Infineon portfolio is centered on their industry-leading discrete semiconductors. We offer an extensive selection of single and dual MOSFETs, alongside a robust range of single IGBTs and advanced IGBT modules. These flagship power transistors are essential for high-efficiency power conversion and motor control, providing engineers with superior thermal performance and minimized switching losses. Beyond advanced field-effect transistors, the selection includes a comprehensive array of diodes and rectifiers, heavily featuring Schottky diodes, as well as fast-recovery and RF/PIN diodes. This power foundation is further supported by bipolar transistors, intelligent power modules, and thyristor SCR modules, delivering the critical building blocks required for complex power system designs. To support broader system integration, the portfolio also encompasses specialized solutions such as solid-state relays, AC/DC LED driver ICs, and Bluetooth communications modules. From high-power industrial rectifiers to wireless connectivity adapters, Infineon equips designers with the precision components needed to build efficient, scalable, and fully connected electronic systems.

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