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AIGW50N65H5XKSA1
IGBT, 80 A, 1.66 V, 270 W, 650 V, TO-247, 3 Pins
⚠️ Reference pricing provided. In case of supply shortages, we will connect you with our trusted procurement partners to ensure your project's continuity.
- Manufacturer: INFINEON
- Product type: Single IGBTs
- DC Collector Current:80A; Collector Emitter Saturation Voltage Vce(on):1.66V; Power Dissipation Pd:270W; Collector Emitter Voltage V(br)ceo:650V; Transistor Case Style:TO-247; No.
- MSL: MSL 1 - Unlimited
- SVHC: No SVHC (25-Jun-2025)
- No. of Pins: 3Pins
- Product Range: TRENCHSTOP 5
- Power Dissipation: 270W
- Transistor Mounting: Through Hole
- Transistor Case Style: TO-247
- Operating Temperature Max: 175°C
- Continuous Collector Current: 80A
- Collector Emitter Voltage Max: 650V
- Collector Emitter Saturation Voltage: 1.66V
| Delivery and price | |
|---|---|
| Units per pack | 100 |
| Price | 2.37 € |
| Current stock | 100+ |
| Lead time | 30 days |
Datasheet
## AIGW50N65H5
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High speed fast IGBT in TRENCHSTOP TM _ 5 technology<br>Features and Benefits: C<br>High speed H5 technology offering:<br>Best-in-Class efficiency in hard switching and resonant<br>topologies<br>Plug and play replacement of previous generation IGBTs<br>650V breakdown voltage G<br>Low gate charge Q G E<br>Maximum junction temperature 175°C<br>Dynamically stress tested<br>Qualified according to AEC-Q101<br>Green package (ROHS compliant)<br>Complete product spectrum and PSpice Models: =<br>http://www. infineon.com/igbt/ Gi,<br>Applications:<br>Off-board charger yf<br>On-board charger<br>DC/DC converter<br>Power-Factor correction<br>1<br>2<br>3<br>**----- End of picture text -----**<br>
## **Applications:**
|**Type**|**_V_CE**|**_I_C**|**_V_CEsat** **_T_vj=25°C**|**_T_vjmax**|**Marking**|**Package**|
|---|---|---|---|---|---|---|
|AIGW50N65H5|650V|50A|1.66V|175°C|AG50EH5|PG-TO247-3|
Datasheet www.infineon.com
2017-06-30
AIGW50N65H5
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## High�speed�switching�series�fifth�generation
## **Table�of�Contents**
Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Table of Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Thermal Resistance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 Electrical Characteristics Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Package Drawing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11 Testing Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13 Disclaimer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
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AIGW50N65H5
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## High�speed�switching�series�fifth�generation
## **Maximum�Ratings**
|**Parameter**|**Symbol**||**Value**|**Unit**|
|---|---|---|---|---|
|Collector-emittervoltage,_T_vj≥25°C|_V_CE||650|V|
|DCcollectorcurrent,limitedby_T_vjmax<br>_T_C=25°Cvaluelimitedbybondwire<br>_T_C=100°C|_I_C||80.0<br>53.5|A|
|Pulsedcollectorcurrent,_t_plimitedby_T_vjmax1)|_I_Cpuls||150.0|A|
|Turn off safe operating area<br>_V_CE≤650V,_T_vj≤175°C,_t_p=1µs1)|-||150.0|A|
|Gate-emitter voltage<br>TransientGate-emittervoltage(_t_p≤10µs,_D_<0.010)|_V_GE||±20<br>±30|V|
|Powerdissipation_T_C=25°C<br>Powerdissipation_T_C=100°C|_P_tot||270.0<br>136.0|W|
|Operating junction temperature|_T_vj|-40...+175||°C|
|Storage temperature|_T_stg|-55...+150||°C|
|Soldering temperature,2)<br>wave soldering1.6mm(0.063in.)from case for 10s|||260|°C|
|Mounting torque, M3 screw<br>Maximum of mounting processes: 3|_M_||0.6|Nm|
## **Thermal�Resistance**
|**ThermalResistance**|||||||
|---|---|---|---|---|---|---|
|**Parameter**|**Symbol **|**Conditions**||**Value**||**Unit**|
||||**min.**|**typ.**|**max.**||
|**RthCharacteristics**|||||||
|IGBT thermal resistance,<br>junction - case|_R_th(j-C)||-|-|0.55|K/W|
|Thermal resistance<br>junction - ambient|_R_th(j-a)||-|-|40|K/W|
## **Electrical�Characteristic,�at�** _**T**_ **vj�=�25°C,�unless�otherwise�specified**
|**Parameter**|**Symbol **|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**typ.**|**max.**||
|**StaticCharacteristic**|||||||
|Collector-emitter breakdown voltage|_V_(BR)CES|_V_GE=0V,_I_C=0.20mA|650|-|-|V|
|Collector-emitter saturation voltage|_V_CEsat|_V_GE=15.0V,_I_C=50.0A<br>_T_vj=25°C<br>_T_vj=125°C<br>_T_vj=175°C|-<br>-<br>-|1.66<br>1.91<br>2.04|2.10<br>-<br>-|V|
|Gate-emitter threshold voltage|_V_GE(th)|_I_C=0.50mA,_V_CE=_V_GE|3.2|4.0|4.8|V|
|Zero gate voltage collector current|_I_CES|_V_CE=650V,_V_GE=0V<br>_T_vj=25°C<br>_T_vj=175°C|-<br>-|-<br>500|40<br>-|µA|
|Gate-emitter leakage current|_I_GES|_V_CE=0V,_V_GE=20V|-|-|100|nA|
|Transconductance|_g_fs|_V_CE=20V,_I_C=50.0A|-|62.0|-|S|
1) Defined by design. Not subject to production test. 2) Package not recommended for surface mount applications
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AIGW50N65H5
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## High�speed�switching�series�fifth�generation
## **Electrical�Characteristic,�at�** _**T**_ **vj�=�25°C,�unless�otherwise�specified**
|**Parameter**|**Symbol **|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**typ.**|**max.**||
|**DynamicCharacteristic**|||||||
|Input capacitance|_C_ies|_V_CE=25V,_V_GE=0V,f=1MHz|-|2800|-|pF|
|Output capacitance|_C_oes||-|54|-||
|Reverse transfer capacitance|_C_res||-|11|-||
|Gate charge|_Q_G|_V_CC=520V,_I_C=50.0A,<br>_V_GE=15V|-|116.0|-|nC|
|Internal emitter inductance<br>measured 5mm (0.197 in.) from<br>case|_L_E||-|13.0|-|nH|
## **Switching�Characteristic,�Inductive�Load**
|**Parameter**|**Symbol **|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**typ.**|**max.**||
|**IGBTCharacteristic,at****_T_vj=25°C**|||||||
|Turn-on delaytime|_t_d(on)|_T_vj=25°C,<br>_V_CC=400V,_I_C=25.0A,<br>_V_GE=0.0/15.0V,<br>_R_G(on)=12.0Ω,_R_G(off)=12.0Ω,<br>_L_σ=30nH,_C_σ=30pF<br>_L_σ,_C_σfromFig.E<br>Energy losses include “tail” and<br>diode reverse recovery.|-|21|-|ns|
|Rise time|_t_r||-|12|-|ns|
|Turn-off delaytime|_t_d(off)||-|173|-|ns|
|Fall time|_t_f||-|11|-|ns|
|Turn-on energy|_E_on||-|0.45|-|mJ|
|Turn-off energy|_E_off||-|0.16|-|mJ|
|Total switchingenergy|_E_ts||-|0.61|-|mJ|
||||||||
|Turn-on delaytime|_t_d(on)|_T_vj=25°C,<br>_V_CC=400V,_I_C=6.0A,<br>_V_GE=0.0/15.0V,<br>_R_G(on)=12.0Ω,_R_G(off)=12.0Ω,<br>_L_σ=30nH,_C_σ=30pF<br>_L_σ,_C_σfromFig.E<br>Energy losses include “tail” and<br>diode reverse recovery.|-|20|-|ns|
|Rise time|_t_r||-|4|-|ns|
|Turn-off delaytime|_t_d(off)||-|187|-|ns|
|Fall time|_t_f||-|24|-|ns|
|Turn-on energy|_E_on||-|0.10|-|mJ|
|Turn-off energy|_E_off||-|0.04|-|mJ|
|Total switchingenergy|_E_ts||-|0.14|-|mJ|
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## High�speed�switching�series�fifth�generation
## **Switching�Characteristic,�Inductive�Load**
|**Parameter**|**Symbol **|**Conditions**||**Value**||**Unit**|
|---|---|---|---|---|---|---|
||||**min.**|**typ.**|**max.**||
|**IGBTCharacteristic,at****_T_vj=150°C**|||||||
|Turn-on delaytime|_t_d(on)|_T_vj=150°C,<br>_V_CC=400V,_I_C=25.0A,<br>_V_GE=0.0/15.0V,<br>_R_G(on)=12.0Ω,_R_G(off)=12.0Ω,<br>_L_σ=30nH,_C_σ=30pF<br>_L_σ,_C_σfromFig.E<br>Energy losses include “tail” and<br>diode reverse recovery.|-|20|-|ns|
|Rise time|_t_r||-|13|-|ns|
|Turn-off delaytime|_t_d(off)||-|200|-|ns|
|Fall time|_t_f||-|13|-|ns|
|Turn-on energy|_E_on||-|0.61|-|mJ|
|Turn-off energy|_E_off||-|0.24|-|mJ|
|Total switchingenergy|_E_ts||-|0.85|-|mJ|
||||||||
|Turn-on delaytime|_t_d(on)|_T_vj=150°C,<br>_V_CC=400V,_I_C=6.0A,<br>_V_GE=0.0/15.0V,<br>_R_G(on)=12.0Ω,_R_G(off)=12.0Ω,<br>_L_σ=30nH,_C_σ=30pF<br>_L_σ,_C_σfromFig.E<br>Energy losses include “tail” and<br>diode reverse recovery.|-|18|-|ns|
|Rise time|_t_r||-|4|-|ns|
|Turn-off delaytime|_t_d(off)||-|225|-|ns|
|Fall time|_t_f||-|31|-|ns|
|Turn-on energy|_E_on||-|0.16|-|mJ|
|Turn-off energy|_E_off||-|0.07|-|mJ|
|Total switchingenergy|_E_ts||-|0.23|-|mJ|
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270 90<br>240 80<br>Nae e t | tf<br>210 PX 70 E R<br>180 60<br>ef No yet iN<br>150 50<br>oN eee<br>By 120 40 EN<br>90 30<br>pt T IN ye EP<br>60 20<br>SaeeNe oe<br>30 10<br>ee eeeeeeee<br>pete<br>0 0<br>N N EE A<br>25 50 75 100 125 150 175 25 50 75 100 125 150<br>T C , CASE TEMPERATURE [°C] T C , CASE TEMPERATURE [°C]<br>Figure 1. Power dissipation as a function of case Figure 2. Collector current as a function of case case<br>temperature temperature<br>( T vj ≤ 175°C) ( V GE ≥ 15V, T vj ≤ 175°C)<br>150 150<br>135 135<br>BED PL | eee eee eae<br>120 120<br>VGE = 20V LLUA | EE VGE = 20V ea|<br>18V 18V<br>105 105<br>15V 15V<br>z pf z ae a<br>90 90<br>12V 12V<br>75 10V 75 10V<br>8V 8V<br>Le eg<br>60 60<br>7V 7V<br>45 6V 45 6V<br>5V 5V<br>: 30 aNEEN (SEERee : 30 | eo<br>15 RN LERe 15 eee,KER}Zee<br>PAN<br>0 l h 0 L A<br>0 1 2 3 4 5 0 1 2 3 4 5<br>V CE , COLLECTOR-EMITTER VOLTAGE [V] V CE , COLLECTOR-EMITTER VOLTAGE [V]<br>P tot I C<br>I C I C<br>**----- End of picture text -----**<br>
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90<br>80<br>e t | tf<br>70 E R<br>60<br>yet iN<br>50<br>eee<br>40 EN<br>30<br>ye EP<br>20<br> oe<br>10<br>eeeeeeee<br>0<br>EE A<br>25 50 75 100 125 150 175<br>T C , CASE TEMPERATURE [°C]<br>Figure 2. Collector current as a function of case case<br>temperature<br>( V GE ≥ 15V, T vj ≤ 175°C)<br>I C<br>**----- End of picture text -----**<br>
Figure 3. Typical ( _T_ vj=25°C)
Figure 4. Typical ( _T_ vj=150°C)
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**----- Start of picture text -----**<br>
150 LY 2.50 Ld<br>— T vj =25°C / — I C =6.25A<br>135 —- T vj =150°C —- I C =12.5A<br>_ 2.25 I C<br>I C<br>120 TL z --- =25A<br>s<br>= | / ileE 2.00 e s<br>105<br>Ww <x 1.75<br>90<br>4 7A)<br>Oo y FE<br>a 75 / = 1.50 —<br>Ww 60 ad<br>ee ee eee<br>1.25<br>. 45 _<br>1.00<br>30<br>0.75<br>15<br>7<br>0 0.50<br>4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0 8.5 25 50 75 100 125 150 175<br>V GE , GATE-EMITTER VOLTAGE [V] T vj , JUNCTION TEMPERATURE [°C]<br>I C<br>CEsat<br>V<br>**----- End of picture text -----**<br>
Figure 5. Typical ( _V_ CE=20V)
Figure 6. Typical a function ( _V_ GE=15V)
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1000 aa 1000<br>| 1 td(off) eea aee ee |i td(off) a aee ee ee es<br>I ttfd(on) ee ee ee | ttfd(on) rr a ae<br>tr tr<br>| p o | t tt _t _<br>p T Pod | e<br>e e e ee<br>100 100<br>ip) a ae a<br>uw aea aee et ip) aa aee es<br>= poe = ee ee ee ee eee<br>- a ee ee ee ee<br>Q re aa eee Q a ee eeeee<br>so eee eee<br>= > = e ee<br>2) 10 a se a 2) 10 a ee ee<br>° a es ° a a<br>a a ee es<br>a a a a<br>a ee a ee<br>aa<br>1 1<br>0 30 60 90 120 150 5 15 25 35 45 55 65<br>I C , COLLECTOR CURRENT [A] R G , GATE RESISTANCE [ Ω ]<br>Figure 7. Typical switching times as a function of Figure 8. Typical switching times as a function of<br>collector current resistance<br>(inductive load, T vj =150°C, V CE=400V, (inductive load, T vj =150°C, V CE=400V,<br>V GE =0/15V, R G(on)=12 Ω , R G(off)=12 Ω , dynamic V GE =0/15V, I C =25A, dynamic test circuit in<br>test circuit in Figure E) Figure E)<br>t t<br>**----- End of picture text -----**<br>
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**----- Start of picture text -----**<br>
1000 LS 5.5 +4<br>| 1 td(off) a a ee a ee ee typ.<br>tf min.<br>I td(on) a ee 5.0 max.<br>tr<br>x oo.<br>oe a ~ F 4.5 p are e<br>ef fo) ——<br>ip)= 100 aa es||]:ia 4.0 Pee ~ = ~ALAL<br>im poa a a (e) ~ sa<br>F es ee Wy 3.5 r —<br><= -<br>3.0<br>a: eee e ee e e —| 6 —a = — SS<br>2)7 10 po a eS Ww= 2.5 S ~~ ~<br>ee ~<br>poa eseo)x 2.0 ~ ~<br>1.5<br>1 1.0<br>25 50 75 100 125 150 175 25 50 75 100 125 150<br>T vj , JUNCTION TEMPERATURE [°C] T vj , JUNCTION TEMPERATURE [°C]<br>Figure 9. Typical switching times as a function of Figure 10. Gate-emitter threshold voltage as a<br>junction temperature of junction temperature<br>(inductive load, V CE =400V, V GE=0/15V, ( I C=0.5mA)<br>I C =25A, R G(on)=12 Ω ; R G(off)=12 Ω , dynamic test<br>circuit in Figure E)<br>10 2.4<br>Eoff Eoff<br>9 Eon Eon<br>Ets 2.1 Ets<br>/ Yo<br>J | | / | ) :7<br>amp) 8 ap) 7<br>1.8<br>ie) / ie) 77<br>7<br>@) / @) 1.5 c<br>aa 6 / aa y<br>©)> // | >© x “<br>owWi 5 / ya V4 owWi 1.2 5 y —<br>Lu yf Lu —<br>4<br>Zz / Zz 0.9 < <<br>= / Yo = a \~<br>— 3<br>=<br>J Y 0.6<br>% a = -_ a<br>2<br>Le | 2 ao<br>0.3 a<br>1 “ae [a] -_<br>0 0.0<br>0 30 60 90 120 150 5 15 25 35 45 55 65 75 85<br>I C , COLLECTOR CURRENT [A] R G , GATE RESISTANCE [ Ω ]<br>t<br>GE(th)<br>V<br>E E<br>**----- End of picture text -----**<br>
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**----- Start of picture text -----**<br>
5.5 +4<br>typ.<br>min.<br>5.0 max.<br>x oo.<br>F 4.5 p are e<br>fo) ——<br>iaa 4.0 Pee ~ = ~ALAL<br>(e) ~ sa<br>Wy 3.5 r —<br>-<br>3.0<br>6 —a = — SS<br>= 2.5 S ~~<br>Ww= ~<br>~<br>x 2.0 ~ ~<br>1.5<br>1.0<br>25 50 75 100 125 150<br>T vj , JUNCTION TEMPERATURE [°C]<br>GE(th)<br>V<br>**----- End of picture text -----**<br>
Figure 11.
Figure 12.
(inductive load, _T_ vj =150°C, _V_ CE=400V, _V_ GE =0/15V, _R_ G(on)=12 Ω , _R_ G(off)=12 Ω , dynamic test circuit in Figure E)
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**----- Start of picture text -----**<br>
(inductive load, T vj =150°C, V CE=400V,<br>V GE =0/15V, I C =25A, dynamic test<br>Figure E)<br>**----- End of picture text -----**<br>
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**----- Start of picture text -----**<br>
1.0 1.1<br>Eoff Eoff<br>0.9 Eon 1.0 Eon<br>Ets Ets<br>0.9<br>op)> 0.8 a_ a op)> 0.8 n na7 Zz | |<br>0.7<br>0.7<br>> 0.6 _ > “ 7 Z Za<br>5 Te fare<br>0.6<br>= | et<br>0.5<br>Zz: _— az a ae<br>0.5<br>Oo 0.4 O Z<br>2 aa<br>0.4<br>0.3<br>0.3<br>: ee ee<br>Bf 0.2 n=<br>0.2<br>eT<br>0.1 0.1<br>0.0 0.0<br>25 50 75 100 125 150 175 200 250 300 350 400 450 500<br>T vj , JUNCTION TEMPERATURE [°C] V CE , COLLECTOR-EMITTER VOLTAGE [V]<br>E E<br>**----- End of picture text -----**<br>
Figure 13.
(inductive load, _V_ CE =400V, _V_ GE=0/15V, _I_ C =25A, _R_ G(on)=12 Ω , _R_ G(off)=12 Ω , test circuit in Figure E)
Figure 14.
(inductive load, _T_ vj =150°C, _V_ GE=0/15V, _I_ C =25A, _R_ G(on)=12 Ω , _R_ G(off)=12 Ω , test circuit in Figure E)
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**----- Start of picture text -----**<br>
16 {<br>V CC Cies<br>_- V CC = 520V / 1E+4 H Coes ot<br>14 CC) // ' a Cres Se<br>[ aes<br>S 12<br>a<br>1000<br>0) y/ _ EE| |<br>< aaa Ue e e ——ee<br>— 10 a<br>Q s_ Aa a<br>ZA ee<br>8<br>FEE : Se 100 pbee<br>a Ee<br>= ° pj} Ps} | _________]<br>xt pNP [Ee]<br>Ww 6 [{ oO a a ed<br>° 4 PE<br>10<br>aa<br>2 a<br>0 1<br>0 20 40 60 80 100 120 0 5 10 15 20 25 30<br>Q G , GATE CHARGE [nC] V CE , COLLECTOR-EMITTER VOLTAGE [V]<br>Figure 15. Typical gate charge Figure 16. Typical capacitance as a function of<br>( I C=50A) collector-emitter voltage<br>C<br>GE<br>V<br>**----- End of picture text -----**<br>
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**----- Start of picture text -----**<br>
( V GE<br>**----- End of picture text -----**<br>
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**----- Start of picture text -----**<br>
1<br>a<br>A<br>= a ee ec<br>D = 0.5<br>2r eesHf ail 0.2 ill<br>cg enBe 0.1 il<br>0.1<br>0.05<br>a HE He<br>2 ea ieeecy,! A cca 1 |<br>7 ere aeS 0.02 To<br>0.01<br><x Ses = at a<br>z En | 1<br>single pulse<br>: Ba ist ean eee<br>BTN<br>0.01<br>icp) CCT CeO PC EC Co<br>z enter ttt 1" me |i<br>rs EY --|I<br>- aD) |<br>PUTMAN ETT TUTTE | op Steel<br>PAU A TM TTT TIT Ti<br>i: 1 2 3 4<br>ri[K/W]: 0.115657 0.129838 0.156524 0.147981<br>τ i[s]: 1.8E-4 1.7E-3 0.0144 0.127484<br>0.001 | tt | a<br>1E-6 1E-5 1E-4 0.001 0.01 0.1 1<br>t p ,PULSE WIDTH [s]<br>Figure 17. IGBT transient thermal impedance<br>( D = t p/T)<br>c)th(j-<br>Z<br>**----- End of picture text -----**<br>
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## High�speed�switching�series�fifth�generation
## **Package Drawing PG-TO247-3**
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AIGW50N65H5
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## High�speed�switching�series�fifth�generation
## **Testing Conditions**
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V GE (t)<br>90% V GE<br>10% V GE t<br>I C (t)<br>90% I C 90% I C<br>10% I C 10% I C<br>t<br>V CE (t)<br>t<br>t d(off) t f t d(on) t r<br>Figure A.<br>V GE (t)<br>90% V GE<br>10% V GE<br>t<br>I C (t)<br>2% I C t<br>V CE (t)<br>t 2 t 4<br>E off [=] V CE x I C x d t E on [=] V CE x I C x d t<br>t 1 t 3 2% V CE<br>t<br>t 1 t 2 t 3 t 4<br>Figure B.<br>**----- End of picture text -----**<br>
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I,V<br>dI F /dt Qt rrrr== Qt aa++ tQ b b<br>a b<br>Q a Q b<br>dI<br>Figure C. Definition of diode switching<br>characteristics<br>**----- End of picture text -----**<br>
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t<br>**----- End of picture text -----**<br>
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Figure D.
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CC<br>**----- End of picture text -----**<br>
Figure E. **Dynamic test circuit** Parasitic inductance Ls, parasitic capacitor Cs, relief capacitor C ,r (only for ZVT switching)
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Datasheet
AIGW50N65H5
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## High�speed�switching�series�fifth�generation
## **Revision�History**
AIGW50N65H5
## **Revision:�2017-06-30,�Rev.�2.1**
|Previous Revision|Previous Revision||
|---|---|---|
|Revision|Date|Subjects(major changes since last revision)|
|2.1|2017-06-30|Data sheet created|
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Datasheet
## party.
## **Warnings**
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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