AUIRLS4030-7P

> **AUTOMOTIVE GRADE** AUIRLS4030-7P ~~—~~ 

## ~~Cinfineon~~ 

HEXFET[® ] Power MOSFET 

## **Features** 

- Optimized for Logic Level Drive 

| Optimized for Logic Level DriveOptimized for Logic Level Drive<br>Advanced Process Technology<br>Ultra Low On-Resistance|**VDSS**<br>**RDS(on)   typ.**|**typ.**|**typ.**|||**100V**<br>**3.2m**|
|---|---|---|---|---|---|---|
|Logic Level Gate Drive<br>175°C Operating Temperature<br>Fast Switching|**max.**<br>**ID**|**max.**||||**3.9m**<br>**190A**|
|Repetitive Avalanche Allowed up to Tjmax|||||||
|Lead-Free, RoHS Compliant|||||||
|Automotive Qualified *|||||||
|**Description**|||||||
|Specifically designed for Automotive applications, this HEXFET®|||||||
|Power MOSFET utilizes the latest processing techniques to achieve|||||||
|extremely low on-resistance per silicon area.  Additional features of<br>this design  are a 175°C junction operating temperature, fast<br>switching speed and improved repetitive avalanche rating . These||D2Pak 7 Pin<br>AUIRLS4030-7P|||||
|features combine to make this design an extremely efficient and<br>reliable device for use in Automotive applications and a wide variety<br>of other applications.|G<br>D<br>S<br>Gate<br>Drain<br>Source<br>~~ee~~||||||
|**Base Part Number**<br>**Package Type**<br>**Standard Pack**<br>**Form**<br>**Quantity**||||**Orderable Part Number**||**Orderable Part Number**|
|AUIRLS4030-7P<br>Tube<br>Tape and Reel Left<br>D2Pak 7 Pin|50<br>800|||AUIRLS4030-7P<br>AUIRLS4030-7TRL|||



## **Absolute Maximum Ratings** 

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device.   These are stress ratings only; and functional operation of the device at these or any other condition beyond those indicated in the specifications is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. The thermal resistance and power dissipation ratings are measured under board mounted and still air conditions. Ambient temperature (TA) is 25°C, unless otherwise specified. 

|**Symbol**<br>**Parameter**<br>**Max.**<br>**Units**<br>ID@ TC= 25°C<br>Continuous Drain Current, VGS@ 10V<br>190<br>A<br>ID @TC= 100°C<br>Continuous Drain Current,VGS @10V<br>130<br>IDM<br>Pulsed Drain Current<br>750<br>PD@TC= 25°C<br>Maximum Power Dissipation<br>370<br>W<br>Linear Derating Factor<br>2.5<br>W/°C<br>VGS<br>Gate-to-SourceVoltage<br>± 16<br>V<br>EAS<br>Single Pulse Avalanche Energy (ThermallyLimited) <br>320<br>mJ<br>IAR<br>Avalanche Current<br>See Fig.14,15, 22a, 22b<br>A<br>EAR<br>Repetitive Avalanche Energy <br>mJ<br>dv/dt<br>Peak Diode Recovery <br>13<br>V/ns<br>TJ<br>Operating Junction and<br>-55  to + 175<br>TSTG<br>Storage Temperature Range<br>°C<br>SolderingTemperature,for 10 seconds(1.6mm from case)<br>300<br>~~re~~<br>~~$$~~<br>~~a~~<br>~~——~~<br>~~ee oe~~<br>~~ee~~||
|---|---|
|**Thermal Resistance**||
|**Symbol**<br>**Parameter**<br>**Typ.**<br>**Max.**<br>**Units**<br>RJC<br>Junction-to-Case<br>–––<br>0.40<br>°C/W<br>RJA<br>Junction-to-Ambient<br>–––<br>40<br>~~ee~~||
|HEXFET® is a registered trademark of Infineon.||
|1<br>2015-11-6<br>*****Qualification standards can be found atwww.infineon.com<br>~~—_—~~||



~~Cinfineon~~ 

AUIRLS4030-7P ~~[~~ 

## **Static @ TJ = 25°C (unless otherwise specified)** 

|Qg<br>~~ee~~|Total Gate Charge|–––|93|140|nC|ID= 110A<br>VDS= 50V<br>VGS= 4.5V|
|---|---|---|---|---|---|---|
|g<br>Qgs<br>~~ee~~<br>~~a~~<br>~~es~~|Gate-to-Source Charge|–––|27|–––|||
|gs<br>Qgd<br>~~a~~<br>~~es~~<br>~~es~~|Gate-to-Drain Charge<br>~~ee~~|–––<br>~~ee~~|43<br>~~ee~~|–––<br>~~ee~~|||
|gd<br>Qsync<br>~~es~~<br>~~es~~<br>~~Rs~~|Total Gate Charge Sync.(Qg - Qgd)<br>~~ee~~|–––<br>~~ee~~|50<br>~~ee~~|–––<br>~~ee~~|||
|td(on)<br>~~es~~<br>~~Rs~~<br>~~es~~|Turn-On Delay Time<br>~~ee~~<br>~~er~~|–––<br>~~ee~~<br>~~er~~|53<br>~~ee~~<br>~~er~~|–––<br>~~ee~~<br>~~er~~|ns|VDD= 65V<br>ID= 110A<br>RG= 2.7<br>VGS= 4.5V|
|d(on)<br>tr<br>~~Rs~~<br>~~es~~|Rise Time<br>~~er~~|–––<br>~~er~~|160<br>~~er~~|–––<br>~~er~~|||
|td(off)<br>~~es~~<br>~~a ee~~<br>~~ee~~|Turn-Off DelayTime<br>~~er~~<br>~~ee~~<br>~~a~~|–––<br>~~er~~<br>~~ee~~<br>~~a~~|110<br>~~er~~<br>~~ee~~<br>~~a~~|–––<br>~~er~~<br>~~ee~~<br>~~a~~|||
|d(off)<br>tf<br>~~ee~~<br>~~ee~~|Fall Time<br>~~a~~|–––<br>~~a~~|87<br>~~a~~|–––<br>~~a~~|||
|Ciss<br>~~ee~~<br>~~ee~~<br>~~es~~|Input Capacitance<br>~~a~~|–––11490<br>~~a~~|11490<br>~~a~~|11490–––<br>~~a~~|pF<br>~~ee~~|VGS= 0V<br>VDS= 50V<br>ƒ= 1.0MHz|
|Coss<br>~~ee~~<br>~~es~~<br>~~ee~~|Output Capacitance<br>~~en~~|–––<br>~~en~~<br>~~ee~~|680<br>~~en~~|–––<br>~~en~~|||
|Crss<br>~~es~~<br>~~ee~~<br>~~ee~~|Reverse Transfer Capacitance<br>~~en~~<br>~~ee~~|–––<br>~~en~~<br>~~ee~~<br>~~ee~~|300<br>~~en~~<br>~~ee~~|–––<br>~~en~~<br>~~ee~~|||
|Coss eff.(ER)<br>~~ee~~<br>~~ee~~|Effective Output Capacitance (EnergyRelated)<br>~~en~~<br>~~ee~~|–––<br>~~en~~<br>~~ee~~<br>~~ee~~|760<br>~~en~~<br>~~ee~~|–––<br>~~en~~<br>~~ee~~||VGS=0V,VDS=0Vto 80V|
|oss eff.(ER)<br>Coss eff.(TR)<br>~~ee~~<br>~~Pf~~|Effective Output Capacitance(Time Related)<br>~~ee~~<br>~~Pf~~|–––<br>~~ee~~<br>~~Pf~~|1170<br>~~ee~~<br>~~Pf~~|–––<br>~~ee~~<br>~~Pf~~||VGS= 0V,VDS= 0V to 80V|
|**Diode Characteristics**<br>~~PeGs~~<br>~~Qe~~|||||||
|~~Pe~~|**Parameter **<br>~~Gs~~|**Min.**<br>~~Gs~~|**Typ. M**<br>~~Gs~~|**. Max.**<br>~~Gs~~|**Units**<br>~~Gs~~<br>~~Qe~~|**Conditions**<br>~~Gs~~|
|IS<br>~~Pe~~<br>~~>t~~|Continuous Source Current<br>(BodyDiode)<br>~~Gs~~<br>~~>t~~|–––<br>~~Gs~~<br>~~>t~~|–––<br>~~Gs~~<br>~~>t~~|190<br>~~Gs~~|A<br>~~Gs~~<br>~~Qe~~<br>||MOSFET symbol<br>showing  the<br>integral reverse<br>p-n junction diode.<br>~~Gs~~<br>a|
|ISM<br>~~>t~~<br>~~es~~|Pulsed Source Current<br>(Body Diode)<br>~~>t~~<br>~~rs~~|–––<br>~~>t~~<br>~~rs~~|–––<br>~~>t~~<br>~~Gsfs~~|750<br>~~Gsfs~~|||
|VSD<br>~~es~~<br>~~a~~|DiodeForwardVoltage<br>~~rs~~<br>~~ee~~|–––<br>~~rs~~<br>~~eee~~|–––<br>~~Gsfs~~<br>~~eee~~|1.3<br>~~Gsfs~~<br>~~eee~~|V<br>~~eee~~|TJ= 25°C,IS= 110A,VGS=0V|
|trr<br>~~es~~<br>~~a~~|Reverse Recovery Time<br>~~rs~~<br>~~ee~~<br>~~**|**~~|–––<br>~~rs~~<br>~~eee~~|53<br>~~Gsfs~~<br>~~eee~~|–––<br>~~Gsfs~~<br>~~eee~~|ns<br>~~eee~~|TJ =25°CVDD= 85V<br>TJ =125°CIF= 110A,<br>TJ =25°Cdi/dt = 100A/µs<br>TJ =125°C <br>TJ= 25°C|
|||–––<br>~~eee~~<br>~~**|**~~|63<br>~~eee~~|–––<br>~~eee~~|||
|Qrr<br>~~a ~~<br>~~a ee~~<br>~~rs~~|Reverse Recovery Charge<br> ~~ee~~<br>~~**|**~~<br>~~ee~~<br>~~|~~<br>|–––<br>~~eee~~<br>~~**|**~~<br>~~ee~~<br>~~eee~~<br>~~|~~|99<br>~~eee~~<br>~~ee~~<br>~~eee~~<br>|–––<br>~~eee~~<br>~~ee~~<br>~~eee~~<br>|nC<br>~~eee~~<br>~~ee~~<br>~~eee~~<br>||
|||–––<br>~~ee~~<br>~~eee~~<br>~~||~~<br>|155<br>~~ee~~<br>~~eee~~<br>~~|~~<br>|–––<br>~~ee~~<br>~~eee~~<br>~~|~~<br>|||
|IRRM<br>~~a ee~~<br>~~rs~~|ReverseRecovery Current<br>~~ee~~<br>~~|~~<br>~~ee~~|–––<br>~~ee~~<br>~~eee~~<br>~~||~~<br>~~ee~~|3.3<br>~~ee~~<br>~~eee~~<br>~~|~~<br>~~ee~~|–––<br>~~ee~~<br>~~eee~~<br>~~|~~<br>~~ee~~|A<br>~~ee~~<br>~~eee~~<br>~~ee~~||
|ton<br>~~rs~~<br>~~eG~~|Forward Turn-On Time<br><br>~~ee~~<br>~~eG~~|Intrinsic turn-on time is negligible(turn-on is dominated byLS+LD)<br>~~|~~<br>~~ee~~<br>~~eG~~|||||



**Notes:**  Repetitive rating;  pulse width limited by max. junction temperature.  Limited by TJmax, starting  TJ = 25°C, L = 0.05mH, RG = 25, IAS = 110A, VGS =10V. Part not recommended for use above this value.  ISD 110A, di/dt 1520A/µs, VDD V(BR)DSS, TJ  175°C. 

-  Pulse width 400µs; duty cycle  2%. 

-  Coss eff. (TR) is a fixed capacitance that gives the same charging time as Coss while VDS is rising from 0 to 80% VDSS. 

-  Coss eff. (ER) is a fixed capacitance that gives the same energy as Coss while VDS is rising from 0 to 80% VDSS. 

-  When mounted on 1" square PCB (FR-4 or G-10 Material). For recommended footprint and soldering techniques refer to application note #AN-994 

-  R is measured at TJ approximately 90°C. 

- RJC value shown is at time zero. 

2 

2015-11-6 

AUIRLS4030-7P ~~La~~ 

## ~~Cafineon~~ 

**==> picture [206 x 195] intentionally omitted <==**

**----- Start of picture text -----**<br>
1000<br>VGS<br>TOP           10V<br>5.0V<br>4.5V<br>4.0V<br>3.5V<br>3.0V<br>100 2.7V<br>BOTTOM 2.5V<br>10<br>2.5V<br>60µs PULSE WIDTH<br>Tj = 25°C<br>1<br>0.1 1 10 100 1000<br>VDS, Drain-to-Source Voltage (V)<br>ID, Drain-to-Source Current (A)<br>**----- End of picture text -----**<br>


**Fig. 1** Typical Output Characteristics 

**==> picture [212 x 427] intentionally omitted <==**

**----- Start of picture text -----**<br>
1000<br>T J  = 175°C<br>100<br>aa<br>10 TJ = 25°C<br>1<br>VDS = 25V<br>60µs PULSE WIDTH<br>0.1 TE<br>1 2 3 4 5<br>VGS, Gate-to-Source Voltage (V)<br>Fig. 3  Typical Transfer Characteristics<br>100000<br>VGS   = 0V,       f = 1 MHZ<br>Ciss    = C gs + Cgd,  C ds SHORTED<br>C rss    = C gd<br>Coss   = Cds + Cgd<br>10000 C iss<br>ia ry<br>Coss<br>1000<br>Ty Crss<br>100 A ail<br>1 10 100 1000<br>VDS, Drain-to-Source Voltage (V)<br>ID, Drain-to-Source Current (A)<br>C, Capacitance (pF)<br>**----- End of picture text -----**<br>


**Fig 5.** Typical Capacitance vs. Drain-to-Source Voltage 

**==> picture [210 x 665] intentionally omitted <==**

**----- Start of picture text -----**<br>
1000<br>VGS<br>TOP           10V<br>5.0V<br>4.5V<br>4.0V<br>3.5V<br>3.0V<br>2.7V<br>BOTTOM 2.5V<br>100<br>2.5V<br>60µs PULSE WIDTH<br>Tj = 175°C<br>10<br>0.1 ii 1 itech 10 100 1000<br>VDS, Drain-to-Source Voltage (V)<br>Fig. 2  Typical Output Characteristics<br>3.0<br>I D  = 110A<br>VGS = 10V<br>2.5<br>oT,<br>2.0<br>1.5<br>1.0<br>Cee<br>0.5<br>-60 -40 -20 0 20 40 60 80 100 120 140160 180<br>TJ , Junction Temperature (°C)<br>Fig. 4  Normalized On-Resistance vs. Temperature<br>5.0<br>ID= 110A VDS= 80V<br>4.0 V DS = 50V<br>3.0 Hoa==e4nSY<br>2.0<br>1.0 et<br>ACCC<br>0.0<br>0 20 40 60 80 100 120<br> QG,  Total Gate Charge (nC)<br>ID, Drain-to-Source Current (A)<br>VGS, Gate-to-Source Voltage (V)<br>RDS(on) , Drain-to-Source On Resistance                        (Normalized)<br>**----- End of picture text -----**<br>


**Fig. 2** Typical Output Characteristics 

**Fig. 4** Normalized On-Resistance vs. Temperature 

**Fig 6.** Typical Gate Charge vs. Gate-to-Source Voltage 

3 

2015-11-6 

AUIRLS4030-7P ~~__L_LL~~ 

## ~~Cinfineon~~ 

**==> picture [209 x 437] intentionally omitted <==**

**----- Start of picture text -----**<br>
1000<br>TJ = 175°C<br>=<br>100<br>10 if T J  = 25°C<br>1<br>V GS  = 0V<br>(<br>0.1<br>0.0 0.5 1.0 1.5 2.0<br>VSD, Source-to-Drain Voltage (V)<br>Fig. 7  Typical Source-to-Drain Diode<br> Forward Voltage<br>200<br>180<br>160<br>SS<br>140 i Sa<br>120<br>SSNS<br>100<br>PF | | TN |<br>80<br>oT<br>60<br>40<br>20 a<br>IIo<br>0<br>25 50 75 100 125 150 175<br> TC , Case Temperature (°C)<br>ISD, Reverse Drain Current (A)<br>ID,  Drain Current (A)<br>**----- End of picture text -----**<br>


**Fig 9.** Maximum Drain Current vs. Case Temperature 

**==> picture [200 x 198] intentionally omitted <==**

**----- Start of picture text -----**<br>
4.0<br>3.5<br>3.0<br>2.5<br>2.0<br>1.5<br>1.0<br>0.5<br>0.0<br>-20 0 20 40 60 80 100 120<br>VDS, Drain-to-Source Voltage (V)<br>Energy (µJ)<br>**----- End of picture text -----**<br>


**Fig 11.** Typical COSS Stored Energy 

**==> picture [207 x 432] intentionally omitted <==**

**----- Start of picture text -----**<br>
10000<br>OPERATION IN THIS AREA<br>LIMITED BY R DS(on)<br>1000<br>EEnenee<br>100µsec<br>100<br>ct SE<br>1msec<br>10msec<br>10<br>DC<br>1 Tc = 25°C<br>Tj = 175°C<br>Single Pulse<br>0.1 aa<br>1 10 100 1000<br>VDS, Drain-to-Source Voltage (V)<br>Fig 8.   Maximum Safe Operating Area<br>125<br>Id = 5mA<br>120<br>CE<br>115 LLEL BRERA  Ee ZARaE<br>110<br>a AO<br>105<br>ECE<br>LEE<br>100<br>WV<br>95 AEE<br>-60 -40 -20 0 20 40 60 80 100 120 140160 180<br>TJ , Temperature ( °C )<br>ID,  Drain-to-Source Current (A)<br>V(BR)DSS, Drain-to-Source Breakdown Voltage (V)<br>**----- End of picture text -----**<br>


**Fig 8.** Maximum Safe Operating Area 

**Fig 10.** Drain-to-Source Breakdown Voltage 

**==> picture [204 x 196] intentionally omitted <==**

**----- Start of picture text -----**<br>
1400<br>ID<br>GERRRaE<br>1200 TOP         12A<br>16A<br>1000 BOTTOM 110A<br>N<br>800<br>600<br>NT<br>400 PNA EEE<br>200<br>SSS<br>| PSL<br>0<br>25 50 75 100 125 150 175<br>Starting TJ , Junction Temperature (°C)<br>EAS , Single Pulse Avalanche Energy (mJ)<br>**----- End of picture text -----**<br>


**Fig 12.** Maximum Avalanche Energy vs. Drain Current 

2015-11-6 

4 

~~Cinfin eon~~ 

AUIRLS4030-7P ~~__L_LL~~ 

**==> picture [496 x 690] intentionally omitted <==**

**----- Start of picture text -----**<br>
1<br>TM LT<br>D = 0.50<br>0.1<br>0.20<br>0.01 Sgn 0.020.100.05 geese Se  J  J 1  1 R  1 R 1  2 R2 2 R 2  CC Ri (°C/W)  0.176  aa  0.000343  I (sec)<br>0.01 Ci= Ci= i RiiRi 0.227  0.006073<br>0.001 Sieail TOCTWILL<br>SINGLE PULSE Notes:<br>( THERMAL RESPONSE ) 1. Duty Factor D = t1/t2<br>2. Peak Tj = P dm x Zthjc + Tc<br>eu HEEEE<br>0.0001<br>1E-006 1E-005 0.0001 0.001 0.01 0.1<br>t1 , Rectangular Pulse Duration (sec)<br>Fig 13.   Maximum Effective Transient Thermal Impedance, Junction-to-Case<br>1000<br>Duty Cycle = Single Pulse<br>Allowed avalanche Current vs avalanche<br>100 eel | | HIS pulsewidth, tav, assuming  Tj  = 150 TL °C and<br>0.01 Tstart =25°C (Single Pulse)<br>Ra 0.05 TT 7 |!a<br>10 0.10<br>inet Si<br>1<br>Allowed avalanche Current vs avalanche<br>pulsewidth, tav, assuming   j = 25°C and<br>Tstart = 150°C.<br>aan<br>0.1 AL<br>1.0E-06 1.0E-05 1.0E-04 1.0E-03 1.0E-02 1.0E-01<br>tav (sec)<br>Fig 14.    Avalanche Current vs. Pulse width<br>400 Notes on Repetitive Avalanche Curves , Figures 14, 15:<br>TOP          Single Pulse                 (For further info, see AN-1005 at www.infineon.com)<br>BOTTOM   1.0% Duty Cycle<br>1. Avalanche failures assumption:<br>ID = 110A Purely a thermal phenomenon and failure occurs at a temperature far in<br>300<br>excess of Tjmax. This is validated for every part type.<br>2. Safe operation in Avalanche is allowed as long as Tjmaxjmax is not exceeded.<br>3.  Equation below based on circuit and waveforms shown in Figures 18a, 18b.<br>200 NNT 4.  PD (ave) = Average power dissipation per single avalanche pulse.<br>5.  BV = Rated breakdown voltage (1.3 factor accounts for voltage increase<br>during avalanche).<br>6.  Iav = Allowable avalanche current.<br>PN<br>100 7.  T = Allowable rise in junction temperature, not to exceedT = Allowable rise in junction temperature, not to exceed = Allowable rise in junction temperature, not to exceedAllowable rise in junction temperature, not to exceed Tjmax jmax (assumed as<br>25°C in Figure 13, 14).<br>Bate<br>tav = Average time in avalanche.<br>LEN D = Duty cycle in avalanche =  tav ·f<br>0<br>ZthJC(D, tav) = Transient thermal resistance, see Figures 13)<br>25 50 75 100 125 150 175<br>Starting TJ , Junction Temperature (°C) PD (ave) = 1/2 ( 1.3·BV·Iav) = D (ave) = 1/2 ( 1.3·BV·Iav) =  = 1/2 ( 1.3·BV·Iav) = av) = ) =   T/ ZthJCthJC<br>EAR , Avalanche Energy (mJ)<br>Thermal Response ( Z  thJC ) °C/W<br>Avalanche Current (A)<br>**----- End of picture text -----**<br>


   - Purely a thermal phenomenon and failure occurs at a temperature far in 

2. Safe operation in Avalanche is allowed as long as Tjmaxjmax is not exceeded. 

3.  Equation below based on circuit and waveforms shown in Figures 18a, 18b. 

5.  BV = Rated breakdown voltage (1.3 factor accounts for voltage increase during avalanche). 

7. T = Allowable rise in junction temperature, not to exceedT = Allowable rise in junction temperature, not to exceed = Allowable rise in junction temperature, not to exceedAllowable rise in junction temperature, not to exceed Tjmax jmax (assumed as 25°C in Figure 13, 14). 

**PD (ave) = 1/2 ( 1.3·BV·Iav) = D (ave) = 1/2 ( 1.3·BV·Iav) =  = 1/2 ( 1.3·BV·Iav) = av) = ) =**  **T/ ZthJCthJC Iav = 2**  **T/ [1.3·BV·Zth]** 

**EAS (AR) = PD (ave)·tav** 

**Fig 15.** Maximum Avalanche Energy vs. Temperature 

5 ~~=~~ 

~~°°”~~ »°»°»°@-&0.0 

2015-11-6 

AUIRLS4030-7P ~~a~~ 

## ~~Cinfineon~~ 

**==> picture [206 x 425] intentionally omitted <==**

**----- Start of picture text -----**<br>
3.0<br>2.5<br>PET<br>2.0<br>PEST<br>1.5<br>ID = 250µA<br>SBS<br>I D  = 1.0mA<br>1.0 ID = 1.0A<br>PRS<br>0.5<br>LEELELIN<br>0.0<br>-75 -50 -25 0 25 50 75 100 125 150 175<br>TJ , Temperature ( °C )<br>Fig 16.   Threshold Voltage vs. Temperature<br>30<br>IF = 110A<br>25 V R = 85V<br>TJ = 25°C<br>20 T J = 125°C<br>15 | -CEP|e<br>A<br>10<br>par |<br>5<br>At tt<br>0<br>0 -t 200 400 it 600 ft 800 1000<br>diF /dt (A/µs)<br>VGS(th), Gate threshold Voltage (V)<br>IRRM (A)<br>**----- End of picture text -----**<br>


**Fig 16.** Threshold Voltage vs. Temperature 

**==> picture [207 x 431] intentionally omitted <==**

**----- Start of picture text -----**<br>
30<br>IF = 75A<br>25 V R = 85V<br>| |e<br>TJ = 25°C<br>20 T J = 125°C<br>ae<br>15<br>ea<br>10<br>ee<br>5 Aet| | |<br>0 | fy<br>0 200 400 600 800 1000<br>diF /dt (A/µs)<br>Fig. 17  - Typical Recovery Current vs. diff/dt<br>1400<br>IF = 75A<br>1200 V R  = 85V<br>TJ = 25°C<br>1000 TJ = 125°C<br>800 | PeeTT<br>bey<br>600<br>400<br>mean<br>Eo<br>200<br>0<br>eT ELT<br>0 200 400 600 800 1000<br>diF /dt (A/µs)<br>IRRM (A)<br>QRR (nC)<br>**----- End of picture text -----**<br>


**Fig. 17** - Typical Recovery Current vs. diff/dt 

**Fig. 18** - Typical Recovery Current vs. dif/dt 

**Fig. 19** - Typical Stored Charge vs. dif/dt 

**==> picture [206 x 196] intentionally omitted <==**

**----- Start of picture text -----**<br>
1600<br>IF = 110A |<br>1400 |<br>VR = 85V<br>1200 T J = 25°C |<br>TJ = 125°C<br>|,<br>1000<br>800<br>600 P| arava<br>400 | [feet] eAfT<br>oe<br>200 |<br>pT<br>0 | |<br>0 200 400 600 800 1000<br>diF /dt (A/µs)<br>QRR (nC)<br>**----- End of picture text -----**<br>


**Fig. 20** - Typical Stored Charge vs. dif/dt 

6 ~~=~~ 

2015-11-6 

~~Cinfir~~ 

AUIRLS4030-7P ~~_~~ 

**Fig 21.** Peak Diode Recovery dv/dt Test Circuit for N-Channel HEXFET® Power MOSFETs 

**==> picture [175 x 108] intentionally omitted <==**

**----- Start of picture text -----**<br>
15V<br>L DRIVER<br>VDS<br>R G D.U.T +<br>- [V][DD]<br>20V JL IAS<br>ae tp Y 0.01<br>**----- End of picture text -----**<br>


**Fig 22a.** Unclamped Inductive Test Circuit 

**==> picture [112 x 26] intentionally omitted <==**

**----- Start of picture text -----**<br>
V(BR)DSS<br>tp ><br>**----- End of picture text -----**<br>


**==> picture [18 x 9] intentionally omitted <==**

**----- Start of picture text -----**<br>
IAS<br>**----- End of picture text -----**<br>


**Fig 22b.** Unclamped Inductive Waveforms 

**Fig 23a.** Switching Time Test Circuit 

**Fig 23b.** Switching Time Waveforms 

**==> picture [188 x 128] intentionally omitted <==**

**----- Start of picture text -----**<br>
Vds Hi Id<br>Vgs<br>I<br>|<br>Vgs(th) !! ['] t<br>i t<br>A :<br>Qgs1 Qgs2 Qgd Qgodr<br>**----- End of picture text -----**<br>


**Fig 24a.** Gate Charge Test Circuit 

**Fig 24b.** Gate Charge Waveform 

2015-11-6 

7 

AUIRLS4030-7P ~~__L_LL~~ 

## ~~Cinfin eon~~ 

## **D[2] Pak - 7 Pin Package Outline** (Dimensions are shown in millimeters (inches)) 

## **D[2] Pak - 7 Pin Part Marking Information** 

**==> picture [331 x 148] intentionally omitted <==**

**----- Start of picture text -----**<br>
Part Number  AUIRLS4030-7<br>Date Code<br>IR Logo  T é4R YWWA  Y= Year<br>WW= Work Week<br><br>XX         XX<br>[|<br>Lot Code<br>**----- End of picture text -----**<br>


Note: For the most current drawing please refer to IR website at http://www.irf.com/package/ 

8 

2015-11-6 

AUIRLS4030-7P 

## D[2] Pak - 7 Pin Tape and Reel 

Note: For the most current drawing please refer to IR website at http://www.irf.com/package/ 

9 

2015-11-6 

AUIRLS4030-7P ~~“e_»&»«=«=5=$FDEee°°»~~ **Qualification Information** 

|**Qualification Information**|**Qualification Information**|||
|---|---|---|---|
|**Qualification Level**||Automotive<br>(per AEC-Q101)||
|||Comments: This part number(s) passed Automotive qualification. Infineon’s<br>Industrial and Consumer qualification level is granted by extension of the higher<br>Automotive level.||
|**Moisture Sensitivity Level**||D2-Pak 7 Pin|MSL1|
|**ESD**|Machine Model|Class M4 (+/- 800V)† <br>AEC-Q101-002||
||Human Body Model|Class H3A (+/- 6000V)† <br>AEC-Q101-001||
||Charged Device Model|Class C5 (+/- 2000V)† <br>AEC-Q101-005||
|**RoHS Compliant**||Yes||



- Highest passing voltage. 

## **Revision History** 

|**Date**|**Comments**|
|---|---|
|3/3/2014|<br>Added  "Logic Level Gate Drive" bullet in the features section on page 1<br><br>Updated data sheet with new IR corporate template|
|4/2/2014|<br>Updated package  outline and  part marking  on page 8 & 9<br><br>Updated typo on the fig.19 and fig.20,unit ofy-axis from "A" to "nC" onpage 6.|
|11/6/2015|<br>Updated datasheet with corporate template<br><br>Corrected orderingtable onpage 1.|



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

## **IMPORTANT NOTICE** 

The information given in this document shall in no event be regarded as a guarantee of conditions or characteristics (“Beschaffenheitsgarantie”). With respect to any examples, hints or any typical values stated herein and/or any information regarding the application of the product, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation warranties of non-infringement of intellectual property rights of any third party. 

In addition, any information given in this document is subject to customer’s compliance with its obligations stated in this document and any applicable legal requirements, norms and standards concerning customer’s products and any use of the product of Infineon Technologies in customer’s applications. 

The data contained in this document is exclusively intended for technically trained staff. It is the responsibility of customer’s technical departments to evaluate the suitability of the product for the intended application and the completeness of the product information given in this document with respect to such application. 

For further information on the product, technology, delivery terms and conditions and prices please contact your nearest Infineon Technologies office (www.infineon.com). 

## **WARNINGS** 

Due to technical requirements products may contain dangerous substances. For information on the types in question please contact your nearest Infineon Technologies office. 

Except as otherwise explicitly approved by Infineon Technologies in a written document signed by authorized representatives of Infineon Technologies, Infineon Technologies’ products may not be used in any applications where a failure of the product or any consequences of the use thereof can reasonably be expected to result in personal injury. 

10 

2015-11-6