BSC0924NDIATMA1

**BSC0924NDI** 

## **Dual N-Channel OptiMOS™ MOSFET** 

## **Product Summary** 

## **Features** 

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||||||||
|---|---|---|---|---|---|---|
|Q1|Q2|
|V|DS|30|30|V|
|R|DS(on),max|V|GS=10 V|5|3.7|mW|
|V|GS=4.5 V|7|5.2|
|I|D|40|40|A|

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- Dual N-channel OptiMOS™ MOSFET 

- Integrated monolithic Schottky-like diode 

- Optimized for high performance Buck converter • Logic level (4.5V rated) 

- 100% avalanche tested • Qualified according to JEDEC[1)] for target applications • Pb-free lead  plating; RoHS compliant • Halogen-free according to IEC61249-2-22 

VPhase 

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||||||||||
|---|---|---|---|---|---|---|---|---|
|Type|Package|Marking|
|BSC0924NDI|PG-TISON-8|0924NDI|
|——|||(vPhase)|i|
|Maximum ratings,|at|T|j=25 °C, unless otherwise specified|[2)]|
|Parameter|Symbol|Conditions|Value|Unit|
|Q1|Q2|
|Continuous drain current|I|D|T|C=70 °C, VGS=10V|40|40|A|
|T|A=25 °C, VGS=4.5V|[3)]|17|32|
|T|A=70 °C, VGS=4.5V|[3)]|14|25|
|e=e—|T|A=25 °C, VGS=10V|[4)]|10|13|
|Pulsed drain current|[5)]|I|D,pulse|T|C=70 °C|160|160|
|Q1:|I|D=20 A,|
|Avalanche energy, single pulse|E|AS|Q2:|I|D=20 A,|9|10|mJ|
|R|GS=25|W|
|Gate source voltage|V|GS|±20|V|
|Power dissipation|P|tot|T|A=25 °C|[2)]|2.5|2.5|W|
|T|A=25 °C, minimum|
|1.0|1.0|
|footprint|[3)]|
|Operating and storage temperature|T|j,|T|stg|-55 ... 150|°C|
|IEC climatic category; DIN IEC 68-1|55/150/56|

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- 1) J-STD20 and JESD22 

- 2) One transistor active 

- 3) Device on 40 mm x 40 mm x 1.5 mm epoxy PCB FR4 with 6 cm2 (one layer, 70 µm thick) copper area for drain connection. PCB is vertical in still air. 

- 4) Device mounted on a minimum pad (one layer, 70 µm thick). One transistor active 

- [See figure 3 for more detailed information.] 

- 5) 

Rev.2.0 

page 1 

2013-07-30 

|**BSC0924NDI**<br>**Parameter**<br>**Symbol Conditions**<br>**Unit**<br>**min.**<br>**typ.**<br>**max.**<br>**Values**<br>Cinfineon~~|~~|**BSC0924NDI**<br>**Parameter**<br>**Symbol Conditions**<br>**Unit**<br>**min.**<br>**typ.**<br>**max.**<br>**Values**<br>Cinfineon~~|~~|**BSC0924NDI**<br>**Parameter**<br>**Symbol Conditions**<br>**Unit**<br>**min.**<br>**typ.**<br>**max.**<br>**Values**<br>Cinfineon~~|~~|
|---|---|---|
|**Thermal characteristics**|||
|Thermal resistance, junction -|Q1 _R_thJC<br>-<br>-<br>4.2|K/W|
|case|Q2<br>-<br>-<br>3.4||
|Thermal resistance, junction -<br>ambient1)|Q1 _R_thJA<br>Q2<br>6 cm2cooling area2)<br>50<br>-<br>-||
||Q1<br>Q2<br>minimal footprint,<br>steady state3)<br>-<br>125<br>-||
|**Electrical characteristics,**at_T_j=25 °C, unless otherwise specified|||
|**Static characteristics**|||
|Drain-source breakdown voltage<br>Gate threshold voltage<br>Zero gate voltage drain current<br>Gate-source leakage current<br>Gate resistance<br>Transconductance<br>Breakdown voltage temperature<br>coefficient<br>Drain-source on-state<br>resistance|Q1<br>Q2<br>Q1<br>Q2<br>Q1<br>Q2<br>Q1 _I_DSS<br>-<br>-<br>1<br>Q2<br>-<br>-<br>500<br>Q1<br>-<br>-<br>0.1<br>Q2<br>-<br>3<br>-<br>Q1 _I_GSS<br>Q2<br>Q1 _R_DS(on)<br>-<br>5.4<br>7.0<br>Q2<br>-<br>4.2<br>5.2<br>Q1<br>-<br>3.8<br>5.0<br>Q2<br>-<br>2.8<br>3.7<br>Q1 _R_G<br>1.3<br>2.6<br>5.2<br>Q2<br>0.5<br>0.9<br>1.8<br>Q1 _g_fs<br>32<br>65<br>-<br>Q2<br>36<br>71<br>-<br>|_V_DS|>2|_I_D|_R_DS(on)max,<br>_I_D=20 A<br>_V_DS=24 V,_V_GS=0 V,<br>_T_j=25 °C<br>_V_DS=24 V,_V_GS=0 V,<br>_T_j=150 °C<br>15<br>-<br>100<br>2<br>1.2<br>-<br>-<br>_I_D=10 mA, referenced<br>to 25 °C<br>_V_GS=4.5 V,_I_D=20 A<br>_V_GS=10 V,_I_D=20 A<br>d_V_(BR)DSS<br>/d_T_j<br>-<br>-<br>30<br>-<br>_V_GS=20 V,_V_DS=0 V<br>-<br>_V_DS=_V_GS,_I_D=250 µA<br>_V_(BR)DSS _V_GS=0 V,_I_D=10 mA<br>_V_GS(th)<br>~~eeee~~<br>~~oe~~<br>~~y=~~<br>~~|~~<br>~~|TT~~<br>~~n~~~~**e**~~<br>~~oe e~~<br>~~e~~<br>~~yj | TT~~<br>~~SH of~~<br>~~fH [EEE~~<br>~~aoeeee~~<br>~~qo]~~|µA<br>mA<br>mW<br>W<br>S<br>V<br>mV/K<br>V<br>nA|



Rev.2.0 

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2013-07-30 

**BSC0924NDI** 

|**Parameter**|**Symbol **|**Conditions**<br>**Values**|**Unit**|
|---|---|---|---|
|||**min.**<br>**typ.**<br>**max.**||
|**Dynamic characteristics**||||
|Input capacitance<br>Output capacitance<br>Reverse transfer capacitance<br>Turn-on delay time<br>Rise time<br>Turn-off delay time<br>Fall time<br>**Gate Charge Characteristics**|Q1 _C_iss<br>Q2<br>Q1 _C_oss<br>Q2<br>Q1 Crss<br>Q2<br>Q1 _t_d(on)<br>Q2<br>Q1 _t_r<br>Q2<br>Q1 _t_d(off)<br>Q2<br>Q1 _t_f<br>Q2<br>~~a~~<br>~~|~~<br>~~a~~<br>~~|~~<br>~~4~~<br>~~|~~<br>~~4~~<br>~~|~~<br>~~4~~<br>~~|~~<br>~~4~~<br>~~|~~<br>~~4~~<br>~~|~~|-<br>870<br>1160<br>-<br>1100<br>1470<br>-<br>330<br>439<br>-<br>460<br>612<br>-<br>49<br>-<br>-<br>64<br>-<br>-<br>4.7<br>-<br>3.3<br>-<br>-<br>3.8<br>-<br>-<br>2.8<br>-<br>-<br>17<br>-<br>-<br>15<br>-<br>-<br>3.0<br>-<br>-<br>2.2<br>-<br>_V_GS=0 V,<br>_V_DS= 15 V,_f_=1 MHz<br>_V_DD=15 V,<br>_V_GS=10 V,_R_G=1.6W,<br>_I_D=20 A<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Pt~~<br>~~Pt ~~~~**|**~~<br>~~Ft~~|pF<br>ns|
|Gate to source charge<br>Gate to drain charge<br>Gate charge total<br>Gate plateau voltage<br>Gate to source charge<br>Gate to drain charge<br>Gate charge total|Q1 _Q_gs<br>-<br>2.4<br>3.2<br>_Q_gd<br>-<br>2.2<br>2.9<br>_Q_g<br>-<br>6.7<br>10<br>_V_plateau<br>-<br>2.8<br>-<br>Q2 _Q_gs<br>-<br>2.9<br>3.9<br>_Q_gd<br>-<br>2.9<br>3.8<br>_Q_g<br>8.5<br>12.8<br>_V_DD=15 V,<br>_I_D=30 A,<br>_V_GS=0 to 4.5 V<br>~~|~~<br>~~PF tf|~~<br>~~|~~<br>~~Pt |~~<br>~~|~~<br>~~Pt |~~<br>~~|~~<br>~~Pt |~~<br>~~|~~<br>~~|~~<br>~~|~~<br>~~**P**t |~~<br>~~|~~<br>~~|~~||nC<br>V<br>nC<br>~~|~~|
|Gate plateau voltage<br>Output charge|_V_plateau<br>Q1 _Q_oss<br>Q2<br>~~+~~<br>~~oe~~|2.7<br>-<br>9<br>12<br>-<br>12<br>16<br>_V_DD=15 V,_V_GS=0 V<br>~~=~~|V<br>nC|



Rev.2.0 

page 3 

2013-07-30 

**BSC0924NDI Parameter Symbol Conditions Values Unit min. typ. max. Reverse Diode** Diode continuous forward current Q1 _I_ S - - 30 A Q2 40 _T_ C=25 °C Diode pulse current Q1 _I_ S,pulse - - 160 Q2 - - 160 Diode forward voltage Q1 _V_ SD _V_ GS=0 V, _I_ F=20 A, - 0.86 1 V _T_ =25 °C j Q2 _V_ GS=0 V, _I_ F=3 A, - 0.56 0.7 _T_ =25 °C j Reverse recovery charge Q1 _Q_ rr _V_ R=15 V, _I_ F= _I_ S, - 5 - nC Q2 d _i_ F/d _t_ =100 A/µs - 5 - ~~SHE~~ 2) Device on 40 mm x 40 mm x 1.5 mm epoxy PCB FR4 with 6 cm2 (one layer, 70 µm thick) copper area for drain connection. PCB is vertical in still air. 3) device mounted on a minimum pad (one layer, 70 µm thick) 

Rev.2.0 

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2013-07-30 

**BSC0924NDI** 

## **1 Power dissipation (Q1)** 

_P_ tot=f( _T_ A)[3)] 

## **2 Power dissipation (Q2)** _P_ tot=f( _T_ A)[3)] 

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1.2  1.2<br>1  1<br>0.8  0.8<br>0.6  0.6<br>0.4  0.4<br>0.2  0.2<br>0  0<br>0  40  80  120  160  0  40  80  120  160<br>T A [°C]  T A [°C]<br> [W]   [W]<br>tot tot<br>P P<br>**----- End of picture text -----**<br>


## **3 Drain current (Q1)** 

_I_ D=f( _T_ C) parameter: _V_ GS≥10 V 

## **4 Drain current (Q2)** 

_I_ D=f( _T_ C) 

parameter: _V_ GS≥10 V 

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50  50<br>40  40<br>30  30<br>20  20<br>10  10<br>0  0<br>0  40  80  120  160  0  40  80  120  160<br>T C [°C]  T C [°C]<br> [A]   [A]<br>I D I D<br>**----- End of picture text -----**<br>


Rev.2.0 

2013-07-30 

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**BSC0924NDI** 

## **5 Safe operating area (Q1)** 

_I_ D=f( _V_ DS); _T_ C=25 °C; _D_ =0 parameter: _t_ p 

## **6 Safe operating area (Q2)** 

_I_ D=f( _V_ DS); _T_ C=25 °C; _D_ =0 parameter: _t_ p 

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10 [3 ] 10 [3 ]<br>1 µs<br>10 [2 ] 10 [2 ] 1 µs<br>10 µs<br>10 µs<br>100 µs<br>100 µs<br>1 ms<br>1 ms<br>10 [1 ] 10 [1 ]<br>10 ms<br>10 ms<br>DC  DC<br>10 [0 ] 10 [0 ]<br>10 [-1 ] 10 [-1 ]<br>10 [-1 ] 10 [0 ] 10 [1 ] 10 [2 ] 10 [-1 ] 10 [0 ] 10 [1 ] 10 [2 ]<br>V DS [V]  V DS [V]<br>[A]   [A]<br>I D I D<br>**----- End of picture text -----**<br>


## **7 Max. transient thermal impedance (Q1)** 

_Z_ thJC=f( _t_ p) 

parameter: _D_ = _t_ p/ _T_ 

## **8 Max. transient thermal impedance (Q2)** 

_Z_ thJC=f( _t_ p) 

parameter: _D_ = _t_ p/ _T_ 

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10 [1 ] 10 [1 ]<br>0.5<br>0.5  10 [0 ] 0.2<br>0.1<br>0.2<br>10 [0 ] 0.05<br>0.02<br>0.1<br>0.05  0.01<br>10 [-1 ]<br>0.02  single pulse<br>0.01<br>single pulse<br>10 [-1 ] 10 [-2 ]<br>10 [-5 ] 10 [-4 ] 10 [-3 ] 10 [-2 ] 10 [-1 ] 10 [0 ] 10 [-5 ] 10 [-4 ] 10 [-3 ] 10 [-2 ] 10 [-1 ] 10 [0 ]<br>t p [s]  t p [s]<br> [K/W]   [K/W]<br>thJC thJC<br>Z Z<br>**----- End of picture text -----**<br>


Rev.2.0 

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2013-07-30 

**BSC0924NDI** 

## **9 Typ. output characteristics (Q1)** 

_I_ D=f( _V_ DS); _T_ j=25 °C parameter: _V_ GS 

## **10 Typ. output characteristics (Q2)** 

_I_ D=f( _V_ DS); _T_ j=25 °C 

parameter: _V_ GS 

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160<br>10 V  4.5 V<br>120  4 V<br>3.5 V<br>80<br>3.3 V<br>3 V<br>40<br>2.8 V<br>0<br>0  1  2  3<br>V DS [V]<br> [A]<br>I D<br>**----- End of picture text -----**<br>


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400<br>10 V<br>300<br>4.5 V<br>4 V<br>200<br>3.5 V<br>100<br>3.3 V<br>3 V<br>2.8 V<br>0<br>0  1  2  3<br>V DS [V]<br> [A]<br>I D<br>**----- End of picture text -----**<br>


## **11 Typ. drain-source on resistance (Q1)** 

_R_ DS(on)=f( _I_ D); _T_ j=25 °C 

parameter: _V_ GS 

## **12 Typ. drain-source on resistance (Q2)** 

_R_ DS(on)=f( _I_ D); _T_ j=25 °C parameter: _V_ GS 

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15  10<br>3 V<br>12  8<br>3.3 V<br>3 V  3.3 V  3.5 V<br>3.5 V<br>9  6<br>4 V<br>4 V  4.5 V<br>6  4.5 V  4  5 V<br>5 V<br>10 V<br>10 V<br>3  2<br>0  0<br>0  20  40  60  80  0  20  40  60  80<br>I D [A]  I D [A]<br>]  ]<br>W W<br> [m  [m<br>DS(on) DS(on)<br>R R<br>**----- End of picture text -----**<br>


Rev.2.0 

2013-07-30 

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**BSC0924NDI** 

## **13 Typ. transfer characteristics (Q1)** 

## **14 Typ. transfer characteristics (Q2)** 

_I_ D=f(=f( _V_ GS); ); | _V_ DS |>2 | |>2 | _I_ D| | _R_ DS(on)max parameter: _T_ j 

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I  D=f(=f( V  GS); );  | V  DS |>2 | |>2 |  I  D| |  R  DS(on)max I  D=f( V  GS);  |V  DS |>2 |  I  D | R  DS(on)max<br>parameter:  T  j parameter:  T  j<br>160  160<br>120  120<br>80  80<br>40  40<br>150 °C<br>25 °C  25 °C<br>150 °C<br>AL<br>0  0<br>0  1  2  3  4  0  1  2  3  4<br>V GS [V]  V GS [V]<br>15 Drain-source on-state resistance (Q1) 16 Drain-source on-state resistance (Q2)<br>R  DS(on)=f( T  j);  I  D=20 A;  V  GS=10 V R  DS(on)=f( T  j);  I  D=20 A;  V  GS=10 V<br>9  5<br>8<br>4<br>7<br>6<br>typ<br>3<br>5<br>typ<br>4<br>2<br>3<br>2<br>1<br>1<br>0  0<br>-60  -20  20  60  100  140  180  -60  -20  20  60  100  140  180<br>T j [°C]  T j [°C]<br> [A]   [A]<br>I D I D<br>]  ]<br>W W<br>[m  [m<br>DS(on) DS(on)<br>R R<br>**----- End of picture text -----**<br>


Rev.2.0 

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**BSC0924NDI** 

## **17 Typ. gate threshold voltage (Q1)** 

_V_ GS(th)=f( _T_ j); _V_ GS= _V_ DS; _I_ D=250 µA 

## **18 Typ. gate threshold voltage (Q2)** 

_V_ GS(th)=f( _T_ j); _V_ GS= _V_ DS; _I_ D=10 mA 

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2.8  2.8<br>2.4  2.4<br>2  2<br>1.6  1.6<br>1.2  1.2<br>0.8  0.8<br>0.4  0.4<br>0  0<br>-60  -20  20  60  100  140  180  -60  -20  20  60  100  140  180<br>T j [°C]  T j [°C]<br> [V]   [V]<br>GS(th) GS(th)<br>V V<br>**----- End of picture text -----**<br>


## **19 Typ. capacitances (Q1)** 

_C_ =f( _V_ DS); _V_ GS=0 V; _f_ =1 MHz 

## **20 Typ. capacitances (Q2)** 

_C_ =f( _V_ DS); _V_ GS=0 V; _f_ =1 MHz 

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10 [4 ] 10 [4 ]<br>10 [3 ] Ciss  10 [3 ] Ciss<br>Coss<br>Coss<br>10 [2 ] 10 [2 ]<br>Crss<br>Crss<br>mi a ] [ r t<br>10 [1 ] 10 [1 ]<br>0  10  20  30  0  10  20  30<br>V DS [V]  V DS [V]<br> [pF]   [pF]<br>C C<br>**----- End of picture text -----**<br>


Rev.2.0 

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**BSC0924NDI** 

## **21 Forward characteristics of reverse diode (Q1)** 

_I_ F=f( _V_ SD) parameter: _T_ j 

## **22 Forward characteristics of reverse diode (Q2)** _I_ F=f( _V_ SD) 

parameter: _T_ j 

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10 [3 ] 10 [3 ]<br>150 °C<br>10 [2 ] 10 [2 ]<br>25 °C<br>150 °C  25 °C<br>100 °C  -55 °C<br>10 [1 ] 10 [1 ]<br>10 [0 ] 10 [0 ]<br>10 [-1 ] 10 [-1 ]<br>0  0.2  0.4  0.6  0.8  1  1.2  0  0.2  0.4  0.6  0.8  1<br>V SD [V]  V SD [V]<br>23 Avalanche characteristics (Q1) 24 Avalanche characteristics (Q2)<br>=f( t  AV); );  R  GS=25 W=25 WW I  AS=f( t  AV);  R  GS=25 W<br>parameter:  T  j(start) parameter:  T  j(start)<br>10 [2 ] 10 [2 ]<br>25 °C<br>10 [1 ] 10 [1 ]<br>25 °C<br>100 °C  100 °C<br>125 °C  125 °C<br>10 [0 ] WA 10 [0 ]<br>10 [0 ] 10 [1 ] 10 [2 ] 10 [3 ] 10 [0 ] 10 [1 ] 10 [2 ] 10 [3 ]<br>t AV [µs]  t AV [µs]<br>page 10 2013-07-30<br> [A]   [A]<br>I F I F<br> [A]   [A]<br>I AV I AV<br>**----- End of picture text -----**<br>


## **23 Avalanche characteristics (Q1)** 

_I_ AS=f( _t_ AV); ); _R_ GS=25 W=25 WW parameter: _T_ j(start) 

Rev.2.0 

**BSC0924NDI** 

## **25 Typ. gate charge (Q1)** 

_V_ GS=f( _Q_ gate); _I_ D=20 A pulsed parameter: _V_ DD 

## **26 Typ. gate charge (Q2)** 

_V_ GS=f( _Q_ gate); _I_ D=20 A pulsed parameter: _V_ DD 

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10  10<br>15 V<br>fp<br>8  8<br>15 V  6 V<br>6 V  24 V<br>24 V<br>6  6<br>y ff<br>4  4<br>2  2<br>math (A=<br>0  0<br>0  2  4  6  8  10  12  14  0  12  24<br>Q gate [nC]  Q gate [nC]<br>27 Drain-source breakdown voltage (Q1) 28 Typ. drain-source leakage current (Q2)<br> BR(DSS)=f(=f( T  j); );  I  D=1 mA=1 mA I  DSS=f( V DS  );  V  GS=0 V<br>parameter:  T  j<br>35  10 [-2 ]<br>34<br>33<br>10 [-3 ] ii<br>32<br>31  125 °C<br>30  10 [-4 ]<br>100 °C<br>29<br>75 °C<br>28<br>10 [-5 ]<br>27<br>25 °C<br>26<br>cor r<br>25  10 [-6 ]<br>-60  -20  20  60  100  140  180  0  5  10  15  20  25<br>T j [°C]  V DSj [V]<br> [V]   [V]<br>GS GS<br>V V<br> [V]<br> [A]<br>BR(DSS) I DSS<br>V<br>**----- End of picture text -----**<br>


## **27 Drain-source breakdown voltage (Q1)** 

_V_ BR(DSS)=f(=f( _T_ j); ); _I_ D=1 mA=1 mA 

Rev.2.0 

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**BSC0924NDI** 

## **PG-TISON** 

Rev.2.0 

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**BSC0924NDI** 

## **PG-TISON** 

Rev.2.0 

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**BSC0924NDI** 

**Published by Infineon Technologies AG 81726 Munich, Germany © 2012 Infineon Technologies AG All Rights Reserved.** 

## **Legal Disclaimer** 

The information given in this document shall in no event be regarded as a guarantee of conditions or characteristics. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, 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. 

## **Information** 

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

## **Warnings** 

Due to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office. Infineon Technologies components may be used in life-support devices 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 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.2.0 

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