TLE42744DV50ATMA1 - INFINEON TECHNOLOGIES AG

Automotive Power

Data Sheet

Rev. 1.3, 2018-03-05

TLE42744

Low Dropout Linear Voltage Regulator

TLE42744DV50

TLE42744GV50

TLE42744EV50

TLE42744GV33

TLE42744DV33

TLE42744GSV33

TLE42744

Type Package Marking

TLE42744DV50 PG-TO252-3 42744V5

TLE42744GV50 PG-TO263-3 42744V5

TLE42744EV50 PG-SSOP-14 exposed pad 42744V5

TLE42744DV33 PG-TO252-3 4274433

TLE42744GV33 PG-TO263-3 42744V33

TLE42744GSV33 PG-SOT223-4 427443

Data Sheet 2 Rev. 1.3, 2018-03-05

PG-TO252-3

PG-TO263-3

PG-SSOP-14 exposed pad

PG-SOT223-4

Low Dropout Linear Voltage Regulator

1Overview

Features

• Very Low Current Consumption

• Output Voltages 5 V and 3.3 V ±2%

• Output Current up to 400 mA

• Very Low Dropout Voltage

• Output Current Limitation

• Reverse Polarity Protection

• Overtemperature Shutdown

• Wide Temperature Range

From -40 °C up to 150 °C

• Green Product (RoHS compliant)

• AEC Qualified

Description

The TLE42744 is a monolithic integrated low dropout voltage regulator for load currents up to 400 mA. An input

voltage up to 40 V is regulated to VQ,nom = 5 V / 3.3 V with a precision of ±2%. The device is designed for the harsh

environment of automotive applications. Therefore it is protected against overload, short circuit and

overtemperature conditions by the implemented output current limitation and the overtemperature shutdown

circuit. The TLE42744 can be also used in all other applications requiring a stabilized 5 V / 3.3 V voltage.

Due to its very low quiescent current the TLE42744 is dedicated for use in applications permanently connected to

VBAT.

TLE42744

Block Diagram

Data Sheet 3 Rev. 1.3, 2018-03-05

2 Block Diagram

Figure 1 Block Diagram

AEB01959

GND

Bandgap

Reference

Control

Amplifier

Sensor

Temperature

Buffer

Saturation

Control and

Protection

Circuit

Data Sheet 4 Rev. 1.3, 2018-03-05

TLE42744

Pin Configuration

3 Pin Configuration

3.1 Pin Assignment PG-TO252-3, PG-TO263-3 and PG-SOT223-4

Figure 2 Pin Configuration (top view)

3.2 Pin Definitions and Functions PG-TO252-3, PG-TO263-3 and PG-SOT223-4

Pin No. Symbol Function

1IInput

block to ground directly at the IC with a ceramic capacitor

2GNDGround

internally connected to heat slug

3QOutput

block to ground with a capacitor close to the IC terminals, respecting the values given

for its capacitance and ESR in “Functional Range” on Page 6

4 / Heat Slug – Heat Slug

internally connected to GND;

connect to GND and heatsink area

AEP02561

ΙQ

GND

AEP02281

PinConfig_PG-SOT223-

4.vsd

123

IGND

GND

TLE42744

Pin Configuration

Data Sheet 5 Rev. 1.3, 2018-03-05

3.3 Pin Assignment PG-SSOP-14 exposed pad

Figure 3 Pin Configuration (top view)

3.4 Pin Definitions and Functions PG-SSOP-14 exposed pad

Pin No. Symbol Function

1, 2, 3, 5, 6, 7 n.c. Not connected

can be open or connected to GND

4GNDGround

8, 10, 11, 12,

n.c. Not connected

can be open or connected to GND

9QOutput

block to ground with a capacitor close to the IC terminals, respecting the values given

for its capacitance and ESR in “Functional Range” on Page 6

13 I Input

block to ground directly at the IC with a ceramic capacitor

Pad – Exposed Pad

connect to GND and heatsink area

n.c.

GND

n.c.

TLE7274-2_PINCONFIG_SSOP-

14.SVG

Data Sheet 6 Rev. 1.3, 2018-03-05

TLE42744

General Product Characteristics

4 General Product Characteristics

4.1 Absolute Maximum Ratings

Notes

1. Stresses above the ones listed here may cause permanent damage to the device. Exposure to absolute

maximum rating conditions for extended periods may affect device reliability.

2. Integrated protection functions are designed to prevent IC destruction under fault conditions described in the

data sheet. Fault conditions are considered as “outside” normal operating range. Protection functions are not

designed for continuous repetitive operation.

4.2 Functional Range

Table 1 Absolute Maximum Ratings1)

Tj=-40 °C to 150 °C; all voltages with respect to ground, (unless otherwise specified)

1) not subject to production test, specified by design

Parameter Symbol Values Unit Note / Test Condition Number

Min. Typ. Max.

Input I

Voltage VI-42 – 45 V – P_4.1.1

Output Q

Voltage VQ-1 – 40 V – P_4.1.2

Temperature

Junction temperature Tj-40 – 150 °C – P_4.1.3

Storage temperature Tstg -50 – 150 °C – P_4.1.4

ESD Susceptibility

ESD Absorption VESD,HBM -4 – 4 kV Human Body Model

(HBM)2)

2) ESD susceptibility Human Body Model “HBM” according to AEC-Q100-002 - JESD22-A114

P_4.1.5

ESD Absorption VESD,CDM -1000 – 1000 V Charge Device Model

(CDM)3) at all pins

3) ESD susceptibility Charged Device Model “CDM” according to ESDA STM5.3.1

P_4.1.6

Table 2 Functional Range

Parameter Symbol Values Unit Note / Test Condition Number

Min. Typ. Max.

Input voltage VI5.5 – 40 V TLE42744DV50,

TLE42744GV50,

TLE42744EV50

P_4.2.1

Input voltage VI4.7 – 40 V TLE42744GV33,

TLE42744DV33,

TLE42744GSV33

P_4.2.2

 
 
TLE42744
General Product Characteristics
Data Sheet 7 Rev. 1.3, 2018-03-05
 
Note: Within the functional or operating range, the IC operates as described in the circuit description. The electrical 
characteristics are specified within the conditions given in the Electrical Characteristics table.
4.3 Thermal Resistance
Note: This thermal data was generated in accordance with JEDEC JESD51 standards. For more information, go 
to www.jedec.org.
Output Capacitor’s 
Requirements for Stability
CQ22 – µF 1) P_4.2.3
Output Capacitor’s 
Requirements for Stability
ESR(CQ)–32) P_4.2.4
Junction temperature Tj-40 150 °C – P_4.2.5
1) the minimum output capacitance requirement is applicable for a worst case capacitance tolerance of 30%
2) relevant ESR value at f=10kHz
Table 3 Thermal Resistance
Parameter Symbol Values Unit Note / Test Condition Number
Min. Typ. Max.
TLE42744DV50, TLE42744DV33 (PG-TO252-3)
Junction to Case1) RthJC – 3.6 – K/W measured to heat slug P_4.3.1
Junction to Ambient1) RthJA – 27 – K/W FR4 2s2p board2) P_4.3.2
Junction to Ambient1) RthJA – 115 – K/W FR4 1s0p board, 
footprint only3)
P_4.3.3
Junction to Ambient1) RthJA – 52 – K/W FR4 1s0p board, 
300 mm² heatsink 
area3)
P_4.3.4
Junction to Ambient1) RthJA – 40 – K/W FR4 1s0p board, 
600 mm² heatsink 
area3)
P_4.3.5
TLE42744GV50, TLE42744GV33 (PG-TO263-3)
Junction to Case1) RthJC – 3.6 – K/W measured to heat slug P_4.3.6
Junction to Ambient1) RthJA – 22 – K/W FR4 2s2p board2) P_4.3.7
Junction to Ambient1) RthJA – 74 – K/W FR4 1s0p board, 
footprint only3)
P_4.3.8
Junction to Ambient1) RthJA – 42 – K/W FR4 1s0p board, 
300 mm² heatsink 
area3)
P_4.3.9
Junction to Ambient1) RthJA – 34 – K/W FR4 1s0p board, 
600 mm² heatsink 
area3)
P_4.3.10
Table 2 Functional Range (cont’d)
Parameter Symbol Values Unit Note / Test Condition Number
Min. Typ. Max.

 
Data Sheet 8 Rev. 1.3, 2018-03-05
 
 
TLE42744
General Product Characteristics
TLE42744EV50 (PG-SSOP-14 exposed pad)
Junction to Case1) RthJC – 7 – K/W measured to exposed 
pad
P_4.3.11
Junction to Ambient1) RthJA – 43 – K/W FR4 2s2p board2) P_4.3.12
Junction to Ambient1) RthJA – 120 – K/W FR4 1s0p board, 
footprint only3)
P_4.3.13
Junction to Ambient1) RthJA – 59 – K/W FR4 1s0p board, 
300 mm² heatsink 
area3)
P_4.3.14
Junction to Ambient1) RthJA – 49 – K/W FR4 1s0p board, 
600 mm² heatsink 
area3)
P_4.3.15
TLE42744GSV33 (PG-SOT223-4)
Junction to Case1) RthJC – 17 – K/W measured to heat slug P_4.3.16
Junction to Ambient1) RthJA – 54 – K/W FR4 2s2p board2) P_4.3.17
Junction to Ambient1) RthJA – 139 – K/W FR4 1s0p board, 
footprint only3)
P_4.3.18
Junction to Ambient1) RthJA – 73 – K/W FR4 1s0p board, 
300 mm² heatsink 
area3)
P_4.3.19
Junction to Ambient1) RthJA – 64 – K/W FR4 1s0p board, 
600 mm² heatsink 
area3)
P_4.3.20
1) Not subject to production test, specified by design.
2) Specified RthJA value is according to Jedec JESD51-2,-5,-7 at natural convection on FR4 2s2p board; The Product 
(Chip+Package) was simulated on a 76.2 x 114.3 x 1.5 mm³ board with 2 inner copper layers (2 x 70µm Cu, 2 x 35µm Cu). 
Where applicable a thermal via array under the exposed pad contacted the first inner copper layer.
3) Specified RthJA value is according to Jedec JESD 51-3 at natural convection on FR4 1s0p board; The Product 
(Chip+Package) was simulated on a 76.2 × 114.3 × 1.5 mm3 board with 1 copper layer (1 x 70µm Cu).
Table 3 Thermal Resistance (cont’d)
Parameter Symbol Values Unit Note / Test Condition Number
Min. Typ. Max.

 
 
TLE42744
Electrical Characteristics
Data Sheet 9 Rev. 1.3, 2018-03-05
 
5 Electrical Characteristics
5.1 Electrical Characteristics Voltage Regulator
Table 4 Electrical Characteristics 
VI =13.5 V; Tj=-40 °C to 150 °C; all voltages with respect to ground (unless otherwise specified)
Parameter Symbol Values Unit Note / Test Condition Number
Min. Typ. Max.
Output Q
Output Voltage VQ4.9 5.0 5.1 V TLE42744DV50, 
TLE42744GV50, 
TLE42744EV50
5mA<IQ<400mA
6V<VI<28V
P_5.1.1
Output Voltage VQ4.9 5.0 5.1 V TLE42744DV50, 
TLE42744GV50, 
TLE42744EV50
5mA<IQ<200 mA
6V<VI<40V
P_5.1.2
Output Voltage VQ3.23 3.3 3.37 V TLE42744GV33, 
TLE42744DV33, 
TLE42744GSV33;
5mA<IQ<400mA
4.7 V < VI<28V
P_5.1.3
Output Voltage VQ3.23 3.3 3.37 V TLE42744GV33, 
TLE42744DV33, 
TLE42744GSV33;
5mA<IQ<200 mA
4.7 V < VI<40V
P_5.1.4
Dropout Voltage Vdr – 250 500 mV TLE42744DV50, 
TLE42744GV50, 
TLE42744EV50
IQ= 250 mA
Vdr =VI–VQ1)
P_5.1.5
Load Regulation VQ, lo – 20 50 mV TLE42744DV50, 
TLE42744GV50, 
TLE42744EV50;
IQ= 5 mA to 400 mA 
VI=6V
P_5.1.6
Load Regulation VQ, lo – 40 70 mV TLE42744GV33, 
TLE42744DV33, 
TLE42744GSV33;
IQ= 5 mA to 300 mA 
P_5.1.7
Line Regulation VQ, li – 1025mVVl= 12 V to 32 V
IQ=5mA
P_5.1.8

Data Sheet 10 Rev. 1.3, 2018-03-05

TLE42744

Electrical Characteristics

Output Current Limitation IQ400 600 1100 mA 1) P_5.1.9

Power Supply Ripple Rejection2) PSRR –60–dBfr=100Hz; Vr= 0.5 Vpp P_5.1.10

Temperature Output Voltage

Drift

– 0.5 – mV/K – P_5.1.11

Overtemperature Shutdown

Threshold

Tj,sd 151– 200°C Tj increasing2) P_5.1.12

Overtemperature Shutdown

Threshold Hysteresis

Tj,sdh –25–°CTj decreasing2) P_5.1.13

Current Consumption

Quiescent Current

Iq=II–IQ

Iq–100220µAIQ= 1 mA P_5.1.14

Current Consumption

Iq=II–IQ

Iq–815mAIQ= 250 mA P_5.1.15

Current Consumption

Iq=II–IQ

Iq– 15 25 mA TLE42744DV50,

TLE42744GV50,

TLE42744EV50;

IQ= 400 mA

P_5.1.16

Current Consumption

Iq=II–IQ

Iq– 20 30 mA TLE42744GV33,

TLE42744DV33,

TLE42744GSV33;

IQ= 400 mA

P_5.1.17

1) Measured when the output voltage VQ has dropped 100 mV from the nominal value obtained at VI = 13.5 V.

2) not subject to production test, specified by design

Table 4 Electrical Characteristics (cont’d)

VI =13.5 V; Tj=-40 °C to 150 °C; all voltages with respect to ground (unless otherwise specified)

Parameter Symbol Values Unit Note / Test Condition Number

Min. Typ. Max.

dVQ

-----------

TLE42744

Electrical Characteristics

Data Sheet 11 Rev. 1.3, 2018-03-05

5.2 Typical Performance Characteristics Voltage Regulator

Current Consumption Iq versus

Output Current IQ

Current Consumption Iq versus

Low Output Current IQ

Output Voltage Variation VQ versus

Junction Temperature TJ

Dropout Voltage Vdr versus

Output Current IQ (5 V versions only)

01_IQ_IQ.VSD

0 100 200 300 400

IQ [mA]

[mA]

= 13.5 V

= 25 °C

02_IQ_IQLOW.VSD

0,2

0,4

0,6

0,8

1,2

1,4

0 20406080100

[mA]

= 13.5 V

= 25 °C

03_VQ_TJ.VSD

-0,5

-0,4

-0,3

-0,2

-0,1

0,1

0,2

0,3

0,4

0,5

-40 0 40 80 120

[°C]

[%]

= 5 mA

= 13.5 V

150

04_VDR_IQ.VSD

100

150

200

250

300

350

400

450

500

0 100 200 300 400

[mA]

[mV]

= 150 °C

= 25 °C

= -40 °C

Data Sheet 12 Rev. 1.3, 2018-03-05

TLE42744

Electrical Characteristics

Dropout Voltage Vdr versus

Junction Temperature (5 V versions only)

Maximum Output Current IQ versus

Input Voltage VI

Region Of Stability: Output Capacitor’s ESR

ESR(CQ) versus Output Current IQ

05_VDR_TJ.VSD

100

150

200

250

300

350

400

450

500

-40 0 40 80 120 160

[°C]

[mV]

= 400 mA

= 100 mA

= 10 mA

06 _ IQMAX_VI.VSD

100

200

300

400

500

600

700

800

900

010203040

[V]

Q,max

[mA]

= V

Q,nom

- 100 mV

= -40 °C

= 25 °C

= 150 °C

07_ESR_IQ.VSD

0,01

0,1

0 100 200 300 400

[mA]

ESR(CQ)

[Ω]

CQ = 22 µF

VI = 13.5 V

Stable

Region

Unstable

Region

TLE42744

Application Information

Data Sheet 13 Rev. 1.3, 2018-03-05

6 Application Information

Note: The following information is given as a hint for the implementation of the device only and shall not be

regarded as a description or warranty of a certain functionality, condition or quality of the device.

6.1 Application Diagram

Figure 4 Application Diagram

6.2 Selection of External Components

6.2.1 Input Pin

The typical input circuitry for a linear voltage regulator is shown in the application diagram above.

A ceramic capacitor at the input, in the range of 100 nF to 470 nF, is recommended to filter out the high frequency

disturbances imposed by the line e.g. ISO pulses 3a/b. This capacitor must be placed very close to the input pin

of the linear voltage regulator on the PCB.

An aluminum electrolytic capacitor in the range of 10 µF to 470 µF is recommended as an input buffer to smooth

out high energy pulses, such as ISO pulse 2a. This capacitor should be placed close to the input pin of the linear

voltage regulator on the PCB.

An overvoltage suppressor diode can be used to further suppress any high voltage beyond the maximum rating

of the linear voltage regulator and protect the device against any damage due to over-voltage.

The external components at the input are not mandatory for the operation of the voltage regulator, but they are

recommended in case of possible external disturbances.

6.2.2 Output Pin

An output capacitor is mandatory for the stability of linear voltage regulators.

The requirement to the output capacitor is given in “Functional Range” on Page 6. The graph “Region Of

Stability: Output Capacitor’s ESR ESR(CQ) versus Output Current IQ” on Page 12 shows the stable

operation range of the device.

Supply

100nF10µF

Regulated

Output Voltage

<45V

Load

(e.g.

Micro

Controller)

GND

Bandgap

Reference

GND

Current

Limitation

Temperature

Shutdown

22µF

(ESR<3)

Data Sheet 14 Rev. 1.3, 2018-03-05

TLE42744

Application Information

TLE42744 is designed to be stable with extremely low ESR capacitors. According to the automotive environment,

ceramic capacitors with X5R or X7R dielectrics are recommended.

The output capacitor should be placed as close as possible to the regulator’s output and GND pins and on the

same side of the PCB as the regulator itself.

In case of rapid transients of input voltage or load current, the capacitance should be dimensioned in accordance

and verified in the real application that the output stability requirements are fulfilled.

6.3 Thermal Considerations

Knowing the input voltage, the output voltage and the load profile of the application, the total power dissipation

can be calculated:

(1)

with

•PD: continuous power dissipation

•VI: input voltage

•VQ: output voltage

•IQ: output current

•Iq: quiescent current

The maximum acceptable thermal resistance RthJA can then be calculated:

(2)

with

•Tj,max: maximum allowed junction temperature

•Ta: ambient temperature

Based on the above calculation the proper PCB type and the necessary heat sink area can be determined with

reference to the specification in “Thermal Resistance” on Page 7.

Example

Application conditions:

VI= 13.5 V

VQ= 5 V

IQ= 250 mA

Ta= 85 °C

Calculation of RthJA,max:

PD=(VI – VQ) • IQ + VI • Iq

= (13.5 V – 5 V) • 250 mA + 13.5 V • 15 mA

= 2.125 W + 0.2025 W

= 2.3275 W

PDVIVQ

–()IQVIIq

×+×=

RthJA max,

Tjmax,Ta

–

----------------------------=

TLE42744

Application Information

Data Sheet 15 Rev. 1.3, 2018-03-05

RthJA,max =(Tj,max – Ta) / PD

= (150 °C – 85 °C) / 2.3275 W

=27.93K/W

As a result, the PCB design must ensure a thermal resistance RthJA lower than 27.93 K/W. By considering

TLE42744GV50 (PG-TO263-3 package) and according to “Thermal Resistance” on Page 7, only the FR4 2s2p

board is applicable.

6.4 Reverse Polarity Protection

TLE42744 is self protected against reverse polarity faults and allows negative supply voltage. External reverse

polarity diode is not needed. However, the absolute maximum ratings of the device as specified in “Absolute

Maximum Ratings” on Page 6 must be kept.

The reverse voltage causes several small currents to flow into the IC hence increasing its junction temperature.

As the thermal shut down circuitry does not work in the reverse polarity condition, designers have to consider this

in their thermal design.

Data Sheet 16 Rev. 1.3, 2018-03-05

TLE42744

Package Outlines

7 Package Outlines

Figure 5 PG-TO252-3

5.4 ±0.1

-0.05

6.5 +0.15

±0.5

9.98

6.22 -0.2

1±0.1

±0.15

0.8

0.15 MAX.

±0.1

per side 0.75

2.28

4.57

+0.08

GPT09277

-0.04

0.5

2.3 -0.10

+0.05

0.51 MIN.

+0.08

-0.04

0.5

0...0.15

A0.25 M

0.1

All metal surfaces tin plated,

except area of cut.

(5)

(4.24)

-0.01

+0.20

0.9

TLE42744

Package Outlines

Data Sheet 17 Rev. 1.3, 2018-03-05

Figure 6 PG-TO263-3

BA0.25

0.1

Typical

±0.2

GPT09362

8.5

7.55

(15)

±0.2

9.25

±0.3

0...0.15

5.08

2.54

0.75

±0.1

1.05

±0.1

1.27

4.4

0.5

±0.1

±0.3

2.7

4.7

±0.5

0.05

0.1

All metal surfaces: tin plated, except area of cut.

2.4

Metal surface min. x=7.25, y=6.9

0...0.3

8˚ MAX.

Data Sheet 18 Rev. 1.3, 2018-03-05

TLE42744

Package Outlines

Figure 7 PG-SSOP-14 exposed pad

14 8

14x

0.25

±0.05

0.15 DC A-B

0.65 C

STAND OFF

0.05

(1.45)

1.7 MAX.

0.08C

4.9

±0.11)

A-BH0.1 2x

1) Does not include plastic or metal protrusion of 0.15 max. per side

2) Lead width can be 0.61 max. in dambar area

Bottom View

±0.2

2.65

±0.2

614x

0.64±0.25

3.9

±0.11)

0.35 x 45°

0.1 HD2x

0.2 C

+0.06

0.19

MAX.

Index

Marking

Exposed

Diepad

SEATING

PLANE

6 x 0.65 = 3.9

TLE42744

Package Outlines

Data Sheet 19 Rev. 1.3, 2018-03-05

Figure 8 PG-SOT223-4

Green Product (RoHS compliant)

To meet the world-wide customer requirements for environmentally friendly products and to be compliant with

government regulations the device is available as a green product. Green products are RoHS-Compliant (i.e

Pb-free finish on leads and suitable for Pb-free soldering according to IPC/JEDEC J-STD-020).

SOT223-PO V04

123

±0.1

±0.04

0.5 MIN.

0.28

0.1 MAX.

6.5

±0.2

4.6

2.3

0.7

±0.1

0.25

1.6

±0.1

±0.3

B0.25

±0.2

3.5

0...10˚

For further information on alternative packages, please visit our website:

http://www.infineon.com/packages.Dimensions in mm

 
Data Sheet 20 Rev. 1.3, 2018-03-05
 
 
TLE42744
Revision History
8 Revision History
Revision Date Changes
1.3 2018-03-05 Marking update in Chapter Overview (TLE42744GSV33 and TLE42744DV33)
Updated Template on the last page.
1.2 2014-07-03 Application Information added.
PG-TO252-3 and PG-SSOP-14 EP package outlines updated.
1.1 2010-01-13 Updated Version Data Sheet:
version TLE42744EV50 in PG-SSOP-14 exposed pad and all related description 
added;
3.3V versions TLE42744GV33 in PG-TO263-3, TLE42744DV33 in PG-TO252-3 
and TLE42744GSV33 in PG-SOT223-4 and all related description added
1.0 2009-01-14 Initial Version final Data Sheet

Trademarks

All referenced product or service names and trademarks are the property of their respective owners.

Edition 2018-03-05

Published by

Infineon Technologies AG

81726 Munich, Germany

Do you have a question about any

aspect of this document?

Email: erratum@infineon.com

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 technology, delivery terms

and conditions and prices, please contact the 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.