INFINEON TLE7230G

Target Datasheet TLE7230 R/G
Smart Octal Low-Side Switch
Features
Product Summary
♦ Full Protection
Supply voltage
VS
4.5 – 5.5 V
Overload
Overtemperature
Drain source clamping voltage VDS(AZ)max 60
V
Overvoltage
On resistance
RON
0.8
Ω
♦ Low Quiescent Current< 10µA
♦ 16 bit SPI (for Daisychain)
♦ Direct Parallel Control of Four Channels
♦ PWM input (demux)
♦ Parallel Inputs High or Low Active Programmable
♦ Programmable functions
Boollean operation
Overload behavior
Power P-DSO 36
Overtemperature behavior
Switching time
♦ General Fault Flag
♦ Digital Ports Compatible to 5V and 3,3 V Micro Controllers
♦ Electostatic Discharge (ESD) Protection
♦ Full reverse current capability without latchup or loss of function
P-DSO-24
General description
Detailed Block Diagram
PRG
GND
Octal Low-Side Switch in
Smart
Power
Technology
(SPT) with a Serial Peripheral
Interface (SPI) and eight open
drain DMOS output stages.
The TLE 7230 R/G is protected by embedded protection functions and designed for
automotive applications.
RESET
FAULT
VS
VDO
VS
VBB
Protection
Functions
IN1
IN2
as Ch. 1
IN3
as Ch. 1
IN4
as Ch. 1
LOGIC
Output Stage
16
SCLK
SI
CS
1
8
Serial Interface
SPI
OUT1
4
Output Control
Buffer
8
OUT8
SO
GND
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12. Oct. 2003
Target Datasheet TLE7230 R/G
Power SO 36 package
Pin Description
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
Symbol
GND
NC
NC
OUT1
OUT2
IN1
IN2
VS
Reset
CS
PRG
IN3
IN4
OUT3
OUT4
NC
NC
GND
GND
NC
NC
OUT5
OUT6
NC
VDO
26
27
28
29
30
31
32
33
34
35
36
Fault
SO
SCLK
SI
NC
NC
OUT7
OUT8
NC
NC
GND
Pin Configuration (Top view)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
Function
Ground
not connected
not connected
Output Channel 1
Output Channel 2
Input Channel 1
Input Channel 2
Supply Voltage
Reset
Chip Select
Program
Input Channel 3
Input Channel 4
Output Channel 3
Output Channel 4
not connected
not connected
Ground
Ground
not connected
not connected
Output Channel 5
Output Channel 6
not connected
Supply for digital
Outputs
General Fault Flag
Serial Data Output
Serial Clock
Serial Data Input
not connected
not connected
Output Channel 7
Output Channel 8
not connected
not connected
Ground
GND
NC
NC
Out1
Out2
IN1
IN2
VS
Reset
CS
PRG
IN3
IN4
Out3
Out4
NC
NC
GND
GND
NC
NC
Out8
Out7
NC
NC
SI
SCLK
SO
Fault
VDO
NC
Out6
Out5
NC
NC
GND
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
Power- P-DSO-36
Heat Slug internally connected to ground pins
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12. Oct. 2003
Target Datasheet TLE7230 R/G
SO 24 package (thermal enhanced)
Pin Description
Pin
1
2
3
4
5
6
7
8
9
10
11
Symbol
CS
IN
OUT3
OUT4
GND
GND
GND
GND
OUT5
OUT6
VDO
12
13
14
15
16
17
18
19
20
21
22
23
24
SO
SCLK
SI
OUT7
OUT8
GND
GND
GND
GND
OUT1
OUT2
VS
Reset
Pin Configuration (Top view)
Function
Chip Select
Mappable input
Output Channel 3
Output Channel 4
Ground
Ground
Ground
Ground
Output Channel 5
Output Channel 6
Supply for digital
Outputs
Serial Data Output
Serial Clock
Serial Data Input
Output Channel 7
Output Channel 8
Ground
Ground
Ground
Ground
Output Channel 1
Output Channel 2
Supply Voltage
Reset
1
2
3
4
5
6
7
8
9
10
11
12
CS
IN
Out3
Out4
GND
GND
GND
GND
Out5
Out6
VDO
SO
Reset
Vs
Out2
Out1
GND
GND
GND
GND
Out8
Out7
SI
SCLK
24
23
22
21
20
19
18
17
16
15
14
13
P-DSO-24
Heat Slug internally connected to ground pins
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12. Oct. 2003
Target Datasheet TLE7230 R/G
Maximum Ratings for Tj = – 40°C to 150°C
Parameter
Supply Voltage
Symbol
VS
Continuous Drain Source Voltage (OUT1...OUT8)
VDS
48
V
Input Voltage, All Inputs and Data Lines
VIN
- 0.3 ... + 6
V
Operating Temperature Range
Storage Temperature Range
Tj
Tstg
- 40 ... + 150
- 55 ... + 150
°C
Output Current per Channel (see el. characteristics)
ID(lim)
ID(lim)min
A
Reverse current per channel
IR
- ID(lim)min
A
EAS
tbd
mJ
VESD
VESD
2000
2000
Output Clamping Energy (single pulse)
ID = 0.5 A
Electrostatic Discharge Voltage (Human Body Model)
according to MIL STD 883D, method 3015.7 and EOS/ESD
assn. standard S5.1 – 1993
Output 1-8 Pins
All other Pins
Values
-0.3 ... + 6
DIN Humidity Category, DIN 40 040
E
IEC Climatic Category, DIN IEC 68-1
40/150/56
Thermal Resistance
junction – case (Power SO-36, all channels on)
junction – case (SO-24, all channels on)
V1.1
Page
RthJC
RthJC
4
tbd
tbd
Unit
V
V
V
K/W
12. Oct. 2003
Target Datasheet TLE7230 R/G
Electrical Characteristics
Parameter and Conditions
VS = 4.5 to 5.5 V ; Tj = - 40 °C to + 150 °C ; Reset = H
(unless otherwise specified)
Symbol
Values
min
Unit
typ
max
1. Power Supply, Reset
Supply Voltage1
VS
4.5
--
5.5
Supply Current
IS
--
1
2
mA
IS(reset)
--
10
µA
tReset,min
10
--
--
µs
TJ = 25°C
TJ = 150°C
RDS(ON)
---
0.8
--
1
1.7
Ω
Output OFF
VDS(AZ)
48
--
60
V
ID(lim)
1
2
A
ID(lkg)
--
5
µA
15 /
60
15 /
60
µs
Supply Current (reset mode)
Reset = L
Minimum Reset Duration
V
2. Outputs
ON Resistance VS = 5 V; ID = 500 mA
Output Clamping Voltage
Current Limit
Output Leakage Current
VReset = L
Vbb=12V
--
Turn-On Time
ID = 0.5 A, resistive load
tON
--
Turn-Off Time
ID = 0.5 A, resistive load
tOFF
--
Input Low Voltage
VINL
- 0.3
--
1.0
V
Input High Voltage
VINH
2.0
--
--
V
Input Voltage Hysteresis
VINHys
100
mV
Input Pull Down/Up Current (IN1 ... IN4)
IIN(1..4)
50
µA
PRG, Reset Pull Up Current
IIN(PRG,Res)
50
µA
Input Pull Down Current (SI, SCLK)
IIN(SI,SCLK)
20
µA
Input Pull Up Current (CS)
IIN(CS)
20
µA
µs
3. Digital Inputs
4. Digital Outputs (SO, Fault)
SO High State Output Voltage
ISOH = 2 mA
VSOH
SO Low State Output Voltage
ISOL = 2.5 mA
VSOL
Output Tri-state Leakage Current CS = H, 0 ≤ VSO ≤ VS
Fault Output Low Voltage
IFAULT = 1.6 mA
1
VVDO 0.4
--
--
V
--
--
0.4
V
ISOlkg
-10
0
10
µA
VFAULTL
--
--
0.4
V
For VS < 4.5V the power stages are switched according the input signals and data bits or are definitely switched
off.
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12. Oct. 2003
Target Datasheet TLE7230 R/G
Electrical Characteristics cont.
Parameter and Conditions
Symbol
VS = 4.5 to 5.5 V ; Tj = - 40 °C to + 150 °C ; Reset = H
(unless otherwise specified)
Values
Unit
min
typ
max
5. Diagnostic Functions
Open Load Detection Voltage
VDS(OL)
VS -2
V
Output Pull Down Current
IPD(OL)
90
µA
Fault Delay Time
td(fault)
100
µs
Overload switch off delay time
Td(off)
Short to Ground Detection Voltage
VDS(SHG)
VS -2.9
V
Short to Ground Detection Current
ISHG
-100
µA
Overload Threshold Current
10
ID(lim) 1...8
1
Tth(sd)
Thys
175
--
Serial Clock Frequency (depending on SO load)
fSCK
Serial Clock Period (1/fclk)
50
µs
2
A
-10
200
--
°C
K
DC
--
5
MHz
tp(SCK)
200
--
--
ns
Serial Clock High Time
tSCKH
50
--
--
ns
Serial Clock Low Time
tSCKL
50
--
--
ns
Enable Lead Time (falling edge of CS to rising edge of CLK) tlead
250
--
--
ns
Enable Lag Time (falling edge of CLK to rising edge ofCS)
tlag
250
---
--
ns
Data Setup Time (required time SI to falling of CLK)
tSU
20
--
--
ns
Data Hold Time (falling edge of CLK to SI)
tH
20
--
--
ns
tDIS
--
--
150
ns
tdt
tbd
--
--
ns
tvalid
----
tbd
tbd
tbd
Overtemperature Shutdown Threshold
Hysteresis2
2
6. SPI-Timing (for VVDO = 4.5V to 5.5V)
Disable Time @ CL = 50 pF
2
3
Transfer Delay Time
(CS high time between two accesses)
Data Valid Time
2
3
CL = 50 pF2
CL = 100 pF2
CL = 220 pF2
ns
This parameter is not subject to production test
This time is necessary between two write accesses. To get the correct diagnostic information, the transfer delay
time has to be extended to the maximum fault delay time td(fault)max = 200µs.
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Target Datasheet TLE7230 R/G
Functional Description
The TLE 7230 R/G is an octal-low-side power switch which provides a serial peripheral interface (SPI)
to control the 8 power DMOS switches, as well as diagnostic feedback. The power transistors are protected4) against overload (current limitation), overtemperature and against overvoltage by an active
zener clamp. The diagnostic logic recognizes a fault condition which can be read out via the serial diagnostic output (SO).
Output Stage Control: Parallel Control or SPI Control
The Output stages can be controlled by parallel Inputs or by SPI command. The IC can be programmed (by SPI) to switch the outputs according to the corresponding SPI command bit or to a combination of SPI bit and parallel input signal. The logic combination of parallel and serial signal is programmable by SPI (Boolean operation) to logic "AND" or "OR" The respective SPI databits are high
active, the parallel Inputs are high or low active according to the PRG pin (see pin description).
Boolean operation:
The logic combination of the parallel and the
serial input signal can be configured by an
SPI command for each of the 8 channels
individually. Logic "AND" or logic "OR" is
possible.
parallel in
off
off
on
on
serial in
off
on
off
on
Output "OR"
off
on
on
on
Output "AND"
off
off
off
on
Mappable parallel input (IN 4):
By SPI Command the parallel input 4 (IN4 or IN) can be defined as parallel input for one or more power
outputs. Depending on the Input Map Register this input can be used to controll one up to eight of the
parallel outputs. Default operation: IN4 / IN is the parallel input for channel 4.
Input Map register
Input buffer
IN n (1..3)
Input buffer
IN 4
Boolean register
Input buffer
IN 4
Boolean register
&
&
Output Latch
≥1
Output Latch
≥1
serial controll register
Channel 4 to 8
serial controll register
Channel 1 to 3
Signal logic channel 1 to 3
Input Map register
Signal logic channel 4 to 8
Switching speed / Slew rate:
The switching speed / slew rate of all 8 channels can be configured by SPI for slow or fast switching
speed (1:5) for each channel individually.
Overtemperature Behavior:
Each channel has an overtemperature sensor and is individually protected against overtemperature.
As soon as overtemperature occurs the channel is immediately turned off and the overtmperature information is reported by diagnosis. In this case there are two different behaviours of the affected channel that can be selected by SPI (for all channels individually).
Autorestart: as long as the input signal of the channel remains on (e.g. parallel input high) the channel
turns automatically on again after cooling down.
4
)The integrated protection functions prevent an IC destruction under fault conditions and may not be used in
normal operation or permanently.
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Target Datasheet TLE7230 R/G
Latching: After overtemperature shutdown the channel stays off until the overtemperature latch is reset by a new LÆH transition of the input signal.
Note: The overtemperature sensors of the output channels are only active if the channel is turned on.
Low Quiescent current mode (Sleep mode) :
By applying ay low signal at the Reset Pin the device can be set to Sleep mode. In this mode all outputs are turned off, the diagnosis and biasing is disabled, the diagnosis and the on/off register are reseted and the current consumption drastically reduced (<10µA). After a reset the outputs are Off, except the outputs are controlled by parallel inputs.
Overload Protection:
The IC can be programmed to react in different ways to overload.
Only Current limit: The IC actively limits the current to the specified current lmit value. If the current
limitation is active for longer than the fault filtering time this fault is reported and stored in the Fault register. The channel is not shutdown.
Current limit + shutdown: The IC actively limits the current to the specified current lmit value. If this current limit is active for more than the specified Overload switch off delay time the affected channel is
turned off and the fault is reported and stored in the fault register. To turn on the channel again this
overload latch has to be reset before with an LÆ H transition of the input signal (parallel /SPI depending on the programmed operation).
Pin description:
OUTPUT 1 to 8 – Drain pins of the 8 channels. Output pins and connected to the load.
GND – Ground pins.
IN 1 to 3 – Parallel Input Pins of the channels 1 to 3
IN 4 / IN – Mappable parallel Input Pin. Can be assigned to different outputs by SPI command. Default
Output is OUT4
PRG - Program pin.
PRG = High (VS): Parallel inputs 1 to 4 are high active
PRG = Low (GND): Parallel inputs 1 to 4 are low active.
If the parallel input pins are not connected (independent of high or low activity) it is guaranteed
that the channels 1 to 4 are switched OFF.
PRG pin itself is internally pulled up when it is not connected.
Reset - If the reset pin is in a logic low state, it clears the SPI shift register and switches all
outputs OFF. An internal pull-up structure is provided on chip.
Fault - There is a general fault pin (open drain) which shows a high to low transition as soon
as an error occurs for any one of the eight channels. This fault indication can be used to generate a µC interrupt. Therefore a ‘diagnosis’ interrupt routine need only be called after this fault
indication. This saves processor time compared to a cyclic reading of the SO information.
VDO – Supply pin of the push-pull digital output drivers. This pin can be used to vary the high-state
output voltage of the SO pin.
Vs – Logic supply pin. This pin is used to supply the integrated circuitry.
CS – Chip Select of the SPI
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Target Datasheet TLE7230 R/G
SO – Signal Output of the Serial Peripheral Interface
SI – Signal Input of the Serial Peripheral Interface. The pin has an internal pull down structure.
SCLK – Clock Input of the Serial Peripheral Interface. The pin has an internal pull down structure
SPI
The SPI is a Serial Peripheral Interface with 4 digital pins
and an 16 bit shift register. The SPI is used to configure and
program the device, turn on and off channels and to read
detailed diagnostic information.
CS
SCLK
SI
SO
SPI
SPI Signal Description:
CS - Chip Select. The system microcontroller selects the TLE 7230 R/G by means of the CS pin.
Whenever the pin is in a logic low state, data can be transferred from the µC and vice versa.
LSB
CS = H : Any signals at the SCLK and SI
pins are ignored and SO is forced into a
high impedance state.
MSB
internal logic registers
CS
CS = HÆL :
• diagnostic information is transferred
16 bit SPI shift register
Serial input
Serial output
from the diagnosis register into the SPI
(diagnosis)
data MSB first
CS
shift register. (in sleep mode no tranfer
MSB first
of diagnostic information)
diagnosis register
• serial input data can be clocked into the
LSB
MSB
SPI shift register from then on
• SO changes from high impedance state to logic high or low state corresponding to the SO bits
SI
SO
CS = L : SPI is working like a shift register. With each clock signal at the SCLK pin the state of the SI is
read into the SPI shift-register (falling clock edge) and one diagnosis bit is written out of SO (rising rising edge).
CS = LÆH:
• transfer of SI bits from SPI shift register into the internal logic registers
• reset of diagnosis register if sent command was valid
To avoid any false clocking the serial clock input pin SCLK should be logic low state during high to low
transition of CS. The SPI of the TLE7230G/R has a modulo 8 counter integrated. If the number of
clock signals is not an integer multiple of 8 the SPI will not accept the data in the shift register and the
fault register will not be reset.
SCLK - Serial Clock. The serial clock pin clocks the internal SPI shift register of the TLE7230G/R. The
serial input (SI) accepts data into the input SPI shift register on the falling edge if while the serial output
(SO) shifts diagnostic information out of the SPI shift register on the rising edge of serial clock. It is essential that the SCLK pin is in a logic low state whenever chip select CS makes any transition.
SI - Serial Input. Serial data bits are shifted in at this pin, the most significant bit (MSB) first. SI information is read in on the falling edge . Input data is latched in the SPI shift register and then transferred
to the internal registers of the logic.
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Target Datasheet TLE7230 R/G
The input data consist of 16 bit, made up of x control bits and y data bits. The control word is used to
program the device, to operate it in a certain mode as well as providing diagnostic information (see SPI
Commands).
SO - Serial Output. Diagnostic data bits are shifted out serially at this pin, the most significant bit (MSB)
first. SO is in a high impedance state until the CS pin goes to a logic low state. New diagnostic data will
appear at the SO pin following the rising edge.
SPI Control and Commands:
MSB
SI:
14
CMD
13
12
11
x
x
x
10
9
8
6
5
4
ADDR
SO:
SO standard diagnosis
Ch 8
Ch 7
SO:
SO after read command in previous frame
0
1
0
0
0
ADDR
CMD
7
Ch 6
3
2
1
LSB
DATA
Ch 5
Ch 4
Ch 3
Ch 2
Ch 1
DATA
Command :
0 0 : Diagnosis Only :
Reads out the diagnosis register. This command has no other influence on the device.
0 1 : Read register :
With the next SO dataframe the content of the addressed register will be sent.
1 0 : Reset Registers
Sets back all internal registers. Logic registers to default and Fault registers to no error.
1 1 : Write register :
The data of the SI word will be written to the addressed register.
No valid Commands :
If the first 8 bit of the SI word contain no valid bit combination it will not lead to an reaction (register value change, switching channels, ...) of the IC. After Chip Select giong
LÆH the diagnosis register will not be reset.
ADDR
Address :
Pointer to register for read and write command
DATA
Data:
Data written to or read from register selected by address ADDR
Ch x
Standard diagnosis for channel x:
Details see "SPI Diagnostics"
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Target Datasheet TLE7230 R/G
Register Description:
Name
Nr.
7
6
5
4
3
2
1
0
ADDR
default
MAP
BOL
OVL
OVT
SLE
STA
CTL
1
2
3
4
5
6
7
Ch8
Ch8
Ch8
Ch8
Ch8
OUT8
Ch8
Ch7
Ch7
Ch7
Ch7
Ch7
OUT7
Ch7
Ch6
Ch6
Ch6
Ch6
Ch6
OUT6
Ch6
Ch5
Ch5
Ch5
Ch5
Ch5
OUT5
Ch5
Ch4
Ch4
Ch4
Ch4
Ch4
OUT4
Ch4
Ch3
Ch3
Ch3
Ch3
Ch3
OUT3
Ch3
Ch2
Ch2
Ch2
Ch2
Ch2
OUT2
Ch2
Ch1
Ch1
Ch1
Ch1
Ch1
OUT1
Ch1
001
010
011
100
101
110
111
08H
00H
00H
00H
00H
00H
00H
Input Mapping Rgister (MAP)
Defined to which outputs the IN4 / IN is assigned (can be one up to all)
0.. No connection to IN4 / IN
1.. Output can be controlled with IN4 / IN pin
Boolean operation Register (BOL)
The logic operation for serial and parallel control signal is defined for all channels individually
0.. Logic "OR"
1.. Logic "AND"
Overload Behavior Rgister (OVL)
The overload behavior of a single channel is defined.
0.. Current limit without shutdown of the channel
1.. Current limit with latching overload shutdown of the channel
Overtemperature Behavior Register (OVT)
The overtemperature behavior of a single channel is defined.
0.. Autorestart after cooling down
1.. Latching shutdown on overtemperature
Switching Speed / Slew Rate Register (SLE)
The switching speed of the channels is defined
0.. fast (10µs)
1.. slow (50µs)
Output State Register (STA)
Reads back the state of the output (read only register)
0: DMOS off
1: DMOS on
Serial Output Control Register (CTL)
Sets the serial controll bits for switching the output stages.
0: Output off
1: Output on
SPI Diagnostics:
As soon as a fault occurs for longer than the fault filtering time, the fault information is latched into the
diagnosis register (and the Fault pin will change from high to low state). A new error on the same
channel will over-write the old error report. Serial data out pin (SO) is in a high impedance state when
CS is high. If CS receives a LOW signal, all diagnosis bits can be shifted out serially. If the sent comV1.1
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Target Datasheet TLE7230 R/G
mand was valid the rising edge of CS will reset all diagnosis registers and restart the fault filtering time.
In case of an invalid command the device will ignore the data bits and the diagnosis register will not be
reset at the rising CS edge.
Figure 1: Two bits per channel diagnostic feedback
Diagnostic Serial Data O ut SO
LSB
M SB
15
3
C h.8
HH
HL
LH
LL
2
C h.2
1
0
C h.1
N orm al function
O verload , Shorted Load or O verte m perature
O pen Load (off)
Short to G N D
For Full Diagnosis there are two diagnostic bits per channel configured as shown in Figure 1.
Normal function: The bit combination HH indicates that there is no fault condition, i.e. normal function.
Overload, Shorted Load or Overtemperature: HL is set when the current limitation gets active, i.e.
there is a overload, short to supply or overtemperature condition. The second reason for this bit combination is overtemperature of the corresponding channel.
Open load: LH is set when open load is detected (in off state of the channel)
Short to GND : LL is set when this condition is detected (in off state)
Timing Figures
Figure 5: Power Outputs
VIN
t
VDS
tON
tOFF
80%
20%
t
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Target Datasheet TLE7230 R/G
Figure 6: Serial Interface Timing Diagram
CS
0.7VS
tdt
0.2 VS
tlag
tSCKH
SCLK
tlead
0.7VS
0.2VS
tSCKL
tSU
tH
0.7VS
SI
0.2VS
Figure 7: Input Timing Diagram
SO Valid Time Waveforms
0.7 V S
SCLK
Enable and Disable Time Waveforms
CS
0.2 V S
t valid
t D is
SO
0.7 V S
0.2 V S
SO
SO
0.7 V S
0.2 V S
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Target Datasheet TLE7230 R/G
(all dimensions in mm)
P-DSO 36-12
Ordering Code
TLE 7230 R
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Target Datasheet TLE7230 R/G
P-DSO 24
Ordering Code
TLE 7230 G
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Target Datasheet TLE7230 R/G
Published by
Infineon Technologies AG,
Bereichs Kommunikation
St.-Martin-Strasse 76,
D-81541 München
© Infineon Technologies AG 1999
All Rights Reserved.
Attention please!
The information herein is given to describe certain components and shall not be considered as warranted characteristics.
Terms of delivery and rights to technical change reserved.
We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and charts stated herein.
Infineon Technologies is an approved CECC manufacturer.
Information
For further information on technology, delivery terms and conditions and prices please contact your nearest Infineon Technologies Office in Germany or our Infineon Technologies Representatives worldwide (see address list).
Warnings
Due to technical requirements components may contain dangerous substances. For information on the types in question
please contact your nearest Infineon Technologies Office.
Infineon Technologies Components may only be used in life-support devices or systems 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.
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