INFINEON TLE4299GMV33

Low-Drop Fixed Voltage Regulator
TLE 4299
Data Sheet
Features
•
•
•
•
•
•
•
•
•
Output voltage 3.3V ± 2%
150 mA Output current
Extreme low current consumption in ON state
Inhibit function: Below 1 µA current consumption
in off mode
Early warning
Reset output low down to VQ = 1 V
Overtemperature protection
Reverse polarity proof
Wide temperature range
Type
Ordering Code
P-DSO-8-3
Package
TLE 4299 GV33
Q67065-A7033 P-DSO-8-3
TLE 4299 GMV33
Q67065-A7032 P-DSO-14-8
P-DSO-14-3, -8, -9, -11
Functional Description
The TLE 4299 is a monolithic voltage regulator with fixed 5-V (see data sheet TLE4299G/GM)
or 3.3 V output, supplying loads up to 150 mA. It is especially designed for applications that may
not be powered down while the motor is off. In addition the TLE 4299GMV includes an inhibit
function. When the inhibit signal is removed, the device is switched off and the quiescent current
is less than 1 µA. To achieve proper operation of the µ-controller, the device supplies a reset
signal. The reset delay time is selected application-specific by an external delay capacitor. The
reset threshold is adjustable. An early warning signal supervises the voltage at pin SI. The
TLE 4299 is pin-compatible to the TLE 4269 and functional similar with the additional inhibit
function. The TLE 4299 is designed to supply microcontroller systems even under automotive
environment conditions. Therefore it is protected against overload, short circuit and over
temperature.
Datasheet Rev. 1.0
1
2005-01-27
TLE 4299
Circuit Description
The TLE 4299 is a PNP based very low drop linear voltage regulator. It regulates the output
voltage to VQ = 3.3 V for an input voltage range of 4.4 V ≤ VI ≤ 45 V. The control circuit protects
the device against potential damages caused by overcurrent and overtemperature.
The internal control circuit achieves a 3.3 V output voltage with a tolerance of ± 2%.
The device includes a power on reset and an under voltage reset function with adjustable reset
delay time and adjustable reset switching threshold as well as a sense control/early warning
function. The device includes an inhibit function to disable it when the ECU is not used for
example while the motor is off.
The reset logic compares the output voltage VQ to an internal threshold. If the output voltage
drops below this level, the external reset delay capacitor CD is discharged. When VD is lower than
VST, the reset output RO is switched Low. If the output voltage drop is very short, the VST level
is not reached and no reset-signal is asserted. This feature avoids resets at short negative spikes
at the output voltage e.g. caused by load changes.
As soon as the output voltage is more positive than the reset threshold, the delay capacitor is
charged with constant current. When the voltage reaches VDT the reset output RO is set High
again.
The reset delay time and the reset reaction time are defined by the external capacitor CD. The reset
function is active down to VI = 1 V.
In addition to the normal reset function, the device gives an early warning. When the SI voltage
drops below VSI,low, the devices asserts the SI output Low to indicate the logic and the µ-processor
that this voltage has dropped. The sense function uses a hysteresis: When the SI-voltage reaches
the VSI,high level, SO is set high again. This feature can be used as early warning function to notice
the µ-controller about a battery voltage drop and a possible reset in a short time. Of course also
any other voltage can be observed by this feature.
The user defines the threshold by the resistor-values RSI1 and RSI2.
For the exact timing and calculation of the reset and sense timing and thresholds, please refer to
the application section.
Datasheet Rev. 1.0
2
2005-01-27
TLE 4299
TLE 4299
I
Q
Current
and
Saturation
Control
BandGapReference
RSO
RRO
SO
SI
Reference
RO
Reset
Control
RADJ
D
GND
AEB03103
Figure 1
Block Diagram TLE 4299 GV33
Datasheet Rev. 1.0
3
2005-01-27
TLE 4299
TLE 4299
I
Q
Current
and
Saturation
Control
BandGapReference
RSO
RRO
Inhibit
Control
INH
SO
SI
Reference
RO
Reset
Control
RADJ
D
GND
AEB03104
Figure 2
Block Diagram TLE 4299 GMV33
Datasheet Rev. 1.0
4
2005-01-27
TLE 4299
P-DSO-8-3
I
1
8
Q
SI
2
7
SO
RADJ
3
6
RO
D
4
5
GND
AEP02832
Figure 3
Pin Configuration (top view)
Pin Definitions and Functions (TLE 4299 GV33)
Pin No.
Symbol
Function
1
I
Input; block directly to GND on the IC with a ceramic capacitor.
2
SI
Sense Input; if not needed connect to Q.
3
RADJ
Reset Threshold Adjust; if not needed connect to GND.
4
D
Reset Delay; to select delay time, connect to GND via external
capacitor.
5
GND
Ground
6
RO
Reset Output; the open-collector output is linked internally to Q via a
20kΩ pull-up resistor. Keep open, if the pin is not needed.
7
SO
Sense Output; open-collector output. Keep open, if the pin is not
needed.
8
Q
Output; connect to GND with a 22 µF capacitor, 0.4 Ω <
ESR < 3.7 Ω.1)
1)
see characteristic curves
Datasheet Rev. 1.0
5
2005-01-27
TLE 4299
P-DSO-14-8
RADJ
1
14
SI
D
2
13
I
GND
3
12
GND
GND
4
11
GND
GND
5
10
GND
INH
6
9
Q
RO
7
8
SO
AEP02831
Figure 4
Pin Configuration (top view)
Pin Definitions and Functions (TLE 4299 GMV33)
Pin No.
Symbol
Function
1
RADJ
Reset Threshold Adjust; if not needed connect to GND.
2
D
Reset Delay; connect to GND via external delay capacitor for setting
delay time.
3, 4, 5
GND
Ground
6
INH
Inhibit: If not needed connect to Input pin I; A high signal switches the
regulator ON.
7
RO
Reset Output; the open-collector output is linked internally to Q via a
20kΩ pull-up resistor. Keep open, if the pin is not needed.
8
SO
Sense Output; open-collector output. Keep open, if the pin is not
needed.
9
Q
Output; connect to GND with a 22 µF capacitor, 0.4 Ω <
ESR < 3.7 Ω.1)
10, 11, 12
GND
Ground
13
I
Input; block to GND directly at the IC by a ceramic capacitor.
14
SI
Sense Input; if not needed connect to Q.
1)
see characteristic curves
Datasheet Rev. 1.0
6
2005-01-27
TLE 4299
Absolute Maximum Ratings
Tj = – 40 to 150 °C
Parameter
Symbol
Limit Values
Unit
Notes
min.
max.
VI
– 40
45
V
–
VINH
– 40
45
V
–
VSI
ISI
– 0.3
45
V
–
-1
1
mA
–
VRADJ
IRADJ
– 0.3
7
V
–
-10
10
mA
–
VD
– 0.3
7
V
–
VR
– 0.3
7
V
–
VSO
– 0.3
7
V
–
VQ
IQ
– 0.3
7
V
–
–5
–
mA
–
Input I
Input voltage
Inhibit Input INH
Input voltage
Sense Input SI
Input voltage
Input current
Reset Threshold Adjust RADJ
Input voltage
Input current
Reset Delay D
Voltage
Reset Output RO
Voltage
Sense Output SO
Voltage
Output Q
Output voltage
Output current
Datasheet Rev. 1.0
7
2005-01-27
TLE 4299
Absolute Maximum Ratings (cont’d)
Tj = – 40 to 150 °C
Parameter
Symbol
Limit Values
Unit
Notes
min.
max.
Tj
TStg
–
150
°C
–
– 50
150
°C
–
VI
Tj
4.4
45
V
–
– 40
150
°C
–
Junction-ambient for foot
print only1)
Rthja
–
200
130
K/W
K/W
P-DSO-8-3
P-DSO-14-8
Junction-ambient for
300mm2 cooling area2)
Rthja
–
164
70
K/W
K/W
P-DSO-8-3
P-DSO-14-8
Junction-pin
Rthjp
–
60
30
K/W
K/W
P-DSO-8-33)
P-DSO-14-84)
Temperature
Junction temperature
Storage temperature
Operating Range
Input voltage
Junction temperature
Thermal Data
1)
FR4, 80x80x1,5mm; 35µ Cu, 5µ Sn; Footprint only
2)
FR4, 80x80x1,5mm; 35µ Cu, 5µ Sn; 300mm2
3)
Measured to pin 5
4)
Measured to pin 4
Note: Stresses above those listed here may cause permanent damage to the device. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
In the operating range, the functions given in the circuit description are fulfilled.
Datasheet Rev. 1.0
8
2005-01-27
TLE 4299
Characteristics
VI = 13.5 V; Tj = – 40 °C < Tj < 150 °C
Parameter
Symbol
Limit Values
min. typ.
Unit Measuring Condition
max.
Output voltage
VQ
3.23
3.30 3.37
V
1 mA ≤ IQ ≤ 100 mA;
5.5 V ≤ VI ≤ 16 V
Output voltage
VQ
3.20
3.30 3.40
V
IQ ≤ 150 mA;
5.5 V ≤ VI ≤ 16 V
Current limit
IQ
250
400
500
mA
–
Current consumption;
Iq = II – IQ
Iq
–
65
105
µA
Inhibit ON;
IQ ≤ 1 mA, Tj < 85 °C
Current consumption;
Iq = II – IQ
Iq
–
170
500
µA
Inhibit ON;
IQ = 10 mA
Current consumption;
Iq = II – IQ
Iq
–
0.7
2
mA
Inhibit ON;
IQ = 50 mA
Current consumption;
Iq = II – IQ
Iq
–
–
1
µA
VINH = 0 V;
Tj = 25 °C
Load regulation
∆VQ
–
5
30
mV
IQ = 1 mA to 100 mA
Line regulation
∆VQ
–
10
25
mV
VI = 6 V to 28 V;
IQ = 1 mA
Power Supply Ripple
rejection
PSRR
–
66
–
dB
fr = 100 Hz; Vr = 1 VSS;
IQ = 100 mA
–
0.8
V
VQ off
-
V
VQ on
Inhibit (TLE 4299 GMV33 only)
Inhibit OFF voltage range
VINH OFF –
Inhibit ON voltage range
VINH ON
3.5
High input current
IINH ON
–
3
5
µA
VINH = 5V
Low input current
IINH OFF
–
0.5
2
µA
VINH = 0.8 V
Datasheet Rev. 1.0
9
2005-01-27
TLE 4299
Characteristics (cont’d)
VI = 13.5 V; Tj = – 40 °C < Tj < 150 °C
Parameter
Symbol
Limit Values
min. typ.
Unit Measuring Condition
max.
Reset Generator
Switching threshold
Vrt
Reset threshold headroom
3.00
3.10 3.20
V
–
VRTHEAD 50
200
300
mV
–
Reset pull up
RRO
10
20
40
kΩ
–
Reset low voltage
VR
–
0.17 0.40
V
VQ < 3.0 V; internal RRO;
IR = 1 mA
External reset pull up
VR ext
5.6
–
kΩ
Pull up resistor Q
Delay switching threshold
VDT
1.6
1.85 2.35
V
–
Switching threshold
VST
0.35
0.50 0.60
V
–
Reset delay low voltage
VD
–
–
0.1
V
VQ < VRT
Charge current
Ich
2.0
3.5
6.0
µA
VD = 1 V
Power-up Reset delay time
td
36
51
60
ms
CD = 100 nF
Reset reaction time
trr
0.5
1.2
3.0
µs
CD = 100 nF
Reset Adjust Switching
Threshold
VRADJ
1.26
1.36 1.44
V
VQ < 3.5V
–
TH
Input Voltage Sense
Sense threshold high
VSI high
1.34
1.45 1.54
V
–
Sense threshold low
VSI low
1.26
1.36 1.44
V
–
Sense input switching
hysteresis
VSI HYST
50
90
130
mV
VSI HYST = VSI high – VSI low
Sense output low voltage
VSO low
–
0.1
0.4
V
VSI < 1.20 V; Vi > 4.2 V;
ISO = 1mA
5.6
–
–
kΩ
–
External SO pull up resistor RSO ext
Sense input current
ISI
–1
0.1
1
µA
Si > 1.0V
Sense high reaction time
tpd SO LH
–
2.4
4.0
µs
RSO ext = 5.6kΩ
Sense low reaction time
tpd SO HL
–
2.5
6.0
µs
RSO ext = 5.6kΩ
Datasheet Rev. 1.0
10
2005-01-27
TLE 4299
Note: The listed characteristics are ensured over the operating range of the integrated circuit.
Typical characteristics specify mean values expected over the production spread. If not
otherwise specified, typical characteristics apply at TA = 25 °C and the given supply
voltage.
II
IQ1
VI
I
Q1
VQ1
RO
VRO
SO
VSO
TLE 4299
IINH
VINH
INH
(TLE4299GMV33
only)
CD
100 nF
D
Ich
IRADJ
VRADJ
RADJ
ISI
VSI
SI
GND
IGND
AES02835
Figure 5
Measurement Circuit
Datasheet Rev. 1.0
11
2005-01-27
TLE 4299
Application Information
TLE 4299
VBAT
CI2
P
CQ1
C
Q 22 F Q2
I
CI1
Current
and
Saturation
Control
BandGapReference
RSO
RRO
SO
RSI1
SI
RO
Reference
RSI2
Reset
Control
RADJ1
RADJ
GND
D
RADJ2
CD
AES03105
Figure 6
Application Diagram TLE 4299 GV33
Datasheet Rev. 1.0
12
2005-01-27
TLE 4299
TLE 4299
VBAT
CI2
P
CQ1
C
Q 22 F Q2
I
CI1
BandGapReference
From
KI. 15
INH
Current
and
Saturation
Control
Inhibit
Logic
RSO
RRO
SO
RSI1
SI
RO
Reference
RSI2
Reset
Control
RADJ1
RADJ
GND
D
RADJ2
CD
AES03106
Figure 7
Application Diagram with Inhibit Function TLE4299 GMV33
The TLE 4299 supplies a regulated 3.3 V output voltage with an accuracy of 2% for an input
voltage between 4.4 V and 45 V in the temperature range of Tj = – 40 to 150 °C, in an output
current range of 1 mA to 100 mA.
The device is capable to supply 150 mA with an accuracy of 3%. For protection at high input
voltage above 25 V, the output current is reduced (SOA protection).
An input capacitor is necessary for compensating line influences and to limit steep input edges.
A resistor of approx. 1 Ω in series with CI, can damp the LC of the input inductivity and the input
capacitor.
The voltage regulator requires for stability an output capacitor CQ of at least 22 µF with an 0.4Ω
< ESR < 3.7Ω for the whole load- and temperature range. For more detailed information, refer to
the characteristical curves.
Datasheet Rev. 1.0
13
2005-01-27
TLE 4299
Reset
The power on reset feature is necessary for a defined start of the microprocessor when switching
on the application. For the reset delay time after the output voltage of the regulator is above the
reset threshold, the reset signal is set High again. The reset delay time is defined by the reset delay
capacitor CD at pin D.
The under-voltage reset circuitry supervises the output voltage. In case VQ decreases below the
reset threshold the reset output is set LOW after the reset reaction time. The reset LOW signal is
generated down to an output voltage VQ to 1 V. Both the reset reaction time and the reset delay
time is defined by the capacitor value.
The power on reset delay time is defined by the charging time of an external delay capacitor CD.
CD = (td × ID) / ∆V
td = CD x ∆V / ID
With
CD
td
∆V
Ich
[1]
[2]
reset delay capacitor
reset delay time
= VDT, typical 1.8 V for power up reset
charge current typical 3.5 µA
For a delay capacitor CD =100 nF the typical power on reset delay time is 51 ms.
The reset reaction time tRR is the time it takes the voltage regulator to set reset output LOW after
the output voltage has dropped below the reset threshold. It is typically 1.2 µs for delay capacitor
of 100 nF. For other values for CD the reaction time can be estimated using the following
equation:
tRR ∼ 10 ns / nF × CD
Datasheet Rev. 1.0
14
[3]
2005-01-27
TLE 4299
VI
t
VQ
< t RR
V RT
dV I D
=
dt C D
VD
t
V DT
V ST
V RO
t RR
td
t
VRO, SAT
t
Power-on-Reset
Figure 8
Thermal
Shutdown
Voltage Dip
at Input
Undervoltage
Secondary
Spike
Overload
at Output
AED03107
Reset Timing Diagram
The reset output is an open collector output. An external pull-up can be added with a resistor value
of at least 5.6 kΩ.
In addition the reset switching threshold can be adjusted by an external voltage divider.
The feature is useful for microprocessors which guarantee safe operation down to voltages
below the internally set reset threshold of 3.10V typical. If the internal used reset threshold of
typical 3.10V is used, the pin RADJ has to beconnected to GND.
If a lower reset threshold is required by the system, a voltage divider defines the reset
threshold VRth between 2.5V and 3.10V as long as the Input Voltage VI>4.4V
VRth = VRADJ TH * (RADJ1 + RADJ2) / RADJ2 (3)
VRADJ TH is typical 1.36 V.
Datasheet Rev. 1.0
15
2005-01-27
TLE 4299
Early Warning
The early warning function compares a voltage defined by the user to an internal reference
voltage. Therefore the supervised voltage has to be scaled down by an external voltage divider in
order to compare it to the internal sense threshold of typical 1.36 V. The sense output pin is set
low, when the voltage at SI falls below this threshold.
A typical example where the circuit can be used is to supervise the input voltage VI to give the
microcontroller a prewarning of low battery condition.
Calculation to the voltage divider can be easily done since the sense input current can be
neglected.
Sense
Input
Voltage
VSI, High
VSI, Low
t
Sense
Output
t PD SO LH
t PD SO HL
High
Low
t
Figure 9
Sense Timing Diagram
VthHL = (RSI1 + RSI2)/RSI2 × VSI low
VthLH = (RSI1 + RSI2)/RSI2 × VSI high
[4]
[5]
The sense in comparator uses a hysteresis of typical 90 mV. This hysteresis of the supervised
threshold is multiplied by the resistor dividers amplification (RSI1 + RSI2)/RSI1.
The sense in comparator can also be used for receiving data with a threshold of typical 1.36 V and
a hysteresis of 90 mV. Of course also the data signal can be scaled down with a resistive divider
as shown above. With a typical delay time of 2.5 µs for positive transitions and 2.4 µs for negative
transitions receiving data of up to 100 kBaud are possible. The sense output is an open collector
output.
Datasheet Rev. 1.0
16
2005-01-27
TLE 4299
Current Consumption Iq versus Junction
Temperature Tj
Current Consumption Iq versus Output
Current IQ
2 _ IQ -IQ .V S D
12
1 _ I q - T j. v s d
I q [µ A ]
q
[m A ]
V I = 1 3 .5 V
100
IQ = 1 m A
10
8
T j = 1 5 0 °C
6
T j = 2 5 °C
4
T j = -4 0 °C
1
2
0 .0 1
-4 0 -2 0
20
0
40
60
40
0
80 100 120 140
80
120
160
T j [° C ]
Current Consumption Iq versus Input
Voltage VI
Output Voltage VQ versus Junction
Temperature Tj
3 _ IQ - V I . V S D
3
AED01671
3.5
T = 2 5 °C
Iq [m A ]
I Q [m A ]
VQ
V
3.4
V Ι = 13.5 V
2
3.3
1 .5
3.2
1
3.1
0 .5
3.0
IQ = 1 0 m A
IQ = 1 m A
0
10
20
30
2.9
-40
40
40
80
120 C 160
Tj
V I [V ]
Datasheet Rev. 1.0
0
17
2005-01-27
TLE 4299
Reverse Output Current IQ versus Output
Voltage VQ
Maximum Output Current IQ versus
Junction Temperature Tj
8 _ IQ M A X - T J .V S D
550
1 0 _ IQ -V Q .v s d
10
VI = 0 V
I Q [m A ]
I Q [m A ]
-2 0
T j = -4 0 °C
V I = 1 3 .5 V
450
T j = 2 5 °C
-4 0
T j = 1 5 0 °C
400
-6 0
350
-8 0
300
-1 0 0
250
-4 0 -2 0
20
0
40
60
80 100 120 140
0
20
10
30
40
T j [° C ]
V Q [V ]
Output Voltage VQ at Input Voltage
Extremes
Maximum Output Current IQ versus Input
Voltage VI
AED03110
350
Ι Q mA
VQ
AED01808
6
[V]
300
250
4
Tj = 25 C
200
3
150
Tj = 125 C
RL = 50 Ω
2
100
1
50
0
0
0
10
20
30
40 V 50
1
2
3
4
V 5
VΙ
VΙ
Datasheet Rev. 1.0
0
18
2005-01-27
TLE 4299
Power Supply Ripple Rejection PSRR
versus Frequency f
Region of Stability
12_ESR IQ _ 1 5 0 .V S D
100
CQ = 22µF
T j = 1 5 0 °C
E SR CQ
[Ω ]
1 3 _ P S R R .V S D
90
PSRR
[d B ]
V I= 6 V
10
IQ = 0 .1 m A
V I= 2 5 V
70
IQ = 1 m A
1
60
S t a b le
R e g io n
V I= 2 5 V
IQ = 1 0 m A
50
V I= 6 V
0 .1
V R IP P L E = 0 . 5 V
V IN = 1 3 . 5 V
C Q = 2 2 µ F T a n t a lu m
T j = 25 °C
40
0 .0 1
0
40
80
120
10
160
100
1k
IQ = 1 0 0 m A
100k
10k
f [H z ]
I Q [m A ]
Load Transient Response Peak Voltage DVQ
Region of Stability
1 2 _ E S R -IQ _ 4 0 .V S D
100
2 0 _ L o a d T r a n c ie n t v s tim e 1 2 5 .v s d
CQ = 22µF
T j = -4 0 °C
E SR CQ
[Ω ]
10
IQ 1 :1 0 0 m A
T j= 1 2 5 ° C
V i= 1 3 .5 V
V I= 6 V
V I= 2 5 V
1
S t a b le
R e g io n
VQ
V I= 2 5 V
V I= 6 V
0 .1
T = 1 µ s /D IV
0 .0 1
0
40
80
120
V Q = 1 0 0 m V /D IV
160
I Q [m A ]
Datasheet Rev. 1.0
19
2005-01-27
TLE 4299
Inhibit Input Current at Input Voltage
Extremes (INH=OFF)
Line Transient Response Peak Voltage DVQ
2 5 _ IIN H v s V IN IN H _ o ff.v s d
2 1 _ L in e T r a n c ie n t v s tim e 1 2 5 .v s d
I IN H
[µ A ]
50
T j= 1 2 5 ° C
V i= 1 3 .5 V
dVI 2V
IN H = O F F
40
30
VQ
T j = -4 0 ...1 5 0 ° C
20
10
T = 5 0 0 µ s/D IV
V Q = 5 0 m V /D IV
10
20
30
40
V IN [ V ]
Inhibut Input Current IINH at Inhibit Input
Voltage Extremes
Reset Trigger Threshold VRT versus
Junction Temperature Tj
2 4 _ IIN H v s V IN H .v s d
I IN H
2 6 _ V R T V S T E M P .V S D
3 .2 5
[µ A ]
50
V I = 1 3 .5 V
V RT
[V ]
40
3 .1 5
T j = 1 5 0 °C
30
3 .1 0
20
R e s e t T r ig g e r
T h r e s h o ld
T j = 2 5 °C
3 .0 5
T j = -4 0 °C
10
3 .0
10
20
30
40
-4 0 -2 0
V IN H [ V ]
0
20
40
60
80 100 120 140
T j [° C ]
Datasheet Rev. 1.0
20
2005-01-27
TLE 4299
Sense Threshold High versus Junction
Temperature Tj
Reset Delay Time TRD versus Junction
Temperature Tj
27_R ESETD ELAY VS
T E M P .V S D
60
V I = 1 3 .5 V
TRD
V I = 1 3 .5 V
V S I_ H i
[V ]
[m s ]
1 .5 0
50
C D = 100nF
45
1 .4 5
40
1 .4 0
35
1 .3 5
-4 0 -2 0
3 4 _ V S I_ H I V S T E M P .V S D
1 .6 0
0
20
40
60
-4 0 -2 0
80 100 120 140
0
20
40
60
T j [° C ]
T j [° C ]
Sense Threshold Low versus Junction
Temperature Tj
Delay Capacitor Charge Current versus
Junction Temperature Tj
2 7 A _ ID -T E M P .V S D
6
3 5 _ V S I_ L O V S T E M P .V S D
1 .5 0
V I = 1 3 .5 V
IC H
80 100 120 140
V I = 1 3 .5 V
V S I_ L o
[µ A ]
[V ]
4
1 .4 0
3
1 .3 5
2
1 .3 0
1
1 .2 5
-4 0 -2 0
0
20
40
60
80 100 120 140
-4 0 -2 0
T j [° C ]
Datasheet Rev. 1.0
0
20
40
60
80 100 120 140
T j [° C ]
21
2005-01-27
TLE 4299
Package Outlines
GPS05121
P-DSO-8-3 (SMD)
(Plastic Dual Small Outline)
Sorts of Packing
Package outlines for tubes, trays etc. are contained in our
Data Book “Package Information”
SMD = Surface Mounted Device
Datasheet Rev. 1.0
22
Dimensions in mm
2005-01-27
TLE 4299
GPS05093
P-DSO-14-8 (SMD)
(Plastic Dual Small Outline)
Sorts of Packing
Package outlines for tubes, trays etc. are contained in our
Data Book “Package Information”
SMD = Surface Mounted Device
Datasheet Rev. 1.0
23
Dimensions in mm
2005-01-27
TLE 4299
Edition 2005-01-27
Published by Infineon Technologies
AG,
St.-Martin-Strasse 53,
D-81541 München, Germany
© Infineon Technologies AG 2005.
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.
Datasheet Rev. 1.0
24
2005-01-27