INFINEON TLE7274D

5-V Low Drop Voltage Regulator
TLE 7274
Features
•
•
•
•
•
•
Output voltage 5 V ±2%
Ultra low current consumption: typ. 20µA
300 mA current capability
Very low-drop voltage
Short-circuit-proof
Suitable for use in automotive electronics
P-TO252-3-1
Functional Description
The TLE 7274 is a monolithic integrated low-drop
voltage regulator for load currents up to 300 mA. An input
voltage up to 42 V is regulated to VQ,nom = 5.0 V with a
precision of ±2%. The sophisticated design allows to
achieve stable operation even with ceramic output
capacitors down to 470 nF. The device is designed for
P-TO263-3-1
the harsh environment of automotive applications.
Therefore it is protected against overload, short circuit
and over temperature conditions. Of course the
TLE 7274 can be used also in all other applications,
where a stabilized 5 V voltage is required. Due to its ultra low stand-by current
consumption of typ. 20µA the TLE 7274 is dedicated for use in applications permanently
connected to VBAT. An integrated output sink current circuitry keeps the voltage at the
Output pin Q below 5.5 V even when reverse currents are applied. Thus connected
devices are protected from overvoltage damage.
For applications requiring extremely low noise levels the Infineon voltage regulator family
TLE 42XY and TLE 44XY is more suited than the TLE 7274. A mV-range output noise
on the TLE 7274 caused by the charge pump operation is unavoidable due to the ultra
low quiescent current concept.
Type
Ordering Code
Package
TLE 7274 D
Q67006-A9728
P-TO252-3-1, P-TO252-3-11
TLE 7274 G
Q67006-A9731
P-TO263-3-1
Data Sheet
1
Rev. 1.1, 2005-07-30
TLE 7274
TLE 7274
I
1
3
Q
Overtemperature
Shutdown
Bandgap
Reference
1
Charge
Pump
2, Tab
GND
Figure 1
Data Sheet
AEB03613.VSD
Block Diagram
2
Rev. 1.1, 2005-07-30
TLE 7274
GND
Ι
Q
AEP02512
Ι GND Q
AEP02281
Figure 2
Pin Configuration P-TO252-3 (D-PAK), P-TO263-3 (D2-PAK)(top view)
Table 1
Pin Definitions and Functions
Pin No.
Symbol
Function
1
I
Input; block to ground directly at the IC with a ceramic capacitor.
2
GND
Ground; Pin 2 internally connected to heatsink.
3
Q
Output; block to ground with a ceramic capacitor, C ≥ 470 nF.
Data Sheet
3
Rev. 1.1, 2005-07-30
TLE 7274
Table 2
Absolute Maximum Ratings
Parameter
Symbol
Limit Values
Unit
Test Condition
Min.
Max.
VI
II
-0.3
45
V
–
-1
–
mA
–
VQ
VQ
IQ
-0.3
5.5
V
–
-0.3
6.2
V
t < 10 s1)
-1
–
mA
–
Tj
Tstg
-40
150
°C
–
-50
150
°C
–
Input I
Voltage
Current
Output Q
Voltage
Voltage
Current
Temperature
Junction temperature
Storage temperature
1) Exposure to these absolute maximum ratings for extended periods (t > 10 s) may affect device reliability.
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.
Data Sheet
4
Rev. 1.1, 2005-07-30
TLE 7274
Table 3
Operating Range
Parameter
Symbol
Input voltage
Junction temperature
Limit Values
VI
Tj
Unit
Remarks
Min.
Max.
5.5
42
V
–
-40
150
°C
–
Note: In the operating range, the functions given in the circuit description are fulfilled.
Table 4
Thermal Resistance
Parameter
Junction case
Junction ambient
Rthj-c
Rthj-a
Rthj-a
Limit Values
Unit Remarks
Min.
Max.
–
8
K/W –
–
80
K/W TO2521)
K/W TO2632)
Worst case, regarding peak temperature; zero airflow; mounted on a PCB FR4, 80 × 80 × 1.5 mm3, heat sink
Junction ambient
1)
Symbol
–
55
area 300 mm2
2) Worst case, regarding peak temperature; zero airflow; mounted on a PCB FR4, 80
area 300 mm2
× 80 × 1.5 mm3, heat sink
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.
Data Sheet
5
Rev. 1.1, 2005-07-30
TLE 7274
Table 1
Electrical Characteristics
VI = 13.5 V; – 40 °C < Tj < 150 °C (unless otherwise specified)
Parameter
Symbol
Limit Values
Min.
Typ. Max.
Unit
Measuring Condition
Output Q
Output voltage
VQ
4.9
5.0
5.1
V
0.1 mA < IQ < 300 mA;
6 V < VI < 16 V
Output voltage
VQ
4.9
5.0
5.1
V
0.1 mA < IQ < 100 mA;
6 V < VI < 40 V
Output current limitation IQ
320
–
–
mA
1)
Output current limitation IQ
–
–
800
mA
Current consumption;
Iq = II - IQ
Iq
–
20
25
µA
Current consumption;
Iq = II - IQ
Iq
–
–
35
µA
Drop voltage
Vdr
–
250
500
mV
Load regulation
∆VQ, lo
-40
15
40
mV
Line regulation
∆VQ, li
-20
5
20
mV
Power supply ripple
rejection
PSRR
–
60
–
dB
VQ = 0V
IQ = 0.1 mA;
Tj = 25 °C
IQ = 0.1 mA;
Tj ≤ 80 °C
IQ = 200 mA;
Vdr = VI - VQ1)
IQ = 5 mA to 250 mA
Vl = 10V to 32 V;
IQ = 5 mA
fr = 100 Hz;
Vr = 0.5 Vpp
Temperature output
voltage drift
dVQ/dT
–
0.5
–
mV/K –
Output Capacitor
CQ
470
–
–
nF
ESR < 3 Ω
1) Measured when the output voltage VQ has dropped 100 mV from the nominal value obtained at VI = 13.5 V.
Data Sheet
6
Rev. 1.1, 2005-07-30
TLE 7274
Application Information
VBat
TLE 7274
VCC
Q 3
1 I
100
nF
470 +
nF
Overtemperature
Shutdown
Bandgap
Reference
4.7
µF
1
Charge
Pump
2, Tab
GND
Figure 3
AEA03614.VSD
Application Diagram
Input, Output
An input capacitor is necessary for damping line influences. A resistor of approx. 1 Ω in
series with CI, can damp the LC of the input inductivity and the input capacitor.
In contrast to most low drop voltage regulators the TLE 7274 only needs moderate
capacitance at the output to assure stability of the regulation loop. This offers more
design flexibility to the circuit designer providing for cost efficient solutions.
The TLE 7274 requires a ceramic output capacitor of at least 470 nF. In order to damp
influences resulting from load current surges it is recommended to add an additional
electrolytic capacitor of 4.7 µF to 47 µF at the output as shown in Figure 3.
Data Sheet
7
Rev. 1.1, 2005-07-30
TLE 7274
Additionally a buffer capacitor CB of > 10µF should be used for the output to suppress
influences from load surges to the voltage levels. This one can either be an aluminum
electrolytic capacitor or a tantalum capacitor following the application requirements.
A general recommendation is to keep the drop over the equivalent serial resistor (ESR)
together with the discharge of the blocking capacitor below the allowed Headroom of
the Application to be supplied (e.g. typ. dVQ = 350mV).
Since the regulator output current roughly rises linearly with time the discharge of the
capacitor can be calculated as follows:
dVCB = dIQ*dt/CB
The drop across the ESR calculates as:
dVESR = dI*ESR
To prevent a reset the following relationship must be fullfilled:
dVC + dVESR < VRH = 350mV
Example: Assuming a load current change of CB = 100mA, a blocking capacitor of dIQ =
22µF and a typical regulator reaction time under normal operating conditions of dt ~
25µs and for special dynamic load conditions, such as load step from very low base
load, a reaction time of dt ~ 75µs..
dVC = dIQ*dt/CB = 100mA * 25µs/22µF = 113mV
So for the ESR we can allow
dVESR = VRH2 - dVC = 350mV - 113mV = 236mV
The permissible ESR becomes:
ESR = dVESR / dIQ = 236mV/100mA = 2.36Ohm
During design-in of the TLE7469 product family, special care needs to be taken with
regards to the regulators reaction time to sudden load current changes starting from very
low pre-load as well as cyclic load changes. The application note “TLE7x Voltage
Regulators - Application Note about Transient Response at ultra low quiescent current
Voltage Regulators” (see 3_cip05405.pdf) gives important hints for successful design-in
of the Voltage Regulators of the TLE7x family.
Data Sheet
8
Rev. 1.1, 2005-07-30
TLE 7274
Typical Performance Characteristics
Current Consumption Iq versus
Junction Temperature Tj
Current Consumption Iq versus Input
Voltage VI
1 _ I q - T j. v s d
3 _ IQ -V I.V S D
Iq [µ A ]
T j = 2 5 °C
I q [µ A ]
V I = 1 3 .5 V
100
40
IQ = 1 0 0 µ A
IQ = 5 0 m A
10
30
IQ = 1 0 m A
IQ = 0 .2 m A
20
1
10
0 .0 1
-4 0 -2 0
0
20
40
60
0
80 100 120 140
20
10
30
V I [V ]
T j [° C ]
Current Consumption Iq versus Output
Current IQ
Output Voltage VQ versus Junction
Temperature Tj
5 A _ V Q -T J .V S D
2 _ IQ - IQ .V S D
30
I q [µ A ]
40
V I = 1 3 .5 V
V Q [V ]
V I = 1 3 .5 V
T j = 2 5 °C
T j = -4 0 °C
20
5 .0 5
15
5 .0 0
10
4 .9 5
5
4 .9 0
0
20
40
60
-4 0 -2 0
100
I Q [m A ]
Data Sheet
IQ = 1 0 0 µ A ...1 0 0 m A
0
20
40
60
80 100 120 140
T j [° C ]
9
Rev. 1.1, 2005-07-30
TLE 7274
Dropout Voltage Vdr versus Output
Current IQ
Maximum Output Current IQ versus
Junction Temperature Tj
6 _ V D R -IQ .V S D
600
8 _ IQ M A X - T J .V S D
620
V d r [m V ]
V I = 1 3 .5 V
I Q [m A ]
T j = 1 5 0 °C
400
580
T j = 2 5 °C
300
560
540
200
T j = -4 0 °C
520
100
100
0
200
500
-4 0 -2 0
300
0
20
40
60
80 100 120 140
T j [° C ]
I Q [m A ]
Dropout Voltage Vdr versus Junction
Temperature Tj
Maximum Output Current IQ versus
Input Voltage VI
7 _ V D R -T J .V S D
600
9 _ S O A .V S D
600
T j = 1 2 5 °C
I Q [m A ]
V d r [m V ]
I Q lim
T j = 2 5 °C
IQ = 2 5 0 m A
400
400
300
300
IQ = 1 5 0 m A
200
200
P v m a x = 1 ,1 8 W f o r T O 2 5 2 @
3 0 0 m m 2 c o o lin g a re a
100
100
IQ = 1 0 m A
-4 0 -2 0
0
20
40
60
80 100 120 140
0
T j [° C ]
Data Sheet
10
20
30
40
V I [V ]
10
Rev. 1.1, 2005-07-30
TLE 7274
Region of Stability
Output Voltage VQ Start-up behaviour
1 4 _ V It im e _ s t a r t u p . v s d
1 2 _ E S R -IQ .V S D
100
C Q = 1 0 n F ...1 0 µ F
T j = 2 5 °C
E SR CQ
[Ω]
V Q [V ]
IN H = O N
10
5 .0 5
1
IQ = 5 m A
5 .0 0
S t a b le
R e g io n
4 .9 0
0 .1
4 .8 0
0 .0 1
0
50
100
150
200
2
1
3
t [m s ]
Power Supply Ripple Rejection PSRR
versus Frequency f
Load Regulation dVQ versus Output
Current Change dIQ
1 3 _ P S R R .V S D
80
5
4
I Q [m A ]
1 8 a _ d V Q - d I Q _ V i6 V . v s d
0
VI = 6V
∆VQ
PSRR
[m V ]
[d B ]
I Q = 0 .1 m A
60
-1 0
IQ = 3 0 m A
T j = -4 0 °C
IQ = 1 0 0 m A
-1 5
50
T j = 2 5 °C
-2 0
40
V R IP P L E = 1 V
V IN = 1 3 . 5 V
C Q = 1 0 µ F T a n t a lu m
T j = 2 5 °C
30
10
100
1k
10k
-3 0
100k
0
50
100
150
250
IQ [m A ]
f [H z ]
Data Sheet
T j = 1 5 0 °C
-2 5
11
Rev. 1.1, 2005-07-30
TLE 7274
Load Regulation dVQ versus Output
Current Change dIQ
Line Regulation dVQ versus Input
Voltage ChangedVI
1 8 b _ d V Q - d I Q _ V i1 3 5 V . v s d
0
V I = 1 3 .5 V
∆VQ
1 9 _ d V Q -d V I_ _ 1 5 0 C .v s d
0
∆VQ
[m V ]
IQ = 1 m A
[m V ]
-1 0
T j = 1 5 0 °C
IQ = 1 0 0 m A
IQ = 1 0 m A
-2
-1 5
-3
T j = -4 0 °C
T j = 2 5 °C
-2 0
-4
-2 5
-5
IQ = 2 0 0 m A
T j = 1 5 0 °C
-3 0
0
50
100
150
-6
250
0
5
10
15
20
25
30
35
40
IQ [m A ]
V I [V ]
Load Regulation dVQ versus Output
Current Change dIQ
Line Regulation dVQ versus Input
Voltage ChangedVI
1 8 c _ d V Q - d I Q _ V i2 8 V . v s d
0
1 9 _ d V Q -d V I_ 2 5 C .v s d
0
VI = 28
∆VQ
45
T j = 2 5 °C
∆VQ
[m V ]
[m V ]
IQ = 1 m A
-2
-1 0
IQ = 1 0 m A
IQ = 1 0 0 m A
IQ = 2 0 0 m A
-3
-1 5
T j = -4 0 °C
-2 0
-4
T j = 2 5 °C
-2 5
-5
T j = 1 5 0 °C
-3 0
0
50
100
150
-6
250
IQ [m A ]
Data Sheet
0
5
10
15
20
25
30
35
40
45
V I [V ]
12
Rev. 1.1, 2005-07-30
TLE 7274
Line Regulation dVQ versus Input
Voltage ChangedVI
Load Transient Response Peak Voltage
dVQ
1 9 _ d V Q -d V I_ -4 0 C .v s d
0
T j = 4 0 °C
∆VQ
2 0 _ L o a d T r a n c ie n t v s tim e 2 5 .v s d
[m V ]
IQ 1 :1 0 0 m A
T j= 2 5 ° C
V i = 1 3 .5 V
IQ = 1 m A
-2
IQ = 1 0 m A
IQ = 1 0 0 m A
-3
IQ = 2 0 0 m A
-4
VQ
-5
-6
0
10
5
15
20
25
30
35
40
T = 4 0 µ s/D IV
45
V Q = 1 0 0 m V /D IV
V I [V ]
Load Transient Response Peak Voltage
dVQ
Line Transient Response Peak Voltage
dVQ
2 0 _ L o a d T r a n c ie n t v s tim e 1 2 5 .v s d
IQ 1 :1 0 0 m A
2 1 _ L in e T r a n c ie n t v s tim e 2 5 .v s d
T j= 1 2 5 ° C
V i = 1 3 .5 V
dVI 2V
T j= 2 5 ° C
V i = 1 3 .5 V
VQ
VQ
T = 4 0 µ s/D IV
Data Sheet
V Q = 1 0 0 m V /D IV
T = 4 0 0 µ s /D IV
13
V Q = 5 0 m V /D IV
Rev. 1.1, 2005-07-30
TLE 7274
Line Transient Response Peak Voltage
dVQ
2 1 _ L in e T r a n c ie n t v s tim e 1 2 5 .v s d
dVI 2V
T j= 1 2 5 ° C
V i = 1 3 .5 V
VQ
T = 4 0 0 µ s /D IV
Data Sheet
V Q = 5 0 m V /D IV
14
Rev. 1.1, 2005-07-30
TLE 7274
Package Outlines
6.5 +0.15
-0.10
2.3 +0.05
-0.10
4.57
0.51 min
0.15 max
per side
0.9 +0.08
-0.04
B
5.4 ±0.1
0.8 ±0.15
9.9 ±0.5
6.22 -0.2
1 ±0.1
A
3x
0.75 ±0.1
0...0.15
0.5 +0.08
-0.04
2.28
1 ±0.1
0.25
M
A B
0.1
GPT09051
All metal surfaces tin plated, except area of cut.
Figure 4
Data Sheet
P-TO252-3-1 (Plastic Transistor Single Outline)
15
Rev. 1.1, 2005-07-30
TLE 7274
6.5 +0.15
-0.05
A
B
(5)
0.5 +0.08
-0.04
0.9 +0.20
-0.01
0...0.15
0.51 min.
0.15 max.
per side
2.3 +0.05
-0.10
0.8 ±0.15
(4.24) 1 ±0.1
9.98 ±0.5
6.22 -0.2
5.4 ±0.1
3x
0.75 ±0.1
0.5 +0.08
-0.04
2.28
4.57
0.1 B
0.25
M
A B
All metal surfaces tin plated, except area of cut.
GPT09277
Figure 5
P-TO252-3-11 (Plastic Transistor Single Outline)
2.2
6.4
10.6
5.8
1.2
5.76
Figure 6
Data Sheet
Foot Print for P-TO-252-3-1 and P-TO-252-3-11 (Plastic Transistor
Single Outline)
16
Rev. 1.1, 2005-07-30
TLE 7274
4.4
10 ±0.2
1.27 ±0.1
B
0.1
A
8.5 1)
0.05
2.4
2.7 ±0.3
4.7 ±0.5
7.55 1)
(15)
9.25 ±0.2
1 ±0.3
0...0.3
0...0.15
0.75 ±0.1
0.5 ±0.1
1.05
8 ˚ MAX.
2.54
5.08
1)
Figure 7
0.25
M
A B
0.1 B
Typical
All metal surfaces: tin plated, except area of cut.
Metal surface min. x=7.25, y=6.9
P-TO263-3-1 (Plastic Transistor Single Outline)
4.6
16.15
9.4
10.8
1.39
1.15
6.23
Figure 8
Foot Print for P-TO263-3-1 (Plastic Transistor Single Outline)
You can find all of our packages, sorts of packing and others in our
Infineon Internet Page “Products”: http://www.infineon.com/products.
Data Sheet
17
Dimensions in mm
Rev. 1.1, 2005-07-30
TLE 7274
Remarks
Data Sheet
18
Rev. 1.1, 2005-07-30
Edition 2005-07-30
Published by Infineon Technologies AG,
St.-Martin-Strasse 53,
81669 München, Germany
© Infineon Technologies AG 2004.
All Rights Reserved.
Attention please!
The information herein is given to describe certain components and shall not be considered as a guarantee of
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.
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For further information on technology, delivery terms and conditions and prices please contact your nearest
Infineon Technologies Office (www.infineon.com).
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