L7824 [STMICROELECTRONICS]
POSITIVE VOLTAGE REGULATORS; 正电压稳压器型号: | L7824 |
厂家: | ST |
描述: | POSITIVE VOLTAGE REGULATORS |
文件: | 总25页 (文件大小:264K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
L7800
SERIES
POSITIVE VOLTAGE REGULATORS
■
■
OUTPUT CURRENT UP TO 1.5 A
OUTPUT VOLTAGES OF 5; 5.2; 6; 8; 8.5; 9;
12; 15; 18; 24V
■
■
■
THERMAL OVERLOAD PROTECTION
SHORT CIRCUIT PROTECTION
OUTPUT TRANSITION SOA PROTECTION
DESCRIPTION
1
3
The L7800 series of three-terminal positive
regulators is available in TO-220 ISOWATT220
TO-3 and D2PAK packages and several fixed
output voltages, making it useful in a wide range
of applications.Theseregulators can provide local
on-card regulation, eliminating the distribution
problems associated with single point regulation.
Each type employs internal current limiting,
thermal shut-down and safe area protection,
making it essentially indestructible. If adequate
heat sinking is provided, they can deliver over 1A
output current. Although designed primarily as
fixed voltage regulators, these devices can be
used with external components to obtain
adjustablevoltages and currents.
1
2
TO-3
D2PAK
3
3
2
2
1
1
TO-220
ISOWATT220
BLOCK DIAGRAM
1/25
January 1997
L7800
ABSOLUTE MAXIMUM RATINGS
Symbol
Parameter
DC Input Voltage (for VO = 5 to 18V)
(for VO = 20, 24V)
Value
Unit
Vi
35
40
V
V
Io
Output Current
Internally limited
Internally limited
Ptot
Top
Power Dissipation
Operating Junction Temperature Range (for L7800)
(for L7800C)
- 55 to 125
0 to 150
oC
oC
Tstg
Storage Temperature Range
- 40 to 150
oC
THERMAL DATA
Symbol
Parameter
D2PAK
TO-220
ISOWATT220
TO-3
Unit
Rthj-case Thermal Resistance Junction-case
Rthj-amb Thermal Resistance Junction-ambient Max
Max
3
62.5
3
50
4
60
4
35
oC/W
oC/W
CONNECTION DIAGRAM AND ORDERING NUMBERS (top view)
TO-220 & ISOWATT220
TO-220
D2PAK
TO-3
Type
L7805
L7805C
L7852C
L7806
D2PAK (*)
ISOWATT220
TO-3
Output Voltage
L7805T
5V
5V
5.2V
L7805CV
L7852CV
L7805CD2T
L7852CD2T
L7805CP
L7852CP
L7805CT
L7852CT
L7806T
6V
L7806C
L7806CV
L7806CD2T
L7806CP
L7806CT
6V
L7808
L7808T
8V
L7808C
L7885C
L7809C
L7812
L7812C
L7815
L7815C
L7818
L7818C
L7820
L7808CV
L7885CV
L7809CV
L7808CD2T
L7885CD2T
L7809CD2T
L7808CP
L7885CP
L7809CP
L7808CT
L7885CT
L7809CT
L7812T
L7812CT
L7815T
L7815CT
L7818T
L7818CT
L7820T
8V
8.5V
9V
12V
12V
15V
15V
18V
18V
20V
20V
24V
24V
L7812CV
L7815CV
L7818CV
L7820CV
L7824CV
L7812CD2T
L7815CD2T
L7818CD2T
L7820CD2T
L7824CD2T
L7812CP
L7815CP
L7818CP
L7820CP
L7824CP
L7820C
L7824
L7824C
L7820CT
L7824T
L7824CT
(*) AVAILABLE IN TAPE AND REEL WITH ”-TR” SUFFIX
2/25
L7800
APPLICATION CIRCUIT
SCHEMATIC DIAGRAM
3/25
L7800
TEST CIRCUITS
Figure 1 : DC Parameter
Figure 2 : Load Regulation.
Figure 3 : Ripple Rejection.
4/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7805 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 10V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
4.8
Typ.
Max.
5.2
Unit
V
Tj = 25 oC
5
5
Vo
Io = 5 mA to 1 A Po ≤ 15 W
4.65
5.35
V
Vi = 8 to 20 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 7 to 25 V Tj = 25 oC
3
1
50
25
mV
mV
Vi = 8 to 12 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
100
25
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 8 to 25 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
0.6
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 8 to 18 V
f = 120 Hz
68
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
17
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
ELECTRICAL CHARACTERISTICS FOR L7806 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 15V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
5.75
5.65
Typ.
Max.
6.25
6.35
Unit
V
Vo
Tj = 25 oC
6
6
Vo
Io = 5 mA to 1 A Po ≤ 15 W
V
Vi = 9 to 21 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 8 to 25 V Tj = 25 oC
60
30
mV
mV
Vi = 9 to 13 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
100
30
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 9 to 25 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
0.7
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 9 to 19 V
f = 120 Hz
65
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
19
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
5/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7808 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 14V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
7.7
Typ.
Max.
8.3
Unit
V
Tj = 25 oC
8
8
Vo
Io = 5 mA to 1 A Po ≤ 15 W
7.6
8.4
V
Vi = 11.5 to 23 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 10.5 to 25 V Tj = 25 oC
80
40
mV
mV
Vi = 11 to 17 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
100
40
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 11.5 to 25 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
1
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 11.5 to 21.5 V
f = 120 Hz
62
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
16
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
ELECTRICAL CHARACTERISTICS FOR L7812 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 19V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
11.5
11.4
Typ.
Max.
12.5
12.6
Unit
V
Vo
Tj = 25 oC
12
Vo
Io = 5 mA to 1 A Po ≤ 15 W
12
V
Vi = 15.5 to 27 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 14.5 to 30 V Tj = 25 oC
120
60
mV
mV
Vi = 16 to 22 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
100
60
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 15 to 30 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
1.5
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 15 to 25 V
f = 120 Hz
61
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
18
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
6/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7815 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 23V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
14.4
Typ.
15
Max.
15.6
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
14.25
15
15.75
V
Vi = 18.5 to 30 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 17.5 to 30 V Tj = 25 oC
150
75
mV
mV
Vi = 20 to 26 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
150
75
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 18.5 to 30 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
1.8
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 18.5 to 28.5 V
f = 120 Hz
60
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
19
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
ELECTRICAL CHARACTERISTICS FOR L7818 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 26V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
17.3
17.1
Typ.
Max.
18.7
18.9
Unit
V
Vo
Tj = 25 oC
18
Vo
Io = 5 mA to 1 A Po ≤ 15 W
18
V
Vi = 22 to 33 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 21 to 33 V Tj = 25 oC
180
90
mV
mV
Vi = 24 to 30 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
180
90
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 22 to 33 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
2.3
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 22 to 32 V
f = 120 Hz
59
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
22
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
7/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7820 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 28V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
19.2
19
Typ.
20
Max.
20.8
21
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
20
V
Vi = 24 to 35 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 22.5 to 35 V Tj = 25 oC
200
100
mV
mV
Vi = 26 to 32 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
200
100
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 24 to 35 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
2.5
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 24 to 35 V
f = 120 Hz
58
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
24
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
ELECTRICAL CHARACTERISTICS FOR L7824 (refer to the test circuits, Tj = -55 to 150 oC,
Vi = 33V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
Typ.
Max.
Unit
V
Vo
Tj = 25 oC
23
24
25
Vo
Io = 5 mA to 1 A Po ≤ 15 W
22.8
24
25.2
V
Vi = 28 to 38 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 27 to 38 V Tj = 25 oC
240
120
mV
mV
Vi = 30 to 36 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
240
120
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
6
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 28 to 38 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
3
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
40
µV/VO
dB
V
SVR Supply Voltage Rejection
Vi = 28 to 38 V
f = 120 Hz
56
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
2.5
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
28
mΩ
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
0.75
2.2
1.2
3.3
Iscp
1.3
A
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
8/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7805C (refer to the test circuits, Tj = 0 to 125 oC,
Vi = 10V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
4.8
Typ.
Max.
5.2
Unit
V
Tj = 25 oC
5
5
Vo
Io = 5 mA to 1 A Po ≤ 15 W
4.75
5.25
V
Vi = 7 to 20 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 7 to 25 V Tj = 25 oC
3
1
100
50
mV
mV
Vi = 8 to 12 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
100
50
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 7 to 25 V
Io = 5 mA
0.5
0.8
mA
mV/oC
∆Vo
∆T
-1.1
40
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 8 to 18 V
f = 120 Hz
Tj = 25 oC
62
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
17
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
750
2.2
Iscp
ELECTRICAL CHARACTERISTICS FOR L7852C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 10V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
Typ.
Max.
Unit
Vo
Tj = 25 oC
5.0
5.2
5.4
V
Vo
Io = 5 mA to 1 A Po ≤ 15 W
4.95
5.2
5.45
V
Vi = 8 to 20 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 7 to 25 V Tj = 25 oC
3
1
105
52
mV
mV
Vi = 8 to 12 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
105
52
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 7 to 25 V
Io = 5 mA
0.5
1.3
mA
mV/oC
∆Vo
∆T
-1.0
42
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 8 to 18 V
f = 120 Hz
Tj = 25 oC
61
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
17
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
750
2.2
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
9/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7806C (refer to the test circuits, Tj = 0 to 125 oC,
Vi = 11V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unlessotherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
5.75
5.7
Typ.
Max.
6.25
6.3
Unit
V
Tj = 25 oC
6
6
Vo
Io = 5 mA to 1 A Po ≤ 15 W
V
Vi = 8 to 21 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 8 to 25 V Tj = 25 oC
120
60
mV
mV
Vi = 9 to 13 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
120
60
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 8 to 25 V
Io = 5 mA
0.5
1.3
mA
mV/oC
∆Vo
∆T
-0.8
45
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 9 to 19 V
f = 120 Hz
Tj = 25 oC
59
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
19
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
550
2.2
Iscp
ELECTRICAL CHARACTERISTICS FOR L7808C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 14V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
Typ.
Max.
Unit
Vo
Tj = 25 oC
7.7
8
8
8.3
V
Vo
Io = 5 mA to 1 A Po ≤ 15 W
7.6
8.4
V
Vi = 10.5 to 25 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 10.5 to 25 V Tj = 25 oC
160
80
mV
mV
Vi = 11 to 17 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
160
80
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 10.5 to 25 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-0.8
52
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 11.5 to 21.5 V
f = 120 Hz
Tj = 25 oC
56
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
16
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
450
2.2
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
10/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7885C (refer to the test circuits, Tj = 0 to 125 oC, Vi =
14.5V, Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
8.2
Typ.
8.5
Max.
8.8
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
8.1
8.5
8.9
V
Vi = 11 to 26 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 11 to 27 V Tj = 25 oC
160
80
mV
mV
Vi = 11.5 to 17.5 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
160
80
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 11 to 27 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-0.8
55
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 12 to 22 V
f = 120 Hz
Tj = 25 oC
56
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
16
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
450
2.2
Iscp
ELECTRICAL CHARACTERISTICS FOR L7809C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 15V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
8.65
8.55
Typ.
Max.
9.35
9.45
Unit
Vo
Tj = 25 oC
9
9
V
Vo
Io = 5 mA to 1 A Po ≤ 15 W
V
Vi = 11.5 to 26 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 11.5 to 26 V Tj = 25 oC
180
90
mV
mV
Vi = 12 to 18 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
180
90
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 11.5 to 26 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1.0
70
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 12 to 23 V
f = 120 Hz
Tj = 25 oC
55
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
17
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
400
2.2
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
11/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7812C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 19V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
11.5
11.4
Typ.
12
Max.
12.5
12.6
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
12
V
Vi = 14.5 to 27 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 14.5 to 30 V Tj = 25 oC
240
120
mV
mV
Vi = 16 to 22 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
240
120
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 14.5 to 30 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
75
µV
dB
V
SVR Supply Voltage Rejection
Vi = 15 to 25 V
f = 120 Hz
55
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
18
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
350
2.2
Iscp
ELECTRICAL CHARACTERISTICS FOR L7815C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 23V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
Typ.
Max.
Unit
Vo
Tj = 25 oC
14.4
15
15.6
V
Vo
Io = 5 mA to 1 A Po ≤ 15 W
14.25
15
15.75
V
Vi = 17.5 to 30 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 17.5 to 30 V Tj = 25 oC
300
150
mV
mV
Vi = 20 to 26 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
300
150
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 17.5 to 30 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
90
µV
dB
V
SVR Supply Voltage Rejection
Vi = 18.5 to 28.5 V
f = 120 Hz
54
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
19
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
230
2.1
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
12/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7818C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 26V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
17.3
17.1
Typ.
18
Max.
18.7
18.9
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
18
V
Vi = 21 to 33 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 21 to 33 V Tj = 25 oC
360
180
mV
mV
Vi = 24 to 30 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
360
180
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 21 to 33 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
110
µV
dB
V
SVR Supply Voltage Rejection
Vi = 22 to 32 V
f = 120 Hz
53
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
22
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
200
2.1
Iscp
ELECTRICAL CHARACTERISTICS FOR L7820C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 28V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
19.2
19
Typ.
Max.
20.8
21
Unit
Vo
Tj = 25 oC
20
V
Vo
Io = 5 mA to 1 A Po ≤ 15 W
20
V
Vi = 23 to 35 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 22.5 to 35 V Tj = 25 oC
400
200
mV
mV
Vi = 26 to 32 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
400
200
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 23 to 35 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
150
µV
dB
V
SVR Supply Voltage Rejection
Vi = 24 to 35 V
f = 120 Hz
52
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
Tj = 25 oC
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
24
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
180
2.1
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
13/25
L7800
ELECTRICAL CHARACTERISTICS FOR L7824C (refer to the test circuits, Tj = 0 to 125 oC, Vi = 33V,
Io = 500 mA, Ci = 0.33 µF, Co = 0.1 µF unless otherwise specified)
Symbol
Vo
Parameter
Output Voltage
Output Voltage
Test Conditions
Min.
23
Typ.
24
Max.
25
Unit
V
Tj = 25 oC
Vo
Io = 5 mA to 1 A Po ≤ 15 W
22.8
24
25.2
V
Vi = 27 to 38 V
∆Vo* Line Regulation
∆Vo* Load Regulation
Vi = 27 to 38 V Tj = 25 oC
480
240
mV
mV
Vi = 30 to 36 V Tj = 25 oC
Io = 5 to 1500 mA
Tj = 25 oC
480
240
mV
mV
Io = 250 to 750 mA T = 25 oC
j
Id
Quiescent Current
Tj = 25 oC
8
0.5
1
mA
mA
∆Id
∆Id
Quiescent Current Change
Quiescent Current Change
Output Voltage Drift
Io = 5 to 1000 mA
Vi = 27 to 38 V
Io = 5 mA
mA
mV/oC
∆Vo
∆T
-1.5
170
eN
Output Noise Voltage
B = 10Hz to 100KHz Tj = 25 oC
µV
dB
V
SVR Supply Voltage Rejection
Vi = 28 to 38 V
f = 120 Hz
Tj = 25 oC
50
Vd
Ro
Isc
Dropout Voltage
Io = 1 A
2
Output Resistance
f = 1 KHz
Vi = 35 V
Tj = 25 oC
28
mΩ
mA
A
Short Circuit Current
Short Circuit Peak Current
Tj = 25 oC
150
2.1
Iscp
* Load and line regulation are specified at constant junction temperature. Changes in Vo due to heating effects must be taken into account
separately. Pulce testing with low duty cycle is used.
14/25
L7800
Figure 4 : Dropout Voltage vs. Junction
Figure 5 : Peak Output Current vs. Input/output
Temperature.
Differential Voltage.
Figure 6 : Supply Voltage Rejection vs.
Figure 7 : Output Voltage vs. Junction
Frequency.
Temperature.
Figure 8 : Output Impedance vs. Frequency.
Figure 9 : Quiescent Current vs. Junction
Temperature.
15/25
L7800
Figure 10 : Load Transient Response.
Figure 11 : Line Transient Response.
Figure 12 : Quiescent Current vs. Input
Voltage.
Figure 13 : Fixed Output Regulator.
Figure 14 : Current Regulator.
V
R 1
XX
IO
=
+ I d
NOTE:
1. To specify an output voltage, substitute voltage value for ”XX”.
2. Although no output capacitor is need for stability, it does
improve transient response.
3. Required if cregulator is locate an appreciable distance from
power supply filter.
16/25
L7800
Figure 15 : Circuit for Increasing Output
Figure 16 : Adjustable Output Regulator
Voltage.
(7 to 30V).
I
R1 ≥ 5 Id
R 2
R 1
VO = V XX (1 +
) + I d R 2
Figure 17 : 0.5 to 10V Regulator.
Figure 18 : High Current Voltage Regulator.
V BEQ1
R1
=
I Q1
I REQ
−
β Q1
V BEQ1
R 1
IO = I REG + Q 1 (I REG
−
)
R 4
VO = V XX
R 1
17/25
L7800
Figure 19 : High Output Current with Short
Figure 20 : Tracking Voltage Regulator.
Figure 22 : Negative Output Voltage Circuit.
Figure 24 : High Input Voltage Circuit.
Circuit Protection.
V BEQ2
I SC
RSC
=
Figure 21 : Split Power Supply (± 15V – 1A).
* Against potential latch-up problems.
Figure 23 : Switching Regulator.
VIN = Vi - (VZ + VBE
)
18/25
L7800
Figure 25 : High Input Voltage Circuit.
Figure 26 : High Output Voltage Regulator.
Figure 27 : High Input and Output Voltage.
Figure 28 : Reducing Power Dissipation with
Dr opping Resistor.
V
− V XX − V
DROP(max)
i(min)
VO = VXX + VZ1
R =
I O(max) + I d(max)
Figure 29 : Remote Shutdown.
19/25
L7800
Figure 30 : Power AM Modulator (unity voltage
Figure 31 : Adjustable Output Voltage with
gain, Io < 1A).
TemperatureCompensation.
R 2
R 1
VO = V XX (1 +
) + V
BE
NOTE: The circuit performs well up to 100KHz
NOTE: Q2 is connected as a diode in order to compensate the
variation of the Q1 VBE with the temperature. C allows a slow rise-
time of the Vo
Figure 32 : Light Controllers (Vo min = Vxx + VBE).
VO rises when the light goes up
VO falls when the light goes up
Figure 33 : Protection against Input Short-circuit
with High Capacitance Loads.
Application with high capacitance loads and an output voltage
greater than 6 volts need an external diode (see fig. 33) to protect
the deviceagainst input short circuit. In this case the input voltage
falls rapidly while the output voltage decrease slowly. The
capacitance dischrges by means of the Base-Emitter junction of
the series pass transistor in the regulator. If the energy is
sufficently high, the transistor may be destroyed. The external
diode by-passes the current from the IC to ground.
20/25
L7800
TO-3 (R) MECHANICAL DATA
mm
inch
TYP.
0.460
DIM.
MIN.
TYP.
MAX.
MIN.
MAX.
A
B
C
D
E
G
N
P
R
U
V
11.7
0.96
1.10
1.70
8.7
0.037
0.043
0.066
0.342
0.787
20.0
10.9
16.9
0.429
0.665
26.2
4.09
1.031
0.161
1.555
3.88
0.152
39.50
30.10
1.185
A
D
P
C
G
R
P003N
21/25
L7800
TO-220 MECHANICAL DATA
mm
inch
TYP.
DIM.
MIN.
4.40
1.23
2.40
TYP.
MAX.
4.60
1.32
2.72
MIN.
0.173
0.048
0.094
MAX.
0.181
0.051
0.107
A
C
D
D1
E
1.27
0.050
0.49
0.61
1.14
1.14
4.95
2.4
0.70
0.88
1.70
1.70
5.15
2.7
0.019
0.024
0.044
0.044
0.194
0.094
0.393
0.027
0.034
0.067
0.067
0.203
0.106
0.409
F
F1
F2
G
G1
H2
L2
L4
L5
L6
L7
L9
DIA.
10.0
10.40
16.4
0.645
13.0
2.65
15.25
6.2
14.0
2.95
15.75
6.6
0.511
0.104
0.600
0.244
0.137
0.147
0.551
0.116
0.620
0.260
0.154
0.151
3.5
3.93
3.85
3.75
L2
Dia.
L5
L9
L7
L6
L4
P011C
22/25
L7800
ISOWATT220 MECHANICAL DATA
mm
inch
TYP.
DIM.
MIN.
4.4
TYP.
MAX.
4.6
2.7
2.75
0.7
1
MIN.
0.173
0.098
0.098
0.015
0.030
0.045
0.045
0.195
0.094
0.393
MAX.
A
B
0.181
0.106
0.108
0.027
0.039
0.067
0.067
0.204
0.106
0.409
2.5
D
2.5
E
0.4
F
0.75
1.15
1.15
4.95
2.4
F1
F2
G
1.7
1.7
5.2
2.7
10.4
G1
H
10
L2
L3
L4
L6
L7
Ø
16
0.630
28.6
9.8
15.9
9
30.6
10.6
16.4
9.3
1.126
0.385
0.626
0.354
0.118
1.204
0.417
0.645
0.366
0.126
3
3.2
L3
L6
L7
¯
1 2 3
L4
L2
P011G
23/25
L7800
2
TO-263 (D PAK) MECHANICAL DATA
mm
inch
TYP.
DIM.
MIN.
4.3
TYP.
MAX.
4.6
MIN.
0.169
0.098
0.027
0.049
0.017
0.047
0.352
0.393
0.192
0.590
0.050
0.055
MAX.
0.181
0.106
0.036
0.055
0.023
0.053
0.368
0.404
0.208
0.624
0.055
0.068
A
A1
B
2.49
0.7
2.69
0.93
1.4
B2
C
1.25
0.45
1.21
8.95
10
0.6
C2
D
1.36
9.35
10.28
5.28
15.85
1.4
E
G
4.88
15
L
L2
L3
1.27
1.4
1.75
E
A
C2
L2
D
L
L3
A1
B2
B
C
G
P011P6/C
24/25
L7800
Information furnished is believed to be accurateand reliable. However, SGS-THOMSON Microelectronics assumes no responsabilityfor the
consequences of use of such informationnor for any infringement of patents or other rights of third parties which may results from its use. No
license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specifications mentioned
in this publication are subject to change without notice. This publication supersedes and replaces all informationpreviously supplied.
SGS-THOMSONMicroelectronics products are notauthorized for use as critical components in life support devices or systems without express
written approval of SGS-THOMSON Microelectonics.
1997 SGS-THOMSON Microelectronics- Printedin Italy - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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25/25
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