STMICROELECTRONICS LM350

LM150/250
LM350
THREE-TERMINAL 3 A
ADJUSTABLE VOLTAGE REGULATORS
..
..
..
.
GUARANTEED 3A OUTPUT CURRENT
ADJUSTABLE OUTPUT DOWN TO 1.2V
LINE REGULATION TYPICALLY 0.005% /V
LOAD REGULATION TYPICALLY 0.1%
GUARANTEED THERMAL REGULATION
CURRENT LIMIT CONSTANT WITH TEMPERATURE
STANDARD 3-LEAD TRANSISTOR PACKAGE
TO3
K SUFFIX
(Steel Can)
ORDER CODE
PART
NUMBER
TEMPERATURE
RANGE
LM150
-55 oC to + 150 oC
LM250
-25 oC to + 150 oC
LM350
0 oC to + 125 oC
EXAMPLE: LM150K
PACKAGE
K
•
•
•
PIN CONNECTION
(bottom view)
Case is output
March 1993
1/7
LM150-LM250-LM350
ABSOLUTE MAXIMUM RATING
Symbol
Ptot
V I - VO
Toper
Parameter
Power Dissipation
Input-Output Voltage DIfferential
Operating Junction Temperature Range
Tstg
Storage Temperature Range
Tlead
Lead Temperature (Soldering, 10 seconds)
LM150
LM250
LM350
Value
Unit
Internally Limited
W
35
-55 to 150
-25 to 150
0 to 125
-65 to 150
V
C
o
300
o
C
o
C
THERMAL CHARACTERISTICS
Symbol
Parameter
Rth(j-c) Typical Junction-Case Thermal Resistance
Rth(j-a)
Max Junction-Ambient Thermal Resistance
SCHEMATIC DIAGRAM
2/7
Value
1.5
35
Unit
C/W
o
o
C/W
LM150-LM250-LM350
ELECTRICAL CHARACTERISTICS
LM150: -55 oC ≤ T j ≤ 150 oC, VI - VO = 5V, IO = 1.5A
LM250: -25 oC ≤ T j ≤ 150 oC, VI - VO = 5V, IO = 1.5A
LM350: 0 oC ≤ T j ≤ 150 oC, VI - VO = 5V, I O = 1.5A
Although power dissipation is internally limited, these specifications apply to power dissipation up to
30W (unless otherwise specified).
Symbol
K VI
K VO
Iadj
∆Iadj
v(ref)
K VI
K VO
KVT
IO(min)
IO(max)
Rvf
KVH
Parameter
Line Regulation - (note 1)
Tamb = 25 oC, 3 V ≤ (V I - VO) ≤ 35 V
Load Regulation Tamb = 25 oC, 10 mA ≤ IO ≤ 3 A
VO ≤ 5V - (note 1)
VO ≥ 5V - (note 1)
Thermal Regulation (pulse = 20 ms)
Adjustment Pin Current
Adjustment Pin Current Change
10 mA ≤ IL ≤ 3 A, 3 V ≤ (VI - VO) ≤ 35 V
Reference Voltage
3V ≤ (VI - VO) ≤ 35 V, 10 mA ≤ IO ≤ 3A, P ≤ 30W
Line Regulation - (note 1)
3 V ≤ (V I - VO) ≤ 35 V
Load Regulation 10 mA ≤ IO ≤ 3 A
VO ≤ 5V - (note 1)
VO ≥ 5V - (note 1)
Temperature Stability (Tmin ≤ Tj ≤ Tmax)
Minimum Load Current (VI - VO ≤ 35 V)
Current Limit (VI - VO ≤ 10 V)
DC
VI - VO = 30 V
RMS Output Noise, % of VO
(Tamb = 25 oC, 10 Hz ≤ f ≤ 10 KHz)
Ripple Rejection Ratio
VO = 10 V, f = 120 Hz
Cadi = 10 µF
Long Term Stability (Tamb = 125 oC)
LM150-LM250
Min.
Typ.
Max.
0.005 0.01
1.19
3
Min.
LM350
Typ.
0.005
Max.
0.03
Unit
%/V
5
0.1
0.002
50
0.2
25
0.5
0.02
100
5
mV
%
%/W
µA
µA
1.24
1.29
V
5
0.1
0.002
50
0.2
15
0.3
0.01
100
5
1.24
1.29
0.02
0.05
0.02
0.05
%/V
20
0.3
1
3.5
50
1
20
0.3
1
3.5
70
1.5
mV
%
%
mA
A
1.19
5
4.5
1
0.001
3
10
4.5
1
0.001
%
dB
66
65
86
0.3
66
1
65
86
0.3
1
%
Note 1 : Regulation is measured at constant junction temperature. Changes in output voltage due to heating effects are taken
into account separately by thermal rejection.
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LM150-LM250-LM350
TYPICAL APPLICATIONS
+ 1.2V to + 25V ADJUSTABLE REGULATOR
LM350
Since the 50µA current from the adjustment terminal represents an error term, the LM350 was designed to minimize Iadj and make it very constant
with line and load changes. To do this, all quiescent
operating current is returned to the output establishing a minimum load current requirement. If there
is insufficient load on the output, the output will rise.
EXTERNAL CAPACITORS
∆ Needed if device is far from filter capacitors.
* Optional-improves transient response. Output capacitors in the
range of 1µF to 100µF of aluminium or tantalum electrolytic are
commonly used to provide improved output impedance and rejection of transients.
R2
* * V O = 1.25V (1 +
)
R1
* * * R1 = 240Ω for LM150 and LM250
APPLICATION HINTS
In operation, the LM350 develops a nominal 1.25V
reference voltage, V(ref), between the output and
adjustment terminal. The reference voltage is impressed across program resistor R1 and, since the
voltage is constant, a constant current I1 then flows
through the output set resistor R2, giving an output
voltage of
R2
VO = V(ref) ( 1+
) + IadjR2
R1
Figure 1.
LM350
An input bypass capacitor is recommended. A
0.1µF disc or 1µF solid tantalum on the input is suitable input by passing for almost all applications.
The device is more sensitive to the absence of input
bypassing when adjustment or output capacitors
are used byt the above values will eliminate the
possibility of problems.
The adjustment terminal can be bypassed to
ground on the LM350 to improve ripple rejection.
This bypass capacitor prevents ripple form being
amplified as the output voltage is increased. With
a 10µF bypass capacitor 75dB ripple rejection is
obtainable at any output level. Increases over 20µF
do not appreciably improve the ripple rejection at
frequencies above 120Hz. If the bypass capacitor
is used, it is sometimes necessary to include protection diodes to prevent the capacitor from discharging through internal low current paths and
damaging the device.
In general, the best type of capacitors to use are
solid tantalum. Solid tantalum capacitors have low
impedance even at high frequencies. Depending
upon capacitor construction, it takes about 25µF in
aluminum electrolytic to equal 1µF solid tantalum at
high frequencies. Ceramic capacitors are also
good at high frequencies, but some types have a
large decrease in capacitance at frequencies
around 0.5MHz. For this reason, 0.01µF disc may
seem to work better than a 0.1µF disc as a bypass.
Although the LM350 is stable with no output capacitors, like any feedback circuit, certain values of
external capacitance can cause excessive ringing.
This occurs with values between 500pF and
5000pF. A 1µF solid tantalum (or 25µF aluminium
electrolytic) on the output swamps this effect and
insures stability.
LOAD REGULATION
The LM350 is capable of providing extremely good
load regulation but a few precautions are needed
to obtain maximum performance. The current set
resistor connected between the adjustment terminal and the output terminal (usually 240Ω) should
be tied directly to the output of the regulator rather
than near the load. This eliminates line drops from
appearing effectively in series with the reference
and degrading regulation. For example, a 15V
regulator with 0.05Ω resistance between the regulator and load will have a load regulation due to line
resistance of 0.05Ω x IL. If the set resistor is connected near the load the effective line resistance
4/7
LM150-LM250-LM350
will be 0.05Ω (1 + R2/R1) or in this case, 11.5 times
worse.
Figure 2 shows the effect of resistance between the
regulator and 140Ω set resistor.
With the TO-3 package, it is easy to minimize the resistance from the case to the set resistor, by using
2 separate leads to the case. The ground of R2 can
be returned near the ground of the load to provide
remote ground sensing and improve load regulation.
PROTECTION DIODES
When external capacitors are used with any IC regulator it is sometimes necessary to add protection
diodes to prevent the capacitors from discharging
through low current points into the regulator. Most
Figure 2 : Regulator with Line Resistance in Output Lead.
LM350
20µF capacitors have low enough internal series resistance to deliver 20A spikes when shorted. Although the surge is short, there is enough energy to
damage parts of the IC.
When an output capacitor is connected to a regulator and the input is shorted, the output capacitor will
discharge into the output of the regulator. The discharge current depends on the value of the capacitor, the output voltage of the regulator, and the rate
of decrease of VI. In the LM350 this discharge path
is through a large junction that is able to sustain 25A
surge with no problem. This is not true of other types
of positive regulators. For output capacitors of
100µF or less at output of 15V or less, there is no
need to use diodes.
The bypass capacitor on the adjustment terminal
can discharge through a low current junction. Discharge occurs when either the input or output is
shorted. Internal to the LM350 is a 50Ω resistor
which limits the peak discharge current. No protection is needed for output voltages of 25V or less and
10µF capacitance. Figure 3 shows an LM350 with
protection diodes included for use with outputs
greater than 25V and high values of output capacitance.
Figure 3 : Regulator with Protection Diodes.
LM350
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LM150-LM250-LM350
TO-3 MECHANICAL DATA
mm
DIM.
MIN.
inch
TYP.
MAX.
MIN.
TYP.
MAX.
A
11.00
13.10
0.433
0.516
B
0.97
1.15
0.038
0.045
C
1.50
1.65
0.059
0.065
D
8.32
8.92
0.327
0.351
E
19.00
20.00
0.748
0.787
G
10.70
11.10
0.421
0.437
N
16.50
17.20
0.649
0.677
P
25.00
26.00
0.984
1.023
R
4.00
4.09
0.157
0.161
U
38.50
39.30
1.515
1.547
V
30.00
30.30
1.187
1.193
A
P
C
O
N
B
V
E
G
U
D
R
P003F
6/7
LM150-LM250-LM350
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsability for the
consequences of use of such information nor 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 information previously supplied.
SGS-THOMSON Microelectronics products are not authorized for use ascritical components in life support devices or systems without express
written approval of SGS-THOMSON Microelectonics.
 1994 SGS-THOMSON Microelectronics - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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