NSC LP2954AISX

LP2954/LP2954A
5V and Adjustable Micropower Low-Dropout Voltage
Regulators
General Description
Features
The LP2954 is a 5V micropower voltage regulator with very
low quiescent current (90 µA typical at 1 mA load) and very
low dropout voltage (typically 60 mV at light loads and
470 mV at 250 mA load current).
The quiescent current increases only slightly at dropout
(120 µA typical), which prolongs battery life.
The LP2954 with a fixed 5V output is available in the
three-lead TO-220 and TO-263 packages. The adjustable
LP2954 is provided in an 8-lead surface mount, small outline
package. The adjustable version also provides a resistor network which can be pin strapped to set the output to 5V.
Reverse battery protection is provided.
The tight line and load regulation (0.04% typical), as well as
very low output temperature coefficient make the LP2954
well suited for use as a low-power voltage reference.
Output accuracy is guaranteed at both room temperature
and over the entire operating temperature range.
n 5V output within 1.2% over temperature (A grade)
n Adjustable 1.23 to 29V output voltage available
(LP2954IM and LP2954AIM)
n Guaranteed 250 mA output current
n Extremely low quiescent current
n Low dropout voltage
n Reverse battery protection
n Extremely tight line and load regulation
n Very low temperature coefficient
n Current and thermal limiting
n Pin compatible with LM2940 and LM340 (5V version
only)
n Adjustable version adds error flag to warn of output drop
and a logic-controlled shutdown
Applications
n High-efficiency linear regulator
n Low dropout battery-powered regulator
Package Outline and Ordering Information
TO-220 3–Lead Plastic Package
SO-8 Small Outline Surface Mount
DS011128-2
Front View
Order Number LP2954AIT or LP2954IT
See NS Package T03B
DS011128-33
Top View
Order Number LP2954AIM or LP2954IM
See NS Package M08A
© 1999 National Semiconductor Corporation
DS011128
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LP2954/LP2954A 5V and Adjustable Micropower Low-Dropout Voltage Regulators
June 1999
Package Outline and Ordering Information
(Continued)
TO-263 3-Lead Plastic Surface-Mount Package
DS011128-9
Top View
DS011128-10
Side View
Order Number LP2954AIS or LP2954IS
See NS Package TS3B
Ordering Information
Order Number
LP2954AIT
Temp. Range
Package
NS Package
(TJ) ˚C
(JEDEC)
Number
−40 to +125
TO-220
TO3B
−40 to +125
TO-263
TS3B
−40 to +125
SO-8
M08A
LP2954IT
LP2954AIS
LP2954IS
LP2954AIM
LP2954IM
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2
Absolute Maximum Ratings (Note 1)
Storage Temperature Range
Lead Temperature
(Soldering, 5 seconds)
Power Dissipation (Note 2)
Input Supply Voltage
ESD Rating
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Operating Junction Temperature
Range
LP2954AI/LP2954I
−65˚C to +150˚C
260˚C
Internally Limited
−20V to +30V
2 kV
−40˚C to +125˚C
Electrical Characteristics
Limits in standard typeface are for TJ = 25˚C, bold typeface applies over the −40˚C to +125˚C temperature range. Limits
are guaranteed by production testing or correlation techniques using standard Statistical Quality Control (SQC) methods. Unless otherwise noted: VIN = 6V, IL = 1 mA, CL = 2.2 µF.
Symbol
VO
Parameter
Conditions
Output Voltage
Output Voltage
Typical
5.0
1 mA ≤ IL ≤ 250 mA
5.0
(Note 3)
20
2954AI
2954I
Units
Min
Max
Min
Max
4.975
5.025
4.950
5.050
4.940
5.060
4.900
5.100
4.930
5.070
4.880
5.120
100
V
150
ppm/˚C
%
Temp. Coefficient
Line Regulation
Load Regulation
VIN = 6V to 30V
IL = 1 to 250 mA
IL = 0.1 to 1 mA
VIN–VO
Dropout Voltage
0.03
(Note 4)
IL = 1 mA
0.04
60
(Note 5)
IL = 50 mA
IGND
Ground Pin Current
240
0.16
0.20
0.20
0.30
%
mV
100
100
150
150
300
300
420
420
400
310
400
520
520
IL = 250 mA
470
600
600
800
800
IL = 1 mA
90
IL = 50 mA
IL = 100 mA
IL = 250 mA
Ground Pin
0.20
0.40
IL = 100 mA
(Note 6)
IGND
0.10
0.20
1.1
4.5
21
VIN = 4.5V
Current at Dropout
120
150
150
180
180
2
2
2.5
2.5
6
6
8
8
28
28
µA
mA
33
33
170
170
210
210
µA
mA
(Note 6)
ILIMIT
en
Current Limit
VOUT = 0V
380
Thermal Regulation
(Note 7)
0.05
Output Noise
CL = 2.2 µF
400
CL = 33 µF
260
CL = 33µF(Note 9)
80
500
500
530
530
0.2
0.2
%/W
µV RMS
Voltage
(10 Hz to 100 kHz)
IL = 100 mA
3
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Electrical Characteristics
(Continued)
Limits in standard typeface are for TJ = 25˚C, bold typeface applies over the −40˚C to +125˚C temperature range. Limits
are guaranteed by production testing or correlation techniques using standard Statistical Quality Control (SQC) methods. Unless otherwise noted: VIN = 6V, IL = 1 mA, CL = 2.2 µF.
Symbol
Parameter
Conditions
Typical
2954AI
Min
2954I
Units
Max
Min
Max
1.245
1.255
1.205
1.190
1.255
1.270
Additional Specifications for the Adjustable Device (LP2954AIM and LP2954IM)
VREF
Reference Voltage
(Note 10)
1.230
∆VREF/
VREF
Reference Voltage
Line Regulation
VIN = 2.5V to
VO(NOM)+1V
VIN = 2.5V to
VO(NOM)+1V to 30V
(Note 11)
0.03
∆VREF/∆T
Reference Voltage
Temperature
Coefficient
IB(FB)
Feedback Pin Bias
Current
IGND
Ground Pin Current
at Shutdown (Note
6)
VSHUTDOWN≤1.1V
Output ″OFF″
Pulldown Current
(Note 12)
IO(SINK)
(Note 3)
1.215
1.205
0.1
0.2
0.2
0.4
20
V
ppm/˚C
20
40
60
40
60
nA
105
140
140
µA
30
20
30
20
mA
Dropout Detection Comparator
IOH
Output ″HIGH″
Leakage Current
VOH = 30V
0.01
1
2
1
2
µA
VOL
Output ″LOW″
Voltage
VIN = VO(NOM)−0.5V
IO(COMP) = 400µA
150
250
400
250
400
mV
VTHR(MAX)
Upper Threshold
Voltage
(Note 13)
−60
−80
−95
−35
−25
−80
−95
−35
−25
mV
VTHR(MIN)
Lower Threshold
Voltage
(Note 13)
−85
−110
−160
−55
−40
−110
−160
−55
−40
mV
Hysteresis
(Note 13)
15
(Referred to VREF)
±3
VIN(S/D) = 0V to 5V
10
HYST
mV
Shutdown Input
VOS
HYST
IB
Input Offset Voltage
Hysteresis
Input Bias Current
−7.5
−10
7.5
10
−7.5
−10
7.5
10
−30
−50
30
50
−30
−50
30
50
6
mV
mV
nA
Note 1: Absolute maximum ratings indicate limits beyond which damage to the component may occur. Electrical specifications do not apply when operating the device outside of its rated operating conditions.
Note 2: The maximum allowable power dissipation is a function of the maximum junction temperature, TJ (MAX), the junction-to-ambient thermal resistance, θJ-A,
and the ambient temperature, TA. The maximum allowable power dissipation at any ambient temperature is calculated using:
.
Exceeding the maximum allowable power dissipation will result in excessive die temperature, and the regulator will go into thermal shutdown. The junction-to-ambient
thermal resistance of the TO-220 (without heatsink) is 60˚C/W, 73˚C/W for the TO-263, and 160˚C/W for the SO-8. If the TO-263 package is used, the thermal resistance can be reduced by increasing the P.C. board copper area thermally connected to the package: Using 0.5 square inches of copper area, θJA is 50˚C/W; with
1 square inch of copper area, θJA is 37˚C/W; and with 1.6 or more square inches of copper area, θJA is 32˚C/W. The junction-to-case thermal resistance is 3˚C/W.
If an external heatsink is used, the effective junction-to-ambient thermal resistance is the sum of the junction-to-case resistance (3˚C/W), the specified thermal resistance of the heatsink selected, and the thermal resistance of the interface between the heatsink and the LP2954. Some typical values are listed for interface materials used with TO-220:
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4
Electrical Characteristics
(Continued)
TABLE 1. Typical Values of Case-to-Heatsink
Thermal Resistance (˚C/W) (Data from AAVID Eng.)
TABLE 2. Typical Values of Case-to-Heatsink
Thermal Resistance (˚C/W) (Data from Thermalloy)
Silicone grease
1.0
Thermasil III
1.3
Dry interface
1.3
Thermasil II
1.5
Mica with grease
1.4
Thermalfilm (0.002) with grease
2.2
Note 3: Output voltage temperature coefficient is defined as the worst case voltage change divided by the total temperature range.
Note 4: Regulation is measured at constant junction temperature using low duty cycle pulse testing. Parts are tested separately for load regulation in the load
ranges 0.1 mA–1 mA and 1 mA–250 mA. Changes in output voltage due to heating effects are covered by the thermal regulation specification.
Note 5: Dropout voltage is defined as the input to output differential at which the output voltage drops 100 mV below the value measured with a 1V differential.
Note 6: Ground pin current is the regulator quiescent current. The total current drawn from the source is the sum of the load current plus the ground pin current.
Note 7: Thermal regulation is defined as the change in output voltage at a time T after a change in power dissipation is applied, excluding load or line regulation
effects. Specifications are for 200 mA load pulse at VIN = 20V (3W pulse) for T = 10 ms.
Note 8: When used in dual-supply systems where the regulator load is returned to a negative supply, the output voltage must be diode-clamped to ground.
Note 9: Connect a 0.1µF capacitor from the output to the feedback pin.
Note 10: VREF≤VOUT≤(VIN−1V), 2.3V≤VIN≤30V, 100µA≤IL≤250mA.
Note 11: Two seperate tests are performed, one covering VIN = 2.5V to VO(NOM)+1V and the other test for VIN = 2.5V to VO(NOM)+1V to 30V.
Note 12: VSHUTDOWN≤1.1V, VOUT = VO(NOM).
Note 13: Comparator thresholds are expressed in terms of a voltage differential at the Feedback terminal below the nominal reference voltage measured at
VIN = VO(NOM)+1V. To express these thresholds in terms of output voltage change, multiply by the Error amplifier gain, which is VOUT/VREF = (R1+R2)/R2.
Note 14: Human body model, 200pF discharged through 1.5kΩ.
Typical Performance Characteristics
Quiescent Current
Quiescent Current
DS011128-12
Ground Pin Current
Ground Pin Current vs Load
DS011128-13
Ground Pin Current
DS011128-15
Output Noise Voltage
DS011128-16
5
DS011128-14
DS011128-17
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Typical Performance Characteristics
(Continued)
Ripple Rejection
Ripple Rejection
Ripple Rejection
DS011128-19
DS011128-18
Line Transient Response
Line Transient Response
DS011128-21
Load Transient Response
DS011128-20
Output Impedance
DS011128-22
Load Transient Response
DS011128-24
DS011128-23
Dropout Characteristics
DS011128-25
Thermal Response
DS011128-26
Short-Circuit Output
Current and Maximum
Output Current
DS011128-27
DS011128-28
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Typical Performance Characteristics
(Continued)
Maximum Power Dissipation
(TO-263) (See (Note 2) )
DS011128-11
Application Hints
DROPOUT VOLTAGE
The dropout voltage of the regulator is defined as the minimum input-to-output voltage differential required for the output voltage to stay within 100 mV of the output voltage measured with a 1V differential. The dropout voltages for various
values of load current are listed under Electrical Characteristics.
If the regulator is powered from a rectified AC source with a
capacitive filter, the minimum AC line voltage and maximum
load current must be used to calculate the minimum voltage
at the input of the regulator. The minimum input voltage, including AC ripple on the filter capacitor , must not drop
below the voltage required to keep the LP2954 in regulation.
It is also advisable to verify operating at minimum operating
ambient temperature, since the increasing ESR of the filter
capacitor makes this a worst-case test for dropout voltage
due to increased ripple amplitude.
EXTERNAL CAPACITORS
A 2.2 µF (or greater) capacitor is required between the output pin and the ground to assure stability (refer to Figure 1).
Without this capacitor, the part may oscillate. Most types of
tantalum or aluminum electrolytics will work here. Film types
will work, but are more expensive. Many aluminum electrolytics contain electrolytes which freeze at −30˚C, which requires the use of solid tantalums below −25˚C. The important
parameters of the capacitor are an ESR of about 5Ω or less
and a resonant frequency above 500 kHz (the ESR may increase by a factor of 20 or 30 as the temperature is reduced
from 25˚C to −30˚C). The value of this capacitor may be increased without limit. At lower values of output current, less
output capacitance is required for stability. The capacitor can
be reduced to 0.68 µF for currents below 10 mA or 0.22 µF
for currents below 1 mA.
A 1 µF capacitor should be placed from the input pin to
ground if there is more than 10 inches of wire between the input and the AC filter capacitor or if a battery input is used.
Programming the output for voltages below 5V runs the error
amplifier at lower gains requiring more output capacitance
for stability. At 3.3V output, a minimum of 4.7 µF is required.
For the worst case condition of 1.23V output and 250 mA of
load current, a 6.8 µF (or larger) capacitor should be used.
Stray capacitance to the Feedback terminal can cause instability. This problem is most likely to appear when using high
value external resistors to set the output voltage. Adding a
100 pF capacitor between the Output and Feedback pins
and increasing the output capacitance to 6.8 µF (or greater)
will cure the problem.
HEATSINK REQUIREMENTS
A heatsink may be required with the LP2954 depending on
the maximum power dissipation and maximum ambient temperature of the application. Under all possible operating conditions, the junction temperature must be within the range
specified under Absolute Maximum Ratings.
To determine if a heatsink is required, the maximum power
dissipated by the regulator, P(max), must be calculated. It is
important to remember that if the regulator is powered from
a transformer connected to the AC line, the maximum
specified AC input voltage must be used (since this produces the maximum DC input voltage to the regulator). Figure 1 shows the voltages and currents which are present in
the circuit. The formula for calculating the power dissipated
in the regulator is also shown in Figure 1.
MINIMUM LOAD
When setting the output voltage using an external resistive
divider, a minimum current of 1 µA is recommended through
the resistors to provide a minimum load.
It should be noted that a minimum load current is specified in
several of the electrical characteristic test conditions, so this
value must be used to obtain correlation on these tested limits. The part is parametrically tested down to 100 µA, but is
functional with no load.
7
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Application Hints
the value of R2 in cases where the regulator must work with
no load (see MINIMUM LOAD ). IFB will produce a typical 2%
error in VOUT which can be eliminated at room temperature
by trimming R1. For better accuracy, choosing R2 = 100 kΩ
will reduce this error to 0.17% while increasing the resistor
program current to 12 µA. Since the typical quiescent current
is 120 µA, this added current is negligible.
(Continued)
DS011128-5
*See External Capacitors
PTotal = (VIN −5) IL+ (VIN) IG
FIGURE 1. Basic 5V Regulator Circuit
The next parameter which must be calculated is the maximum allowable temperature rise, TR(max). This is calculated
by using the formula:
TR(max) = TJ(max) − TA(max)
where: TJ(max) is the maximum allowable junction
temperature
TA(max) is the maximum ambient temperature
Using the calculated values for TR(max) and P(max), the required value for junction-to-ambient thermal resistance,
θ(J-A), can now be found:
θ(J-A) = TR(max)/P(max)
If the calculated value is 60˚ C/W or higher , the regulator
may be operated without an external heatsink. If the calculated value is below 60˚ C/W, an external heatsink is required. The required thermal resistance for this heatsink can
be calculated using the formula:
θ(H-A) = θ(J-A) − θ(J-C) − θ(C-H)
DS011128-36
* See Application Hints
** Drive with TTL-low to shut down
FIGURE 2. Adjustable Regulator
DROPOUT DETECTION COMPARATOR
This comparator produces a logic “LOW” whenever the output falls out of regulation by more than about 5%. This figure
results from the comparator’s built-in offset of 60 mV divided
by the 1.23V reference (refer to block diagrams on page 1).
The 5% low trip level remains constant regardless of the programmed output voltage. An out-of-regulation condition can
result from low input voltage, current limiting, or thermal limiting.
where:
θ(J-C) is the junction-to-case thermal resistance, which is
specified as 3˚ C/W maximum for the LP2954.
θ(C-H) is the case-to-heatsink thermal resistance, which is
dependent on the interfacing material (if used). For details
and typical values, refer to (Note 2) listed at the end of the
ELECTRICAL CHARACTERISTICS section.
θ(H-A) is the heatsink-to-ambient thermal resistance. It is this
specification (listed on the heatsink manufacturers data
sheet) which defines the effectiveness of the heatsink. The
heatsink selected must have a thermal resistance which is
equal to or lower than the value of θ(H-A) calculated from the
above listed formula.
Figure 3 gives a timing diagram showing the relationship between the output voltage, the ERROR output, and input voltage as the input voltage is ramped up and down to a regulator programmed for 5V output. The ERROR signal becomes
low at about 1.3V input. It goes high at about 5V input, where
the output equals 4.75V. Since the dropout voltage is load
dependent, the input voltage trip points will vary with load
current. The output voltage trip point does not vary.
The comparator has an open-collector output which requires
an external pull-up resistor. This resistor may be connected
to the regulator output or some other supply voltage. Using
the regulator output prevents an invalid “HIGH” on the comparator output which occurs if it is pulled up to an external
voltage while the regulator input voltage is reduced below
1.3V. In selecting a value for the pull-up resistor, note that
while the output can sink 400 µA, this current adds to battery
drain. Suggested values range from 100 kΩ to 1 MΩ. This
resistor is not required if the output is unused.
When VIN ≤ 1.3V, the error flag pin becomes a high impedance, allowing the error flag voltage to rise to its pull-up voltage. Using VOUT as the pull-up voltage (rather than an external 5V source) will keep the error flag voltage below 1.2V
(typical) in this condition. The user may wish to divide down
the error flag voltage using equal-value resistors (10 kΩ suggested) to ensure a low-level logic signal during any fault
condition, while still allowing a valid high logic level during
normal operation.
PROGRAMMING THE OUTPUT VOLTAGE
The regulator may be pin-strapped for 5V operation using its
internal resistive divider by tying the Output and Sense pins
together and also tying the Feedback and 5V Tap pins together.
Alternatively, it may be programmed for any voltage between
the 1.23V reference and the 30V maximum rating using an
external pair of resistors (see Figure 2). The complete equation for the output voltage is:
where VREF is the 1.23V reference and IFB is the Feedback
pin bias current (−20 nA typical). The minimum recommended load current of 1 µA sets an upper limit of 1.2 MΩ on
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8
Application Hints
Noise can be reduced more effectively by a bypass capacitor
placed across R1 (refer to Figure 2). The formula for selecting the capacitor to be used is:
(Continued)
This gives a value of about 0.1 µF. When this is used, the
output capacitor must be 6.8 µF (or greater) to maintain stability. The 0.1 µF capacitor reduces the high frequency gain
of the circuit to unity, lowering the output noise from 260 µV
to 80 µV using a 10 Hz to 100 kHz bandwidth. Also, noise is
no longer proportional to the output voltage, so improvements are more pronounced at high output voltages.
SHUTDOWN INPUT
A logic-level signal will shut off the regulator output when a
“LOW” ( < 1.2V) is applied to the Shutdown input.
To prevent possible mis-operation, the Shutdown input must
be actively terminated. If the input is driven from
open-collector logic, a pull-up resistor (20 kΩ to 100 kΩ recommended) should be connected from the Shutdown input
to the regulator input.
If the Shutdown input is driven from a source that actively
pulls high and low (like an op-amp), the pull-up resistor is not
required, but may be used.
If the shutdown function is not to be used, the cost of the
pull-up resistor can be saved by simply tying the Shutdown
input directly to the regulator input.
IMPORTANT: Since the Absolute Maximum Ratings state
that the Shutdown input can not go more than 0.3V below
ground, the reverse-battery protection feature which protects
the regulator input is sacrificed if the Shutdown input is tied
directly to the regulator input.
If reverse-battery protection is required in an application, the
pull-up resistor between the Shutdown input and the regulator input must be used.
DS011128-37
* In shutdown mode, ERROR will go high if it has been pulled up to an
external supply. To avoid this invalid response, pull up to regulator output.
** Exact value depends on dropout voltage. (See Application Hints)
FIGURE 3. ERROR Output Timing
OUTPUT ISOLATION
The regulator output can be left connected to an active voltage source (such as a battery) with the regulator input power
turned off, as long as the regulator ground pin is connected to ground . If the ground pin is left floating, damage
to the regulator can occur if the output is pulled up by an
external voltage source.
REDUCING OUTPUT NOISE
In reference applications it may be advantageous to reduce
the AC noise present on the output. One method is to reduce
regulator bandwidth by increasing output capacitance. This
is relatively inefficient, since large increases in capacitance
are required to get significant improvement.
Typical Applications
Typical Application Circuit
DS011128-1
5V Regulator
DS011128-6
9
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Typical Applications
(Continued)
5V Current Limiter
DS011128-7
*Output voltage equals +VIN minus dropout voltage, which varies with output current. Current limits at 380 mA (typical).
Schematic Diagram
DS011128-8
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10
Physical Dimensions
inches (millimeters) unless otherwise noted
TO-220 3-Lead Plastic Package
Order Number LP2954AIT or LP2954IT
NS Package T03B
11
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Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
TO-263 3-Lead Plastic Surface Mount Package
Order Number LP2954AIS or LP2954IS
NS Package TS3B
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12
inches (millimeters) unless otherwise noted (Continued)
SO-8 Surface Mount Package
Order Number LP2954AIM or LP2954IM
NS Package Number M08A
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LP2954/LP2954A 5V and Adjustable Micropower Low-Dropout Voltage Regulators
Physical Dimensions