NSC LP3882ES-1.8

LP3882
1.5A Fast-Response Ultra Low Dropout Linear
Regulators
General Description
Features
The LP3882 is a high current, fast response regulator which
can maintain output voltage regulation with minimum input to
output voltage drop. Fabricated on a CMOS process, the
device operates from two input voltages: Vbias provides
voltage to drive the gate of the N-MOS power transistor,
while Vin is the input voltage which supplies power to the
load. The use of an external bias rail allows the part to
operate from ultra low Vin voltages. Unlike bipolar regulators, the CMOS architecture consumes extremely low quiescent current at any output load current. The use of an
N-MOS power transistor results in wide bandwidth, yet minimum external capacitance is required to maintain loop stability.
The fast transient response of these devices makes them
suitable for use in powering DSP, Microcontroller Core voltages and Switch Mode Power Supply post regulators. The
parts are available in TO-220 and TO-263 packages.
Dropout Voltage: 110 mV (typ) @ 1.5A load current.
Ground Pin Current: 3 mA (typ) at full load.
Shutdown Current: 60 nA (typ) when S/D pin is low.
Precision Output Voltage: 1.5% room temperature accuracy.
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Ultra low dropout voltage (110 mV @ 1.5A typ)
Low ground pin current
Load regulation of 0.04%/A
60 nA typical quiescent current in shutdown
1.5% output accuracy (25˚C)
TO-220, TO-263 packages
Over temperature/over current protection
−40˚C to +125˚C junction temperature range
Applications
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DSP Power Supplies
Server Core and I/O Supplies
PC Add-in-Cards
Local Regulators in Set-Top Boxes
Microcontroller Power Supplies
High Efficiency Power Supplies
SMPS Post-Regulators
Typical Application Circuit
20063201
At least 4.7 µF of input and output capacitance is required for stability.
Connection Diagrams
20063202
TO-220, Top View
© 2003 National Semiconductor Corporation
20063203
TO-263, Top View
DS200632
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LP3882 1.5A Fast-Response Ultra Low Dropout Linear Regulators
August 2003
LP3882
Ordering Information
Order Number
Package Type
Package Drawing
Supplied As
LP3882ES-1.2
TO263-5
TS5B
Rail
LP3882ESX-1.2
TO263-5
TS5B
Tape and Reel
LP3882ET-1.2
TO220-5
T05D
Rail
LP3882ES-1.5
TO263-5
TS5B
Rail
LP3882ESX-1.5
TO263-5
TS5B
Tape and Reel
LP3882ET-1.5
TO220-5
T05D
Rail
LP3882ES-1.8
TO263-5
TS5B
Rail
LP3882ESX-1.8
TO263-5
TS5B
Tape and Reel
LP3882ET-1.8
TO220-5
T05D
Rail
Block Diagram
20063224
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2
IOUT (Survival)
(Note 1)
Output Voltage (Survival)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Storage Temperature Range
−40˚C to +150˚C
Operating Ratings
260˚C
VIN Supply Voltage
ESD Rating
Human Body Model (Note 3)
Machine Model (Note 10)
(VOUT + VDO) to 5.5V
Shutdown Input Voltage
2 kV
200V
0 to +6V
IOUT
1.5A
VIN Supply Voltage (Survival)
−0.3V to +6V
Operating Junction
Temperature Range
VBIAS Supply Voltage (Survival)
−0.3V to +7V
VBIAS Supply Voltage
Shutdown Input Voltage (Survival)
−0.3V to +7V
Power Dissipation (Note 2)
−0.3V to +6V
Junction Temperature
−65˚C to +150˚C
Lead Temp. (Soldering, 5 seconds)
Internally Limited
Internally Limited
−40˚C to +125˚C
4.5V to 6V
Electrical Characteristics Limits in standard typeface are for TJ = 25˚C, and limits in boldface type apply
over the full operating temperature range. Unless otherwise specified: VIN = VO(NOM) + 1V, VBIAS = 4.5V, IL = 10 mA, CIN =
COUT = 4.7 µF, VS/D = VBIAS.
Symbol
VO
Parameter
Output Voltage Tolerance
Conditions
10 mA < IL < 1.5A
VO(NOM) + 1V ≤ VIN ≤ 5.5V
4.5V ≤ VBIAS ≤ 6V
Typical
(Note 4)
MIN
(Note 5)
MAX
(Note 5)
1.198
1.234
1.186
1.246
1.478
1.522
1.455
1.545
1.773
1.827
1.746
1.854
Units
1.216
1.5
V
1.8
∆VO/∆VIN
Output Voltage Line Regulation
(Note 7)
VO(NOM) + 1V ≤ VIN ≤ 5.5V
∆VO/∆IL
Output Voltage Load Regulation
(Note 8)
10 mA < IL < 1.5A
VDO
Dropout Voltage (Note 9)
IL = 1.5A
IQ(VIN)
Quiescent Current Drawn from
VIN Supply
10 mA < IL < 1.5A
V
IQ(VBIAS)
Quiescent Current Drawn from
VBIAS Supply
Short-Circuit Current
≤ 0.3V
10 mA < IL < 1.5A
V
ISC
S/D
S/D
≤ 0.3V
VOUT = 0V
0.01
%/V
0.04
0.06
%/A
110
170
270
mV
3
7
8
mA
0.03
1
30
µA
1
2
3
mA
0.03
1
30
µA
3
A
Shutdown Input
VSDT
Output Turn-off Threshold
Output = ON
0.7
Output = OFF
0.7
Td (OFF)
Turn-OFF Delay
RLOAD X COUT << Td (OFF)
20
Td (ON)
Turn-ON Delay
RLOAD X COUT << Td (ON)
15
IS/D
S/D Input Current
V S/D =1.3V
1
≤ 0.3V
−1
V
S/D
3
1.3
0.3
V
µs
µA
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LP3882
Absolute Maximum Ratings
LP3882
Electrical Characteristics Limits in standard typeface are for TJ = 25˚C, and limits in boldface type apply
over the full operating temperature range. Unless otherwise specified: VIN = VO(NOM) + 1V, VBIAS = 4.5V, IL = 10 mA, CIN =
COUT = 4.7 µF, VS/D = VBIAS. (Continued)
Symbol
Parameter
Conditions
Typical
(Note 4)
MIN
(Note 5)
MAX
(Note 5)
Units
AC Parameters
PSRR (VIN)
Ripple Rejection for VIN Input
Voltage
PSRR
(VBIAS)
Ripple Rejection for VBIAS
Voltage
VIN = VOUT +1V, f = 120 Hz
VIN = VOUT + 1V, f = 1 kHz
VBIAS = VOUT + 3V, f = 120 Hz
VBIAS = VOUT + 3V, f = 1 kHz
en
80
65
dB
70
65
Output Noise Density
f = 120 Hz
Output Noise Voltage
VOUT = 1.8V
BW = 10 Hz − 100 kHz
150
1
BW = 300 Hz − 300 kHz
90
µV/root−Hz
µV (rms)
Note 1: Absolute maximum ratings indicate limits beyond which damage to the component may occur. Operating ratings indicate conditions for which the device
is intended to be functional, but do not guarantee specific performance limits. For guaranteed specifications, see Electrical Characteristics. Specifications do not
apply when operating the device outside of its rated operating conditions.
Note 2: At elevated temperatures, device power dissipation must be derated based on package thermal resistance and heatsink thermal values. θJ-A for TO-220
devices is 65˚C/W if no heatsink is used. If the TO-220 device is attached to a heatsink, a θJ-S value of 4˚C/W can be assumed. θJ-A for TO-263 devices is
approximately 40˚C/W if soldered down to a copper plane which is at least 1.5 square inches in area. If power dissipation causes the junction temperature to exceed
specified limits, the device will go into thermal shutdown.
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5k resistor into each pin.
Note 4: Typical numbers represent the most likely parametric norm for 25˚C operation.
Note 5: Limits are guaranteed through testing, statistical correlation, or design.
Note 6: If used in a dual-supply system where the regulator load is returned to a negative supply, the output pin must be diode clamped to ground.
Note 7: Output voltage line regulation is defined as the change in output voltage from nominal value resulting from a change in input voltage.
Note 8: Output voltage load regulation is defined as the change in output voltage from nominal value as the load current increases from no load to full load.
Note 9: Dropout voltage is defined as the minimum input to output differential required to maintain the output with 2% of nominal value.
Note 10: The machine model is a 220 pF capacitor discharged directly into each pin. The machine model ESD rating of pin 5 is 100V.
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4
Unless otherwise specified: TA = 25˚C, COUT = 4.7µF, Cin =
Dropout vs IL
IGND vs VSD
20063205
20063204
VOUT vs Temperature
DC Load Regulation
20063206
20063207
Line Regulation vs VIN
Line Regulation vs VBIAS
20063208
20063209
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LP3882
Typical Performance Characteristics
4.7µF, S/D pin is tied to VBIAS, VIN = 2.2V, VOUT = 1.8V.
LP3882
Typical Performance Characteristics Unless otherwise specified: TA = 25˚C, COUT = 4.7µF, Cin =
4.7µF, S/D pin is tied to VBIAS, VIN = 2.2V, VOUT = 1.8V. (Continued)
IBIAS vs IL
IGND vs VSD
20063212
20063210
Noise Measurement
VOUTStartup Waveform
20063215
20063214
VOUTStartup Waveform
Line Regulation vs VBIAS
20063218
20063216
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Line Regulation vs VBIAS
VIN PSRR
20063219
20063220
VIN PSRR
VBIAS PSRR
20063223
20063222
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LP3882
Typical Performance Characteristics Unless otherwise specified: TA = 25˚C, COUT = 4.7µF, Cin =
4.7µF, S/D pin is tied to VBIAS, VIN = 2.2V, VOUT = 1.8V. (Continued)
LP3882
LP388X devices. The regulator output can tolerate ceramic
capacitance totaling up to 15% of the amount of Tantalum
capacitance connected from the output to ground.
Application Hints
VBIAS RESTRICTIONS FOR PROPER START-UP
To prevent misoperation, ensure that VBIAS is below 50mV
before start-up is initiated. This scenario can occur in systems with a backup battery using reverse-biased "blocking"
diodes which may allow enough leakage current to flow into
the VBIAS node to raise it’s voltage slightly above ground
when the main power is removed. Using low leakage diodes
or a resistive pull down can prevent the voltage at VBIAS from
rising above 50mV. Large bulk capacitors connected to
VBIAS may also cause a start-up problem if they do not
discharge fully before re-start is initiated (but only if VBIAS is
allowed to fall below 1V). A resistor connected across the
capacitor will allow it to discharge more quickly. It should be
noted that the probability of a "false start" caused by incorrect logic states is extremely low.
OUTPUT "BYPASS" CAPACITORS
Many designers place small value "bypass" capacitors at
various circuit points to reduce noise. Ceramic capacitors in
the value range of about 1000pF to 0.1µF placed directly on
the output of a PNP or P-FET LDO regulator can cause a
loss of phase margin which can result in oscillations, even
when a Tantalum output capacitor is in parallel with it. This is
not unique to National Semiconductor LDO regulators, it is
true of any P-type LDO regulator.
The reason for this is that PNP or P-FET regulators have a
higher output impedance (compared to an NPN regulator),
which results in a pole-zero pair being formed by every
different capacitor connected to the output.
The zero frequency is approximately:
Fz = 1 / (2 X π X ESR X C)
EXTERNAL CAPACITORS
To assure regulator stability, input and output capacitors are
required as shown in the Typical Application Circuit.
Where ESR is the equivalent series resistance of the capacitor, and C is the value of capacitance.
The pole frequency is:
Fp = 1 / (2 X π X RL X C)
Where RL is the load resistance connected to the regulator
output.
To understand why a small capacitor can reduce phase
margin: assume a typical LDO with a bandwidth of 1MHz,
which is delivering 0.5A of current from a 2.5V output (which
means RL is 5 Ohms). We then place a .047 µF capacitor on
the output. This creates a pole whose frequency is:
Fp = 1 / (2 X π X 5 X .047 X 10E-6) = 677 kHz
This pole would add close to 60 degrees of phase lag at the
crossover (unity gain) frequency of 1 MHz, which would
almost certainly make this regulator oscillate. Depending on
the load current, output voltage, and bandwidth, there are
usually values of small capacitors which can seriously reduce phase margin. If the capacitors are ceramic, they tend
to oscillate more easily because they have very little internal
inductance to damp it out. If bypass capacitors are used, it is
best to place them near the load and use trace inductance to
"decouple" them from the regulator output.
OUTPUT CAPACITOR
At least 4.7µF of output capacitance is required for stability
(the amount of capacitance can be increased without limit).
The output capacitor must be located less than 1 cm from
the output pin of the IC and returned to a clean analog
ground. The ESR (equivalent series resistance) of the output
capacitor must be within the "stable" range as shown in the
graph below over the full operating temperature range for
stable operation.
INPUT CAPACITOR
The input capacitor must be at least 4.7 µF, but can be
increased without limit. It’s purpose is to provide a low
source impedance for the regulator input. Ceramic capacitors work best for this, but Tantalums are also very good.
There is no ESR limitation on the input capacitor (the lower,
the better). Aluminum electrolytics can be used, but their
ESR increase very quickly at cold temperatures. They are
not recommended for any application where temperatures
go below about 10˚C.
20063231
Minimum ESR vs Output Load Current
Tantalum capacitors are recommended for the output as
their ESR is ideally suited to the part’s requirements and the
ESR is very stable over temperature. Aluminum electrolytics
are not recommended because their ESR increases very
rapidly at temperatures below 10C. Aluminum caps can only
be used in applications where lower temperature operation
is not required.
A second problem with Al caps is that many have ESR’s
which are only specified at low frequencies. The typical loop
bandwidth of a linear regulator is a few hundred kHz to
several MHz. If an Al cap is used for the output cap, it must
be one whose ESR is specified at a frequency of 100 kHz or
more.
Because the ESR of ceramic capacitors is only a few milli
Ohms, they are not suitable for use as output capacitors on
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BIAS CAPACITOR
The 0.1µF capacitor on the bias line can be any good quality
capacitor (ceramic is recommended).
BIAS VOLTAGE
The bias voltage is an external voltage rail required to get
gate drive for the N-FET pass transistor. Bias voltage must
be in the range of 4.5 - 6V to assure proper operation of the
part.
8
The heatsink to be used in the application should have a
heatsink to ambient thermal resistance,
(Continued)
UNDER VOLTAGE LOCKOUT
θHA≤ θJA − θCH − θJC.
The bias voltage is monitored by a circuit which prevents the
regulator output from turning on if the bias voltage is below
approximately 4V.
In this equation, θCH is the thermal resistance from the case
to the surface of the heat sink and θJC is the thermal resistance from the junction to the surface of the case. θJC is
about 3˚C/W for a TO220 package. The value for θCH depends on method of attachment, insulator, etc. θCH varies
between 1.5˚C/W to 2.5˚C/W. If the exact value is unknown,
2˚C/W can be assumed.
SHUTDOWN OPERATION
Pulling down the shutdown (S/D) pin will turn-off the regulator. Pin S/D must be actively terminated through a pull-up
resistor (10 kΩ to 100 kΩ) for a proper operation. If this pin
is driven from a source that actively pulls high and low (such
as a CMOS rail to rail comparator), the pull-up resistor is not
required. This pin must be tied to Vin if not used.
HEATSINKING TO-263 PACKAGE
The TO-263 package uses the copper plane on the PCB as
a heatsink. The tab of these packages are soldered to the
copper plane for heat sinking. The graph below shows a
curve for the θJA of TO-263 package for different copper area
sizes, using a typical PCB with 1 ounce copper and no solder
mask over the copper area for heat sinking.
POWER DISSIPATION/HEATSINKING
A heatsink may be required depending on the maximum
power dissipation and maximum ambient temperature of the
application. Under all possible conditions, the junction temperature must be within the range specified under operating
conditions. The total power dissipation of the device is given
by:
PD = (VIN−VOUT)IOUT+ (VIN)IGND
where IGND is the operating ground current of the device.
The maximum allowable temperature rise (TRmax) depends
on the maximum ambient temperature (TAmax) of the application, and the maximum allowable junction temperature
(TJmax):
TRmax = TJmax− TAmax
The maximum allowable value for junction to ambient Thermal Resistance, θJA, can be calculated using the formula:
θJA = TRmax / PD
These parts are available in TO-220 and TO-263 packages.
The thermal resistance depends on amount of copper area
or heat sink, and on air flow. If the maximum allowable value
of θJA calculated above is ≥ 60 ˚C/W for TO-220 package
and ≥ 60 ˚C/W for TO-263 package no heatsink is needed
since the package can dissipate enough heat to satisfy these
requirements. If the value for allowable θJA falls below these
limits, a heat sink is required.
20063225
FIGURE 1. θJA vs Copper (1 Ounce) Area for TO-263
package
HEATSINKING TO-220 PACKAGE
The thermal resistance of a TO220 package can be reduced
by attaching it to a heat sink or a copper plane on a PC
board. If a copper plane is to be used, the values of θJA will
be same as shown in next section for TO263 package.
9
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LP3882
Application Hints
LP3882
Application Hints
(Continued)
As shown in the graph below, increasing the copper area
beyond 1 square inch produces very little improvement. The
minimum value for θJA for the TO-263 package mounted to a
PCB is 32˚C/W.
Figure 2 shows the maximum allowable power dissipation
for TO-263 packages for different ambient temperatures,
assuming θJA is 35˚C/W and the maximum junction temperature is 125˚C.
20063226
FIGURE 2. Maximum power dissipation vs ambient
temperature for TO-263 package
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10
LP3882
Physical Dimensions
inches (millimeters) unless otherwise noted
TO220 5-lead, Molded, Stagger Bend Package (TO220-5)
NS Package Number T05D
11
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LP3882 1.5A Fast-Response Ultra Low Dropout Linear Regulators
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
TO263 5-Lead, Molded, Surface Mount Package (TO263-5)
NS Package Number TS5B
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