LP38500-ADJ,LP38502-ADJ
LP38500/2-ADJ, LP38500A/2A-ADJ 1.5A FlexCap Low Dropout Linear Regulator
for 2.7V to 5.5V Inputs
Literature Number: SNVS539E
LP38500/2-ADJ, LP38500A/
2A-ADJ
October 30, 2009
1.5A FlexCap Low Dropout Linear Regulator for 2.7V to
5.5V Inputs
General Description
National's FlexCap LDO's feature unique compensation that
allows the use of any type of output capacitor with no limits
on minimum or maximum ESR. The LP38500/2 series of low-
dropout linear regulators operates from a +2.7V to +5.5V input
supply. These ultra low dropout linear regulators respond very
quickly to step changes in load, which makes them suitable
for low voltage microprocessor applications. Developed on a
CMOS process, (utilizing a PMOS pass transistor), the
LP38500/2 has low quiescent current that changes little with
load current.
Ground Pin Current: Typically 2 mA at 1.5A load current.
Disable Mode: Typically 25 nA quiescent current when the
Enable pin is pulled low.
Simplified Compensation: Stable with any type of output
capacitor, regardless of ESR.
Precision Output: "A" grade versions available with 1.5%
VADJ tolerance (25°C) and 3% over line, load and tempera-
ture.
Features
■FlexCap: Stable with ceramic, tantalum, or aluminum
capacitors
■Stable with 10 µF input/output capacitor
■Adjustable output voltage from 0.6V to 5V
■Low ground pin current
■25 nA quiescent current in shutdown mode
■Guaranteed output current of 1.5A
■Available in TO-263, TO-263 THIN, and LLP-8 packages
■Guaranteed VADJ accuracy of ±1.5% @ 25°C (A Grade)
■Guaranteed accuracy of ±3.5% @ 25°C (STD)
■Over-Temperature and Over-Current protection
■−40°C to +125°C operating TJ range
■Enable pin (LP38502)
Applications
■ASIC Power Supplies In:
Printers, Graphics Cards, DVD Players
Set Top Boxes, Copiers, Routers
■DSP and FPGA Power Supplies
■SMPS Regulator
■Conversion from 3.3V or 5V Rail
Typical Application Circuit
30036119
© 2009 National Semiconductor Corporation 300361 www.national.com
LP38500/2-ADJ, LP38500A/2A-ADJ 1.5A FlexCap Low Dropout Linear Regulator for 2.7V to 5.5V
Inputs
Connection Diagrams for TO-263 (TS) Package
30036121
Top View (LP38500TS-ADJ)
TO-263 Package
30036122
Top View (LP38502TS-ADJ)
TO-263 Package
Connection Diagrams for TO-263 THIN (TJ) Package
30036163
Top View (LP38500TJ-ADJ, LP38500ATJ-ADJ)
TO-263 THIN Package
30036162
Top View (LP38502TJ-ADJ, LP38502ATJ-ADJ)
TO-263 THIN Package
Pin Descriptions for TO-263 (TS), TO-263 THIN (TJ) Packages
Pin # Designation Function
1
EN Enable (LP38502 only). Pull high to enable the output, low to disable the output. This pin has
no internal bias and must be either tied to the input voltage, or actively driven.
N/C In the LP38500, this pin has no internal connections. It can be left floating or used for trace
routing.
2 IN Input Supply
3 GND Ground
4 OUT Regulated Output Voltage
5 ADJ Sets output voltage
DAP DAP
The DAP is used to remove heat from the device by conducting it to the copper clad area on
the PCB which acts as the heatsink. The DAP is electrically connected to the backside of the
die. The DAP must be connected to ground potential, but can not be used as the only ground
connection.
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LP38500/2-ADJ, LP38500A/2A-ADJ
Connection Diagrams for LLP-8 (SD) Package
30036159
Top View (LP38500SD-ADJ, LP38500ASD-ADJ)
LLP-8 Package
30036160
Top View (LP38502SD-ADJ, LP38502ASD-ADJ)
LLP-8 Package
Pin Descriptions for LLP-8 (SD) Package
Pin # Designation Function
1 GND Ground
2
IN Input Supply (LP38500 only). Input Supply pins share current and must be connected
together on the PC Board.
EN Enable (LP38502 only). Pull high to enable the output, low to disable the output. This pin has
no internal bias and must be either tied to the input voltage, or actively driven.
3, 4 IN Input Supply. Input Supply pins share current and must be connected together on the PC
Board.
5, 6, 7 OUT Regulated Output Voltage. Output pins share current and must be connected together on the
PC Board.
8 ADJ Sets output voltage
DAP DAP
The DAP is used to remove heat from the device by conducting it to a copper clad area on
the PCB which acts as a heatsink. The DAP is electrically connected to the backside of the
die. The DAP must be connected to ground potential, but can not be used as the only ground
connection.
Ordering Information
TABLE 1. Package Marking and Ordering Information
Output
Voltage
Order Number Package Type Package Marking Supplied As:
ADJ
LP38500SDX-ADJ
LLP-8
LP38500SD-ADJ Tape and Reel of 4500 Units
LP38500SD-ADJ LP38500SD-ADJ Tape and Reel of 1000 Units
LP38502SDX-ADJ LP38502SD-ADJ Tape and Reel of 4500 Units
LP38502SD-ADJ LP38502SD-ADJ Tape and Reel of 1000 Units
LP38500ASDX-ADJ LP38500ASD-ADJ Tape and Reel of 4500 Units
LP38500ASD-ADJ LP38500ASD-ADJ Tape and Reel of 1000 Units
LP38502ASDX-ADJ LP38502ASD-ADJ Tape and Reel of 4500 Units
LP38502ASD-ADJ LP38502ASD-ADJ Tape and Reel of 1000 Units
ADJ
LP38500TSX-ADJ
TO-263
LP38500TS-ADJ Tape and Reel of 500 Units
LP38500TS-ADJ LP38500TS-ADJ Rail of 45 Units
LP38502TSX-ADJ LP38502TS-ADJ Tape and Reel of 500 Units
LP38502TS-ADJ LP38502TS-ADJ Rail of 45 Units
ADJ
LP38500TJ-ADJ
TO-263 THIN
LP38500TJ-ADJ Tape and Reel of 1000 Units
LP38502TJ-ADJ LP38502TJ-ADJ Tape and Reel of 1000 Units
LP38500ATJ-ADJ LP38500ATJ-ADJ Tape and Reel of 1000 Units
LP38502ATJ-ADJ LP38502ATJ-ADJ Tape and Reel of 1000 Units
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LP38500/2-ADJ, LP38500A/2A-ADJ
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Storage Temperature Range −65°C to +150°C
Lead Temperature
(Soldering, 5 sec.) 260°C
ESD Rating (Note 2) ±2 kV
Power Dissipation(Note 3) Internally Limited
Input Pin Voltage (Survival) −0.3V to +6.0V
Enable Pin Voltage (Survival) −0.3V to +6.0V
Output Pin Voltage (Survival) −0.3V to +6.0V
IOUT (Survival) Internally Limited
Operating Ratings (Note 1)
Input Supply Voltage 2.7V to 5.5V
Enable Input Voltage 0.0V to 5.5V
Output Current (DC) 0 to 1.5A
Junction Temperature(Note 3) −40°C to +125°C
VOUT 0.6V to 5V
Electrical Characteristics
LP38500/2–ADJ
Unless otherwise specified: VIN = 3.3V, IOUT = 10 mA, CIN = 10 µF, COUT = 10 µF, VEN = VIN, VOUT = 1.8V. Limits in standard type
are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of -40°C to +125°C. Minimum and
Maximum limits are guaranteed through test, design, or statistical correlation. Typical values represent the most likely parametric
norm at TJ = 25°C, and are provided for reference purposes only.
Symbol Parameter Conditions Min Typ Max Units
VADJ Adjust Pin Voltage (Note 6)2.7V ≤ VIN ≤ 5.5V
10 mA ≤ IOUT ≤ 1.5A
0.584
0.575 0.605 0.626
0.635 V
VADJ
Adjust Pin Voltage (Note 6)
"A" GRADE
2.7V ≤ VIN ≤ 5.5V
10 mA ≤ IOUT ≤ 1.5A
0.596
0.587 0.605 0.614
0.623 V
IADJ Adjust Pin Bias Current 2.7V ≤ VIN ≤ 5.5V 50 750 nA
VDO Dropout Voltage (Note 7)IOUT = 1.5A 220 275
375 mV
ΔVOUT/ΔVIN
Output Voltage Line
Regulation
(Note 4, Note 6)
2.7V ≤ VIN ≤ 5.5V —0.04
0.05 —%/V
ΔVOUT/ΔIOUT
Output Voltage Load
Regulation
(Note 5, Note 6)
10 mA ≤ IOUT ≤ 1.5A —0.18
0.33 —%/A
IGND
Ground Pin Current In Normal
Operation Mode 10 mA ≤ IOUT ≤ 1.5A —23.5
4.5 mA
IDISABLED Ground Pin Current VEN < VIL(EN) —0.025 0.125
15 µA
IOUT(PK) Peak Output Current VOUT ≥ VOUT(NOM) - 5% 3.6 A
ISC Short Circuit Current VOUT = 0V 23.7 A
Enable Input (LP38502 Only)
VIH(EN) Enable Logic High VOUT = ON 1.4 — — V
VIL(EN) Enable Logic Low VOUT = OFF — — 0.65
td(off) Turn-off delay
Time from VEN < VIL(EN) to VOUT =
OFF
ILOAD = 1.5A
—25 —
µs
td(on) Turn-on delay
Time from VEN >VIH(EN) to VOUT =
ON
ILOAD = 1.5A
—25 —
IIH(EN) Enable Pin High Current VEN = VIN —1—nA
IIL(EN) Enable Pin Low Current VEN = 0V —0.1 —
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LP38500/2-ADJ, LP38500A/2A-ADJ
Symbol Parameter Conditions Min Typ Max Units
AC Parameters
PSRR Ripple Rejection
VIN = 3.0V, IOUT = 1.5A
f = 120Hz —58 —
dB
VIN = 3.0V, IOUT = 1.5A
f = 1 kHz —56 —
ρn(l/f) Output Noise Density f = 120Hz, COUT = 10 µF CER —1.0 —µV/√Hz
enOutput Noise Voltage BW = 100Hz – 100kHz
COUT = 10 µF CER —100 —µV (rms)
Thermal Characteristics
TSD Thermal Shutdown TJ rising —170 —°C
ΔTSD Thermal Shutdown Hysteresis TJ falling from TSD —10 —
θJ-A
Thermal Resistance
Junction to Ambient
TO-263, TO-263 THIN(Note 8)
1 sq. in. copper —37 —
°C/W
Thermal Resistance
Junction to Ambient LLP-8 (Note 9)—80 —
θJ-C
Thermal Resistance
Junction to Case
TO-263, TO-263 THIN —5—°C/W
LLP-8 —16 —
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but does not guarantee specific performance limits. For guaranteed specifications and conditions, see the Electrical Characteristics.
Note 2: The human body model is a 100pF capacitor discharged through a 1.5kΩ resistor into each pin.
Note 3: Operating junction temperature must be evaluated, and derated as needed, based on ambient temperature (TA), power dissipation (PD), maximum
allowable operating junction temperature (TJ(MAX)), and package thermal resistance (θJA). See Application Information.
Note 4: Output voltage line regulation is defined as the change in output voltage from the nominal value due to change in the voltage at the input.
Note 5: Output voltage load regulation is defined as the change in output voltage from the nominal value due to change in the load current.
Note 6: The line and load regulation specification contains only the typical number. However, the limits for line and load regulation are included in the adjust
voltage tolerance specification.
Note 7: Dropout voltage is defined as the minimum input to output differential voltage at which the output drops 2% below the nominal value. For any output
voltage less than 2.5V, the minimum VIN operating voltage is the limiting factor.
Note 8: The value of θJA for the TO-263 (TS) package and TO-263 THIN (TJ) package can range from approximately 30 to 60°C/W depending on the amount of
PCB copper dedicated to heat transfer (See Application Information).
Note 9: θJA for the LLP-8 package was measured using the LP38502SD-ADJ evaluation board (See Application Information).
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LP38500/2-ADJ, LP38500A/2A-ADJ
Typical Performance Characteristics Unless otherwise specified: TJ = 25°C, VIN = 2.7V, VEN = VIN,
CIN = 10 µF, COUT = 10 µF, IOUT = 10 mA, VOUT = 1.8V
Noise Density
30036110
Noise Density
30036114
IGND vs Load Current
30036111
IGND(OFF) vs Temperature
30036112
VADJ vs Temperature
30036113
Dropout Voltage vs Load Current
30036115
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LP38500/2-ADJ, LP38500A/2A-ADJ
VEN vs Temperature
30036116
Turn-on Characteristics
30036117
Turn-on Time
30036155
Turn-on Time
30036156
PSRR
30036120
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LP38500/2-ADJ, LP38500A/2A-ADJ
Block Diagrams (TO-263, TO-263 THIN)
LP38500-ADJ TO-263 Block Diagram
30036150
LP38502-ADJ TO-263 Block Diagram
30036151
Block Diagrams (LLP-8)
LP38500-ADJ LLP-8 Block Diagram
30036158
LP38502-ADJ LLP-8 Block Diagram
30036151
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LP38500/2-ADJ, LP38500A/2A-ADJ
Application Information
EXTERNAL CAPACITORS
The LP3850X requires that at least 10 µF (±20%) capacitors
be used at the input and output pins located within one cm of
the IC. Larger capacitors may be used without limit on size for
both CIN and COUT. Capacitor tolerances such as temperature
variation and voltage loading effects must be considered
when selecting capacitors to ensure that they will provide the
minimum required amount of capacitance under all operating
conditions for the application.
In general, ceramic capacitors are best for noise bypassing
and transient response because of their ultra low ESR. It must
be noted that if ceramics are used, only the types with X5R
or X7R dielectric ratings should be used (never Z5U or Y5F).
Capacitors which have the Z5U or Y5F characteristics will see
a drop in capacitance of as much as 50% if their temperature
increases from 25°C to 85°C. In addition, the capacitance
drops significantly with applied voltage: a typical Z5U or Y5F
capacitor can lose as much as 60% of it’s rated capacitance
if only half of the rated voltage is applied to it. For these rea-
sons, only X5R and X7R ceramics should be used.
INPUT CAPACITOR
All linear regulators can be affected by the source impedance
of the voltage which is connected to the input. If the source
impedance is too high, the reactive component of the source
may affect the control loop’s phase margin. To ensure prop-
er loop operation, the ESR of the capacitor used for CIN
must not exceed 0.5 Ohms. Any good quality ceramic ca-
pacitor will meet this requirement, as well as many good
quality tantalums. Aluminum electrolytic capacitors may also
work, but can possibly have an ESR which increases signifi-
cantly at cold temperatures. If the ESR of the input capacitor
may exceed 0.5 Ohms, it is recommended that a 2.2 µF ce-
ramic capacitor be used in parallel, as this will assure stable
loop operation.
OUTPUT CAPACITOR
Any type of capacitor may be used for COUT, with no limita-
tions on minimum or maximum ESR, as long as the minimum
amount of capacitance is present. The amount of capacitance
can be increased without limit. Increasing the size of COUT
typically will give improved load transient response.
SETTING THE OUTPUT VOLTAGE
The output voltage of the LP38500/2-ADJ can be set to any
value between 0.6V and 5V using two external resistors
shown as R1 and R2 in Figure 1.
30036161
FIGURE 1.
The value of R2 should always be less than or equal to 10
kΩ for good loop compensation. R1 can be selected for a giv-
en VOUT using the following formula:
VOUT = VADJ (1 + R1/R2) + IADJ (R1)
Where VADJ is the adjust pin voltage and IADJ is the bias cur-
rent flowing into the adjust pin.
STABILITY AND PHASE MARGIN
Any regulator which operates using a feedback loop must be
compensated in such a way as to ensure adequate phase
margin, which is defined as the difference between the phase
shift and -180 degrees at the frequency where the loop gain
crosses unity (0 dB). For most LDO regulators, the ESR of the
output capacitor is required to create a zero to add enough
phase lead to ensure stable operation. The LP38500/2-ADJ
has a unique internal compensation circuit which maintains
phase margin regardless of the ESR of the output capacitor,
so any type of capacitor may be used.
Figure 2 shows the gain/phase plot of the LP38500/2-ADJ
with an output of 1.2V, 10 µF ceramic output capacitor, deliv-
ering 1.5A of load current. It can be seen that the unity-gain
crossover occurs at 150 kHz, and the phase margin is about
40° (which is very stable).
30036153
FIGURE 2. Gain-Bandwidth Plot for 1.5A Load
Figure 3 shows the gain and phase with no external load. In
this case, the only load is provided by the gain setting resistors
(about 12 kΩ total in this test). It is immediately obvious that
the unity-gain frequency is significantly lower (dropping to
about 500 Hz), at which point the phase margin is 125°.
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LP38500/2-ADJ, LP38500A/2A-ADJ
30036154
FIGURE 3. Gain-Bandwidth Plot for No Load
The reduction in unity-gain bandwidth as load current is re-
duced is normal for any LDO regulator using a P-FET or PNP
pass transistor, because they have a pole in the loop gain
function given by:
This illustrates how the pole goes to the highest frequency
when RL is minimum value (maximum load current). In gen-
eral, LDO’s have maximum bandwidth (and lowest phase
margin) at full load current. In the case of the LP38500/2-ADJ,
it can be seen that it has good phase margin even when using
ceramic capacitors with ESR values of only a few milli Ohms.
LOAD TRANSIENT RESPONSE
Load transient response is defined as the change in regulated
output voltage which occurs as a result of a change in load
current. Many applications have loads which vary, and the
control loop of the voltage regulator must adjust the current
in the pass FET transistor in response to load current
changes. For this reason, regulators with wider bandwidths
often have better transient response.
The LP38500/2-ADJ employs an internal feedforward design
which makes the load transient response much faster than
would be predicted simply by loop speed: this feedforward
means any voltage changes appearing on the output are cou-
pled through to the high-speed driver used to control the gate
of the pass FET along a signal path using very fast FET de-
vices. Because of this, the pass transistor’s current can
change very quickly.
Figure 3 shows the output voltage load transient which occurs
on a 1.8V output when the load changes from 0.1A to 1.5A at
an average slew rate of 0.5A/µs. As shown, the peak output
voltage change from nominal is about 40 mV, which is about
2.2%.
30036157
FIGURE 4. Load Transient Response
In cases where extremely fast load changes occur, the output
capacitance may have to be increased. When selecting ca-
pacitors, it must be understood that the better performing
ones usually cost the most. For fast changing loads, the in-
ternal parasitics of ESR (equivalent series resistance) and
ESL (equivalent series inductance) degrade the capacitor’s
ability to source current quickly to the load. The best capacitor
types for transient performance are (in order):
1. Multilayer Ceramic: with the lowest values of ESR and
ESL, they can have ESR values in the range of a few milli
Ohms. Disadvantage: capacitance values above about
22 µF significantly increase in cost.
2. Low-ESR Aluminum Electrolytics: these are aluminum
types (like OSCON) with a special electrolyte which
provides extremely low ESR values, and are the closest
to ceramic performance while still providing large
amounts of capacitance. These are cheaper (by
capacitance) than ceramic.
3. Solid tantalum: can provide several hundred µF of
capacitance, transient performance is slightly worse than
OSCON type capacitors, cheaper than ceramic in large
values.
4. General purpose aluminum electrolytics: cheap and
provide a lot of capacitance, but give the worst
performance.
In general, managing load transients is done by paralleling
ceramic capacitance with a larger bulk capacitance. In this
way, the ceramic can source current during the rapidly chang-
ing edge and the bulk capacitor can support the load current
after the first initial spike in current.
PRINTED CIRCUIT BOARD LAYOUT
Good layout practices will minimize voltage error and prevent
instability which can result from ground loops. The input and
output capacitors should be directly connected to the IC pins
with short traces that have no other current flowing in them
(Kelvin connect).
The best way to do this is to place the capacitors very near
the IC and make connections directly to the IC pins via short
traces on the top layer of the PCB. The regulator’s ground pin
should be connected through vias to the internal or backside
ground plane so that the regulator has a single point ground.
The external resistors which set the output voltage must also
be located very near the IC with all connections directly tied
via short traces to the pins of the IC (Kelvin connect). Do not
connect the resistive divider to the load point or DC error will
be induced.
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LP38500/2-ADJ, LP38500A/2A-ADJ
RFI/EMI SUSCEPTIBILITY
RFI (Radio Frequency Interference) and EMI (Electro-Mag-
netic Interference) can degrade any integrated circuit's per-
formance because of the small dimensions of the geometries
inside the device. In applications where circuit sources are
present which generate signals with significant high frequen-
cy energy content (> 1 MHz), care must be taken to ensure
that this does not affect the IC regulator.
If RFI/EMI noise is present on the input side of the regulator
(such as applications where the input source comes from the
output of a switching regulator), good ceramic bypass capac-
itors must be used at the input pin of the IC to reduce the
amount of EMI conducted into the IC.
If the LP38500/2-ADJ output is connected to a load which
switches at high speed (such as a clock), the high-frequency
current pulses required by the load must be supplied by the
capacitors on the IC output. Since the bandwidth of the reg-
ulator loop is less than 300 kHz, the control circuitry cannot
respond to load changes above that frequency. This means
the effective output impedance of the IC at frequencies above
300 kHz is determined only by the output capacitor(s). Ce-
ramic capacitors provide the best performance in this type of
application.
In applications where the load is switching at high speed, the
output of the IC may need RF isolation from the load. In such
cases, it is recommended that some inductance be placed
between the output capacitor and the load, and good RF by-
pass capacitors be placed directly across the load. PCB
layout is also critical in high noise environments, since RFI/
EMI is easily radiated directly into PC traces. Noisy circuitry
should be isolated from "clean" circuits where possible, and
grounded through a separate path. At MHz frequencies,
ground planes begin to look inductive and RFI/EMI can cause
ground bounce across the ground plane. In multi-layer PC
Board applications, care should be taken in layout so that
noisy power and ground planes do not radiate directly into
adjacent layers which carry analog power and ground.
OUTPUT NOISE
Noise is specified in two ways:
Spot Noise or Output noise density is the RMS sum of all
noise sources, measured at the regulator output, at a specific
frequency (measured with a 1Hz bandwidth). This type of
noise is usually plotted on a curve as a function of frequency.
Total output noise voltage or Broadband noise is the RMS
sum of spot noise over a specified bandwidth, usually several
decades of frequencies. Attention should be paid to the units
of measurement.
Spot noise is measured in units µV/√Hz or nV/√Hz and total
output noise is measured in µV(rms). The primary source of
noise in low-dropout regulators is the internal reference. In
CMOS regulators, noise has a low frequency component and
a high frequency component, which depend strongly on the
silicon area and quiescent current.
Noise can generally be reduced in two ways: increase the
transistor area or increase the reference current. However,
enlarging the transisitors will increase die size, and increasing
the reference current means higher total supply current
(ground pin current).
SHORT-CIRCUIT PROTECTION
The LP38500/2-ADJ contains internal current limiting which
will reduce output current to a safe value if the output is over-
loaded or shorted. Depending upon the value of VIN, thermal
limiting may also become active as the average power dissi-
pated causes the die temperature to increase to the limit value
(about 170°C). The hysteresis of the thermal shutdown cir-
cuitry can result in a “cyclic” behavior on the output as the die
temperature heats and cools.
ENABLE OPERATION (LP38502-ADJ Only)
The Enable pin (EN) must be actively terminated by either a
10 kΩ pull-up resistor to VIN, or a driver which actively pulls
high and low (such as a CMOS rail to rail comparator). If active
drive is used, the pull-up resistor is not required. This pin must
be tied to VIN if not used (it must not be left floating).
DROPOUT VOLTAGE
The dropout voltage of a regulator is defined as the input-to-
output differential required by the regulator to keep the output
voltage within 2% of the nominal value. For CMOS LDOs, the
dropout voltage is the product of the load current and the
RDS(on) of the internal MOSFET pass element.
Since the output voltage is beginning to “drop out” of regula-
tion when it drops by 2%, electrical performance of the device
will be reduced compared to the values listed in the Electrical
Characteristics table for some parameters (line and load reg-
ulation and PSRR would be affected).
REVERSE CURRENT PATH
The internal MOSFET pass element in the LP38500/2-ADJ
has an inherent parasitic diode. During normal operation, the
input voltage is higher than the output voltage and the para-
sitic diode is reverse biased. However, if the output is pulled
above the input in an application, then current flows from the
output to the input as the parasitic diode gets forward biased.
The output can be pulled above the input as long as the cur-
rent in the parasitic diode is limited to 200 mA continuous and
1A peak. The regulator output pin should not be taken below
ground potential. If the LP38500/2-ADJ is used in a dual-sup-
ply system where the regulator load is returned to a negative
supply, the output must be diode-clamped to ground.
POWER DISSIPATION/HEATSINKING
The maximum power dissipation (PD(MAX)) of the LP38500/2-
ADJ is limited by the maximum junction temperature of
125°C, along with the maximum ambient temperature (TA
(MAX)) of the application, and the thermal resistance (θJA) of
the package. Under all possible conditions, the junction tem-
perature (TJ) must be within the range specified in the Oper-
ating Ratings. The total power dissipation of the device is
given by:
PD = ((VIN − VOUT) x IOUT) + (VIN x IGND) (1)
where IGND is the operating ground current of the device
(specified under Electrical Characteristics).
The maximum allowable junction temperature rise (ΔTJ) de-
pends on the maximum expected ambient temperature
(TA(MAX)) of the application, and the maximum allowable junc-
tion temperature (TJ(MAX)):
ΔTJ = TJ(MAX)− TA(MAX) (2)
The maximum allowable value for junction to ambient Ther-
mal Resistance, θJA, can be calculated using the formula:
θJA = ΔTJ / PD(MAX) (3)
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LP38500/2-ADJ, LP38500A/2A-ADJ
The LP38500/2-ADJ is available in the TO-263 and LLP-8
packages. The thermal resistance depends on the amount of
copper area allocated to heat transfer.
HEATSINKING TO-263 and TO-263 THIN PACKAGES
The TO-263 package and TO-263 THIN package use the
copper plane on the PCB as a heatsink. The DAP of the pack-
age is soldered to the copper plane for heat sinking. Figure
5 shows a typical curve for the θJA of the TO-263 package for
different copper area sizes (the thermal performance of both
TO-263 and TO-263 THIN are the same). The tests were
done using a PCB with 1 ounce copper on top side only, with
copper patterns which were square in shape.
30036152
FIGURE 5. θJA vs Copper Area for TO-263 Package
As shown in the figure, increasing the copper area beyond 1.5
square inch produces very little improvement.
HEATSINKING LLP-8 PACKAGE
The junction-to-ambient thermal resistance for the LLP-8
package is dependent on how much PCB copper is present
to conduct heat away from the device. The LP38502SD-ADJ
evaluation board (980600046-100) was tested and gave a
result of about 80°C/W with a power dissipation of 1W and no
external airflow. This evaluation board is a two layer board
using two ounce copper, and the copper area on topside for
heatsinking is approximately two square inches. Multiple vias
under the DAP also thermally connect to the backside layer
which has about three square inches of copper dedicated to
heatsinking.
Finite modeling of the LP38502SD-ADJ with a four layer
board (JEDEC JESD51-7 and JESD51-5) with one thermal
via directly under the DAP to the first copper plane predicts a
θJA of 72°C/W.
With four thermal vias directly under the DAP to the first cop-
per plane, the modeling predicts a θJA of 50°C/W.
Adding a dog-bone copper area with four additional thermal
vias in the dog-bone area to the first copper plane can improve
θJA to 45C°C/W.
See Application Note AN-1520 A Guide to Board Layout for
Best Thermal Resistance for Exposed Packages for addition-
al thermal considerations for printed circuit board layouts.
www.national.com 12
LP38500/2-ADJ, LP38500A/2A-ADJ
Physical Dimensions inches (millimeters) unless otherwise noted
TO-263 5-Lead, Molded, Surface Mount Package
NS Package Number TS5B
TO-263 THIN 5-Lead, Molded, Surface Mount Package
NS Package Number TJ5A
13 www.national.com
LP38500/2-ADJ, LP38500A/2A-ADJ
8-Lead LLP Package
NS Package Number SDA08C
www.national.com 14
LP38500/2-ADJ, LP38500A/2A-ADJ
Notes
15 www.national.com
LP38500/2-ADJ, LP38500A/2A-ADJ
Notes
LP38500/2-ADJ, LP38500A/2A-ADJ 1.5A FlexCap Low Dropout Linear Regulator for 2.7V to 5.5V
Inputs
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