Datasheet LND5203, LND5203-5.0, LND5203-3.5, LND5203-3.3, LND5203-3.0 Datasheet (Linear Dimensions)

DATA SHEET

LND5203

3 A Low Dropout Positive Voltage Regulator

GENERAL DESCRIPTION

The LND5203 series of positive adjustable and
fixed regulators are designed to provide 3A with
higher efficiency than currently available
devices. All internal circuitry are designed to
operate down to 700mV input to output
differential and the dropout voltage is fully
specified as a function of load current. Dropout
voltage of the device is 100mV at light loads and
rising to 700mV at maximum output current. A
second low current input is required to achieve
this dropout. The LND5203 can also be used as
a single supply device (3-pin version). On-chip
trimming adjusts the reference voltage to 1%.

FEATURES

• Adjustable or fixed Output

• Output Current of 3A

• Low Dropout, 700mV at 3A Output

Current

• 0.04% Line Regulation

• 0.1% Load Regulation

• 100% Thermal Limit Burn-In

• Fast Transient Response

• Remote Sense

TYPICAL APPLICATION DATA

2.5 V, 3A Regulator

V

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

OUT

= V

(I+R2/R1) +I

REF

ADJ

R2

APPLICATIONS

• High efficiency Linear Regulators

• Post Regulators for Switching

Supplies

• Adjustable Power Supply

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LND5203

Package Information

3 LEAD TO –220 (Front view) 5 LEAD TO –220 (Front View)

Vpower

Vin
Vout
ADJ/GND

Absolute Maximum Rating

SYMBOL PARAMETER MAXIMUM UNITS

P

V

T

T

T

d

in

J

STG

LEAD

Power Dissipation Internally limited W
Input Voltage
V

Power

V

Control

Operating Junction
Temperature range

Control Section
Power Transistor

Storage Temperature -65 to 150 ºC
Lead Temperature (Soldering,

10 sec)

7

13

0 to 125
0 to 150

300 ºC

Vcontrol
OUTPUT
ADJ/GND
SENSE

V

ºC

Device Selection Guide (note 1)

DEVICE OUTPUT VOLTAGE

LND5203 Adj.
LND5203-1.5 1.5V
LND5203-2.5 2.5V

LND5203-2.85 2.85V

LND5203-3.0 3.0V
LND5203-3.3 3.3V
LND5203-3.5 3.5V
LND5203-5.0 5.0V

Note 1: Other fixed versions are available V

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

=1.5v to 5.0V

Out

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LND5203

Electrical Characteristics

At I

= 0mA and TJ = ± 25 °C unless otherwise specified

load

PARAMETER DEVICE TEST CONDITIONS MIN TYP MAX UNIT

=2.75V, V

V

control

10mA

Reference Voltage LND5203

V

=2.7V to 12 V

Control

V

=3.3V to 5.5V, I

Power

3A
V

=4V, V

LND5203-1.5

V

Control

Control

=3V, V

to 3A
V

=5V, V

Control

V

LND5203-2.5

Control

=4V, V

to 3A

V

=5.35V, V

Control

V

=4.4V,V

Control

=0mA to 3A

Load

V

=5.5V, V

Control

V

=4.5V, V

Control

Output Voltage

LND5203-2.85

LND5203-3.0

to 3A
V

=5.8V, V

LND5203-3.3

V

Control

Control

=4.8V, V

0mA to 3A
V

=6V,V

LND5203-3.5

V

Control

Control

=5V, V

to 3A
V

=7.5V, V

LND5203-5.0

V

Control

Control

=6.5V V

to 3 A

=10mA, (1.5V+Vout) <= V

I

Line Regulation All

Load

<= 12V,0.8V <=(V

5.5V
V

Load Regulation All

Minimum Load
Current(Note 2)

LND5203 V

Control Pin Current(Note 3) All

LND5203-1.5/-

Ground Pin Current

2.5/-2.85/-3.0/-

3.3/-3.5/-5.0

Adjust Pin Current LND5203

Control=VOut

+0.8V, Iload=10mA to 3A

Control

V

Control=VOut

I

Load

V

Control=VOut

I

Load

V

Control

I

Load

Current Limit All (VIn-V

V

Ripple Rejection All

Control=VPower=VOut

.p, I

+2.5V,V

=5V,V

+2.5V, V

=10mA to 3A

+2.5, V

=10mA to 3A

=2.75V, V

=10mA

)=3V * 3 4 A

Out

=1.5A

Load

Thermal Regulation LND5203 TA=25ºC,30ms pulse 0.003 %/W
Dropout Voltage Note 4

Control Input All

Power Input
(V

Power-VOut

)

All V

V

Power=VOut

V

Power=VOut

Control=VOut

+0.8, I
+0.8Vi

+2.5V, I

Power

Power

Power

Power

Power

Power

Power

power

= 2V, I

Load

=

1.238

1.250

*

=10mA to

Load

=2V

=2.3V,I

Load

=0mA

=3.3V

Power

Power

Power

Power

Power

Power

=3.3V I

=3.7V, I

3.8V, I

=3.8V
= 4.1V, I

=3.35V

3.5V

Load

=0mA

Load

Load

=0mA

=

=4V

=4.3V,I

=5.5V

Power

=5.8V, I

Power

Power-VOut

=3.3V, V

Power=VOut

Power

+2.5V,V

Load

Load

Load

=0mA

Load

=0mA

Load

Control

) <=

Power=VOut

=0V * 1.7 5 mA

ADJ

Power=VOut

+0.8V,

+0.8V,

=2.05V

=1Vp

Ripple

=10mA

=3A

=3A * 0.55 0.70 V

1.230

1.485

*

1.475

2.475

*

2.460

2.821

*

2.805

2.970

*

2.950

3.267

*

3.247

3.465

*

3.445

4.950

*

4.920

1.250

1.500

1.500

2.500

2.500

2.850

2.850

3.000

3.000

3.300

3.300

3.500

3.500

5.000

5.000

* 0.04 0.20 %

* 0.08 0.40 %

*

*510mA

* 50 120 µA

60 75 dB

*

1.00

1.15

1.262

1.270

1.515

1.525

2.525

2.540

2.879

2.895

3.030

3.050

3.333

3.353

3.535

3.555

5.050

5.080

60

1.15

1.30

V

V

V

V

V

V

V

V

mA

V

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

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)

V

LND5203

The* denotes the specifications which apply over the full temperature range.
Note 1: Unless otherwise specified Vout=Vsense. For LND5203 (adj.) Vadj=0V
Note 2: For the adjustable device the minimum load current is the minimum current required to maintain regulation.
Normally the current in the resistor divider used to set the output voltage is selected to meet the minimum load current
requirement.
Note 3: The control pin current is the drive current required for the output transistor. This current will track output with
a ratio of about 1:100.
Note 4: The dropout voltage for the LND5203 is caused by either minimum control voltage or minimum power voltage.
The specifications represent the minimum input/output voltage required to maintain 1% regulation.

PIN FUNCTIONS (5-LEAD

(Pin 5): This pin is the

Sense (Pin 1): This pin is the positive

side of the reference voltage. With this
pin it is possible to Kelvin sense the
output voltage at the load.
Adjust (Pin 2): This pin is the negative
side of the reference voltage. Adding a
small bypass capacitor from the Adjust
pin to ground improves the transient
response. For fixed voltage devices the
Adjust pin is also brought out to allow
the user to add a bypass capacitor.
GND (Pin 2): For fixed voltage devices
this is the bottom of the resistor divider
that sets the output voltage.

power

collector of the power transistor. The
output load current is supplied
through this pin. The voltage at this
pin must be 0.7V greater than the
output voltage for the device to
regulate.

V

(pin 4): This pin is the supply

control

pin for the control circuitry. The
current flow into this pin will be about
1% of the output current. The
voltage at this pin must be 1.3V
greater than the output voltage for
the device to regulate.
Output (Pin 3): This is the power
output of the device.

BLOCK DIAGRAM

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

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APPLICATION INFORMATION

LND5203

The LND5203 series of adjustable and fixed
regulators are designed to power the new
generation of microprocessors. The LND5203 is
designed to make use of multiple power
supplies, present in most systems, to reduce the
dropout voltage. One of the advantages of the
two supply approach is maximizing the
efficiency.
The second supply is at least 1V greater than
output voltage and is providing the power for the
control circuitry and supplies the drive current to
the NPN output transistor. This allows the NPN
output transistor to be driven into saturation. For
the control voltage the current requirement is
small equal to about 1% of the output current.
This drive current becomes part of the output
current. The maximum voltage on the Control
pin is 12V. The maximum voltage at the Power
pin is 7V. By tying the control and power inputs
together the LND5203 can also be operated as
a single supply device. In single supply
operation the dropout will be determined by the
minimum control voltage.
Both fixed and adjustable versions have remote
sense pins, permitting very accurate regulation
of output voltage. As a result, over an output
current range of
100mA to 3A, the typical load regulation are less
than 1mV. For the fixed voltages the adjust pin
is brought out allowing the user to improve
transient response by bypassing the internal
resistor divider. Optimum transient response is
provided using a capacitor in the range of 0.1µF
to 1µF for bypassing the Adjust pin. In addition
to the enhancements mentioned, the reference
accuracy has been improved by a factor of two
with a guaranteed initial tolerance of ±1% at
25ºC and 1.6% accuracy over the full
temperature and load current range.

Typical applications for the LND5203 include

3.3V to 2.5V conversion with a 5V control
supply, 5V to 4.2 V conversion with a 12V
control supply. The device is fully protected
against overcurrent and overtemperature
conditions.

Grounding and Output Sensing

The LND5203 allows true Kelvin sensing for
both the high and low side of the load. As a
result the voltage regulation at the load can
be easily optimized. Voltage drops due to
parasitic resistance’s between the regulator
and the load can be placed inside the
regulation loop. The advantages of remote
sensing are illustrated in figures 1 through 3.
Figure 1 shows the device connected as a
conventional 3 terminal regulator with the
sense lead connected directly to the output of
the device. Rp is the parasitic resistance of
the connections between the device and the
load. Trace A of figure 3 illustrates the effect
of Rp.
Figure 2 shows the device connected to take
advantage of the remote sense feature. The
Sense pin and the top of the resistor divider
are connected to the top of the load. The
bottom of the resistor divider is connected to
the bottom of the load. The effect on output
regulation can be seen in trace B of figure 3.
It is important to note that the voltage drops
due to Rp are not eliminated; they will add to
the dropout voltage of the regulator
regardless. The LND5203 can control the
voltage at the load as long as the input­output voltage is greater than the total of the
dropout voltage of the device plus the voltage
drop across Rp.

Stability

The circuit design used in the LND5203
series requires the use of an output capacitor
as part of the device frequency
compensation. The addition of 150 µF
aluminum electrolytic or a 22 µF solid
tantalum on the output will ensure stability for
all operating conditions

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

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LND5203

Figure 1. Conventional Load Sensing

( Iout ) (Rp)

Vout
Figure 1

Vout
Figure 2

Figure 2. Remote Load Sensing

A

B

Iout

Time

Figure 3. Remote sensing improves Load Regulation

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

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p

LND5203

Output Voltage

The LND5203 (adjustable version)
develops a 1.25V reference voltage
between the Sense pin and the Adjust
pin (Figure 4). Placing a resistor
between these two terminals causes a
constant current to flow through R1
and down though R2 to set the output
voltage. In general R1 is chosen so
that this current is the specified
minimum load current of 5mA. The
current out of the Adjust pin is small,
typically 50 µA and it adds to the
current from R1. For the best
regulation the top of the resistor
divider should be connected directly to
the Sense

in.

Figure 4. Settling Output Voltage

Protection Diodes

In normal operation LND5203 family does
not need any protection diodes between
the adjustment pin and the output to the
input to prevent die overstresses. Internal
resistors are limiting the internal current
paths on the ADJ pin. Therefore even
with bypass capacitors on the adjust pin
no protection diode is needed to ensure
device safety under short-circuit
conditions. The adjust pin can be driver
on a transient basis ±7V with respect to
the output with out any device
degradation. A protection diode between
the Output pin and Vpower pin is not
usually needed. Microsecond surge
currents of 50A to 100A can be handled
by the internal diode between the Output
pin and Vpower pin of the device. In
normal operations it is difficult to get those
values of surge currents even with the
use of large output capacitance. Only
with high value output capacitors, such as
1000µF to 5000µF and the Vpower pin
are instantaneously shorted to ground,
damage can occur. A diode from output
to input is recommended (Figure 5).
If LND5203 is connected as a single
supply device with the control and power
input pins shorted together the internal
diode between the output and the power­input pin will protect the control input pin.

Thermal Considerations

The LND5203 series have internal power
and thermal-limiting circuitry designed to
protect the device under overload
conditions. However, maximum junction
temperature ratings should not be
exceeded under continuous normal load
conditions. Careful consideration must be
given to all sources of thermal resistance
from junction ambient, including junction­to-case, case to-heat sink interface and
heat sink resistance itself.
Junction temperature of the control
section can run up to 125ºC. Junction
temperature of the Power section can run
up to 150ºC.

• Linear Dimensions, Inc. • 445 East Ohio Street, Chicago IL 60611 USA • tel 312.321.1810 • fax 312.321.1830 •

Figure 5. Optional Clamp Diodes Protect Against
Input Crowbar Circuits

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