Datasheet LT1581-2.5, LT1581 Datasheet (Linear Technology)

FEATURES

■

Low Dropout, 430mV at 10A Output Current

■

Fast Transient Response

■

Remote Sense

■

1mV Load Regulation

■

Fixed 2.5V Output and Adjustable Output

■

No Supply Sequencing Problems in
Dual Supply Mode

LT1581/LT1581-2.5

10A, Very Low

Dropout Regulators

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DESCRIPTION

The LT®1581 is a 10A low dropout regulator designed to
power the new generation of microprocessors. The drop­out voltage of this device is 100mV at light loads rising to
just 430mV at 10A. To achieve this dropout a second low
current input voltage 1V greater than the output voltage is
required. The device can also be used as a single supply
device where dropout is comparable to an LT1584.

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APPLICATIONS

■

Microprocessor Supplies

■

Post Regulators for Switching Supplies

■

High Current Regulators

■

5V to 3.XXV for Pentium® Processors Operating
at 90MHz to 166MHz and Beyond

■

3.3V to 2.9V for Portable Pentium Processor

■

PowerPCTM Series Power Supplies

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TYPICAL APPLICATION

2.5V Microprocessor Supply

3.3V
10A

0.2A

OUTPUT

LT1581-2.5

SENSE

ADJGND

0.1µF

330µF
OS-CON

10µF
TANT

POWER

CONTROL

+

5V

+

2.5V/10A

+

100µF TANT
AVX TPS
× 7

1581 TA01

Several other new features have been added to the LT1581.
A remote SENSE pin is brought out. This feature virtually
eliminates output voltage variations due to load changes.
Typical load regulation for a load current step of 100mA to
10A, measured at the SENSE pin, is less than 1mV.

The LT1581 has fast transient response, equal to the
LT1584. On fixed voltage devices, the ADJUST pin is
brought out. A small capacitor on the ADJUST pin further
improves transient response.

This device is ideal for generating processor supplies of
2V to 3V on motherboards where both 5V and 3.3V
supplies are available.

, LTC and LT are registered trademarks of Linear Technology Corporation.

Pentium is a registered trademark of Intel Corporation.
PowerPC is a trademark of IBM Corporation.

Dropout Voltage –

Minimum Power Voltage

0.8
INDICATES GUARANTEED TEST POINTS

0.7

0.6

) (V)

0.5

0.4

0.3

0.2

0.1

0

0

DATA SHEET LIMIT

3

1

4

2

OUTPUT CURRENT (A)

TJ = 25°C

5

68109

TJ = 125°C

7

1581 G03

OUT

– V

POWER

(V

MINIMUM POWER VOLTAGE (V)

1

LT1581/LT1581-2.5

WW

W

ABSOLUTE MAXIMUM RATINGS

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U

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PACKAGE/ORDER INFORMATION

(Note 1)

V
V
Operating Junction Temperature Range

Storage Temperature ............................ –65°C to 150°C

Lead Temperature (Soldering, 10 sec).................. 300°C

PRECONDITIONING

100% Thermal Limit Functional Test

ELECTRICAL CHARACTERISTICS

Input Voltage ................................................ 6V

POWER
CONTROL

Input Voltage ........................................... 13V

Control Section...................................... 0°C to 125°C

Power Transistor ...................................0°C to 150°C

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The ● denotes specifications which apply over the full operating

FRONT VIEW

7
6
5
4
3
2
1

TAB IS

OUTPUT

*PIN2 = NC FOR LT1581CT7, GND FOR LT1581CT7-2.5

T7 PACKAGE

7-LEAD PLASTIC TO-220

θJA = 50°C/ W

NC
V

CONTROL



V

POWER

OUTPUT
SENSE
NC/GND*
ADJUST

ORDER PART



LT1581CT7
LT1581CT7-2.5

Consult factory for Industrial and Military grade parts.

NUMBER

temperature range, otherwise specifications are at TA = 25°C. (Note 2)

PARAMETER CONDITIONS MIN TYP MAX UNITS

Output Voltage: LT1581-2.5 V

Reference Voltage: LT1581 V

= 0V) V

(V

ADJ

Line Regulation: LT1581-2.5 V

LT1581 V

Load Regulation: LT1581-2.5 V

LT1581 (V

= 0V) V

ADJ

Minimum Load Current: LT1581 V
Control Pin Current: LT1581-2.5 V

(Note 5) V

Control Pin Current: LT1581 V
(Note 5) V

Ground Pin Current: LT1581-2.5 V
Adjust Pin Current: LT1581 (V

= 0V) V

ADJ

Current Limit: LT1581-2.5 V

LT1581 (V

= 0V) V

ADJ

Ripple Rejection: LT1581-2.5 V

LT1581 V

V
V

V

V
V

V
V

I

V

= 5V, V

CONTROL

= 4V to 12V, V

CONTROL

= 4V to 12V, V

CONTROL

= 2.75V, V

CONTROL

= 2.7V to 12V, V

CONTROL

= 2.7V to 12V, V

CONTROL

= 3.65V to 12V, V

CONTROL

= 2.5V to 12V, V

CONTROL

= 5V, V

CONTROL

= 2.75V, V

CONTROL

= 5V, V

CONTROL

= 5V, V

CONTROL

= 5V, V

CONTROL

= 5V, V

CONTROL

= 5V, V

CONTROL

= 2.75V, V

CONTROL

= 2.75V, V

CONTROL

= 2.75V, V

CONTROL

= 2.75V, V

CONTROL

= 5V, V

CONTROL

= 2.75V, V

CONTROL

= 5V, V

CONTROL

= 2.75V, V

CONTROL

= V

CONTROL

= 4A, TJ = 25°C

OUT

= V

CONTROL

= 0V, I

ADJ

POWER

POWER

OUT

Thermal Regulation 30ms Pulse 0.004 0.020 %/W
Thermal Resistance, Junction-to-Case Control Circuitry/Power Transistor 0.65/2.50 °C/W

= 3.3V, I

POWER

POWER
POWER

= 2V, I

POWER

POWER
POWER

POWER

POWER

= 3.3V, I

POWER

POWER

POWER
POWER
POWER
POWER

POWER

POWER

POWER

= 3.3V, V
= 3.3V, I

= 3.3V, I
= 3.3V, I
= 3.3V, I

POWER
POWER
POWER
POWER

= 3.3V, I

POWER

= 3.3V, ∆V

POWER

= 2.1V, I

= 2.05V, I
= 2.05V, I
= 2.05V, I
= 2.05V, I

= 2.05V, I

= 2.05V, ∆V

= 5V Avg, V

= 3.75V Avg, V

= 4A, TJ = 25°C

= 0mA 2.485 2.500 2.515 V

LOAD

= 3V to 5.5V, I
= 3.3V to 5.5V, I

= 10mA 1.243 1.250 1.257 V

LOAD

= 1.75V to 5.5V, I
= 2.05V to 5.5V, I

= 3V to 5.5V, I

= 1.75V to 5.5V, I

= 0mA to 10A ● 110 mV

LOAD

= 10mA to 10A ● 15 mV

LOAD

= 0V (Note 4) ● 310 mA

ADJ

= 100mA ● 510 mA

LOAD

= 4A ● 20 50 mA

LOAD

= 7A ● 40 100 mA

LOAD

= 10A ● 70 170 mA

LOAD

LOAD
LOAD
LOAD

LOAD

= 0mA ● 610 mA

LOAD

LOAD

= 100mV ● 10.1 11 A

OUT

OUT

= 1V

RIPPLE

= 1V

RIPPLE

= 0mA to 4A ● 2.475 2.500 2.525 V

LOAD

= 0mA to 10A ● 2.475 2.500 2.525 V

LOAD

= 0mA to 4A ● 1.237 1.250 1.263 V

LOAD

= 0mA to 10A ● 1.237 1.250 1.263 V

LOAD

= 10mA ● 13 mV

LOAD

= 10mA ● 13 mV

LOAD

= 100mA ● 510 mA
= 4A ● 20 50 mA
= 7A ● 40 100 mA
= 10A ● 70 170 mA

= 10mA ● 60 120 µA

= 100mV ● 10.1 11 A

, f

P-P

= 120Hz, 55 80 dB

RIPPLE

, f

P-P

= 120Hz, 60 80 dB

RIPPLE

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2

LT1581/LT1581-2.5

ELECTRICAL CHARACTERISTICS

The ● denotes specifications which apply over the full operating

temperature range, otherwise specifications are at TA = 25°C. (Note 2)

PARAMETER CONDITIONS MIN TYP MAX UNITS
Dropout Voltage (Note 3)

Minimum V

CONTROL

– V

(V

Minimum V
(V
(V

– V

CONTROL

= 0V) V

ADJ

Minimum V

– V

(V

POWER

Minimum V
(V

– V

POWER

= 0V) V

(V

ADJ

: LT1581-2.5 V

CONTROL

)V

OUT

: LT1581 V

CONTROL

)V

OUT

: LT1581-2.5 V

POWER

)V

OUT

: LT1581 V

POWER

)V

OUT

POWER
POWER

V

POWER

V

POWER

V

POWER
POWER

POWER
POWER

V

POWER

V

POWER
CONTROL

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

CONTROL
CONTROL
CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

V

CONTROL

= 3.3V, I
= 3.3V, I
= 3.3V, I
= 3.3V, I
= 3.3V, I

= 2.05V, I
= 2.05V, I
= 2.05V, I
= 2.05V, I
= 2.05V, I

= 5V, I
= 5V, I
= 5V, I
= 5V, I
= 5V, I
= 5V, I
= 5V, I
= 5V, I

= 2.75V, I
= 2.75V, I
= 2.75V, I
= 2.75V, I
= 2.75V, I
= 2.75V, I
= 2.75V, I
= 2.75V, I

LOAD
LOAD
LOAD
LOAD
LOAD

LOAD
LOAD
LOAD
LOAD
LOAD
LOAD
LOAD
LOAD

= 100mA ● 1.02 1.25 V
= 1A ● 1.04 1.27 V
= 4A ● 1.06 1.30 V
= 7A ● 1.10 1.33 V
= 10A ● 1.12 1.35 V

= 100mA ● 1.02 1.25 V

LOAD

= 1A ● 1.04 1.27 V

LOAD

= 4A ● 1.06 1.30 V

LOAD

= 7A ● 1.10 1.33 V

LOAD

= 10A ● 1.12 1.35 V

LOAD

= 100mA ● 0.10 0.20 V
= 1A ● 0.13 0.25 V
= 4A, TJ = 25°C 0.22 0.33 V
= 4A ● 0.37 V
= 7A, TJ = 25°C 0.31 0.45 V
= 7A ● 0.55 V
= 10A, TJ = 25°C 0.43 0.63 V
= 10A ● 0.70 V

= 100mA ● 0.10 0.20 V

LOAD

= 1A ● 0.13 0.25 V

LOAD

= 4A, TJ = 25°C 0.22 0.33 V

LOAD

= 4A ● 0.37 V

LOAD

= 7A, TJ = 25°C 0.31 0.45 V

LOAD

= 7A ● 0.55 V

LOAD

= 10A, TJ = 25°C 0.43 0.63 V

LOAD

= 10A ● 0.70 V

LOAD

Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.

Note 2: Unless otherwise specified, V
adjustable device, V

ADJ

= 0V.

OUT

= V

. For the LT1581

SENSE

Note 3: For the LT1581, dropout is caused by either minimum control
voltage (V

) or minimum power voltage (V

CONTROL

). Both parameters

POWER

are specified with respect to the output voltage. The specifications represent
the minimum input-to-output voltage required to maintain 1% regulation.

Note 4: For the LT1581 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 5: The CONTROL pin current is the drive current required for the
output transistor. This current will track output current with roughly a
1:100 ratio. The minimum value is equal to the quiescent current of the
device.

3

LT1581/LT1581-2.5

OUTPUT CURRENT (A)

MINIMUM POWER VOLTAGE (V)

(V

POWER

– V

OUT

) (V)

0.8

0.7

0.6

0.5

0.4

0.3

0.2

0.1

0

1581 G03

0

1

5

7

4

2

3

68109

DATA SHEET LIMIT

TJ = 25°C

TJ = 125°C

INDICATES GUARANTEED TEST POINTS

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TYPICAL PERFORMANCE CHARACTERISTICS

Control Pin Current vs
Output Current



200

INDICATES GUARANTEED TEST POINTS

180
160
140
120



100

80
60
40

CONTROL PIN CURRENT (mA)

20

0

0

DATA SHEET LIMIT

35

12

OUTPUT CURRENT (A)

467

LT1581 Reference Voltage vs
Temperature

1.262

1.259

1.256

1.253

1.250

1.247

REFERENCE VOLTAGE (V)

1.244

1.241

1.238
–50 –25

0 25 75 125

TEMPERATURE (°C)

TYPICAL

DEVICE



910

8

1581 G01

Dropout Voltage —
Minimum Control Voltage

2

INDICATES GUARANTEED TEST POINTS





) (V)

OUT



– V

1



CONTROL



(V

MINIMUM CONTROL VOLTAGE



0

0

DATA SHEET LIMIT

3

1

2

OUTPUT CURRENT (A)

4

TJ = 25°CTJ = 125°C

5

68109

7

1581 G02

Dropout Voltage —
Minimum Power Voltage

LT1581-2.5 Output Voltage vs
Temperature

2.512

2.509

2.506

2.503

2.500

2.497

OUTPUT VOLTAGE (V)

2.494

2.491

2.488

50

100

150

1581 G04

–50 –25

0 25 75 125

50

TEMPERATURE (°C)

100

1581 G05

50mV/DIV

LOAD

150

Load Current Step Response

V

OUT

10A

400mA

50µs/DIV 1581 G06

PIN FUNCTIONS

ADJUST (Pin 1): This pin is the negative side of the
reference voltage for the device. Transient response can
be improved by adding a small bypass capacitor from the
ADJUST pin to ground. For fixed voltage devices the
ADJUST pin is also brought out to allow the user to add a
bypass capacitor.

GND (Pin 2, Fixed Voltage Devices Only): For fixed
voltage devices this is the bottom of the resistor divider
that sets the output voltage.

SENSE (Pin 3): This pin is the positive side of the reference
voltage for the device. With this pin it is possible to Kelvin
sense the output voltage at the load.

4

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OUTPUT (Pin 4): This is the power output of the device.
V

(Pin 5): This is the collector to the power device

POWER

of the LT1581. The output load current is supplied through
this pin. For the device to regulate, the voltage at this pin
must be between 0.1V and 0.7V greater than the output
voltage (see Dropout specifications).

V

CONTROL

(Pin 6): This pin is the supply pin for the control

circuitry of the device. The current flow into this pin will
be about 1% of the output current. For the device to
regulate, the voltage at this pin must be between 1.0V and

1.35V greater than the output voltage (see Dropout
specifications).

BLOCK DIAGRA

ADJ

W

CONTROL

SENSE

FOR FIXED
VOLTAGE
DEVICE


LT1581/LT1581-2.5

POWER

+

–

OUTPUT

1581 BD

GND

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APPLICATIONS INFORMATION

The LT1581 is a low dropout regulator designed to power
the new generation of microprocessors. Low dropout
regulators have become more common in desktop com­puter systems as microprocessor manufacturers have
moved away from 5V only CPUs. A wide range of supply
requirements exists today with new voltages just over the
horizon. In many cases the input/output differential is very
small, effectively disqualifying many of the low dropout
regulators on the market today. The LT1581 is designed to
make use of multiple power supplies present in most
systems to reduce the dropout voltage. This 2-supply
approach maximizes efficiency.

The second supply, at least 1V greater than the output
voltage, is used to provide power for the control circuitry
and supply the drive current to the NPN output transistor.
This allows the NPN to be driven into saturation, thereby
reducing the dropout voltage by a VBE compared to
conventional designs. The current requirement for the

control voltage is relatively small, equal to approximately
1% of the output current or about 100mA for a 10A load.
The bulk of this current is drive current for the NPN output
transistor. This drive current becomes part of the output
current.

The control voltage must be at least 1V greater than the
output voltage to obtain optimum performance. The maxi­mum voltage on the V
voltage at the V

pin is limited to 7V. GND pin current

POWER

CONTROL

pin is 13V. The maximum

for fixed voltage devices is 6mA (typ) and is constant as a
function of load. ADJUST pin current for adjustable de­vices is 60µ A at 25°C and varies proportional to absolute
temperature.

The LT1581 has improved frequency compensation which
permits the use of capacitors with very low ESR. This is
critical in addressing the needs of modern, low voltage,
high speed microprocessors. Current generation micro-

5

LT1581/LT1581-2.5

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APPLICATIONS INFORMATION

processors cycle load current from several hundred mil­liamperes to several amperes in tens of nanoseconds.
Output voltage tolerances are tighter and include transient
response as part of the specification. The LT1581 is
designed to meet the fast current load step requirements
of these microprocessors and saves total cost by needing
less output capacitance to maintain regulation.

Careful design has eliminated any supply sequencing
issues associated with a dual supply system. The output
voltage will not turn on until both supplies are operating.
If the control voltage comes up first, the output current will
be limited to a few milliamperes until the power input
voltage comes up. If the power input comes up first the
output will not turn on at all until the control voltage comes
up. The output can never come up unregulated. The
LT1581 can also be operated as a single supply device by
tying the control and power inputs together. Dropout in
single supply operation will be determined by the mini­mum control voltage.

The LT1581 includes several innovative features that
require additional pins over the traditional 3-terminal
regulator. Both the fixed and adjustable devices have
remote sense pins, permitting very accurate regulation of
output voltage at the load, where it counts, rather than at
the regulator. As a result the typical load regulation over
an output current range of 100mA to 10A with a 2.5V
output is typically less than 1mV. For the fixed voltage
devices the ADJUST pin is also brought out. This allows
the user to improve transient response by bypassing the
internal resistor divider. In the past, fixed output voltage
devices did not provide this capability. Bypassing the
ADJUST pin with a capacitor in the range of 0.1µF to 1µF
will provide optimum transient response. The value cho­sen will depend on the amount of output capacitance in the
system.

In addition to the enhancements mentioned above, the
reference accuracy has been improved by a factor of two
with a guaranteed initial tolerance of ±0.6% at 25°C.
Temperature drift is also very well controlled. When com­bined with ratiometrically accurate internal divider resis­tors the part can easily hold 1% output accuracy over the
full temperature range and load current range, guaran-

teed, while operating with an input/output differential of
well under 1V.

Typical applications for the LT1581 include 3.3V to 2.5V
conversion with a 5V control supply, 5V to 4.2V conver­sion with a 12V control supply or 5V to 3.6V conversion
with a 12V control supply. It is easy to obtain dropout
voltages of less than 0.4V at 4A along with excellent static
and dynamic specifications. The LT1581 is capable of 10A
of output current with a maximum dropout of 0.7V. The
LT1581 has fast transient response that allows it to handle
the large current changes associated with today’s micro­processors. The device is fully protected against overcurrent
and overtemperature conditions. Both fixed voltage (2.5V)
and adjustable output versions are available. The device is
available in a 7-lead TO-220 package.

Grounding and Output Sensing

The LT1581 allows true Kelvin sensing for both the high
and low side of the load. This means that the voltage
regulation at the load can be easily optimized. Voltage
drops due to parasitic resistances between the regulator
and the load which would normally degrade regulation can
be placed inside the regulation loop of the LT1581. Figures
1 through 3 illustrate the advantages of remote sensing.
Figure 1 shows the LT1581 connected as a conventional
3-terminal regulator with the SENSE lead connected di­rectly to the output of the device. RP represents the
parasitic resistance of the connections between the LT1581
and the load. The load is typically a microprocessor and
RP is made up of the PC traces and/or connector resis­tances, in the case of a modular regulator, between the
regulator and the processor. The effect of RP can be seen
in trace A of Figure 3. Very small resistances cause
significant load regulation steps. For example, at 10A
output current the output voltage will shift by 10mV for
every 0.001Ω of resistance. In Figure 2 the LT1581 is
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. RP is now
effectively connected inside the regulating loop of the
LT1581 and the load regulation at the load will be negli­gible for reasonable values of RP. Trace B of Figure 3

6

LT1581/LT1581-2.5

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APPLICATIONS INFORMATION

5V

3.3V

3.3V

CONTROL

POWER

Figure 1. Conventional Load Sensing

CONTROL

POWER

LT1581

ADJ

5V

LT1581

R2

SENSE

OUTPUT

R1

SENSE

R

P

LOAD

R

P

+

V

OUT

–

1581 F01

LT1581 can control the voltage at the load as long as the
input/output voltage is greater than the total of the dropout
voltage of the LT1581 plus the voltage drop across RP.

Stability

The LT1581 requires the use of an output capacitor as part
of the device frequency compensation. The device re­quires a minimum of 22µ F tantalum or 150µF of aluminum
electrolytic to ensure stability. Larger capacitor values
increase stability and improve transient performance.

Many different types of capacitors are available and have
widely varying characteristics. These capacitors differ in
capacitor tolerance (sometimes up to ±100%), equivalent
series resistance, equivalent series inductance and ca­pacitance temperature coefficient. The LT1581 frequency
compensation optimizes frequency response with low
ESR capacitors. In general, use capacitors with an ESR of
less than 1Ω.

LOAD

+

V

OUT

–

1581 F02

ADJ

R2

OUTPUT

R1

R

P

R

P

Figure 2. Remote Load Sensing

)(RP)

(∆I

OUT

V



OUT

FIGURE 1

V



OUT

FIGURE 2

I

OUT

TIME

1581 F03

Figure 3. Remote Sensing Improves Load Regulation

illustrates the effect on output regulation. 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 of whether they are inside the loop as in Figure
2 or outside the loop as in Figure 1. This means that the

For microprocessor applications larger value capacitors
will be needed to meet the transient requirements of the
processor. Processor manufacturers require tight voltage
tolerances on the power supply. High quality bypass
capacitors must be used to limit the high frequency noise
generated by the processor. Multiple small ceramic ca­pacitors in addition to high quality bulk tantalum capaci­tors are typically required to limit parasitic inductance
(ESL) and resistance (ESR) in the capacitors to acceptable
levels. The LT1581 is stable with the type of capacitors
recommended by processor manufacturers.

Bypassing the adjust terminal on the LT1581 improves
ripple rejection and transient response. The ADJUST pin is
brought out on the fixed voltage device specifically to
allow this capability.

Capacitor values on the order of several hundred microfar­ads are used to ensure good transient response with heavy
load current changes. Output capacitance can increase
without limit and larger values of output capacitance
further improve the stability and transient response of the
LT1581.

Modern microprocessors generate large high frequency
current transients. The load current step contains higher
order frequency components that the output coupling

7

LT1581/LT1581-2.5

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APPLICATIONS INFORMATION

network must handle until the regulator throttles to the
load current level. Capacitors are not ideal elements and
contain parasitic resistance and inductance. These para­sitic elements dominate the change in output voltage at
the beginning of a transient load step change. The ESR of
the output capacitors produces an instantaneous step in
output voltage (∆V = ∆I)(ESR). The ESL of the output
capacitors produces a droop proportional to the rate of
change of the output current (V = L)(∆I/∆t). The output
capacitance produces a change in output voltage
proportional to the time until the regulator can respond
(∆V = ∆t)(∆I/C). These transient effects are illustrated in
Figure 4 .

ESR
EFFECTS

ESL
EFFECTS

SLOPE, =

V

∆I

t

C

POINT AT WHICH REGULATOR

TAKES CONTROL

Figure 4

CAPACITANCE
EFFECTS

1581 F04

V

CONTROL

+

CONTROL

V

POWER

V

OUT

= V

POWER

+

I

R2

1 + + I

REF

(

(R2)

ADJ

)

R1

Figure 5. Setting Output Voltage

LT1581

ADJ

ADJ

OUTPUT

SENSE

= 60µA

V

R1

REF

R2

V

+

OUT

1581 F05

minimum load current of 10mA. The current out of the
ADJUST pin adds to the current from R1. The ADJUST pin
current is small, typically 60µ A. The output voltage contri­bution of the ADJUST pin current is small and only needs
to be considered when very precise output voltage setting
is required. Note that the top of the resistor divider should
be connected directly to the SENSE pin for best regulation.
See the section on grounding and Kelvin sensing above.

The use of capacitors with low ESR, low ESL and good
high frequency characteristics is critical in meeting the
output voltage tolerances of these high speed micropro­cessors. These requirements dictate a combination of
high quality, surface mount, tantalum and ceramic capaci­tors. The location of the decoupling network is critical to
transient performance. Place the decoupling network as
close to the processor pins as possible because trace runs
from the decoupling capacitors to the processor pins are
inductive. The ideal location for the decoupling network is
actually inside the microprocessor socket cavity. In addi­tion, use large power and ground plane areas to minimize
distribution drops.

Output Voltage

The adjustable version of the LT1581 develops a 1.25V
reference voltage between the SENSE pin and the ADJUST
pin (see Figure 5). Placing a resistor R1 between these two
terminals causes a constant current to flow through R1
and down through R2 to set the overall output voltage.
Normally, R1 is chosen so that this current is the specified

Protection Diodes

In normal operation the LT1581 does not require protec­tion diodes. Older 3-terminal regulators require protection
diodes between the OUTPUT pin and the INPUT pin or
between the ADJUST pin and the OUTPUT pin to prevent
die overstress.

On the LT1581, internal resistors limit internal current
paths on the ADJUST 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 driven on a transient
basis ± 7V with respect to the output without any device
degradation.

A protection diode between the OUTPUT pin and the
V
between the OUTPUT pin and the V

pin is usually not needed. An internal diode

POWER

POWER

pin on the
LT1581 can handle microsecond surge currents of 50A to
100A. Even with large value output capacitors it is difficult
to obtain those values of surge currents in normal opera­tion. Only with large values of output capacitance, such as

8

LT1581/LT1581-2.5

U

WUU

APPLICATIONS INFORMATION

1000µF to 5000µF, and with the V
neously shorted to ground can damage occur. A crowbar
circuit at the power input can generate those levels of
current and a diode from output to power input is then
recommended. This is shown in Figure 6. Normal power
supply cycling or system “hot-plugging and unplugging”
will not do any damage.

A protection diode between the OUTPUT pin and the
V

CONTROL

pin is usually not needed. An internal diode
between the OUTPUT pin and the V
LT1581 can handle microsecond surge currents of 1A to
10A. This can only occur if the V

CONTROL

neously shorted to ground with a crowbar circuit with
large value output capacitors. Since the V
usually a low current supply, this condition is unlikely. A
protection diode from the OUTPUT pin to the V
is recommended if the V

CONTROL

pin can be instanta­neously shorted to ground. This is shown in Figure 6.
Normal power supply cycling or system “hot-plugging
and unplugging” will not do any damage.

V

CONTROL

+

CONTROL

V

POWER

+

*OPTIONAL DIODES: 1N4002

Figure 6. Optional Clamp Diodes Protect Against
Input Crowbar Circuits

POWER

OUTPUT

LT1581

SENSE

ADJ

If the LT1581 is connected as a single supply device with
the control and power input pins shorted together, the
internal diode between the output and the power input pins
will protect the control input pin.

Like any other regulator exceeding the maximum input-to­output differential can cause the internal transistors to
break down and none of the internal protection circuitry is
then functional.

pin instanta-

POWER

CONTROL

pin is instanta-

CONTROL

D1*

pin on the

pin is

CONTROL

D2*

R1

R2

pin

V

+

OUT

1581 F06

Thermal Considerations

The LT1581 has internal current and thermal limiting
designed to protect the device under overload conditions.
For continuous normal load conditions maximum junction
temperature ratings must not be exceeded. It is important
to give careful consideration to all sources of thermal
resistance from junction to ambient. This includes junc­tion-to-case, case-to-heat sink interface and heat sink
resistance itself. Thermal resistance specifications are
given in the electrical characteristics for both the Control
section and the Power section of the device. The thermal
resistance of the Control section is given as 0.65°C/W and
junction temperature of the Control section is allowed to
run at up to 125°C. The thermal resistance of the Power
section is given as 2.5°C/W and the junction temperature
of the Power section is allowed to run at up to 150°C. The
difference in thermal resistances between Control and
Power sections is due to thermal gradients between the
power transistor and the control circuitry.

Virtually all of the power dissipated by the device is
dissipated in the power transistor. The temperature rise in
the power transistor will be greater than the temperature
rise in the Control section so the effective thermal resis­tance, temperature rise per watt dissipated, will be lower
in the Control section. At power levels below 12W the
temperature gradient will be less than 25°C and the
maximum ambient temperature will be determined by the
junction temperature of the Control section. This is due to
the lower maximum junction temperature in the Control
section. At power levels greater than 12W the temperature
gradient will be greater than 25°C and the maximum
ambient temperature will be determined by the Power
section. For both cases the junction temperature is deter­mined by the total power dissipated in the device. For most
low dropout applications the power dissipation will be less
than 12W.

The power in the device is made up of two main compo­nents: the power in the output transistor and the power in
the drive circuit. The additional power in the control circuit
is negligible.

The power in the drive circuit will be equal to:

P

DRIVE

= (V

CONTROL

– V

OUT

)(I

CONTROL

)

9

LT1581/LT1581-2.5

U

WUU

APPLICATIONS INFORMATION

where I
I

OUT

I

CONTROL

I

CONTROL

CONTROL

/58 (max).

is a function of output current. A curve of
vs I

Characteristics curves.
The power in the output transistor is equal to:

P

OUTPUT

The total power is equal to:

P

TOTAL

Junction-to-case thermal resistance is specified from the
IC junction to the bottom of the case directly below the die.
This is the lowest resistance path for heat flow. Proper
mounting is required to ensure the best possible thermal
flow from this area of the package to the heat sink. Thermal
compound at the case-to-heat sink interface is strongly
recommended. If the case of the device must be electroni­cally isolated, a thermally conductive spacer can be used
as long as the added contribution to thermal resistance is
considered. Please consult Linear Technology’s “Mount­ing Considerations for Power Semiconductors,”

Linear Applications Handbook, Volume 1

RR3-20. Note that the case of the LT1581 is electrically
connected to the output.

The following example illustrates how to calculate
maximum junction temperature. Using an LT1581 and
assuming:

is equal to between I

can be found in the Typical Performance

OUT

= (V

= P

DRIVE

POWER

+ P

– V

OUTPUT

OUT

)(I

OUT

/100 (typ) and

OUT

)

, Pages RR3-1 to

1990

Power dissipation under these conditions is equal to:

Total Power Dissipation = P
P

= (V

DRIVE

I

CONTROL

P

DRIVE

P

OUTPUT

CONTROL

= I

OUT

= (5.25V – 2.5V)(69mA) = 190mW

= (V

– V

OUT

/58 = 4A/58 = 69mA

– V

POWER

OUT

DRIVE

) (I

CONTROL

)(I

OUT

+ P

)

OUTPUT

)

= ( 3.465V – 2.5V)(4A) = 3.9W

Total Power Dissipation = 4.09W

Junction temperature will be equal to:

TJ = TA + P

TOTAL

(θ

HEATSINK

+ θ

CASE-HEATSINK

+ θJC)

For the Control section:

TJ = 70°C + 4.09W(4°C/W + 1°C/W + 0.65°C/ W) = 93°C
93°C < 125°C = T

for Control Section

JMAX

For the Power section:

TJ = 70 °C + 4.09W (4°C/W + 1°C/W + 2.5°C/ W) = 101°C
101°C < 150°C = T

for Power Section

JMAX

In both cases the junction temperature is below the
maximum rating for the respective sections, ensuring
reliable operation.

V

CONTROL

V

POWER

V

OUT

TA = 70°C, θ

θ

CASE-HEATSINK

(max continuous) = 5.25V (5V + 5%),

(max continuous) = 3.465V (3.3V + 5%),

= 2.5V, Iout = 4A,

HEATSINK

10

= 4°C/W,

= 1°C/W (with thermal compound)

U

TYPICAL APPLICATION

5V

3.3V

+

C3

22µF

25V

RTN

PACKAGE DESCRIPTION

LT1581/LT1581-2.5

2.5V/10A Regulator

5

V

POWER

LT1581

ADJ

+

C2
220µF
10V

0.33µF

C4

1

R2
110Ω
1%

V

CONT

SENSE

V

OUT

110Ω

1%

R1

100µF

10V

6
3

= 2.5V

V

4

OUT

V

CC

+

100µF

10V

C1

+

× 2

1µF
25V
× 10

V

SS

U

Dimensions in inches (millimeters) unless otherwise noted.

MICROPROCESSOR
SOCKET

1581 TA03

0.390 – 0.415

(9.906 – 10.541)

0.460 – 0.500

(11.684 – 12.700)

0.040 – 0.060

(1.016 – 1.524)

T7 Package

7-Lead Plastic TO-220 (Standard)

(LTC DWG # 05-08-1422)

0.147 – 0.155

(3.734 – 3.937)

DIA

0.230 – 0.270

(5.842 – 6.858)

0.570 – 0.620

(14.478 – 15.748)

0.330 – 0.370

(8.382 – 9.398)

0.260 – 0.320

(6.604 – 8.128)

0.026 – 0.036

(0.660 – 0.914)

(3.860 – 5.130)



0.700 – 0.728

(17.780 – 18.491)

0.152 – 0.202



0.135 – 0.165

(3.429 – 4.191)

0.165 – 0.180

(4.191 – 4.572)

0.620

(15.75)

TYP



0.045 – 0.055

(1.143 – 1.397)



0.095 – 0.115 

(2.413 – 2.921)

0.013 – 0.023

(0.330 – 0.584)

0.155 – 0.195

(3.937 – 4.953)

T7 (TO-220) (FORMED) 1197

Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no represen­tation that the interconnection of its circuits as described herein will not infringe on existing patent rights.

11

LT1581/LT1581-2.5

TYPICAL APPLICATION

Dual Regulators Power Pentium Processor or Upgrade CPU

R12

0.0075Ω*

5V

R1
10k

R10

10k

U

+

LT1006

–

12V

C6

0.01µF

C8

0.1µF

+

D1

1N4148

C1
220µF
10V

1N4148

R2

470Ω

D2

V

INVOUT

LT1587

ADJ

R4
178Ω
1%

R3
110Ω
1%

C4

0.33µF

I/O
SUPPLY

C3

+

5V

R11
10k

220µF
10V

3.5V/3.3V

0.35%

Q1

E3

0
1

R8

107Ω

CPU TYPE

P55C
P54C

R14, 2Ω

C10
1µF

5V

R5
10k

2N3904

CORE

C7

+

330µF

6.3V

Q3

R9

2N7002

10k

Q2

SUPPLY

3.5V/2.5V

E3
TO CPU
VOLTAGE
SELECT PIN

1581 TA04

12V

C11

R13

0.005Ω*

C9

+

220µF
10V

*RESISTORS ARE IMPLEMENTED AS COPPER TRACES ON PCB 
IF 1 OZ COPPER, TRACE WIDTHS ARE 0.05 INCH
IF 2 OZ COPPER, TRACE WIDTHS ARE 0.025 INCH
R13 IS 0.83 INCHES LONG, R12 IS 1.24 INCHES LONG

22µF

35V

+

C2
220µF
10V

6

+

5

C5

0.33µF

V

CONT

V

POWER

89.8Ω

0.5%

LT1581

ADJ

R6

SENSE

V

OUT

1

R7
107Ω

0.25%

3

4

ZVN4206

RELATED PARTS

PART NUMBER DESCRIPTION COMMENTS

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LTC1435 High Current Synchronous Step-Down Controller >90% Efficiency in 12V to 3.3V Applications
LT1575/LT1577 Single and Dual Low Dropout Regulator Controllers Fast Transient Response, No Bulk Capacitors Needed
LT1580 7A Fast Transient Response Regulator with 0.7V Dropout For 3.3V to 2.XXV Applications
LT1584 7A Low Dropout Fast Transient Response Regulator For High Performance Microprocessors
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12

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507

●

www.linear-tech.com

158125fa LT/TP 0399 2K REV A • PRINTED IN USA

 LINEAR TECHNOLOGY CORPORATION 1996