Pam2808, Application information – Diodes PAM2808 User Manual

PAM2808

Document number: DSxxxxx Rev. 1 - 0

5 of 8

www.diodes.com

October 2012

© Diodes Incorporated

PAM2808

A Product Line of

Diodes Incorporated

Application Information

External Capacitor Requirements

A 4.7μF or larger ceramic input bypass capacitor, connected between V

IN

and GND and located close to the PAM2808, is required for stability. A

4.7µF minimum value capacitor from V

O

to GND is also required. To improve transient response, noise rejection, and ripple rejection, an

additional 10μF or larger, low ESR capacitor is recommended at the output. A higher-value, low ESR output capacitor may be necessary if large,
fast-rise-time load transients are anticipated and the device is located several inches from the power source, especially if the minimum input
voltage of 2.5V is used.

Regulator Protection

The PAM2808 features internal current limiting, thermal protection and short circuit protection. During normal operation, the PAM2808 limits
output current to about 2.5A. When current limiting engages, the output voltage scales back linearly until the over current condition ends. While
current limiting is designed to prevent gross device failure, care should be taken not to exceed the power dissipation ratings of the package. If the
temperature of the device exceeds +150°C, thermal-protection circuitry will shut down. Once the device has cooled down to approximately +40°C
below the high temp trip point, regulator operation resumes.

Thermal Information

The amount of heat generates is:

(

)

I

V

V

P

O

O

IN

D

−

=

All integrated circuits have a maximum allowable junction temperature (T

J

MAX

) above which normal operation is not assured. A system designer

must design the operating environment so that the operating junction temperature (T

J

) does not exceed the maximum junction temperature

(T

J MAX

). The two main environmental variables that a designer can use to improve thermal performance are air flow and external heat sinks. The

purpose o f this information is to aid the designer in determining the proper operating environment for a linear regulator that is operating at a
specific power level.

In general, the maximum expected power (P

D(MAX)

) consumed by a linear regulator is computed as:

(

)

I

x

V

I

x

V

V

P

)

Q

(

)

AVG

(

I

)

AVG

(

O

)

AVG

(

O

)

AVG

(I

DMAX

+

−

=

Where:

V

I(AVG)

is the average input voltage.

V

O(AVG)

is the average output voltage.

I

O(AVG)

is the average output current.

I

(Q)

is the quiescent current.

The quiescent current is insignificant compared to the average output current; therefore, the term V

I(AVG)

x I

(Q)

can be neglected. The operating

junction temperature is computed by adding the ambient temperature (T

A

) and the increase in temperature due to the regulator's power

dissipation. The temperature rise is computed by multiplying the maximum expected power dissipation by the sum of the thermal resistances
between the junction and the case (R

θJC

), the case to heatsink (R

θJS

), and the heatsink to ambient (R

θJA

). Thermal resistances are measures of

how effectively an object dissipates heat. Typically, the larger the device, the more surface area available for power dissipation so that the
object’s thermal resistance will be lower.