Intel CELERON 200 User Manual

Thermal Metrology

28

Thermal and Mechanical Design Guidelines

For reference thermal solution of Intel Celeron processor 200 sequence on Intel

Desktop Board D201GLY2, the junction-to-local ambient thermal characterization

parameter of the processor, Ψ

JA

, is comprised of Ψ

JS

, the thermal interface material

thermal characterization parameter, Ψ

HS_BASE

the thermal characterization parameter

of the heatsink base from bottom center of heatsink base to top center of heatsink

base surface, and of Ψ

S-TOP-A

, the sink-to-local ambient thermal characterization

parameter:

Equation 3

Ψ

JA

=

Ψ

JS

+

Ψ

HS_BASE

+

Ψ

S-TOP-A

Where:

Ψ

JS

= Thermal characterization parameter of the thermal interface material

(°C/W)

Ψ

HS_BASE

= Thermal characterization parameter of the heatsink base (°C/W)

Ψ

S-TOP-A

= Thermal characterization parameter from heatsink top to local

ambient (°C/W)

Ψ

JS

is strongly dependent on the thermal conductivity, thickness and performance

degradation across time of the TIM between the heatsink and processor die.

Ψ

HS_BASE

is a measure of the thermal characterization parameter of the heatsink base.

It is dependent on the heatsink base material, thermal conductivity, thickness and

geometry.

Ψ

S-TOP-A

is a measure of the thermal characterization parameter from the top center

point of the heatsink base to the local ambient air. Ψ

S-TOP-A

is dependent on the

heatsink material, thermal conductivity, and geometry. It is also strongly dependent

on the air flow through the fins of the heatsink.

Equation 4 (

Ψ

JA

− Ψ

JS

− Ψ

HS_BASE

)

× P

D

+ T

A

= T

S-TOP-MAX

With a given processor junction-to-local ambient requirement (Ψ

JA

) and TIM

performance (Ψ

JS

) and processor power consumption (P

D

), the processor’s heatsink

requirement (T

S-TOP-MAX

)

could be defined by Equation 4.