Continue to Site

Welcome to EDAboard.com

Welcome to our site! EDAboard.com is an international Electronics Discussion Forum focused on EDA software, circuits, schematics, books, theory, papers, asic, pld, 8051, DSP, Network, RF, Analog Design, PCB, Service Manuals... and a whole lot more! To participate you need to register. Registration is free. Click here to register now.

Register Log in

finding the value of CTH

Status
Not open for further replies.
mohamis288

mohamis288

Full Member level 3
Joined
Mar 1, 2022
Messages
164
Helped
0
Reputation
0
Reaction score
1
Trophy points
18
Activity points
1,235
Hi,
I want to do thermal simulation on LDMOS power amplifier. CTH is an important factor in normal condition? I must consider that through thermal simulation or I skip it? its value is not available in datasheet ( even in similar LDMOS power amplifier). so what value for this is rational?
 

Solution
D
This is going to encompass duty cycle / pulsed heating
as thermal time constant and "heat waveform" will
determine an effective volume / mass. It's messy, is
what I came away with last time I tried.

LDMOS has good thermals when "on" because current
and remaining resistance are diffuse. In "saturation"
the heat is all dropped in the much smaller drift region
volume, must then be transported to and past drawn
device extents. Carrier transport across reverse vs
forward biased junctions, vs uniform field free regions
and all that kind of fun.
Sort by date Sort by votes
This is going to encompass duty cycle / pulsed heating
as thermal time constant and "heat waveform" will
determine an effective volume / mass. It's messy, is
what I came away with last time I tried.

LDMOS has good thermals when "on" because current
and remaining resistance are diffuse. In "saturation"
the heat is all dropped in the much smaller drift region
volume, must then be transported to and past drawn
device extents. Carrier transport across reverse vs
forward biased junctions, vs uniform field free regions
and all that kind of fun.
 

Attachments

  • silicon_heat_capacity_ECTP2005paper139.pdf
    390.1 KB · Views: 193
  • 2014-Stout-Linear-Superposition-EC-Webinar_handout.pdf
    1.3 MB · Views: 197
Upvote 1 Downvote
Solution
Consider the thermal stack of the product, to think about
the transient thermal behavior.

You have the core device, inside a die, inside a package,
on a board.

Each "assembly" has a different ultimate heat capacity
(your CTH). The die is simplest; call it all silicon, volume
X*Y*Z, specific heat, there's your gross CTH. You may
also find a thermal time constant formula for this
prismatic material shape, using the dimensions and
constant.

Device inside the die, is a fraction of the volume and
the X-Y extents (see remark about heat concentration
in the drift region, and look at a layout). Thermal time
constant and CTH will be lower (if CTH is framed by
"what is my maximum die temp reached?" against a
time varying load).

Package adds heavy metal heat slug and a better
"DC" thermal path. The time for device to reach
steady state temp has increased, the rate of heat removal
also increases but so does the time for heat to get from
drift region to package baseplate. I'd treat this as a two
part problem as materials are now heterogeneous in
type and size.

It would be comforting if your calculations returned
numbers of the same order, as the steady state and
pulsed power ratings (but then they must also
comprehend the vendor's test setup, heatsink,
airflow, etc. which has now gone beyond any hand
calcs, becoming province of multiphysics or thermal
simulators.
 

Upvote 0 Downvote
Status
Not open for further replies.

Similar threads

Part and Inventory Search

Welcome to EDABoard.com

Sponsor

Back
Top