ngspice/examples/soa/diode-soa-sh.cir

SOA test for generic diode, including self-heating
* forward direction
* ngspice-35

*.temp  200

vtamb tamb 0 27

v1 1 0 0.7
R1 1 0 100 ; just a parallel resistor
D1 1 0 tj dmod thermal
Rtj tj tamb 100 ; the thermal resistance junction to ambient
* diode model parameters include all SOA parameters
.model dmod d (rs=200m bv=21 rth0=1e6 tnom=25 fv_max=1.5 bv_max=20 id_max=1.5 pd_max=1 te_max=175)

.option warn=1 maxwarns=2

.control
save  @d1[id] all
*dc v1 3 -22.5 -0.5
dc v1 0.02 2 0.02
*display
set xbrushwidth=3

* get data from diode model
let pdmax =  @dmod[pd_max]
let idmax = @dmod[id_max]
let vmax = @dmod[fv_max]
let tmax = @dmod[te_max]
let tnom = @dmod[tnom]

let iid = @d1[id]
let ilen = length(iid)
let soa = unitvec(ilen) * idmax
* the current power dissipation in the diode
let pd=@d1[id]*v(1) + 1p ; 1p for log scale, avoid 0

* plot the static SOA diagram
* no self heating
let i = 0
while i < ilen
* power limit
  let pp = soa[i] * v(1)[i]
  if pp > pdmax
    let soa[i] = soa[i] * pdmax / pp
  end
* voltage limit
  if v(1)[i] > vmax
    let soa[i] = 1p
  end
* temperature limit
  let tcur = pp * @Rtj[r] + v(tamb)
  if tcur[i] > tmax
    let soa[i] = 1p
  end  
  let i = i + 1
end

settype current iid soa
plot iid soa loglog ylimit 10m 10 xlimit 0.1 1 title 'Diode SOA (safe operating area, no self-heating)' ylabel 'Diode current' xlabel 'Diode forward voltage'


unlet pdmax
let pdmax = @dmod[pd_max] - (v(tj) - tnom) / @Rtj[r]
let tdio = v(tj)

echo
*echo pdmax $&pdmax 
*echo temp $&tdio 
*echo tnom $&tnom
echo

let plen = length(pdmax)
let i = 0
while i < plen
  if pdmax[i] < 0
    let pdmax[i] = 1p
  end
  let i = i + 1
end

* plot the static SOA diagram
* now with self heating
let i = 0
while i < ilen
* power limit
  let pp = soa[i] * v(1)[i]
  if pp > pdmax[i]
    let soa[i] = soa[i] * pdmax[i] / pp
  end
* voltage limit
  if v(1)[i] > vmax
    let soa[i] = 1p
  end
* temperature limit
  let tcur = pp * @Rtj[r] + v(tamb)
  if tcur[i] > tmax
    let soa[i] = 1p
  end  
  let i = i + 1
end

settype current iid soa
plot iid soa loglog ylimit 10m 10 xlimit 0.1 1  title 'Diode SOA (safe operating area, including self-heating)' ylabel 'Diode current' xlabel 'Diode forward voltage'

*settype power pd pdmax
*plot pd pdmax loglog ylimit 1m 10 xlimit 0.1 1

*settype temperature tj
*plot tj

*plot pd vs tj pdmax vs tj

.endc

.end
New folder with SOA (safe operating area) examples in the ngspice examples section 2021-08-20 11:48:09 +02:00			`SOA test for generic diode, including self-heating`
			`* forward direction`
			`* ngspice-35`

			`*.temp 200`

			`vtamb tamb 0 27`

			`v1 1 0 0.7`
			`R1 1 0 100 ; just a parallel resistor`
			`D1 1 0 tj dmod thermal`
			`Rtj tj tamb 100 ; the thermal resistance junction to ambient`
			`* diode model parameters include all SOA parameters`
			`.model dmod d (rs=200m bv=21 rth0=1e6 tnom=25 fv_max=1.5 bv_max=20 id_max=1.5 pd_max=1 te_max=175)`

			`.option warn=1 maxwarns=2`

			`.control`
			`save @d1[id] all`
			`*dc v1 3 -22.5 -0.5`
			`dc v1 0.02 2 0.02`
			`*display`
			`set xbrushwidth=3`

			`* get data from diode model`
			`let pdmax = @dmod[pd_max]`
			`let idmax = @dmod[id_max]`
			`let vmax = @dmod[fv_max]`
			`let tmax = @dmod[te_max]`
			`let tnom = @dmod[tnom]`

			`let iid = @d1[id]`
			`let ilen = length(iid)`
			`let soa = unitvec(ilen) * idmax`
			`* the current power dissipation in the diode`
			`let pd=@d1[id]*v(1) + 1p ; 1p for log scale, avoid 0`

			`* plot the static SOA diagram`
			`* no self heating`
			`let i = 0`
			`while i < ilen`
			`* power limit`
			`let pp = soa[i] * v(1)[i]`
			`if pp > pdmax`
			`let soa[i] = soa[i] * pdmax / pp`
			`end`
			`* voltage limit`
			`if v(1)[i] > vmax`
			`let soa[i] = 1p`
			`end`
			`* temperature limit`
			`let tcur = pp * @Rtj[r] + v(tamb)`
			`if tcur[i] > tmax`
			`let soa[i] = 1p`
			`end`
			`let i = i + 1`
			`end`

			`settype current iid soa`
			`plot iid soa loglog ylimit 10m 10 xlimit 0.1 1 title 'Diode SOA (safe operating area, no self-heating)' ylabel 'Diode current' xlabel 'Diode forward voltage'`



			`unlet pdmax`
			`let pdmax = @dmod[pd_max] - (v(tj) - tnom) / @Rtj[r]`
			`let tdio = v(tj)`

			`echo`
			`*echo pdmax $&pdmax`
			`*echo temp $&tdio`
			`*echo tnom $&tnom`
			`echo`

			`let plen = length(pdmax)`
			`let i = 0`
			`while i < plen`
			`if pdmax[i] < 0`
			`let pdmax[i] = 1p`
			`end`
			`let i = i + 1`
			`end`

			`* plot the static SOA diagram`
			`* now with self heating`
			`let i = 0`
			`while i < ilen`
			`* power limit`
			`let pp = soa[i] * v(1)[i]`
			`if pp > pdmax[i]`
			`let soa[i] = soa[i] * pdmax[i] / pp`
			`end`
			`* voltage limit`
			`if v(1)[i] > vmax`
			`let soa[i] = 1p`
			`end`
			`* temperature limit`
			`let tcur = pp * @Rtj[r] + v(tamb)`
			`if tcur[i] > tmax`
			`let soa[i] = 1p`
			`end`
			`let i = i + 1`
			`end`

			`settype current iid soa`
			`plot iid soa loglog ylimit 10m 10 xlimit 0.1 1 title 'Diode SOA (safe operating area, including self-heating)' ylabel 'Diode current' xlabel 'Diode forward voltage'`

			`*settype power pd pdmax`
			`*plot pd pdmax loglog ylimit 1m 10 xlimit 0.1 1`

			`*settype temperature tj`
			`*plot tj`

			`*plot pd vs tj pdmax vs tj`

			`.endc`

			`.end`