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update vdmos examples to the new model interface

pre-master-46
dwarning 6 years ago
committed by Holger Vogt
parent
0362d63094
commit
d244b1c008
19 changed files with 392 additions and 86 deletions
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  1. 115
      examples/vdmos/100W.sp
  2. 92
      examples/vdmos/100W_wingspread.sp
  3. 2
      examples/vdmos/IXTH80N20L-IXTH48P20P-quasisat.sp
  4. 0
      examples/vdmos/IXTP6N100D2-cap.sp
  5. 0
      examples/vdmos/IXTP6N100D2-n-weak-inv.sp
  6. 25
      examples/vdmos/VDMOS-DIO-AC.cir
  7. 14
      examples/vdmos/VDMOS-DIO.sp
  8. 56
      examples/vdmos/crss_coss_ciss.sp
  9. 43
      examples/vdmos/dcdc.sp
  10. 12
      examples/vdmos/inv_vdmos.sp
  11. 25
      examples/vdmos/inv_vdmos_dc.cir
  12. 4
      examples/vdmos/ro_11_vdmos.sp
  13. 24
      examples/vdmos/self-heating.sp
  14. 40
      examples/vdmos/soa_chk.sp
  15. 18
      examples/vdmos/vdmos-out.cir
  16. 8
      examples/vdmos/vdmos-out.sp
  17. 0
      examples/vdmos/vdmos-out_ir_mtr.sp
  18. 0
      examples/vdmos/vdmosp-out-mtr.sp
  19. 0
      examples/vdmos/vdmosp-out.sp

115
examples/vdmos/100W.sp
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@ -0,0 +1,115 @@
100W VDMOS power amplifier
*100W into 8Ω at less than .1% THD
*72° phase margin @ 950kHz
*Adjust R7 for 15mA quiescent current through Q1/Q2
*R24 & R25 are optional output offset trimming
*
VTamb tamb 0 25
MQ1 +V N010 N012 tn tcn IRFP240 tnodeout
X1 tcn tamb case-ambient
MQ2 -V N020 N017 tp tcp IRFP9240 tnodeout
X2 tcp tamb case-ambient
R1 OUT N017 .33
R2 N012 OUT .33
C1 OUT N016 100n
R3 N016 0 10
R4 N010 N009 470
R5 N020 N019 470
V1 +V 0 50
V2 0 -V 50
Q3 N009 N006 N005 0 MJE350
Q4 N006 N006 N004 0 MJE350
R6 +V N005 100
R7 N009 N019 820
Q5 N019 N023 N024 0 MJE340
R8 +V N004 100
R9 N024 -V 100
Q6 N022 N021 N024 0 MJE340
C2 N023 N019 18p
C3 N022 N021 18p
R10 N006 N022 10K
Q7 N023 N015 N008 0 MJE350
Q8 N021 N011 N008 0 MJE350
R13 N023 -V 3.9K
R14 N021 -V 3.9K
Q9 N008 N003 N001 0 MJE350
R15 +V N001 470
R16 N002 N001 1K
Q10 N003 N002 +V 0 MJE350
R17 N003 N007 10K
R18 N007 0 10K
C4 +V N007 47u
R19 OUT1 N011 27K
R20 N011 N018 1K
C5 N018 0 100u
C6 N015 0 330p
R21 N015 N014 2.2K
R22 N014 0 47K
C7 N014 N013 2.2u
Vin N013 0 ac 0 dc 0 SINE(0 {V} 1K)
RLOAD OUT 0 8
R24 +V N011 3.7Meg
R25 N011 -V 6.1Meg
V3 OUT OUT1 dc 0 ac 1
C8 OUT1 N011 3p
*
.param V=1.44 ; 100W RMS
.save @r1[i] @r2[i] v(out1) v(out) @rload[i] v(tn) v(tp) v(tcn) v(tcp) inoise_spectrum
.control
op
print v(out) @r1[i] @r2[i]
ac dec 100 10 1Meg
plot db(V(out)/V(out1))
set units=degrees
plot ph(V(out)/V(out1))
tran 1u 1000m
fourier 1K V(out)
plot v(out)*@rload[i]
settype temperature v(tn) v(tp) v(tcn) v(tcp)
plot v(tn) v(tp) v(tcn) v(tcp)
linearize v(out)
fft v(out)
plot db(v(out)) xlimit 0 20k
alter v3 ac = 0
alter vin ac = 1
noise V(out) Vin dec 10 10 100K
setplot noise2
plot inoise_spectrum
.endc
*
.model IRFP240 VDMOS nchan
+ Vto=4 Kp=5.9 Lambda=.001 Theta=0.015 ksubthres=.27
+ Rd=61m Rs=18m Rg=3 Rds=1e7
+ Cgdmax=2.45n Cgdmin=10p a=0.3 Cgs=1.2n
+ Is=60p N=1.1 Rb=14m XTI=3
+ Cjo=1.5n Vj=0.8 m=0.5
+ tcvth=0.0065 MU=-1.27 texp0=1.5
+ Rthjc=0.4 Cthj=5e-3
+ mtriode=0.8
.model IRFP9240 VDMOS pchan
+ Vto=-4 Kp=8.8 Lambda=.003 Theta=0.08 ksubthres=.35
+ Rd=180m Rs=50m Rg=3 Rds=1e7
+ Cgdmax=1.25n Cgdmin=50p a=0.23 Cgs=1.15n
+ Is=150p N=1.3 Rb=16m XTI=2
+ Cjo=1.3n Vj=0.8 m=0.5
+ tcvth=0.004 MU=-1.27 texp0=1.5
+ Rthjc=0.4 Cthj=5e-3
+ mtriode=0.6
*
.model MJE340 NPN(Is=1.03431e-13 BF=172.974 NF=.939811 VAF=27.3487 IKF=0.0260146 ISE=4.48447e-11 Ne=1.61605 Br=16.6725
+ Nr=0.796984 VAR=6.11596 IKR=0.10004 Isc=9.99914e-14 Nc=1.99995 RB=1.47761 IRB=0.2 RBM=1.47761 Re=0.0001 RC=1.42228
+ XTB=2.70726 XTI=1 Eg=1.206 CJE=1e-11 VJE=0.75 Mje=.33 TF=1e-09 XTF=1 VTF=10 ITF=0.01 CJC=1e-11 VJC=.75 MJC=0.33 XCJC=.9
+ Fc=0.5 CJS=0 VJS=0.75 MJS=0.5 TR=1e-07 PTF=0 KF=1e-15 AF=1)
.model MJE350 PNP(Is=6.01619e-15 BF=157.387 NF=.910131 VAF=23.273 IKF=0.0564808 Ise=4.48479e-12 Ne=1.58557 BR=0.1
+ NR=1.03823 VAR=4.14543 IKR=.0999978 ISC=1.00199e-13 Nc=1.98851 RB=.1 IRB=0.202965 RBM=0.1 Re=.0710678 Rc=.355339
+ XTB=1.03638 XTI=3.8424 Eg=1.206 Cje=1e-11 Vje=0.75 Mje=0.33 TF=1e-09 XTF=1 VTF=10 ITF=0.01 Cjc=1e-11 Vjc=0.75
+ Mjc=0.33 XCJC=0.9 Fc=0.5 Cjs=0 Vjs=0.75 Mjs=0.5 TR=1e-07 PTF=0 KF=1e-15 AF=1)
*
.subckt case-ambient case amb
rcs case 1 0.1
csa 1 0 30m
rsa 1 amb 1.3
.ends
.end

92
examples/vdmos/100W_wingspread.sp
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@ -0,0 +1,92 @@
VDMOS wingspread plot example
M1 +V N004 N005 IRFP240
M2 -V N009 N007 IRFP9240
R1 OUT N007 .33
R2 N005 OUT .33
R4 N004 N003 470
R5 N009 N008 470
V1 +V 0 50
V2 0 -V 50
Q3 -V N011 N008 0 MJE350
R7 N003 N008 870
Q5 +V N002 N003 0 MJE340
Vin N006 0 0
RLoad OUT 0 r = 8
V3 N001 N006 4.8
V4 N006 N010 4.8
I1 +V N001 12m
I2 N010 -V 12m
R3 N002 N001 10
R8 N011 N010 10
*
.save all @r1[i] @r2[i] v(out) @rload[i]
.control
let gain=vector(2005)
reshape gain [5][401]
let irload=vector(2005)
reshape irload [5][401]
let offset = 0.05
foreach Rl 4 6 8
setplot new
set curplottitle = "wingspread $Rl Ohm"
set plotname=$curplot
alter Rload r = $Rl
let index = 0
foreach vbias 4.7 4.8 4.9 5.0 5.1
alter v3 dc = $vbias + offset
alter v4 dc = $vbias - offset
op
print v(out) @r1[i] @r2[i]
dc vin -20 20 0.1
set dcplotname = $curplot
setplot $plotname
let gain[index] = deriv({$dcplotname}.out)
let irload[index] = {$dcplotname}.@rload[i]
let index = index + 1
destroy $dcplotname
end
settype current irload
plot gain[0] gain[1] gain[2] gain[3] gain[4] vs irload[2]
end
.endc
*
.model IRFP240 VDMOS nchan
+ Vto=4 Kp=5.9 Lambda=.001 Theta=0.015 ksubthres=.27
+ Rd=61m Rs=18m Rg=3 Rds=1e7
+ Cgdmax=2.45n Cgdmin=10p a=0.3 Cgs=1.2n
+ Is=60p N=1.1 Rb=14m XTI=3
+ Cjo=1.5n Vj=0.8 m=0.5
+ tcvth=0.0065 MU=-1.27 texp0=1.5
*+ Rthjc=1.8k Cthj=1e-3
+ mtriode=0.8
.model IRFP9240 VDMOS pchan
+ Vto=-4 Kp=8.8 Lambda=.003 Theta=0.08 ksubthres=.35
+ Rd=180m Rs=50m Rg=3 Rds=1e7
+ Cgdmax=1.25n Cgdmin=50p a=0.23 Cgs=1.15n
+ Is=150p N=1.3 Rb=16m XTI=2
+ Cjo=1.3n Vj=0.8 m=0.5
+ tcvth=0.004 MU=-1.27 texp0=1.5
*+ Rthjc=1.8k Cthj=1e-3
+ mtriode=0.6
*
.model MJE340 NPN(Is=1.03431e-13 BF=172.974 NF=.939811 VAF=27.3487 IKF=0.0260146 ISE=4.48447e-11 Ne=1.61605 Br=16.6725
+ Nr=0.796984 VAR=6.11596 IKR=0.10004 Isc=9.99914e-14 Nc=1.99995 RB=1.47761 IRB=0.2 RBM=1.47761 Re=0.0001 RC=1.42228
+ XTB=2.70726 XTI=1 Eg=1.206 CJE=1e-11 VJE=0.75 Mje=.33 TF=1e-09 XTF=1 VTF=10 ITF=0.01 CJC=1e-11 VJC=.75 MJC=0.33 XCJC=.9
+ Fc=0.5 CJS=0 VJS=0.75 MJS=0.5 TR=1e-07 PTF=0 KF=0 AF=1)
.model MJE350 PNP(Is=6.01619e-15 BF=157.387 NF=.910131 VAF=23.273 IKF=0.0564808 Ise=4.48479e-12 Ne=1.58557 BR=0.1
+ NR=1.03823 VAR=4.14543 IKR=.0999978 ISC=1.00199e-13 Nc=1.98851 RB=.1 IRB=0.202965 RBM=0.1 Re=.0710678 Rc=.355339
+ XTB=1.03638 XTI=3.8424 Eg=1.206 Cje=1e-11 Vje=0.75 Mje=0.33 TF=1e-09 XTF=1 VTF=10 ITF=0.01 Cjc=1e-11 Vjc=0.75
+ Mjc=0.33 XCJC=0.9 Fc=0.5 Cjs=0 Vjs=0.75 Mjs=0.5 TR=1e-07 PTF=0 KF=0 AF=1)
*
.end

2
examples/vdmos/IXTH80N20L-IXTH48P20P-quasisat.cir → examples/vdmos/IXTH80N20L-IXTH48P20P-quasisat.sp
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@ -36,7 +36,7 @@ plot dc3.vs2#branch vs2#branch
+ VTO=4 KP=15 + VTO=4 KP=15
+ Lambda=3m $ will be reset by altermod to original 2m + Lambda=3m $ will be reset by altermod to original 2m
+ Mtriode=0.4 + Mtriode=0.4
+ subslope=120m
+ Ksubthres=120m
+ subshift=160m + subshift=160m
+ Rs=5m Rd=10m Rds=200e6 + Rs=5m Rd=10m Rds=200e6
+ Cgdmax=9000p Cgdmin=300p A=0.25 + Cgdmax=9000p Cgdmin=300p A=0.25

0
examples/vdmos/IXTP6N100D2-cap.cir → examples/vdmos/IXTP6N100D2-cap.sp
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0
examples/vdmos/IXTP6N100D2-n-weak-inv.cir → examples/vdmos/IXTP6N100D2-n-weak-inv.sp
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25
examples/vdmos/VDMOS-DIO-AC.cir
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@ -1,25 +0,0 @@
Capacitance and current comparison between models d and bulk diode in vdmos
D1 ad kd dio
.model dio d TT=1371n IS=2.13E-08 N=1.564 RS=0.0038 m=0.548 Vj=0.1 Cjo=3200pF
Va ad 0 DC 0.5 AC 1 $ DC -20
Vk kd 0 0
m1 d g s IXTP6N100D2
.MODEL IXTP6N100D2 VDMOS(KP=2.9 RS=0.1 RD=1.3 RG=1 VTO=-2.7 LAMBDA=0.03 CGDMAX=3000p CGDMIN=2p CGS=2915p a=1 TT=1371n IS=2.13E-08 N=1.564 RB=0.0038 m=0.548 Vj=0.1 Cjo=3200pF ksubthres=0.1 subslope=43m subshift=-25m)
Vd d 0 DC -0.5 AC 1 $ DC 20
Vg g 0 -5 $ transistor is off
Vs s 0 0
.ac dec 10 1 100K
.control
save @d1[id] @m1[id] all
run
plot mag(i(Vs)) mag (i(Vk))
plot ph(i(Vs)) ph(i(Vk))
.endc
.end

14
examples/vdmos/VDMOS-DIO.cir → examples/vdmos/VDMOS-DIO.sp
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@ -3,25 +3,27 @@ Capacitance and current comparison between models d and bulk diode in vdmos
D1 ad kd dio D1 ad kd dio
.model dio d TT=1371n IS=2.13E-08 N=1.564 RS=0.0038 m=0.548 Vj=0.1 Cjo=3200pF .model dio d TT=1371n IS=2.13E-08 N=1.564 RS=0.0038 m=0.548 Vj=0.1 Cjo=3200pF
Va ad 0 dc 0 pwl(0 -2 2.5 0.5)
Va ad 0 ac 1 dc 0.5 pwl(0 -2 2.5 0.5)
Vk kd 0 0 Vk kd 0 0
m1 d g s IXTP6N100D2 m1 d g s IXTP6N100D2
.MODEL IXTP6N100D2 VDMOS(KP=2.9 RS=0.1 RD=1.3 RG=1 VTO=-2.7 LAMBDA=0.03 CGDMAX=3000p CGDMIN=2p CGS=2915p a=1 TT=1371n IS=2.13E-08 N=1.564 RB=0.0038 m=0.548 Vj=0.1 Cjo=3200pF ksubthres=0.1) .MODEL IXTP6N100D2 VDMOS(KP=2.9 RS=0.1 RD=1.3 RG=1 VTO=-2.7 LAMBDA=0.03 CGDMAX=3000p CGDMIN=2p CGS=2915p a=1 TT=1371n IS=2.13E-08 N=1.564 RB=0.0038 m=0.548 Vj=0.1 Cjo=3200pF ksubthres=0.1)
Vd d 0 dc 0 pwl(0 2 2.5 -0.5)
Vd d 0 ac 1 dc -0.5 pwl(0 2 2.5 -0.5)
Vg g 0 -5 $ transistor is off Vg g 0 -5 $ transistor is off
Vs s 0 0 Vs s 0 0
.tran 10m 2.5
.control .control
save @d1[cd] @m1[cds] all
run
save all @d1[id] @m1[id] @d1[cd] @m1[cds] all
tran 10m 2.5
plot abs(i(Vk)) abs(i(Vs)) ylog plot abs(i(Vk)) abs(i(Vs)) ylog
plot @d1[cd] @m1[cds] plot @d1[cd] @m1[cds]
*plot abs(i(Vk)) - abs(i(Vs)) *plot abs(i(Vk)) - abs(i(Vs))
*plot @d1[cd] - @m1[cds] *plot @d1[cd] - @m1[cds]
ac dec 10 1 100K
plot mag(i(Vs)) mag (i(Vk))
plot ph(i(Vs)) ph(i(Vk))
.endc .endc
.end .end

56
examples/vdmos/crss_coss_ciss.sp
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@ -0,0 +1,56 @@
crss coss ciss
*
VP1 P1 0 PULSE(0 1.15m 100n 10n 10n 1 2)
VP2 P4 0 PULSE(0 2.8m 100n 10n 10n 1 2)
*
M1 d1 g1 0 IRFP240
V1 g1 0 0.0
V2 1 d1 0.0
G1 0 1 P1 0 1.04
*
M2 d2 0 d2 IRFP240
V3 2 d2 0.0
G2 0 2 P4 0 1.1
*
M3 d3 g3 0 IRFP9240
V4 g3 0 0.0
V5 3 d3 0.0
G3 3 0 P1 0 0.85
e1 d1p 0 d3 0 -1
*
M4 d4 0 d4 IRFP9240
V6 4 d4 0.0
G4 4 0 P4 0 1.0
e2 d2p 0 d4 0 -1
*
.control
tran 1n 25u
*plot v(d1) v(d2) v(d3) v(d4)
plot 'i(v1)/deriv(v(d1))' 'i(v2)/deriv(v(d1))' vs v(d1) xlog xlimit 1 100 ylimit 0 3n title "IRFP240 crss & coss"
plot 'i(v3)/deriv(v(d2))' vs v(d2) xlog xlimit 1 100 ylimit 0 3n title "IRFP240 ciss"
plot 'i(v4)/deriv(v(d3))' 'i(v5)/deriv(v(d3))' vs v(d1p) xlog xlimit 1 100 ylimit 0 3n title "IRFP9240 crss & coss"
plot 'i(v6)/deriv(v(d4))' vs v(d2p) xlog xlimit 1 100 ylimit 0 3n title "IRFP9240 ciss"
.endc
.model IRFP240 VDMOS nchan
+ Vto=4 Kp=5.9 Lambda=.001 Theta=0.015 ksubthres=.27
+ Rd=61m Rs=18m Rg=3 Rds=1e7
+ Cgdmax=2.45n Cgdmin=10p a=0.3 Cgs=1.2n
+ Is=60p N=1.1 Rb=14m XTI=3
+ Cjo=1.5n Vj=0.8 m=0.5
+ tcvth=0.0065 MU=-1.27 texp0=1.5
*+ Rthjc=1.8k Cthj=1e-3
+ mtriode=0.8
.model IRFP9240 VDMOS pchan
+ Vto=-4 Kp=8.8 Lambda=.003 Theta=0.08 ksubthres=.35
+ Rd=180m Rs=50m Rg=3 Rds=1e7
+ Cgdmax=1.25n Cgdmin=50p a=0.23 Cgs=1.15n
+ Is=150p N=1.3 Rb=16m XTI=2
+ Cjo=1.3n Vj=0.8 m=0.5
+ tcvth=0.004 MU=-1.27 texp0=1.5
*+ Rthjc=1.8k Cthj=1e-3
+ mtriode=0.6
.end

43
examples/vdmos/dcdc.sp
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@ -0,0 +1,43 @@
Simple regulated DCDC step-up converter
V1 clock 0 PULSE(0 6 0 19u 1u 10n 20.01u)
V2 ref 0 2.5
R1 OUT outdiv 100K
R2 0 outdiv 27k
R3 outdiv x 10k
C2 err x 50n
B1 err 0 V = max(0,min(5,V(ref,x)*10k))
B2 gate 0 V = max(0,min(5,V(err,clock)*1k))
V3 +V 0 5.0
L1 +V lx 220u
RL lx out1 125m
M1 out1 gate 0 IRF510
D1 out1 OUT MBRS340
C1 OUT cx 33u
RC cx 0 50m
R4 out2 OUT R = (time<12ms ? {Rload} : time<20ms ? {Rload/2} : {2*Rload})
V4 out2 0 0.0
.param Rload=100
.model IRF510 VDMOS nchan
+ Vto=3.6 Kp=1.3 Lambda=.001 Theta=0.07 ksubthres=.1
+ Rg=3 Rd=200m Rs=54m Rds=1e7
+ Cgdmax=.2n Cgdmin=.05n a=0.3 Cgs=.12n
+ Is=17p N=1.1 Rb=80m XTI=3
+ Cjo=.25n Vj=0.8 m=0.5
+ tcvth=0.007 MU=-1.27 texp0=1.5
.model MBRS340 D(Is=22.6u Rs=.042 N=1.094 Cjo=480p M=.61 Eg=.69 Xti=2)
.control
listing e
option method=gear
tran 10n 30m 0 5n
* write dcdc.raw
plot v(err) v(clock) v(gate) v(out)
plot -i(V3) i(V4) ylimit 0 1
rusage all
.endc
.end

12
examples/vdmos/inv_vdmos.cir → examples/vdmos/inv_vdmos.sp
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@ -1,20 +1,22 @@
*****************==== Inverter ====******************* *****************==== Inverter ====*******************
*********** VDMOS **************************** *********** VDMOS ****************************
vdd 1 0 5 vdd 1 0 5
vss 4 0 0
.subckt inv out in vdd vss .subckt inv out in vdd vss
mp1 out in vdd p1 mp1 out in vdd p1
mn1 out in vss n1 mn1 out in vss n1
.ends .ends
xinv 3 2 1 0 inv
xinv 3 2 1 4 inv
Vin 2 0 Pulse (0 5 10n 10n 10n 140n 300n)
.tran 1n 1u
Vin 2 0 DC 0 Pulse (0 5 10n 10n 10n 140n 300n)
.control .control
run
dc Vin 0 5 0.05
* current and output in a single plot
plot v(2) v(3) vss#branch
tran 1n 1u
* current and output in a single plot * current and output in a single plot
plot v(2) v(3) plot v(2) v(3)
.endc .endc

25
examples/vdmos/inv_vdmos_dc.cir
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@ -1,25 +0,0 @@
*****************==== Inverter ====*******************
*********** VDMOS inverter dc ****************************
vdd 1 0 5
vss 4 0 0
.subckt inv out in vdd vss
mp1 out in vdd p1
mn1 out in vss n1
.ends
xinv 3 2 1 4 inv
Vin 2 0 0
.dc Vin 0 5 0.05
.control
run
* current and output in a single plot
plot v(2) v(3) vss#branch
.endc
.model N1 vdmos cgdmin=0.2p cgdmax=1p a=2 cgs=0.5p rg=5k
.model P1 vdmos cgdmin=0.2p cgdmax=1p a=2 cgs=0.5p rg=5k pchan
.end

4
examples/vdmos/ro_11_vdmos.cir → examples/vdmos/ro_11_vdmos.sp
View File

@ -18,8 +18,8 @@ xinv7 9 8 1 0 inv
xinv8 10 9 1 0 inv xinv8 10 9 1 0 inv
xinv9 2 10 1 0 inv xinv9 2 10 1 0 inv
.model N1 vdmos cgdmin=0.05p cgdmax=0.2p a=1.2 cgs=0.15p rg=10 kp=2e-5 rb=1e7 cjo=1n subslope=0.2
.model P1 vdmos cgdmin=0.05p cgdmax=0.2p a=1.2 cgs=0.15p rg=10 kp=2e-5 rb=1e7 cjo=1n pchan subslope=0.2
.model N1 vdmos cgdmin=0.05p cgdmax=0.2p a=1.2 cgs=0.15p rg=10 kp=2e-5 rb=1e7 cjo=1n ksubthres=0.2
.model P1 vdmos cgdmin=0.05p cgdmax=0.2p a=1.2 cgs=0.15p rg=10 kp=2e-5 rb=1e7 cjo=1n pchan ksubthres=0.2
.tran 0.1n 1u .tran 0.1n 1u

24
examples/vdmos/self-heating.sp
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@ -0,0 +1,24 @@
VDMOS self heating test
M1 D G 0 t tc IRFP240 tnodeout
rthk tc 0 0.05
VG G 0 5V Pulse 0 10 0 1m 1m 100m 200m
*RD D D1 4
VD D 0 2V
.model IRFP240 VDMOS nchan
+ Vto=4 Kp=5.9 Lambda=.001 Theta=0.015 ksubthres=.27
+ Rd=61m Rs=18m Rg=3 Rds=1e7
+ Cgdmax=2.45n Cgdmin=10p a=0.3 Cgs=1.2n
+ Is=60p N=1.1 Rb=14m XTI=3
+ Cjo=1.5n Vj=0.8 m=0.5
+ tcvth=0.0065 MU=-1.27 texp0=1.5
+ Rthjc=0.02 Cthj=1e-3 Rthca=100
+ mtriode=0.8
.control
dc vd 0.1 50 .1 vg 5 13 2
plot -i(vd)
settype temperature v(t) v(tc)
plot v(t) v(tc)
*tran 1m 0.01
*plot v(d) v(g)
.endc
.end

40
examples/vdmos/soa_chk.sp
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@ -0,0 +1,40 @@
VDMOS SOA check
.model IRFP240 VDMOS nchan
+ Vto=4 Kp=5.9 Lambda=.001 Theta=0.015 ksubthres=.27
+ Rd=61m Rs=18m Rg=3 Rds=1e7
+ Cgdmax=2.45n Cgdmin=10p a=0.3 Cgs=1.2n
+ Is=60p N=1.1 Rb=14m Cjo=1.5n XTI=3
+ tcvth=0.0065 MU=-1.27 texp0=1.5
+ mtriode=0.8
+ Vgs_max=20 Vgd_max=20 Vds_max=200
vd1 d1 0 dc 0.1
vg1 g1 0 dc 0.0
vs1 s1 0 dc 0.0
m1 d1 g1 s1 IRFP240
.model IRFP9240 VDMOS pchan
+ Vto=-4 Kp=8.8 Lambda=.003 Theta=0.08 ksubthres=.35
+ Rd=180m Rs=50m Rg=3 Rds=1e7
+ Cgdmax=1.25n Cgdmin=50p a=0.23 Cgs=1.15n
+ Is=150p N=1.3 Rb=16m Cjo=1.3n XTI=2
+ tcvth=0.004 MU=-1.27 texp0=1.5
+ mtriode=0.6
+ Vgs_max=20 Vgd_max=20 Vds_max=200
vd2 0 d2 dc 0.1
vg2 0 g2 dc 0.0
vs2 0 s2 dc 0.0
m2 d2 g2 s2 IRFP9240
.options warn=1 maxwarns=6
.control
dc vd1 -1 210 1 vg1 5 25 5
plot -i(vd1)
dc vd2 -1 210 1 vg2 5 25 5
plot i(vd2)
.endc
.end

18
examples/vdmos/vdmos-out.cir
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@ -1,18 +0,0 @@
VDMOS output
m1 d g s n1
*.model n1 vdmos rb=0.05 is=10n kp=2 bv=12 rd=0.1
.model N1 vdmos vto=1 cgdmin=0.05p cgdmax=0.2p a=1.2 cgs=0.15p rg=10 kp=2e-4 rb=1e4 is=1e-9 bv=12 cjo=1p subslope=0.1
vd d 0 1
vg g 0 1
vs s 0 0
.control
dc vd -2 15 0.05 vg 0 5 1
plot vs#branch
dc vg 0 5 0.05 vd 0.5 2.5 0.5
plot vs#branch ylog
.endc
.end

8
examples/vdmos/vdmos-out_ir.cir → examples/vdmos/vdmos-out.sp
View File

@ -2,17 +2,17 @@ VDMOS output
m1 d g s IRFZ48Z m1 d g s IRFZ48Z
.model IRFZ48Z VDMOS (Rg = 1.77 Vto=4 Rd=1.85m Rs=0.0m Rb=3.75m Kp=25 Cgdmax=2.1n Cgdmin=0.05n Cgs=1.8n Cjo=0.55n Is=2.5p tt=20n mfg=International_Rectifier Vds=55 Ron=8.6m Qg=43n)
.model IRFZ48Z VDMOS (Rg = 1.77 Vto=4 Rd=1.85m Rs=0.0m Rb=3.75m Kp=25 Cgdmax=2.1n Cgdmin=0.05n Cgs=1.8n Cjo=0.55n Is=2.5p tt=20n ksubthres=0.1 mfg=International_Rectifier Vds=55 Ron=8.6m Qg=43n)
vd d 0 1 vd d 0 1
vg g 0 1 vg g 0 1
vs s 0 0 vs s 0 0
.dc vd -1 15 0.05 vg 3 7 1
.control .control
run
dc vd -1 15 0.05 vg 3 7 1
plot vs#branch plot vs#branch
dc vg 2 7 0.05 vd 0.5 2.5 0.5
plot vs#branch ylog
.endc .endc
.end .end

0
examples/vdmos/vdmos-out_ir_mtr.cir → examples/vdmos/vdmos-out_ir_mtr.sp
View File

0
examples/vdmos/vdmosp-out-mtr.cir → examples/vdmos/vdmosp-out-mtr.sp
View File

0
examples/vdmos/vdmosp-out.cir → examples/vdmos/vdmosp-out.sp
View File

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