Tubes Model

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https://cbp.tnw.utwente.nl/PolymeerDictaat/node62.html
Перевести · The tube model The movement of a chain in a dense polymeric system is highly constrained. Due to entanglements with other chains …
https://www.dreamstime.com/photos-images/tubes-model.html
Перевести · Your Tubes Model stock images are ready. Download all free or royalty-free photos and images. Use them in commercial designs under …
https://gist.github.com/chanmix51/6947361
Перевести · 12.10.2013 · * Modeling Of Tubes Employing Genetic Algorithms * * Models contain 1G resistors from all nodes to earth in order to avoid * floating nodes. Triode and tetrode/pentode models contain a diode for * simulating grid current. * * Non-commercial use is permitted, but at your own risk... This model …
https://hum3d.com/de/3d-models/test-tubes
Перевести · 22.12.2017 · 3D model of Test Tubes available for Download in FBX, OBJ, 3DS, C4D and other file formats for 23 software. Model is …
Beautiful Mature Model SUNSET Photoshoot
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How To Model Pipes And Wires ¦ Simple Techniques [Maya]
tdsl.duncanamps.com/dcigna/tubes/spice
Перевести · Spice Models of Vacuum Tubes. Here are models of a few popular audio tubes that have been generously donated by others*. (If you have any working models that you would like to add, please let me know.) general model for the heater of indirectly heated tubes …
https://m.youtube.com/watch?v=pE5Amr0E64w
Перевести · 25.11.2009 · A quick tutorial on how to model two tubes as if they were welded together. …
How are vacuum tubes modeled in motega software?
How are vacuum tubes modeled in motega software?
* Model generated by Motega software: * Modeling Of Tubes Employing Genetic Algorithms * Models contain 1G resistors from all nodes to earth in order to avoid * floating nodes. Triode and tetrode/pentode models contain a diode for
Are there any free models of vacuum tubes?
Are there any free models of vacuum tubes?
Intusofthas made available some free IsSpice models of vacuum tubes. Visit their web site and look for newsletters #34 and #35. If you have other Spice models of vacuum tubes (even the same tubes) please let me know. I would like to add them to the list!
tdsl.duncanamps.com/dcigna/tubes/spice/
Which is the main concept of the tube model?
Which is the main concept of the tube model?
The chain thus creates a new piece of tube and at the same time destroys part of the tube on the other side. This kind of motion is called reptation . It is clear from the above picture that the reptative motion will determine the long time motion of the chain. The main concept of the model is the primitive chain.
cbp.tnw.utwente.nl/PolymeerDictaat/node6…
Who is the best modeler for spice tubes?
Who is the best modeler for spice tubes?
If it tilts your decision, Charles Hymowitzof Intusoft has a lot of experience modeling tubes and has offered his help for all types of Spice support (IsSpice, PSpice, or any other brand of Spice.) Back to the Audio Tube page This page has been visited times since 5 August 1996.
tdsl.duncanamps.com/dcigna/tubes/spice/
https://m.youtube.com/watch?v=lkpmnaHmD9k
Перевести · 24.07.2021 · This episode on Blondihacks, I'm making fire tubes for my boiler with a special tool for the job. Exclusive videos, drawings, models …
https://www.diyaudio.com/forums/tubes-valves/243950-vacuum-tube-spice-models.html
Перевести · 18.04.2016 · Vacuum tubes SPICE models, another way: Dominique_free: Software Tools: 2: 12th November 2013 06:26 PM: Tube spice models: nhuwar: Tubes / Valves: 45: 25th November 2011 08:47 AM: Computer program for tube curves and Spice models: Jim Tonne: Software Tools: 9: 21st November 2010 10:10 AM: Got my tube spice models…
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*--------------------------------------------------------------------------
* Model generated by Motega software:
* Modeling Of Tubes Employing Genetic Algorithms
* Models contain 1G resistors from all nodes to earth in order to avoid
* floating nodes. Triode and tetrode/pentode models contain a diode for
* Non-commercial use is permitted, but at your own risk... This model
* is provided "as is", without warranty of any kind. In no event shall
* Jeroen Boschma be liable for any claim, damages or other liability,
* whether in an action of contract, tort or otherwise, arising from,
* out of or in connection with the tube model or the use or other
* Motega V 1.0, 12-Sep-2010 23:58:18
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
+ PARAMS: ua=1 ug2=1 xa=1 xg2=1 qa=1 qg2=1 kg1=1 kg2=1 kvba=1 kvbg2=1 ce=1
* Resistors in order to avoid floating nodes
* Intermediate expressions which simplify the current calculation
E1 1 0 VALUE={xa + ce*PWR(V(A,K),2)}
E2 2 0 VALUE={V(Gr2,K)*LOG(1 + EXP(qa*(1/ua + V(Gr1,K)/V(Gr2,K))))/qa}
E3 3 0 VALUE={V(Gr2,K)*LOG(1 + EXP(qg2*(1/ug2 + V(Gr1,K)/V(Gr2,K))))/qg2}
G1 A K VALUE={(PWR(V(2),V(1)) + PWRS(V(2),V(1)))*ATAN(V(A,K)/kvba)/kg1}
G2 Gr2 K VALUE={(PWR(V(3),V(1)) + PWRS(V(3),V(1)))*ATAN(V(A,K)/kvbg2)/kg2}
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
* Resistors in order to avoid floating nodes
+ PARAMS: ua=76.129 ug2=8.581K xa=759.154M xg2=952.570M qa=233.302 qg2=151.489
+ kg1=68.216 kg2=142.261 kvba=19.057 kvbg2=2.179M ce=22.808U
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
* Resistors in order to avoid floating nodes
+ PARAMS: ua=164.060 ug2=2.189K xa=442.879M xg2=687.751M qa=620.235 qg2=93.692
+ kg1=89.910 kg2=161.636 kvba=11.369 kvbg2=655.832 ce=358.645N
+ params: mu=18.8 ex=1.5 kg1=540 kp=165 kvb=174 rgi=1000 vct=0.01
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
* liste des paramètres et ce que j'en ai déduit
* G = modifie la pente avant le coude pour les courbes d'anodes
* MU = modifie la pente après le coude pour les courbes d'anodes
* MU12 = modifie la hauteur du courant d'anode
* E1 = modifie l'écartement des courbes de courant d'anode
* K1 = modifie l'angle du coude du courant d'anode
* k3 = modifie l'écartement des courbes avant le coude pour les courbes d'anodes
* k4 = modifie la hauteur du courant d'écran
* K5 = modifie la valeur maxi du courant d'écran pour les faibles valeurs de Va
* K6 = modifie l'angle du coude du courant d'écran
* K = modifie l'écartement des courbes de courant d'écran
X1 1 2 3 4 PENTH1 G=.100m MU=10000 MU12=30.9 E1=4.6 k1=90.2 k2=2.1 k3=0.8 k4=85.6 k5=26.8 k6=10.6 K=4.50m
**************************************
**Modèle mathématique issu de EXCEM **
**************************************
B1 10 0 V=IF(V(A,C)>0,(V(G2,C)/{MU12})*(V(A,C)-({k3}*V(G1,C)))/((V(G2,C)/{k1})+V(A,C)),0)
B2 A C I={G}*((V(G1,C)+V(10,0))+(V(A,C)/({MU}*(1-(V(G1,C)/{k2})))))**{E1}
B6 12 0 V=IF(V(G2,C)>0,(V(G1,C)+(V(G2,C)/{k4})),0)
B7 G2 C I={K}*(V(12,0)**1.5)*((V(A,C)+{k5})/(V(A,C)+{k6}))**3
B4 6 0 V=IF(V(G1,C)>0,{ALPHA}*V(G1,C)**1.5,{BETA}/-(V(G1,C)-.1))
.MODEL DX D(IS=1N RS=1 CJO=1PF TT=1N)
Esp 2 0 VALUE={V(P,K)+13.49*V(S,K)+130.4*V(G,K)}
E1 3 2 VALUE={5.521E-7*(PWR(V(2),1.5)+PWRS(V(2),1.5))/2}
E2 3 4 VALUE={5.521E-7*PWR(13.49*V(S,K),1.5)*V(P,K)/25}
E3 5 4 VALUE={(1-V(4,2)/ABS(V(4,2)+0.001))/2}
Gp P S VALUE={0.92*(V(3,4)*(1-V(5,4))+V(3,2)*V(5,4))}
.MODEL DX D(IS=1N RS=1 CJO=1PF TT=1N)
Esp 2 0 VALUE={V(P,K)+13.49*V(S,K)+130.4*V(G,K)}
E1 3 2 VALUE={5.521E-7*(PWR(V(2),1.5)+PWRS(V(2),1.5))/2}
E2 3 4 VALUE={5.521E-7*PWR(13.49*V(S,K),1.5)*V(P,K)/25}
E3 5 4 VALUE={(1-V(4,2)/ABS(V(4,2)+0.001))/2}
Gp P S VALUE={0.92*(V(3,4)*(1-V(5,4))+V(3,2)*V(5,4))}
Eat at 0 VALUE={0.636*ATAN(V(A,K)/5)}
Eme me 0 VALUE={PWR(LIMIT{V(A,K),0,2000},1.5)/1750}
Emu mu 0 VALUE={PWRS(V(G,K),1-(LIMIT{-V(G,K),30,9999}-30)/2000)}
Egs gs 0 VALUE={LIMIT{V(A,K)/2.5+V(S,K)*15.15+V(mu)*134,0,1E6}}
Egs2 gs2 0 VALUE={PWRS(V(gs),1.5)*0.8E-6}
Ecath cc 0 VALUE={LIMIT{V(gs2)*V(at),0,V(me)}}
Escrn sc 0 VALUE={0.76*V(gs2)*(1.1-V(at))}
Gs S K VALUE={V(sc)*LIMIT{V(S,K),0,10}/10}
Gg G K VALUE={PWR(LIMIT{V(G,K)+1,0,1E6},1.5)*(1.25-V(at))*650E-6}
Eat at 0 VALUE={limit(0.636*ATAN(limit(V(A,K),0,200)/5.39935952007373),0,1e6)} ;arctangent shaping
Eme me 0 VALUE={0.000459037814532166*PWR(V(A,K),1.19017332861348)} ; diodeline
Egs gs1 0 VALUE={LIMIT(V(A,K)/12216.2805361082+V(S,K)/21.6080182096161+V(G,K)/0.878756035095985 ,0,1E6)} ;the basic voltage
Egs2 gs2 0 VALUE={PWRS(V(gs1),1.48413876122404)*0.0030939788209251} ;raise to the power and mult by perveance
Ga A K VALUE={limit(V(gs2)*V(at),0,V(me))} ; anode current limited per diode line
Gs S K VALUE={1.06934398863015*V(gs2)*(1.1-V(at))}; screen current, reverse arctangent shaping
Gg G K VALUE={PWR(LIMIT(V(G,K)+-0.2500372391271 ,0,1E6),1.5)*(1.25-V(at))*-0.00098104133922726} ; grid current
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
.SUBCKT 6F12PT 1 2 3 ; P G C (Triode) 07 Nov 2004
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
Bp P K I=(0.02003791851m)*uramp(V(P,K)*ln(1.0+(-0.07740549711)+exp((4.618036737)+(4.618036737)*((20.288965)+(-110.4389272m)*V(G,K))*V(G,K)/sqrt((28.13407639)**2+(V(P,K)-(7.118597372))**2)))/(4.618036737))**(1.380047579)
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
Bp P K I=((0.001149607902m)+(0.0001063352726m)*V(G,K))*uramp((91.16514401)*V(G,K)+V(P,K)+(52.29904339))**1.5 * V(P,K)/(V(P,K)+(2.177964467))
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
Bp P K I=(0.01701593477m)*uramp(V(P,K)*ln(1.0+(-0.1251806139)+exp((1.234948774)+(1.234948774)*((34.50197863)+(-26.60747394m)*V(G,K))*V(G,K)/sqrt((22.53603268)**2+(V(P,K)-(-4.400778147))**2)))/(1.234948774))**(1.369425091)
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
Bp P K I=(0.0253900853m)*uramp(V(P,K)*ln(1.0+(-0.002225559277)+exp((2.167148412)+(2.167148412)*((98.41058113)+(-236.6932297m)*V(G,K))*V(G,K)/sqrt((21.28395113)**2+(V(P,K)-(-33.16307233))**2)))/(2.167148412))**(1.238709418)
*--------------------------------------------------------------------------
*--------------------------------------------------------------------------
*+ PARAMS: CCG=2.7P CGP=1.5P CCP=1.65P RGI=2000
*+ MU=25.96 EX=1.79 KG1=557.56 KP=137.33 KVB=391.918
*E1 7 0 VALUE={V(1,3)/KP*LOG(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
*G1 1 3 VALUE={((PWR(V(7),EX)+PWRS(V(7),EX))/(2*KG1))}
*.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
+ params: mu=7.7 ex=1.512 kg1=8700 kp=57 kvb=1116 rgi=1000 vct=.372
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
+PARAMS: LIP= 1.5 LIF= .003 RAF= 1.92357959289845E-03 RAS= .98 CDO= 0
+ MU0= 4.2 MUR= 0.0006 EMC= 0.0000868
+ CGA=1.65E-11 CGK=7.50E-12 CAK=5.50E-12
+ KK1=1744 KP=41.4 KVB=17.1 vg0=1.5
+ CGA=16.5p CGK=7.5p CAK=5.5p RGI=1000
.func V_6() {KP*( (1/MU)+((V(G,K)-vg0)/sqrt(V(A,K)**2+KVB**2)) )}
E8 8 0 VALUE={(V(A,K))/KP*LN(1+EXP(V_6()))}
Eam am 0 VALUE= {2*Pow(V(8),ERP)/KK1}
+ params: mu=40.9 ex=1.71 kg1=825 kp=126 kvb=708 rgi=2000 vct=.01
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
.subckt 3A5 1 2 3 ; uses vacuum diode grid current model
+ params: mu=16.13 ex=1.526 kg1=3270 kp=126 kvb=2 rgi=3000
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=60u rs=1 cjo=1pf N=180)
+PARAMS: LIP= 1.5 LIF= 10 RAF= 0.00536 RAS= 1 CDO= 0
+ MU0= 8.321 MUR= 0.0012 EMC= 0.000533
+ CGA=1.00E-11 CGK=2.50E-11 CAK=1.00E-12
.SUBCKT 6AN8T 1 2 3 ; P G C; NEW MODEL ; TRIODE SECTION
+ PARAMS: MU=21.5 EX=1.3 KG1=1180 KP=84 KVB=300 RGI=2000
+ CCG=2.3P CGP=2.2P CCP=1.0P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
+{V(1,3)/KP*LOG(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1}
RCP 1 3 1G ; TO AVOID FLOATING NODES IN MU-FOLLOWER
C1 2 3 {CCG} ; CATHODE-GRID; WAS 1.6P
C2 2 1 {CGP} ; GRID-PLATE; WAS 1.5P
C3 1 3 {CCP} ; CATHODE-PLATE; WAS 0.5P
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
+PARAMS: LIP= 1 LIF= 0.01 RAF= 0.0058 RAS= 0.7 CDO= 0
+ MU0= 2.05 MUR= 0.0017 EMC= 0.0005
+ CGA=1.10E-11 CGK=8.00E-12 CAK=3.00E-12
+ params: mu=68.2 ex=1.386 kg1=487 kp=234 kvb=1680 rgi=2000 vct=.346
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
+PARAMS: LIP= 1.5 LIF= 10 RAF= 0.030667 RAS= 5 CDO=-0.5
+ MU0= 50 MUR= 0.035 EMC= 0.00000256
+ CGA=4.00E-12 CGK=2.70E-12 CAK=4.00E-12
.func V_6() {KP*( (1/MU)+(V(G,K)/sqrt(V(A,K)**2+KVB**2)) )}
E8 8 0 VALUE={(V(A,K))/KP*LN(1+EXP(V_6()))}
Eam am 0 VALUE= {2*Pow(V(8),ERP)/KK1}
+ CGA=16.5p CGK=7.5p CAK=5.5p RGI=1000 ;(2A3 values)
.func V_6() {KP*( (1/MU)+((V(G,K)-vg0)/sqrt(V(A,K)**2+KVB**2)) )}
E8 8 0 VALUE={(V(A,K))/KP*LN(1+EXP(V_6()))}
Eam am 0 VALUE= {2*Pow(V(8),ERP)/KK1}
.subckt 6C45-PE 1 2 3 ; plate grid cathode
+ params: mu=47.4501 ex=2.374193 kg1=268.615545 kp=485.735371 kvb=501.503636 rgi=300
e1 7 0 value= {v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=10pf tt=1n)
+ params: mu=21.17 ex=1.442 kg1=1920 kp=150 kvb=10 rgi=1000 vct=.48
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
.subckt 6CW4 1 2 3 ; placca griglia catodo NUVISTOR R.C.A.
+ params: mu=68.75 ex=1.35 kg1=160 kp=250 kvb=300 rgi=200
+ a=2.133e-7 b=-9.40e-5 c=.0139666 d=.64
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
+{a*v(1,3)*v(1,3)*v(1,3)+b*v(1,3)*v(1,3)+c*v(1,3)+d}
g1 1 3 value= {(pwr(v(7),v(8))+pwrs(v(7),v(8)))/kg1}
.model dx d(is=1n rs=1 cjo=10pf tt=1n)
+PARAMS: LIP= 1.5 LIF= 10 RAF= 0.09 RAS= 0.2 CDO= 0
+ CGA=1.40E-12 CGK=3.30E-12 CAK=1.80E-12
Bp P K I=(0.3800825583m)*uramp(V(P,K)*ln(1.0+(-0.02540430176)+exp((7.018331616)+(7.018331616)*((15.85848193)+(-66.34009258m)*V(G,K))*V(G,K)/sqrt((27.2125877)**2+(V(P,K)-(5.267363515))**2)))/(7.018331616))**(1.211856956)
Bp P K I=((0.002251977888m)+(-5.369015936e-005m)*V(G,K))*uramp((370.7812379)*V(G,K)+V(P,K)+(423.2938397))**1.5 * V(P,K)/(V(P,K)+(57.14378617))
+ params: mu=94.8 ex=1.274 kg1=103 kp=153 kvb=792 rgi=2000 vct=.122
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
+ params: mu=38.9 ex=1.484 kg1=780 kp=162 kvb=1176 rgi=2000 vct=.384
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
+PARAMS: LIP= 1.5 LIF= 10 RAF= 0.01 RAS= 1 CDO= 0
+ MU0= 37.5 MUR= 0.01 EMC= 0.000005
+ CGA=1.60E-12 CGK=3.20E-12 CAK=1.50E-12
+ params: mu=18.8 ex=1.666 kg1=810 kp=85.5 kvb=600 rgi=2000 vct=.02
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
Gp P K VALUE={1.54E-6*(PWR(V(2),1.5)+PWRS(V(2),1.5))/2}
+PARAMS: LIP= 1 LIF= 0.0037 RAF= 0.02 RAS= 2 CDO= 0
+ MU0= 19.2642 MUR= 0.006167 EMC= 0.0000189
+ CGA=3.90E-12 CGK=2.40E-12 CAK=7.00E-13
.func V_6() {KP*( (1/MU)+((V(G,K)-vg0)/sqrt(V(A,K)**2+KVB**2)) )}
E8 8 0 VALUE={(V(A,K))/KP*LN(1+EXP(V_6()))}
Eam am 0 VALUE= {2*Pow(V(8),ERP)/KK1}
Bp P K I=(0.04842259598m)*uramp(V(P,K)*ln(1.0+(-0.1171696503)+exp((6.561427624)+(6.561427624)*((18.54552963)+(-100.6055605m)*V(G,K))*V(G,K)/sqrt((40.8808477)**2+(V(P,K)-(25.43292096))**2)))/(6.561427624))**(1.491616235)
+PARAMS: LIP= 1 LIF= 0.0037 RAF= 0.09869 RAS= 1 CDO=-0.5
+ MU0= 45.093 MUR= 0.012937 EMC= 0.00000863
+ CGA=1.60E-12 CGK=2.30E-12 CAK=4.00E-13
+PARAMS: LIP= 1 LIF= 0.0037 RAF= 0.000001 RAS= 2.065382774 CDO= 0
+ MU0= 17.08958652 MUR= 0.010938375 EMC= 0.0000183
+ CGA=1.60E-12 CGK=1.80E-12 CAK=4.50E-13
+ params: mu=45 ex=1.4 kg1=465 kp=132 kvb=181 rgi=2000 vct=.356
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
+PARAMS: LIP= 1.5 LIF= 0.000016 RAF= 0.076498 RAS= 1 CDO=-0.53056
+ MU0= 87.302 MUR=-0.013621 EMC= 0.00000111
+ CGA=3.90E-12 CGK=2.40E-12 CAK=7.00E-13
+ params: mu=45 ex=1.47 kg1=2355 kp=300 kvb=136.5 rgi=950 vct=.704
+{v(1,3)/kp*log(1+exp(kp*(1/mu+v(2,3)/sqrt(kvb+v(1,3)*v(1,3)))))}
g1 1 3 value= {(pwr(v(7),ex)+pwrs(v(7),ex))/kg1}
.model dx d(is=1n rs=1 cjo=1pf tt=1n)
Bp P K I=(0.7475666979m)*uramp(V(P,K)*ln(1.0+(-0.03869784353)+exp((5.06748961)+(5.06748961)*((7.783573199)+(-7.718521472m)*V(G,K))*V(G,K)/sqrt((16.65965534)**2+(V(P,K)-(1.974437216))**2)))/(5.06748961))**(1.293967904)
Gp P K VALUE={22.34E-6*(PWR(V(2),1.5)+PWRS(V(2),1.5))/2}
+ KK1=6350 KP=26.5 KVB=9 vg0=0.5 va0=6.0
+ CGA=7.4p CGK=3.7p CAK=2.1p RGI=1000
.func V_6() {KP*( (1/MU)+((V(G,K)-vg0)/sqrt(V(A,K)**2+KVB**2)) )}
E8 8 0 VALUE={(V(A,K)-va0)/KP*LN(1+EXP(V_6()))}
Eam am 0 VALUE= {2*Pow(V(8),ERP)/KK1}
Bp P K I=((0.008071931767m)+(3.503608694e-005m)*V(G,K))*uramp((11.35872332)*V(G,K)+V(P,K)+(-21.07038254))**1.5 * V(P,K)/(V(P,K)+(-4.024455933))
+PARAMS: LIP= 1 LIF= 10 RAF= 0.015 RAS= 1.8 CDO= 0
+ MU0= 12.8 MUR= 0.001 EMC= 0.000008
+ CGA=2.80E-12 CGK=3.50E-12 CAK=2.50E-12
.subckt 211_VT4C 1 3 4 ; TRIODO DI POTENZA D.H.T. ( G.E.)
g1 2 4 value = {(exp(1.5*(log((v(2,4)/12)+v(3,4)))))/3010}
Gp P K VALUE={9.39E-6*(PWR(V(2),1.5)+PWRS(V(2)
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