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Tube_IM.lib
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Tube_IM.lib
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* 29.03.07
* TUBE LIBRARY
* Tube list
* 6DJ8, ECC88
* 12AX7
* 12AU7, ECC82
* 2A3
* 300B
* 12AT7, ECC81
* 6550
* EL34
* 6L6GC
* KT88
* 6AN8 -----> 6AN8T triode, 6AN8P PENTODE
* 6SN7
* 5842, 417A
* 5V4GA
* 5Y3GT
* 6D22S
* 6S33S Attention! Russian "C" means "S", "P" means "R"
* 6N7S
* 6N8S
* 6N6P
* 6N23P
* 6P3S_T Triode Mode
* 6N5P
* 6N1P
* 6S41S Attention! Russian "C" means "S", "P" means "R"
* GU50_T Triode Mode
* 6P45S_T Triode Mode
* 6N3P-E
* 6P3S Pentode Attention! Russian "C" means "S", "P" means "R"
* GU50 Pentode
* 6P14P_T Triode Mode
* 6R3S-1_T Triode Mode. Attention! Russian "C" means "S", "P" means "R"
* 6F5P_T Triode
* 6F5P_PT Pentode in triode mode
* 6N13S
* 6F5P Pentode
* EL84/6BQ5/6P14P
* 6N3P
* 6S51N-V
* 6S52N-V
* 6F12P_T Triode
* 6F12P_P Pentode
* 6P18P_P Pentode
* 6P18P_T Triode Mode
* 6E5P Tetrode
* 6N28B-V
* 6N30P-DR
* 6N27P
* 6P15P_P Pentode
* 6F3P_P Pentode
* 6F3P_T Triode
* 6F3P_PT Pentode in triode mode
* 6S19P
* 6N2P
* 6N9S
* 6E5P_T Tetrode in triode mode, R2gp=200ohm
* 6CW4
* 6P36S_T
* 6S45P-E
* 6J4 Pentode 6Æ4
* 6J4_T Pentode in triode mode
* 6P9
* 6P9_T Pentode in triode mode
* 6J32P Pentode 6Æ32Ï
* 6J32P_T Pentode in triode mode
* 6J9P Pentode 6Æ9Ï
* 6J11P Pentode 6Æ11Ï
* 6BR7 Pentode
* 6BR7_T Pentode in triode mode
* 6J38P Pentode 6Æ38Ï
* 6J38P_T Pentode in triode mode
* 6G2 Triode - Attention! This is 6Ã2 triode
* 6G7 Triode - Attention! This is 6Ã7 triode
* 6S4S
* 6J2P Pentode 6Æ2Ï
* 6J2P_T Pentode in triode mode
* 6B4G
* EF800 (EF860)
* 6L6
* E180F (~6J9P)
* 6P14P Pentode
* 30P1S_T Pentode in triode mode
* 6S7B Triode
* 5C3S
* 5C4S
* 6C5S
* 5C8S
* 6D20P
* 6X2P (diode)
* 6N17B
* 6J8 Pentode Soviet 6Æ8
* 6J8_T Pentode in triode mode
* 6J9G-V Pentode
* 6S3P
* 6P7S_T Triode mode
* 6S6B
* EC360
* ECC84
* ECC85
* EF80
* EF184
* ECF82-T (triode part, Eq. 6U8)
* ECF82 (pentode part, Eq. 6U8A)
* ECF82_PT (pentode in triode mode, 6U8A, TungSol data)
* EL84_T (=6P14P_T, another data, triode mode)
* 6P13S_T (triode mode)
* EL36_T (triode mode)
* 6P15P_T (triode mode)
* 6J9P_T (triode mode)
* 6J11P_T (triode mode)
* 6J52P_T (triode mode)
* 6J3P_T (triode mode)
* 6J4P_T (triode mode)
* EL861_T (triode mode)
* EL861 (Eq. E81L)
* 6J7_T (triode mode)
*Norman Koren library
*$
.SUBCKT 6DJ8 1 2 3 ; P G C; NEW MODEL
+ PARAMS: MU=28 EX=1.3 KG1=330 KP=320 KVB=300 RGI=2000
+ CCG=2.3P CGP=2.1P CCP=.7P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 12AX7 1 2 3 ; P G C; NEW MODEL
+ PARAMS: MU=100 EX=1.4 KG1=1060 KP=600 KVB=300 RGI=2000
+ CCG=2.3P CGP=2.4P CCP=.9P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
C2 2 1 {CGP} ; GRID=PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 12AU7 1 2 3 ; P G C; NEW MODEL
+ 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.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 2A3 1 2 3 ; P G C; NEW MODEL
+ PARAMS: MU=4.2 EX=1.4 KG1=1500 KP=60 KVB=300 RGI=2000
+ CCG=2.3P CGP=2.2P CCP=1.0P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 300B 1 2 3 ; P G C; NEW MODEL
+ PARAMS: MU=3.95 EX=1.4 KG1=1550 KP=65 KVB=300 RGI=1000
+ CCG=2.3P CGP=2.2P CCP=1.0P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 12AT7 1 2 3 ; P G C; NEW MODEL
+ PARAMS: MU=60 EX=1.35 KG1=460 KP=300 KVB=300 RGI=2000
+ CCG=2.3P CGP=2.2P CCP=1.0P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6550 1 2 3 4 ; P G1 C G2
+ PARAMS: MU=7.9 EX=1.35 KG1=890 KG2=4200 KP=60 KVB=24
+ CCG=14P CPG1=.85P CCP=12P RGI=1K
RE1 7 0 1MEG ; DUMMY SO NODE 7 HAS 2 CONNECTIONS
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
* G2 4 3 VALUE={PWR(V(4,3)/MU+V(2,3),EX)/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT EL34 1 2 3 4 ; P G1 C G2
+ PARAMS: MU=11 EX=1.35 KG1=650 KG2=4200 KP=60 KVB=24
+ CCG=15P CPG1=1P CCP=8P RGI=1K
RE1 7 0 1G ; DUMMY SO NODE 7 HAS 2 CONNECTIONS
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6L6GC 1 2 3 4 ; P G1 C G2
+ PARAMS: MU=8.7 EX=1.35 KG1=1460 KG2=4500 KP=48 KVB=12
+ CCG=14P CPG1=.85P CCP=12P RGI=1K
RE1 7 0 1MEG ; DUMMY SO NODE 7 HAS 2 CONNECTIONS
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT KT88 1 2 3 4 ; P G1 C G2
+ PARAMS: MU=8.8 EX=1.35 KG1=730 KG2=4800 KP=32 KVB=16
+ CCG=14P CPG1=.85P CCP=12P RGI=1K
RE1 7 0 1MEG ; DUMMY SO NODE 7 HAS 2 CONNECTIONS
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6AN8T 1 2 3 ; P G C; NEW MODEL ; TRIODE SECTION
+ PARAMS: MU=21.2 EX=1.36 KG1=945 KP=84 KVB=300 RGI=2000
+ CCG=2.7P CGP=2.2P CCP=1.0P ; ADD .7PF TO ADJACENT PINS; .5 TO OTHERS.
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
C2 2 1 {CGP} ; GRID-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6AN8P 1 2 3 4 ; P G1 C G2 ; SECTION
+ PARAMS: MU=45 EX=1.35 KG1=520 KG2=120 KP=120 KVB=18
+ CCG=8P CPG1=.8P CCP=3P RGI=2K
RE1 7 0 1MEG ; DUMMY SO NODE 7 HAS 2 CONNECTIONS
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
*Mithat Konar library
* Connections: Plate
* | Grid
* | | Cathode
* | | |
.SUBCKT 6SN7 1 2 3
+ PARAMS: MU=22.004 EX=1.2128 KG1=1213.7 KP=203.06 KVB=355.09
+ RGI=2000
+ CCG=2.4P CGP=3.9P CCP=0.7P ;
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
C2 2 1 {CGP} ; GRID-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
* Connections: Plate
* | Grid
* | | Cathode
* | | |
.SUBCKT 5842 1 2 3
+ PARAMS: MU=42.4 EX=2.21 KG1=393 KP=629 KVB=446
+ RGI=2000
+ CCG=9.0P CGP=1.8P CCP=0.48P ;
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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
C2 2 1 {CGP} ; GRID-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
*Duncan Munro library
* Device type: Valve rectifier
.SUBCKT 5V4GA A K
RCP A K 1G ; TO AVOID FLOATING NODES
GP A K VALUE={1.4E-3*(PWR(V(A,K),1.5)+PWRS(V(A,K),1.5))/2}
.ENDS 5V4GA
*$
.SUBCKT 5Y3GT A K
RCP A K 1G ; TO AVOID FLOATING NODES
GP A K VALUE={2.69E-4*(PWR(V(A,K),1.5)+PWRS(V(A,K),1.5))/2}
.ENDS 5Y3GT
*$
.SUBCKT 6D22S A K
RCP A K 1G ; TO AVOID FLOATING NODES
GP A K VALUE={6.769E-3*(PWR(V(A,K),1.2646)+PWRS(V(A,K),1.2646))/2}
CP A K 12p
.ENDS 6D22S
*$
*Eugene V. Karpov library
*For tubes manufactured in USSR
.SUBCKT 6S33S 1 2 3 ; P G C; (Triode) 22-Oct-2001
+ PARAMS: MU=3.1 EX=1.4 KG1=163 KP=15 KVB=300 RGI=1000
+ CCG=2.3P CGP=2.2P CCP=1.0P ;
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+V(2,3)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N7S 1 2 3 ; P G C; (Triode) 20-Oct-2001
+ PARAMS: MU=35.29 EX=1.48 KG1=3201.6 KP=590.54
+ KVB=87.5 VCT=0.75 RGI=1000
+ CCG=4.3P CGP=2.4P CCP=5.4P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N8S 1 2 3 ; P G C (Triode) 24-Oct-2001
+ PARAMS: MU= 22.87 EX= 1.516 KG1=2209.8 KP=167.87
+ KVB=155.4 VCT=0.70 RGI=1000
+ CCG=3P CGP=1.2P CCP=4P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N6P 1 2 3 ; P G C (Triode) 25-Oct-2001
+ PARAMS: MU= 17.22 EX= 1.715 KG1=1155.0 KP=87.74
+ KVB=300.0 VCT=0.00 RGI=1000
+ CCG=4P CGP=3P CCP=1.9P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N23P 1 2 3 ; P G C (Triode) 26-Oct-2001
+ PARAMS: MU=33.04 EX=1.220 KG1=212.4 KP=183.83
+ KVB=300.0 VCT=0.00 RGI=2000
+ CCG=3.6P CGP=1.5P CCP=2P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P3S_T 1 2 3 ; P G C (Triode Mode) 28-Oct-2001
+ PARAMS: MU=10.76 EX=1.314 KG1=712.7 KP=24.67
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=11P CGP=1P CCP=8.2P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N5P 1 2 3 ; P G C (Triode)
+ PARAMS: MU=23.76 EX=1.244 KG1=300.1 KP=164.49
+ KVB=300.0 VCT=0.00 RGI=2k
+ CCG=3P CGP=2.25P CCP=1.5P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6S41S 1 2 3 ; P G C (Triode) 30-Oct-2001
+ PARAMS: MU=2.58 EX=1.450 KG1=689.1 KP=9.98
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=11P CGP=15P CCP=5P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N1P 1 2 3 ; P G C (Triode) 30-Oct-2001
+ PARAMS: MU=38.29 EX=1.761 KG1=1430.7 KP=245.76
+ KVB=300.0 VCT=0.00 RGI=2k
+ CCG=3P CGP=2.25P CCP=1.5P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT GU50_T 1 2 3 ; P G C (Triode Mode) 30-Oct-2001
+ PARAMS: MU=5.41 EX=1.366 KG1=1350.7 KP=34.52
+ KVB=300.0 VCT=0.00 RGI=2k
+ CCG=14P CGP=2.58P CCP=9.2P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P45S_T 1 2 3 ; P G C (Triode Mode)02-Nov-2001
+ PARAMS: MU=3.97 EX=1.512 KG1=517.5 KP=43.74
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=55P CGP=13.7P CCP=20P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N3P-E 1 2 3 ; P G C (Triode) 16-Nov-2001
+ PARAMS: MU=31.33 EX=1.979 KG1=1920.5 KP=211.72
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=2.5P CGP=1.3P CCP=1.4P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P3S 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2006
+ PARAMS: MU= 14.432 EX=1.036 KG1=320 KP=33 KG2=2200
+ KVB=21.6 VCT=0.00 RGI=1K
+ CCG=11P CPG1=.85P CCP=8.2P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT GU50 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2006
+ PARAMS: MU=8.5 EX=1.350 KG1=1020 KP=15.9 KG2=17000
+ KVB=30.3 VCT=0.00 RGI=2k
+ CCG=14P CPG1=0.4P CCP=9.2P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={(EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KG2}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P14P_T 1 2 3 ; P G C (Triode Mode) 15-March-2002
+ PARAMS: MU=21.49 EX=1.428 KG1=514.4 KP=136.46
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=11P CGP=0.5P CCP=7P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX-1 D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6R3S-1_T 1 2 3 ; P G C (Triode Mode) 16-March-2002
+ PARAMS: MU=7.15 EX=1.418 KG1=419.4 KP=44.66
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=13P CGP=0.3P CCP=6P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F5P-T 1 2 3 ; P G C (Triode) 22-Sep-2002
+ PARAMS: MU=73.16 EX=1.668 KG1=522.9 KP=353.07
+ KVB=519.0 VCT=0.60 RGI=1k
+ CCG=3.5P CGP=1.8P CCP=0.25P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F5P-PT 1 2 3 ; P G C (Pentode in Triode mode) 22-Sep-2002
+ PARAMS: MU=7.49 EX=1.622 KG1=1336.3 KP=59.91
+ KVB=120.0 VCT=0.00 RGI=1k
+ CCG=11.7P CGP=1.56P CCP=8.8P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N13S 1 2 3 ; P G C (Triode) 31-Agu-2002
+ PARAMS: MU= 2.35 EX= 1.247 KG1= 637.1 KP= 12.40
+ KVB=300.0 VCT=0.0 RGI=1k
+ CCG=8P CGP=10P CCP=3P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F5P-P 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2006
+ PARAMS: MU=11.5 EX=1.204 KG1=303.0 KP=34.87 KC= 85
+ KVB=20.1 VCT=0.00 RGI=1k
+ CCG=11.7P CPG1=0.7P CCP=8.8P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={STP(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)))
+*(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)))}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N3P 1 2 3 ; P G C (Triode) 03-Apr-2003
+ PARAMS: MU=34.82 EX=1.909 KG1=1445.3 KP=171.13
+ KVB=300.0 VCT=0.00 RGI=1k
+ CCG=2.5P CGP=1.3P CCP=1.4P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6S51N 1 2 3 ; P G C (Triode) 21 May 2004
+ PARAMS: MU=54.72 EX=1.248 KG1=123.5 KP=99.63
+ KVB=300.0 VCT=0.00 RGI=1500
+ CCG=4.2P CGP=1.8P CCP=2.5P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6S52N 1 2 3 ; P G C (Triode) 25 May 2004
+ PARAMS: MU= 70.32 EX= 1.250 KG1= 188.8 KP=230.58
+ KVB=300.0 VCT=0.00 RGI=1500
+ CCG=4.35P CGP=1.9P CCP=1.3P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F12P_T 1 2 3 ; P G C (Triode) 07 Nov 2004
+ PARAMS: MU=523.74 EX= 1.039 KG1= 13.5 KP=384.91
+ KVB= 300.0 VCT= 0.00 RGI=4500
+ CCG=4.6P CGP=1.6P CCP=0.26P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F12P_P 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2004
+ PARAMS: MU= 71.45 EX= 1.350 KG1= 260.8 KP=7396.95 KC= 75
+ KVB= 17.9 VCT= 0.00 RGI= 4500k
+ CCG=6.6P CPG1=0.02P CCP=1.9P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))}
G2 4 3 VALUE={STP(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))
+*(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P18P_P 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2006
+ PARAMS: MU= 14.95 EX= 1.350 KG1= 568.0 KP=37.41 KC= 150
+ KVB= 34.4 VCT= 0.00 RGI=1000
+ CCG=11.5P CPG1=0.2P CCP=6P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))}
G2 4 3 VALUE={STP(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))
+*(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P18P_T 1 2 3 ; P G C (Triode)
+ PARAMS: MU= 16.23 EX= 1.470 KG1= 419.3 KP= 38.32
+ KVB= 300.0 VCT= 0.00 RGI=1000
+ CCG=11.5P CGP=0.7P CCP=6P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6E5P 1 2 3 4 ; P G1 C G2 (Tetrode) 24-Dec-2006
+ PARAMS: MU= 42.48 EX= 1.350 KG1= 145.2 KP=191.93 KC= 24.5
+ KVB= 46.4 VCT= 0.00 RGI=1000
+ CCG=15P CPG1=0.6P CCP=2.5P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))}
G2 4 3 VALUE={STP(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))
+*(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*1.57*TANH(2*V(1,3)/(KVB*3.14159))))}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N28B-V 1 2 3 ; P G C (Triode) 12-Dec-2004
+ PARAMS: MU= 22.45 EX= 1.369 KG1= 458.9 KP= 82.65
+ KVB= 300.0 VCT= 0.00 RGI=1500
+ CCG=3.3P CGP=2P CCP=2.2P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N30P-DR 1 2 3 ; P G C (Triode) 12-Dec-2004
+ PARAMS: MU= 16.81 EX= 1.305 KG1= 188.0 KP=110.43
+ KVB= 300.0 VCT= 0.00 RGI=1500
+ CCG=6.3P CGP=2P CCP=2.4P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6N27P 1 2 3 ; P G C (Triode) 18-Dec-2004
+ PARAMS: MU=16.3 EX=1.3 KG1=350.1 KP=76.28
+ KVB=150.0 VCT=0.00 RGI=1500
+ CCG=3P CGP=1.3P CCP=2P
E1 7 0 VALUE=
+{V(1,3)/KP*LN(1+EXP(KP*(1/MU+(V(2,3)+VCT)/SQRT(KVB+V(1,3)*V(1,3)))))}
RE1 7 0 1G
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;
C2 2 1 {CGP} ; GRID-PLATE;
C3 1 3 {CCP} ; CATHODE-PLATE;
D3 5 3 DX ; FOR GRID CURRENT
R1 2 5 {RGI} ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6P15P_P 1 2 3 4 ; P G1 C G2 (Pentode) 28-Nov-2005
+ PARAMS: MU= 27.37 EX= 1.350 KG1= 433.9 KP=188.23 KC= 128.5
+ KVB= 16.6 VCT= 0.00 RGI=1k
+ CCG=13.5P CPG1=0.07P CCP=7P
RE1 7 0 1MEG
E1 7 0 VALUE= ; E1 BREAKS UP LONG EQUATION FOR G1.
+{V(4,3)/KP*LN(1+EXP((1/MU+V(2,3)/V(4,3))*KP))}
G1 1 3 VALUE={(PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)}
G2 4 3 VALUE={STP(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)))
+*(((EXP(EX*(LN((V(4,3)/MU)+V(2,3)))))/KC)-((PWR(V(7),EX)+PWRS(V(7),EX))/KG1*ATAN(V(1,3)/KVB)))}
RCP 1 3 1G ; FOR CONVERGENCE
C1 2 3 {CCG} ; CATHODE-GRID 1
C2 1 2 {CPG1} ; GRID 1-PLATE
C3 1 3 {CCP} ; CATHODE-PLATE
R1 2 5 {RGI} ; FOR GRID CURRENT
D3 5 3 DX ; FOR GRID CURRENT
.MODEL DX D(IS=1N RS=1 CJO=10PF TT=1N)
.ENDS
*$
.SUBCKT 6F3P_P 1 2 3 4 ; P G1 C G2 (Pentode) 24-Dec-2006
+ PARAMS: MU= 9.12 EX= 1.350 KG1= 929.0 KP=219.91 KC= 253
+ KVB= 39.3 VCT= 0.00 RGI=1k
+ CCG=9.3P CPG1=0.3P CCP=8.5P
RE1 7 0 1MEG