IR2117 spice model subckts

[sp3twg]

I am using the IR2117 spice model available from IR.

it has 2 subckts and I think Altium is not liking this...
it has

.SUBCKT IR2117
....
.ENDS IR2117

and

.SUBCKT COMP 1 2 3
E1 4 0 VALUE={IF(V(1)>V(2), 5V, 0)}
R1 4 3 1
C1 3 0 10P
.ENDS COMP

at the very end of the file

it complains about parsing the IF statement and it seems fine to me .. any thoughts?

 

[dselec]

Send the asm files for your project ill help

 

[sp3twg]

what ASM files? there is no assembly involved

 

[dselec]

what ASM files? there is no assembly involved

"IR2117 spice model" u mentioned spice model

 

[sp3twg]

**********************************************************************
*
* Copyright (c) International Rectifier
*
* IR2117: Single Channel Driver
*
* Ports
* VCC: Logic and Gate Drive Supply
* IN: Logic Input for Gate Driver Output (HO), in phase
* COM: Logic Ground
* VB: High Side Floating Supply
* HO: High Side Gate Dive Output
* VS: High Side Floating Supply Return
*
* Created by Pspice Version 8
*
* Date Created: 04/2003
*
***********************************************************************
*
* This behavioral model was developed in compliance with Data Sheet
* No. PD60146-L except noted below:
* (1) There is no frequency effect on temperature.
* (2) The power dissipation is different.
* (3) The values of output high/low short circuit current are adjusted
* for the proper modeling of turn-on rise/turn-off fall time.
* (4) The "com" pin must be grounded.
***********************************************************************


.SUBCKT IR2117 1 2 3 4 5 6
+PARAMS:
+ V1=10 V2=15 V3=20
+ T1=-40 T2=25 T3=125
+ tonT1=125n tonT2=125n tonT3=125n
+ tonV1=125n tonV2=125n tonV3=125n
+ toffT1=105n toffT2=105n toffT3=105n
+ toffV1=105n toffV2=105n toffV3=105n

.MODEL diode25 d
+IS=1.0e-14 RS=0.01 N=1 EG=1.11
+XTI=3 BV=25 IBV=0.0001 CJO=0
+VJ=0.75 M=0.333 FC=0.5 TT=0
+KF=0 AF=1

.MODEL diode625 d
+IS=1.0e-14 RS=0.01 N=1 EG=1.11
+XTI=3 BV=625 IBV=0.0001 CJO=0
+VJ=0.75 M=0.333 FC=0.5 TT=0
+KF=0 AF=1

D_MD1_D5 3 1 DIODE25
D_MD1_D1 2 1 DIODE25
D_MD1_D4 3 2 DIODE25
R_MD1_R2 3 2 750k
R_MD1_R1 3 1 214k
X_MD1_Trig_Comp1 MD1_Trig_2 MD1_Trig_3 MD2_Nand_2 COMP
C_MD1_Trig_C 0 MD2_Nand_2 10p
R_MD1_Trig_R1 MD1_Trig_3 MD1_Trig_1 100Meg
S_MD1_Trig_P MD1_Trig_4 0 MD2_Nand_2 0 _MD1_Trig_P
RS_MD1_Trig_P MD2_Nand_2 0 1G
.MODEL _MD1_Trig_P VSWITCH Roff=5e9 Ron=1 Voff=0.01 Von=4.99
R_MD1_Trig_R2 MD1_Trig_4 MD1_Trig_3 66.7Meg
R_MD1_Trig_R3 0 MD1_Trig_4 106.1Meg
E_MD1_ABM14 MD1_Trig_2 0 VALUE { V(2)-v(3) }
E_MD1_ABM15 MD1_Trig_1 0 VALUE { V(1)-v(3) }
S_MD2_Inv_N MD2_Inv_3 0 MD2_Nand_3 0 _MD2_Inv_N
RS_MD2_Inv_N MD2_Nand_3 0 1G
.MODEL _MD2_Inv_N VSWITCH Roff=1e6 Ron=1 Voff=0v Von=5v
S_MD2_Inv_P MD2_Inv_2 MD2_Inv_3 MD2_Nand_3 0 _MD2_Inv_P
RS_MD2_Inv_P MD2_Nand_3 0 1G
.MODEL _MD2_Inv_P VSWITCH Roff=1e6 Ron=1 Voff=5v Von=0v
V_MD2_Inv_V MD2_Inv_2 0 5V
R_MD2_Inv_R MD3_DlyHS_2 MD2_Inv_3 1
C_MD2_Inv_C 0 MD3_DlyHS_2 10p
E_MD2_ABM12 MD2_Uvcc_1 0 VALUE { V(1)-v(3) }
C_MD2_Uvcc_c1 MD2_Uvcc_2 MD2_Uvcc_3 10n
C_MD2_Uvcc_c2 MD2_Uvcc_4 MD2_Uvcc_2 10n
S_MD2_Uvcc_P MD2_Uvcc_3 MD2_Uvcc_2 MD2_Nand_1 0 _MD2_Uvcc_P
RS_MD2_Uvcc_P MD2_Nand_1 0 1G
.MODEL _MD2_Uvcc_P VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD2_Uvcc_N MD2_Uvcc_2 MD2_Uvcc_4 MD2_Nand_1 0 _MD2_Uvcc_N
RS_MD2_Uvcc_N MD2_Nand_1 0 1G
.MODEL _MD2_Uvcc_N VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
X_MD2_Uvcc_Comp MD2_Uvcc_1 MD2_Uvcc_2 MD2_Nand_1 COMP
C_MD2_Uvcc_c3 0 MD2_Nand_1 10p
E_MD2_Uvcc_ABM2 MD2_Uvcc_3 0 VALUE { 8.6 }
E_MD2_Uvcc_ABM3 MD2_Uvcc_4 0 VALUE { 8.2 }
S_MD2_Nand_P1 MD2_Nand_5 MD2_Nand_3 MD2_Nand_2 0 _MD2_Nand_P1
RS_MD2_Nand_P1 MD2_Nand_2 0 1G
.MODEL _MD2_Nand_P1 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD2_Nand_N1 MD2_Nand_3 MD2_Nand_4 MD2_Nand_1 0 _MD2_Nand_N1
RS_MD2_Nand_N1 MD2_Nand_1 0 1G
.MODEL _MD2_Nand_N1 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
S_MD2_Nand_P2 MD2_Nand_5 MD2_Nand_3 MD2_Nand_1 0 _MD2_Nand_P2
RS_MD2_Nand_P2 MD2_Nand_1 0 1G
.MODEL _MD2_Nand_P2 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
V_MD2_Nand_V MD2_Nand_5 0 5V
S_MD2_Nand_N2 MD2_Nand_4 0 MD2_Nand_2 0 _MD2_Nand_N2
RS_MD2_Nand_N2 MD2_Nand_2 0 1G
.MODEL _MD2_Nand_N2 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
C_MD2_c1 0 MD2_Nand_3 10p
C_MD2_c2 0 MD3_DlyHS_2 10p
C_MD3_C1 0 MD4_RS_2 10p
E_MD3_ABM12 MD3_DlyHS_1 0 VALUE { V(1)-v(3) }
E_MD3_DlyHS_Turn_On_Vth MD3_DlyHS_3 0 VALUE { (5* EXP(-( {tonT1}+(
+ {tonT3}-{tonT1})/({T3}-{T1})*(TEMP-{T1})) /10/ 10n))/(5* EXP(-( {tonT1}+(
+ {tonT3}-{tonT1})/({T3}-{T1})*({T2}-{T1})) /10/ 10n))*5*EXP(-{tonT2}/10/10n)*
+ (EXP(-({tonV1}+({tonV3}-{tonV1})/({V3}-{V1})*(V(MD3_DlyHS_1)-
+ {V1}))/10/10n))/((EXP(-( {tonV1}+({tonV3}-{tonV1})/({V3}-{V1})*({V2}-
+ {V1}))/10/10n))) }
E_MD3_DlyHS_Turn_Off_Vth MD3_DlyHS_5 0 VALUE { (5-5* EXP(-( {toffT1}+(
+ {toffT3}-{toffT1})/({T3}-{T1})*(TEMP-{T1}))/10/10n))/(5-5* EXP(-( {toffT1}+(
+ {toffT3}-{toffT1})/({T3}-{T1})*({T2}-{T1}))/10/10n))*(5-5*EXP(-
+ {toffT2}/10/10n))*(1-EXP(-( {toffV1}+({toffV3}-{toffV1})/({V3}-
+ {V1})*(V(MD3_DlyHS_1)-{V1})) /10/ 10n))/(1-EXP(-( {toffV1}+({toffV3}-
+ {toffV1})/({V3}-{V1})*({V2}-{V1})) /10/ 10n)) }
C_MD3_DlyHS_C 0 MD3_DlyHS_4 10n
S_MD3_DlyHS_P1 MD3_DlyHS_11 MD3_DlyHS_12 MD3_DlyHS_7 0 _MD3_DlyHS_P1
RS_MD3_DlyHS_P1 MD3_DlyHS_7 0 1G
.MODEL _MD3_DlyHS_P1 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD3_DlyHS_P2 MD3_DlyHS_12 MD3_DlyHS_10 MD4_RS_2 0 _MD3_DlyHS_P2
RS_MD3_DlyHS_P2 MD4_RS_2 0 1G
.MODEL _MD3_DlyHS_P2 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD3_DlyHS_N1 MD3_DlyHS_10 0 MD4_RS_2 0 _MD3_DlyHS_N1
RS_MD3_DlyHS_N1 MD4_RS_2 0 1G
.MODEL _MD3_DlyHS_N1 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
S_MD3_DlyHS_MN1 MD4_RS_2 0 MD3_DlyHS_8 0 _MD3_DlyHS_MN1
RS_MD3_DlyHS_MN1 MD3_DlyHS_8 0 1G
.MODEL _MD3_DlyHS_MN1 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
S_MD3_DlyHS_MP2 MD3_DlyHS_14 MD4_RS_2 MD3_DlyHS_8 0 _MD3_DlyHS_MP2
RS_MD3_DlyHS_MP2 MD3_DlyHS_8 0 1G
.MODEL _MD3_DlyHS_MP2 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD3_DlyHS_MP1 MD3_DlyHS_13 MD3_DlyHS_14 MD3_DlyHS_10 0 _MD3_DlyHS_MP1
RS_MD3_DlyHS_MP1 MD3_DlyHS_10 0 1G
.MODEL _MD3_DlyHS_MP1 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD3_DlyHS_delay_P MD3_DlyHS_6 MD3_DlyHS_4 MD3_DlyHS_2 0
+ _MD3_DlyHS_delay_P
RS_MD3_DlyHS_delay_P MD3_DlyHS_2 0 1G
.MODEL _MD3_DlyHS_delay_P VSWITCH Roff=1e6 Ron=10 Voff=5V Von=0V
S_MD3_DlyHS_delay_N MD3_DlyHS_4 0 MD3_DlyHS_2 0 _MD3_DlyHS_delay_N
RS_MD3_DlyHS_delay_N MD3_DlyHS_2 0 1G
.MODEL _MD3_DlyHS_delay_N VSWITCH Roff=1e6 Ron=10 Voff=0V Von=5V
X_MD3_DlyHS_Comp2 MD3_DlyHS_4 MD3_DlyHS_5 MD3_DlyHS_8 COMP
X_MD3_DlyHS_Comp1 MD3_DlyHS_3 MD3_DlyHS_4 MD3_DlyHS_7 COMP
S_MD3_DlyHS_N2 MD3_DlyHS_10 0 MD3_DlyHS_7 0 _MD3_DlyHS_N2
RS_MD3_DlyHS_N2 MD3_DlyHS_7 0 1G
.MODEL _MD3_DlyHS_N2 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
S_MD3_DlyHS_MN2 MD4_RS_2 0 MD3_DlyHS_10 0 _MD3_DlyHS_MN2
RS_MD3_DlyHS_MN2 MD3_DlyHS_10 0 1G
.MODEL _MD3_DlyHS_MN2 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
V_MD3_DlyHS_V0 MD3_DlyHS_6 0 5V
C_MD3_DlyHS_C3 0 MD3_DlyHS_7 10p
V_MD3_DlyHS_V1 MD3_DlyHS_11 0 5V
C_MD3_DlyHS_C6 0 MD3_DlyHS_10 10p IC=-5V
V_MD3_DlyHS_V2 MD3_DlyHS_13 0 5V
C_MD3_DlyHS_C4 0 MD3_DlyHS_8 10p
C_MD3_DlyHS_C5 0 MD4_RS_2 10p IC=0V
D_MD4_D5 3 6 DIODE625
D_MD4_D4 3 4 DIODE625
R_MD4_R 6 4 300k
S_MD4_Inv1_N MD4_Inv1_3 0 MD4_RS_2 0 _MD4_Inv1_N
RS_MD4_Inv1_N MD4_RS_2 0 1G
.MODEL _MD4_Inv1_N VSWITCH Roff=1e6 Ron=1 Voff=0v Von=5v
S_MD4_Inv1_P MD4_Inv1_2 MD4_Inv1_3 MD4_RS_2 0 _MD4_Inv1_P
RS_MD4_Inv1_P MD4_RS_2 0 1G
.MODEL _MD4_Inv1_P VSWITCH Roff=1e6 Ron=1 Voff=5v Von=0v
V_MD4_Inv1_V MD4_Inv1_2 0 5V
R_MD4_Inv1_R MD4_Nor_1 MD4_Inv1_3 1
C_MD4_Inv1_C 0 MD4_Nor_1 10p
S_MD4_Nor_P1 MD4_Nor_3 MD4_Nor_4 MD4_Nor_1 0 _MD4_Nor_P1
RS_MD4_Nor_P1 MD4_Nor_1 0 1G
.MODEL _MD4_Nor_P1 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD4_Nor_P2 MD4_Nor_4 MD4_Inv2_1 MD4_Nor_2 0 _MD4_Nor_P2
RS_MD4_Nor_P2 MD4_Nor_2 0 1G
.MODEL _MD4_Nor_P2 VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD4_Nor_N1 MD4_Inv2_1 0 MD4_Nor_2 0 _MD4_Nor_N1
RS_MD4_Nor_N1 MD4_Nor_2 0 1G
.MODEL _MD4_Nor_N1 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
S_MD4_Nor_N2 MD4_Inv2_1 0 MD4_Nor_1 0 _MD4_Nor_N2
RS_MD4_Nor_N2 MD4_Nor_1 0 1G
.MODEL _MD4_Nor_N2 VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
V_MD4_Nor_V MD4_Nor_3 0 5V
C_MD4_Uvbs_c1 MD4_Uvbs_4 MD4_Uvbs_5 10n
C_MD4_Uvbs_c2 MD4_Uvbs_6 MD4_Uvbs_4 10n
X_MD4_Uvbs_Comp 4 MD4_Uvbs_4 MD4_Inv3_1 COMP
S_MD4_Uvbs_P MD4_Uvbs_5 MD4_Uvbs_4 MD4_Inv3_1 0 _MD4_Uvbs_P
RS_MD4_Uvbs_P MD4_Inv3_1 0 1G
.MODEL _MD4_Uvbs_P VSWITCH Roff=1e6 Ron=1 Voff=5V Von=0V
S_MD4_Uvbs_N MD4_Uvbs_4 MD4_Uvbs_6 MD4_Inv3_1 0 _MD4_Uvbs_N
RS_MD4_Uvbs_N MD4_Inv3_1 0 1G
.MODEL _MD4_Uvbs_N VSWITCH Roff=1e6 Ron=1 Voff=0V Von=5V
E_MD4_Uvbs_ABM18 MD4_Uvbs_5 0 VALUE { V(6)+8.6+V(3) }
E_MD4_Uvbs_ABM19 MD4_Uvbs_6 0 VALUE { V(6)+8.2+V(3) }
C_MD4_Uvbs_c3 0 MD4_Inv3_1 10p
S_MD4_Inv2_N MD4_Inv2_3 0 MD4_Inv2_1 0 _MD4_Inv2_N
RS_MD4_Inv2_N MD4_Inv2_1 0 1G
.MODEL _MD4_Inv2_N VSWITCH Roff=1e6 Ron=1 Voff=0v Von=5v
S_MD4_Inv2_P MD4_Inv2_2 MD4_Inv2_3 MD4_Inv2_1 0 _MD4_Inv2_P
RS_MD4_Inv2_P MD4_Inv2_1 0 1G
.MODEL _MD4_Inv2_P VSWITCH Roff=1e6 Ron=1 Voff=5v Von=0v
V_MD4_Inv2_V MD4_Inv2_2 0 5V
R_MD4_Inv2_R MD4_RS_1 MD4_Inv2_3 1
C_MD4_Inv2_C 0 MD4_RS_1 10p
S_MD4_Inv3_N MD4_Inv3_3 0 MD4_Inv3_1 0 _MD4_Inv3_N
RS_MD4_Inv3_N MD4_Inv3_1 0 1G
.MODEL _MD4_Inv3_N VSWITCH Roff=1e6 Ron=1 Voff=0v Von=5v
S_MD4_Inv3_P MD4_Inv3_2 MD4_Inv3_3 MD4_Inv3_1 0 _MD4_Inv3_P
RS_MD4_Inv3_P MD4_Inv3_1 0 1G
.MODEL _MD4_Inv3_P VSWITCH Roff=1e6 Ron=1 Voff=5v Von=0v
V_MD4_Inv3_V MD4_Inv3_2 0 5V
R_MD4_Inv3_R MD4_Nor_2 MD4_Inv3_3 1
C_MD4_Inv3_C 0 MD4_Nor_2 10p
D_MD4_D3 6 4 DIODE25
D_MD4_D2 6 MD4_11 DIODE25
D_MD4_D1 MD4_12 4 DIODE25
R_MD4_R1 MD4_11 5 1.0
R_MD4_R2 MD4_12 5 1.0
S_MD4_RS_P1 MD4_RS_5 MD4_RS_6 MD4_RS_1 0 _MD4_RS_P1
RS_MD4_RS_P1 MD4_RS_1 0 1G
.MODEL _MD4_RS_P1 VSWITCH Roff=1e6 Ron=1m Voff=5V Von=0V
S_MD4_RS_P2 MD4_RS_6 MD4_Inv4_1 MD4_RS_3 0 _MD4_RS_P2
RS_MD4_RS_P2 MD4_RS_3 0 1G
.MODEL _MD4_RS_P2 VSWITCH Roff=1e6 Ron=1m Voff=5V Von=0V
S_MD4_RS_N1 MD4_Inv4_1 0 MD4_RS_3 0 _MD4_RS_N1
RS_MD4_RS_N1 MD4_RS_3 0 1G
.MODEL _MD4_RS_N1 VSWITCH Roff=1e8 Ron=1m Voff=0V Von=5V
S_MD4_RS_N2 MD4_Inv4_1 0 MD4_RS_1 0 _MD4_RS_N2
RS_MD4_RS_N2 MD4_RS_1 0 1G
.MODEL _MD4_RS_N2 VSWITCH Roff=1e8 Ron=1m Voff=0V Von=5V
S_MD4_RS_N3 MD4_RS_3 0 MD4_RS_2 0 _MD4_RS_N3
RS_MD4_RS_N3 MD4_RS_2 0 1G
.MODEL _MD4_RS_N3 VSWITCH Roff=1e8 Ron=1m Voff=0V Von=5V
S_MD4_RS_N4 MD4_RS_3 0 MD4_Inv4_1 0 _MD4_RS_N4
RS_MD4_RS_N4 MD4_Inv4_1 0 1G
.MODEL _MD4_RS_N4 VSWITCH Roff=1e8 Ron=1m Voff=0V Von=5V
C_MD4_RS_C7 MD4_RS_6 MD4_RS_5 10p
S_MD4_RS_P4 MD4_RS_7 MD4_RS_3 MD4_Inv4_1 0 _MD4_RS_P4
RS_MD4_RS_P4 MD4_Inv4_1 0 1G
.MODEL _MD4_RS_P4 VSWITCH Roff=1e6 Ron=1m Voff=5V Von=0V
S_MD4_RS_P3 MD4_RS_5 MD4_RS_7 MD4_RS_2 0 _MD4_RS_P3
RS_MD4_RS_P3 MD4_RS_2 0 1G
.MODEL _MD4_RS_P3 VSWITCH Roff=1e6 Ron=1m Voff=5V Von=0V
C_MD4_RS_C2 0 MD4_RS_1 10p IC=0
C_MD4_RS_C3 0 MD4_RS_2 10p IC=0
C_MD4_RS_C10 MD4_RS_7 MD4_RS_5 10p
C_MD4_RS_C11 MD4_RS_3 MD4_RS_7 10p
C_MD4_RS_C12 0 MD4_RS_3 10p
C_MD4_RS_C9 0 MD4_Inv4_1 10p
C_MD4_RS_C8 MD4_Inv4_1 MD4_RS_6 10p
C_MD4_RS_C1 0 MD4_Inv4_1 10p IC=0
V_MD4_RS_V1 MD4_RS_5 0 5V
C_MD4_C1 6 5 10p IC=0
S_MD4_Inv4_N MD4_Inv4_3 0 MD4_Inv4_1 0 _MD4_Inv4_N
RS_MD4_Inv4_N MD4_Inv4_1 0 1G
.MODEL _MD4_Inv4_N VSWITCH Roff=1e6 Ron=1 Voff=0v Von=5v
S_MD4_Inv4_P MD4_Inv4_2 MD4_Inv4_3 MD4_Inv4_1 0 _MD4_Inv4_P
RS_MD4_Inv4_P MD4_Inv4_1 0 1G
.MODEL _MD4_Inv4_P VSWITCH Roff=1e6 Ron=1 Voff=5v Von=0v
V_MD4_Inv4_V MD4_Inv4_2 0 5V
R_MD4_Inv4_R MD4_OHS_1 MD4_Inv4_3 1
C_MD4_Inv4_C 0 MD4_OHS_1 10p
S_MD4_OHS_P 4 MD4_OHS_2 MD4_OHS_1 0 _MD4_OHS_P
RS_MD4_OHS_P MD4_OHS_1 0 1G
.MODEL _MD4_OHS_P VSWITCH Roff=5e8 Ron=100m Voff=4.99 Von=0.01
S_MD4_OHS_N MD4_OHS_3 6 MD4_OHS_1 0 _MD4_OHS_N
RS_MD4_OHS_N MD4_OHS_1 0 1G
.MODEL _MD4_OHS_N VSWITCH Roff=5e8 Ron=100m Voff=0.01 Von=4.99
R_MD4_OHS_R1 5 MD4_OHS_2 36.4
R_MD4_OHS_R2 MD4_OHS_3 5 18.2
.ENDS IR2117

.SUBCKT COMP 1 2 3
E1 4 0 VALUE={IF((V(1)>V(2)), 5V, 0)}
R1 4 3 1
C1 3 0 10P
.ENDS



I get these errors on the bolded line above:


Class Document Source Message Time Date No.

[Error] Syntax error. 3:20:23 PM 2/1/2012 37
[Error] Error parsing expression. 3:20:23 PM 2/1/2012 38
[Error] Error on line 386: e1\x_md4_uvbs_comp\xu2 4\x_md4_uvbs_comp\xu2 0 value={if((v(netc4_2)>v(md4_uvbs_4\xu2)), 5v, 0)} 3:20:23 PM 2/1/2012 39

 

[dselec]

**********************************************************************
*
* Copyright (c) International Rectifier
*
* IR2117: Single Channel Driver
*
* sorry my mistake
if u are using ltspice 4 from linear technology the file looks like this xyz.asc
send me the same format to my email:dselec@orange.net.il this site does not enable sending files

 

[dselec]

View attachment ATT00127.txt

**********************************************************************
*
* Copyright (c) International Rectifier
*
* IR2117: Single Channel Driver
*
* sorry my mistake
if u are using ltspice 4 from linear technology the file looks like this xyz.asc
send me the same format to my email:dselec@orange.net.il this site does not enable sending files
ok bit complicated you-need to zip your file......like this example= " ir2117.zip"

 

[sp3twg]

I'm not using LTSpice I'm using Altium

 

[keith1200rs]

I don't have Altium documentation but if you have then you need to look up the syntax for the voltage controlled voltage source, the IF statement and how voltages should be represented in statements. The various versions of SPICE often have slight differences in those areas.

Keith

 

[dselec]

Looks just like ltspice
I like to learn new programs .
tell me which version u using, is it free ware and send me the file .
try out ltspice 4 for free is incredible.

 

[keith1200rs]

All SPICE netlists "look" similar but here are plenty of minor differences which mean one model doesn't work on a different simulator without some tweaking. Hspice tends to be a common "standard" and Pspice has some differences. I am guessing Altium uses a variant of Pspice.

Keith

 

[dselec]

Well we cant help unless u tell us which altium software u using and sent us the file