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Update to the examples for osdi

pre-master-46
Holger Vogt 3 years ago
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62 changed files with 185689 additions and 0 deletions
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  1. 75
      examples/osdi/EKV2.6/Modelcards/ekv26_0u15.par
  2. 157
      examples/osdi/EKV2.6/Modelcards/ekv26_0u5.par
  3. 41
      examples/osdi/EKV2.6/ekv26_inverter.sp
  4. 922
      examples/osdi/EKV2.6/ekv26_mod.va
  5. 27
      examples/osdi/EKV2.6/netlist_mod_nmos.sp
  6. 28
      examples/osdi/EKV2.6/netlist_mod_pmos.sp
  7. 1
      examples/osdi/EKV2.6/test_osdi_win/README
  8. 59
      examples/osdi/README
  9. 641
      examples/osdi/bsimbulk/Modelcards/model.l
  10. 40
      examples/osdi/bsimbulk/bsimbulk_inverter.sp
  11. 41
      examples/osdi/bsimbulk/bsimbulk_ro.sp
  12. 89241
      examples/osdi/bsimbulk/c7552_ann_bsimbulk.net
  13. 27
      examples/osdi/bsimbulk/netlist_mod_nmos.sp
  14. 29
      examples/osdi/bsimbulk/netlist_mod_pmos.sp
  15. 45
      examples/osdi/bsimbulk/nmos_pmos_BSIMBULK.sp
  16. 1
      examples/osdi/bsimbulk/test_osdi_win/README
  17. 137
      examples/osdi/bsimcmg/Modelcards/modelcard.nmos
  18. 138
      examples/osdi/bsimcmg/Modelcards/modelcard.pmos
  19. 38
      examples/osdi/bsimcmg/inverter_ro.sp
  20. 36
      examples/osdi/bsimcmg/inverter_transient.sp
  21. 28
      examples/osdi/bsimcmg/netlist_nmos.sp
  22. 28
      examples/osdi/bsimcmg/netlist_pmos.sp
  23. 54
      examples/osdi/bsimcmg/ringosc_17stg.sp
  24. 27
      examples/osdi/bsimcmg/simple_inverter_dc.sp
  25. 1
      examples/osdi/bsimcmg/test_osdi_win/README
  26. 43
      examples/osdi/hicuml0/DFF_Y_ECL_HICUM.sp
  27. 59
      examples/osdi/hicuml0/DFF_Y_ECL_VBIC.sp
  28. 46
      examples/osdi/hicuml0/ECL-RO-5.cir
  29. 25
      examples/osdi/hicuml0/ECL-RO.cir
  30. 303
      examples/osdi/hicuml0/KiCad/ECL-RO.kicad_pro
  31. 1473
      examples/osdi/hicuml0/KiCad/ECL-RO.kicad_sch
  32. 107
      examples/osdi/hicuml0/KiCad/ECL_Bip.kicad_sym
  33. 3
      examples/osdi/hicuml0/KiCad/sym-lib-table
  34. 40
      examples/osdi/hicuml0/Modelcards/model-card-hicumL0V1p11_mod.lib
  35. 23
      examples/osdi/hicuml0/bip_subsmod.sp
  36. 20
      examples/osdi/hicuml0/hic0_gum.sp
  37. 20
      examples/osdi/hicuml0/hic0_out.sp
  38. 1
      examples/osdi/hicuml0/test_osdi_win/README
  39. 35
      examples/osdi/hicuml0/vbic_out.sp
  40. 76
      examples/osdi/mextram/Modelcards/mex_model.lib
  41. 18
      examples/osdi/mextram/mex_gum.sp
  42. 16
      examples/osdi/mextram/mex_out.sp
  43. 1
      examples/osdi/mextram/test_osdi_win/README
  44. 641
      examples/osdi/mixed-models/Modelcards/model.l
  45. 283
      examples/osdi/mixed-models/Modelcards/psp103_nmos-2.mod
  46. 283
      examples/osdi/mixed-models/Modelcards/psp103_pmos-2.mod
  47. 80
      examples/osdi/mixed-models/bb-psp_ro.sp
  48. 40
      examples/osdi/mixed-models/bsimbulk_inverter.sp
  49. 66
      examples/osdi/mixed-models/psp_inverter.sp
  50. 1
      examples/osdi/mixed-models/test_osdi_win/README
  51. 283
      examples/osdi/psp103/Modelcards/psp103_nmos-2.mod
  52. 283
      examples/osdi/psp103/Modelcards/psp103_pmos-2.mod
  53. 89240
      examples/osdi/psp103/c7552_ann_psp.net
  54. 70
      examples/osdi/psp103/nmos_pmos_PSP.sp
  55. 66
      examples/osdi/psp103/psp_inverter.sp
  56. 33
      examples/osdi/psp103/psp_out_nmos_nm.sp
  57. 33
      examples/osdi/psp103/psp_out_pmos_nm.sp
  58. 66
      examples/osdi/psp103/psp_ro.sp
  59. 32
      examples/osdi/psp103/psp_transfer.sp
  60. 1
      examples/osdi/psp103/test_osdi_win/README
  61. 16
      examples/osdi/r2_cmc/res_r2_cmc.cir
  62. 1
      examples/osdi/r2_cmc/test_osdi_win/README

75
examples/osdi/EKV2.6/Modelcards/ekv26_0u15.par
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@ -0,0 +1,75 @@
*** SPICE Models
*** Models created by Daniel Foty.
*** (c) 2001, Gilgamesh Associates and EPFL – All rights reserved.
*** These models are provided without warranty or support.
*** These models represent a completely fictitious 0.15um process, and do
*** NOT correspond to any real silicon process. They are provided expressly for
*** use in the examples provided in this text, and should not be used for any
*** real silicon product design.
*** NMOS EKV MOSFET Model ***************************************************
*** Level=44 in WinSPICE and ELDO, Level=55 in ADM/HSPICE, Level=5 in PSPICE,
*** Level=EKV in Spectre
*** Lmin=0.15u Wmin=1.05u (If Scale=0.15u then Lmin=1 and Wmin=7)
*—————
.MODEL nmos nmos
+ LEVEL=44
*** Setup Parameters
+ UPDATE=2.6
*** Process Related Model Parameters
+ COX=9.083E-3 XJ=0.15E-6
*** Intrinsic Model Parameters
+ VTO=0.4 GAMMA=0.71 PHI=0.97 KP=453E-6
+ E0=88.0E6 UCRIT=4.0E6
+ DL=-0.05E-6 DW=-0.02E-6
+ LAMBDA = 0.30 LETA=0.28 WETA=0
+ Q0=280E-6 LK=0.5E-6
*** Substrate Current Parameters
+ IBN=1.0 IBA=200E6 IBB=350E6
*** Intrinsic Model Temperature Parameters
+ TNOM=27.0 TCV=1.5E-3 BEX=-1.5 UCEX=1.7 IBBT=0
*** 1/f Noise Model Parameters
+ KF=1E-27 AF=1
*** Series Resistance and Area Calculation Parameters
+ HDIF=0.24e-6 ACM=3 RSH=5.0 RS=1250.526
+ RD=1250.526 LDIF=0.07e-6
*** Junction Current Parameters
+ JS=1.0E-6 JSW=5.0E-11 XTI=0 N=1.5
*** Junction Capacitances Parameters
+ CJ=1.0E-3 CJSW=2.0E-10 CJGATE=5.0E-10
+ MJ=0.5 MJSW=0.3 PB=0.9 PBSW=0.9 FC=0.5
*** Gate Overlap Capacitances
+ CGSO=3.0E-10 CGDO=3.0E-10 CGBO=3.0E-11
*** PMOS EKV MOSFET Model ***************************************************
*** Level=44 in WinSPICE and ELDO, Level=55 in ADM/HSPICE, Level=5 in PSPICE,
*** Level=EKV in Spectre
*** Lmin=0.15u Wmin=1.05u (If Scale=0.15u then Lmin=1 and Wmin=7)
*—————
.MODEL pmos pmos
+ LEVEL = 44
*** Setup Parameters
+ UPDATE = 2.6
*** Process Related Model Parameters
+ COX=9.083E-3 XJ=0.15E-6
*** Intrinsic Model Parameters
+ VTO=-0.4 GAMMA=0.69 PHI=0.87 KP=92.15E-6
+ E0=51.0E6 UCRIT=18.0E6
+ DL=-0.05E-6 DW=-0.03E-6
+ LAMBDA=1.1 LETA=0.45 WETA=0
+ Q0=200E-6 LK=0.6E-6
*** Substrate Current Parameters
+ IBN=1.0 IBA=0.0 IBB=300E6
*** Intrinsic Model Temperature Parameters
+ TNOM=25.0 TCV=-1.4E-3 BEX=-1.4 UCEX=2.0 IBBT=0.0
*** 1/f Noise Model Parameters
+ KF=1.0E-28 AF=1
*** Series Resistance and Area Calculation Parameters
+ HDIF=0.24E-6 ACM=3 RSH=5.0 RS=3145.263
+ RD=3145.263 LDIF=0.07e-6
*** Junction Current Parameters
+ JS=1.0E-7 JSW=5.0E-12 XTI=0 N=1.8
*** Junction Capacitances Parameters
+ CJ=1.3E-3 CJSW=2.5E-10 CJGATE=5.5E-10
+ MJ=0.5 MJSW=0.35 PB=0.9 PBSW=0.9 FC=0.5
*** Gate Overlap Capacitances
+ CGSO=3.2E-10 CGDO=3.2E-10 CGBO=3.0E-11

157
examples/osdi/EKV2.6/Modelcards/ekv26_0u5.par
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@ -0,0 +1,157 @@
**********************************************************************
* EKV v2.6 parameters for 0.5um CMOS C. EPFL-LEG, 1999
* ----------------------------------
*
* ELDO (LEVEL = 44) / PSPICE (LEVEL = 5) example parameter set
* for the EKV v2.6 model is provided for NMOS and PMOS.
*
*
* IMPORTANT NOTES:
* ----------------
*
* Parameters do not correspond to a particular technology but
* have reasonable values for standard 0.5um CMOS.
* Not intended for use in real design.
*
* Includes all intrinsic model parameters. An example set for
* extrinsic model parameters is provided.
*
* Geometry range: W >= 0.8um, L >= 0.5um
* Voltage range: |Vgb| < 3.3V, |Vdb| < 3.3V, |Vsb| < 2V
*
* For use with either simulator, comment/uncomment respective lines.
* Use of extrinsic model parameters and models (series resistance,
* junction currents/capacitances) is in general simulator-dependent.
*
**********************************************************************
* EKV v2.6 NMOS
*---------------
.MODEL NCH EKV_VA
*+ LEVEL = 44
*** Setup Parameters
*+ UPDATE = 2.6
*+ XQC = 0.4
+ TYPE = 1
*** Process Related Model Parameters
+ COX = 3.45E-3
+ XJ = 0.15E-6
*** Intrinsic Model Parameters
+ VTO = 0.6
+ GAMMA = 0.71
+ PHI = 0.97
+ KP = 150E-6
+ E0 = 88.0E6
+ UCRIT = 4.5E6
+ DL = -0.05E-6
+ DW = -0.02E-6
+ LAMBDA = 0.23
+ LETA = 0.28
+ WETA = 0.05
+ Q0 = 280E-6
+ LK = 0.5E-6
*** Substrate Current Parameters
+ IBN = 1.0
+ IBA = 200E6
+ IBB = 350E6
*** Intrinsic Model Temperature Parameters
+ TNOM = 25.0
+ TCV = 1.5E-3
+ BEX = -1.5
+ UCEX = 1.7
+ IBBT = 0.0
*** 1/f Noise Model Parameters
+ KF = 1E-27
+ AF = 1
*** Short-Distance Matching Statistical Parameters (for MC simulation only)
*+ AVTO = 0 DEV = 10.0E-3 ; ELDO v4.6
*+ AGAMMA = 0 DEV = 10.0E-3 ; ELDO v4.6
*+ AKP = 0 DEV = 25.0E-3 ; ELDO v4.6
*** Series Resistance and Area Calulation Parameters
*+ RLEV = 3
+ HDIF = 0.9E-6
+ RSH = 510
*** Junction Current Parameters
*+ ALEV = 3
+ JS = 8.0E-6
+ JSW = 1.5E-10
+ XTI = 0
+ N = 1.5
*** Junction Capacitances Parameters
+ CJ = 8.0E-4
+ CJSW = 3.0E-10
+ MJ = 0.5
+ MJSW = 0.3
+ PB = 0.9
+ PBSW = 0.5
+ FC = 0.5
*** Gate Overlap Capacitances
+ CGSO = 1.5E-10
+ CGDO = 1.5E-10
+ CGBO = 4.0E-10
* EKV v2.6 PMOS
*---------------
.MODEL PCH EKV_VA
*+ LEVEL = 44
*** Setup Parameters
*+ UPDATE = 2.6
*+ XQC = 0.4
+ TYPE = -1
*** Process Related Model Parameters
+ COX = 3.45E-3
+ XJ = 0.15E-6
*** Intrinsic Model Parameters
+ VTO = -0.55
+ GAMMA = 0.69
+ PHI = 0.87
+ KP = 35.0E-6
+ E0 = 51.0E6
+ UCRIT = 18.0E6
+ DL = -0.05E-6
+ DW = -0.03E-6
+ LAMBDA = 1.1
+ LETA = 0.45
+ WETA = 0.0
+ Q0 = 200E-6
+ LK = 0.6E-6
*** Substrate Current Parameters
+ IBN = 1.0
+ IBA = 10E6
+ IBB = 300E6
*** Intrinsic Model Temperature Parameters
+ TNOM = 25.0
+ TCV = -1.4E-3
+ BEX = -1.4
+ UCEX = 2.0
+ IBBT = 0.0
*** 1/f Noise Model Parameters
+ KF = 1.0E-28
+ AF = 1
*** Short-Distance Matching Statistical Parameters (for MC simulation only)
*+ AVTO = 0 DEV = 10.0E-3 ; ELDO v4.6
*+ AGAMMA = 0 DEV = 10.0E-3 ; ELDO v4.6
*+ AKP = 0 DEV = 25.0E-3 ; ELDO v4.6
*** Series Resistance and Area Calulation Parameters
*+ RLEV = 3
+ HDIF = 0.9E-6
+ RSH = 990
*** Junction Current Parameters
*+ ALEV = 3
+ JS = 4.0E-5
+ JSW = 7.0E-10
+ XTI = 0
+ N = 1.8
*** Junction Capacitances Parameters
+ CJ = 8.0E-4
+ CJSW = 4.0E-10
+ MJ = 0.5
+ MJSW = 0.35
+ PB = 0.9
+ PBSW = 0.8
+ FC = 0.5
*** Gate Overlap Capacitances
+ CGSO = 1.5E-10
+ CGDO = 1.5E-10
+ CGBO = 4.0E-10

41
examples/osdi/EKV2.6/ekv26_inverter.sp
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@ -0,0 +1,41 @@
* EKV 2.6
* simple inverter
.param Vcc = 1.8
* model definitions:
*.model .MODEL PCH EKV_VA type=-1
*.model .MODEL NCH EKV_VA type=1
.include Modelcards/ekv26_0u5.par
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss out not1
*Rout out 0 1k
.subckt not1 a vdd vss z
Np1 z a vdd vdd pch W=2u L=0.5u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
Nn1 z a vss vss nch W=1u L=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10ps 10ns
.dc V1 0 'vcc' 'vcc/100'
.control
pre_osdi test_osdi_win/ekv26_mod.osdi
run
*set nolegend
set xbrushwidth=3
plot in out
plot dc1.out
plot dc1.i(Vmeas)
rusage
.endc
.end

922
examples/osdi/EKV2.6/ekv26_mod.va
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@ -0,0 +1,922 @@
/*
EKV MOS model version 2.6 rev.15 with documentation at: http://ekv.epfl.ch
Matthias Bucher, Christophe Lallement, Christian Enz, Fabien Theodoloz, Francois Krummenacher
Electronics Laboratories, Swiss Federal Institute of Technology Lausanne, Switzerland
This Verilog-A was developed by Wladek Grabinski with modifications
by Tiburon Design Automation (www.tiburon-da.com).
This software has been provided pursuant to a License Agreement containing restrictions on its use.
It may not be copied or distributed in any form or medium, disclosed to third parties,
reverse engineered or used in any manner not provided for in said License Agreement
except with the prior written authorization.
Licensed under the Educational Community License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at http://opensource.org/licenses/ECL-2.0
Unless required by applicable law or agreed to in writing, software distributed under
the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND,
either express or implied. See the License for the specific language governing permissions
and limitations under the License.
$RCSfile: ekv.va,v $ $Revision: 1.9 $ $Date: 2003/12/17 01:20:10 $
$RCSfile: ekv.va,v $ $Revision: 2.6.15 $ $Date: 2020/05/29 11:50:10 $
*/
/*
`include "disciplines.vams"
`include "constants.vams"
`include "compact.vams"
*/
// Macros for the model/instance parameters
//
// MPRxx model parameter real
// MPIxx model parameter integer
// IPRxx instance parameter real
// IPIxx instance parameter integer
// ||
// cc closed lower bound, closed upper bound
// oo open lower bound, open upper bound
// co closed lower bound, open upper bound
// oc open lower bound, closed upper bound
// cz closed lower bound=0, open upper bound=inf
// oz open lower bound=0, open upper bound=inf
// nb no bounds
// ex no bounds with exclude
// sw switch(integer only, values 0=false and 1=true)
// ty switch(integer only, values -1=p-type and +1=n-type)
//
// IPM instance parameter mFactor(multiplicity, implicit for LRM 2.2)
// OPP operating point parameter, includes units and description for printing
`define OPP(nam,uni,des) (* units=uni, desc=des *) real nam;
`define OPM(nam,uni,des) (* units=uni, desc=des, multiplicity="multiply" *) real nam;
`define OPD(nam,uni,des) (* units=uni, desc=des, multiplicity="divide" *) real nam;
`define MPRnb(nam,def,uni, des) (* units=uni, desc=des *) parameter real nam=def;
`define MPRex(nam,def,uni,exc, des) (* units=uni, desc=des *) parameter real nam=def exclude exc;
`define MPRcc(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter real nam=def from[lwr:upr];
`define MPRoo(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter real nam=def from(lwr:upr);
`define MPRco(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter real nam=def from[lwr:upr);
`define MPRoc(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter real nam=def from(lwr:upr];
`define MPRcz(nam,def,uni, des) (* units=uni, desc=des *) parameter real nam=def from[ 0:inf);
`define MPRoz(nam,def,uni, des) (* units=uni, desc=des *) parameter real nam=def from( 0:inf);
`define MPInb(nam,def,uni, des) (* units=uni, desc=des *) parameter integer nam=def;
`define MPIex(nam,def,uni,exc, des) (* units=uni, desc=des *) parameter integer nam=def exclude exc;
`define MPIcc(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter integer nam=def from[lwr:upr];
`define MPIoo(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter integer nam=def from(lwr:upr);
`define MPIco(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter integer nam=def from[lwr:upr);
`define MPIoc(nam,def,uni,lwr,upr,des) (* units=uni, desc=des *) parameter integer nam=def from(lwr:upr];
`define MPIcz(nam,def,uni, des) (* units=uni, desc=des *) parameter integer nam=def from[ 0:inf);
`define MPIoz(nam,def,uni, des) (* units=uni, desc=des *) parameter integer nam=def from( 0:inf);
`define MPIsw(nam,def,uni, des) (* units=uni, desc=des *) parameter integer nam=def from[ 0: 1];
`define MPIty(nam,def,uni, des) (* units=uni, desc=des *) parameter integer nam=def from[ -1: 1] exclude 0;
`define IPRnb(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter real nam=def;
`define IPRex(nam,def,uni,exc, des) (* units=uni, type = "instance", desc=des *) parameter real nam=def exclude exc;
`define IPRcc(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from[lwr:upr];
`define IPRoo(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from(lwr:upr);
`define IPRco(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from[lwr:upr);
`define IPRoc(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from(lwr:upr];
`define IPRcz(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from[ 0:inf);
`define IPRoz(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter real nam=def from( 0:inf);
`define IPInb(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def;
`define IPIex(nam,def,uni,exc, des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def exclude exc;
`define IPIcc(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from[lwr:upr];
`define IPIoo(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from(lwr:upr);
`define IPIco(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from[lwr:upr);
`define IPIoc(nam,def,uni,lwr,upr,des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from(lwr:upr];
`define IPIcz(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from[ 0:inf);
`define IPIoz(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def from( 0:inf);
`define BPRco(nam, def, uni, lwr, upr, des) (* units = uni, type = "instance", desc = des *) parameter real nam = def from[lwr : upr);
`define BPRoz(nam, def, uni, des) (* units = uni, type = "instance", desc = des *) parameter real nam = def from(0.0 : inf);
`define BPRcz(nam, def, uni, des) (* units = uni, type = "instance", desc = des *) parameter real nam = def from[0.0 : inf);
`define BPIcc(nam, def, uni, lwr, upr, des) (* units = uni, type = "instance", desc = des *) parameter integer nam = def from[lwr : upr];
`define BPInb(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter integer nam=def;
`define BPRnb(nam,def,uni, des) (* units=uni, type = "instance", desc=des *) parameter real nam=def;
// includes: in case we do not want to include any other file [AB:040902]
// we can just add the following section in this file
// AB: i hope this may help our code to be easily transported
//----------------------------------------
// from disciplines.h we need:
// Electrical
// Current in amperes
nature Current
units = "A";
access = I;
idt_nature = Charge;
`ifdef CURRENT_ABSTOL
abstol = `CURRENT_ABSTOL;
`else
abstol = 1e-12;
`endif
endnature
// Charge in coulombs
nature Charge
units = "coul";
access = Q;
ddt_nature = Current;
`ifdef CHARGE_ABSTOL
abstol = `CHARGE_ABSTOL;
`else
abstol = 1e-14;
`endif
endnature
// Potential in volts
nature Voltage
units = "V";
access = V;
idt_nature = Flux;
`ifdef VOLTAGE_ABSTOL
abstol = `VOLTAGE_ABSTOL;
`else
abstol = 1e-6;
`endif
endnature
// Flux in Webers
nature Flux
units = "Wb";
access = Phi;
ddt_nature = Voltage;
`ifdef FLUX_ABSTOL
abstol = `FLUX_ABSTOL;
`else
abstol = 1e-9;
`endif
endnature
// Conservative discipline
discipline electrical
potential Voltage;
flow Current;
enddiscipline
// Signal flow disciplines
discipline voltage
potential Voltage;
enddiscipline
discipline current
potential Current;
enddiscipline
//from constants.h we need
`define C_EPSSIL 1.03594314e-10
`define C_EPSOX 34.5e-12
`define C_QE 1.602e-19
`define C_K 1.3807e-23
`define P_K 1.3806226e-23
`define P_EPS0 8.85418792394420013968e-12
`define P_CELSIUS0 273.15
`define POS_MIN 1.0E-6
`define SQRT2 1.4142135623730950488016887242097
`define ONE3RD 0.33333333333333333333333333333333
`define ONESQRT2 0.70710678118654752440084436210485
//if any other constant is needed it may be copied from the constants.h and be put above.
//------------------------------------------ end of includes
`define FWD 1
`define REV -1
// AB 040902
`define NOT_GIVEN -1.0e21
`define DEFAULT_TNOM 25
module ekv_va(d,g,s,b);
// %%DEVICE_CLASS=MOS(NMOS:TYPE=1,PMOS:TYPE=-1)%%
// Node definitions
inout d,g,s,b; // external nodes
electrical d,g,s,b; // external nodes
// Branch definitions
branch (d,s) ds;
branch (d,b) db;
branch (s,b) sb;
branch (g,b) gb;
// * Local variables
real tmp1, tmp2, tmp3; // temporary variables
real VGprime, GAMMAprime;// short and narrow channel effect
real VP, VPprime; // pinch-off voltage
real if_, ir, irprime; // normalized currents
real VDSS, VDSSprime;// saturation voltage
real deltaL, Leq; // channel length reduction
real beta; // transconductance factor
real n; // slope factor
real Ispec; // specific current
real Vt; // k*T/q
real gm, gms, gmbs, gds;
real isub, Isub;
real inv_Vt, Vt_01, Vt_2, Vt_4, Vt_Vt, Vt_Vt_2, Vt_Vt_16;
real eps_COX, eps_COX_W, eps_COX_L;
real Lc, Lc_LAMBDA, IBN_2, T0, T1, eta_qi;
real inv_UCRIT, Lc_UCRIT, Lc_IBB, IBA_IBB;
integer Mode;
real WETA_W, LETA_L;
real E0_Q_1, AWL;
real T, KP_Weff;
real Eg, refEg, deltaT, ratioT, Tnom;
real VTO_T, VTO_S, KP_T, UCRIT_T, IBB_T, PHI_T, GAMMA_S;
real sqrt_Lprime_Lmin;
real GAMMAstar, sqrt_GAMMAstar;
real big_sqrt_VP;
real big_sqrt_VP0, VP0;
real PHI_VD, PHI_VS;
real sqrt_PHI;
real sqrt_PHI_VP, sqrt_PHI_VD, sqrt_PHI_VS;
real sqrt_PHI_VD_Vt, sqrt_PHI_VS_Vt;
real Vds, deltaV_2, Vip;
real VDSS_sqrt, sqrt_VDSS_deltaV, sqrt_Vds_VDSS_deltaV;
real VDSSprime_sqrt, sqrt_VDSSprime_deltaV, sqrt_Vds_VDSSprime_deltaV;
real if_ir;
real sqrt_if, sqrt_ir, sqrt_irprime;
real dif_dv, dir_dv, dirprime_dv;
// Charge related variables
real sif, sir, sif2, sir2, sif3, sir3;
real sif_sir_2;
real qi, qb;
real QD, QS, QI, QB, QG;
real VP_PHI_eps, sqrt_PHI_VP_2, WLCox;
real n_Vt_COX, n_1, n_1_n;
// Variables used for derivatives computation
real dVP_dVD, dVP_dVG, dVP_dVS;
real dif_dVD, dif_dVS, dif_dVG;
real dir_dVD, dir_dVS, dir_dVG;
real dVDSS_dVD, dVDSS_dVG, dVDSS_dVS;
real ddeltaV_dVD, ddeltaV_dVG, ddeltaV_dVS;
real dVip_dVD, dVip_dVG, dVip_dVS;
real dVDSSprime_dVD, dVDSSprime_dVG, dVDSSprime_dVS;
real dirprime_dVD, dirprime_dVG, dirprime_dVS;
real dLeq_dVD, dLeq_dVG, dLeq_dVS;
real dbeta_dVD, dbeta_dVG, dbeta_dVS;
real VGstar, sqrt_VGstar;
real VG, VD, VS;
real Von, Vdsat, Id, Ibd;
real Gn;
real GAMMA_sqrt_PHI, Lmin, Lprime, T0_GAMMA_1, THETA_VP_1, Vc;
real Vdsprime, Vt_Vc, dGAMMAprime_dVD, dGAMMAprime_dVG, dGAMMAprime_dVS;
real dVPprime_dVD, dVPprime_dVG, dVPprime_dVS, ddeltaL_dVD, ddeltaL_dVG;
real ddeltaL_dVS, dn_dVD, dn_dVG, dn_dVS;
real log_Vc_Vt, sqrt_PHI_VP0, sqrt_VP_Vt;
real Lc_IBB_Vib, Vib, dIsub_factor, exp_ib;
real inv_Vib, sqrt_PHI_VP2_2;
real V0, deltaVFB, vL;
real dQI_dVD, dQI_dVS, dQI_dVG;
real dQB_dVD, dQB_dVS, dQB_dVG;
real Leff, Weff;
real RSeff, RDeff;
real yk, z0, zk;
real EPSOX, epssil;
real ddt_QD, ddt_QS;
//DIODES realted variables [AB: 040902]
real as_i, ad_i, ps_i, pd_i, v_di_b, v_si_b;
real temp_arg, tmp0;
real js_t, jsw_t, jswg_t;
real pb_t, pbsw_t, pbswg_t;
real cj_t, cjsw_t, cjswg_t;
real njts_t, njtssw_t, njtsswg_t;
real is_d, arg_d, is_s, arg_s;
real f_breakdown_d, f_breakdown_s, idb_tun, isb_tun;
real csb_d, cssw_d, csswg_d;
real csb_s, cssw_s, csswg_s;
real qjd, qjs;
// parameter definitions
parameter integer TYPE = 1 from [-1:1] exclude 0; // NMOS=1, PMOS=-1
parameter integer Noise = 1 from [0:1]; // Set to zero to prevent noise calculation
parameter real Trise = 0.0 from [-inf:inf]; // Difference sim. temp and device temp [C deg]
// parameter real Temp = -`NOT_GIVEN from [`P_CELSIUS0:inf]; // Device temp [C]
//AB: the parameter name Temp is not working for no obvious reason; changed to TEMP
parameter real TEMP = -`NOT_GIVEN from [`P_CELSIUS0:inf]; // Device temp [C]
parameter real TNOM = -`NOT_GIVEN; // Temperature [C]
// Instance parameters
// - intrinsic model
`IPRoz( L ,1.0e-5 ,"m" ,"Length" )
`IPRoz( W ,1.0e-5 ,"m" ,"Total width including fingers" )
`IPIco( M ,1 ,"" ,1 ,inf ,"Parallel multiplier" )
`IPIco( NS ,1 ,"" ,1 ,inf ,"Series multiplier" )
`BPRnb( DTEMP ,0.0 ,"K" ,"Offset of device temperature" )
// - external parasitics
`IPRcz( AS ,0.0 ,"m^2" ,"Source-to-substrate junction area" )
`IPRcz( AD ,0.0 ,"m^2" ,"Drain-to-substrate junction area" )
`IPRcz( PS ,0.0 ,"m" ,"Source-to-substrate junction perimeter" )
`IPRcz( PD ,0.0 ,"m" ,"Drain-to-substrate junction perimeter" )
`IPRcz( NRS ,1.0 ,"" ,"Number of squares in source" )
`IPRcz( NRD ,1.0 ,"" ,"Number of squares in drain" )
// *** Process related parameters
parameter real COX = 2.0E-3 from [0.0:inf]; // Gate oxide capacitance per unit area [F]
parameter real XJ = 300E-9 from [0.0:inf]; // Junction depth [m]
//*** Threshold voltage/substrate effect parameters (long-channel)
parameter real VTO = 0.5 from [-inf:inf]; // Long-channel threshold voltage [V]
parameter real TCV = 1.0e-3; // Threshold voltage temperature coefficient [V/K]
parameter real GAMMA = 0.7 from [0.0:inf]; // Body effect parameter
parameter real PHI = 0.5 from [0.2:inf]; // Bulk Fermi potential [V]
//*** Mobility parameters (long-channel) ***
parameter real KP = 150E-6 from [0.0:inf]; // Transconductance parameter [A/V/V]
parameter real BEX = -1.5; // Mobility temperature exponent
parameter real THETA = 0.0 from [0.0:inf]; // Mobility reduction coefficient [1/V]
parameter real E0 = 1.0E8; // Mobility reduction coefficient [V/m]
//*** Velocity sat./channel length mod. parameters (short-channel)
parameter real UCRIT = 2.0E6 from [0.0:inf]; // Longitudinal critical field [V/m]
parameter real UCEX = 0.8; // Longitudinal critical field temperature exponent
parameter real LAMBDA = 0.8 from [0.0:inf]; // Depletion length coefficient (channel length modulation)
//*** Process related parameters
parameter real DL = -0.01E-6; // Channel width correction [m]
parameter real DW = -0.01E-6; // Channel length correction [m]
//*** Threshold voltage/substrate effect parameter (narrow-channel)
parameter real WETA = 0.2 from [0.0:inf]; // Narrow-channel effect coefficient
//*** Threshold voltage/substrate effect parameters (short-channel)
parameter real LETA = 0.3 from [0.0:inf]; // Short-channel effect coefficient
parameter real Q0 = 230E-6 from [0.0:inf]; // Reverse short channel effect peak charge density
parameter real LK = 0.4E-6 from [0.0:inf]; // Reverse short channel effect characteristic length [m]
//*** Substrate current parameters
parameter real IBA = 5.0E8 from [0.0:inf]; // First impact ionization coefficient [1/m]
parameter real IBB = 4.0E8 from [0.0:inf]; // Second impact ionization coefficient [V/m]
parameter real IBBT = 9.0e-4; // Temperature coefficient for IBB [1/K]
parameter real IBN = 1.0 from [0.0:inf]; // Saturation voltage factor for impact ionization
//*** Series resistance parameters
parameter real RSH = 0.0 from [0.0:inf]; // Sheet resistance [Ohms]
parameter real HDIF = 0.5E-6 from [0.0:inf]; // Sheet resistance multipler
//*** for MC analysis fk 25/05/97
parameter real AVTO = 1E-6 from [0.0:inf]; // Area related threshold voltage mismatch parameter [Vm]
parameter real AKP = 1E-6 from [0.0:inf]; // Area related gain mismatch parameter [m]
parameter real AGAMMA = 1E-6 from [0.0:inf]; // Area related body effect mismatch parameter [sqr(V) m]
parameter real AF = 1.0 from (0:inf); // Flicker noise exponent
parameter real KF = 0.0 from [0:inf); // Flicker noise coefficient
//*** JUNCTION DRAIN-BULK AND SOURCE-BULK AREA, CURRENT, CAPACITANCE [AB:040902]
parameter real xd_n = 1.0 from [0.0:inf);
parameter real xd_js = 1.0E-09 from [0.0:inf);
parameter real xd_jsw = 1.0E-12 from [0.0:inf);
parameter real xd_jswg = 1.0E-12 from [0.0:inf);
parameter real xd_mj = 0.900 from [0.0:1.0];
parameter real xd_mjsw = 0.700 from [0.0:1.0];
parameter real xd_mjswg = 0.700 from [0.0:1.0];
parameter real xd_pb = 0.800 from (0.0:inf);
parameter real xd_pbsw = 0.600 from (0.0:inf);
parameter real xd_pbswg = 0.600 from (0.0:inf);
parameter real xd_cj = 1.0E-09 from [0.0:inf);
parameter real xd_cjsw = 1.0E-12 from [0.0:inf);
parameter real xd_cjswg = 1.0E-12 from [0.0:inf);
parameter real xd_gmin = 0.0 from [0.0:inf);
parameter real xd_xjbv = 0.0 from [0.0:inf);
parameter real xd_bv = 10.0 from [0.0:inf);
parameter real xd_njts = 1.0 from [0.0:inf);
parameter real xd_njtssw = 1.0 from [0.0:inf);
parameter real xd_njtsswg = 1.0 from [0.0:inf);
parameter real xd_vts = 0.0 from [0.0:inf);
parameter real xd_vtssw = 0.0 from [0.0:inf);
parameter real xd_vtsswg = 0.0 from [0.0:inf);
parameter real tp_xti = 3.0 from (-inf:inf);
parameter real tp_cj = 0.0 from (-inf:inf);
parameter real tp_cjsw = 0.0 from (-inf:inf);
parameter real tp_cjswg = 0.0 from (-inf:inf);
parameter real tp_pb = 0.0 from (-inf:inf);
parameter real tp_pbsw = 0.0 from (-inf:inf);
parameter real tp_pbswg = 0.0 from (-inf:inf);
parameter real tp_njts = 0.0 from [0.0:inf);
parameter real tp_njtssw = 0.0 from [0.0:inf);
parameter real tp_njtsswg = 0.0 from [0.0:inf);
analog begin
// Set constant
EPSOX = 3.9 * `P_EPS0;
epssil = 11.7 * `P_EPS0;
Ibd = 0.0;
// The following are necessary to prevent memory states being reserved:
THETA_VP_1 = 0.0;
VPprime = 0.0;
sqrt_VP_Vt = 0.0;
// Geometry, voltage and temperature independent model variables
eps_COX = epssil/COX;
Lc = sqrt(eps_COX*XJ);
Lc_LAMBDA = Lc * LAMBDA;
eps_COX_W = 3.0 * eps_COX * WETA;
eps_COX_L = eps_COX * LETA;
IBN_2 = IBN + IBN;
T0 = COX / (epssil*E0);
V0 = (Q0+Q0) / COX;
eta_qi = TYPE > 0 ? 0.5 : 0.3333333333333;
/* Model working variables, geometry and voltage independent,
* which need to be updated after temperature change
* EKV model internal variables depending on temperature.
*/
/* If Temp is explicitly specified, use that value
otherwise use Tckt+Trise */
if (TEMP == -`NOT_GIVEN) //AB: 040902 Temp -> TEMP
T = $temperature + Trise;
else
T = TEMP + `P_CELSIUS0; //AB: 040902 Temp -> TEMP
if (TNOM == -`NOT_GIVEN)
Tnom = `DEFAULT_TNOM + `P_CELSIUS0;
else
Tnom = TNOM + `P_CELSIUS0;
Vt = $vt(T);
Vt_01 = 0.1 * Vt;
inv_Vt = 1.0 / Vt;
Vt_2 = Vt + Vt;
Vt_4 = Vt_2 + Vt_2;
Vt_Vt = Vt * Vt;
Vt_Vt_2 = Vt_Vt + Vt_Vt;
Vt_Vt_16 = 16.0 * Vt_Vt;
Eg = 1.16 - 7.02e-4 * T * T / (T + 1108.0);
refEg = 1.16 - (7.02e-4*Tnom*Tnom) / (Tnom + 1108.0);
deltaT = T - Tnom;
ratioT = T / Tnom;
VTO_T = VTO - TCV * deltaT;
KP_T = KP * pow(ratioT, BEX);
UCRIT_T = UCRIT * pow(ratioT, UCEX);
IBB_T = IBB * (1.0 + IBBT * deltaT);
PHI_T = PHI * ratioT - 3.0 * Vt * ln(ratioT) - refEg * ratioT + Eg;
// !! mb 99/07/30 prevents PHI from becoming smaller than 0.2
tmp1 = 0.2;
tmp2 = PHI_T - tmp1;
PHI_T = 0.5*(tmp2 + sqrt(tmp2*tmp2 + Vt*Vt)) + tmp1;
sqrt_PHI = sqrt(PHI_T);
inv_UCRIT = 1.0/UCRIT_T;
Lc_UCRIT = Lc * UCRIT_T;
Lc_IBB = Lc * IBB_T;
IBA_IBB = IBA / IBB_T;
/* VTO, KP and GAMMA with variation for MC analysis if required.
* The default value for model parameters AVTO, AKP and AGAMMA
* is set to 1e-6 to allow meaningful sensitivity analysis. Only
* the deviation from this value has to be taken into account
*/
// wg: for userc.c and verilog implementations
Leff = L + DL;
// wg: for userc.c and verilog implementations
Weff = W + DW;
Vc = UCRIT_T*Leff; // NOTE: use L if necessary
log_Vc_Vt = Vt*(ln(0.5*Vc*inv_Vt)-0.6); // mb 98/02/05 (r1)
// de-normalization
AWL = 1.0/sqrt(Weff*Leff);
if (TYPE > 0)
VTO_S = ((AVTO != 1e-6) ? AWL*(AVTO - 1e-6) + VTO_T : VTO_T);
else
VTO_S = ((AVTO != 1e-6) ? AWL*(1e-6 - AVTO) - VTO_T: -VTO_T);
KP_Weff = Weff * ((AKP != 1e-6) ? KP_T*(1 + (AKP - 1e-6)*AWL) : KP_T);
GAMMA_S = ((AGAMMA !=1e-6) ? GAMMA + (AGAMMA - 1e-6)*AWL : GAMMA);
GAMMA_sqrt_PHI = GAMMA_S*sqrt_PHI;
/* ************************************
* STATIC MODEL EQUATIONS
* *************************************/
// VGprime:
if (V0 == 0.0)
deltaVFB = 0.0;
// else begin : VGprime //AB: 040902 VGPrime is also a variable and
else begin : VGprime_block //AB: 040902 VGPrime -> VGprime_block
real sqv;
// mb 99/03/26 corrected for multiple device number
vL = 0.28 * (Leff/(LK*NS) - 0.1);
sqv = 1.0 / (1.0 + 0.5*(vL + sqrt(vL*vL + 1.936e-3)));
deltaVFB = V0 * sqv * sqv;
end
VG = TYPE * V(g,b); // wg 22/04/08 corrected for device TYPE
VS = TYPE * V(s,b);
VD = TYPE * V(d,b);
if (VD - VS < 0) begin
Mode = `REV;
T1 = VS;
VS = VD;
VD = T1;
end
else
Mode = `FWD;
// VGB = VGS - VBS;
// VBD = VBS - VDS;
VGstar = VG - VTO_S - deltaVFB + PHI_T + GAMMA_sqrt_PHI;
sqrt_VGstar = sqrt(VGstar*VGstar + 2.0*Vt_Vt_16);
VGprime = 0.5*(VGstar + sqrt_VGstar);
// Pinch-off voltage VP, limited to VP >= -PHI
PHI_VS = PHI_T+VS;
sqrt_PHI_VS_Vt = sqrt(PHI_VS*PHI_VS+Vt_Vt_16);
sqrt_PHI_VS = sqrt(0.5*(PHI_VS+sqrt_PHI_VS_Vt));
PHI_VD = PHI_T+VD;
sqrt_PHI_VD_Vt = sqrt(PHI_VD*PHI_VD+Vt_Vt_16);
sqrt_PHI_VD = sqrt(0.5*(PHI_VD+sqrt_PHI_VD_Vt));
WETA_W = eps_COX_W * M / Weff;
LETA_L = eps_COX_L * NS / Leff;
// mb: symmetric version of GAMMAprime necessary with charges model
big_sqrt_VP0 = sqrt(VGprime + 0.25*GAMMA_S*GAMMA_S);
VP0 = VGprime - PHI_T - GAMMA_S*(big_sqrt_VP0 - 0.5*GAMMA_S);
sqrt_PHI_VP0 = sqrt(VP0+PHI_T+Vt_01);
GAMMAstar = GAMMA_S - LETA_L * (sqrt_PHI_VS+sqrt_PHI_VD) +
WETA_W * sqrt_PHI_VP0;
// keep GAMMAprime from becoming negative
sqrt_GAMMAstar = sqrt(GAMMAstar*GAMMAstar+Vt_01);
GAMMAprime = 0.5*(GAMMAstar+sqrt_GAMMAstar);
big_sqrt_VP = sqrt(VGprime+0.25*GAMMAprime*GAMMAprime);
VP = VGprime-PHI_T-GAMMAprime*(big_sqrt_VP-0.5*GAMMAprime);
// Forward normalized current:
tmp1 = (VP - VS) * inv_Vt;
if (tmp1 > -0.35) begin
z0 = 2.0/(1.3 + tmp1 - ln(tmp1 + 1.6));
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -15.0) begin
z0 = 1.55 + exp(-tmp1);
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -23.0) begin
yk = 1.0/(2.0 + exp(-tmp1));
end else begin
yk = exp(tmp1) + 1E-64;
end
end
end
if_ = yk*(1.0 + yk);
sqrt_if = sqrt(if_);
dif_dv = yk;
// Saturation voltage:
Vt_Vc = Vt / Vc;
VDSS_sqrt = sqrt(0.25+sqrt_if*Vt_Vc);
VDSS = Vc*(VDSS_sqrt-0.5);
Vds = 0.5*(VD-VS);
deltaV_2 = Vt_Vt_16*(LAMBDA*(sqrt_if-
VDSS*inv_Vt)+15.625e-3);
sqrt_VDSS_deltaV = sqrt(VDSS*VDSS+deltaV_2);
sqrt_Vds_VDSS_deltaV = sqrt((Vds-VDSS)*(Vds-VDSS)+deltaV_2);
Vip = sqrt_VDSS_deltaV-sqrt_Vds_VDSS_deltaV;
VDSSprime_sqrt = sqrt(0.25+(sqrt_if-0.75*ln(if_))*Vt_Vc);
VDSSprime = Vc*(VDSSprime_sqrt-0.5)+log_Vc_Vt;
// Reverse normalized current:
Vdsprime = Vds-VDSSprime; // mb 97/07/18 introduced Vdsprime
sqrt_VDSSprime_deltaV = sqrt(VDSSprime*VDSSprime+deltaV_2);
sqrt_Vds_VDSSprime_deltaV = sqrt(Vdsprime*Vdsprime+deltaV_2);
tmp1 = (VP-Vds-VS-sqrt_VDSSprime_deltaV+
sqrt_Vds_VDSSprime_deltaV)*inv_Vt;
// include -> Charge F(x) interpolate function
if (tmp1 > -0.35) begin
z0 = 2.0/(1.3 + tmp1 - ln(tmp1 + 1.6));
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -15.0) begin
z0 = 1.55 + exp(-tmp1);
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -23.0) begin
yk = 1.0/(2.0 + exp(-tmp1));
end else begin
yk = exp(tmp1) + 1E-64;
end
end
end
irprime = yk*(1.0 + yk);
sqrt_irprime = sqrt(irprime);
dirprime_dv = yk;
/* Channel length modulation & mobility reduction due
* to longitudinal field */
deltaL = Lc_LAMBDA*ln(1.0+(Vds-Vip)/Lc_UCRIT);
Lprime = Leff-deltaL+(Vds+Vip)*inv_UCRIT;
Lmin = 0.1*Leff;
sqrt_Lprime_Lmin = sqrt(Lprime*Lprime+Lmin*Lmin);
Leq = 0.5*(Lprime+sqrt_Lprime_Lmin);
// Transconductance factor:
// Mobility reduction due to vertical field
// Reverse normalized current:
// ratioV_ir
tmp1 = (VP - VD) * inv_Vt;
if (tmp1 > -0.35) begin
z0 = 2.0/(1.3 + tmp1 - ln(tmp1 + 1.6));
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -15.0) begin
z0 = 1.55 + exp(-tmp1);
zk = (2.0 + z0)/(1.0 + tmp1 + ln(z0));
yk = (1.0 + tmp1 + ln(zk))/(2.0 + zk);
end else begin
if (tmp1 > -23.0) begin
yk = 1.0/(2.0 + exp(-tmp1));
end else begin
yk = exp(tmp1) + 1E-64;
end
end
end
ir = yk*(1.0 + yk);
sqrt_ir = sqrt(ir);
dir_dv = yk;
sif2 = 0.25+if_;
sir2 = 0.25+ir;
sif = sqrt(sif2);
sir = sqrt(sir2);
sif_sir_2 = (sif+sir)*(sif+sir);
VP_PHI_eps = VP+PHI_T+1.0e-6;
sqrt_PHI_VP_2 = 2.0*sqrt(VP_PHI_eps);
n_1 = GAMMA_S/sqrt_PHI_VP_2;
n_1_n = GAMMA_S/(sqrt_PHI_VP_2 + GAMMA_S);
// Normalized inversion charge (qi=QI/WLCox)
qi = -(1.0+n_1)*Vt*((0.66666666+0.66666666)*
(sir2+sir*sif+sif2)/(sif+sir) - 1.0);
// Normalized depletion charge (qb=QB/WLCox), for depletion to inversion
qb = -0.5*GAMMA_S*sqrt_PHI_VP_2 - n_1_n*qi;
if (E0 == 0.0) begin
/* NOTE: this version of the simple mobility model from prior
* versions of the EKV model is reinstated.
* In case E0 is *not* specified, this
* simple mobility model is used according to THETA, if specified.
* VPprime:
* mb eliminated discontinuity of derivative of 1+THETA*VP
*/
sqrt_VP_Vt = sqrt(VP*VP + Vt_Vt_2);
VPprime = 0.5 * (VP + sqrt_VP_Vt);
THETA_VP_1 = 1.0+THETA*VPprime;
beta = KP_Weff / (Leq * THETA_VP_1); // mb 97/07/18
end
else begin
/* new model for mobility reduction, linked to the charges model
* mb 98/10/11 (r10) introduced fabs(Eeff) (jpm)
* E0_Q_1 = 1.0 + T0 * abs(qb+eta_qi*qi);
*/
if ((qb + eta_qi*qi) > 0.0)
E0_Q_1 = 1.0 + T0*(qb + eta_qi*qi);
else
E0_Q_1 = 1.0 - T0*(qb + eta_qi*qi);
T0_GAMMA_1 = 1.0 + T0*GAMMA_sqrt_PHI;
beta = KP_Weff * T0_GAMMA_1 / (Leq * E0_Q_1);
end
/* Slope factor: mb introduced new formula to avoid divergence
* of n for VP->-PHI */
sqrt_PHI_VP = sqrt(PHI_T+VP+Vt_4); // mb 95/12/19 introduced Vt_4
n = 1.0 + GAMMA_S/(2.0*sqrt_PHI_VP);
// Drain current:
if_ir = if_-irprime;
Ispec = Vt_Vt_2 * n * beta;
Id = Ispec * if_ir;
/* Return threshold voltage
* Von = Vth(Vs) = Vto + Gamma*(sqrt(Phi + Vsb)-sqrt(Phi)) */
Von = VTO_S + GAMMAprime*(sqrt_PHI_VS - sqrt_PHI);
// Return saturation voltage (estimate)
Vdsat = Vt * (2.0*sqrt_if + 4.0);
// Return equivalent conductance for thermal noise calculation
Gn = beta * abs(qi);
/* Pinch-off voltage derivatives:
* mb 97/09/14 symmetric version of GAMMAprime necessary with
* charges model
* mb 99/05/10 (r12) New VGprime formulation (REVISION III) allows
* VP derivatives to be expressed with a single equation
*/
tmp1 = GAMMAprime / (sqrt_GAMMAstar+sqrt_GAMMAstar);
tmp2 = VGprime/sqrt_VGstar; // dVGprime_dVG
dGAMMAprime_dVD = -LETA_L * tmp1 * sqrt_PHI_VD / sqrt_PHI_VD_Vt;
dGAMMAprime_dVS = -LETA_L * tmp1 * sqrt_PHI_VS / sqrt_PHI_VS_Vt;
dGAMMAprime_dVG = WETA_W * tmp1 * (big_sqrt_VP0-0.5*GAMMA_S) /
(big_sqrt_VP0*sqrt_PHI_VP0) * tmp2;
tmp3 = (VP+PHI_T) / big_sqrt_VP;
dVP_dVD = -tmp3 * dGAMMAprime_dVD;
dVP_dVS = -tmp3 * dGAMMAprime_dVS;
dVP_dVG = -tmp3 * dGAMMAprime_dVG + (1.0 -
GAMMAprime/(big_sqrt_VP+big_sqrt_VP)) * tmp2;
// Forward normalized current derivatives:
tmp1 = dif_dv * inv_Vt; // mb 95/08/28, 97/04/21
dif_dVD = tmp1 * dVP_dVD;
dif_dVS = tmp1 * (dVP_dVS-1.0);
dif_dVG = tmp1 * dVP_dVG;
// Saturation voltage derivatives:
tmp1 = Vt / (4.0*VDSS_sqrt*sqrt_if);
dVDSS_dVD = tmp1 * dif_dVD;
dVDSS_dVS = tmp1 * dif_dVS;
dVDSS_dVG = tmp1 * dif_dVG;
// deltaV derivatives:
tmp1 = (Vt_4+Vt_4) * LAMBDA;
tmp2 = Vt / (sqrt_if+sqrt_if);
ddeltaV_dVD = tmp1 * (dif_dVD*tmp2 - dVDSS_dVD);
ddeltaV_dVS = tmp1 * (dif_dVS*tmp2 - dVDSS_dVS);
ddeltaV_dVG = tmp1 * (dif_dVG*tmp2 - dVDSS_dVG);
// Vip derivatives:
tmp1 = 1.0 / sqrt_VDSS_deltaV;
tmp2 = 1.0 / sqrt_Vds_VDSS_deltaV;
tmp3 = Vds-VDSS;
dVip_dVD = (VDSS*dVDSS_dVD + ddeltaV_dVD) * tmp1 -
(tmp3 * (0.5-dVDSS_dVD) + ddeltaV_dVD) * tmp2;
dVip_dVS = (VDSS*dVDSS_dVS + ddeltaV_dVS) * tmp1 -
(tmp3 * (-0.5-dVDSS_dVS) + ddeltaV_dVS) * tmp2;
dVip_dVG = (VDSS*dVDSS_dVG + ddeltaV_dVG) * tmp1 -
(tmp3 * -dVDSS_dVG + ddeltaV_dVG) * tmp2;
// VDSSprime derivatives:
tmp1 = Vt * (sqrt_if-1.5)/(4.0*VDSSprime_sqrt*if_);
dVDSSprime_dVD = tmp1 * dif_dVD;
dVDSSprime_dVS = tmp1 * dif_dVS;
dVDSSprime_dVG = tmp1 * dif_dVG;
// Reverse normalized current derivatives:
tmp1 = dirprime_dv * inv_Vt; // mb 95/08/28, 97/04/21
tmp2 = 1.0 / sqrt_VDSSprime_deltaV; // mb 97/04/21
tmp3 = 1.0 / sqrt_Vds_VDSSprime_deltaV;
dirprime_dVD = tmp1 * (dVP_dVD-0.5 -
(VDSSprime*dVDSSprime_dVD+ddeltaV_dVD) * tmp2 +
(Vdsprime*(0.5-dVDSSprime_dVD)+ddeltaV_dVD) * tmp3);
dirprime_dVS = tmp1 * (dVP_dVS-0.5 -
(VDSSprime*dVDSSprime_dVS+ddeltaV_dVS) * tmp2 +
(Vdsprime*(-0.5-dVDSSprime_dVS)+ddeltaV_dVS) * tmp3);
dirprime_dVG = tmp1*(dVP_dVG -
(VDSSprime*dVDSSprime_dVG+ddeltaV_dVG) * tmp2 +
(Vdsprime*(-dVDSSprime_dVG)+ddeltaV_dVG) * tmp3);
// Channel length modulation & mobility reduction derivatives:
// deltaL derivatives:
tmp1 = Lc_LAMBDA / (Lc_UCRIT+Vds-Vip);
ddeltaL_dVD = tmp1 * (0.5-dVip_dVD);
ddeltaL_dVS = tmp1 * (-0.5-dVip_dVS);
ddeltaL_dVG = -tmp1 * dVip_dVG;
// Leq derivatives:
tmp1 = 1.0 / sqrt_Lprime_Lmin; // in fact dLeq_dVX/Leq
dLeq_dVD = tmp1 * (-ddeltaL_dVD + (0.5+dVip_dVD)*inv_UCRIT);
dLeq_dVS = tmp1 * (-ddeltaL_dVS + (-0.5+dVip_dVS)*inv_UCRIT);
dLeq_dVG = tmp1 * (-ddeltaL_dVG + dVip_dVG*inv_UCRIT);
// Transconductance factor derivatives:
tmp1 = dir_dv*inv_Vt;
dir_dVD = tmp1 * (dVP_dVD-1.0);
dir_dVS = tmp1 * dVP_dVS;
dir_dVG = tmp1 * dVP_dVG;
tmp1 = -(1.0+n_1)*Vt*0.66666666/sif_sir_2;
tmp2 = tmp1*(sif+2.0*sir);
tmp3 = tmp1*(sir+2.0*sif);
tmp1 = -n_1*qi/((2.0+n_1+n_1)*VP_PHI_eps);
dQI_dVD = tmp1 * dVP_dVD + tmp2 * dif_dVD + tmp3 * dir_dVD;
dQI_dVS = tmp1 * dVP_dVS + tmp2 * dif_dVS + tmp3 * dir_dVS;
dQI_dVG = tmp1 * dVP_dVG + tmp2 * dif_dVG + tmp3 * dir_dVG;
tmp1 = (1.0+n_1)-qi/(2.0*(1.0+n_1)*VP_PHI_eps);
dQB_dVD = -n_1_n * (tmp1 * dVP_dVD + dQI_dVD);
dQB_dVS = -n_1_n * (tmp1 * dVP_dVS + dQI_dVS);
dQB_dVG = -n_1_n * (tmp1 * dVP_dVG + dQI_dVG);
if (E0 == 0.0) begin
tmp1 = THETA * VPprime / (THETA_VP_1 * sqrt_VP_Vt);
// VPprime derivatives:
dVPprime_dVD = tmp1 * dVP_dVD;
dVPprime_dVS = tmp1 * dVP_dVS;
dVPprime_dVG = tmp1 * dVP_dVG;
dbeta_dVD = -dLeq_dVD - dVPprime_dVD; // in fact dbeta_dVX / beta
dbeta_dVS = -dLeq_dVS - dVPprime_dVS;
dbeta_dVG = -dLeq_dVG - dVPprime_dVG;
end
else begin
tmp1 = T0 / E0_Q_1;
dbeta_dVD = -dLeq_dVD + tmp1 * (dQB_dVD+eta_qi*dQI_dVD);
dbeta_dVS = -dLeq_dVS + tmp1 * (dQB_dVS+eta_qi*dQI_dVS);
dbeta_dVG = -dLeq_dVG + tmp1 * (dQB_dVG+eta_qi*dQI_dVG);
end
// Slope factor derivatives:
tmp1 = -GAMMA_S/(4.0*n*sqrt_PHI_VP*(PHI_T+VP+Vt_4));// mb 95/12/19
dn_dVD = tmp1 * dVP_dVD;
dn_dVS = tmp1 * dVP_dVS;
dn_dVG = tmp1 * dVP_dVG;
// Transconductances:
gds = Ispec*((dn_dVD + dbeta_dVD)*if_ir + dif_dVD - dirprime_dVD);
gms = -Ispec*((dn_dVS + dbeta_dVS)*if_ir + dif_dVS - dirprime_dVS);
gm = Ispec*((dn_dVG + dbeta_dVG)*if_ir + dif_dVG - dirprime_dVG);
gmbs = gms - gm - gds;
// S/D resistance corrections including W and DW
RSeff = (RSH*HDIF)/(Weff-DW);
RDeff = (RSH*HDIF)/(Weff-DW);
tmp1 = 1.0/(1.0 + gms*RSeff + gds*RDeff);
Id = Id*tmp1;
/****** Impact ionization current ******
* mb 95/12/19 introduced impact ionization
* This current component is flowing from the intrinsic drain terminal
* to the bulk (for NMOS) in parallel with the junction current.
* The simulator should also take into account the corresponding
* conductances.
*/
// Substrate current:
Vib = VD-VS-IBN_2*VDSS;
if ((Vib > 0.0) && (IBA_IBB > 0.0)) begin
inv_Vib = 1.0/Vib;
Lc_IBB_Vib = -Lc_IBB*inv_Vib;
if (Lc_IBB_Vib < -35.0) // math precision check
Lc_IBB_Vib = -35.0;
exp_ib = exp(Lc_IBB_Vib);
isub = IBA_IBB*Vib*exp_ib;
Isub = isub*Id;
dIsub_factor = Isub*inv_Vib*(1.0-Lc_IBB_Vib);
end
else begin
Lc_IBB_Vib = 0.0;
Isub = 0.0;
end
// END: substrate current computation
Ibd = Ibd - Isub;
// --- Charge calculations ---
WLCox = Weff * Leff * COX;
sif3 = sif*sif2;
sir3 = sir*sir2;
tmp1 = sqrt(PHI_T + 0.5 * VP);
sqrt_PHI_VP2_2 = tmp1+tmp1;
n_Vt_COX = (1.0 + GAMMAprime/sqrt_PHI_VP2_2) * Vt*WLCox;
QD = -n_Vt_COX*(0.266666666*(3.0*sir3+6.0*sir2*sif+4.0*
sir*sif2+2.0*sif3)/sif_sir_2 - 0.5);
QS = -n_Vt_COX*(0.266666666*(3.0*sif3+6.0*sif2*sir+4.0*
sif*sir2+2.0*sir3)/sif_sir_2 - 0.5);
QI = QS + QD;
QB = WLCox * (-0.5*GAMMAprime*sqrt_PHI_VP_2 + VGprime - VGstar) -
QI*GAMMAprime/(GAMMAprime+sqrt_PHI_VP2_2);
QG = -QI -QB;
I(ds) <+ TYPE * Mode * Id; // wg 22/04/08 corrected for device TYPE
ddt_QD = ddt(QD);
ddt_QS = ddt(QS);
if (Mode == `FWD) begin
I(db) <+ TYPE * ddt_QD; // wg 22/04/08 corrected for device TYPE
I(sb) <+ TYPE * ddt_QS;
I(db) <+ TYPE * Isub;
end
else begin
I(sb) <+ TYPE * ddt_QD; // wg 22/04/08 corrected for device TYPE
I(db) <+ TYPE * ddt_QS;
I(sb) <+ TYPE * Isub;
end
I(gb) <+ TYPE * ddt(QG); // wg 22/04/08 corrected for device TYPE
// if (Noise) begin : Noise //AB: 040902 Noise is also a variable and
if (Noise) begin : Noise_block //AB: 040902 Noise -> Noise_block
real S_flicker, S_thermal;
S_thermal = 4 * `P_K * T * Gn;
S_flicker = KF * gm * gm / (Weff * NS * Leff * COX);
I(ds) <+ white_noise(S_thermal, "thermal") +
flicker_noise(S_flicker, AF, "flicker");
end
///////////////////////////////////
//EXTRINSIC PART: JUNCTION DIODES//
///////////////////////////////////
//diode area and perimeter computation
if ((AS == 0.0) && (HDIF>0.0)) as_i = 2.0*HDIF*Weff;
else as_i = AS;
if ((PS == 0.0) && (HDIF>0.0)) ps_i = 4.0*HDIF+1.0*Weff;
else ps_i = PS;
if ((AD == 0.0) && (HDIF>0.0)) ad_i = 2.0*HDIF*Weff;
else ad_i = AD;
if ((PD == 0.0) && (HDIF>0.0)) pd_i = 4.0*HDIF+1.0*Weff;
else pd_i = PD;
//temperature update for diodes
temp_arg = exp((refEg/$vt(Tnom) - Eg/Vt + tp_xti*ln(ratioT))/xd_n);
js_t = xd_js*temp_arg;
jsw_t = xd_jsw*temp_arg;
jswg_t = xd_jswg*temp_arg;
pb_t = xd_pb - tp_pb*deltaT;
pbsw_t = xd_pbsw - tp_pbsw*deltaT;
pbswg_t = xd_pbswg - tp_pbswg*deltaT;
cj_t = xd_cj*(1.0+tp_cj*deltaT);
cjsw_t = xd_cjsw*(1.0+tp_cjsw*deltaT);
cjswg_t = xd_cjswg*(1.0+tp_cjswg*deltaT);
njts_t = xd_njts*(1.0+(ratioT-1.0)*tp_njts);
njtssw_t = xd_njtssw*(1.0+(ratioT-1.0)*tp_njtssw);
njtsswg_t = xd_njtsswg*(1.0+(ratioT-1.0)*tp_njtsswg);
//DC
v_di_b = TYPE*V(d,b);
v_si_b = TYPE*V(s,b);
//DRAIN - BULK
is_d = js_t*ad_i+jsw_t*pd_i+jswg_t*Weff;
arg_d = -v_di_b*ratioT/(Vt*xd_n);
if (arg_d < -40.0) arg_d = -40.0;
tmp0 = (-v_di_b+xd_bv)*ratioT/(Vt*xd_n);
if (tmp0>70) f_breakdown_d = 1.0;
else f_breakdown_d = 1.0 + xd_xjbv*exp(-tmp0);
// TRAP-ASSISTED TUNNELING CURRENT
idb_tun = -Weff*jswg_t*(exp(v_di_b*ratioT/(Vt*njtsswg_t) * xd_vtsswg/max(xd_vtsswg+v_di_b,1.0e-3))-1.0);
idb_tun = idb_tun - pd_i*jsw_t*(exp(v_di_b*ratioT/(Vt*njtssw_t) * xd_vtssw/max(xd_vtssw+v_di_b,1.0e-3))-1.0);
idb_tun = idb_tun - ad_i*js_t*(exp(v_di_b*ratioT/(Vt*njts_t) * xd_vts/max(xd_vts+v_di_b,1.0e-3))-1.0);
I(d,b) <+ (is_d * (1.0 - exp(arg_d))*f_breakdown_d+v_di_b*xd_gmin + idb_tun)*TYPE*M;
//SOURCE - BULK
is_s = js_t*as_i+jsw_t*ps_i+jswg_t*Weff;
arg_s = -v_si_b*ratioT/(Vt*xd_n);
if (arg_s < -40.0) arg_s = -40.0;
tmp0 = (-v_si_b+xd_bv)*ratioT/(Vt*xd_n);
if (tmp0>70) f_breakdown_s = 1.0;
else f_breakdown_s = 1.0 + xd_xjbv*exp(-tmp0);
// TRAP-ASSISTED TUNNELING CURRENT
isb_tun = -Weff*jswg_t*(exp(v_si_b*ratioT/(Vt*njtsswg_t) * xd_vtsswg/max(xd_vtsswg+v_si_b,1.0e-3))-1.0);
isb_tun = isb_tun - ps_i*jsw_t*(exp(v_si_b*ratioT/(Vt*njtssw_t) * xd_vtssw/max(xd_vtssw+v_si_b,1.0e-3))-1.0);
isb_tun = isb_tun - as_i*js_t*(exp(v_si_b*ratioT/(Vt*njts_t) * xd_vts/max(xd_vts+v_si_b,1.0e-3))-1.0);
I(s,b) <+ (is_s * (1.0 - exp(arg_s))*f_breakdown_s+v_si_b*xd_gmin + isb_tun)*TYPE*M;
//AC
//DRAIN - BULK
if (v_di_b>0.0)
begin
csb_d = cj_t * ad_i * exp(-xd_mj*ln(1.0+v_di_b/pb_t));
cssw_d = cjsw_t * pd_i * exp(-xd_mjsw*ln(1.0+v_di_b/pbsw_t));
csswg_d = cjswg_t * Weff * exp(-xd_mjswg*ln(1.0+v_di_b/pbswg_t));
end
else
begin
csb_d = cj_t * ad_i * (1.0 - xd_mj*v_di_b/pb_t);
cssw_d = cjsw_t * pd_i * (1.0 - xd_mjsw*v_di_b/pbsw_t);
csswg_d = cjswg_t * Weff * (1.0 - xd_mjswg*v_di_b/pbswg_t);
end
qjd = (csb_d+cssw_d+csswg_d) * v_di_b;
I(d,b) <+ ddt(qjd)*TYPE*M;
//SOURCE - BULK
if (v_si_b>0.0)
begin
csb_s = cj_t * as_i * exp(-xd_mj*ln(1.0+v_si_b/pb_t));
cssw_s = cjsw_t * ps_i * exp(-xd_mjsw*ln(1.0+v_si_b/pbsw_t));
csswg_s = cjswg_t * Weff * exp(-xd_mjswg*ln(1.0+v_si_b/pbswg_t));
end
else
begin
csb_s = cj_t * as_i * (1.0 - xd_mj*v_si_b/pb_t);
cssw_s = cjsw_t * ps_i * (1.0 - xd_mjsw*v_si_b/pbsw_t);
csswg_s = cjswg_t * Weff * (1.0 - xd_mjswg*v_si_b/pbswg_t);
end
qjs = (csb_s+cssw_s+csswg_s) * v_si_b;
I(s,b) <+ ddt(qjs)*TYPE*M;
//END OF DIODES
end
endmodule

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examples/osdi/EKV2.6/netlist_mod_nmos.sp
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OSDI EKV 2.6 NMOS Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 1
VG gg 0 1
VS ss 0 0
VB bb 0 0
* model definitions:
*.model .MODEL NCH EKV_VA type=1
.include Modelcards/ekv26_0u5.par
*OSDI EKV:
N1 dd gg ss bb nch W=5e-6 L=0.5e-6
.control
pre_osdi test_osdi_win/ekv26_mod.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
dc Vd 0 1.6 0.01 VG 0 1.6 0.2
* plot source current
plot i(VS)
.endc
.end

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examples/osdi/EKV2.6/netlist_mod_pmos.sp
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OSDI EKV 2.6 PMOS Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 -1
VG gg 0 -1
VS ss 0 0
VB bb 0 0
* model definitions:
*.model .MODEL PCH EKV_VA type=-1
.include Modelcards/ekv26_0u5.par
*OSDI EKV:
N1 dd gg ss bb pch W=5e-6 L=5e-7
.control
pre_osdi test_osdi_win/ekv26_mod.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
*op
dc Vd 0 -1.8 -0.01 VG 0 -1.8 -0.2
* plot source current
plot i(VS)
.endc
.end

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examples/osdi/EKV2.6/test_osdi_win/README
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Place ekv26_mod.osdi here.

59
examples/osdi/README
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A 'quick and dirty' howto for OpenVAF and OSDI:
Example BSIMBULK
Tested under MS Windows 10
Have OpenVAF compiler available.
Sources will be available soon.
Download BSIMBULK model from http://www.bsim.berkeley.edu/models/bsimbulk/
Open bsimbulk.va in a text editor
Search for the module name, here:
module bsimbulk(d, g, s, b, t);
The module name 'bsimbulk' will become the new model type in the .model statement
.model mname type ( pname1 = pval1 pname2 = pval2 ... ).
Compile bsimbulk.va with OpenVAF to obtain bsimbulk.osdi
Put bsimbulk.osdi into directory bsimbulk/test_osdi_win
Search for suitable model parameters
BSIMBULK107 distro does not contain any parameters
BSIMBULK106 does contain a model parameter file model.l among the benchmark tests
Put model.l into directory bsimbulk/Modelcards
Edit model.l:
Check if model type is 'bsimbulk' (it is already)
Choose a model name for mname (nch or pch may be o.k., or BSIMBULK_osdi_N or ...)
There are NMOS and PMOS parameters in the same file here.
Create a ngspice netlist in directory bsimbulk, e.g. bb_IDvsVG.cir.
*** BSIMBULK107 Id versus Vgs ***
* the voltage sources
Vd dd 0 50m
Vg gg 0 1
Vs ss 0 0
Vb bb 0 0
* load the model parameter sets
.include Modelcards/model.l
* the call to the transistor (OSDI devices always start with N !)
NMN1 dd gg ss bb BSIMBULK_osdi_N W=500n L=90n
* the .control section
.control
* load the model dynamically
pre_osdi test_osdi_win/bsimbulk107.osdi
* the dc simulation
dc Vg 0 1.5 0.01 Vb 0 -1.6 -0.4
* plotting
set xbrushwidth=3
plot I(Vs)
.endc
.end
*********************************
So we have two OSDI specific actions in the netlist:
load the model by
pre_osdi test_osdi_win/bsimbulk107.osdi
instantiate the transistor by
NMN1 dd gg ss bb BSIMBULK_osdi_N W=500n L=90n

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* model parameters fron BSIMBULK 106.2
.model BSIMBULK_osdi_N bsimbulk
+level=77
+TYPE = 1
+GEOMOD = 0
+RGEOMOD = 0
+COVMOD = 1
+RDSMOD = 0
+GIDLMOD = 1
+IGCMOD = 0
+IGBMOD = 0
+LLONG = 2e-6
+WWIDE = 1e-5
+XL = -1.7e-8
+XW = 1.1e-8
+LINT = 0
+WINT = 0
+DLC = 0
+DWC = 0
+TOXE = 1.74e-9
+TOXP = 1.7e-9
+NDEP = 4.6e23
+NSD = 1e26
+NGATE = 8.5e25
+VFB = -1.02
+EPSROX = 3.9
+EPSRSUB = 11.9
+NI0SUB = 1.1e16
+XJ = 1.5e-7
+DMCG = 0
+DMDG = 0
+DMCGT = 0
+CIT = 1e-8
+CDSCD = 0.001
+CDSCB = 0
+CDSCBL = 0.007
+CDSCBLEXP = 1
+NFACTOR = 0.002
+NFACTORL = 2.1e-8
+NFACTORLEXP = 6.264
+NDEPL1 = 0.096
+NDEPLEXP1 = 1
+NDEPL2 = -0.0032
+NDEPLEXP2 = 2.05
+DVTP0 = 7.5e-7
+DVTP1 = -4.4e-7
+NDEPW = -0.1548
+NDEPWEXP = 0.7441
+NDEPWL = 0
+NDEPWLEXP = 0.2
+K2W = 0
+AGIDL = 3.728e-8
+AGIDLL = -0.04815
+AGIDLW = -0.0341
+BGIDL = 8.123e9
+CGIDL = 1.21e-6
+EGIDL = -2.952
+PHIN = 0.05
+K2L = 0.001636
+K2 = -0.014
+ETA0 = 8.416e-6
+ETAB = -5.561e-5
+ETABEXP = 2.155
+DSUB = 3
+VSAT = 6.4e4
+VSATW = 0.05
+VSATWEXP = 1
+DELTA = 0.15
+DELTAL = 0.1
+DELTALEXP = 1e-5
+U0 = 0.04546
+ETAMOB = 1.5
+U0L = 0.025
+U0LEXP = 0.95
+UA = 0.4007
+UAW = 0.05
+UAWEXP = 1
+UAL = 0.00475
+UALEXP = 1.118
+EUW = -0.02
+EUWEXP = 1
+EUL = 0.001
+EULEXP = 1
+EU = 1.9
+UDL = 1e-15
+UDLEXP = 1
+UD = 1.042e-5
+UCS = 2
+UCW = 0
+UCWEXP = 1
+UC = 1e-07
+UCL = 2.5e4
+UCLEXP = 1
+PCLM = 0.15
+PCLML = 0.01
+PCLMLEXP = 0.4
+PCLMG = 0
+PSCBE1 = 5
+PSCBE2 = 1.29e-12
+PDITS = 0
+PDITSL = 0
+PDITSD = 0
+RSWMIN = 0
+RSW = 100
+RDWMIN = 0
+RDW = 100
+RDSW = 20
+RDSWMIN = 0
+PRWG = 1
+PRWB = 0
+WR = 1
+RSH = 0
+PDIBLCB = 0
+PDIBLC = 0.01
+PDIBLCL = 1e-5
+PDIBLCLEXP = 1e-6
+PVAG = 0
+PTWG = 0.2
+PTWGL = 3e4
+PTWGLEXP = 5e-6
+FPROUT = 0
+CF = 0
+CFRCOEFF = 1
+CGSO = 2.5e-10
+CGDO = 2.5e-10
+CGSL = 1.2e-10
+CGDL = 1.2e-10
+CKAPPAS = 1.25
+CKAPPAD = 1.25
+CGBO = 0
+ADOS = 0
+BDOS = 1
+QM0 = 0.001
+ETAQM = 0.54
+NDEPCV = 8e23
+VFBCV = -0.95
+VSATCV = 1e5
+PCLMCV = 0
+PSAT = 0.46
+PSATL = 6
+PSATLEXP = 0.06
+TNFACTOR = 0
+TETA0 = 0
+UTE = -1.4
+UTEL = -0.001
+UA1 = -0.0011
+UA1L = 0
+UC1 = 0
+UD1 = 0
+UD1L = 0
+UCSTE = -0.005
+PRT = 0
+AT = -0.05
+ATL = -0.1
+TDELTA = -0.0048
+PTWGT = -0.002
+PTWGTL = 0.01
+KT1 = -0.115
+KT1EXP = 1
+KT1L = 1.286e-9
+KT2 = -0.003157
+K2LEXP = 1.698
+K2WEXP = 0.005
+TBGASUB = 0
+AIGS = 0.0136
+BIGS = 0.00171
+CIGS = 0.075
+AIGSL = 0
+AIGD = 0.0136
+BIGD = 0.00171
+CIGD = 0.075
+AIGDL = 0
+AIGC = 0.01285
+LAIGC = 2.132e-6
+BIGC = 0.0013
+CIGC = 0.013
+AIGCL = -0.01227
+PIGCD = 1
+PIGCDL = 6.196
+AIGBINV = 0.015
+BIGBINV = 0.000949
+CIGBINV = 0.006
+EIGBINV = 1.1
+NIGBINV = 3
+AIGBACC = 0.01751
+BIGBACC = 8.307
+CIGBACC = -898.7
+NIGBACC = 1
+LPSAT = 0
+WPSAT = 0
+PPSAT = 0
+PSATB = 0
+PSATX = 3
+WVSAT = 0
+PVSAT = 0
+WPTWG = 0
+PPTWG = 0
+TNOM = 25
+WDVTP0 = 0
+WDVTP1 = 0
+LUTE = 0.04574
+LUA1 = 8.365e-5
+LAT = 0
+DVTP2 = 0
+DVTP3 = 0
+DVTP4 = 0
+DVTP5 = 0
+VSATL = 1350
+VSATLEXP = 0.00033
+SCA = 0
+SCB = 0
+SCC = 0
+SC = 0
.model BSIMBULK_osdi_P bsimbulk
+level=77
+TYPE = -1
+GEOMOD = 0
+RGEOMOD = 0
+RGATEMOD = 0
+RBODYMOD = 0
+IGCMOD = 0
+IGBMOD = 0
+COVMOD = 1
+RDSMOD = 2
+GIDLMOD = 0
+TNOIMOD = 0
+SHMOD = 0
+TOXE = 2.34e-9
+TOXP = 1.925e-9
+DTOX = 0
+EPSROX = 3.9
+TNOM = 25
+XL = 0
+XW = 0
+LINT = 0
+LLONG = 1000000
+LL = 0
+LW = 0
+LWL = 0
+LLN = 1
+LWN = 1
+WINT = -9.0134104e-9
+WL = 0
+WW = 0
+WWL = 0
+WLN = 1
+WWN = 1
+WWIDE = 1000000
+DLC = 0
+LLC = 0
+LWC = 0
+LWLC = 0
+DWC = 0
+WLC = 0
+WWC = 0
+WWLC = 0
+JSS = 0.0001
+JSD = 0.0001
+JSWS = 0
+JSWD = 0
+JSWGS = 0
+JSWGD = 0
+NJS = 1
+NJD = 1
+IJTHSFWD = 0.1
+IJTHDFWD = 0.1
+IJTHSREV = 0.1
+IJTHDREV = 0.1
+BVS = 10
+BVD = 10
+XJBVS = 1
+XJBVD = 1
+JTSS = 0
+JTSD = 0
+JTSSWS = 0
+JTSSWD = 0
+JTSSWGS = 0
+JTSSWGD = 0
+JTWEFF = 0
+NJTS = 20
+NJTSD = 20
+NJTSSW = 20
+NJTSSWD = 20
+NJTSSWG = 20
+NJTSSWGD = 20
+VTSS = 10
+VTSD = 10
+VTSSWS = 10
+VTSSWD = 10
+VTSSWGS = 10
+VTSSWGD = 10
+CJS = 0.0005
+CJD = 0.0005
+CJSWS = 5e-10
+CJSWD = 5e-10
+CJSWGS = 0
+CJSWGD = 0
+PBS = 1
+PBD = 1
+PBSWS = 1
+PBSWD = 1
+PBSWGS = 1
+PBSWGD = 1
+MJS = 0.5
+MJD = 0.5
+MJSWS = 0.33
+MJSWD = 0.33
+MJSWGS = 0.33
+MJSWGD = 0.33
+TPB = 0
+TCJ = 0
+TPBSW = 0
+TCJSW = 0
+TPBSWG = 0
+TCJSWG = 0
+XTIS = 3
+XTID = 3
+XTSS = 0.02
+XTSD = 0.02
+XTSSWS = 0.02
+XTSSWD = 0.02
+XTSSWGS = 0.02
+XTSSWGD = 0.02
+TNJTS = 0
+TNJTSD = 0
+TNJTSSW = 0
+TNJTSSWD = 0
+TNJTSSWG = 0
+TNJTSSWGD = 0
+NOIA = 6.25e40
+NOIB = 3.125e25
+NOIC = 8.75e8
+EM = 41000000
+EF = 1
+LINTNOI = 0
+NTNOI = 1
+TNOIA = 0
+TNOIB = 0
+TNOIC = 0
+RNOIA = 0.577
+RNOIB = 0.5164
+RNOIC = 0.395
+DWJ = 0
+DMCG = 0
+DMCI = 0
+DMDG = 0
+DMCGT = 0
+XGW = 0
+XGL = 0
+GBMIN = 1e-12
+RSHG = 0.1
+RBPB = 50
+RBPD = 50
+RBPS = 50
+RBDB = 50
+RBSB = 50
+RBPS0 = 50
+RBPSL = 0
+RBPSW = 0
+RBPSNF = 0
+RBPD0 = 50
+RBPDL = 0
+RBPDW = 0
+RBPDNF = 0
+RBPBX0 = 100
+RBPBXL = 0
+RBPBXW = 0
+RBPBXNF = 0
+RBPBY0 = 100
+RBPBYL = 0
+RBPBYW = 0
+RBPBYNF = 0
+RBSBX0 = 100
+RBSBY0 = 100
+RBDBX0 = 100
+RBDBY0 = 100
+RBSDBXL = 0
+RBSDBXW = 0
+RBSDBXNF = 0
+RBSDBYL = 0
+RBSDBYW = 0
+RBSDBYNF = 0
+XRCRG1 = 12
+XRCRG2 = 1
+NGCON = 1
+NDEP = 8.062e23
+NDEPL1 = 1.2139
+NDEPLEXP1 = 1.9088
+NDEPL2 = -1.1825
+NDEPLEXP2 = 1.9173
+NDEPW = 0.065035
+NDEPWEXP = 0.48882
+NDEPWL = 0.00040893
+NDEPWLEXP = 1.3273
+EASUB = 4.05
+NI0SUB = 1.1e16
+BG0SUB = 1.17
+EPSRSUB = 11.9
+XJ = 1.5e-7
+VFB = -1.2108
+VFBSDOFF = 0
+NSD = 1e26
+DVTP0 = 1.8335e-7
+DVTP1 = 220.59
+DVTP2 = 9.6351e-10
+DVTP3 = 0.89017
+DVTP4 = 98.728
+DVTP5 = 5.1435e-17
+PHIN = 0.045
+ETA0 = 0.0051075
+ETAB = -0.010908157
+ETABEXP = 0.09999
+DSUB = 1.0667
+K2 = -0.093146
+K2L = 0.065574
+K2LEXP = 0.79778
+K2W = 0.030809
+K2WEXP = 0.87253
+CIT = 1.0136148e-5
+CDSCD = 0.0011509049
+CDSCDL = -0.00048388809
+CDSCDLEXP = 0.13963388
+CDSCB = 9.9995516e-6
+CDSCBL = 1.4756534e-9
+CDSCBLEXP = 1
+NFACTOR = 0.0017201
+NFACTORL = 1.7832e-6
+NFACTORLEXP = 0.99988
+NFACTORW = 0.11149
+NFACTORWEXP = 0.8993
+NFACTORWL = -0.01386
+U0 = 0.04004
+U0L = 0.58676
+U0LEXP = 0.11151
+ETAMOB = 4.0947
+UA = 0.4298
+UAL = -0.0087246
+UALEXP = 1.3647
+UAW = 0.11575
+UAWEXP = 0.4385
+UAWL = -7.027e-5
+EU = 1.3371
+EUL = 0.0021948
+EULEXP = 1.4769
+EUW = -0.0031666
+EUWEXP = 1.9366
+EUWL = -0.00013929
+UD = 0.0093995
+UDL = 0.067484
+UDLEXP = 0.099452
+UCS = 0.9999
+UC = 4.91e-6
+UCL = 0.001096
+UCLEXP = 0.0015937
+VSAT = 9609100
+VSATL = 6.8282
+VSATLEXP = 0.086396
+VSATW = 0.016834
+VSATWEXP = 3.0172
+VSATCVL = 0
+VSATCVLEXP = 1
+VSATCVW = 0
+VSATCVWEXP = 1
+DELTA = 0.1779
+DELTAL = 0.1269
+DELTALEXP = 0.18156
+PCLM = 0
+PCLML = 0
+PCLMLEXP = 1e-13
+PCLMG = 0
+PCLMCVL = 0
+PCLMCVLEXP = 1
+PSCBE1 = 4.24e8
+PSCBE2 = 1e-8
+PDITS = 0.85536
+PDITSL = 8473.9
+PDITSD = 0
+PDIBLC = 0.005
+PDIBLCL = 0
+PDIBLCLEXP = 1
+PDIBLCB = -0.49995
+PVAG = 1
+FPROUT = 0
+FPROUTL = 0
+FPROUTLEXP = 1
+PTWG = 0.09999
+PTWGL = 0.069993
+PTWGLEXP = 0.0009999
+PSAT = 1e-13
+PSATL = 0
+PSATLEXP = 1
+PSATB = 0.9999
+PSATX = 1e-13
+RSH = 0
+PRWG = 1
+PRWB = 0.010098993
+PRWBL = 0.00070000265
+PRWBLEXP = 1
+WR = 1
+RSWMIN = 0
+RSW = 10
+RSWL = 0
+RSWLEXP = 1
+RDWMIN = 0
+RDW = 10
+RDWL = 0
+RDWLEXP = 1
+RDSWMIN = 0
+RDSW = 0
+RDSWL = 0.0007
+RDSWLEXP = 1e-7
+ALPHA0 = 0
+ALPHA0L = 0
+ALPHA0LEXP = 1
+BETA0 = 0
+AGIDL = 0
+AGIDLL = 0
+AGIDLW = 0
+BGIDL = 2.3e9
+CGIDL = 0.5
+EGIDL = 0.8
+AGISL = 0
+AGISLL = 0
+AGISLW = 0
+BGISL = 2.3e9
+CGISL = 0.5
+EGISL = 0.00171
+AIGBACC = 0.00171
+BIGBACC = 0.00171
+CIGBACC = 0.075
+NIGBACC = 1
+AIGBINV = 0.0111
+BIGBINV = 0.000949
+CIGBINV = 0.006
+EIGBINV = 1.1
+NIGBINV = 3
+AIGC = 0.0136
+AIGCL = 3
+AIGCW = 0.0136
+BIGC = 0.00171
+CIGC = 0.075
+AIGS = 0.0136
+AIGSL = 0.075
+AIGSW = 0.0136
+AIGD = 0.0136
+AIGDL = 0
+AIGDW = 0.0136
+BIGS = 0.00171
+BIGD = 0.00171
+CIGS = 0.075
+CIGD = 0.075
+TOXREF = 0.075
+NTOX = 1
+POXEDGE = 1
+PIGCD = 1
+PIGCDL = 1
+NDEPCV = 4.598e23
+NDEPCVL1 = 0
+NDEPCVLEXP1 = 1
+NDEPCVL2 = 0
+NDEPCVLEXP2 = 2
+NDEPCVW = 0
+NDEPCVWEXP = 1
+NDEPCVWL = 0
+NDEPCVWLEXP = 1
+NGATE = 7.764e25
+CF = 0
+CFRCOEFF = 1
+CGSO = 187.0e-12
+CGDO = 187.0e-12
+CGBO = 0
+CGSL = 130.0e-12
+CGDL = 130.0e-12
+CKAPPAS = 1.6
+CKAPPAD = 1.6
+ADOS = 221.4
+BDOS = 1.350
+QM0 = 405.7e-6
+ETAQM = 848.5e-3
+VFBCV = -996.0e-3
+VFBCVL = 0
+VFBCVLEXP = 1
+VFBCVW = 0
+VFBCVWEXP = 1
+VFBCVWL = 0
+VFBCVWLEXP = 1
+TBGASUB = 0.000473
+TBGBSUB = 636
+TDELTA = 0
+PTWGT = 0
+IIT = 0
+TGIDL = 0
+IGT = 0
+KT1 = -0.11
+KT1L = 0
+KT2 = 0.022
+KT1EXP = 1
+UTE = -1.5
+UA1 = 0.001
+UD1 = 0
+UC1 = -5.6e-11
+UCSTE = -0.004775
+PRT = 0
+AT = -0.00156
+SCA = 0
+SCB = 0
+SCC = 0
+SC = 0
+KU0WE = 0
+KVTH0WE = 0
+K2WE = 0
+WEB = 0
+WEC = 0
+SCREF = 1e-6
+SA = 0
+SB = 0
+SD = 0
+SAREF = 1e-6
+SBREF = 1e-6
+WLOD = 0
+KVSAT = 0
+KU0 = 0
+TKU0 = 0
+LKU0 = 0
+WKU0 = 0
+PKU0 = 0
+LLODKU0 = 0
+WLODKU0 = 0
+KVTH0 = 0
+LKVTH0 = 0
+WKVTH0 = 0
+PKVTH0 = 0
+LLODVTH = 0
+WLODVTH = 0
+STK2 = 0
+LODK2 = 1
+STETA0 = 0
+LODETA0 = 1
+RTH0 = 1e7
+MOBSCALE = 1

40
examples/osdi/bsimbulk/bsimbulk_inverter.sp
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* BSIMBULK model vers. 107
* simple inverter
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/model.l
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss out not1
*Rout out 0 1k
.subckt not1 a vdd vss z
Np1 z a vdd vdd BSIMBULK_osdi_P l=0.1u w=1u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
Nn1 z a vss vss BSIMBULK_osdi_N l=0.1u w=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10ps 10ns
.dc V1 0 'vcc' 'vcc/100'
.control
pre_osdi test_osdi_win/bsimbulk107.osdi
run
*set nolegend
set xbrushwidth=3
plot in out
plot dc1.out
plot dc1.i(Vmeas)
rusage
.endc
.end

41
examples/osdi/bsimbulk/bsimbulk_ro.sp
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* BSIMBULK model vers. 107
* simple 5-stage ring oscillator
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/model.l
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss in2 not1
Xnot2 in2 vdd vss in3 not1
Xnot3 in3 vdd vss in4 not1
Xnot4 in4 vdd vss in5 not1
Xnot5 in5 vdd vss in not1
*Rout out 0 1k
.subckt not1 a vdd vss z
Np1 z a vdd vdd BSIMBULK_osdi_P l=0.1u w=1u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
Nn1 z a vss vss BSIMBULK_osdi_N l=0.1u w=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10p 10n uic
.control
pre_osdi test_osdi_win/bsimbulk107.osdi
run
set xbrushwidth=3
plot in
rusage
.endc
.end

89241
examples/osdi/bsimbulk/c7552_ann_bsimbulk.net
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27
examples/osdi/bsimbulk/netlist_mod_nmos.sp
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OSDI BSIMBULK NMOS Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 1
VG gg 0 1
VS ss 0 0
VB bb 0 0
* model definitions:
*.model BSIMBULK_osdi_N bsimbulk type=1
.include Modelcards/model.l
*OSDI BSIMBULK:
N1 dd gg ss bb BSIMBULK_osdi_N W=500n L=90n
.control
pre_osdi test_osdi_win/bsimbulk107.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
dc Vd 0 1.6 0.01 VG 0 1.6 0.2
* plot source current
plot i(VS)
.endc
.end

29
examples/osdi/bsimbulk/netlist_mod_pmos.sp
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OSDI BSIMBULK PMOS Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 -1
VG gg 0 -1
VS ss 0 0
VB bb 0 0
* model definitions:
*.model BSIMBULK_osdi_P bsimbulk type=-1
.include Modelcards/model.l
*OSDI BSIMBULK:
*
N1 dd gg ss bb BSIMBULK_osdi_P W=500n L=90n
.control
pre_osdi test_osdi_win/bsimbulk107.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
*op
dc Vd 0 -1.8 -0.01 VG 0 -1.8 -0.2
* plot source current
plot i(VS)
.endc
.end

45
examples/osdi/bsimbulk/nmos_pmos_BSIMBULK.sp
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*** NMOS and PMOS transistors BSIMBULK (Id-Vgs, Vbs) (Id-Vds, Vgs) (Id-Vgs, T) ***
Nn1 2 1 3 4 BSIMBULK_osdi_N l=0.1u w=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
vgsn 1 0 3.5
vdsn 2 0 0.1
vssn 3 0 0
vbsn 4 0 0
Np1 22 11 33 44 BSIMBULK_osdi_P l=0.1u w=1u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
vgsp 11 0 -3.5
vdsp 22 0 -0.1
vssp 33 0 0
vbsp 44 0 0
* BSIMBULK modelparameters for BSIMBULK106, Berkeley
.include Modelcards/model.l
.control
* Load the models dynamically
pre_osdi test_osdi_win/bsimbulk107.osdi
set xgridwidth=2
set xbrushwidth=3
* NMOS
dc vgsn 0 1.5 0.05 vbsn 0 -1.5 -0.3
plot vssn#branch ylabel 'Id vs. Vgs, Vbs 0 ... -1.5'
plot abs(vssn#branch) ylog ylabel 'Id vs. Vgs, Vbs 0 ... -1.5'
dc vdsn 0 1.6 0.01 vgsn 0 1.6 0.2
plot vssn#branch ylabel 'Id vs. Vds, Vgs 0 ... 1.6'
dc vgsn 0 1.5 0.05 temp -40 160 40
plot vssn#branch ylabel 'Id vs. Vds, Temp. -40 ... 160'
plot abs(vssn#branch) ylog ylabel 'Id vs. Vds, Temp. -40 ... 160'
* PMOS
dc vgsp 0 -1.5 -0.05 vbsp 0 1.5 0.3
plot vssp#branch ylabel 'Id vs. Vgs, Vbs 0 ... 1.5'
plot abs(vssp#branch) ylog ylabel 'Id vs. Vgs, Vbs 0 ... 1.5'
dc vdsp 0 -1.6 -0.01 vgsp 0 -1.6 -0.2
plot vssp#branch ylabel 'Id vs. Vds, Vgs 0 ... -1.6'
dc vgsp 0 -1.5 -0.05 temp -40 160 40
plot vssp#branch ylabel 'Id vs. Vds, Temp. -40 ... 160'
plot abs(vssp#branch) ylog ylabel 'Id vs. Vds, Temp. -40 ... 160'
.endc
.end

1
examples/osdi/bsimbulk/test_osdi_win/README
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Place bsimbulk107.osdi here.

137
examples/osdi/bsimcmg/Modelcards/modelcard.nmos
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******** BSIM-MG 105 Sample Modelcard for NMOS ********
** The BSIM-MG sample modelcard below was not extracted/obtained
** from/based on any real technologies. It should not be used for any
** other purposes except for benchmarking the implementation of BSIM-MG
** against BSIM Team's standard results
.model BSIMCMG_osdi_N BSIMCMG_va
+ BULKMOD = 1
+ CGEOMOD = 0
+ TYPE = 1
+ GEOMOD = 0
+ GIDLMOD = 1
+ IGBMOD = 0
+ IGCMOD = 1
+ IIMOD = 0
+ NGATE = 0
+ NQSMOD = 0
+ RDSMOD = 0
+ RGATEMOD = 0
+ RGEOMOD = 0
+ NSEG = 5
+ SDTERM = 0
+ SHMOD = 0
+ AGIDL = 1.00E-12
+ AGISL = 1.00E-12
+ AIGC = 0.014
+ AIGD = 0.0115
+ AIGS = 0.0115
+ AT = 0.001
+ BG0SUB = 1.17
+ BGIDL = 1.00E+07
+ BGISL = 1.00E+07
+ BIGC = 0.005
+ BIGD = 0.00332
+ BIGS = 0.00332
+ CDSC = 0.01
+ CDSCD = 0.01
+ CFD = 0.20E-10
+ CFS = 0.20E-10
+ CGBL = 0
+ CGBO = 0
+ CGDL = 0
+ CGDO = 1e-10
+ CGSL = 0
+ CGSO = 1e-10
+ CIGC = 0.25
+ CIGD = 0.35
+ CIGS = 0.35
+ CIT = 0
+ CKAPPAD = 0.6
+ CKAPPAS = 0.6
+ CTH0 = 0.000001243
+ DELTAVSAT = 0.5
+ DELTAW = 0
+ DELTAWCV = 0
+ DLBIN = 0
+ DLC = 0
+ DLCIGD = 1.00E-09
+ DLCIGS = 1.00E-09
+ DROUT = 1
+ DSUB = 0.5
+ DVT0 = 0.05
+ DVT1 = 0.5
+ DVTSHIFT = 0
+ EASUB = 4.05
+ EGIDL = 0.35
+ EGISL = 0.35
+ EOT = 1.50E-09
+ EOTACC = 1.00E-10
+ EOTBOX = 1.40E-07
+ EPSROX = 3.9
+ EPSRSP = 3.9
+ EPSRSUB = 11.9
+ ETA0 = 0.05
+ ETAMOB = 2
+ ETAQM = 0.54
+ EU = 1.2
+ HFIN = 3.00E-08
+ IGT = 2.5
+ K1RSCE = 0
+ KSATIV = 2
+ KT1 = 0
+ KT1L = 0
+ LINT = -2.00E-09
+ LPE0 = 0
+ LCDSCD = 5.00E-05
+ LCDSCDR = 5.00E-05
+ LRDSW = 0.2
+ LVSAT = 0
+ MEXP = 4
+ NBODY = 1.00E+22
+ NC0SUB = 2.86E+25
+ NI0SUB = 1.10E+16
+ NSD = 2.00E+26
+ PCLM = 0.05
+ PCLMCV = 0.013
+ PCLMG = 0
+ PDIBL1 = 0
+ PDIBL2 = 0.002
+ PHIG = 4.39
+ PHIN = 0.05
+ POXEDGE = 1.1
+ PQM = 0.66
+ PRT = 0
+ PTWG = 0
+ PTWGT = 0.004
+ PVAG = 0
+ QM0 = 0.001
+ QMFACTOR = 2.5
+ RDSW = 200
+ RDSWMIN = 0
+ RDWMIN = 0
+ RSHD = 0
+ RSHS = 0
+ RSWMIN = 0
+ RTH0 = 0.225
+ TBGASUB = 0.000473
+ TBGBSUB = 636
+ TGIDL = -0.007
+ TMEXP = 0
+ TNOM = 25
+ TOXP = 2.10E-09
+ U0 = 0.025
+ UA = 0.55
+ UA1 = 0.001032
+ UCS = 1
+ UCSTE = -0.004775
+ UD = 0
+ UD1 = 0
+ UP = 0
+ UTE = -0.7
+ UTL = 0
+ VSAT = 80000
+ WR = 1
+ WTH0 = 2.60E-07
+ XL = 0

138
examples/osdi/bsimcmg/Modelcards/modelcard.pmos
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@ -0,0 +1,138 @@
******** BSIM-MG 105 Sample Modelcard for PMOS ********
** The BSIM-MG sample modelcard below was not extracted/obtained
** from/based on any real technologies. It should not be used for any
** other purposes except for benchmarking the implementation of BSIM-MG
** against BSIM Team's standard results
*.model pmos1 PMOS level=17
.model BSIMCMG_osdi_P BSIMCMG_va
+BULKMOD = 1
+ CGEOMOD = 0
+ TYPE = 0
+ GEOMOD = 0
+ GIDLMOD = 1
+ IGBMOD = 0
+ IGCMOD = 1
+ IIMOD = 0
+ NGATE = 0
+ NQSMOD = 0
+ RDSMOD = 0
+ RGATEMOD = 0
+ RGEOMOD = 0
+ NSEG = 5
+ SDTERM = 0
+ SHMOD = 0
+ AGIDL = 2E-12
+ AGISL = 2E-12
+ AIGC = 0.007
+ AIGD = 0.006
+ AIGS = 0.006
+ AT = 0.0008234
+ BG0SUB = 1.17
+ BGIDL = 1.50E+08
+ BGISL = 1.50E+08
+ BIGC = 0.0015
+ BIGD = 0.001944
+ BIGS = 0.001944
+ CDSC = 0.003469
+ CDSCD = 0.001486
+ CFD = 0.2e-10
+ CFS = 0.2e-10
+ CGBL = 0
+ CGBO = 0
+ CGDL = 0
+ CGDO = 1E-10
+ CGSL = 0
+ CGSO = 1E-10
+ CIGC = 1
+ CIGD = 1
+ CIGS = 1
+ CIT = 0
+ CKAPPAD = 0.6
+ CKAPPAS = 0.6
+ CTH0 = 1.243E-06
+ DELTAVSAT = 11.56
+ DELTAW = 0
+ DELTAWCV = -1.00E-08
+ DLBIN = 0
+ DLC = -9.2E-09
+ DLCIGD = 5.00E-09
+ DLCIGS = 5.00E-09
+ DROUT = 4.97
+ DSUB = 0.5
+ DVT0 = 0.05006
+ DVT1 = 0.4
+ DVTSHIFT = 0
+ EASUB = 4.05
+ EGIDL = 1.142
+ EGISL = 1.142
+ EOT = 2.10E-09
+ EOTACC = 3.00E-10
+ EOTBOX = 1.40E-07
+ EPSROX = 3.9
+ EPSRSP = 3.9
+ EPSRSUB = 11.9
+ ETA0 = 0.03952
+ ETAMOB = 4
+ ETAQM = 0.54
+ EU = 0.05
+ HFIN = 3.00E-08
+ IGT = 3.5
+ K1RSCE = 0
+ KSATIV = 1.592
+ KT1 = 0.08387
+ KT1L = 0
+ LINT = -2.5E-09
+ LPE0 = 0
+ LCDSCD = 0
+ LCDSCDR = 0
+ LRDSW = 1.3
+ LVSAT = 1441
+ MEXP = 2.491
+ NBODY = 1E+22
+ NC0SUB = 2.86E+25
+ NI0SUB = 1.1E+16
+ NSD = 2E+26
+ PCLM = 0.01
+ PCLMCV = 0.013
+ PCLMG = 1
+ PDIBL1 = 800
+ PDIBL2 = 0.005704
+ PHIG = 4.678
+ PHIN = 0.05
+ POXEDGE = 1.152
+ PQM = 0.66
+ PRT = 0.002477
+ PTWG = 6.322
+ PTWGT = 0.0015
+ PVAG = 200
+ QM0 = 2.183E-12
+ QMFACTOR = 0
+ RDSW = 190.6
+ RDSWMIN = 0
+ RDWMIN = 0
+ RSHD = 0
+ RSHS = 0
+ RSWMIN = 0
+ RTH0 = 0.15
+ TBGASUB = 0.000473
+ TBGBSUB = 636
+ TGIDL = -0.01
+ TMEXP = 0
+ TNOM = 25
+ TOXP = 2.1E-09
+ U0 = 0.02935
+ UA = 1.133
+ UA1 = 0.00134
+ UCS = 0.2672
+ UCSTE = 0
+ UD = 0.0105
+ UD1 = 0
+ UP = 0
+ UTE = 0
+ UTL = 0.001
+ VSAT = 48390
+ WR = 1
+ WTH0 = 2.60E-07
+ XL = 0

38
examples/osdi/bsimcmg/inverter_ro.sp
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@ -0,0 +1,38 @@
*Sample netlist for BSIM-CMG
*Ring Oscillator
.include Modelcards/modelcard.nmos
.include Modelcards/modelcard.pmos
* --- Voltage Sources ---
vdd supply 0 dc=1.0
Vss ss 0 0
* --- Inverter Subcircuit ---
.subckt mg_inv vin vout vdd ss
NP1 vout vin vdd vdd BSIMCMG_osdi_P TFIN=15n L=40n NFIN=10 NRS=1 NRD=1
NN1 vout vin ss ss BSIMCMG_osdi_N TFIN=15n L=40n NFIN=10 NRS=1 NRD=1 D=40n
.ends
* --- Inverter ---
Xinv1 vi 1 supply ss mg_inv
Xinv2 1 2 supply ss mg_inv
Xinv3 2 3 supply ss mg_inv
Xinv4 3 4 supply ss mg_inv
Xinv5 4 vi supply ss mg_inv
Xinv6 vi vo supply 0 mg_inv
* --- Transient Analysis ---
.tran 0.1p 1n
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
run
plot i(vss)
plot v(vo)
.endc
.end

36
examples/osdi/bsimcmg/inverter_transient.sp
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@ -0,0 +1,36 @@
*Sample netlist for BSIM-CMG
* (exec-spice "ngspice %s" t)
*Inverter Transient
.include Modelcards/modelcard.nmos
.include Modelcards/modelcard.pmos
* --- Voltage Sources ---
vdd supply 0 dc=1.0
vsig vi 0 dc=0.5 sin (0.5 0.5 1MEG)
* --- Inverter Subcircuit ---
.subckt mg_inv vin vout vdd gnd
NP1 vout vin vdd vdd BSIMCMG_osdi_P
NN1 vout vin gnd gnd BSIMCMG_osdi_N
.ends
* --- Inverter ---
Xinv1 vi 1 supply 0 mg_inv
Xinv2 1 2 supply 0 mg_inv
Xinv3 2 3 supply 0 mg_inv
Xinv4 3 4 supply 0 mg_inv
Xinv5 4 vo supply 0 mg_inv
* --- Transient Analysis ---
.tran 20n 5u
.print tran v(vi) v(vo)
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
run
plot v(vi) v(vo)
.endc
.end

28
examples/osdi/bsimcmg/netlist_nmos.sp
View File

@ -0,0 +1,28 @@
OSDI BSIMCMG Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 1
VG gg 0 1
VS ss 0 0
VB bb 0 0
* model definitions:
*.model bsim4_osdi bsim4va
.include Modelcards/modelcard.nmos
*OSDI BSIM4:
* Where to put instance parameters channel width and length?
N1 dd gg ss bb BSIMCMG_osdi_N ; W=5u L=0.2u
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
dc Vd 0 2.5 0.01 VG 0 2.5 0.5
* plot source current
plot i(VS)
.endc
.end

28
examples/osdi/bsimcmg/netlist_pmos.sp
View File

@ -0,0 +1,28 @@
OSDI BSIMCMG Test
*.options abstol=1e-15
* one voltage source per MOS terminal:
VD dd 0 -1
VG gg 0 -1
VS ss 0 0
VB bb 0 0
* model definitions:
*
.include Modelcards/modelcard.pmos
*OSDI BSIMCMG:
* Where to put instance parameters channel width and length?
N1 dd gg ss bb BSIMCMG_osdi_P
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
* a DC sweep: drain, gate
dc Vd 0 -1.8 -0.01 VG 0 -1.8 -0.3
* plot source current
plot i(VS)
.endc
.end

54
examples/osdi/bsimcmg/ringosc_17stg.sp
View File

@ -0,0 +1,54 @@
*Sample netlist for BSIM-MG
* (exec-spice "ngspice %s" t)
*17-stage ring oscillator
.include Modelcards/modelcard.nmos
.include Modelcards/modelcard.pmos
* --- Voltage Sources ---
vdd supply 0 dc=1.0
* --- Inverter Subcircuit ---
.subckt mg_inv vin vout vdd gnd
NP1 vout vin vdd vdd BSIMCMG_osdi_P
NN1 vout vin gnd gnd BSIMCMG_osdi_N
.ends
* --- 17 Stage Ring oscillator ---
Xinv1 1 2 supply 0 mg_inv
Xinv2 2 3 supply 0 mg_inv
Xinv3 3 4 supply 0 mg_inv
Xinv4 4 5 supply 0 mg_inv
Xinv5 5 6 supply 0 mg_inv
Xinv6 6 7 supply 0 mg_inv
Xinv7 7 8 supply 0 mg_inv
Xinv8 8 9 supply 0 mg_inv
Xinv9 9 10 supply 0 mg_inv
Xinv10 10 11 supply 0 mg_inv
Xinv11 11 12 supply 0 mg_inv
Xinv12 12 13 supply 0 mg_inv
Xinv13 13 14 supply 0 mg_inv
Xinv14 14 15 supply 0 mg_inv
Xinv15 15 16 supply 0 mg_inv
Xinv16 16 17 supply 0 mg_inv
Xinv17 17 1 supply 0 mg_inv
* --- Initial Condition ---
.ic v(1)=1
.tran 1p 1n
.measure tran t1 when v(1)=0.5 cross=1
.measure tran t2 when v(1)=0.5 cross=7
.measure tran period param='(t2-t1)/3'
.measure tran frequency param='3/(t2-t1)'
.measure tran delay_per_stage param='period/34'
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
run
plot v(1)
.endc
.end

27
examples/osdi/bsimcmg/simple_inverter_dc.sp
View File

@ -0,0 +1,27 @@
*Sample netlist for BSIM-CMG
* (exec-spice "ngspice %s" t)
*Inverter DC
.include Modelcards/modelcard.nmos
.include Modelcards/modelcard.pmos
* --- Voltage Sources ---
vdd supply 0 dc=1.0
vsig vin 0 dc=0.5 sin (0.5 0.5 1MEG)
NP1 vout vin supply supply BSIMCMG_osdi_P
NN1 vout vin 0 0 BSIMCMG_osdi_N
* --- DC Analysis ---
*.dc vsig 0 1 0.01
* --- Transient Analysis ---
.tran 10n 2u
.control
pre_osdi test_osdi_win/bsimcmg.osdi
set xbrushwidth=3
run
plot v(vout) v(vin)
.endc
.end

1
examples/osdi/bsimcmg/test_osdi_win/README
View File

@ -0,0 +1 @@
Place bsimcmg.osdi here.

43
examples/osdi/hicuml0/DFF_Y_ECL_HICUM.sp
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@ -0,0 +1,43 @@
ECL DFF HICUM2.4 test case
*
V6 D GND dc 0 PULSE(-.25 0 0 1P 1P .25N .50N)
V5 D_BAR GND dc 0 PULSE(0 -.25 0 1P 1P .25N .50N)
V4 CLK GND dc 0 PULSE(-0.9 -1.2 0 1P 1P .125N .25N)
V3 CLK_BAR GND dc 0 PULSE(-1.2 -0.9 0 1P 1P .125N .25N)
VVCS NET2 GND DC -0.8
R6 GND NET6 800
R5 GND NET11 800
R4 NET12 VEE 350
VVEE VEE GND DC -2.0
R3 GND NET10 800
R2 NET13 VEE 350
R1 GND Q 800
XQVLGNPN16 NET7 CLK_BAR NET4 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN15 NET5 CLK NET3 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN14 NET1dt Q NET7 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN13 Q NET6 NET9 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN12 NET6 NET11 NET5 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN11 NET11 D_BAR NET8 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN1dt NET4 NET2 NET13 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN9 NET3 NET2 NET12 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN8 NET8 CLK_BAR NET3 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN7 NET9 CLK NET4 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN6 Q NET1dt NET7 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN5 NET1dt NET11 NET9 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN4 NET11 NET6 NET5 VEE dt hicumL0V1p1_c_sbt
XQVLGNPN3 NET6 D NET8 VEE dt hicumL0V1p1_c_sbt
Rdt dt 0 1G
*
.include Modelcards/model-card-hicumL0V1p11_mod.lib
.SAVE V(D) V(CLK) V(Q)
.control
pre_osdi test_osdi_win/HICUML0-2.osdi
TRAN 0.25p 5n
rusage
set color0=white
set xbrushwidth=2
plot V(D) V(CLK) V(Q) ylimit -1.2 0.2
*quit
.endc
.END

59
examples/osdi/hicuml0/DFF_Y_ECL_VBIC.sp
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@ -0,0 +1,59 @@
ECL DFF VBIC test case
*
V6 D GND PULSE(-.25 0 0 1P 1P .25N .50N)
V5 D_BAR GND PULSE(0 -.25 0 1P 1P .25N .50N)
V4 CLK GND PULSE(-0.9 -1.2 0 1P 1P .125N .25N)
V3 CLK_BAR GND PULSE(-1.2 -0.9 0 1P 1P .125N .25N)
VVCS NET2 GND DC -0.8
R6 GND NET6 800
R5 GND NET11 800
R4 NET12 VEE 350
VVEE VEE GND DC -2.0
R3 GND NET10 800
R2 NET13 VEE 350
R1 GND Q 800
QVLGNPN16 NET7 CLK_BAR NET4 VEE NPN_VBIC_VLG
QVLGNPN15 NET5 CLK NET3 VEE NPN_VBIC_VLG
QVLGNPN14 NET10 Q NET7 VEE NPN_VBIC_VLG
QVLGNPN13 Q NET6 NET9 VEE NPN_VBIC_VLG
QVLGNPN12 NET6 NET11 NET5 VEE NPN_VBIC_VLG
QVLGNPN11 NET11 D_BAR NET8 VEE NPN_VBIC_VLG
QVLGNPN10 NET4 NET2 NET13 VEE NPN_VBIC_VLG
QVLGNPN9 NET3 NET2 NET12 VEE NPN_VBIC_VLG
QVLGNPN8 NET8 CLK_BAR NET3 VEE NPN_VBIC_VLG
QVLGNPN7 NET9 CLK NET4 VEE NPN_VBIC_VLG
QVLGNPN6 Q NET10 NET7 VEE NPN_VBIC_VLG
QVLGNPN5 NET10 NET11 NET9 VEE NPN_VBIC_VLG
QVLGNPN4 NET11 NET6 NET5 VEE NPN_VBIC_VLG
QVLGNPN3 NET6 D NET8 VEE NPN_VBIC_VLG
*
.MODEL NPN_VBIC_VLG NPN LEVEL=4
+TNOM = 27 RCI = 1E3 RCX = 50
+VO = 1.5 GAMM = 3.402097E-11 HRCF = 1
+RBX = 243 RBI = 20 RE = 30
+RS = 0 RBP = 0 IS = 8.084033E-18
+NF = 1 NR = 1.005 FC = 0.5
+CJE = 2.083234E-15 PE = 0.8793669 ME = 0.3108762
+CJC = 1.803275E-15 PC = 0.5512188 MC = 0.4454263
+CJCP = 8E-15 PS = 0.66956 MS = 0.2243
+IBEI = 4.542609E-20 WBE = 1 NEI = 1
+IBEN = 3.275162E-16 NEN = 1.5543186 IBCI = 3.594252E-19
+NCI = 0.996 IBCN = 1.717776E-17 NCN = 1.202521
+AVC1 = 3E-4 AVC2 = 1E-5 ISP = 1.332E-19
+WSP = 1 NFP = 1 IBEIP = 0
+IBENP = 0 IBCIP = 0 NCIP = 1
+IBCNP = 0 NCNP = 2 VEF = 109.6523
+VER = 2.2052435 IKF = 6.03524E-3 IKR = 1.807895E-4
+IKP = 2.908576E-5 TF = 1.1E-12 XTF = 21.5423
+VTF = 12.4758677 ITF = 0.0175231 TR = 2.23542E-9
.SAVE V(D) V(CLK) V(Q)
.control
TRAN 0.25p 5n
rusage
set color0=white
set xbrushwidth=2
plot V(D) V(CLK) V(Q)
*quit
.endc
.END

46
examples/osdi/hicuml0/ECL-RO-5.cir
View File

@ -0,0 +1,46 @@
.title ECL nor gate ring oscillator, 9 stages, 734 MHz
.include "Modelcards/model-card-hicumL0V1p11_mod.lib"
.subckt nor in1 in2 a1 a2 vee GND
XQ1 Net-_R1-Pad2_ IN1 Net-_Q1-Pad3_ VEE DT1 hicumL0V1p1_c_sbt
XQ2 Net-_R1-Pad2_ IN2 Net-_Q1-Pad3_ VEE DT1 hicumL0V1p1_c_sbt
XQ3 Net-_R2-Pad2_ Net-_R3-Pad2_ Net-_Q1-Pad3_ VEE DT1 hicumL0V1p1_c_sbt
XQ4 GND Net-_R2-Pad2_ A1 VEE DT1 hicumL0V1p1_c_sbt
XQ5 GND Net-_R1-Pad2_ A2 VEE DT1 hicumL0V1p1_c_sbt
Rt1 DT1 0 1G
R1 GND Net-_R1-Pad2_ 220
R2 GND Net-_R2-Pad2_ 220
R3 GND Net-_R3-Pad2_ 575
R4 Net-_R3-Pad2_ VEE 1.92k
R5 Net-_Q1-Pad3_ VEE 780
Ra1 A1 VEE 510
Ra2 A2 VEE 510
.ends
X1 out9 out9 a1 out1 vee gnd nor
X2 out1 out1 a2 out2 vee gnd nor
X3 out2 out2 a3 out3 vee gnd nor
X4 out3 out3 a4 out4 vee gnd nor
X5 out4 out4 a5 out5 vee gnd nor
X6 out5 out5 a2 out6 vee gnd nor
X7 out6 out6 a3 out7 vee gnd nor
X8 out7 out7 a4 out8 vee gnd nor
X9 out8 out8 a5 out9 vee gnd nor
V1 VEE GND -5.2
.tran 0.02n 200n
.control
pre_osdi test_osdi_win/HICUML0-2.osdi
run
rusage
plot out9 xlimit 100n 110n
linearize out9
fft out9
plot mag(out9) xlimit 0 2G ylimit 0 0.5
.endc
.end

25
examples/osdi/hicuml0/ECL-RO.cir
View File

@ -0,0 +1,25 @@
.title KiCad schematic
.include "Modelcards/model-card-hicumL0V1p11_mod.lib"
V2 IN1 GND dc -1.75 pulse(-1.75 -0.9 0 1n 1n 5u 10u)
V1 VEE GND -5.2
Ra1 A1 VEE 510
XQ5 GND Net-_Q1-Pad1_ A2 VEE DT hicumL0V1p1_c_sbt
XQ4 GND Net-_Q3-Pad1_ A1 VEE DT hicumL0V1p1_c_sbt
R4 Net-_Q3-Pad2_ VEE 1.92k
XQ2 Net-_Q1-Pad1_ IN2 Net-_Q1-Pad3_ VEE DT hicumL0V1p1_c_sbt
XQ1 Net-_Q1-Pad1_ IN1 Net-_Q1-Pad3_ VEE DT hicumL0V1p1_c_sbt
R5 Net-_Q1-Pad3_ VEE 780
XQ3 Net-_Q3-Pad1_ Net-_Q3-Pad2_ Net-_Q1-Pad3_ VEE DT hicumL0V1p1_c_sbt
R2 GND Net-_Q3-Pad1_ 220
R1 GND Net-_Q1-Pad1_ 220
R3 GND Net-_Q3-Pad2_ 575
Ra2 A2 VEE 510
V3 In2 GND dc -1.75 pulse(-1.75 -0.9 0 1n 1n 2.5u 5u)
Rt1 DT GND 1G
.tran 0.1n 100u
.control
pre_osdi test_osdi_win/HICUML0-2.osdi
run
plot a1 a2+2 in1+4 in2+6
.endc
.end

303
examples/osdi/hicuml0/KiCad/ECL-RO.kicad_pro
View File

@ -0,0 +1,303 @@
{
"board": {
"layer_presets": []
},
"boards": [],
"cvpcb": {
"equivalence_files": []
},
"erc": {
"erc_exclusions": [],
"meta": {
"version": 0
},
"pin_map": [
[
0,
0,
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0,
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0,
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],
[
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],
[
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[
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0,
0,
0,
0,
0,
0,
0,
0,
2
],
[
1,
1,
1,
1,
1,
0,
1,
1,
1,
1,
1,
2
],
[
0,
0,
0,
1,
0,
0,
1,
0,
0,
0,
0,
2
],
[
0,
2,
1,
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0,
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2
],
[
0,
2,
0,
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0,
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0,
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0,
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],
[
0,
2,
1,
1,
0,
0,
1,
0,
2,
0,
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],
[
2,
2,
2,
2,
2,
2,
2,
2,
2,
2,
2,
2
]
],
"rule_severities": {
"bus_definition_conflict": "error",
"bus_entry_needed": "error",
"bus_label_syntax": "error",
"bus_to_bus_conflict": "error",
"bus_to_net_conflict": "error",
"different_unit_footprint": "error",
"different_unit_net": "error",
"duplicate_reference": "error",
"duplicate_sheet_names": "error",
"extra_units": "error",
"global_label_dangling": "warning",
"hier_label_mismatch": "error",
"label_dangling": "error",
"lib_symbol_issues": "warning",
"multiple_net_names": "warning",
"net_not_bus_member": "warning",
"no_connect_connected": "warning",
"no_connect_dangling": "warning",
"pin_not_connected": "error",
"pin_not_driven": "error",
"pin_to_pin": "warning",
"power_pin_not_driven": "error",
"similar_labels": "warning",
"unannotated": "error",
"unit_value_mismatch": "error",
"unresolved_variable": "error",
"wire_dangling": "error"
}
},
"libraries": {
"pinned_footprint_libs": [],
"pinned_symbol_libs": []
},
"meta": {
"filename": "ECL-RO.kicad_pro",
"version": 1
},
"net_settings": {
"classes": [
{
"bus_width": 12.0,
"clearance": 0.2,
"diff_pair_gap": 0.25,
"diff_pair_via_gap": 0.25,
"diff_pair_width": 0.2,
"line_style": 0,
"microvia_diameter": 0.3,
"microvia_drill": 0.1,
"name": "Default",
"pcb_color": "rgba(0, 0, 0, 0.000)",
"schematic_color": "rgba(0, 0, 0, 0.000)",
"track_width": 0.25,
"via_diameter": 0.8,
"via_drill": 0.4,
"wire_width": 6.0
}
],
"meta": {
"version": 2
},
"net_colors": null
},
"pcbnew": {
"last_paths": {
"gencad": "",
"idf": "",
"netlist": "",
"specctra_dsn": "",
"step": "",
"vrml": ""
},
"page_layout_descr_file": ""
},
"schematic": {
"annotate_start_num": 0,
"drawing": {
"default_line_thickness": 6.0,
"default_text_size": 50.0,
"field_names": [],
"intersheets_ref_own_page": false,
"intersheets_ref_prefix": "",
"intersheets_ref_short": false,
"intersheets_ref_show": false,
"intersheets_ref_suffix": "",
"junction_size_choice": 3,
"label_size_ratio": 0.375,
"pin_symbol_size": 25.0,
"text_offset_ratio": 0.15
},
"legacy_lib_dir": "",
"legacy_lib_list": [],
"meta": {
"version": 1
},
"net_format_name": "Spice",
"ngspice": {
"fix_include_paths": true,
"fix_passive_vals": false,
"meta": {
"version": 0
},
"model_mode": 4,
"workbook_filename": "555bip.wbk"
},
"page_layout_descr_file": "",
"plot_directory": "",
"spice_adjust_passive_values": false,
"spice_external_command": "C:\\Spice64\\bin\\ngspice-2022-osdi.exe \"%I\"",
"subpart_first_id": 65,
"subpart_id_separator": 0
},
"sheets": [
[
"35461762-06be-4c9e-bf12-e38db35c4dcf",
""
]
],
"text_variables": {}
}

1473
examples/osdi/hicuml0/KiCad/ECL-RO.kicad_sch
File diff suppressed because it is too large
View File

107
examples/osdi/hicuml0/KiCad/ECL_Bip.kicad_sym
View File

@ -0,0 +1,107 @@
(kicad_symbol_lib (version 20211014) (generator kicad_symbol_editor)
(symbol "npn" (pin_numbers hide) (pin_names (offset 0) hide) (in_bom yes) (on_board yes)
(property "Reference" "Q1" (id 0) (at 6.096 1.6511 0)
(effects (font (size 1.27 1.27)) (justify left))
)
(property "Value" "npn" (id 1) (at 6.096 -0.8889 0)
(effects (font (size 1.27 1.27)) (justify left))
)
(property "Footprint" "" (id 2) (at 0 0 0)
(effects (font (size 1.27 1.27) italic) hide)
)
(property "Datasheet" "" (id 3) (at -2.54 0 0)
(effects (font (size 1.27 1.27)) (justify left) hide)
)
(property "Spice_Primitive" "Q" (id 4) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "Spice_Model" "NP" (id 5) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "Spice_Netlist_Enabled" "Y" (id 6) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "Spice_Lib_File" "bipmod.lib" (id 7) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "ki_keywords" "Transistor Double NPN" (id 8) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "ki_description" "100mA IC, 30V Vce, Double NPN Transistors, Current mirror configuration, SOT-143" (id 9) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(property "ki_fp_filters" "SOT?143*" (id 10) (at 0 0 0)
(effects (font (size 1.27 1.27)) hide)
)
(symbol "npn_0_0"
(pin passive line (at 6.604 -5.08 90) (length 2.54)
(name "S" (effects (font (size 1.27 1.27))))
(number "4" (effects (font (size 1.27 1.27))))
)
(pin passive line (at 8.128 -5.08 90) (length 2.54)
(name "DT" (effects (font (size 1.27 1.27))))
(number "5" (effects (font (size 1.27 1.27))))
)
)
(symbol "npn_0_1"
(polyline
(pts
(xy 2.54 0)
(xy 3.302 0)
)
(stroke (width 0.1524) (type default) (color 0 0 0 0))
(fill (type none))
)
(polyline
(pts
(xy 5.08 -2.54)
(xy 3.175 -0.635)
)
(stroke (width 0) (type default) (color 0 0 0 0))
(fill (type none))
)
(polyline
(pts
(xy 5.08 2.54)
(xy 3.175 0.635)
)
(stroke (width 0) (type default) (color 0 0 0 0))
(fill (type none))
)
(polyline
(pts
(xy 3.175 -1.905)
(xy 3.175 1.905)
(xy 3.175 1.905)
)
(stroke (width 0.508) (type default) (color 0 0 0 0))
(fill (type outline))
)
(polyline
(pts
(xy 3.81 -1.778)
(xy 4.318 -1.27)
(xy 4.826 -2.286)
(xy 3.81 -1.778)
(xy 3.81 -1.778)
)
(stroke (width 0) (type default) (color 0 0 0 0))
(fill (type outline))
)
)
(symbol "npn_1_1"
(pin passive line (at 5.08 5.08 270) (length 2.54)
(name "C" (effects (font (size 1.27 1.27))))
(number "1" (effects (font (size 1.27 1.27))))
)
(pin passive line (at 0 0 0) (length 2.54)
(name "B" (effects (font (size 1.27 1.27))))
(number "2" (effects (font (size 1.27 1.27))))
)
(pin passive line (at 5.08 -5.08 90) (length 2.54)
(name "E" (effects (font (size 1.27 1.27))))
(number "3" (effects (font (size 1.27 1.27))))
)
)
)
)

3
examples/osdi/hicuml0/KiCad/sym-lib-table
View File

@ -0,0 +1,3 @@
(sym_lib_table
(lib (name "ECL_Bip")(type "KiCad")(uri "${KIPRJMOD}/ECL_Bip.kicad_sym")(options "")(descr ""))
)

40
examples/osdi/hicuml0/Modelcards/model-card-hicumL0V1p11_mod.lib
View File

@ -0,0 +1,40 @@
********************************************************************************
********************************************************************************
* HICUM Level0 Version 1.1 model cards for testing
********************************************************************************
********************************************************************************
* 1D transistor: Isothermal Simulation and Temperature dependence
********************************************************************************
********************************************************************************
* Complete transistor: Isothermal Simulation with substrate diode
********************************************************************************
.subckt hicumL0V1p1_c_sbt c b e s dt
*qhcm0 c b e s dt hic0_full
nqhcm0 c b e s dt hic0_full
*.model hic0_full npn
.ends
.model hic0_full hicumL0va
+ level=7 is=1.3525E-18 vef=8.0 iqf=3.0e-2 iqr=1e6
+ iqfh=1e6 tfh=1e-8 ibes=1.16E-20 mbe=1.015 ires=1.16e-16 mre=2.0 ibcs=1.16e-20
+ mbc=1.015 mcf=1.0 mcr=1 kavl=0.9488 eavl=11.96e10 alkav=0.825e-4
+ aleav=0.196e-3 rbi0=71.76 rbx=8.83 fgeo=0.73 re=12.534 rcx=9.165 iscs=1.0e-17 msc=1.0
+ cje0=8.11e-15 vde=0.95 ze=0.5 aje=1.8 cjci0=1.16e-15 vdci=0.8 zci=0.333
+ vptci=46 cjcx0=5.4e-15 vdcx=0.7 zcx=0.333 vptcx=100 fbc=0.1526 vr0e=1.6 vr0c=8.0
+ cjs0=3.64e-14 vds=0.6 zs=0.447 vpts=100 t0=4.75e-12 dt0h=2.1e-12 tbvl=4.0e-12
+ tef0=1.8e-12 gte=1.4 thcs=30.0e-12 ahc=0.75 tr=0.0 rci0=127.8 vlim=0.7
+ vces=0.1 vpt=5 cbepar=1.13e-15 cbcpar=2.97e-15 kf=1.43e-8 af=2.0 vgb=1.17
+ alt0=0.0 kt0=0.0 zetaci=1.6 alvs=1.0e-3 alces=0.4e-3 zetarbi=0.588
+ zetarbx=0.206 zetarcx=0.223 zetare=0.0 vge=1.1386 vgc=1.1143 vgs=1.15 f1vg=-1.02377e-4
+ f2vg=4.3215e-4 zetact=3.5 zetabet=4.0 rth=0.0 cth=0.0
+ tnom=27.0 type=1 ; npn=1 pnp=0
*+ dt=0.0
********************************************************************************
* Complete test transistor: default
********************************************************************************
.subckt hicumL0V11_default c b e s dt
qhcm0 c b e s dt hic0_full
.ends hicumL0V11_default
********************************************************************************

23
examples/osdi/hicuml0/bip_subsmod.sp
View File

@ -0,0 +1,23 @@
Bip model in subckt Gummel Test Ic=f(Vc,Vb)
VB B 0 0.5
VC C 0 1.0
VS S 0 0.0
X1 C B 0 S bip_default
.control
dc vb 0.2 1.4 0.01
plot abs(i(vc)) abs(i(vb)) abs(i(vs)) ylimit 0.1p 100m ylog
plot abs(i(vc))/abs(i(vb)) vs abs(i(vc)) xlog xlimit 100p 100m ylimit 0 200 retraceplot
.endc
********************************************************************************
* Complete test transistor: default
********************************************************************************
.subckt bip_default c b e s
qhcm0 c b e s hic0_full
.model hic0_full npn
.ends hicumL0V11_default
********************************************************************************
.end

20
examples/osdi/hicuml0/hic0_gum.sp
View File

@ -0,0 +1,20 @@
HICUM0 Gummel Test Ic=f(Vc,Vb)
VB B 0 0.5
VC C 0 1.0
VS S 0 0.0
*AQ1 C B 0 S DT hicumL0V1p1_c_sbt
XQ1 C B 0 S DT hicumL0V1p1_c_sbt
Rdt dt 0 1G
.control
pre_osdi test_osdi_win/HICUML0-2.osdi
dc vb 0.2 1.4 0.01
set xbrushwidth=2
plot abs(i(vc)) abs(i(vb)) abs(i(vs)) ylimit 0.1p 100m ylog
plot abs(i(vc))/abs(i(vb)) vs abs(i(vc)) xlog xlimit 100p 100m ylimit 0 200 retraceplot
.endc
.include Modelcards/model-card-hicumL0V1p11_mod.lib
.end

20
examples/osdi/hicuml0/hic0_out.sp
View File

@ -0,0 +1,20 @@
HICUM0 Output Test Ic=f(Vc,Ib)
IB 0 B 200n
VC C 0 2.0
VS S 0 0.0
X1 C B 0 S DT hicumL0V1p1_c_sbt
Rdt dt 0 1G
.control
pre_osdi test_osdi_win/HICUML0-2.osdi
dc vc 0.0 3.0 0.05 ib 10u 100u 10u
set xbrushwidth=2
plot abs(i(vc))
*plot v(dt)
.endc
.include Modelcards/model-card-hicumL0V1p11_mod.lib
.end

1
examples/osdi/hicuml0/test_osdi_win/README
View File

@ -0,0 +1 @@
Place HICUML0-2.osdi here.

35
examples/osdi/hicuml0/vbic_out.sp
View File

@ -0,0 +1,35 @@
HICUM0 Output Test Ic=f(Vc,Ib)
IB 0 B 200n
VC C 0 2.0
VS S 0 0.0
Q1 C B 0 S NPN_VBIC_VLG
.control
dc vc 0.0 5.0 0.05 ib 10u 100u 10u
run
plot abs(i(vc))
plot v(dt)
.endc
.MODEL NPN_VBIC_VLG NPN LEVEL=4
+TNOM = 27 RCI = 1E3 RCX = 50
+VO = 1.5 GAMM = 3.402097E-11 HRCF = 1
+RBX = 243 RBI = 20 RE = 30
+RS = 0 RBP = 0 IS = 8.084033E-18
+NF = 1 NR = 1.005 FC = 0.5
+CJE = 2.083234E-15 PE = 0.8793669 ME = 0.3108762
+CJC = 1.803275E-15 PC = 0.5512188 MC = 0.4454263
+CJCP = 8E-15 PS = 0.66956 MS = 0.2243
+IBEI = 4.542609E-20 WBE = 1 NEI = 1
+IBEN = 3.275162E-16 NEN = 1.5543186 IBCI = 3.594252E-19
+NCI = 0.996 IBCN = 1.717776E-17 NCN = 1.202521
+AVC1 = 3E-4 AVC2 = 1E-5 ISP = 1.332E-19
+WSP = 1 NFP = 1 IBEIP = 0
+IBENP = 0 IBCIP = 0 NCIP = 1
+IBCNP = 0 NCNP = 2 VEF = 109.6523
+VER = 2.2052435 IKF = 6.03524E-3 IKR = 1.807895E-4
+IKP = 2.908576E-5 TF = 1.1E-12 XTF = 21.5423
+VTF = 12.4758677 ITF = 0.0175231 TR = 2.23542E-9
.end

76
examples/osdi/mextram/Modelcards/mex_model.lib
View File

@ -0,0 +1,76 @@
*MEXTRAM modelcard
.model BJTRF1 bjt504tva
*+ LEVEL=6
+MULT=1.000E+00
+TREF=25.000E+00
+DTA=0.000E+00
+EXMOD=1.000E+00
+EXPHI=0.000E+00
+EXAVL=1.000E+00
+IS=23.571E-18
+IK=231.660E-03
+VER=2.100E+00
+VEF=36.001E+00
+BF=186.538E+00
+IBF=1.140E-15
+MLF=2.000E+00
+XIBI=0.000E+00
+BRI=9.231E+00
+IBR=61.600E-15
+VLR=400.000E-03
+XEXT=648.148E-03
+WAVL=1.064E-06
+VAVL=3.330E+00
+SFH=882.471E-03
+RE=949.668E-03
+RBC=27.769E+00
+RBV=32.004E+00
+RCBLX=1.0
+RCBLI=1.0
+RCC=18.026E+00
+RCV=237.417E+00
+SCRCV=882.839E+00
+IHC=3.370E-03
+AXI=300.000E-03
+CJE=55.566E-15
+VDE=900.000E-03
+PE=500.000E-03
+XCJE=52.478E-03
+CJC=25.153E-15
+VDC=660.000E-03
+PC=450.000E-03
+XP=310.000E-03
+MC=500.000E-03
+XCJC=122.100E-03
+MTAU=1.000E+00
+TAUE=6.200E-12
+TAUB=977.273E-15
+TEPI=7.980E-12
+TAUR=64.400E-12
+DEG=0.000E+00
+XREC=0.000E+00
+AQBO=701.246E-03
+AE=308.246E-03
+AB=846.000E-03
+AEPI=2.500E+00
+AEX=619.000E-03
+AC=1.580E+00
+DVGBF=52.000E-03
+DVGBR=0.000E+00
+VGB=1.197E+00
+VGC=1.200E+00
+VGJ=1.200E+00
+DVGTE=1.202E+00
+AF=2.350E+00
+KF=47.298E-09
+KFN=1.000E-09
+ISS=18.480E-18
+IKS=219.348E-06
+CJS=146.628E-15
+VDS=542.048E-03
+PS=314.095E-03
+VGS=1.221E+00
+AS=1.580E+00
+RTH=300
+CTH=3E-09

18
examples/osdi/mextram/mex_gum.sp
View File

@ -0,0 +1,18 @@
MEXTRAM Gummel Test Ic,b,s=f(Vc,Ib)
.include Modelcards/mex_model.lib
VB B 0 0.5
VC C 0 2.0
VS S 0 0.0
NQ1 C B 0 S DT BJTRF1
.control
pre_osdi test_osdi_win/bjt504t.osdi
dc vb 0.2 1.4 0.01
plot abs(i(vc)) abs(i(vb)) abs(i(vs)) ylog xlimit 0.3 1.4 ylimit 1e-12 100e-3
plot abs(i(vc))/abs(i(vb)) vs abs(-i(vc)) xlog xlimit 1e-09 10e-3 ylimit 0 150
.endc
.end

16
examples/osdi/mextram/mex_out.sp
View File

@ -0,0 +1,16 @@
MEXTRAM Output Test Ic=f(Vc,Ib)
.include Modelcards/mex_model.lib
IB 0 b 1u
VC C 0 2.0
VS S 0 0.0
NQ1 C B 0 S T BJTRF1
.control
pre_osdi test_osdi_win/bjt504t.osdi
dc vc 0 6.0 0.05 ib 1u 8u 1u
plot abs(i(vc)) xlabel Vce title Output-Characteristic
.endc
.end

1
examples/osdi/mextram/test_osdi_win/README
View File

@ -0,0 +1 @@
Place bjt505.osdi here.

641
examples/osdi/mixed-models/Modelcards/model.l
View File

@ -0,0 +1,641 @@
* model parameters fron BSIMBULK 106.2
.model BSIMBULK_osdi_N bsimbulk
+level=77
+TYPE = 1
+GEOMOD = 0
+RGEOMOD = 0
+COVMOD = 1
+RDSMOD = 0
+GIDLMOD = 1
+IGCMOD = 0
+IGBMOD = 0
+LLONG = 2e-6
+WWIDE = 1e-5
+XL = -1.7e-8
+XW = 1.1e-8
+LINT = 0
+WINT = 0
+DLC = 0
+DWC = 0
+TOXE = 1.74e-9
+TOXP = 1.7e-9
+NDEP = 4.6e23
+NSD = 1e26
+NGATE = 8.5e25
+VFB = -1.02
+EPSROX = 3.9
+EPSRSUB = 11.9
+NI0SUB = 1.1e16
+XJ = 1.5e-7
+DMCG = 0
+DMDG = 0
+DMCGT = 0
+CIT = 1e-8
+CDSCD = 0.001
+CDSCB = 0
+CDSCBL = 0.007
+CDSCBLEXP = 1
+NFACTOR = 0.002
+NFACTORL = 2.1e-8
+NFACTORLEXP = 6.264
+NDEPL1 = 0.096
+NDEPLEXP1 = 1
+NDEPL2 = -0.0032
+NDEPLEXP2 = 2.05
+DVTP0 = 7.5e-7
+DVTP1 = -4.4e-7
+NDEPW = -0.1548
+NDEPWEXP = 0.7441
+NDEPWL = 0
+NDEPWLEXP = 0.2
+K2W = 0
+AGIDL = 3.728e-8
+AGIDLL = -0.04815
+AGIDLW = -0.0341
+BGIDL = 8.123e9
+CGIDL = 1.21e-6
+EGIDL = -2.952
+PHIN = 0.05
+K2L = 0.001636
+K2 = -0.014
+ETA0 = 8.416e-6
+ETAB = -5.561e-5
+ETABEXP = 2.155
+DSUB = 3
+VSAT = 6.4e4
+VSATW = 0.05
+VSATWEXP = 1
+DELTA = 0.15
+DELTAL = 0.1
+DELTALEXP = 1e-5
+U0 = 0.04546
+ETAMOB = 1.5
+U0L = 0.025
+U0LEXP = 0.95
+UA = 0.4007
+UAW = 0.05
+UAWEXP = 1
+UAL = 0.00475
+UALEXP = 1.118
+EUW = -0.02
+EUWEXP = 1
+EUL = 0.001
+EULEXP = 1
+EU = 1.9
+UDL = 1e-15
+UDLEXP = 1
+UD = 1.042e-5
+UCS = 2
+UCW = 0
+UCWEXP = 1
+UC = 1e-07
+UCL = 2.5e4
+UCLEXP = 1
+PCLM = 0.15
+PCLML = 0.01
+PCLMLEXP = 0.4
+PCLMG = 0
+PSCBE1 = 5
+PSCBE2 = 1.29e-12
+PDITS = 0
+PDITSL = 0
+PDITSD = 0
+RSWMIN = 0
+RSW = 100
+RDWMIN = 0
+RDW = 100
+RDSW = 20
+RDSWMIN = 0
+PRWG = 1
+PRWB = 0
+WR = 1
+RSH = 0
+PDIBLCB = 0
+PDIBLC = 0.01
+PDIBLCL = 1e-5
+PDIBLCLEXP = 1e-6
+PVAG = 0
+PTWG = 0.2
+PTWGL = 3e4
+PTWGLEXP = 5e-6
+FPROUT = 0
+CF = 0
+CFRCOEFF = 1
+CGSO = 2.5e-10
+CGDO = 2.5e-10
+CGSL = 1.2e-10
+CGDL = 1.2e-10
+CKAPPAS = 1.25
+CKAPPAD = 1.25
+CGBO = 0
+ADOS = 0
+BDOS = 1
+QM0 = 0.001
+ETAQM = 0.54
+NDEPCV = 8e23
+VFBCV = -0.95
+VSATCV = 1e5
+PCLMCV = 0
+PSAT = 0.46
+PSATL = 6
+PSATLEXP = 0.06
+TNFACTOR = 0
+TETA0 = 0
+UTE = -1.4
+UTEL = -0.001
+UA1 = -0.0011
+UA1L = 0
+UC1 = 0
+UD1 = 0
+UD1L = 0
+UCSTE = -0.005
+PRT = 0
+AT = -0.05
+ATL = -0.1
+TDELTA = -0.0048
+PTWGT = -0.002
+PTWGTL = 0.01
+KT1 = -0.115
+KT1EXP = 1
+KT1L = 1.286e-9
+KT2 = -0.003157
+K2LEXP = 1.698
+K2WEXP = 0.005
+TBGASUB = 0
+AIGS = 0.0136
+BIGS = 0.00171
+CIGS = 0.075
+AIGSL = 0
+AIGD = 0.0136
+BIGD = 0.00171
+CIGD = 0.075
+AIGDL = 0
+AIGC = 0.01285
+LAIGC = 2.132e-6
+BIGC = 0.0013
+CIGC = 0.013
+AIGCL = -0.01227
+PIGCD = 1
+PIGCDL = 6.196
+AIGBINV = 0.015
+BIGBINV = 0.000949
+CIGBINV = 0.006
+EIGBINV = 1.1
+NIGBINV = 3
+AIGBACC = 0.01751
+BIGBACC = 8.307
+CIGBACC = -898.7
+NIGBACC = 1
+LPSAT = 0
+WPSAT = 0
+PPSAT = 0
+PSATB = 0
+PSATX = 3
+WVSAT = 0
+PVSAT = 0
+WPTWG = 0
+PPTWG = 0
+TNOM = 25
+WDVTP0 = 0
+WDVTP1 = 0
+LUTE = 0.04574
+LUA1 = 8.365e-5
+LAT = 0
+DVTP2 = 0
+DVTP3 = 0
+DVTP4 = 0
+DVTP5 = 0
+VSATL = 1350
+VSATLEXP = 0.00033
+SCA = 0
+SCB = 0
+SCC = 0
+SC = 0
.model BSIMBULK_osdi_P bsimbulk
+level=77
+TYPE = -1
+GEOMOD = 0
+RGEOMOD = 0
+RGATEMOD = 0
+RBODYMOD = 0
+IGCMOD = 0
+IGBMOD = 0
+COVMOD = 1
+RDSMOD = 2
+GIDLMOD = 0
+TNOIMOD = 0
+SHMOD = 0
+TOXE = 2.34e-9
+TOXP = 1.925e-9
+DTOX = 0
+EPSROX = 3.9
+TNOM = 25
+XL = 0
+XW = 0
+LINT = 0
+LLONG = 1000000
+LL = 0
+LW = 0
+LWL = 0
+LLN = 1
+LWN = 1
+WINT = -9.0134104e-9
+WL = 0
+WW = 0
+WWL = 0
+WLN = 1
+WWN = 1
+WWIDE = 1000000
+DLC = 0
+LLC = 0
+LWC = 0
+LWLC = 0
+DWC = 0
+WLC = 0
+WWC = 0
+WWLC = 0
+JSS = 0.0001
+JSD = 0.0001
+JSWS = 0
+JSWD = 0
+JSWGS = 0
+JSWGD = 0
+NJS = 1
+NJD = 1
+IJTHSFWD = 0.1
+IJTHDFWD = 0.1
+IJTHSREV = 0.1
+IJTHDREV = 0.1
+BVS = 10
+BVD = 10
+XJBVS = 1
+XJBVD = 1
+JTSS = 0
+JTSD = 0
+JTSSWS = 0
+JTSSWD = 0
+JTSSWGS = 0
+JTSSWGD = 0
+JTWEFF = 0
+NJTS = 20
+NJTSD = 20
+NJTSSW = 20
+NJTSSWD = 20
+NJTSSWG = 20
+NJTSSWGD = 20
+VTSS = 10
+VTSD = 10
+VTSSWS = 10
+VTSSWD = 10
+VTSSWGS = 10
+VTSSWGD = 10
+CJS = 0.0005
+CJD = 0.0005
+CJSWS = 5e-10
+CJSWD = 5e-10
+CJSWGS = 0
+CJSWGD = 0
+PBS = 1
+PBD = 1
+PBSWS = 1
+PBSWD = 1
+PBSWGS = 1
+PBSWGD = 1
+MJS = 0.5
+MJD = 0.5
+MJSWS = 0.33
+MJSWD = 0.33
+MJSWGS = 0.33
+MJSWGD = 0.33
+TPB = 0
+TCJ = 0
+TPBSW = 0
+TCJSW = 0
+TPBSWG = 0
+TCJSWG = 0
+XTIS = 3
+XTID = 3
+XTSS = 0.02
+XTSD = 0.02
+XTSSWS = 0.02
+XTSSWD = 0.02
+XTSSWGS = 0.02
+XTSSWGD = 0.02
+TNJTS = 0
+TNJTSD = 0
+TNJTSSW = 0
+TNJTSSWD = 0
+TNJTSSWG = 0
+TNJTSSWGD = 0
+NOIA = 6.25e40
+NOIB = 3.125e25
+NOIC = 8.75e8
+EM = 41000000
+EF = 1
+LINTNOI = 0
+NTNOI = 1
+TNOIA = 0
+TNOIB = 0
+TNOIC = 0
+RNOIA = 0.577
+RNOIB = 0.5164
+RNOIC = 0.395
+DWJ = 0
+DMCG = 0
+DMCI = 0
+DMDG = 0
+DMCGT = 0
+XGW = 0
+XGL = 0
+GBMIN = 1e-12
+RSHG = 0.1
+RBPB = 50
+RBPD = 50
+RBPS = 50
+RBDB = 50
+RBSB = 50
+RBPS0 = 50
+RBPSL = 0
+RBPSW = 0
+RBPSNF = 0
+RBPD0 = 50
+RBPDL = 0
+RBPDW = 0
+RBPDNF = 0
+RBPBX0 = 100
+RBPBXL = 0
+RBPBXW = 0
+RBPBXNF = 0
+RBPBY0 = 100
+RBPBYL = 0
+RBPBYW = 0
+RBPBYNF = 0
+RBSBX0 = 100
+RBSBY0 = 100
+RBDBX0 = 100
+RBDBY0 = 100
+RBSDBXL = 0
+RBSDBXW = 0
+RBSDBXNF = 0
+RBSDBYL = 0
+RBSDBYW = 0
+RBSDBYNF = 0
+XRCRG1 = 12
+XRCRG2 = 1
+NGCON = 1
+NDEP = 8.062e23
+NDEPL1 = 1.2139
+NDEPLEXP1 = 1.9088
+NDEPL2 = -1.1825
+NDEPLEXP2 = 1.9173
+NDEPW = 0.065035
+NDEPWEXP = 0.48882
+NDEPWL = 0.00040893
+NDEPWLEXP = 1.3273
+EASUB = 4.05
+NI0SUB = 1.1e16
+BG0SUB = 1.17
+EPSRSUB = 11.9
+XJ = 1.5e-7
+VFB = -1.2108
+VFBSDOFF = 0
+NSD = 1e26
+DVTP0 = 1.8335e-7
+DVTP1 = 220.59
+DVTP2 = 9.6351e-10
+DVTP3 = 0.89017
+DVTP4 = 98.728
+DVTP5 = 5.1435e-17
+PHIN = 0.045
+ETA0 = 0.0051075
+ETAB = -0.010908157
+ETABEXP = 0.09999
+DSUB = 1.0667
+K2 = -0.093146
+K2L = 0.065574
+K2LEXP = 0.79778
+K2W = 0.030809
+K2WEXP = 0.87253
+CIT = 1.0136148e-5
+CDSCD = 0.0011509049
+CDSCDL = -0.00048388809
+CDSCDLEXP = 0.13963388
+CDSCB = 9.9995516e-6
+CDSCBL = 1.4756534e-9
+CDSCBLEXP = 1
+NFACTOR = 0.0017201
+NFACTORL = 1.7832e-6
+NFACTORLEXP = 0.99988
+NFACTORW = 0.11149
+NFACTORWEXP = 0.8993
+NFACTORWL = -0.01386
+U0 = 0.04004
+U0L = 0.58676
+U0LEXP = 0.11151
+ETAMOB = 4.0947
+UA = 0.4298
+UAL = -0.0087246
+UALEXP = 1.3647
+UAW = 0.11575
+UAWEXP = 0.4385
+UAWL = -7.027e-5
+EU = 1.3371
+EUL = 0.0021948
+EULEXP = 1.4769
+EUW = -0.0031666
+EUWEXP = 1.9366
+EUWL = -0.00013929
+UD = 0.0093995
+UDL = 0.067484
+UDLEXP = 0.099452
+UCS = 0.9999
+UC = 4.91e-6
+UCL = 0.001096
+UCLEXP = 0.0015937
+VSAT = 9609100
+VSATL = 6.8282
+VSATLEXP = 0.086396
+VSATW = 0.016834
+VSATWEXP = 3.0172
+VSATCVL = 0
+VSATCVLEXP = 1
+VSATCVW = 0
+VSATCVWEXP = 1
+DELTA = 0.1779
+DELTAL = 0.1269
+DELTALEXP = 0.18156
+PCLM = 0
+PCLML = 0
+PCLMLEXP = 1e-13
+PCLMG = 0
+PCLMCVL = 0
+PCLMCVLEXP = 1
+PSCBE1 = 4.24e8
+PSCBE2 = 1e-8
+PDITS = 0.85536
+PDITSL = 8473.9
+PDITSD = 0
+PDIBLC = 0.005
+PDIBLCL = 0
+PDIBLCLEXP = 1
+PDIBLCB = -0.49995
+PVAG = 1
+FPROUT = 0
+FPROUTL = 0
+FPROUTLEXP = 1
+PTWG = 0.09999
+PTWGL = 0.069993
+PTWGLEXP = 0.0009999
+PSAT = 1e-13
+PSATL = 0
+PSATLEXP = 1
+PSATB = 0.9999
+PSATX = 1e-13
+RSH = 0
+PRWG = 1
+PRWB = 0.010098993
+PRWBL = 0.00070000265
+PRWBLEXP = 1
+WR = 1
+RSWMIN = 0
+RSW = 10
+RSWL = 0
+RSWLEXP = 1
+RDWMIN = 0
+RDW = 10
+RDWL = 0
+RDWLEXP = 1
+RDSWMIN = 0
+RDSW = 0
+RDSWL = 0.0007
+RDSWLEXP = 1e-7
+ALPHA0 = 0
+ALPHA0L = 0
+ALPHA0LEXP = 1
+BETA0 = 0
+AGIDL = 0
+AGIDLL = 0
+AGIDLW = 0
+BGIDL = 2.3e9
+CGIDL = 0.5
+EGIDL = 0.8
+AGISL = 0
+AGISLL = 0
+AGISLW = 0
+BGISL = 2.3e9
+CGISL = 0.5
+EGISL = 0.00171
+AIGBACC = 0.00171
+BIGBACC = 0.00171
+CIGBACC = 0.075
+NIGBACC = 1
+AIGBINV = 0.0111
+BIGBINV = 0.000949
+CIGBINV = 0.006
+EIGBINV = 1.1
+NIGBINV = 3
+AIGC = 0.0136
+AIGCL = 3
+AIGCW = 0.0136
+BIGC = 0.00171
+CIGC = 0.075
+AIGS = 0.0136
+AIGSL = 0.075
+AIGSW = 0.0136
+AIGD = 0.0136
+AIGDL = 0
+AIGDW = 0.0136
+BIGS = 0.00171
+BIGD = 0.00171
+CIGS = 0.075
+CIGD = 0.075
+TOXREF = 0.075
+NTOX = 1
+POXEDGE = 1
+PIGCD = 1
+PIGCDL = 1
+NDEPCV = 4.598e23
+NDEPCVL1 = 0
+NDEPCVLEXP1 = 1
+NDEPCVL2 = 0
+NDEPCVLEXP2 = 2
+NDEPCVW = 0
+NDEPCVWEXP = 1
+NDEPCVWL = 0
+NDEPCVWLEXP = 1
+NGATE = 7.764e25
+CF = 0
+CFRCOEFF = 1
+CGSO = 187.0e-12
+CGDO = 187.0e-12
+CGBO = 0
+CGSL = 130.0e-12
+CGDL = 130.0e-12
+CKAPPAS = 1.6
+CKAPPAD = 1.6
+ADOS = 221.4
+BDOS = 1.350
+QM0 = 405.7e-6
+ETAQM = 848.5e-3
+VFBCV = -996.0e-3
+VFBCVL = 0
+VFBCVLEXP = 1
+VFBCVW = 0
+VFBCVWEXP = 1
+VFBCVWL = 0
+VFBCVWLEXP = 1
+TBGASUB = 0.000473
+TBGBSUB = 636
+TDELTA = 0
+PTWGT = 0
+IIT = 0
+TGIDL = 0
+IGT = 0
+KT1 = -0.11
+KT1L = 0
+KT2 = 0.022
+KT1EXP = 1
+UTE = -1.5
+UA1 = 0.001
+UD1 = 0
+UC1 = -5.6e-11
+UCSTE = -0.004775
+PRT = 0
+AT = -0.00156
+SCA = 0
+SCB = 0
+SCC = 0
+SC = 0
+KU0WE = 0
+KVTH0WE = 0
+K2WE = 0
+WEB = 0
+WEC = 0
+SCREF = 1e-6
+SA = 0
+SB = 0
+SD = 0
+SAREF = 1e-6
+SBREF = 1e-6
+WLOD = 0
+KVSAT = 0
+KU0 = 0
+TKU0 = 0
+LKU0 = 0
+WKU0 = 0
+PKU0 = 0
+LLODKU0 = 0
+WLODKU0 = 0
+KVTH0 = 0
+LKVTH0 = 0
+WKVTH0 = 0
+PKVTH0 = 0
+LLODVTH = 0
+WLODVTH = 0
+STK2 = 0
+LODK2 = 1
+STETA0 = 0
+LODETA0 = 1
+RTH0 = 1e7
+MOBSCALE = 1

283
examples/osdi/mixed-models/Modelcards/psp103_nmos-2.mod
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* psp_VA_and_CMC_ref_data 103.3.0 asym_nmos_t
* LEVEL=103.0
* https://www.cea.fr/cea-tech/leti/pspsupport/Documents/Level%20103.3.3/psp_VA_and_CMC_ref_data.tar.gz
.model nch psp103va level=69
+type=1
+TR=27.0
+DTA=0
+SWGEO=1
+QMC=1.0
+LVARO=-10.0E-9
+LVARL=0
+LVARW=0
+LAP=10.0E-9
+WVARO=10.0E-9
+WVARL=0
+WVARW=0
+WOT=0
+DLQ=0
+DWQ=0
+VFBO=-1.1
+VFBL=0
+VFBW=0
+VFBLW=0
+STVFBO=5.0E-4
+STVFBL=0
+STVFBW=0
+STVFBLW=0
+TOXO=1.5E-9
+EPSROXO=3.9
+NSUBO=3.0E+23
+NSUBW=0
+WSEG=1.5E-10
+NPCK=1.0E+24
+NPCKW=0
+WSEGP=0.9E-8
+LPCK=5.5E-8
+LPCKW=0
+FOL1=2.0E-2
+FOL2=5.0E-6
+FACNEFFACO=0.8
+FACNEFFACL=0
+FACNEFFACW=0
+FACNEFFACLW=0
+GFACNUDO=0.1
+GFACNUDL=0
+GFACNUDLEXP=1
+GFACNUDW=0
+GFACNUDLW=0
+VSBNUDO=0
+DVSBNUDO=1
+VNSUBO=0
+NSLPO=0.05
+DNSUBO=0
+DPHIBO=0
+DPHIBL=0
+DPHIBLEXP=1.0
+DPHIBW=0
+DPHIBLW=0
+DELVTACO=0
+DELVTACL=0
+DELVTACLEXP=1
+DELVTACW=0
+DELVTACLW=0
+NPO=1.5E+26
+NPL=10.0E-18
+CTO=5.0E-15
+CTL=4.0E-2
+CTLEXP=0.6
+CTW=0
+CTLW=0
+TOXOVO=1.5E-9
+TOXOVDO=2.0E-9
+LOV=10.0E-9
+LOVD=0
+NOVO=7.5E+25
+NOVDO=5.0e+25
+CFL=3.0E-4
+CFLEXP=2.0
+CFW=5.0E-3
+CFBO=0.3
+UO=3.5E-2
+FBET1=-0.3
+FBET1W=0.15
+LP1=1.5E-7
+LP1W=-2.5E-2
+FBET2=50.0
+LP2=8.5E-10
+BETW1=5.0E-2
+BETW2=-2.0E-2
+WBET=5.0E-10
+STBETO=1.75
+STBETL=-2.0E-2
+STBETW=-2.0E-3
+STBETLW=-3.0E-3
+MUEO=0.6
+MUEW=-1.2E-2
+STMUEO=0.5
+THEMUO=2.75
+STTHEMUO=-0.1
+CSO=1.0E-2
+CSL=0
+CSLEXP=1
+CSW=0
+CSLW=0
+STCSO=-5.0
+XCORO=0.15
+XCORL=2.0E-3
+XCORW=-3.0E-2
+XCORLW=-3.5E-3
+STXCORO=1.25
+FETAO=1
+RSW1=50
+RSW2=5.0E-2
+STRSO=-2.0
+RSBO=0
+RSGO=0
+THESATO=1.0E-6
+THESATL=0.6
+THESATLEXP=0.75
+THESATW=-1.0E-2
+THESATLW=0
+STTHESATO=1.5
+STTHESATL=-2.5E-2
+STTHESATW=-2.0E-2
+STTHESATLW=-5.0E-3
+THESATBO=0.15
+THESATGO=0.75
+AXO=20
+AXL=0.2
+ALPL=7.0E-3
+ALPLEXP=0.6
+ALPW=5.0E-2
+ALP1L1=2.5E-2
+ALP1LEXP=0.4
+ALP1L2=0.1
+ALP1W=8.5E-3
+ALP2L1=0.5
+ALP2LEXP=0
+ALP2L2=0.5
+ALP2W=-0.2
+VPO=0.25
+A1O=1.0
+A1L=0
+A1W=0
+A2O=10.0
+STA2O=-0.5
+A3O=1.0
+A3L=0
+A3W=0
+A4O=0
+A4L=0
+A4W=0
+GCOO=5.0
+IGINVLW=50.0
+IGOVW=10.0
+IGOVDW=0
+STIGO=1.5
+GC2O=1.0
+GC3O=-1.0
+CHIBO=3.1
+AGIDLW=50.0
+AGIDLDW=0
+BGIDLO=35.0
+BGIDLDO=41
+STBGIDLO=-5.0E-4
+STBGIDLDO=0
+CGIDLO=0.15
+CGIDLDO=0
+CGBOVL=0
+CFRW=5.0E-17
+CFRDW=0
+FNTO=1
+NFALW=8.0E+22
+NFBLW=3.0E7
+NFCLW=0
+RGO=0
+RINT=0
+RVPOLY=0
+RSHG=0
+DLSIL=0
+RBULKO=0
+RWELLO=0
+RJUNDO=0
+RJUNSO=0
+SWJUNEXP=0
+TRJ=27.0
+IMAX=1.0E3
+VJUNREF=2.5
+FJUNQ=0.03
+CJORBOT=1.0E-3
+CJORSTI=1.0E-9
+CJORGAT=0.5E-9
+VBIRBOT=0.75
+VBIRSTI=1.0
+VBIRGAT=0.75
+PBOT=0.35
+PSTI=0.35
+PGAT=0.6
+PHIGBOT=1.16
+PHIGSTI=1.16
+PHIGGAT=1.16
+IDSATRBOT=5.0E-9
+IDSATRSTI=1.0E-18
+IDSATRGAT=1.0E-18
+CSRHBOT=5.0E2
+CSRHSTI=0
+CSRHGAT=1.0E3
+XJUNSTI=1.0E-8
+XJUNGAT=1.0E-9
+CTATBOT=5.0E2
+CTATSTI=0
+CTATGAT=1.0E3
+MEFFTATBOT=0.25
+MEFFTATSTI=0.25
+MEFFTATGAT=0.25
+CBBTBOT=1.0E-12
+CBBTSTI=1.0E-18
+CBBTGAT=1.0E-18
+FBBTRBOT=1.0E9
+FBBTRSTI=1.0E9
+FBBTRGAT=1.0E9
+STFBBTBOT=-1.0E-3
+STFBBTSTI=-1.0E-3
+STFBBTGAT=-1.0E-2
+VBRBOT=10.0
+VBRSTI=10.0
+VBRGAT=10.0
+PBRBOT=3
+PBRSTI=4
+PBRGAT=3
+VJUNREFD=2.5
+FJUNQD=0.03
+CJORBOTD=1.0E-3
+CJORSTID=1.0E-9
+CJORGATD=1.0E-9
+VBIRBOTD=1.0
+VBIRSTID=1.0
+VBIRGATD=1.0
+PBOTD=0.5
+PSTID=0.5
+PGATD=0.5
+PHIGBOTD=1.16
+PHIGSTID=1.16
+PHIGGATD=1.16
+IDSATRBOTD=1.0E-12
+IDSATRSTID=1.0E-18
+IDSATRGATD=1.0E-18
+CSRHBOTD=1.0E+2
+CSRHSTID=1.0E-4
+CSRHGATD=1.0E-4
+XJUNSTID=1.0E-7
+XJUNGATD=1.0E-7
+CTATBOTD=1.0E+2
+CTATSTID=1.0E-4
+CTATGATD=1.0E-4
+MEFFTATBOTD=0.25
+MEFFTATSTID=0.25
+MEFFTATGATD=0.25
+CBBTBOTD=1.0E-12
+CBBTSTID=1.0E-18
+CBBTGATD=1.0E-18
+FBBTRBOTD=1.0E9
+FBBTRSTID=1.0E9
+FBBTRGATD=1.0E9
+STFBBTBOTD=-1.0E-3
+STFBBTSTID=-1.0E-3
+STFBBTGATD=-1.0E-3
+VBRBOTD=10.0
+VBRSTID=10.0
+VBRGATD=10.0
+PBRBOTD=4
+PBRSTID=4
+PBRGATD=4
* thermal parameters
*+RTHO=1.1E4
*+RTHW1=990.5
*+RTHW2=14.4
*+RTHLW=15.0
*+CTHO =1.0E-7
*+CTHW1=1.0e-8
*+CTHW2=1.5
*+CTHLW=4.0
*+STRTHO=1.3

283
examples/osdi/mixed-models/Modelcards/psp103_pmos-2.mod
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* psp_VA_and_CMC_ref_data 103.3.0 asym_pmos_t
* LEVEL=103.0
* https://www.cea.fr/cea-tech/leti/pspsupport/Documents/Level%20103.3.3/psp_VA_and_CMC_ref_data.tar.gz
.model pch psp103va level=69
+TYPE=-1
+TR=27.0
+DTA=0
+SWGEO=1
+QMC=1.0
+LVARO=-10.0E-9
+LVARL=0
+LVARW=0
+LAP=10.0E-9
+WVARO=10.0E-9
+WVARL=0
+WVARW=0
+WOT=0
+DLQ=0
+DWQ=0
+VFBO=-1.1
+VFBL=0
+VFBW=0
+VFBLW=0
+STVFBO=5.0E-4
+STVFBL=0
+STVFBW=0
+STVFBLW=0
+TOXO=1.5E-9
+EPSROXO=3.9
+NSUBO=3.0E+23
+NSUBW=0
+WSEG=1.5E-10
+NPCK=1.0E+24
+NPCKW=0
+WSEGP=0.9E-8
+LPCK=5.5E-8
+LPCKW=0
+FOL1=2.0E-2
+FOL2=5.0E-6
+FACNEFFACO=0.8
+FACNEFFACL=0
+FACNEFFACW=0
+FACNEFFACLW=0
+GFACNUDO=0.1
+GFACNUDL=0
+GFACNUDLEXP=1
+GFACNUDW=0
+GFACNUDLW=0
+VSBNUDO=0
+DVSBNUDO=1
+VNSUBO=0
+NSLPO=0.05
+DNSUBO=0
+DPHIBO=0
+DPHIBL=0
+DPHIBLEXP=1.0
+DPHIBW=0
+DPHIBLW=0
+DELVTACO=0
+DELVTACL=0
+DELVTACLEXP=1
+DELVTACW=0
+DELVTACLW=0
+NPO=1.5E+26
+NPL=10.0E-18
+CTO=5.0E-15
+CTL=4.0E-2
+CTLEXP=0.6
+CTW=0
+CTLW=0
+TOXOVO=1.5E-9
+TOXOVDO=2.0E-9
+LOV=10.0E-9
+LOVD=0
+NOVO=7.5E+25
+NOVDO=5.0e+25
+CFL=3.0E-4
+CFLEXP=2.0
+CFW=5.0E-3
+CFBO=0.3
+UO=3.5E-2
+FBET1=-0.3
+FBET1W=0.15
+LP1=1.5E-7
+LP1W=-2.5E-2
+FBET2=50.0
+LP2=8.5E-10
+BETW1=5.0E-2
+BETW2=-2.0E-2
+WBET=5.0E-10
+STBETO=1.75
+STBETL=-2.0E-2
+STBETW=-2.0E-3
+STBETLW=-3.0E-3
+MUEO=0.6
+MUEW=-1.2E-2
+STMUEO=0.5
+THEMUO=2.75
+STTHEMUO=-0.1
+CSO=1.0E-2
+CSL=0
+CSLEXP=1
+CSW=0
+CSLW=0
+STCSO=-5.0
+XCORO=0.15
+XCORL=2.0E-3
+XCORW=-3.0E-2
+XCORLW=-3.5E-3
+STXCORO=1.25
+FETAO=1
+RSW1=50
+RSW2=5.0E-2
+STRSO=-2.0
+RSBO=0
+RSGO=0
+THESATO=1.0E-6
+THESATL=0.6
+THESATLEXP=0.75
+THESATW=-1.0E-2
+THESATLW=0
+STTHESATO=1.5
+STTHESATL=-2.5E-2
+STTHESATW=-2.0E-2
+STTHESATLW=-5.0E-3
+THESATBO=0.15
+THESATGO=0.75
+AXO=20
+AXL=0.2
+ALPL=7.0E-3
+ALPLEXP=0.6
+ALPW=5.0E-2
+ALP1L1=2.5E-2
+ALP1LEXP=0.4
+ALP1L2=0.1
+ALP1W=8.5E-3
+ALP2L1=0.5
+ALP2LEXP=0
+ALP2L2=0.5
+ALP2W=-0.2
+VPO=0.25
+A1O=1.0
+A1L=0
+A1W=0
+A2O=10.0
+STA2O=-0.5
+A3O=1.0
+A3L=0
+A3W=0
+A4O=0
+A4L=0
+A4W=0
+GCOO=5.0
+IGINVLW=50.0
+IGOVW=10.0
+IGOVDW=0
+STIGO=1.5
+GC2O=1.0
+GC3O=-1.0
+CHIBO=3.1
+AGIDLW=50.0
+AGIDLDW=0
+BGIDLO=35.0
+BGIDLDO=41
+STBGIDLO=-5.0E-4
+STBGIDLDO=0
+CGIDLO=0.15
+CGIDLDO=0
+CGBOVL=0
+CFRW=5.0E-17
+CFRDW=0
+FNTO=1
+NFALW=8.0E+22
+NFBLW=3.0E7
+NFCLW=0
+RGO=0
+RINT=0
+RVPOLY=0
+RSHG=0
+DLSIL=0
+RBULKO=0
+RWELLO=0
+RJUNDO=0
+RJUNSO=0
+SWJUNEXP=0
+TRJ=27.0
+IMAX=1.0E3
+VJUNREF=2.5
+FJUNQ=0.03
+CJORBOT=1.0E-3
+CJORSTI=1.0E-9
+CJORGAT=0.5E-9
+VBIRBOT=0.75
+VBIRSTI=1.0
+VBIRGAT=0.75
+PBOT=0.35
+PSTI=0.35
+PGAT=0.6
+PHIGBOT=1.16
+PHIGSTI=1.16
+PHIGGAT=1.16
+IDSATRBOT=5.0E-9
+IDSATRSTI=1.0E-18
+IDSATRGAT=1.0E-18
+CSRHBOT=5.0E2
+CSRHSTI=0
+CSRHGAT=1.0E3
+XJUNSTI=1.0E-8
+XJUNGAT=1.0E-9
+CTATBOT=5.0E2
+CTATSTI=0
+CTATGAT=1.0E3
+MEFFTATBOT=0.25
+MEFFTATSTI=0.25
+MEFFTATGAT=0.25
+CBBTBOT=1.0E-12
+CBBTSTI=1.0E-18
+CBBTGAT=1.0E-18
+FBBTRBOT=1.0E9
+FBBTRSTI=1.0E9
+FBBTRGAT=1.0E9
+STFBBTBOT=-1.0E-3
+STFBBTSTI=-1.0E-3
+STFBBTGAT=-1.0E-2
+VBRBOT=10.0
+VBRSTI=10.0
+VBRGAT=10.0
+PBRBOT=3
+PBRSTI=4
+PBRGAT=3
+VJUNREFD=2.5
+FJUNQD=0.03
+CJORBOTD=1.0E-3
+CJORSTID=1.0E-9
+CJORGATD=1.0E-9
+VBIRBOTD=1.0
+VBIRSTID=1.0
+VBIRGATD=1.0
+PBOTD=0.5
+PSTID=0.5
+PGATD=0.5
+PHIGBOTD=1.16
+PHIGSTID=1.16
+PHIGGATD=1.16
+IDSATRBOTD=1.0E-12
+IDSATRSTID=1.0E-18
+IDSATRGATD=1.0E-18
+CSRHBOTD=1.0E+2
+CSRHSTID=1.0E-4
+CSRHGATD=1.0E-4
+XJUNSTID=1.0E-7
+XJUNGATD=1.0E-7
+CTATBOTD=1.0E+2
+CTATSTID=1.0E-4
+CTATGATD=1.0E-4
+MEFFTATBOTD=0.25
+MEFFTATSTID=0.25
+MEFFTATGATD=0.25
+CBBTBOTD=1.0E-12
+CBBTSTID=1.0E-18
+CBBTGATD=1.0E-18
+FBBTRBOTD=1.0E9
+FBBTRSTID=1.0E9
+FBBTRGATD=1.0E9
+STFBBTBOTD=-1.0E-3
+STFBBTSTID=-1.0E-3
+STFBBTGATD=-1.0E-3
+VBRBOTD=10.0
+VBRSTID=10.0
+VBRGATD=10.0
+PBRBOTD=4
+PBRSTID=4
+PBRGATD=4
* thermal parameters
*+RTHO=1.1E4
*+RTHW1=990.5
*+RTHW2=14.4
*+RTHLW=15.0
*+CTHO =1.0E-7
*+CTHW1=1.0e-8
*+CTHW2=1.5
*+CTHLW=4.0
*+STRTHO=1.3

80
examples/osdi/mixed-models/bb-psp_ro.sp
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@ -0,0 +1,80 @@
* Mix up two models
* BSIMBULK model vers. 107
* PSP model vers. 103
* simple 5-stage ring oscillator
* Power supply
.param Vcc = 1.2
* Path to the models
.include Modelcards/model.l
.include Modelcards/psp103_nmos-2.mod
.include Modelcards/psp103_pmos-2.mod
* The voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
* The circuit: five stages
Xnot1 in vdd vss in2 notbb
Xnot2 in2 vdd vss in3 notpsp
Xnot3 in3 vdd vss in4 notbb
Xnot4 in4 vdd vss in5 notpsp
Xnot5 in5 vdd vss in notbb
* Inverter BSIMBULK
.subckt notbb a vdd vss z
Np1 z a vdd vdd BSIMBULK_osdi_P l=0.1u w=1u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
Nn1 z a vss vss BSIMBULK_osdi_N l=0.1u w=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* Inverter PSP
.subckt notpsp a vdd vss z
nmp1 z a vdd vdd pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
nmn1 z a vss vss nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* Simulation command:
.tran 10p 10n uic
.control
* Load the models dynamically
pre_osdi test_osdi_win/bsimbulk107.osdi test_osdi_win/psp103.osdi
* Run the simulation
run
* Plotting
set xbrushwidth=3
plot in
* Resource usage
rusage
.endc
.end

40
examples/osdi/mixed-models/bsimbulk_inverter.sp
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* BSIMBULK model vers. 107
* simple inverter
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/model.l
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss out not1
*Rout out 0 1k
.subckt not1 a vdd vss z
Np1 z a vdd vdd BSIMBULK_osdi_P l=0.1u w=1u as=0.26235p ad=0.26235p ps=2.51u pd=2.51u
Nn1 z a vss vss BSIMBULK_osdi_N l=0.1u w=0.5u as=0.131175p ad=0.131175p ps=1.52u pd=1.52u
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10ps 10ns
.dc V1 0 'vcc' 'vcc/100'
.control
pre_osdi test_osdi_win/bsimbulk107.osdi
run
*set nolegend
set xbrushwidth=3
plot in out
plot dc1.out
plot dc1.i(Vmeas)
rusage
.endc
.end

66
examples/osdi/mixed-models/psp_inverter.sp
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* PSP models
* simple inverter
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/psp103_nmos-2.mod
.include Modelcards/psp103_pmos-2.mod
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss out not1
*Rout out 0 1k
.subckt not1 a vdd vss z
*m01 z a vdd vdd pch l=0.1u w=1u as=0.26235 ad=0.26235 ps=2.51 pd=2.51
nmp1 z a vdd vdd pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*m02 z a vss vss nch l=0.1u w=0.5u as=0.131175 ad=0.131175 ps=1.52 pd=1.52
nmn1 z a vss vss nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10ps 10ns
.dc V1 0 'vcc' 'vcc/100'
.control
pre_osdi test_osdi_win/psp103.osdi
run
*set nolegend
set xbrushwidth=2
plot in out
plot dc1.out
plot dc1.i(Vmeas)
rusage
.endc
.end

1
examples/osdi/mixed-models/test_osdi_win/README
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Place bsimbulk107.osdi and psp103.osdi here.

283
examples/osdi/psp103/Modelcards/psp103_nmos-2.mod
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* psp_VA_and_CMC_ref_data 103.3.0 asym_nmos_t
* LEVEL=103.0
* https://www.cea.fr/cea-tech/leti/pspsupport/Documents/Level%20103.3.3/psp_VA_and_CMC_ref_data.tar.gz
.model nch psp103va level=69
+type=1
+TR=27.0
+DTA=0
+SWGEO=1
+QMC=1.0
+LVARO=-10.0E-9
+LVARL=0
+LVARW=0
+LAP=10.0E-9
+WVARO=10.0E-9
+WVARL=0
+WVARW=0
+WOT=0
+DLQ=0
+DWQ=0
+VFBO=-1.1
+VFBL=0
+VFBW=0
+VFBLW=0
+STVFBO=5.0E-4
+STVFBL=0
+STVFBW=0
+STVFBLW=0
+TOXO=1.5E-9
+EPSROXO=3.9
+NSUBO=3.0E+23
+NSUBW=0
+WSEG=1.5E-10
+NPCK=1.0E+24
+NPCKW=0
+WSEGP=0.9E-8
+LPCK=5.5E-8
+LPCKW=0
+FOL1=2.0E-2
+FOL2=5.0E-6
+FACNEFFACO=0.8
+FACNEFFACL=0
+FACNEFFACW=0
+FACNEFFACLW=0
+GFACNUDO=0.1
+GFACNUDL=0
+GFACNUDLEXP=1
+GFACNUDW=0
+GFACNUDLW=0
+VSBNUDO=0
+DVSBNUDO=1
+VNSUBO=0
+NSLPO=0.05
+DNSUBO=0
+DPHIBO=0
+DPHIBL=0
+DPHIBLEXP=1.0
+DPHIBW=0
+DPHIBLW=0
+DELVTACO=0
+DELVTACL=0
+DELVTACLEXP=1
+DELVTACW=0
+DELVTACLW=0
+NPO=1.5E+26
+NPL=10.0E-18
+CTO=5.0E-15
+CTL=4.0E-2
+CTLEXP=0.6
+CTW=0
+CTLW=0
+TOXOVO=1.5E-9
+TOXOVDO=2.0E-9
+LOV=10.0E-9
+LOVD=0
+NOVO=7.5E+25
+NOVDO=5.0e+25
+CFL=3.0E-4
+CFLEXP=2.0
+CFW=5.0E-3
+CFBO=0.3
+UO=3.5E-2
+FBET1=-0.3
+FBET1W=0.15
+LP1=1.5E-7
+LP1W=-2.5E-2
+FBET2=50.0
+LP2=8.5E-10
+BETW1=5.0E-2
+BETW2=-2.0E-2
+WBET=5.0E-10
+STBETO=1.75
+STBETL=-2.0E-2
+STBETW=-2.0E-3
+STBETLW=-3.0E-3
+MUEO=0.6
+MUEW=-1.2E-2
+STMUEO=0.5
+THEMUO=2.75
+STTHEMUO=-0.1
+CSO=1.0E-2
+CSL=0
+CSLEXP=1
+CSW=0
+CSLW=0
+STCSO=-5.0
+XCORO=0.15
+XCORL=2.0E-3
+XCORW=-3.0E-2
+XCORLW=-3.5E-3
+STXCORO=1.25
+FETAO=1
+RSW1=50
+RSW2=5.0E-2
+STRSO=-2.0
+RSBO=0
+RSGO=0
+THESATO=1.0E-6
+THESATL=0.6
+THESATLEXP=0.75
+THESATW=-1.0E-2
+THESATLW=0
+STTHESATO=1.5
+STTHESATL=-2.5E-2
+STTHESATW=-2.0E-2
+STTHESATLW=-5.0E-3
+THESATBO=0.15
+THESATGO=0.75
+AXO=20
+AXL=0.2
+ALPL=7.0E-3
+ALPLEXP=0.6
+ALPW=5.0E-2
+ALP1L1=2.5E-2
+ALP1LEXP=0.4
+ALP1L2=0.1
+ALP1W=8.5E-3
+ALP2L1=0.5
+ALP2LEXP=0
+ALP2L2=0.5
+ALP2W=-0.2
+VPO=0.25
+A1O=1.0
+A1L=0
+A1W=0
+A2O=10.0
+STA2O=-0.5
+A3O=1.0
+A3L=0
+A3W=0
+A4O=0
+A4L=0
+A4W=0
+GCOO=5.0
+IGINVLW=50.0
+IGOVW=10.0
+IGOVDW=0
+STIGO=1.5
+GC2O=1.0
+GC3O=-1.0
+CHIBO=3.1
+AGIDLW=50.0
+AGIDLDW=0
+BGIDLO=35.0
+BGIDLDO=41
+STBGIDLO=-5.0E-4
+STBGIDLDO=0
+CGIDLO=0.15
+CGIDLDO=0
+CGBOVL=0
+CFRW=5.0E-17
+CFRDW=0
+FNTO=1
+NFALW=8.0E+22
+NFBLW=3.0E7
+NFCLW=0
+RGO=0
+RINT=0
+RVPOLY=0
+RSHG=0
+DLSIL=0
+RBULKO=0
+RWELLO=0
+RJUNDO=0
+RJUNSO=0
+SWJUNEXP=0
+TRJ=27.0
+IMAX=1.0E3
+VJUNREF=2.5
+FJUNQ=0.03
+CJORBOT=1.0E-3
+CJORSTI=1.0E-9
+CJORGAT=0.5E-9
+VBIRBOT=0.75
+VBIRSTI=1.0
+VBIRGAT=0.75
+PBOT=0.35
+PSTI=0.35
+PGAT=0.6
+PHIGBOT=1.16
+PHIGSTI=1.16
+PHIGGAT=1.16
+IDSATRBOT=5.0E-9
+IDSATRSTI=1.0E-18
+IDSATRGAT=1.0E-18
+CSRHBOT=5.0E2
+CSRHSTI=0
+CSRHGAT=1.0E3
+XJUNSTI=1.0E-8
+XJUNGAT=1.0E-9
+CTATBOT=5.0E2
+CTATSTI=0
+CTATGAT=1.0E3
+MEFFTATBOT=0.25
+MEFFTATSTI=0.25
+MEFFTATGAT=0.25
+CBBTBOT=1.0E-12
+CBBTSTI=1.0E-18
+CBBTGAT=1.0E-18
+FBBTRBOT=1.0E9
+FBBTRSTI=1.0E9
+FBBTRGAT=1.0E9
+STFBBTBOT=-1.0E-3
+STFBBTSTI=-1.0E-3
+STFBBTGAT=-1.0E-2
+VBRBOT=10.0
+VBRSTI=10.0
+VBRGAT=10.0
+PBRBOT=3
+PBRSTI=4
+PBRGAT=3
+VJUNREFD=2.5
+FJUNQD=0.03
+CJORBOTD=1.0E-3
+CJORSTID=1.0E-9
+CJORGATD=1.0E-9
+VBIRBOTD=1.0
+VBIRSTID=1.0
+VBIRGATD=1.0
+PBOTD=0.5
+PSTID=0.5
+PGATD=0.5
+PHIGBOTD=1.16
+PHIGSTID=1.16
+PHIGGATD=1.16
+IDSATRBOTD=1.0E-12
+IDSATRSTID=1.0E-18
+IDSATRGATD=1.0E-18
+CSRHBOTD=1.0E+2
+CSRHSTID=1.0E-4
+CSRHGATD=1.0E-4
+XJUNSTID=1.0E-7
+XJUNGATD=1.0E-7
+CTATBOTD=1.0E+2
+CTATSTID=1.0E-4
+CTATGATD=1.0E-4
+MEFFTATBOTD=0.25
+MEFFTATSTID=0.25
+MEFFTATGATD=0.25
+CBBTBOTD=1.0E-12
+CBBTSTID=1.0E-18
+CBBTGATD=1.0E-18
+FBBTRBOTD=1.0E9
+FBBTRSTID=1.0E9
+FBBTRGATD=1.0E9
+STFBBTBOTD=-1.0E-3
+STFBBTSTID=-1.0E-3
+STFBBTGATD=-1.0E-3
+VBRBOTD=10.0
+VBRSTID=10.0
+VBRGATD=10.0
+PBRBOTD=4
+PBRSTID=4
+PBRGATD=4
* thermal parameters
*+RTHO=1.1E4
*+RTHW1=990.5
*+RTHW2=14.4
*+RTHLW=15.0
*+CTHO =1.0E-7
*+CTHW1=1.0e-8
*+CTHW2=1.5
*+CTHLW=4.0
*+STRTHO=1.3

283
examples/osdi/psp103/Modelcards/psp103_pmos-2.mod
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* psp_VA_and_CMC_ref_data 103.3.0 asym_pmos_t
* LEVEL=103.0
* https://www.cea.fr/cea-tech/leti/pspsupport/Documents/Level%20103.3.3/psp_VA_and_CMC_ref_data.tar.gz
.model pch psp103va level=69
+TYPE=-1
+TR=27.0
+DTA=0
+SWGEO=1
+QMC=1.0
+LVARO=-10.0E-9
+LVARL=0
+LVARW=0
+LAP=10.0E-9
+WVARO=10.0E-9
+WVARL=0
+WVARW=0
+WOT=0
+DLQ=0
+DWQ=0
+VFBO=-1.1
+VFBL=0
+VFBW=0
+VFBLW=0
+STVFBO=5.0E-4
+STVFBL=0
+STVFBW=0
+STVFBLW=0
+TOXO=1.5E-9
+EPSROXO=3.9
+NSUBO=3.0E+23
+NSUBW=0
+WSEG=1.5E-10
+NPCK=1.0E+24
+NPCKW=0
+WSEGP=0.9E-8
+LPCK=5.5E-8
+LPCKW=0
+FOL1=2.0E-2
+FOL2=5.0E-6
+FACNEFFACO=0.8
+FACNEFFACL=0
+FACNEFFACW=0
+FACNEFFACLW=0
+GFACNUDO=0.1
+GFACNUDL=0
+GFACNUDLEXP=1
+GFACNUDW=0
+GFACNUDLW=0
+VSBNUDO=0
+DVSBNUDO=1
+VNSUBO=0
+NSLPO=0.05
+DNSUBO=0
+DPHIBO=0
+DPHIBL=0
+DPHIBLEXP=1.0
+DPHIBW=0
+DPHIBLW=0
+DELVTACO=0
+DELVTACL=0
+DELVTACLEXP=1
+DELVTACW=0
+DELVTACLW=0
+NPO=1.5E+26
+NPL=10.0E-18
+CTO=5.0E-15
+CTL=4.0E-2
+CTLEXP=0.6
+CTW=0
+CTLW=0
+TOXOVO=1.5E-9
+TOXOVDO=2.0E-9
+LOV=10.0E-9
+LOVD=0
+NOVO=7.5E+25
+NOVDO=5.0e+25
+CFL=3.0E-4
+CFLEXP=2.0
+CFW=5.0E-3
+CFBO=0.3
+UO=3.5E-2
+FBET1=-0.3
+FBET1W=0.15
+LP1=1.5E-7
+LP1W=-2.5E-2
+FBET2=50.0
+LP2=8.5E-10
+BETW1=5.0E-2
+BETW2=-2.0E-2
+WBET=5.0E-10
+STBETO=1.75
+STBETL=-2.0E-2
+STBETW=-2.0E-3
+STBETLW=-3.0E-3
+MUEO=0.6
+MUEW=-1.2E-2
+STMUEO=0.5
+THEMUO=2.75
+STTHEMUO=-0.1
+CSO=1.0E-2
+CSL=0
+CSLEXP=1
+CSW=0
+CSLW=0
+STCSO=-5.0
+XCORO=0.15
+XCORL=2.0E-3
+XCORW=-3.0E-2
+XCORLW=-3.5E-3
+STXCORO=1.25
+FETAO=1
+RSW1=50
+RSW2=5.0E-2
+STRSO=-2.0
+RSBO=0
+RSGO=0
+THESATO=1.0E-6
+THESATL=0.6
+THESATLEXP=0.75
+THESATW=-1.0E-2
+THESATLW=0
+STTHESATO=1.5
+STTHESATL=-2.5E-2
+STTHESATW=-2.0E-2
+STTHESATLW=-5.0E-3
+THESATBO=0.15
+THESATGO=0.75
+AXO=20
+AXL=0.2
+ALPL=7.0E-3
+ALPLEXP=0.6
+ALPW=5.0E-2
+ALP1L1=2.5E-2
+ALP1LEXP=0.4
+ALP1L2=0.1
+ALP1W=8.5E-3
+ALP2L1=0.5
+ALP2LEXP=0
+ALP2L2=0.5
+ALP2W=-0.2
+VPO=0.25
+A1O=1.0
+A1L=0
+A1W=0
+A2O=10.0
+STA2O=-0.5
+A3O=1.0
+A3L=0
+A3W=0
+A4O=0
+A4L=0
+A4W=0
+GCOO=5.0
+IGINVLW=50.0
+IGOVW=10.0
+IGOVDW=0
+STIGO=1.5
+GC2O=1.0
+GC3O=-1.0
+CHIBO=3.1
+AGIDLW=50.0
+AGIDLDW=0
+BGIDLO=35.0
+BGIDLDO=41
+STBGIDLO=-5.0E-4
+STBGIDLDO=0
+CGIDLO=0.15
+CGIDLDO=0
+CGBOVL=0
+CFRW=5.0E-17
+CFRDW=0
+FNTO=1
+NFALW=8.0E+22
+NFBLW=3.0E7
+NFCLW=0
+RGO=0
+RINT=0
+RVPOLY=0
+RSHG=0
+DLSIL=0
+RBULKO=0
+RWELLO=0
+RJUNDO=0
+RJUNSO=0
+SWJUNEXP=0
+TRJ=27.0
+IMAX=1.0E3
+VJUNREF=2.5
+FJUNQ=0.03
+CJORBOT=1.0E-3
+CJORSTI=1.0E-9
+CJORGAT=0.5E-9
+VBIRBOT=0.75
+VBIRSTI=1.0
+VBIRGAT=0.75
+PBOT=0.35
+PSTI=0.35
+PGAT=0.6
+PHIGBOT=1.16
+PHIGSTI=1.16
+PHIGGAT=1.16
+IDSATRBOT=5.0E-9
+IDSATRSTI=1.0E-18
+IDSATRGAT=1.0E-18
+CSRHBOT=5.0E2
+CSRHSTI=0
+CSRHGAT=1.0E3
+XJUNSTI=1.0E-8
+XJUNGAT=1.0E-9
+CTATBOT=5.0E2
+CTATSTI=0
+CTATGAT=1.0E3
+MEFFTATBOT=0.25
+MEFFTATSTI=0.25
+MEFFTATGAT=0.25
+CBBTBOT=1.0E-12
+CBBTSTI=1.0E-18
+CBBTGAT=1.0E-18
+FBBTRBOT=1.0E9
+FBBTRSTI=1.0E9
+FBBTRGAT=1.0E9
+STFBBTBOT=-1.0E-3
+STFBBTSTI=-1.0E-3
+STFBBTGAT=-1.0E-2
+VBRBOT=10.0
+VBRSTI=10.0
+VBRGAT=10.0
+PBRBOT=3
+PBRSTI=4
+PBRGAT=3
+VJUNREFD=2.5
+FJUNQD=0.03
+CJORBOTD=1.0E-3
+CJORSTID=1.0E-9
+CJORGATD=1.0E-9
+VBIRBOTD=1.0
+VBIRSTID=1.0
+VBIRGATD=1.0
+PBOTD=0.5
+PSTID=0.5
+PGATD=0.5
+PHIGBOTD=1.16
+PHIGSTID=1.16
+PHIGGATD=1.16
+IDSATRBOTD=1.0E-12
+IDSATRSTID=1.0E-18
+IDSATRGATD=1.0E-18
+CSRHBOTD=1.0E+2
+CSRHSTID=1.0E-4
+CSRHGATD=1.0E-4
+XJUNSTID=1.0E-7
+XJUNGATD=1.0E-7
+CTATBOTD=1.0E+2
+CTATSTID=1.0E-4
+CTATGATD=1.0E-4
+MEFFTATBOTD=0.25
+MEFFTATSTID=0.25
+MEFFTATGATD=0.25
+CBBTBOTD=1.0E-12
+CBBTSTID=1.0E-18
+CBBTGATD=1.0E-18
+FBBTRBOTD=1.0E9
+FBBTRSTID=1.0E9
+FBBTRGATD=1.0E9
+STFBBTBOTD=-1.0E-3
+STFBBTSTID=-1.0E-3
+STFBBTGATD=-1.0E-3
+VBRBOTD=10.0
+VBRSTID=10.0
+VBRGATD=10.0
+PBRBOTD=4
+PBRSTID=4
+PBRGATD=4
* thermal parameters
*+RTHO=1.1E4
*+RTHW1=990.5
*+RTHW2=14.4
*+RTHLW=15.0
*+CTHO =1.0E-7
*+CTHW1=1.0e-8
*+CTHW2=1.5
*+CTHLW=4.0
*+STRTHO=1.3

89240
examples/osdi/psp103/c7552_ann_psp.net
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70
examples/osdi/psp103/nmos_pmos_PSP.sp
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*** NMOS and PMOS transistors PSP 103.8 (Id-Vgs, Vbs) (Id-Vds, Vgs) (Id-Vgs, T) ***
nmn1 2 1 3 4 nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
vgsn 1 0 3.5
vdsn 2 0 0.1
vssn 3 0 0
vbsn 4 0 0
nmp1 22 11 33 44 pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
vgsp 11 0 -3.5
vdsp 22 0 -0.1
vssp 33 0 0
vbsp 44 0 0
* PSP modelparameters for PSP 103.3
.include Modelcards/psp103_nmos-2.mod
.include Modelcards/psp103_pmos-2.mod
.control
* Load the models dynamically
pre_osdi test_osdi_win/psp103.osdi
set xgridwidth=2
set xbrushwidth=3
* NMOS
dc vgsn 0 1.5 0.05 vbsn 0 -1.5 -0.3
plot vssn#branch ylabel 'Id vs. Vgs, Vbs 0 ... -1.5'
plot abs(vssn#branch) ylog ylabel 'Id vs. Vgs, Vbs 0 ... -1.5'
dc vdsn 0 1.6 0.01 vgsn 0 1.6 0.2
plot vssn#branch ylabel 'Id vs. Vds, Vgs 0 ... 1.6'
dc vgsn 0 1.5 0.05 temp -40 160 40
plot vssn#branch ylabel 'Id vs. Vds, Temp. -40 ... 160'
plot abs(vssn#branch) ylog ylabel 'Id vs. Vds, Temp. -40 ... 160'
* PMOS
dc vgsp 0 -1.5 -0.05 vbsp 0 1.5 0.3
plot vssp#branch ylabel 'Id vs. Vgs, Vbs 0 ... 1.5'
plot abs(vssp#branch) ylog ylabel 'Id vs. Vgs, Vbs 0 ... 1.5'
dc vdsp 0 -1.6 -0.01 vgsp 0 -1.6 -0.2
plot vssp#branch ylabel 'Id vs. Vds, Vgs 0 ... -1.6'
dc vgsp 0 -1.5 -0.05 temp -40 160 40
plot vssp#branch ylabel 'Id vs. Vds, Temp. -40 ... 160'
plot abs(vssp#branch) ylog ylabel 'Id vs. Vds, Temp. -40 ... 160'
.endc
.end

66
examples/osdi/psp103/psp_inverter.sp
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* PSP models
* simple inverter
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/psp103_nmos-2.mod
.include Modelcards/psp103_pmos-2.mod
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss out not1
*Rout out 0 1k
.subckt not1 a vdd vss z
*m01 z a vdd vdd pch l=0.1u w=1u as=0.26235 ad=0.26235 ps=2.51 pd=2.51
nmp1 z a vdd vdd pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*m02 z a vss vss nch l=0.1u w=0.5u as=0.131175 ad=0.131175 ps=1.52 pd=1.52
nmn1 z a vss vss nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10ps 10ns
.dc V1 0 'vcc' 'vcc/100'
.control
pre_osdi test_osdi_win/psp103.osdi
run
*set nolegend
set xbrushwidth=2
plot in out
plot dc1.out
plot dc1.i(Vmeas)
rusage
.endc
.end

33
examples/osdi/psp103/psp_out_nmos_nm.sp
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psp103 nch output
*
vd d 0 dc 0.05
vg g 0 dc 0.0
vs s 0 dc 0.0
vb b 0 dc 0.0
nm1 d g s b nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*
.option temp=21
.include Modelcards/psp103_nmos-2.mod
*.include Modelcards/psp103_nmos.mod
.control
pre_osdi test_osdi_win/psp103.osdi
dc vd 0 2.0 0.05 vg 0 1.5 0.25
plot i(vs)
dc vg 0 1.5 0.05 vb 0 -3.0 -1
plot i(vs)
.endc
.end

33
examples/osdi/psp103/psp_out_pmos_nm.sp
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psp103 pch output
*
vd d 0 dc -0.1
vg g 0 dc 0.0
vs s 0 dc 0.0
vb b 0 dc 0.0
nm1 d g s b pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*
.option temp=21
.control
pre_osdi test_osdi_win/psp103.osdi
dc vd 0 -2.0 -0.05 vg 0 -1.5 -0.25 ; saturation
plot i(vs)
dc vg 0 -1.5 -0.05 vb 0 3.0 1
plot i(vs)
.endc
*
.include Modelcards/psp103_pmos-2.mod
.end

66
examples/osdi/psp103/psp_ro.sp
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* PSP models
* simple 5-stage ring oscillator
.param Vcc = 1.2
.csparam vcc='Vcc'
* Path to the models
.include Modelcards/psp103_nmos-2.mod
.include Modelcards/psp103_pmos-2.mod
* the voltage sources:
Vdd vdd gnd DC 'Vcc'
V1 in gnd pulse(0 'Vcc' 0p 200p 100p 1n 2n)
Vmeas vss 0 0
Xnot1 in vdd vss in2 not1
Xnot2 in2 vdd vss in3 not1
Xnot3 in3 vdd vss in4 not1
Xnot4 in4 vdd vss in5 not1
Xnot5 in5 vdd vss in not1
*Rout out 0 1k
.subckt not1 a vdd vss z
*m01 z a vdd vdd pch l=0.1u w=1u as=0.26235 ad=0.26235 ps=2.51 pd=2.51
nmp1 z a vdd vdd pch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*m02 z a vss vss nch l=0.1u w=0.5u as=0.131175 ad=0.131175 ps=1.52 pd=1.52
nmn1 z a vss vss nch
+l=0.1u
+w=1u
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
c3 a vss 0.384f
c2 z vss 0.576f
.ends
* simulation command:
.tran 10p 10n uic
.control
pre_osdi test_osdi_win/psp103.osdi
run
set xbrushwidth=3
plot in
rusage
.endc
.end

32
examples/osdi/psp103/psp_transfer.sp
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psp103 nch transfer
*
vd d 0 dc 0.1
vg g 0 dc 0.0
vs s 0 dc 0.0
vb b 0 dc 0.0
nm1 d g s b nch
+l=1.0e-06
+w=10.0e-06
+sa=0.0e+00
+sb=0.0e+00
+absource=1.0e-12
+lssource=1.0e-06
+lgsource=1.0e-06
+abdrain=1.0e-12
+lsdrain=1.0e-06
+lgdrain=1.0e-06
+mult=1.0e+00
*
.option temp=21
.control
pre_osdi test_osdi_win/psp103.osdi
set xbrushwidth=2
dc vg 0 1.5 0.02 vb -3 0 0.5
plot abs(i(vd))
dc vg -0.3 1.5 0.01 vb -3 0 0.5
plot abs(i(vd)) ylog ylimit 1e-12 1e-03
.endc
*
.include Modelcards/psp103_nmos-2.mod
.end

1
examples/osdi/psp103/test_osdi_win/README
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@ -0,0 +1 @@
Place psp103.osdi and juncap200.osdi here.

16
examples/osdi/r2_cmc/res_r2_cmc.cir
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r2_cmc
v1 1 0 10
NRr2_cmc 1 0 rmodel w=1u l=20u isnoisy=1
* Poly resistor, r2_cmc model
.model rmodel r2_cmc(level=2 rsh=200 xl=0.2u xw=-0.05u p3=0.12 q3=1.6 p2=0.015 q2=3.8 tc1=1.5e-4 tc2=7e-7)
.control
pre_osdi test_osdi_win/r2_cmc.osdi
op
let res = v(1) / -v1#branch
print res
.endc
.end

1
examples/osdi/r2_cmc/test_osdi_win/README
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@ -0,0 +1 @@
Place r2_cmc.osdi here.
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