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kicad-source/eeschema/sim/sim_model_ngspice_data_bjt.cpp

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Breakup sim_model_ngspice_data.cpp into multiple files to avoid unreasonable compiler link times
2023-05-20 19:58:36 -04:00
/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2022 Mikolaj Wielgus
Revise Copyright statement to align with TLF Recommendation is to avoid using the year nomenclature as this information is already encoded in the git repo. Avoids needing to repeatly update. Also updates AUTHORS.txt from current repo with contributor names
2025-01-01 13:30:11 -08:00
* Copyright The KiCad Developers, see AUTHORS.TXT for contributors.
Breakup sim_model_ngspice_data.cpp into multiple files to avoid unreasonable compiler link times
2023-05-20 19:58:36 -04:00
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include <sim/sim_model_ngspice.h>
void NGSPICE_MODEL_INFO_MAP::addBJT()
{
modelInfos[MODEL_TYPE::BJT] = { "BJT", "NPN", "PNP", { "C", "B", "E", "<S>" }, "Bipolar Junction Transistor", {}, {} };
// Model parameters
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "type", 309, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_STRING, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "npn", "pnp", "NPN or PNP" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "npn", 101, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_BOOL, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "NaN", "NaN", "NPN type device" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "pnp", 102, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_BOOL, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "NaN", "NaN", "PNP type device" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "subs", 204, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::DC, "-1721368256", "-514428616", "Vertical or Lateral device" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnom", 151, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "27", "27", "Parameter measurement temperature" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tref", 151, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "27", "27", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "is_", 103, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "1e-16", "1e-16", "Saturation Current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ibe", 104, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Base-Emitter saturation Current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ibc", 105, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Base-Collector saturation Current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "bf", 106, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "100", "100", "Ideal forward beta" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "nf", 107, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1", "1", "Forward emission coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vaf", 108, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Forward Early voltage" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "va", 108, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ikf", 109, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Forward beta roll-off corner current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ik", 109, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ise", 110, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "B-E leakage saturation current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "c2", 110, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ne", 111, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1.5", "1.5", "B-E leakage emission coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "br", 112, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1", "1", "Ideal reverse beta" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "nr", 113, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1", "1", "Reverse emission coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "var", 114, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Reverse Early voltage" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vb", 114, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ikr", 115, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "reverse beta roll-off corner current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "isc", 116, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "B-C leakage saturation current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "c4", 116, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "nc", 117, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "2", "2", "B-C leakage emission coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "rb", 118, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Zero bias base resistance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "irb", 119, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Current for base resistance=(rb+rbm)/2" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "rbm", 120, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Minimum base resistance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "re", 121, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Emitter resistance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "rc", 122, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Collector resistance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cje", 123, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::CAPACITANCE, "0", "0", "Zero bias B-E depletion capacitance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vje", 124, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0.75", "0.75", "B-E built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "pe", 124, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.75", "0.75", "B-E built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "mje", 125, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0.33", "0.33", "B-E junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "me", 125, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.33", "0.33", "B-E junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tf", 126, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "s", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Ideal forward transit time" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "xtf", 127, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Coefficient for bias dependence of TF" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vtf", 128, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Voltage giving VBC dependence of TF" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "itf", 129, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "High current dependence of TF" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ptf", 130, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "deg", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Excess phase" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cjc", 131, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::CAPACITANCE, "0", "0", "Zero bias B-C depletion capacitance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vjc", 132, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0.75", "0.75", "B-C built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "pc", 132, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.75", "0.75", "B-C built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "mjc", 133, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0.33", "0.33", "B-C junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "mc", 133, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.33", "0.33", "B-C junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "xcjc", 134, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1", "1", "Fraction of B-C cap to internal base" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tr", 135, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "s", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Ideal reverse transit time" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cjs", 136, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::CAPACITANCE, "0", "0", "Zero bias Substrate capacitance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "csub_", 136, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "Zero bias Substrate capacitance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ccs", 136, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "Zero bias Substrate capacitance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vjs", 137, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0.75", "0.75", "Substrate junction built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ps", 137, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.75", "0.75", "Substrate junction built in potential" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "mjs", 138, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Substrate junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ms", 138, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "Substrate junction grading coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "xtb", 139, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Forward and reverse beta temp. exp." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "eg", 140, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "eV", SIM_MODEL::PARAM::CATEGORY::DC, "1.11", "1.11", "Energy gap for IS temp. dependency" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "xti", 141, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "3", "3", "Temp. exponent for IS" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "fc", 142, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0.5", "0.5", "Forward bias junction fit parameter" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "kf", 144, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::NOISE, "0", "0", "Flicker Noise Coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "af", 143, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::NOISE, "0", "0", "Flicker Noise Exponent" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "invearlyvoltf", 301, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Inverse early voltage:forward" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "invearlyvoltr", 302, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Inverse early voltage:reverse" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "invrollofff", 303, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Inverse roll off - forward" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "invrolloffr", 304, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Inverse roll off - reverse" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "collectorconduct", 305, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Collector conductance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "emitterconduct", 306, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Emitter conductance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "transtimevbcfact", 307, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "s", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Transit time VBC factor" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "excessphasefactor", 308, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "deg", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Excess phase fact." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "iss", 145, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Substrate Jct. Saturation Current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ns", 146, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::DC, "1", "1", "Substrate current emission coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "rco", 147, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::DC, "0.01", "0.01", "Intrinsic coll. resistance" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vo", 148, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::DC, "10", "10", "Epi drift saturation voltage" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "gamma", 149, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "1e-11", "1e-11", "Epi doping parameter" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "qco", 150, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "C", SIM_MODEL::PARAM::CATEGORY::DC, "0", "0", "Epi Charge parameter" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tlev", 152, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "Temperature equation selector" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tlevc", 153, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "Temperature equation selector" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tbf1", 154, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "BF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tbf2", 155, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "BF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tbr1", 156, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "BR 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tbr2", 157, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "BR 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tikf1", 158, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IKF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tikf2", 159, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IKF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tikr1", 160, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IKR 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tikr2", 161, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IKR 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tirb1", 162, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IRB 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tirb2", 163, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IRB 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnc1", 164, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NC 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnc2", 165, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NC 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tne1", 166, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NE 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tne2", 167, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NE 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnf1", 168, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnf2", 169, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnr1", 170, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NR 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tnr2", 171, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NR 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trb1", 172, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RB 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trb", 172, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trb2", 173, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RB 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trc1", 174, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RC 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trc", 174, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trc2", 175, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RC 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tre1", 176, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RE 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tre", 176, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tre2", 177, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RE 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trm1", 178, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RBM 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "trm2", 179, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "RBM 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvaf1", 180, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VAF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvaf2", 181, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VAF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvar1", 182, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VAR 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvar2", 183, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VAR 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ctc", 184, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "CJC temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cte", 185, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "CJE temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cts", 186, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "CJS temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvjc", 187, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VJC temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvje", 188, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VJE temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tvjs", 189, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "VJS temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "titf1", 190, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ITF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "titf2", 191, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ITF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ttf1", 192, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "TF 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ttf2", 193, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "TF 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ttr1", 194, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "TR 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ttr2", 195, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "TR 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmje1", 196, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJE 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmje2", 197, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJE 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmjc1", 198, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJC 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmjc2", 199, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJC 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmjs1", 200, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJS 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tmjs2", 201, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "MJS 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tns1", 202, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NS 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tns2", 203, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "NS 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "nkf", 205, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::DC, "0.5", "0.5", "NKF High current beta rolloff exponent" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "nk", 205, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0.5", "0.5", "n.a." );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tis1", 206, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IS 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tis2", 207, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "IS 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tise1", 208, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISE 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tise2", 209, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISE 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tisc1", 210, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISC 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tisc2", 211, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISC 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tiss1", 212, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISS 1. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "tiss2", 213, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "ISS 2. temperature coefficient" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "quasimod", 214, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "Temperature equation selector" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vg", 215, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "eV", SIM_MODEL::PARAM::CATEGORY::DC, "1.206", "1.206", "Energy gap for QS temp. dependency" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "cn", 216, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "2.42", "2.2", "Temperature exponent of RCI" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "d", 217, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0.87", "0.52", "Temperature exponent of VO" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vbe_max", 218, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum voltage B-E junction" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vbc_max", 219, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum voltage B-C junction" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "vce_max", 220, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum voltage C-E branch" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "pd_max", 221, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum device power dissipation" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ic_max", 222, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum collector current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "ib_max", 223, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum base current" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "te_max", 224, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::LIMITING_VALUES, "1e+99", "1e+99", "maximum temperature" );
modelInfos[MODEL_TYPE::BJT].modelParams.emplace_back( "rth0", 225, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "Ω", SIM_MODEL::PARAM::CATEGORY::TEMPERATURE, "0", "0", "thermal resistance juntion to ambient" );
// Instance parameters
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "off", 2, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_BOOL, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Device initially off", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "icvbe", 3, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Initial B-E voltage", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "icvce", 4, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Initial C-E voltage", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "m", 9, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::GEOMETRY, "", "", "Parallel Multiplier", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "area", 1, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::GEOMETRY, "", "", "(Emitter) Area factor", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "areab", 10, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::GEOMETRY, "", "", "Base area factor", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "areac", 11, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::GEOMETRY, "", "", "Collector area factor", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "ic", 5, SIM_MODEL::PARAM::DIR_IN, SIM_VALUE::TYPE_FLOAT_VECTOR, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Initial condition vector", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_area", 6, SIM_MODEL::PARAM::DIR_IN, SIM_VALUE::TYPE_BOOL, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "flag to request sensitivity WRT area", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "colnode", 212, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Number of collector node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "basenode", 213, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Number of base node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "emitnode", 214, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Number of emitter node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "substnode", 215, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Number of substrate node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "colprimenode", 217, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal collector node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "baseprimenode", 218, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal base node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "emitprimenode", 219, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_INT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal emitter node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "ic", 222, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Current at collector node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "ib", 223, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Current at base node", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "ie", 247, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Emitter current", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "is", 248, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "A", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "1e-16", "1e-16", "Substrate current", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "vbe", 220, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "B-E voltage", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "vbc", 221, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "V", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "B-C voltage", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gm", 226, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Small signal transconductance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gpi", 224, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Small signal input conductance - pi", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gmu", 225, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Small signal conductance - mu", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gx", 236, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Conductance from base to internal base", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "go", 227, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Small signal output conductance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "geqcb", 238, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "d(Ibe)/d(Vbc)", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gcsub", 239, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal Subs. cap. equiv. cond.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "gdsub", 254, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal Subs. Diode equiv. cond.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "geqbx", 240, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal C-B-base cap. equiv. cond.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cpi", 250, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal base to emitter capacitance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cmu", 251, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Internal base to collector capacitance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cbx", 252, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Base to collector capacitance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "csub", 253, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "0", "0", "Substrate capacitance", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cqbe", 229, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Cap. due to charge storage in B-E jct.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cqbc", 231, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Cap. due to charge storage in B-C jct.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cqsub", 233, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Cap. due to charge storage in Subs. jct.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cqbx", 235, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Cap. due to charge storage in B-X jct.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "cexbc", 237, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "F", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Total Capacitance in B-X junction", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "qbe", 228, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Charge storage B-E junction", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "qbc", 230, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Charge storage B-C junction", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "qsub", 232, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Charge storage Subs. junction", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "qbx", 234, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Charge storage B-X junction", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "p", 249, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "Power dissipation", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_dc", 246, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "dc sensitivity", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_real", 241, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "real part of ac sensitivity", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_imag", 242, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "dc sens. & imag part of ac sens.", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_mag", 243, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "sensitivity of ac magnitude", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_ph", 244, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_FLOAT, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "sensitivity of ac phase", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "sens_cplx", 245, SIM_MODEL::PARAM::DIR_OUT, SIM_VALUE::TYPE_COMPLEX, "", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "ac sensitivity", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "temp", 7, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::PRINCIPAL, "", "", "instance temperature", true );
modelInfos[MODEL_TYPE::BJT].instanceParams.emplace_back( "dtemp", 8, SIM_MODEL::PARAM::DIR_INOUT, SIM_VALUE::TYPE_FLOAT, "°C", SIM_MODEL::PARAM::CATEGORY::SUPERFLUOUS, "", "", "instance temperature delta from circuit", true );
}
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