/* * ccvs.cpp - ccvs class implementation * * Copyright (C) 2003, 2004, 2005, 2006 Stefan Jahn * * This 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, or (at your option) * any later version. * * This software 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 package; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, * Boston, MA 02110-1301, USA. * * $Id: ccvs.cpp,v 1.14 2006/02/25 14:42:50 raimi Exp $ * */ #if HAVE_CONFIG_H # include #endif #define __USE_BSD #define __USE_XOPEN #include #include #include "complex.h" #include "object.h" #include "node.h" #include "circuit.h" #include "component_id.h" #include "constants.h" #include "ccvs.h" ccvs::ccvs () : circuit (4) { type = CIR_CCVS; setVoltageSources (2); } void ccvs::calcSP (nr_double_t frequency) { nr_double_t g = getPropertyDouble ("G") / z0; nr_double_t t = getPropertyDouble ("T"); complex z1 = polar (g / 2.0, M_PI - 2.0 * M_PI * frequency * t); complex z2 = polar (g / 2.0, - 2.0 * M_PI * frequency * t); setS (NODE_1, NODE_1, 0.0); setS (NODE_1, NODE_2, 0.0); setS (NODE_1, NODE_3, 0.0); setS (NODE_1, NODE_4, 1.0); setS (NODE_2, NODE_1, z2); setS (NODE_2, NODE_2, 0.0); setS (NODE_2, NODE_3, 1.0); setS (NODE_2, NODE_4, z1); setS (NODE_3, NODE_1, z1); setS (NODE_3, NODE_2, 1.0); setS (NODE_3, NODE_3, 0.0); setS (NODE_3, NODE_4, z2); setS (NODE_4, NODE_1, 1.0); setS (NODE_4, NODE_2, 0.0); setS (NODE_4, NODE_3, 0.0); setS (NODE_4, NODE_4, 0.0); } void ccvs::initDC (void) { allocMatrixMNA (); setB (NODE_1, VSRC_1, +1.0); setB (NODE_2, VSRC_1, +0.0); setB (NODE_3, VSRC_1, +0.0); setB (NODE_4, VSRC_1, -1.0); setB (NODE_1, VSRC_2, +0.0); setB (NODE_2, VSRC_2, -1.0); setB (NODE_3, VSRC_2, +1.0); setB (NODE_4, VSRC_2, +0.0); setC (VSRC_1, NODE_1, +0.0); setC (VSRC_1, NODE_2, +1.0); setC (VSRC_1, NODE_3, -1.0); setC (VSRC_1, NODE_4, +0.0); setC (VSRC_2, NODE_1, +1.0); setC (VSRC_2, NODE_2, +0.0); setC (VSRC_2, NODE_3, +0.0); setC (VSRC_2, NODE_4, -1.0); setD (VSRC_1, VSRC_1, - getPropertyDouble ("G")); setD (VSRC_2, VSRC_2, 0.0); setD (VSRC_1, VSRC_2, 0.0); setD (VSRC_2, VSRC_1, 0.0); setE (VSRC_1, 0.0); setE (VSRC_2, 0.0); } void ccvs::initAC (void) { initDC (); } void ccvs::calcAC (nr_double_t frequency) { nr_double_t t = getPropertyDouble ("T"); complex g = polar (getPropertyDouble ("G"), - 2.0 * M_PI * frequency * t); setD (VSRC_1, VSRC_1, -g); } void ccvs::initTR (void) { nr_double_t t = getPropertyDouble ("T"); initDC (); deleteHistory (); if (t > 0.0) { setHistory (true); initHistory (t); setC (VSRC_2, NODE_1, +0.0); setC (VSRC_2, NODE_2, +1.0); setC (VSRC_2, NODE_3, -1.0); setC (VSRC_2, NODE_4, +0.0); setC (VSRC_1, NODE_1, +1.0); setC (VSRC_1, NODE_2, +0.0); setC (VSRC_1, NODE_3, +0.0); setC (VSRC_1, NODE_4, -1.0); setD (VSRC_1, VSRC_1, 0.0); } } void ccvs::calcTR (nr_double_t t) { nr_double_t T = getPropertyDouble ("T"); if (T > 0.0) { T = t - T; nr_double_t g = getPropertyDouble ("G"); nr_double_t i = getJ (VSRC_1, T); setE (VSRC_2, g * i); } }