/* * rectwaveguide.cpp - rectangular waveguide class implementation * * Copyright (C) 2001 Gopal Narayanan * Copyright (C) 2005, 2006 Stefan Jahn * * 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 package; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include #include #include #include "units.h" #include "transline.h" #include "rectwaveguide.h" RECTWAVEGUIDE::RECTWAVEGUIDE() : TRANSLINE() { m_name = "RectWaveGuide"; } /* * returns square of k */ double RECTWAVEGUIDE::kval_square() { double kval; kval = 2.0* M_PI* f* sqrt( mur* er ) / C0; return kval * kval; } /* * given mode numbers m and n * returns square of cutoff kc value */ double RECTWAVEGUIDE::kc_square( int m, int n ) { return pow( (m * M_PI / a), 2.0 ) + pow( (n * M_PI / b), 2.0 ); } /* * given mode numbers m and n * returns cutoff fc value */ double RECTWAVEGUIDE::fc( int m, int n ) { return sqrt( kc_square( m, n ) / mur / er ) * C0 / 2.0 / M_PI; } /* * alphac - returns attenuation due to conductor losses for all propagating * modes in the waveguide */ double RECTWAVEGUIDE::alphac() { double Rs, f_c; double ac; short m, n, mmax, nmax; Rs = sqrt( M_PI * f * murC * MU0 / sigma ); ac = 0.0; mmax = (int) floor( f / fc( 1, 0 ) ); nmax = mmax; /* below from Ramo, Whinnery & Van Duzer */ /* TE(m,n) modes */ for( n = 0; n<= nmax; n++ ) { for( m = 1; m <= mmax; m++ ) { f_c = fc( m, n ); if( f > f_c ) { switch( n ) { case 0: ac += ( Rs / ( b * ZF0 * sqrt( 1.0 - pow( (f_c / f), 2.0 ) ) ) ) * ( 1.0 + ( (2 * b / a) * pow( (f_c / f), 2.0 ) ) ); break; default: ac += ( (2. * Rs) / ( b * ZF0 * sqrt( 1.0 - pow( (f_c / f), 2.0 ) ) ) ) * ( ( ( 1. + (b / a) ) * pow( (f_c / f), 2.0 ) ) + ( ( 1. - pow( (f_c / f), 2.0 ) ) * ( ( (b / a) * ( ( (b / a) * pow( m, 2. ) ) + pow( n, 2. ) ) ) / ( pow( (b * m / a), 2.0 ) + pow( n, 2.0 ) ) ) ) ); break; } } } } /* TM(m,n) modes */ for( n = 1; n<= nmax; n++ ) { for( m = 1; m<= mmax; m++ ) { f_c = fc( m, n ); if( f > f_c ) { ac += ( (2. * Rs) / ( b * ZF0 * sqrt( 1.0 - pow( (f_c / f), 2.0 ) ) ) ) * ( ( ( pow( m, 2.0 ) * pow( (b / a), 3.0 ) ) + pow( n, 2. ) ) / ( ( pow( (m * b / a), 2. ) ) + pow( n, 2.0 ) ) ); } } } ac = ac * 20.0 * log10( exp( 1. ) ); /* convert from Np/m to db/m */ return ac; } /* * alphac_cutoff - returns attenuation for a cutoff wg */ double RECTWAVEGUIDE::alphac_cutoff() { double acc; acc = sqrt( kc_square( 1, 0 ) - kval_square() ); acc = 20 * log10( exp( 1.0 ) ) * acc; return acc; } /* * returns attenuation due to dielectric losses */ double RECTWAVEGUIDE::alphad() { double k_square, beta; double ad; k_square = kval_square(); beta = sqrt( k_square - kc_square( 1, 0 ) ); ad = (k_square * tand) / (2.0 * beta); ad = ad * 20.0 * log10( exp( 1. ) ); /* convert from Np/m to db/m */ return ad; } /* * get_rectwaveguide_sub * get and assign rectwaveguide substrate parameters * into rectwaveguide structure */ void RECTWAVEGUIDE::get_rectwaveguide_sub() { er = getProperty( EPSILONR_PRM ); mur = getProperty( MUR_PRM ); murC = getProperty( MURC_PRM ); sigma = 1.0 / getProperty( RHO_PRM ); tand = getProperty( TAND_PRM ); tanm = getProperty( TANM_PRM ); } /* * get_rectwaveguide_comp * get and assign rectwaveguide component parameters * into rectwaveguide structure */ void RECTWAVEGUIDE::get_rectwaveguide_comp() { f = getProperty( FREQUENCY_PRM ); } /* * get_rectwaveguide_elec * get and assign rectwaveguide electrical parameters * into rectwaveguide structure */ void RECTWAVEGUIDE::get_rectwaveguide_elec() { Z0 = getProperty( Z0_PRM ); ang_l = getProperty( ANG_L_PRM ); } /* * get_rectwaveguide_phys * get and assign rectwaveguide physical parameters * into rectwaveguide structure */ void RECTWAVEGUIDE::get_rectwaveguide_phys() { a = getProperty( PHYS_WIDTH_PRM ); b = getProperty( PHYS_S_PRM ); l = getProperty( PHYS_LEN_PRM ); } /* * analyze - analysis function */ void RECTWAVEGUIDE::analyze() { double lambda_g; double k_square; /* Get and assign substrate parameters */ get_rectwaveguide_sub(); /* Get and assign component parameters */ get_rectwaveguide_comp(); /* Get and assign physical parameters */ get_rectwaveguide_phys(); k_square = kval_square(); if( kc_square( 1, 0 ) <= k_square ) { /* propagating modes */ // Z0 definition using fictive voltages and currents Z0 = 2.0* ZF0* sqrt( mur / er ) * (b / a) / sqrt( 1.0 - pow( (fc( 1, 0 ) / f), 2.0 ) ); /* calculate electrical angle */ lambda_g = 2.0 * M_PI / sqrt( k_square - kc_square( 1, 0 ) ); ang_l = 2.0 * M_PI * l / lambda_g; /* in radians */ atten_cond = alphac() * l; atten_dielectric = alphad() * l; er_eff = ( 1.0 - pow( fc( 1, 0 ) / f, 2.0 ) ); } else { /* evanascent modes */ Z0 = 0; ang_l = 0; er_eff = 0; atten_dielectric = 0.0; atten_cond = alphac_cutoff() * l; } setProperty( Z0_PRM, Z0 ); setProperty( ANG_L_PRM, ang_l ); show_results(); } /* * synthesize - synthesis function */ void RECTWAVEGUIDE::synthesize() { double lambda_g, k_square, beta; /* Get and assign substrate parameters */ get_rectwaveguide_sub(); /* Get and assign component parameters */ get_rectwaveguide_comp(); /* Get and assign electrical parameters */ get_rectwaveguide_elec(); /* Get and assign physical parameters */ get_rectwaveguide_phys(); if( isSelected( PHYS_S_PRM ) ) { /* solve for b */ b = Z0 * a * sqrt( 1.0 - pow( fc( 1, 0 ) / f, 2.0 ) ) / ( 2.0 * ZF0 * sqrt( mur / er ) ); setProperty( PHYS_S_PRM, b ); } else if( isSelected( PHYS_WIDTH_PRM ) ) { /* solve for a */ a = sqrt( pow( 2.0 * ZF0 * b / Z0, 2.0 ) + pow( C0 / (2.0 * f), 2.0 ) ); setProperty( PHYS_WIDTH_PRM, a ); } k_square = kval_square(); beta = sqrt( k_square - kc_square( 1, 0 ) ); lambda_g = 2.0 * M_PI / beta; l = (ang_l * lambda_g) / (2.0 * M_PI); /* in m */ setProperty( PHYS_LEN_PRM, l ); if( kc_square( 1, 0 ) <= k_square ) { /*propagating modes */ beta = sqrt( k_square - kc_square( 1, 0 ) ); lambda_g = 2.0 * M_PI / beta; atten_cond = alphac() * l; atten_dielectric = alphad() * l; er_eff = ( 1.0 - pow( (fc( 1, 0 ) / f), 2.0 ) ); } else { /*evanascent modes */ Z0 = 0; ang_l = 0; er_eff = 0; atten_dielectric = 0.0; atten_cond = alphac_cutoff() * l; } show_results(); } #define MAXSTRLEN 128 void RECTWAVEGUIDE::show_results() { int m, n, max = 6; char text[MAXSTRLEN], txt[32]; // Z0EH = Ey / Hx (definition with field quantities) Z0EH = ZF0 * sqrt( kval_square() / ( kval_square() - kc_square( 1, 0 ) ) ); setResult( 0, Z0EH, "Ohm" ); setResult( 1, er_eff, "" ); setResult( 2, atten_cond, "dB" ); setResult( 3, atten_dielectric, "dB" ); // show possible TE modes (H modes) if( f < fc( 1, 0 ) ) strcpy( text, "none" ); else { strcpy( text, "" ); for( m = 0; m<= max; m++ ) { for( n = 0; n<= max; n++ ) { if( (m == 0) && (n == 0) ) continue; if( f >= ( fc( m, n ) ) ) { sprintf( txt, "H(%u,%u) ", m, n ); if( (strlen( text ) + strlen( txt ) + 5) < MAXSTRLEN ) strcat( text, txt ); else { strcat( text, "..." ); m = n = max + 1; // print no more modes } } } } } setResult( 4, text ); // show possible TM modes (E modes) if( f < fc( 1, 1 ) ) strcpy( text, "none" ); else { strcpy( text, "" ); for( m = 1; m<= max; m++ ) { for( n = 1; n<= max; n++ ) { if( f >= fc( m, n ) ) { sprintf( txt, "E(%u,%u) ", m, n ); if( (strlen( text ) + strlen( txt ) + 5) < MAXSTRLEN ) strcat( text, txt ); else { strcat( text, "..." ); m = n = max + 1; // print no more modes } } } } } setResult( 5, text ); }