969 lines
34 KiB
C++
969 lines
34 KiB
C++
/*
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* c_microstrip.cpp - coupled microstrip class implementation
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*
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* Copyright (C) 2002 Claudio Girardi <claudio.girardi@ieee.org>
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* Copyright (C) 2005, 2006 Stefan Jahn <stefan@lkcc.org>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or (at
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* your option) any later version.
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*
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* This program is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this package; see the file COPYING. If not, write to
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* the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor,
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* Boston, MA 02110-1301, USA.
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*
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*/
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/* c_microstrip.c - Puts up window for coupled microstrips and
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* performs the associated calculations
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* Based on the original microstrip.c by Gopal Narayanan
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*/
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#include <cmath>
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#include <cstdio>
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#include <cstdlib>
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#include <cstring>
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#include "c_microstrip.h"
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#include "microstrip.h"
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#include "transline.h"
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#include "units.h"
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C_MICROSTRIP::C_MICROSTRIP() : TRANSLINE(),
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h( 0.0 ), // height of substrate
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ht( 0.0 ), // height to the top of box
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t( 0.0 ), // thickness of top metal
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rough( 0.0 ), // Roughness of top metal
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w( 0.0 ), // width of lines
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w_t_e( 0.0 ), // even-mode thickness-corrected line width
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w_t_o( 0.0 ), // odd-mode thickness-corrected line width
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l( 0.0 ), // length of lines
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s( 0.0 ), // spacing of lines
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Z0_e_0( 0.0 ), // static even-mode impedance
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Z0_o_0( 0.0 ), // static odd-mode impedance
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Zdiff( 0.0), // differential impedance
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Z0e( 0.0 ), // even-mode impedance
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Z0o( 0.0 ), // odd-mode impedance
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c_e( 0.0 ), // even-mode capacitance
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c_o( 0.0 ), // odd-mode capacitance
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ang_l_e( 0.0 ), // even-mode electrical length in angle
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ang_l_o( 0.0 ), // odd-mode electrical length in angle
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er_eff_e( 0.0 ), // even-mode effective dielectric constant
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er_eff_o( 0.0 ), // odd-mode effective dielectric constant
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er_eff_e_0( 0.0 ), // static even-mode effective dielectric constant
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er_eff_o_0( 0.0 ), // static odd-mode effective dielectric constant
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w_eff( 0.0 ), // Effective width of line
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atten_dielectric_e( 0.0 ), // even-mode dielectric losses (dB)
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atten_cond_e( 0.0 ), // even-mode conductors losses (dB)
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atten_dielectric_o( 0.0 ), // odd-mode dielectric losses (dB)
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atten_cond_o( 0.0 ), // odd-mode conductors losses (dB)
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aux_ms( nullptr )
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{
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m_Name = "Coupled_MicroStrip";
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Init();
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}
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C_MICROSTRIP::~C_MICROSTRIP()
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{
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delete aux_ms;
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}
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/*
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* delta_u_thickness_single() computes the thickness effect on
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* normalized width for a single microstrip line
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*
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* References: H. A. Atwater, "Simplified Design Equations for
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* Microstrip Line Parameters", Microwave Journal, pp. 109-115,
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* November 1989.
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*/
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double C_MICROSTRIP::delta_u_thickness_single( double u, double t_h )
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{
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double delta_u;
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if( t_h > 0.0 )
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{
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delta_u =
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(1.25 * t_h /
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M_PI) *
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( 1.0 +
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log( ( 2.0 +
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(4.0 * M_PI * u -
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2.0) / ( 1.0 + exp( -100.0 * ( u - 1.0 / (2.0 * M_PI) ) ) ) ) / t_h ) );
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}
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else
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{
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delta_u = 0.0;
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}
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return delta_u;
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}
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/*
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* delta_u_thickness() - compute the thickness effect on normalized
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* width for coupled microstrips
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*
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* References: Rolf Jansen, "High-Speed Computation of Single and
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* Coupled Microstrip Parameters Including Dispersion, High-Order
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* Modes, Loss and Finite Strip Thickness", IEEE Trans. MTT, vol. 26,
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* no. 2, pp. 75-82, Feb. 1978
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*/
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void C_MICROSTRIP::delta_u_thickness()
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{
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double e_r, u, g, t_h;
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double delta_u, delta_t, delta_u_e, delta_u_o;
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e_r = m_parameters[EPSILONR_PRM];
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u = m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM]; /* normalized line width */
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g = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM]; /* normalized line spacing */
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t_h = m_parameters[T_PRM] / m_parameters[H_PRM]; /* normalized strip thickness */
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if( t_h > 0.0 )
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{
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/* single microstrip correction for finite strip thickness */
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delta_u = delta_u_thickness_single( u, t_h );
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delta_t = t_h / ( g * e_r );
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/* thickness correction for the even- and odd-mode */
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delta_u_e = delta_u * ( 1.0 - 0.5 * exp( -0.69 * delta_u / delta_t ) );
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delta_u_o = delta_u_e + delta_t;
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}
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else
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{
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delta_u_e = delta_u_o = 0.0;
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}
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w_t_e = m_parameters[PHYS_WIDTH_PRM] + delta_u_e * m_parameters[H_PRM];
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w_t_o = m_parameters[PHYS_WIDTH_PRM] + delta_u_o * m_parameters[H_PRM];
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}
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/*
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* compute various parameters for a single line
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*/
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void C_MICROSTRIP::compute_single_line()
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{
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if( aux_ms == NULL )
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aux_ms = new MICROSTRIP();
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/* prepare parameters for single microstrip computations */
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aux_ms->m_parameters[EPSILONR_PRM] = m_parameters[EPSILONR_PRM];
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aux_ms->m_parameters[PHYS_WIDTH_PRM] = m_parameters[PHYS_WIDTH_PRM];
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aux_ms->m_parameters[H_PRM] = m_parameters[H_PRM];
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aux_ms->m_parameters[T_PRM] = 0.0;
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//aux_ms->m_parameters[H_T_PRM] = m_parameters[H_T_PRM];
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aux_ms->m_parameters[H_T_PRM] = 1e12; /* arbitrarily high */
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aux_ms->m_parameters[FREQUENCY_PRM] = m_parameters[FREQUENCY_PRM];
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aux_ms->m_parameters[MURC_PRM] = m_parameters[MURC_PRM];
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aux_ms->microstrip_Z0();
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aux_ms->dispersion();
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}
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/*
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* filling_factor_even() - compute the filling factor for the coupled
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* microstrips even-mode without cover and zero conductor thickness
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*/
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double C_MICROSTRIP::filling_factor_even( double u, double g, double e_r )
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{
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double v, v3, v4, a_e, b_e, q_inf;
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v = u * ( 20.0 + g * g ) / ( 10.0 + g * g ) + g * exp( -g );
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v3 = v * v * v;
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v4 = v3 * v;
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a_e = 1.0 + log( ( v4 + v * v / 2704.0 ) / ( v4 + 0.432 ) ) / 49.0
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+ log( 1.0 + v3 / 5929.741 ) / 18.7;
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b_e = 0.564 * pow( ( ( e_r - 0.9 ) / ( e_r + 3.0 ) ), 0.053 );
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/* filling factor, with width corrected for thickness */
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q_inf = pow( ( 1.0 + 10.0 / v ), -a_e * b_e );
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return q_inf;
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}
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/**
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* filling_factor_odd() - compute the filling factor for the coupled
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* microstrips odd-mode without cover and zero conductor thickness
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*/
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double C_MICROSTRIP::filling_factor_odd( double u, double g, double e_r )
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{
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double b_odd = 0.747 * e_r / ( 0.15 + e_r );
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double c_odd = b_odd - ( b_odd - 0.207 ) * exp( -0.414 * u );
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double d_odd = 0.593 + 0.694 * exp( -0.562 * u );
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/* filling factor, with width corrected for thickness */
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double q_inf = exp( -c_odd * pow( g, d_odd ) );
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return q_inf;
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}
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/*
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* delta_q_cover_even() - compute the cover effect on filling factor
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* for the even-mode
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*/
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double C_MICROSTRIP::delta_q_cover_even( double h2h )
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{
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double q_c;
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if( h2h <= 39 )
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q_c = tanh( 1.626 + 0.107 * h2h - 1.733 / sqrt( h2h ) );
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else
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q_c = 1.0;
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return q_c;
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}
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/*
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* delta_q_cover_odd() - compute the cover effect on filling factor
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* for the odd-mode
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*/
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double C_MICROSTRIP::delta_q_cover_odd( double h2h )
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{
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double q_c;
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if( h2h <= 7 )
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q_c = tanh( 9.575 / ( 7.0 - h2h ) - 2.965 + 1.68 * h2h - 0.311 * h2h * h2h );
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else
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q_c = 1.0;
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return q_c;
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}
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/**
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* er_eff_static() - compute the static effective dielectric constants
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*
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* References: Manfred Kirschning and Rolf Jansen, "Accurate
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* Wide-Range Design Equations for the Frequency-Dependent
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* Characteristic of Parallel Coupled Microstrip Lines", IEEE
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* Trans. MTT, vol. 32, no. 1, Jan. 1984
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*/
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void C_MICROSTRIP::er_eff_static()
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{
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double u_t_e, u_t_o, g, h2, h2h;
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double a_o, t_h, q, q_c, q_t, q_inf;
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double er_eff_single;
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double er;
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er = m_parameters[EPSILONR_PRM];
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/* compute zero-thickness single line parameters */
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compute_single_line();
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er_eff_single = aux_ms->er_eff_0;
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h2 = m_parameters[H_T_PRM];
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u_t_e = w_t_e / m_parameters[H_PRM]; /* normalized even_mode line width */
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u_t_o = w_t_o / m_parameters[H_PRM]; /* normalized odd_mode line width */
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g = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM]; /* normalized line spacing */
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h2h = h2 / m_parameters[H_PRM]; /* normalized cover height */
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t_h = m_parameters[T_PRM] / m_parameters[H_PRM]; /* normalized strip thickness */
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/* filling factor, computed with thickness corrected width */
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q_inf = filling_factor_even( u_t_e, g, er );
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/* cover effect */
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q_c = delta_q_cover_even( h2h );
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/* thickness effect */
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q_t = aux_ms->delta_q_thickness( u_t_e, t_h );
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/* resultant filling factor */
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q = ( q_inf - q_t ) * q_c;
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/* static even-mode effective dielectric constant */
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er_eff_e_0 = 0.5 * ( er + 1.0 ) + 0.5 * ( er - 1.0 ) * q;
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/* filling factor, with width corrected for thickness */
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q_inf = filling_factor_odd( u_t_o, g, er );
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/* cover effect */
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q_c = delta_q_cover_odd( h2h );
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/* thickness effect */
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q_t = aux_ms->delta_q_thickness( u_t_o, t_h );
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/* resultant filling factor */
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q = ( q_inf - q_t ) * q_c;
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a_o = 0.7287 * ( er_eff_single - 0.5 * ( er + 1.0 ) ) * ( 1.0 - exp( -0.179 * u_t_o ) );
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/* static odd-mode effective dielectric constant */
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er_eff_o_0 = ( 0.5 * ( er + 1.0 ) + a_o - er_eff_single ) * q + er_eff_single;
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}
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/**
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* delta_Z0_even_cover() - compute the even-mode impedance correction
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* for a homogeneous microstrip due to the cover
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*
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* References: S. March, "Microstrip Packaging: Watch the Last Step",
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* Microwaves, vol. 20, no. 13, pp. 83.94, Dec. 1981.
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*/
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double C_MICROSTRIP::delta_Z0_even_cover( double g, double u, double h2h )
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{
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double f_e, g_e, delta_Z0_even;
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double x, y, A, B, C, D, E, F;
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A = -4.351 / pow( 1.0 + h2h, 1.842 );
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B = 6.639 / pow( 1.0 + h2h, 1.861 );
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C = -2.291 / pow( 1.0 + h2h, 1.90 );
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f_e = 1.0 - atanh( A + ( B + C * u ) * u );
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x = pow( 10.0, 0.103 * g - 0.159 );
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y = pow( 10.0, 0.0492 * g - 0.073 );
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D = 0.747 / sin( 0.5 * M_PI * x );
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E = 0.725 * sin( 0.5 * M_PI * y );
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F = pow( 10.0, 0.11 - 0.0947 * g );
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g_e = 270.0 * ( 1.0 - tanh( D + E * sqrt( 1.0 + h2h ) - F / ( 1.0 + h2h ) ) );
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delta_Z0_even = f_e * g_e;
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return delta_Z0_even;
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}
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/**
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* delta_Z0_odd_cover() - compute the odd-mode impedance correction
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* for a homogeneous microstrip due to the cover
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*
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* References: S. March, "Microstrip Packaging: Watch the Last Step",
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* Microwaves, vol. 20, no. 13, pp. 83.94, Dec. 1981.
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*/
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double C_MICROSTRIP::delta_Z0_odd_cover( double g, double u, double h2h )
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{
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double f_o, g_o, delta_Z0_odd;
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double G, J, K, L;
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J = tanh( pow( 1.0 + h2h, 1.585 ) / 6.0 );
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f_o = pow( u, J );
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G = 2.178 - 0.796 * g;
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if( g > 0.858 )
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K = log10( 20.492 * pow( g, 0.174 ) );
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else
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K = 1.30;
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if( g > 0.873 )
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L = 2.51 * pow( g, -0.462 );
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else
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L = 2.674;
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g_o = 270.0 * ( 1.0 - tanh( G + K * sqrt( 1.0 + h2h ) - L / ( 1.0 + h2h ) ) );
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delta_Z0_odd = f_o * g_o;
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return delta_Z0_odd;
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}
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/**
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* Z0_even_odd() - compute the static even- and odd-mode static
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* impedances
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*
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* References: Manfred Kirschning and Rolf Jansen, "Accurate
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* Wide-Range Design Equations for the Frequency-Dependent
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* Characteristic of Parallel Coupled Microstrip Lines", IEEE
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* Trans. MTT, vol. 32, no. 1, Jan. 1984
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*/
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void C_MICROSTRIP::Z0_even_odd()
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{
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double er_eff, h2, u_t_e, u_t_o, g, h2h;
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double Q_1, Q_2, Q_3, Q_4, Q_5, Q_6, Q_7, Q_8, Q_9, Q_10;
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double delta_Z0_e_0, delta_Z0_o_0, Z0_single, er_eff_single;
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h2 = m_parameters[H_T_PRM];
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u_t_e = w_t_e / m_parameters[H_PRM]; /* normalized even-mode line width */
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u_t_o = w_t_o / m_parameters[H_PRM]; /* normalized odd-mode line width */
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g = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM]; /* normalized line spacing */
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h2h = h2 / m_parameters[H_PRM]; /* normalized cover height */
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Z0_single = aux_ms->Z0_0;
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er_eff_single = aux_ms->er_eff_0;
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/* even-mode */
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er_eff = er_eff_e_0;
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Q_1 = 0.8695 * pow( u_t_e, 0.194 );
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Q_2 = 1.0 + 0.7519 * g + 0.189 * pow( g, 2.31 );
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Q_3 = 0.1975 + pow( ( 16.6 + pow( ( 8.4 / g ), 6.0 ) ), -0.387 )
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+ log( pow( g, 10.0 ) / ( 1.0 + pow( g / 3.4, 10.0 ) ) ) / 241.0;
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Q_4 = 2.0 * Q_1
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/ ( Q_2 * ( exp( -g ) * pow( u_t_e, Q_3 ) + ( 2.0 - exp( -g ) ) * pow( u_t_e, -Q_3 ) ) );
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/* static even-mode impedance */
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Z0_e_0 = Z0_single * sqrt( er_eff_single / er_eff )
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/ ( 1.0 - sqrt( er_eff_single ) * Q_4 * Z0_single / ZF0 );
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/* correction for cover */
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delta_Z0_e_0 = delta_Z0_even_cover( g, u_t_e, h2h ) / sqrt( er_eff );
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Z0_e_0 = Z0_e_0 - delta_Z0_e_0;
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/* odd-mode */
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er_eff = er_eff_o_0;
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Q_5 = 1.794 + 1.14 * log( 1.0 + 0.638 / ( g + 0.517 * pow( g, 2.43 ) ) );
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Q_6 = 0.2305 + log( pow( g, 10.0 ) / ( 1.0 + pow( g / 5.8, 10.0 ) ) ) / 281.3
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+ log( 1.0 + 0.598 * pow( g, 1.154 ) ) / 5.1;
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Q_7 = ( 10.0 + 190.0 * g * g ) / ( 1.0 + 82.3 * g * g * g );
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Q_8 = exp( -6.5 - 0.95 * log( g ) - pow( g / 0.15, 5.0 ) );
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Q_9 = log( Q_7 ) * ( Q_8 + 1.0 / 16.5 );
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Q_10 = ( Q_2 * Q_4 - Q_5 * exp( log( u_t_o ) * Q_6 * pow( u_t_o, -Q_9 ) ) ) / Q_2;
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/* static odd-mode impedance */
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Z0_o_0 = Z0_single * sqrt( er_eff_single / er_eff )
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/ ( 1.0 - sqrt( er_eff_single ) * Q_10 * Z0_single / ZF0 );
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/* correction for cover */
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delta_Z0_o_0 = delta_Z0_odd_cover( g, u_t_o, h2h ) / sqrt( er_eff );
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Z0_o_0 = Z0_o_0 - delta_Z0_o_0;
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}
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/*
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* er_eff_freq() - compute er_eff as a function of frequency
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*/
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void C_MICROSTRIP::er_eff_freq()
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{
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double P_1, P_2, P_3, P_4, P_5, P_6, P_7;
|
|
double P_8, P_9, P_10, P_11, P_12, P_13, P_14, P_15;
|
|
double F_e, F_o;
|
|
double er_eff, u, g, f_n;
|
|
|
|
u = m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM]; /* normalize line width */
|
|
g = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM]; /* normalize line spacing */
|
|
|
|
/* normalized frequency [GHz * mm] */
|
|
f_n = m_parameters[FREQUENCY_PRM] * m_parameters[H_PRM] / 1e06;
|
|
|
|
er_eff = er_eff_e_0;
|
|
P_1 = 0.27488 + ( 0.6315 + 0.525 / pow( 1.0 + 0.0157 * f_n, 20.0 ) ) * u
|
|
- 0.065683 * exp( -8.7513 * u );
|
|
P_2 = 0.33622 * ( 1.0 - exp( -0.03442 * m_parameters[EPSILONR_PRM] ) );
|
|
P_3 = 0.0363 * exp( -4.6 * u ) * ( 1.0 - exp( -pow( f_n / 38.7, 4.97 ) ) );
|
|
P_4 = 1.0 + 2.751 * ( 1.0 - exp( -pow( m_parameters[EPSILONR_PRM] / 15.916, 8.0 ) ) );
|
|
P_5 = 0.334 * exp( -3.3 * pow( m_parameters[EPSILONR_PRM] / 15.0, 3.0 ) ) + 0.746;
|
|
P_6 = P_5 * exp( -pow( f_n / 18.0, 0.368 ) );
|
|
P_7 = 1.0
|
|
+ 4.069 * P_6 * pow( g, 0.479 ) * exp( -1.347 * pow( g, 0.595 ) - 0.17 * pow( g, 2.5 ) );
|
|
|
|
F_e = P_1 * P_2 * pow( ( P_3 * P_4 + 0.1844 * P_7 ) * f_n, 1.5763 );
|
|
/* even-mode effective dielectric constant */
|
|
er_eff_e = m_parameters[EPSILONR_PRM] - ( m_parameters[EPSILONR_PRM] - er_eff ) / ( 1.0 + F_e );
|
|
|
|
er_eff = er_eff_o_0;
|
|
P_8 = 0.7168 * ( 1.0 + 1.076 / ( 1.0 + 0.0576 * ( m_parameters[EPSILONR_PRM] - 1.0 ) ) );
|
|
P_9 = P_8
|
|
- 0.7913 * ( 1.0 - exp( -pow( f_n / 20.0, 1.424 ) ) )
|
|
* atan( 2.481 * pow( m_parameters[EPSILONR_PRM] / 8.0, 0.946 ) );
|
|
P_10 = 0.242 * pow( m_parameters[EPSILONR_PRM] - 1.0, 0.55 );
|
|
P_11 = 0.6366 * ( exp( -0.3401 * f_n ) - 1.0 ) * atan( 1.263 * pow( u / 3.0, 1.629 ) );
|
|
P_12 = P_9 + ( 1.0 - P_9 ) / ( 1.0 + 1.183 * pow( u, 1.376 ) );
|
|
P_13 = 1.695 * P_10 / ( 0.414 + 1.605 * P_10 );
|
|
P_14 = 0.8928 + 0.1072 * ( 1.0 - exp( -0.42 * pow( f_n / 20.0, 3.215 ) ) );
|
|
P_15 = fabs( 1.0 - 0.8928 * ( 1.0 + P_11 ) * P_12 * exp( -P_13 * pow( g, 1.092 ) ) / P_14 );
|
|
|
|
F_o = P_1 * P_2 * pow( ( P_3 * P_4 + 0.1844 ) * f_n * P_15, 1.5763 );
|
|
/* odd-mode effective dielectric constant */
|
|
er_eff_o = m_parameters[EPSILONR_PRM] - ( m_parameters[EPSILONR_PRM] - er_eff ) / ( 1.0 + F_o );
|
|
}
|
|
|
|
|
|
/*
|
|
* conductor_losses() - compute microstrips conductor losses per unit
|
|
* length
|
|
*/
|
|
void C_MICROSTRIP::conductor_losses()
|
|
{
|
|
double e_r_eff_e_0, e_r_eff_o_0, Z0_h_e, Z0_h_o, delta;
|
|
double K, R_s, Q_c_e, Q_c_o, alpha_c_e, alpha_c_o;
|
|
|
|
e_r_eff_e_0 = er_eff_e_0;
|
|
e_r_eff_o_0 = er_eff_o_0;
|
|
Z0_h_e = Z0_e_0 * sqrt( e_r_eff_e_0 ); /* homogeneous stripline impedance */
|
|
Z0_h_o = Z0_o_0 * sqrt( e_r_eff_o_0 ); /* homogeneous stripline impedance */
|
|
delta = m_parameters[SKIN_DEPTH_PRM];
|
|
|
|
if( m_parameters[FREQUENCY_PRM] > 0.0 )
|
|
{
|
|
/* current distribution factor (same for the two modes) */
|
|
K = exp( -1.2 * pow( ( Z0_h_e + Z0_h_o ) / ( 2.0 * ZF0 ), 0.7 ) );
|
|
/* skin resistance */
|
|
R_s = 1.0 / ( m_parameters[SIGMA_PRM] * delta );
|
|
/* correction for surface roughness */
|
|
R_s *= 1.0
|
|
+ ( ( 2.0 / M_PI )
|
|
* atan( 1.40 * pow( ( m_parameters[ROUGH_PRM] / delta ), 2.0 ) ) );
|
|
|
|
/* even-mode strip inductive quality factor */
|
|
Q_c_e = ( M_PI * Z0_h_e * m_parameters[PHYS_WIDTH_PRM] * m_parameters[FREQUENCY_PRM] )
|
|
/ ( R_s * C0 * K );
|
|
/* even-mode losses per unith length */
|
|
alpha_c_e = ( 20.0 * M_PI / log( 10.0 ) ) * m_parameters[FREQUENCY_PRM]
|
|
* sqrt( e_r_eff_e_0 ) / ( C0 * Q_c_e );
|
|
|
|
/* odd-mode strip inductive quality factor */
|
|
Q_c_o = ( M_PI * Z0_h_o * m_parameters[PHYS_WIDTH_PRM] * m_parameters[FREQUENCY_PRM] )
|
|
/ ( R_s * C0 * K );
|
|
/* odd-mode losses per unith length */
|
|
alpha_c_o = ( 20.0 * M_PI / log( 10.0 ) ) * m_parameters[FREQUENCY_PRM]
|
|
* sqrt( e_r_eff_o_0 ) / ( C0 * Q_c_o );
|
|
}
|
|
else
|
|
{
|
|
alpha_c_e = alpha_c_o = 0.0;
|
|
}
|
|
|
|
atten_cond_e = alpha_c_e * m_parameters[PHYS_LEN_PRM];
|
|
atten_cond_o = alpha_c_o * m_parameters[PHYS_LEN_PRM];
|
|
}
|
|
|
|
|
|
/*
|
|
* dielectric_losses() - compute microstrips dielectric losses per
|
|
* unit length
|
|
*/
|
|
void C_MICROSTRIP::dielectric_losses()
|
|
{
|
|
double e_r, e_r_eff_e_0, e_r_eff_o_0;
|
|
double alpha_d_e, alpha_d_o;
|
|
|
|
e_r = m_parameters[EPSILONR_PRM];
|
|
e_r_eff_e_0 = er_eff_e_0;
|
|
e_r_eff_o_0 = er_eff_o_0;
|
|
|
|
alpha_d_e = ( 20.0 * M_PI / log( 10.0 ) ) * ( m_parameters[FREQUENCY_PRM] / C0 )
|
|
* ( e_r / sqrt( e_r_eff_e_0 ) ) * ( ( e_r_eff_e_0 - 1.0 ) / ( e_r - 1.0 ) )
|
|
* m_parameters[TAND_PRM];
|
|
alpha_d_o = ( 20.0 * M_PI / log( 10.0 ) ) * ( m_parameters[FREQUENCY_PRM] / C0 )
|
|
* ( e_r / sqrt( e_r_eff_o_0 ) ) * ( ( e_r_eff_o_0 - 1.0 ) / ( e_r - 1.0 ) )
|
|
* m_parameters[TAND_PRM];
|
|
|
|
atten_dielectric_e = alpha_d_e * m_parameters[PHYS_LEN_PRM];
|
|
atten_dielectric_o = alpha_d_o * m_parameters[PHYS_LEN_PRM];
|
|
}
|
|
|
|
|
|
/*
|
|
* c_microstrip_attenuation() - compute attenuation of coupled
|
|
* microstrips
|
|
*/
|
|
void C_MICROSTRIP::attenuation()
|
|
{
|
|
m_parameters[SKIN_DEPTH_PRM] = skin_depth();
|
|
conductor_losses();
|
|
dielectric_losses();
|
|
}
|
|
|
|
|
|
/*
|
|
* line_angle() - calculate strips electrical lengths in radians
|
|
*/
|
|
void C_MICROSTRIP::line_angle()
|
|
{
|
|
double e_r_eff_e, e_r_eff_o;
|
|
double v_e, v_o, lambda_g_e, lambda_g_o;
|
|
|
|
e_r_eff_e = er_eff_e;
|
|
e_r_eff_o = er_eff_o;
|
|
|
|
/* even-mode velocity */
|
|
v_e = C0 / sqrt( e_r_eff_e );
|
|
/* odd-mode velocity */
|
|
v_o = C0 / sqrt( e_r_eff_o );
|
|
/* even-mode wavelength */
|
|
lambda_g_e = v_e / m_parameters[FREQUENCY_PRM];
|
|
/* odd-mode wavelength */
|
|
lambda_g_o = v_o / m_parameters[FREQUENCY_PRM];
|
|
/* electrical angles */
|
|
ang_l_e = 2.0 * M_PI * m_parameters[PHYS_LEN_PRM] / lambda_g_e; /* in radians */
|
|
ang_l_o = 2.0 * M_PI * m_parameters[PHYS_LEN_PRM] / lambda_g_o; /* in radians */
|
|
}
|
|
|
|
|
|
/**
|
|
* Note that differential impedance is exactly twice the odd mode impedance.
|
|
* Odd mode is not the same as single-ended impedance, so avoid approximations found
|
|
* on websites that use static single ended impedance as the starting point
|
|
*/
|
|
void C_MICROSTRIP::diff_impedance()
|
|
{
|
|
Zdiff = 2 * Z0_o_0;
|
|
}
|
|
|
|
|
|
void C_MICROSTRIP::syn_err_fun( double* f1, double* f2, double s_h, double w_h, double e_r,
|
|
double w_h_se, double w_h_so )
|
|
{
|
|
double g, he;
|
|
|
|
g = cosh( 0.5 * M_PI * s_h );
|
|
he = cosh( M_PI * w_h + 0.5 * M_PI * s_h );
|
|
|
|
*f1 = ( 2.0 / M_PI ) * acosh( ( 2.0 * he - g + 1.0 ) / ( g + 1.0 ) );
|
|
*f2 = ( 2.0 / M_PI ) * acosh( ( 2.0 * he - g - 1.0 ) / ( g - 1.0 ) );
|
|
|
|
if( e_r <= 6.0 )
|
|
*f2 += ( 4.0 / ( M_PI * ( 1.0 + e_r / 2.0 ) ) ) * acosh( 1.0 + 2.0 * w_h / s_h );
|
|
else
|
|
*f2 += ( 1.0 / M_PI ) * acosh( 1.0 + 2.0 * w_h / s_h );
|
|
|
|
*f1 -= w_h_se;
|
|
*f2 -= w_h_so;
|
|
}
|
|
|
|
|
|
/*
|
|
* synth_width - calculate widths given Z0 and e_r
|
|
* from Akhtarzad S. et al., "The design of coupled microstrip lines",
|
|
* IEEE Trans. MTT-23, June 1975 and
|
|
* Hinton, J.H., "On design of coupled microstrip lines", IEEE Trans.
|
|
* MTT-28, March 1980
|
|
*/
|
|
void C_MICROSTRIP::synth_width()
|
|
{
|
|
double Z0, e_r;
|
|
double w_h_se, w_h_so, w_h, a, ce, co, s_h;
|
|
double f1, f2, ft1, ft2, j11, j12, j21, j22, d_s_h, d_w_h, err;
|
|
double eps = 1e-04;
|
|
|
|
f1 = f2 = 0;
|
|
e_r = m_parameters[EPSILONR_PRM];
|
|
|
|
Z0 = m_parameters[Z0_E_PRM] / 2.0;
|
|
/* Wheeler formula for single microstrip synthesis */
|
|
a = exp( Z0 * sqrt( e_r + 1.0 ) / 42.4 ) - 1.0;
|
|
w_h_se = 8.0 * sqrt( a * ( ( 7.0 + 4.0 / e_r ) / 11.0 ) + ( ( 1.0 + 1.0 / e_r ) / 0.81 ) ) / a;
|
|
|
|
Z0 = m_parameters[Z0_O_PRM] / 2.0;
|
|
/* Wheeler formula for single microstrip synthesis */
|
|
a = exp( Z0 * sqrt( e_r + 1.0 ) / 42.4 ) - 1.0;
|
|
w_h_so = 8.0 * sqrt( a * ( ( 7.0 + 4.0 / e_r ) / 11.0 ) + ( ( 1.0 + 1.0 / e_r ) / 0.81 ) ) / a;
|
|
|
|
ce = cosh( 0.5 * M_PI * w_h_se );
|
|
co = cosh( 0.5 * M_PI * w_h_so );
|
|
/* first guess at m_parameters[PHYS_S_PRM]/h */
|
|
s_h = ( 2.0 / M_PI ) * acosh( ( ce + co - 2.0 ) / ( co - ce ) );
|
|
/* first guess at w/h */
|
|
w_h = acosh( ( ce * co - 1.0 ) / ( co - ce ) ) / M_PI - s_h / 2.0;
|
|
|
|
m_parameters[PHYS_S_PRM] = s_h * m_parameters[H_PRM];
|
|
m_parameters[PHYS_WIDTH_PRM] = w_h * m_parameters[H_PRM];
|
|
|
|
syn_err_fun( &f1, &f2, s_h, w_h, e_r, w_h_se, w_h_so );
|
|
|
|
/* rather crude Newton-Rhapson; we need this because the estimate of */
|
|
/* w_h is often quite far from the true value (see Akhtarzad S. et al.) */
|
|
do
|
|
{
|
|
/* compute Jacobian */
|
|
syn_err_fun( &ft1, &ft2, s_h + eps, w_h, e_r, w_h_se, w_h_so );
|
|
j11 = ( ft1 - f1 ) / eps;
|
|
j21 = ( ft2 - f2 ) / eps;
|
|
syn_err_fun( &ft1, &ft2, s_h, w_h + eps, e_r, w_h_se, w_h_so );
|
|
j12 = ( ft1 - f1 ) / eps;
|
|
j22 = ( ft2 - f2 ) / eps;
|
|
|
|
/* compute next step */
|
|
d_s_h = ( -f1 * j22 + f2 * j12 ) / ( j11 * j22 - j21 * j12 );
|
|
d_w_h = ( -f2 * j11 + f1 * j21 ) / ( j11 * j22 - j21 * j12 );
|
|
|
|
//g_print("j11 = %e\tj12 = %e\tj21 = %e\tj22 = %e\n", j11, j12, j21, j22);
|
|
//g_print("det = %e\n", j11*j22 - j21*j22);
|
|
//g_print("d_s_h = %e\td_w_h = %e\n", d_s_h, d_w_h);
|
|
|
|
s_h += d_s_h;
|
|
w_h += d_w_h;
|
|
|
|
/* check the error */
|
|
syn_err_fun( &f1, &f2, s_h, w_h, e_r, w_h_se, w_h_so );
|
|
|
|
err = sqrt( f1 * f1 + f2 * f2 );
|
|
/* converged ? */
|
|
} while( err > 1e-04 );
|
|
|
|
|
|
m_parameters[PHYS_S_PRM] = s_h * m_parameters[H_PRM];
|
|
m_parameters[PHYS_WIDTH_PRM] = w_h * m_parameters[H_PRM];
|
|
}
|
|
|
|
|
|
/*
|
|
* Z0_dispersion() - calculate frequency dependency of characteristic
|
|
* impedances
|
|
*/
|
|
void C_MICROSTRIP::Z0_dispersion()
|
|
{
|
|
double Q_0;
|
|
double Q_11, Q_12, Q_13, Q_14, Q_15, Q_16, Q_17, Q_18, Q_19, Q_20, Q_21;
|
|
double Q_22, Q_23, Q_24, Q_25, Q_26, Q_27, Q_28, Q_29;
|
|
double r_e, q_e, p_e, d_e, C_e;
|
|
double e_r_eff_o_f, e_r_eff_o_0;
|
|
double e_r_eff_single_f, e_r_eff_single_0, Z0_single_f;
|
|
double f_n, g, u, e_r;
|
|
double R_1, R_2, R_7, R_10, R_11, R_12, R_15, R_16, tmpf;
|
|
|
|
e_r = m_parameters[EPSILONR_PRM];
|
|
|
|
u = m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM]; /* normalize line width */
|
|
g = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM]; /* normalize line spacing */
|
|
|
|
/* normalized frequency [GHz * mm] */
|
|
f_n = m_parameters[FREQUENCY_PRM] * m_parameters[H_PRM] / 1e06;
|
|
|
|
e_r_eff_single_f = aux_ms->er_eff;
|
|
e_r_eff_single_0 = aux_ms->er_eff_0;
|
|
Z0_single_f = aux_ms->m_parameters[Z0_PRM];
|
|
|
|
e_r_eff_o_f = er_eff_o;
|
|
e_r_eff_o_0 = er_eff_o_0;
|
|
|
|
Q_11 = 0.893 * ( 1.0 - 0.3 / ( 1.0 + 0.7 * ( e_r - 1.0 ) ) );
|
|
Q_12 = 2.121 * ( pow( f_n / 20.0, 4.91 ) / ( 1.0 + Q_11 * pow( f_n / 20.0, 4.91 ) ) )
|
|
* exp( -2.87 * g ) * pow( g, 0.902 );
|
|
Q_13 = 1.0 + 0.038 * pow( e_r / 8.0, 5.1 );
|
|
Q_14 = 1.0 + 1.203 * pow( e_r / 15.0, 4.0 ) / ( 1.0 + pow( e_r / 15.0, 4.0 ) );
|
|
Q_15 = 1.887 * exp( -1.5 * pow( g, 0.84 ) ) * pow( g, Q_14 )
|
|
/ ( 1.0
|
|
+ 0.41 * pow( f_n / 15.0, 3.0 ) * pow( u, 2.0 / Q_13 )
|
|
/ ( 0.125 + pow( u, 1.626 / Q_13 ) ) );
|
|
Q_16 = ( 1.0 + 9.0 / ( 1.0 + 0.403 * pow( e_r - 1.0, 2 ) ) ) * Q_15;
|
|
Q_17 = 0.394 * ( 1.0 - exp( -1.47 * pow( u / 7.0, 0.672 ) ) )
|
|
* ( 1.0 - exp( -4.25 * pow( f_n / 20.0, 1.87 ) ) );
|
|
Q_18 = 0.61 * ( 1.0 - exp( -2.13 * pow( u / 8.0, 1.593 ) ) ) / ( 1.0 + 6.544 * pow( g, 4.17 ) );
|
|
Q_19 = 0.21 * g * g * g * g
|
|
/ ( ( 1.0 + 0.18 * pow( g, 4.9 ) ) * ( 1.0 + 0.1 * u * u )
|
|
* ( 1.0 + pow( f_n / 24.0, 3.0 ) ) );
|
|
Q_20 = ( 0.09 + 1.0 / ( 1.0 + 0.1 * pow( e_r - 1, 2.7 ) ) ) * Q_19;
|
|
Q_21 = fabs( 1.0
|
|
- 42.54 * pow( g, 0.133 ) * exp( -0.812 * g ) * pow( u, 2.5 )
|
|
/ ( 1.0 + 0.033 * pow( u, 2.5 ) ) );
|
|
|
|
r_e = pow( f_n / 28.843, 12 );
|
|
q_e = 0.016 + pow( 0.0514 * e_r * Q_21, 4.524 );
|
|
p_e = 4.766 * exp( -3.228 * pow( u, 0.641 ) );
|
|
d_e = 5.086 * q_e * ( r_e / ( 0.3838 + 0.386 * q_e ) )
|
|
* ( exp( -22.2 * pow( u, 1.92 ) ) / ( 1.0 + 1.2992 * r_e ) )
|
|
* ( pow( e_r - 1.0, 6.0 ) / ( 1.0 + 10 * pow( e_r - 1.0, 6.0 ) ) );
|
|
C_e = 1.0
|
|
+ 1.275
|
|
* ( 1.0
|
|
- exp( -0.004625 * p_e * pow( e_r, 1.674 )
|
|
* pow( f_n / 18.365, 2.745 ) ) )
|
|
- Q_12 + Q_16 - Q_17 + Q_18 + Q_20;
|
|
|
|
|
|
R_1 = 0.03891 * pow( e_r, 1.4 );
|
|
R_2 = 0.267 * pow( u, 7.0 );
|
|
R_7 = 1.206 - 0.3144 * exp( -R_1 ) * ( 1.0 - exp( -R_2 ) );
|
|
R_10 = 0.00044 * pow( e_r, 2.136 ) + 0.0184;
|
|
tmpf = pow( f_n / 19.47, 6.0 );
|
|
R_11 = tmpf / ( 1.0 + 0.0962 * tmpf );
|
|
R_12 = 1.0 / ( 1.0 + 0.00245 * u * u );
|
|
R_15 = 0.707 * R_10 * pow( f_n / 12.3, 1.097 );
|
|
R_16 = 1.0 + 0.0503 * e_r * e_r * R_11 * ( 1.0 - exp( -pow( u / 15.0, 6.0 ) ) );
|
|
Q_0 = R_7 * ( 1.0 - 1.1241 * ( R_12 / R_16 ) * exp( -0.026 * pow( f_n, 1.15656 ) - R_15 ) );
|
|
|
|
/* even-mode frequency-dependent characteristic impedances */
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|
m_parameters[Z0_E_PRM] = Z0_e_0 * pow( 0.9408 * pow( e_r_eff_single_f, C_e ) - 0.9603, Q_0 )
|
|
/ pow( ( 0.9408 - d_e ) * pow( e_r_eff_single_0, C_e ) - 0.9603, Q_0 );
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|
|
|
Q_29 = 15.16 / ( 1.0 + 0.196 * pow( e_r - 1.0, 2.0 ) );
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|
tmpf = pow( e_r - 1.0, 3.0 );
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Q_28 = 0.149 * tmpf / ( 94.5 + 0.038 * tmpf );
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|
tmpf = pow( e_r - 1.0, 1.5 );
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Q_27 = 0.4 * pow( g, 0.84 ) * ( 1.0 + 2.5 * tmpf / ( 5.0 + tmpf ) );
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|
tmpf = pow( ( e_r - 1.0 ) / 13.0, 12.0 );
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|
Q_26 = 30.0 - 22.2 * ( tmpf / ( 1.0 + 3.0 * tmpf ) ) - Q_29;
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|
tmpf = ( e_r - 1.0 ) * ( e_r - 1.0 );
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|
Q_25 = ( 0.3 * f_n * f_n / ( 10.0 + f_n * f_n ) ) * ( 1.0 + 2.333 * tmpf / ( 5.0 + tmpf ) );
|
|
Q_24 = 2.506 * Q_28 * pow( u, 0.894 ) * pow( ( 1.0 + 1.3 * u ) * f_n / 99.25, 4.29 )
|
|
/ ( 3.575 + pow( u, 0.894 ) );
|
|
Q_23 = 1.0
|
|
+ 0.005 * f_n * Q_27
|
|
/ ( ( 1.0 + 0.812 * pow( f_n / 15.0, 1.9 ) ) * ( 1.0 + 0.025 * u * u ) );
|
|
Q_22 = 0.925 * pow( f_n / Q_26, 1.536 ) / ( 1.0 + 0.3 * pow( f_n / 30.0, 1.536 ) );
|
|
|
|
/* odd-mode frequency-dependent characteristic impedances */
|
|
m_parameters[Z0_O_PRM] =
|
|
Z0_single_f
|
|
+ ( Z0_o_0 * pow( e_r_eff_o_f / e_r_eff_o_0, Q_22 ) - Z0_single_f * Q_23 )
|
|
/ ( 1.0 + Q_24 + pow( 0.46 * g, 2.2 ) * Q_25 );
|
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}
|
|
|
|
|
|
void C_MICROSTRIP::calcAnalyze()
|
|
{
|
|
/* compute thickness corrections */
|
|
delta_u_thickness();
|
|
/* get effective dielectric constants */
|
|
er_eff_static();
|
|
/* impedances for even- and odd-mode */
|
|
Z0_even_odd();
|
|
/* calculate freq dependence of er_eff_e, er_eff_o */
|
|
er_eff_freq();
|
|
/* calculate frequency dependence of Z0e, Z0o */
|
|
Z0_dispersion();
|
|
/* calculate losses */
|
|
attenuation();
|
|
/* calculate electrical lengths */
|
|
line_angle();
|
|
/* calculate diff impedance */
|
|
diff_impedance();
|
|
}
|
|
|
|
|
|
void C_MICROSTRIP::showAnalyze()
|
|
{
|
|
setProperty( Z0_E_PRM, m_parameters[Z0_E_PRM] );
|
|
setProperty( Z0_O_PRM, m_parameters[Z0_O_PRM] );
|
|
setProperty( ANG_L_PRM, sqrt( ang_l_e * ang_l_o ) );
|
|
|
|
//Check for errors
|
|
if( !std::isfinite( m_parameters[Z0_O_PRM] ) || m_parameters[Z0_O_PRM] <= 0.0 )
|
|
setErrorLevel( Z0_O_PRM, TRANSLINE_ERROR );
|
|
|
|
if( !std::isfinite( m_parameters[Z0_E_PRM] ) || m_parameters[Z0_E_PRM] <= 0.0 )
|
|
setErrorLevel( Z0_E_PRM, TRANSLINE_ERROR );
|
|
|
|
if( !std::isfinite( m_parameters[ANG_L_PRM] ) || m_parameters[ANG_L_PRM] <= 0.0 )
|
|
setErrorLevel( ANG_L_PRM, TRANSLINE_ERROR );
|
|
|
|
// Check for warnings
|
|
if( !std::isfinite( m_parameters[PHYS_WIDTH_PRM] ) || m_parameters[PHYS_WIDTH_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_WIDTH_PRM, TRANSLINE_WARNING );
|
|
|
|
if( !std::isfinite( m_parameters[PHYS_S_PRM] ) || m_parameters[PHYS_S_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_S_PRM, TRANSLINE_WARNING );
|
|
|
|
if( !std::isfinite( m_parameters[PHYS_LEN_PRM] ) || m_parameters[PHYS_LEN_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_LEN_PRM, TRANSLINE_WARNING );
|
|
}
|
|
|
|
void C_MICROSTRIP::showSynthesize()
|
|
{
|
|
setProperty( PHYS_WIDTH_PRM, m_parameters[PHYS_WIDTH_PRM] );
|
|
setProperty( PHYS_S_PRM, m_parameters[PHYS_S_PRM] );
|
|
setProperty( PHYS_LEN_PRM, m_parameters[PHYS_LEN_PRM] );
|
|
|
|
//Check for errors
|
|
if( !std::isfinite( m_parameters[PHYS_WIDTH_PRM] ) || m_parameters[PHYS_WIDTH_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_WIDTH_PRM, TRANSLINE_ERROR );
|
|
|
|
if( !std::isfinite( m_parameters[PHYS_S_PRM] ) || m_parameters[PHYS_S_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_S_PRM, TRANSLINE_ERROR );
|
|
|
|
if( !std::isfinite( m_parameters[PHYS_LEN_PRM] ) || m_parameters[PHYS_LEN_PRM] <= 0.0 )
|
|
setErrorLevel( PHYS_LEN_PRM, TRANSLINE_ERROR );
|
|
|
|
// Check for warnings
|
|
if( !std::isfinite( m_parameters[Z0_O_PRM] ) || m_parameters[Z0_O_PRM] <= 0.0 )
|
|
setErrorLevel( Z0_O_PRM, TRANSLINE_WARNING );
|
|
|
|
if( !std::isfinite( m_parameters[Z0_E_PRM] ) || m_parameters[Z0_E_PRM] <= 0.0 )
|
|
setErrorLevel( Z0_E_PRM, TRANSLINE_WARNING );
|
|
|
|
if( !std::isfinite( m_parameters[ANG_L_PRM] ) || m_parameters[ANG_L_PRM] <= 0.0 )
|
|
setErrorLevel( ANG_L_PRM, TRANSLINE_WARNING );
|
|
}
|
|
|
|
void C_MICROSTRIP::show_results()
|
|
{
|
|
|
|
setResult( 0, er_eff_e, "" );
|
|
setResult( 1, er_eff_o, "" );
|
|
setResult( 2, atten_cond_e, wxT( "dB" ) );
|
|
setResult( 3, atten_cond_o, wxT( "dB" ) );
|
|
setResult( 4, atten_dielectric_e, wxT( "dB" ) );
|
|
setResult( 5, atten_dielectric_o, wxT( "dB" ) );
|
|
|
|
setResult( 6, m_parameters[SKIN_DEPTH_PRM] / UNIT_MICRON, wxT( "µm" ) );
|
|
setResult( 7, Zdiff, wxT( "Ω" ) );
|
|
}
|
|
|
|
|
|
void C_MICROSTRIP::syn_fun(
|
|
double* f1, double* f2, double s_h, double w_h, double Z0_e, double Z0_o )
|
|
{
|
|
m_parameters[PHYS_S_PRM] = s_h * m_parameters[H_PRM];
|
|
m_parameters[PHYS_WIDTH_PRM] = w_h * m_parameters[H_PRM];
|
|
|
|
/* compute coupled microstrip parameters */
|
|
calcAnalyze();
|
|
|
|
*f1 = m_parameters[Z0_E_PRM] - Z0_e;
|
|
*f2 = m_parameters[Z0_O_PRM] - Z0_o;
|
|
}
|
|
|
|
|
|
/*
|
|
* synthesis function
|
|
*/
|
|
void C_MICROSTRIP::calcSynthesize()
|
|
{
|
|
double Z0_e, Z0_o, ang_l_dest;
|
|
double f1, f2, ft1, ft2, j11, j12, j21, j22, d_s_h, d_w_h, err;
|
|
double eps = 1e-04;
|
|
double w_h, s_h, le, lo;
|
|
|
|
|
|
/* required value of Z0_e and Z0_o */
|
|
Z0_e = m_parameters[Z0_E_PRM];
|
|
Z0_o = m_parameters[Z0_O_PRM];
|
|
|
|
|
|
ang_l_e = m_parameters[ANG_L_PRM];
|
|
ang_l_o = m_parameters[ANG_L_PRM];
|
|
ang_l_dest = m_parameters[ANG_L_PRM];
|
|
|
|
|
|
/* calculate width and use for initial value in Newton's method */
|
|
synth_width();
|
|
w_h = m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM];
|
|
s_h = m_parameters[PHYS_S_PRM] / m_parameters[H_PRM];
|
|
f1 = f2 = 0;
|
|
|
|
/* rather crude Newton-Rhapson */
|
|
do
|
|
{
|
|
/* compute Jacobian */
|
|
syn_fun( &ft1, &ft2, s_h + eps, w_h, Z0_e, Z0_o );
|
|
j11 = ( ft1 - f1 ) / eps;
|
|
j21 = ( ft2 - f2 ) / eps;
|
|
syn_fun( &ft1, &ft2, s_h, w_h + eps, Z0_e, Z0_o );
|
|
j12 = ( ft1 - f1 ) / eps;
|
|
j22 = ( ft2 - f2 ) / eps;
|
|
|
|
/* compute next step; increments of s_h and w_h */
|
|
d_s_h = ( -f1 * j22 + f2 * j12 ) / ( j11 * j22 - j21 * j12 );
|
|
d_w_h = ( -f2 * j11 + f1 * j21 ) / ( j11 * j22 - j21 * j12 );
|
|
|
|
s_h += d_s_h;
|
|
w_h += d_w_h;
|
|
|
|
/* compute the error with the new values of s_h and w_h */
|
|
syn_fun( &f1, &f2, s_h, w_h, Z0_e, Z0_o );
|
|
err = sqrt( f1 * f1 + f2 * f2 );
|
|
|
|
/* converged ? */
|
|
} while( err > 1e-04 );
|
|
|
|
/* denormalize computed width and spacing */
|
|
m_parameters[PHYS_S_PRM] = s_h * m_parameters[H_PRM];
|
|
m_parameters[PHYS_WIDTH_PRM] = w_h * m_parameters[H_PRM];
|
|
|
|
|
|
/* calculate physical length */
|
|
le = C0 / m_parameters[FREQUENCY_PRM] / sqrt( er_eff_e ) * ang_l_dest / 2.0 / M_PI;
|
|
lo = C0 / m_parameters[FREQUENCY_PRM] / sqrt( er_eff_o ) * ang_l_dest / 2.0 / M_PI;
|
|
m_parameters[PHYS_LEN_PRM] = sqrt( le * lo );
|
|
|
|
calcAnalyze();
|
|
|
|
m_parameters[ANG_L_PRM] = ang_l_dest;
|
|
m_parameters[Z0_E_PRM] = Z0_e;
|
|
m_parameters[Z0_O_PRM] = Z0_o;
|
|
}
|