KiCad PCB EDA Suite
COPLANAR Class Reference

#include <coplanar.h>

Inheritance diagram for COPLANAR:
TRANSLINE GROUNDEDCOPLANAR

Public Member Functions

 COPLANAR ()
 
void calcSynthesize () override
 Computation for synthesis. More...
 
void setProperty (enum PRMS_ID aPrmId, double aValue)
 
double getProperty (enum PRMS_ID aPrmId)
 
void getProperties ()
 @function getProperties More...
 
void checkProperties ()
 @function checkProperties More...
 
void setResult (int, double, const char *)
 
void setResult (int, const char *)
 
bool isSelected (enum PRMS_ID aPrmId)
 
void Init ()
 
virtual void synthesize ()
 
virtual void calc ()
 
void analyze ()
 

Public Attributes

const char * m_Name
 
KIGFX::COLOR4D errCol = KIGFX::COLOR4D( 1, 0.63, 0.63, 1 )
 
KIGFX::COLOR4D warnCol = KIGFX::COLOR4D( 1, 1, 0.57, 1 )
 
KIGFX::COLOR4D okCol = KIGFX::COLOR4D( 1, 1, 1, 1 )
 

Protected Member Functions

bool minimizeZ0Error1D (double *)
 @function minimizeZ0Error1D More...
 
double skin_depth ()
 @function skin_depth calculate skin depth More...
 
void ellipke (double, double &, double &)
 
double ellipk (double)
 
void setErrorLevel (PRMS_ID, char)
 @function setErrorLevel More...
 

Protected Attributes

bool backMetal
 
double m_parameters [EXTRA_PRMS_COUNT]
 
double len
 
double er_eff
 
double ang_l
 

Private Member Functions

void calcAnalyze () override
 Computation for analysis. More...
 
void showSynthesize () override
 Shows analysis results and checks for errors / warnings. More...
 
void showAnalyze () override
 Shows synthesis results and checks for errors / warnings. More...
 
void show_results () override
 Shows results. More...
 

Detailed Description

Definition at line 30 of file coplanar.h.

Constructor & Destructor Documentation

◆ COPLANAR()

COPLANAR::COPLANAR ( )

Definition at line 34 of file coplanar.cpp.

34 : TRANSLINE()
35{
36 m_Name = "CoPlanar";
37 backMetal = false;
38 Init();
39}
bool backMetal
Definition: coplanar.h:39
void Init()
Definition: transline.cpp:90
const char * m_Name
Definition: transline.h:84

References backMetal, TRANSLINE::Init(), and TRANSLINE::m_Name.

Member Function Documentation

◆ analyze()

void TRANSLINE::analyze ( )
inherited

Definition at line 211 of file transline.cpp.

212{
215 calcAnalyze();
216 showAnalyze();
217 show_results();
218}
void getProperties()
@function getProperties
Definition: transline.cpp:150
void checkProperties()
@function checkProperties
Definition: transline.cpp:169
virtual void showAnalyze()
Shows synthesis results and checks for errors / warnings.
Definition: transline.h:112
virtual void show_results()
Shows results.
Definition: transline.h:122
virtual void calcAnalyze()
Computation for analysis.
Definition: transline.h:102

References TRANSLINE::calcAnalyze(), TRANSLINE::checkProperties(), TRANSLINE::getProperties(), TRANSLINE::show_results(), and TRANSLINE::showAnalyze().

Referenced by PANEL_TRANSLINE::OnTranslineAnalyse().

◆ calc()

virtual void TRANSLINE::calc ( )
inlinevirtualinherited

Definition at line 97 of file transline.h.

97{}

◆ calcAnalyze()

void COPLANAR::calcAnalyze ( )
overrideprivatevirtual

Computation for analysis.

Reimplemented from TRANSLINE.

Definition at line 50 of file coplanar.cpp.

51{
53
54 // other local variables (quasi-static constants)
55 double k1, kk1, kpk1, k2, k3, q1, q2, q3 = 0, qz, er0 = 0;
56 double zl_factor;
57
58 // compute the necessary quasi-static approx. (K1, K3, er(0) and Z(0))
61 kk1 = ellipk( k1 );
62 kpk1 = ellipk( sqrt( 1 - k1 * k1 ) );
63 q1 = kk1 / kpk1;
64
65
66 // backside is metal
67 if( backMetal )
68 {
69 k3 = tanh( ( M_PI / 4 ) * ( m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM] ) )
70 / tanh( ( M_PI / 4 )
74 q3 = ellipk( k3 ) / ellipk( sqrt( 1 - k3 * k3 ) );
75 qz = 1 / ( q1 + q3 );
76 er0 = 1 + q3 * qz * ( m_parameters[EPSILONR_PRM] - 1 );
77 zl_factor = ZF0 / 2 * qz;
78 }
79 // backside is air
80 else
81 {
82 k2 = sinh( ( M_PI / 4 ) * ( m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM] ) )
83 / sinh( ( M_PI / 4 )
87 q2 = ellipk( k2 ) / ellipk( sqrt( 1 - k2 * k2 ) );
88 er0 = 1 + ( m_parameters[EPSILONR_PRM] - 1 ) / 2 * q2 / q1;
89 zl_factor = ZF0 / 4 / q1;
90 }
91
92
93 // adds effect of strip thickness
94 if( m_parameters[T_PRM] > 0 )
95 {
96 double d, se, We, ke, qe;
97 d = ( m_parameters[T_PRM] * 1.25 / M_PI )
98 * ( 1 + log( 4 * M_PI * m_parameters[PHYS_WIDTH_PRM] / m_parameters[T_PRM] ) );
99 se = m_parameters[PHYS_S_PRM] - d;
101
102 // modifies k1 accordingly (k1 = ke)
103 ke = We / ( We + se + se ); // ke = k1 + (1 - k1 * k1) * d / 2 / s;
104 qe = ellipk( ke ) / ellipk( sqrt( 1 - ke * ke ) );
105
106 // backside is metal
107 if( backMetal )
108 {
109 qz = 1 / ( qe + q3 );
110 er0 = 1 + q3 * qz * ( m_parameters[EPSILONR_PRM] - 1 );
111 zl_factor = ZF0 / 2 * qz;
112 }
113 // backside is air
114 else
115 {
116 zl_factor = ZF0 / 4 / qe;
117 }
118
119 // modifies er0 as well
120 er0 = er0
121 - ( 0.7 * ( er0 - 1 ) * m_parameters[T_PRM] / m_parameters[PHYS_S_PRM] )
122 / ( q1 + ( 0.7 * m_parameters[T_PRM] / m_parameters[PHYS_S_PRM] ) );
123 }
124
125 // pre-compute square roots
126 double sr_er = sqrt( m_parameters[EPSILONR_PRM] );
127 double sr_er0 = sqrt( er0 );
128
129 // cut-off frequency of the TE0 mode
130 double fte = ( C0 / 4 ) / ( m_parameters[H_PRM] * sqrt( m_parameters[EPSILONR_PRM] - 1 ) );
131
132 // dispersion factor G
133 double p = log( m_parameters[PHYS_WIDTH_PRM] / m_parameters[H_PRM] );
134 double u = 0.54 - ( 0.64 - 0.015 * p ) * p;
135 double v = 0.43 - ( 0.86 - 0.54 * p ) * p;
136 double G = exp( u * log( m_parameters[PHYS_WIDTH_PRM] / m_parameters[PHYS_S_PRM] ) + v );
137
138 // loss constant factors (computed only once for efficiency's sake)
139 double ac = 0;
140
141 if( m_parameters[T_PRM] > 0 )
142 {
143 // equations by GHIONE
144 double n = ( 1 - k1 ) * 8 * M_PI / ( m_parameters[T_PRM] * ( 1 + k1 ) );
145 double a = m_parameters[PHYS_WIDTH_PRM] / 2;
146 double b = a + m_parameters[PHYS_S_PRM];
147 ac = ( M_PI + log( n * a ) ) / a + ( M_PI + log( n * b ) ) / b;
148 }
149
150 double ac_factor = ac / ( 4 * ZF0 * kk1 * kpk1 * ( 1 - k1 * k1 ) );
151 double ad_factor = ( m_parameters[EPSILONR_PRM] / ( m_parameters[EPSILONR_PRM] - 1 ) )
152 * m_parameters[TAND_PRM] * M_PI / C0;
153
154
155 // ....................................................
156 double sr_er_f = sr_er0;
157
158 // add the dispersive effects to er0
159 sr_er_f += ( sr_er - sr_er0 ) / ( 1 + G * pow( m_parameters[FREQUENCY_PRM] / fte, -1.8 ) );
160
161 // for now, the loss are limited to strip losses (no radiation
162 // losses yet) losses in neper/length
164 20.0 / log( 10.0 ) * m_parameters[PHYS_LEN_PRM] * ac_factor * sr_er0
165 * sqrt( M_PI * MU0 * m_parameters[FREQUENCY_PRM] / m_parameters[SIGMA_PRM] );
166 m_parameters[LOSS_DIELECTRIC_PRM] = 20.0 / log( 10.0 ) * m_parameters[PHYS_LEN_PRM] * ad_factor
167 * m_parameters[FREQUENCY_PRM] * ( sr_er_f * sr_er_f - 1 )
168 / sr_er_f;
169
170 m_parameters[ANG_L_PRM] = 2.0 * M_PI * m_parameters[PHYS_LEN_PRM] * sr_er_f
171 * m_parameters[FREQUENCY_PRM] / C0; /* in radians */
172
173 m_parameters[EPSILON_EFF_PRM] = sr_er_f * sr_er_f;
174 m_parameters[Z0_PRM] = zl_factor / sr_er_f;
175}
double ellipk(double)
Definition: transline.cpp:324
double m_parameters[EXTRA_PRMS_COUNT]
Definition: transline.h:131
double skin_depth()
@function skin_depth calculate skin depth
Definition: transline.cpp:237
#define G(x, y, z)
Definition: md5_hash.cpp:16
@ LOSS_DIELECTRIC_PRM
Definition: transline.h:71
@ EPSILON_EFF_PRM
Definition: transline.h:74
@ LOSS_CONDUCTOR_PRM
Definition: transline.h:72
@ SIGMA_PRM
Definition: transline.h:69
@ SKIN_DEPTH_PRM
Definition: transline.h:70
@ FREQUENCY_PRM
Definition: transline.h:51
@ T_PRM
Definition: transline.h:46
@ Z0_PRM
Definition: transline.h:52
@ TAND_PRM
Definition: transline.h:40
@ PHYS_LEN_PRM
Definition: transline.h:60
@ ANG_L_PRM
Definition: transline.h:55
@ EPSILONR_PRM
Definition: transline.h:39
@ PHYS_S_PRM
Definition: transline.h:58
@ H_PRM
Definition: transline.h:42
@ PHYS_WIDTH_PRM
Definition: transline.h:56
#define ZF0
Definition: units.h:62
#define MU0
Definition: units.h:60
#define C0
Definition: units.h:61

References ANG_L_PRM, backMetal, C0, TRANSLINE::ellipk(), EPSILON_EFF_PRM, EPSILONR_PRM, FREQUENCY_PRM, G, H_PRM, LOSS_CONDUCTOR_PRM, LOSS_DIELECTRIC_PRM, TRANSLINE::m_parameters, MU0, PHYS_LEN_PRM, PHYS_S_PRM, PHYS_WIDTH_PRM, SIGMA_PRM, TRANSLINE::skin_depth(), SKIN_DEPTH_PRM, T_PRM, TAND_PRM, Z0_PRM, and ZF0.

◆ calcSynthesize()

void COPLANAR::calcSynthesize ( )
overridevirtual

Computation for synthesis.

Reimplemented from TRANSLINE.

Definition at line 198 of file coplanar.cpp.

199{
202 else
204}
bool isSelected(enum PRMS_ID aPrmId)
Definition: transline.cpp:119
bool minimizeZ0Error1D(double *)
@function minimizeZ0Error1D
Definition: transline.cpp:349

References TRANSLINE::isSelected(), TRANSLINE::m_parameters, TRANSLINE::minimizeZ0Error1D(), PHYS_S_PRM, and PHYS_WIDTH_PRM.

◆ checkProperties()

void TRANSLINE::checkProperties ( )
inherited

@function checkProperties

Checks the input parameters (ie: negative length). Does not check for incompatibility between values as this depends on the line shape.

Definition at line 169 of file transline.cpp.

170{
171 // Do not check for values that are results of analyzing / synthesizing
172 // Do not check for transline specific incompatibilities ( like " conductor height should be lesser than dielectric height")
173 if( !std::isfinite( m_parameters[EPSILONR_PRM] ) || m_parameters[EPSILONR_PRM] <= 0 )
175
176 if( !std::isfinite( m_parameters[TAND_PRM] ) || m_parameters[TAND_PRM] < 0 )
178
179 if( !std::isfinite( m_parameters[RHO_PRM] ) || m_parameters[RHO_PRM] < 0 )
181
182 if( !std::isfinite( m_parameters[H_PRM] ) || m_parameters[H_PRM] < 0 )
184
185 if( !std::isfinite( m_parameters[TWISTEDPAIR_TWIST_PRM] )
188
189 if( !std::isfinite( m_parameters[STRIPLINE_A_PRM] ) || m_parameters[STRIPLINE_A_PRM] <= 0 )
191
192 if( !std::isfinite( m_parameters[H_T_PRM] ) || m_parameters[H_T_PRM] <= 0 )
194
195 // How can we check ROUGH_PRM ?
196
197 if( !std::isfinite( m_parameters[MUR_PRM] ) || m_parameters[MUR_PRM] < 0 )
199
200 if( !std::isfinite( m_parameters[TWISTEDPAIR_EPSILONR_ENV_PRM] )
203
204 if( !std::isfinite( m_parameters[MURC_PRM] ) || m_parameters[MURC_PRM] < 0 )
206
207 if( !std::isfinite( m_parameters[FREQUENCY_PRM] ) || m_parameters[FREQUENCY_PRM] <= 0 )
209}
void setErrorLevel(PRMS_ID, char)
@function setErrorLevel
Definition: transline.cpp:435
@ TWISTEDPAIR_EPSILONR_ENV_PRM
Definition: transline.h:49
@ RHO_PRM
Definition: transline.h:41
@ MURC_PRM
Definition: transline.h:50
@ MUR_PRM
Definition: transline.h:48
@ STRIPLINE_A_PRM
Definition: transline.h:45
@ H_T_PRM
Definition: transline.h:44
@ TWISTEDPAIR_TWIST_PRM
Definition: transline.h:43
#define TRANSLINE_WARNING
Definition: transline.h:30

References EPSILONR_PRM, FREQUENCY_PRM, H_PRM, H_T_PRM, TRANSLINE::m_parameters, MUR_PRM, MURC_PRM, RHO_PRM, TRANSLINE::setErrorLevel(), STRIPLINE_A_PRM, TAND_PRM, TRANSLINE_WARNING, TWISTEDPAIR_EPSILONR_ENV_PRM, and TWISTEDPAIR_TWIST_PRM.

Referenced by TRANSLINE::analyze(), and TRANSLINE::synthesize().

◆ ellipk()

double TRANSLINE::ellipk ( double  k)
protectedinherited

Definition at line 324 of file transline.cpp.

325{
326 double r, lost;
327
328 ellipke( k, r, lost );
329 return r;
330}
void ellipke(double, double &, double &)
Definition: transline.cpp:259
E_SERIE r
Definition: eserie.cpp:41

References TRANSLINE::ellipke(), and r.

Referenced by calcAnalyze().

◆ ellipke()

void TRANSLINE::ellipke ( double  arg,
double &  k,
double &  e 
)
protectedinherited

Definition at line 259 of file transline.cpp.

260{
261 int iMax = 16;
262
263 if( arg == 1.0 )
264 {
265 k = INFINITY; // infinite
266 e = 0;
267 }
268 else if( std::isinf( arg ) && arg < 0 )
269 {
270 k = 0;
271 e = INFINITY; // infinite
272 }
273 else
274 {
275 double a, b, c, fr, s, fk = 1, fe = 1, t, da = arg;
276 int i;
277
278 if( arg < 0 )
279 {
280 fk = 1 / sqrt( 1 - arg );
281 fe = sqrt( 1 - arg );
282 da = -arg / ( 1 - arg );
283 }
284
285 a = 1;
286 b = sqrt( 1 - da );
287 c = sqrt( da );
288 fr = 0.5;
289 s = fr * c * c;
290
291 for( i = 0; i < iMax; i++ )
292 {
293 t = ( a + b ) / 2;
294 c = ( a - b ) / 2;
295 b = sqrt( a * b );
296 a = t;
297 fr *= 2;
298 s += fr * c * c;
299
300 if( c / a < NR_EPSI )
301 break;
302 }
303
304 if( i >= iMax )
305 {
306 k = 0;
307 e = 0;
308 }
309 else
310 {
311 k = M_PI_2 / a;
312 e = M_PI_2 * ( 1 - s ) / a;
313 if( arg < 0 )
314 {
315 k *= fk;
316 e *= fe;
317 }
318 }
319 }
320}
#define NR_EPSI
Definition: transline.cpp:253
#define INFINITY
Definition: transline.cpp:35
#define M_PI_2
Definition: transline.cpp:40

References INFINITY, M_PI_2, and NR_EPSI.

Referenced by TRANSLINE::ellipk().

◆ getProperties()

void TRANSLINE::getProperties ( )
inherited

@function getProperties

Get all properties from the UI. Computes some extra ones.

Definition at line 150 of file transline.cpp.

151{
152 for( int i = 0; i < DUMMY_PRM; ++i )
153 {
154 m_parameters[i] = getProperty( (PRMS_ID) i );
156 }
157
161}
double getProperty(enum PRMS_ID aPrmId)
Definition: transline.cpp:140
PRMS_ID
Definition: transline.h:37
@ DUMMY_PRM
Definition: transline.h:61
#define TRANSLINE_OK
Definition: transline.h:29

References DUMMY_PRM, EPSILON_EFF_PRM, TRANSLINE::getProperty(), TRANSLINE::m_parameters, RHO_PRM, TRANSLINE::setErrorLevel(), SIGMA_PRM, TRANSLINE::skin_depth(), SKIN_DEPTH_PRM, and TRANSLINE_OK.

Referenced by TRANSLINE::analyze(), and TRANSLINE::synthesize().

◆ getProperty()

double TRANSLINE::getProperty ( enum PRMS_ID  aPrmId)
inherited

◆ Init()

void TRANSLINE::Init ( )
inherited

Definition at line 90 of file transline.cpp.

91{
92 wxColour wxcol = wxSystemSettings::GetColour( wxSYS_COLOUR_WINDOW );
93 okCol = KIGFX::COLOR4D( wxcol );
94 okCol.r = wxcol.Red() / 255.0;
95 okCol.g = wxcol.Green() / 255.0;
96 okCol.b = wxcol.Blue() / 255.0;
97 int i;
98 // Initialize these variables mainly to avoid warnings from a static analyzer
99 for( i = 0; i < EXTRA_PRMS_COUNT; ++i )
100 {
101 m_parameters[i] = 0;
102 }
103}
A color representation with 4 components: red, green, blue, alpha.
Definition: color4d.h:104
double r
Red component.
Definition: color4d.h:384
double g
Green component.
Definition: color4d.h:385
double b
Blue component.
Definition: color4d.h:386
KIGFX::COLOR4D okCol
Definition: transline.h:128
@ EXTRA_PRMS_COUNT
Definition: transline.h:75

References KIGFX::COLOR4D::b, EXTRA_PRMS_COUNT, KIGFX::COLOR4D::g, TRANSLINE::m_parameters, TRANSLINE::okCol, and KIGFX::COLOR4D::r.

Referenced by C_MICROSTRIP::C_MICROSTRIP(), COAX::COAX(), COPLANAR(), MICROSTRIP::MICROSTRIP(), RECTWAVEGUIDE::RECTWAVEGUIDE(), STRIPLINE::STRIPLINE(), TRANSLINE::TRANSLINE(), and TWISTEDPAIR::TWISTEDPAIR().

◆ isSelected()

bool TRANSLINE::isSelected ( enum PRMS_ID  aPrmId)
inherited

◆ minimizeZ0Error1D()

bool TRANSLINE::minimizeZ0Error1D ( double *  aVar)
protectedinherited

@function minimizeZ0Error1D

Tries to find a parameter that minimizes the error ( on Z0 ). This function only works with a single parameter. Calls calcAnalyze several times until the error is acceptable. While the error is unnacceptable, changes slightly the parameter.

This function does not change Z0 / Angl_L.

Parameters
avarParameter to synthesize
Returns
'true' if error < MAX_ERROR, else 'false'

Definition at line 349 of file transline.cpp.

350{
351 double Z0_dest, Z0_current, Z0_result, angl_l_dest, increment, slope, error;
352 int iteration;
353
354 if( !std::isfinite( m_parameters[Z0_PRM] ) )
355 {
356 *aVar = NAN;
357 return false;
358 }
359
360 if( ( !std::isfinite( *aVar ) ) || ( *aVar == 0 ) )
361 *aVar = 0.001;
362
363 /* required value of Z0 */
364 Z0_dest = m_parameters[Z0_PRM];
365
366 /* required value of angl_l */
367 angl_l_dest = m_parameters[ANG_L_PRM];
368
369 /* Newton's method */
370 iteration = 0;
371
372 /* compute parameters */
373 calcAnalyze();
374 Z0_current = m_parameters[Z0_PRM];
375
376 error = fabs( Z0_dest - Z0_current );
377
378 while( error > MAX_ERROR )
379 {
380 iteration++;
381 increment = *aVar / 100.0;
382 *aVar += increment;
383 /* compute parameters */
384 calcAnalyze();
385 Z0_result = m_parameters[Z0_PRM];
386 /* f(w(n)) = Z0 - Z0(w(n)) */
387 /* f'(w(n)) = -f'(Z0(w(n))) */
388 /* f'(Z0(w(n))) = (Z0(w(n)) - Z0(w(n+delw))/delw */
389 /* w(n+1) = w(n) - f(w(n))/f'(w(n)) */
390 slope = ( Z0_result - Z0_current ) / increment;
391 slope = ( Z0_dest - Z0_current ) / slope - increment;
392 *aVar += slope;
393
394 if( *aVar <= 0.0 )
395 *aVar = increment;
396
397 /* find new error */
398 /* compute parameters */
399 calcAnalyze();
400 Z0_current = m_parameters[Z0_PRM];
401 error = fabs( Z0_dest - Z0_current );
402
403 if( iteration > 100 )
404 break;
405 }
406
407 /* Compute one last time, but with correct length */
408 m_parameters[Z0_PRM] = Z0_dest;
409 m_parameters[ANG_L_PRM] = angl_l_dest;
412 / 2.0 / M_PI; /* in m */
413 calcAnalyze();
414
415 /* Restore parameters */
416 m_parameters[Z0_PRM] = Z0_dest;
417 m_parameters[ANG_L_PRM] = angl_l_dest;
420 / 2.0 / M_PI; /* in m */
421 return error <= MAX_ERROR;
422}
#define MAX_ERROR
Definition: transline.cpp:332

References ANG_L_PRM, C0, TRANSLINE::calcAnalyze(), EPSILON_EFF_PRM, FREQUENCY_PRM, TRANSLINE::m_parameters, MAX_ERROR, PHYS_LEN_PRM, and Z0_PRM.

Referenced by calcSynthesize(), MICROSTRIP::calcSynthesize(), STRIPLINE::calcSynthesize(), and TWISTEDPAIR::calcSynthesize().

◆ setErrorLevel()

void TRANSLINE::setErrorLevel ( PRMS_ID  aP,
char  aErrorLevel 
)
protectedinherited

@function setErrorLevel

set an error / warning level for a given parameter.

See also
TRANSLINE_OK
TRANSLINE_WARNING
TRANSLINE_ERROR
Parameters
aPparameter
aErrorLevelError level

Definition at line 435 of file transline.cpp.

436{
437 switch( aErrorLevel )
438 {
441 default: SetPropertyBgColorInDialog( aP, &okCol ); break;
442 }
443}
KIGFX::COLOR4D warnCol
Definition: transline.h:127
KIGFX::COLOR4D errCol
Definition: transline.h:126
void SetPropertyBgColorInDialog(enum PRMS_ID aPrmId, const KIGFX::COLOR4D *aCol)
Function SetPropertyBgColorInDialog Set the background color of a parameter.
#define TRANSLINE_ERROR
Definition: transline.h:31

References TRANSLINE::errCol, TRANSLINE::okCol, SetPropertyBgColorInDialog(), TRANSLINE_ERROR, TRANSLINE_WARNING, and TRANSLINE::warnCol.

Referenced by TRANSLINE::checkProperties(), TRANSLINE::getProperties(), C_MICROSTRIP::showAnalyze(), COAX::showAnalyze(), showAnalyze(), MICROSTRIP::showAnalyze(), RECTWAVEGUIDE::showAnalyze(), STRIPLINE::showAnalyze(), TWISTEDPAIR::showAnalyze(), C_MICROSTRIP::showSynthesize(), COAX::showSynthesize(), showSynthesize(), MICROSTRIP::showSynthesize(), RECTWAVEGUIDE::showSynthesize(), STRIPLINE::showSynthesize(), and TWISTEDPAIR::showSynthesize().

◆ setProperty()

◆ setResult() [1/2]

void TRANSLINE::setResult ( int  line,
const char *  text 
)
inherited

Definition at line 127 of file transline.cpp.

128{
129 SetResultInDialog( line, text );
130}
void SetResultInDialog(int line, const char *text)

References SetResultInDialog(), and text.

◆ setResult() [2/2]

void TRANSLINE::setResult ( int  line,
double  value,
const char *  text 
)
inherited

◆ show_results()

void COPLANAR::show_results ( )
overrideprivatevirtual

Shows results.

Reimplemented from TRANSLINE.

Definition at line 179 of file coplanar.cpp.

180{
181
185
187}
void setResult(int, double, const char *)
Definition: transline.cpp:133
#define UNIT_MICRON
Definition: units_scales.h:35

References EPSILON_EFF_PRM, LOSS_CONDUCTOR_PRM, LOSS_DIELECTRIC_PRM, TRANSLINE::m_parameters, TRANSLINE::setResult(), SKIN_DEPTH_PRM, and UNIT_MICRON.

◆ showAnalyze()

void COPLANAR::showAnalyze ( )
overrideprivatevirtual

Shows synthesis results and checks for errors / warnings.

Reimplemented from TRANSLINE.

Definition at line 244 of file coplanar.cpp.

245{
248
249 if( !std::isfinite( m_parameters[PHYS_S_PRM] ) || m_parameters[PHYS_S_PRM] <= 0 )
251
252 if( !std::isfinite( m_parameters[PHYS_WIDTH_PRM] ) || m_parameters[PHYS_WIDTH_PRM] <= 0 )
254
255 if( !std::isfinite( m_parameters[PHYS_LEN_PRM] ) || m_parameters[PHYS_LEN_PRM] < 0 )
257
258 if( !std::isfinite( m_parameters[Z0_PRM] ) || m_parameters[Z0_PRM] < 0 )
260
261 if( !std::isfinite( m_parameters[ANG_L_PRM] ) || m_parameters[ANG_L_PRM] < 0 )
263}
void setProperty(enum PRMS_ID aPrmId, double aValue)
Definition: transline.cpp:109

References ANG_L_PRM, TRANSLINE::m_parameters, PHYS_LEN_PRM, PHYS_S_PRM, PHYS_WIDTH_PRM, TRANSLINE::setErrorLevel(), TRANSLINE::setProperty(), TRANSLINE_ERROR, TRANSLINE_WARNING, and Z0_PRM.

◆ showSynthesize()

void COPLANAR::showSynthesize ( )
overrideprivatevirtual

Shows analysis results and checks for errors / warnings.

Reimplemented from TRANSLINE.

Definition at line 207 of file coplanar.cpp.

References ANG_L_PRM, TRANSLINE::isSelected(), TRANSLINE::m_parameters, PHYS_LEN_PRM, PHYS_S_PRM, PHYS_WIDTH_PRM, TRANSLINE::setErrorLevel(), TRANSLINE::setProperty(), TRANSLINE_ERROR, TRANSLINE_WARNING, and Z0_PRM.

◆ skin_depth()

double TRANSLINE::skin_depth ( )
protectedinherited

@function skin_depth calculate skin depth

$ \frac{1}{\sqrt{ \pi \cdot f \cdot \mu \cdot \sigma }} $

Definition at line 237 of file transline.cpp.

238{
239 double depth;
240 depth = 1.0
243 return depth;
244}

References FREQUENCY_PRM, TRANSLINE::m_parameters, MU0, MURC_PRM, and SIGMA_PRM.

Referenced by C_MICROSTRIP::attenuation(), MICROSTRIP::attenuation(), calcAnalyze(), STRIPLINE::calcAnalyze(), and TRANSLINE::getProperties().

◆ synthesize()

void TRANSLINE::synthesize ( )
virtualinherited

Definition at line 220 of file transline.cpp.

221{
226 show_results();
227}
virtual void showSynthesize()
Shows analysis results and checks for errors / warnings.
Definition: transline.h:117
virtual void calcSynthesize()
Computation for synthesis.
Definition: transline.h:107

References TRANSLINE::calcSynthesize(), TRANSLINE::checkProperties(), TRANSLINE::getProperties(), TRANSLINE::show_results(), and TRANSLINE::showSynthesize().

Referenced by PANEL_TRANSLINE::OnTranslineSynthetize().

Member Data Documentation

◆ ang_l

double TRANSLINE::ang_l
protectedinherited

Definition at line 134 of file transline.h.

Referenced by TRANSLINE::TRANSLINE().

◆ backMetal

bool COPLANAR::backMetal
protected

Definition at line 39 of file coplanar.h.

Referenced by calcAnalyze(), COPLANAR(), and GROUNDEDCOPLANAR::GROUNDEDCOPLANAR().

◆ er_eff

◆ errCol

KIGFX::COLOR4D TRANSLINE::errCol = KIGFX::COLOR4D( 1, 0.63, 0.63, 1 )
inherited

Definition at line 126 of file transline.h.

Referenced by TRANSLINE::setErrorLevel().

◆ len

double TRANSLINE::len
protectedinherited

Definition at line 132 of file transline.h.

Referenced by TRANSLINE::TRANSLINE().

◆ m_Name

◆ m_parameters

double TRANSLINE::m_parameters[EXTRA_PRMS_COUNT]
protectedinherited

Definition at line 131 of file transline.h.

Referenced by RECTWAVEGUIDE::alphac(), COAX::alphac_coax(), RECTWAVEGUIDE::alphad(), COAX::alphad_coax(), C_MICROSTRIP::attenuation(), MICROSTRIP::attenuation(), COAX::calcAnalyze(), calcAnalyze(), RECTWAVEGUIDE::calcAnalyze(), STRIPLINE::calcAnalyze(), TWISTEDPAIR::calcAnalyze(), C_MICROSTRIP::calcSynthesize(), COAX::calcSynthesize(), calcSynthesize(), MICROSTRIP::calcSynthesize(), RECTWAVEGUIDE::calcSynthesize(), STRIPLINE::calcSynthesize(), TWISTEDPAIR::calcSynthesize(), TRANSLINE::checkProperties(), C_MICROSTRIP::compute_single_line(), C_MICROSTRIP::conductor_losses(), MICROSTRIP::conductor_losses(), C_MICROSTRIP::delta_u_thickness(), C_MICROSTRIP::dielectric_losses(), MICROSTRIP::dielectric_losses(), MICROSTRIP::dispersion(), C_MICROSTRIP::er_eff_freq(), C_MICROSTRIP::er_eff_static(), RECTWAVEGUIDE::fc(), RECTWAVEGUIDE::get_rectwaveguide_comp(), RECTWAVEGUIDE::get_rectwaveguide_elec(), RECTWAVEGUIDE::get_rectwaveguide_phys(), RECTWAVEGUIDE::get_rectwaveguide_sub(), TRANSLINE::getProperties(), TRANSLINE::Init(), RECTWAVEGUIDE::kc_square(), RECTWAVEGUIDE::kval_square(), C_MICROSTRIP::line_angle(), MICROSTRIP::line_angle(), STRIPLINE::lineImpedance(), MICROSTRIP::microstrip_Z0(), TRANSLINE::minimizeZ0Error1D(), MICROSTRIP::mur_eff_ms(), C_MICROSTRIP::show_results(), COAX::show_results(), show_results(), MICROSTRIP::show_results(), RECTWAVEGUIDE::show_results(), STRIPLINE::show_results(), TWISTEDPAIR::show_results(), C_MICROSTRIP::showAnalyze(), COAX::showAnalyze(), showAnalyze(), MICROSTRIP::showAnalyze(), RECTWAVEGUIDE::showAnalyze(), STRIPLINE::showAnalyze(), TWISTEDPAIR::showAnalyze(), C_MICROSTRIP::showSynthesize(), COAX::showSynthesize(), showSynthesize(), MICROSTRIP::showSynthesize(), RECTWAVEGUIDE::showSynthesize(), STRIPLINE::showSynthesize(), TWISTEDPAIR::showSynthesize(), TRANSLINE::skin_depth(), C_MICROSTRIP::syn_fun(), C_MICROSTRIP::synth_width(), MICROSTRIP::synth_width(), TRANSLINE::TRANSLINE(), C_MICROSTRIP::Z0_dispersion(), and C_MICROSTRIP::Z0_even_odd().

◆ okCol

KIGFX::COLOR4D TRANSLINE::okCol = KIGFX::COLOR4D( 1, 1, 1, 1 )
inherited

Definition at line 128 of file transline.h.

Referenced by TRANSLINE::Init(), and TRANSLINE::setErrorLevel().

◆ warnCol

KIGFX::COLOR4D TRANSLINE::warnCol = KIGFX::COLOR4D( 1, 1, 0.57, 1 )
inherited

Definition at line 127 of file transline.h.

Referenced by TRANSLINE::setErrorLevel().


The documentation for this class was generated from the following files: