kicad/pcb_calculator/transline_dlg_funct.cpp

391 lines
13 KiB
C++

/*
* This program source code file is part of KICAD, a free EDA CAD application.
*
* Copyright (C) 2011 jean-pierre.charras
* Copyright (C) 1992-2011 Kicad Developers, see change_log.txt for contributors.
*
* 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 <wx/wx.h>
#include <wx/config.h>
#include <wx/filename.h>
#include <pcb_calculator_frame_base.h>
#include <pcb_calculator.h>
#include <UnitSelector.h>
extern double DoubleFromString( const wxString& TextValue );
// these values come from QucsStudio ( by Michael Margraf )
// Display a selection of usual Er, TanD, Rho values
// format is <value><space><comment>
/**
* Function OnEpsilonR_Button
* Shows a list of current relative dielectric constant(Er)
* and set the selected value in main dialog frame
*/
void PCB_CALCULATOR_FRAME::OnTranslineEpsilonR_Button( wxCommandEvent& event )
{
wxArrayString list;
// EpsilonR ( relative dielectric constant) list
list.Add( wxT( "4.5 FR4" ) );
list.Add( wxT( "9.8 alumina (Al2O3)" ) );
list.Add( wxT( "3.78 fused quartz" ) );
list.Add( wxT( "3.38 RO4003" ) );
list.Add( wxT( "2.2 RT/duroid 5880" ) );
list.Add( wxT( "10.2 RT/duroid 6010LM" ) );
list.Add( wxT( "2.1 teflon (PTFE)" ) );
list.Add( wxT( "4.0 PVC" ) );
list.Add( wxT( "2.3 PE" ) );
list.Add( wxT( "6.6 beryllia (BeO)" ) );
list.Add( wxT( "8.7 aluminum nitride" ) );
list.Add( wxT( "11.9 silicon" ) );
list.Add( wxT( "12.9 GaAs" ) );
wxString value = wxGetSingleChoice( wxEmptyString,
_("Relative Dielectric Constants"), list).BeforeFirst( ' ' );
if( ! value.IsEmpty() )
m_Value_EpsilonR->SetValue( value );
}
/**
* Function OnTanD_Button
* Shows a list of current dielectric loss factor (tangent delta)
* and set the selected value in main dialog frame
*/
void PCB_CALCULATOR_FRAME::OnTranslineTanD_Button( wxCommandEvent& event )
{
wxArrayString list;
// List of current dielectric loss factor (tangent delta)
list.Clear();
list.Add( wxT( "2e-2 FR4 @ 1GHz" ) );
list.Add( wxT( "3e-4 beryllia @ 10GHz" ) );
list.Add( wxT( "2e-4 aluminia (Al2O3) @ 10GHz" ) );
list.Add( wxT( "1e-4 fused quartz @ 10GHz" ) );
list.Add( wxT( "2e-3 RO4003 @ 10GHz" ) );
list.Add( wxT( "9e-4 RT/duroid 5880 @ 10GHz" ) );
list.Add( wxT( "2e-4 teflon (PTFE) @ 1MHz" ) );
list.Add( wxT( "5e-2 PVC @ 1MHz" ) );
list.Add( wxT( "2e-4 PE @ 1MHz" ) );
list.Add( wxT( "1e-3 aluminum nitride @ 10GHz" ) );
list.Add( wxT( "0.015 silicon @ 10GHz" ) );
list.Add( wxT( "0.002 GaAs @ 10GHz" ) );
wxString value = wxGetSingleChoice( wxEmptyString,
_("Dielectric Loss Factor"), list).BeforeFirst( ' ' );
if( ! value.IsEmpty() )
m_Value_TanD->SetValue( value );
}
/**
* Function OnTranslineRho_Button
* Shows a list of current Specific resistance list (rho)
* and set the selected value in main dialog frame
*/
void PCB_CALCULATOR_FRAME::OnTranslineRho_Button( wxCommandEvent& event )
{
wxArrayString list;
// Specific resistance list in ohms*meters (rho):
list.Clear();
list.Add( wxT( "2.4e-8 gold" ) );
list.Add( wxT( "1.72e-8 copper" ) );
list.Add( wxT( "1.62e-8 silver" ) );
list.Add( wxT( "12.4e-8 tin" ) );
list.Add( wxT( "10.5e-8 platinum" ) );
list.Add( wxT( "2.62e-8 aluminum" ) );
list.Add( wxT( "6.9e-8 nickel" ) );
list.Add( wxT( "3.9e-8 brass (66Cu 34Zn)" ) );
list.Add( wxT( "9.71e-8 iron" ) );
list.Add( wxT( "6.0e-8 zinc" ) );
wxString value = wxGetSingleChoice( wxEmptyString,
_("Specific Resistance"), list).BeforeFirst( ' ' );
if( ! value.IsEmpty() )
m_Value_Rho->SetValue( value );
}
// Minor helper struct to handle dialog items for a given parameter
struct DLG_PRM_DATA
{
wxStaticText * name;
wxTextCtrl * value;
UNIT_SELECTOR * unit;
};
/**
* Function TranslineTypeSelection
* Must be called after selection of a new transline.
* Update all values, labels and tool tips of parameters needed
* by the new transline
* Irrelevant parameters texts are blanked.
* @param aType = the transline_type_id of the new selected transline
*/
void PCB_CALCULATOR_FRAME::TranslineTypeSelection( enum TRANSLINE_TYPE_ID aType )
{
wxString msg;
#define DOUBLE_TO_CTLR( dlg_item, value ) { msg.Printf( wxT( "%g" ), value );\
dlg_item->SetValue( msg ); }
m_currTransLineType = aType;
if( (m_currTransLineType < START_OF_LIST_TYPE )
|| ( m_currTransLineType >= END_OF_LIST_TYPE ) )
m_currTransLineType = DEFAULT_TYPE;
// This helper bitmap is shown for coupled microstrip only:
m_bmCMicrostripZoddZeven->Show( aType == C_MICROSTRIP_TYPE );
TRANSLINE_IDENT* tr_ident = m_transline_list[m_currTransLineType];
m_currTransLine = tr_ident->m_TLine;
m_radioBtnPrm1->Show( tr_ident->m_HasPrmSelection );
m_radioBtnPrm2->Show( tr_ident->m_HasPrmSelection );
// Setup messages
wxStaticText* left_msg_list[] =
{
m_left_message1, m_left_message2, m_left_message3,
m_left_message4, m_left_message5, m_left_message6,
m_left_message7, NULL
};
wxStaticText* msg_list[] =
{
m_Message1, m_Message2, m_Message3,
m_Message4, m_Message5, m_Message6,
m_Message7, NULL
};
unsigned jj = 0;
for( ; jj < tr_ident->m_Messages.GetCount(); jj++ )
{
if( left_msg_list[jj] == NULL )
break;
left_msg_list[jj]->SetLabel( tr_ident->m_Messages[jj] );
msg_list[jj]->SetLabel( wxEmptyString );
}
while( left_msg_list[jj] )
{
left_msg_list[jj]->SetLabel( wxEmptyString );
msg_list[jj]->SetLabel( wxEmptyString );
jj++;
}
// Init parameters dialog items
struct DLG_PRM_DATA substrateprms[] =
{
{ m_EpsilonR_label,m_Value_EpsilonR, NULL },
{ m_TanD_label,m_Value_TanD, NULL },
{ m_Rho_label, m_Value_Rho, NULL },
{ m_substrate_prm4_label,m_Substrate_prm4_Value, m_SubsPrm4_choiceUnit },
{ m_substrate_prm5_label,m_Substrate_prm5_Value, m_SubsPrm5_choiceUnit },
{ m_substrate_prm6_label,m_Substrate_prm6_Value, m_SubsPrm6_choiceUnit },
{ m_substrate_prm7_label,m_Substrate_prm7_Value, m_SubsPrm7_choiceUnit },
{ m_substrate_prm8_label,m_Substrate_prm8_Value, m_SubsPrm8_choiceUnit },
{ m_substrate_prm9_label,m_Substrate_prm9_Value, m_SubsPrm9_choiceUnit }
};
#define substrateprms_cnt (sizeof(substrateprms)/sizeof(substrateprms[0]))
struct DLG_PRM_DATA physprms[] =
{
{ m_phys_prm1_label,m_Phys_prm1_Value,m_choiceUnit_Param1 },
{ m_phys_prm2_label,m_Phys_prm2_Value,m_choiceUnit_Param2 },
{ m_phys_prm3_label,m_Phys_prm3_Value,m_choiceUnit_Param3 }
};
#define physprms_cnt (sizeof(physprms)/sizeof(physprms[0]))
struct DLG_PRM_DATA elecprms[] =
{
{ m_elec_prm1_label,m_Elec_prm1_Value, m_choiceUnit_ElecPrm1 },
{ m_elec_prm2_label,m_Elec_prm2_Value, m_choiceUnit_ElecPrm2 },
{ m_elec_prm3_label,m_Elec_prm3_Value, m_choiceUnit_ElecPrm3 }
};
#define elecprms_cnt (sizeof(elecprms)/sizeof(elecprms[0]))
struct DLG_PRM_DATA frequencyprms[] =
{
{ m_Frequency_label,m_Value_Frequency_Ctrl, m_choiceUnit_Frequency }
};
#define frequencyprms_cnt (sizeof(frequencyprms)/sizeof(frequencyprms[0]))
unsigned idxsubs = 0;
unsigned idxphys = 0;
unsigned idxelec = 0;
unsigned idxfreq = 0;
for( unsigned ii = 0; ii < tr_ident->GetPrmsCount(); ii++ )
{
TRANSLINE_PRM* prm = tr_ident->GetPrm( ii );
struct DLG_PRM_DATA * data = NULL;
switch( prm->m_Type )
{
case PRM_TYPE_SUBS:
wxASSERT( idxsubs < substrateprms_cnt );
data = &substrateprms[idxsubs];
idxsubs++;
break;
case PRM_TYPE_PHYS:
wxASSERT( idxphys < physprms_cnt );
data = &physprms[idxphys];
idxphys++;
break;
case PRM_TYPE_ELEC:
wxASSERT( idxelec < elecprms_cnt );
data = &elecprms[idxelec];
idxelec++;
break;
case PRM_TYPE_FREQUENCY:
wxASSERT( idxfreq < frequencyprms_cnt );
data = &frequencyprms[idxfreq];
idxfreq++;
break;
}
wxASSERT ( data );
data->name->SetToolTip( prm->m_ToolTip );
data->name->SetLabel( prm->m_Label );
prm->m_ValueCtrl = data->value;
if( prm->m_Id != DUMMY_PRM )
{
DOUBLE_TO_CTLR( data->value, prm->m_Value );
data->value->Enable( true );
}
else
{
data->value->SetValue( wxEmptyString );
data->value->Enable( false );
}
if( prm->m_ConvUnit )
prm->m_UnitCtrl = data->unit;
if( data->unit )
{
data->unit->Show( prm->m_ConvUnit );
data->unit->Enable( prm->m_ConvUnit );
data->unit->SetSelection( prm->m_UnitSelection );
}
}
// Clear all unused params
for( ; idxsubs < substrateprms_cnt; idxsubs++ )
{
substrateprms[idxsubs].name->SetLabel(wxEmptyString);
substrateprms[idxsubs].name->SetToolTip(wxEmptyString);
substrateprms[idxsubs].value->SetValue(wxEmptyString);
substrateprms[idxsubs].value->Enable( false );
if( substrateprms[idxsubs].unit)
{
substrateprms[idxsubs].unit->Show( false );
substrateprms[idxsubs].unit->Enable( false );
substrateprms[idxsubs].unit->SetSelection( 0 );
}
}
for( ; idxphys < physprms_cnt; idxphys++ )
{
physprms[idxphys].name->SetLabel(wxEmptyString);
physprms[idxphys].name->SetToolTip(wxEmptyString);
physprms[idxphys].value->SetValue(wxEmptyString);
physprms[idxphys].value->Enable( false );
if( physprms[idxphys].unit)
{
physprms[idxphys].unit->Show( false );
physprms[idxphys].unit->Enable( false );
physprms[idxphys].unit->SetSelection( 0 );
}
}
for( ; idxelec < elecprms_cnt; idxelec++)
{
elecprms[idxelec].name->SetLabel(wxEmptyString);
elecprms[idxelec].name->SetToolTip(wxEmptyString);
elecprms[idxelec].value->SetValue(wxEmptyString);
elecprms[idxelec].value->Enable( false );
if( elecprms[idxelec].unit)
{
elecprms[idxelec].unit->Show( false );
elecprms[idxelec].unit->Enable( false );
elecprms[idxelec].unit->SetSelection( 0 );
}
}
for( ; idxfreq < frequencyprms_cnt; idxfreq++ )
{
frequencyprms[idxfreq].name->SetLabel(wxEmptyString);
frequencyprms[idxfreq].name->SetToolTip(wxEmptyString);
frequencyprms[idxfreq].value->SetValue(wxEmptyString);
frequencyprms[idxfreq].value->Enable( false );
if( frequencyprms[idxfreq].unit )
{
frequencyprms[idxfreq].unit->Show( false );
frequencyprms[idxfreq].unit->Enable( false );
frequencyprms[idxfreq].unit->SetSelection( 0 );
}
}
}
/**
* Function TransfDlgDataToTranslineParams
* Read values entered in dialog frame, and copy these values
* in current transline parameters, converted in normalized units
*/
void PCB_CALCULATOR_FRAME::TransfDlgDataToTranslineParams()
{
TRANSLINE_IDENT* tr_ident = m_transline_list[m_currTransLineType];
for( unsigned ii = 0; ii < tr_ident->GetPrmsCount(); ii++ )
{
TRANSLINE_PRM* prm = tr_ident->GetPrm( ii );
wxTextCtrl * value_ctrl = (wxTextCtrl * ) prm->m_ValueCtrl;
wxString value_txt = value_ctrl->GetValue();
double value = DoubleFromString(value_txt);
prm->m_Value = value;
UNIT_SELECTOR * unit_ctrl = (UNIT_SELECTOR * ) prm->m_UnitCtrl;
if( unit_ctrl )
{
prm->m_UnitSelection = unit_ctrl->GetSelection();
value *= unit_ctrl->GetUnitScale();
}
prm->m_NormalizedValue = value;
}
}
/**
* Function OnTranslineSelection
* Called on new transmission line selection
*/
void PCB_CALCULATOR_FRAME::OnTranslineSelection( wxCommandEvent& event )
{
enum TRANSLINE_TYPE_ID id = (enum TRANSLINE_TYPE_ID) event.GetSelection();
TranslineTypeSelection( id );
// Texts and units choice widgets can have their size modified:
// The new size must be taken in account
m_panelTransline->GetSizer()->Layout();
m_panelTransline->Refresh();
}