kicad/pcb_calculator/via.cpp

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/*
* This program source code file is part of KICAD, a free EDA CAD application.
*
* Copyright (C) 1992-2019 Kicad Developers, see AUTHORS.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 3
* 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, see <http://www.gnu.org/licenses/>.
*/
/* All calculations are based on this [1] online calculator:
*
* References:
*
* [1]: The CircuitCalculator.com Blog - PCB Via Calculator
* http://circuitcalculator.com/wordpress/2006/03/12/pcb-via-calculator/
*
* [2]: Constructing Your Power Supply - Layout Considerations
* https://www.ti.com/seclit/ml/slup230/slup230.pdf
*
* [3]: Current Carrying Capacity of Vias - Some Conceptual Observations
* https://www.ultracad.com/articles/viacurrents.pdf
*
* [4]: IPC-2221A - Generic Standard on Printed Board Design
* http://www.sphere.bc.ca/class/downloads/ipc_2221a-pcb%20standards.pdf
*
* [5]: Copper - online catalogue source - Goodfellow
* http://www.goodfellow.com/E/Copper.html
*
* [6]: Thermal Conductivity of Metals, Metallic Elements and Alloys
* https://www.engineeringtoolbox.com/thermal-conductivity-metals-d_858.html
*
* [7]: Johnson & Graham, High Speed Digital Design: A Handbook of Black Magic
*/
#include <cmath>
#include <wx/wx.h>
#include <wx/config.h>
#include <pcb_calculator_frame_base.h>
#include <pcb_calculator.h>
#include <UnitSelector.h>
#include <units_scales.h>
#include <common_data.h>
extern double DoubleFromString( const wxString& TextValue );
// Key words to read/write some parameters in config:
#define KEYWORD_VS_HOLE_DIA wxT( "VS_Hole_Dia" )
#define KEYWORD_VS_HOLE_DIA_UNIT wxT( "VS_Hole_Dia_Unit" )
#define KEYWORD_VS_THICKNESS wxT( "VS_Plating_Thickness" )
#define KEYWORD_VS_THICKNESS_UNIT wxT( "VS_Plating_Thickness_Unit" )
#define KEYWORD_VS_LENGTH wxT( "VS_Via_Length" )
#define KEYWORD_VS_LENGTH_UNIT wxT( "VS_Via_Length_Unit" )
#define KEYWORD_VS_PAD_DIA wxT( "VS_Pad_Dia" )
#define KEYWORD_VS_PAD_DIA_UNIT wxT( "VS_Pad_Dia_Unit" )
#define KEYWORD_VS_CLEARANCE_DIA wxT( "VS_Clearance_Dia" )
#define KEYWORD_VS_CLEARANCE_DIA_UNIT wxT( "VS_Clearance_Dia_Unit" )
#define KEYWORD_VS_CH_IMPEDANCE wxT( "VS_Characteristic_Impedance" )
#define KEYWORD_VS_CH_IMPEDANCE_UNIT wxT( "VS_Characteristic_Impedance_Unit" )
#define KEYWORD_VS_CURRENT wxT( "VS_Current" )
#define KEYWORD_VS_RESISTIVITY wxT( "VS_Resistivity" )
#define KEYWORD_VS_PERMITTIVITY wxT( "VS_Permittivity" )
#define KEYWORD_VS_TEMP_DIFF wxT( "VS_Temperature_Differential" )
#define KEYWORD_VS_PULSE_RISE_TIME wxT( "VS_Pulse_Rise_Time" )
/**
* Shows a list of current relative dielectric constant(Er)
* and set the selected value in main dialog frame
*/
void PCB_CALCULATOR_FRAME::OnViaEpsilonR_Button( wxCommandEvent& event )
{
wxArrayString list = StandardRelativeDielectricConstantList();
wxString value = wxGetSingleChoice( wxEmptyString,
_("Relative Dielectric Constants"), list).BeforeFirst( ' ' );
if( ! value.IsEmpty() )
m_textCtrlPlatingPermittivity->SetValue( value );
}
/**
* Shows a list of current Specific resistance list (rho)
* and set the selected value in main dialog frame
*/
void PCB_CALCULATOR_FRAME::OnViaRho_Button( wxCommandEvent& event )
{
wxArrayString list = StandardResistivityList();
wxString value = wxGetSingleChoice( wxEmptyString,
_("Electrical Resistivity in Ohm*m"), list).BeforeFirst( ' ' );
if( ! value.IsEmpty() )
m_textCtrlPlatingResistivity->SetValue( value );
}
void PCB_CALCULATOR_FRAME::onUpdateViaCalcErrorText( wxUpdateUIEvent& event )
{
// Update the Error message if a via has a external diameter
// bigger than the clearance area diameter
// (therefore the via is inside a copper zone and some parameters connot be calculated)
double clearanceDia = std::abs( DoubleFromString( m_textCtrlClearanceDia->GetValue() ) );
clearanceDia *= m_choiceClearanceDia->GetUnitScale();
double padDia = std::abs( DoubleFromString( m_textCtrlViaPadDia->GetValue() ) );
padDia *= m_choiceViaPadDia->GetUnitScale();
m_staticTextWarning->Show( clearanceDia <= padDia );
}
void PCB_CALCULATOR_FRAME::VS_Init( wxConfigBase* aCfg )
{
int tmp;
wxString msg;
#define DEFAULT_UNIT_SEL_MM 0
// Read parameter values
aCfg->Read( KEYWORD_VS_HOLE_DIA, &msg, wxT( "0.4" ) );
m_textCtrlHoleDia->SetValue( msg );
aCfg->Read( KEYWORD_VS_HOLE_DIA_UNIT, &tmp, DEFAULT_UNIT_SEL_MM );
m_choiceHoleDia->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_THICKNESS, &msg, wxT( "0.035" ) );
m_textCtrlPlatingThickness->SetValue( msg );
aCfg->Read( KEYWORD_VS_THICKNESS_UNIT, &tmp, DEFAULT_UNIT_SEL_MM );
m_choicePlatingThickness->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_LENGTH, &msg, wxT( "1.6" ) );
m_textCtrlViaLength->SetValue( msg );
aCfg->Read( KEYWORD_VS_LENGTH_UNIT, &tmp, DEFAULT_UNIT_SEL_MM );
m_choiceViaLength->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_PAD_DIA, &msg, wxT( "0.6" ) );
m_textCtrlViaPadDia->SetValue( msg );
aCfg->Read( KEYWORD_VS_PAD_DIA_UNIT, &tmp, DEFAULT_UNIT_SEL_MM );
m_choiceViaPadDia->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_CLEARANCE_DIA, &msg, wxT( "1.0" ) );
m_textCtrlClearanceDia->SetValue( msg );
aCfg->Read( KEYWORD_VS_CLEARANCE_DIA_UNIT, &tmp, DEFAULT_UNIT_SEL_MM );
m_choiceClearanceDia->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_CH_IMPEDANCE, &msg, wxT( "50" ) );
m_textCtrlImpedance->SetValue( msg );
aCfg->Read( KEYWORD_VS_CH_IMPEDANCE_UNIT , &tmp, DEFAULT_UNIT_SEL_MM );
m_choiceImpedance->SetSelection( tmp );
aCfg->Read( KEYWORD_VS_CURRENT, &msg, wxT( "1" ) );
m_textCtrlAppliedCurrent->SetValue( msg );
aCfg->Read( KEYWORD_VS_RESISTIVITY, &msg, wxT( "1.72e-8" ) );
m_textCtrlPlatingResistivity->SetValue( msg );
aCfg->Read( KEYWORD_VS_PERMITTIVITY, &msg, wxT( "4.5" ) );
m_textCtrlPlatingPermittivity->SetValue( msg );
aCfg->Read( KEYWORD_VS_TEMP_DIFF, &msg, wxT( "10" ) );
m_textCtrlTemperatureDiff->SetValue( msg );
aCfg->Read( KEYWORD_VS_PULSE_RISE_TIME, &msg, wxT( "1" ) );
m_textCtrlRiseTime->SetValue( msg );
}
void PCB_CALCULATOR_FRAME::VS_WriteConfig( wxConfigBase* aCfg )
{
// Save current parameters values in config
aCfg->Write( KEYWORD_VS_HOLE_DIA, m_textCtrlHoleDia->GetValue() );
aCfg->Write( KEYWORD_VS_HOLE_DIA_UNIT, m_choiceHoleDia->GetSelection() );
aCfg->Write( KEYWORD_VS_THICKNESS, m_textCtrlPlatingThickness->GetValue() );
aCfg->Write( KEYWORD_VS_THICKNESS_UNIT, m_choicePlatingThickness->GetSelection() );
aCfg->Write( KEYWORD_VS_LENGTH, m_textCtrlViaLength->GetValue() );
aCfg->Write( KEYWORD_VS_LENGTH_UNIT, m_choiceViaLength->GetSelection() );
aCfg->Write( KEYWORD_VS_PAD_DIA, m_textCtrlViaPadDia->GetValue() );
aCfg->Write( KEYWORD_VS_PAD_DIA_UNIT, m_choiceViaPadDia->GetSelection() );
aCfg->Write( KEYWORD_VS_CLEARANCE_DIA, m_textCtrlClearanceDia->GetValue() );
aCfg->Write( KEYWORD_VS_CLEARANCE_DIA_UNIT, m_choiceClearanceDia->GetSelection() );
aCfg->Write( KEYWORD_VS_CH_IMPEDANCE, m_textCtrlImpedance->GetValue() );
aCfg->Write( KEYWORD_VS_CH_IMPEDANCE_UNIT, m_choiceImpedance->GetSelection() );
aCfg->Write( KEYWORD_VS_CURRENT, m_textCtrlAppliedCurrent->GetValue() );
aCfg->Write( KEYWORD_VS_RESISTIVITY, m_textCtrlPlatingResistivity->GetValue() );
aCfg->Write( KEYWORD_VS_PERMITTIVITY, m_textCtrlPlatingPermittivity->GetValue() );
aCfg->Write( KEYWORD_VS_TEMP_DIFF, m_textCtrlTemperatureDiff->GetValue() );
aCfg->Write( KEYWORD_VS_PULSE_RISE_TIME, m_textCtrlRiseTime->GetValue() );
}
void PCB_CALCULATOR_FRAME::OnViaCalculate( wxCommandEvent& event )
{
// Load parameters
double finishedHoleDia = std::abs( DoubleFromString( m_textCtrlHoleDia->GetValue() ) );
double platingThickness = std::abs( DoubleFromString( m_textCtrlPlatingThickness->GetValue() ) );
double viaLength = std::abs( DoubleFromString( m_textCtrlViaLength->GetValue() ) );
double padDia = std::abs( DoubleFromString( m_textCtrlViaPadDia->GetValue() ) );
double clearanceDia = std::abs( DoubleFromString( m_textCtrlClearanceDia->GetValue() ) );
double charImpedance = std::abs( DoubleFromString( m_textCtrlImpedance->GetValue() ) );
double appliedCurrent = std::abs( DoubleFromString( m_textCtrlAppliedCurrent->GetValue() ) );
double platingResistivity = std::abs( DoubleFromString( m_textCtrlPlatingResistivity->GetValue() ) );
double relativePermitivity = std::abs( DoubleFromString( m_textCtrlPlatingPermittivity->GetValue() ) );
double temperatureDiff = std::abs( DoubleFromString( m_textCtrlTemperatureDiff->GetValue() ) );
double pulseRiseTime = std::abs( DoubleFromString( m_textCtrlRiseTime->GetValue() ) );
// Normalize units
finishedHoleDia *= m_choiceHoleDia->GetUnitScale();
platingThickness *= m_choicePlatingThickness->GetUnitScale();
viaLength *= m_choiceViaLength->GetUnitScale();
padDia *= m_choiceViaPadDia->GetUnitScale();
clearanceDia *= m_choiceClearanceDia->GetUnitScale();
charImpedance *= m_choiceImpedance->GetUnitScale();
// platingResistivity is ok: it is in Ohm*m in tables
// Calculate cross-sectional area of the via's cylindrical structure [3]
double area = M_PI * (finishedHoleDia + platingThickness) * platingThickness; // m^2
double viaResistance = platingResistivity * viaLength / area; // Ohms
// Using thermal resistivity value 2.49e-3 meter-Kelvin/Watt, equivalent to
// thermal conductivity of 401 Watt/(meter-Kelvin) [5][6]
const double thermalResistivity = 2.49e-3; // m K/W
double thermalResistance = thermalResistivity * viaLength / area; // deg C/W
double voltageDrop = appliedCurrent * viaResistance;
double powerLoss = appliedCurrent * voltageDrop;
// Estimate current carrying capacity of the via
// See comment #17 in [1] for a brief discussion on the formula
// This formula from IPC-2221 [4] is also used in the Track Width calculator
area /= pow( UNIT_MIL, 2 ); // m^2 to mil^2
const double k = 0.048;
const double b = 0.44;
const double c = 0.725;
double estimatedAmpacity = k * pow( temperatureDiff, b ) * pow( area, c );
// Equation 7.6 in [7]
double capacitance = 55.51 * relativePermitivity * viaLength * padDia;
capacitance /= clearanceDia - padDia;
// Equation 7.8 in [7]
double timeDegradation = 2.2 * capacitance * charImpedance / 2;
// Equation 7.9 in [7]
double inductance = 200 * viaLength;
inductance *= log( 4 * viaLength / finishedHoleDia ) + 1;
// Equation 7.11 in [7]
double reactance = M_PI * inductance / pulseRiseTime;
// Update the display
VSDisplayValues( viaResistance, voltageDrop, powerLoss, estimatedAmpacity,
thermalResistance, capacitance, timeDegradation, inductance, reactance );
}
void PCB_CALCULATOR_FRAME::VSDisplayValues( double aViaResistance, double aVoltageDrop,
double aPowerLoss, double aEstimatedAmpacity, double aThermalResistance,
double aCapacitance, double aTimeDegradation, double aInductance, double aReactance )
{
wxString msg;
msg.Printf( "%g", aViaResistance );
m_ViaResistance->SetLabel( msg );
msg.Printf( "%g", aVoltageDrop );
m_ViaVoltageDrop->SetLabel( msg );
msg.Printf( "%g", aPowerLoss );
m_ViaPowerLoss->SetLabel( msg );
msg.Printf( "%g", aEstimatedAmpacity );
m_ViaAmpacity->SetLabel( msg );
msg.Printf( "%g", aThermalResistance );
m_ViaThermalResistance->SetLabel( msg );
msg.Printf( "%g", aCapacitance );
m_ViaCapacitance->SetLabel( msg );
msg.Printf( "%g", aTimeDegradation );
m_RiseTimeOutput->SetLabel( msg );
msg.Printf( "%g", aInductance );
m_Inductance->SetLabel( msg );
msg.Printf( "%g", aReactance );
m_Reactance->SetLabel( msg );
}