2017-02-23 08:00:37 +00:00
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/*
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* This program source code file is part of KiCad, a free EDA CAD application.
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*
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* Copyright (C) 2017 KiCad Developers, see AUTHORS.txt for contributors.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at 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,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU 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 program; if not, you may find one here:
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* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
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* or you may search the http://www.gnu.org website for the version 2 license,
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* or you may write to the Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
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*/
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#include "microwave_inductor.h"
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#include <wx/wx.h>
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#include <base_units.h>
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#include <validators.h>
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#include <wxPcbStruct.h>
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#include <class_pad.h>
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#include <class_edge_mod.h>
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#include <class_module.h>
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using namespace MWAVE;
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/**
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* Function gen_arc
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* generates an arc using arc approximation by lines:
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* Center aCenter
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* Angle "angle" (in 0.1 deg)
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* @param aBuffer = a buffer to store points.
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* @param aStartPoint = starting point of arc.
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* @param aCenter = arc centre.
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* @param a_ArcAngle = arc length in 0.1 degrees.
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*/
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static void gen_arc( std::vector <wxPoint>& aBuffer,
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const wxPoint& aStartPoint,
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const wxPoint& aCenter,
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int a_ArcAngle )
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{
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const int SEGM_COUNT_PER_360DEG = 16;
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auto first_point = aStartPoint - aCenter;
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int seg_count = ( ( abs( a_ArcAngle ) ) * SEGM_COUNT_PER_360DEG ) / 3600;
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if( seg_count == 0 )
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seg_count = 1;
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double increment_angle = (double) a_ArcAngle * M_PI / 1800 / seg_count;
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// Creates nb_seg point to approximate arc by segments:
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for( int ii = 1; ii <= seg_count; ii++ )
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{
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double rot_angle = increment_angle * ii;
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double fcos = cos( rot_angle );
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double fsin = sin( rot_angle );
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wxPoint currpt;
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// Rotate current point:
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currpt.x = KiROUND( ( first_point.x * fcos + first_point.y * fsin ) );
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currpt.y = KiROUND( ( first_point.y * fcos - first_point.x * fsin ) );
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auto corner = aCenter + currpt;
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aBuffer.push_back( corner );
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}
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}
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/**
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* Function BuildCornersList_S_Shape
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* Create a path like a S-shaped coil
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* @param aBuffer = a buffer where to store points (ends of segments)
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* @param aStartPoint = starting point of the path
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* @param aEndPoint = ending point of the path
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* @param aLength = full length of the path
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* @param aWidth = segment width
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*/
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static int BuildCornersList_S_Shape( std::vector <wxPoint>& aBuffer,
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const wxPoint& aStartPoint,
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const wxPoint& aEndPoint,
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int aLength, int aWidth )
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{
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/* We must determine:
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* segm_count = number of segments perpendicular to the direction
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* segm_len = length of a strand
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* radius = radius of rounded parts of the coil
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* stubs_len = length of the 2 stubs( segments parallel to the direction)
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* connecting the start point to the start point of the S shape
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* and the ending point to the end point of the S shape
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* The equations are (assuming the area size of the entire shape is Size:
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* Size.x = 2 * radius + segm_len
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* Size.y = (segm_count + 2 ) * 2 * radius + 2 * stubs_len
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* inductorPattern.m_length = 2 * delta // connections to the coil
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* + (segm_count-2) * segm_len // length of the strands except 1st and last
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* + (segm_count) * (PI * radius) // length of rounded
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* segm_len + / 2 - radius * 2) // length of 1st and last bit
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*
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* The constraints are:
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* segm_count >= 2
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* radius < m_Size.x
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* Size.y = (radius * 4) + (2 * stubs_len)
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* segm_len > radius * 2
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*
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* The calculation is conducted in the following way:
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* first:
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* segm_count = 2
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* radius = 4 * Size.x (arbitrarily fixed value)
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* Then:
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* Increasing the number of segments to the desired length
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* (radius decreases if necessary)
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*/
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wxPoint size;
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// This scale factor adjusts the arc length to handle
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// the arc to segment approximation.
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// because we use SEGM_COUNT_PER_360DEG segment to approximate a circle,
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// the trace len must be corrected when calculated using arcs
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// this factor adjust calculations and must be changed if SEGM_COUNT_PER_360DEG is modified
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// because trace using segment is shorter the corresponding arc
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// ADJUST_SIZE is the ratio between tline len and the arc len for an arc
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// of 360/ADJUST_SIZE angle
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#define ADJUST_SIZE 0.988
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auto pt = aEndPoint - aStartPoint;
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double angle = -ArcTangente( pt.y, pt.x );
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int min_len = KiROUND( EuclideanNorm( pt ) );
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int segm_len = 0; // length of segments
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int full_len; // full len of shape (sum of length of all segments + arcs)
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/* Note: calculations are made for a vertical coil (more easy calculations)
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* and after points are rotated to their actual position
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* So the main direction is the Y axis.
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* the 2 stubs are on the Y axis
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* the others segments are parallel to the X axis.
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*/
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// Calculate the size of area (for a vertical shape)
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size.x = min_len / 2;
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size.y = min_len;
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// Choose a reasonable starting value for the radius of the arcs.
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int radius = std::min( aWidth * 5, size.x / 4 );
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int segm_count; // number of full len segments
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// the half size segments (first and last segment) are not counted here
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int stubs_len = 0; // length of first or last segment (half size of others segments)
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for( segm_count = 0; ; segm_count++ )
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{
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stubs_len = ( size.y - ( radius * 2 * (segm_count + 2 ) ) ) / 2;
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if( stubs_len < size.y / 10 ) // Reduce radius.
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{
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stubs_len = size.y / 10;
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radius = ( size.y - (2 * stubs_len) ) / ( 2 * (segm_count + 2) );
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if( radius < aWidth ) // Radius too small.
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{
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// Unable to create line: Requested length value is too large for room
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return 0;
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}
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}
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segm_len = size.x - ( radius * 2 );
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full_len = 2 * stubs_len; // Length of coil connections.
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full_len += segm_len * segm_count; // Length of full length segments.
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full_len += KiROUND( ( segm_count + 2 ) * M_PI * ADJUST_SIZE * radius ); // Ard arcs len
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full_len += segm_len - (2 * radius); // Length of first and last segments
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// (half size segments len = segm_len/2 - radius).
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if( full_len >= aLength )
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break;
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}
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// Adjust len by adjusting segm_len:
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int delta_size = full_len - aLength;
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// reduce len of the segm_count segments + 2 half size segments (= 1 full size segment)
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segm_len -= delta_size / (segm_count + 1);
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// Generate first line (the first stub) and first arc (90 deg arc)
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pt = aStartPoint;
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aBuffer.push_back( pt );
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pt.y += stubs_len;
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aBuffer.push_back( pt );
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auto centre = pt;
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centre.x -= radius;
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gen_arc( aBuffer, pt, centre, -900 );
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pt = aBuffer.back();
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int half_size_seg_len = segm_len / 2 - radius;
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if( half_size_seg_len )
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{
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pt.x -= half_size_seg_len;
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aBuffer.push_back( pt );
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}
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// Create shape.
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int ii;
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int sign = 1;
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segm_count += 1; // increase segm_count to create the last half_size segment
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for( ii = 0; ii < segm_count; ii++ )
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{
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int arc_angle;
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if( ii & 1 ) // odd order arcs are greater than 0
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sign = -1;
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else
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sign = 1;
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arc_angle = 1800 * sign;
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centre = pt;
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centre.y += radius;
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gen_arc( aBuffer, pt, centre, arc_angle );
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pt = aBuffer.back();
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pt.x += segm_len * sign;
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aBuffer.push_back( pt );
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}
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// The last point is false:
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// it is the end of a full size segment, but must be
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// the end of the second half_size segment. Change it.
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sign *= -1;
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aBuffer.back().x = aStartPoint.x + radius * sign;
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// create last arc
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pt = aBuffer.back();
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centre = pt;
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centre.y += radius;
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gen_arc( aBuffer, pt, centre, 900 * sign );
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aBuffer.back();
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// Rotate point
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angle += 900;
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for( unsigned jj = 0; jj < aBuffer.size(); jj++ )
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{
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RotatePoint( &aBuffer[jj].x, &aBuffer[jj].y, aStartPoint.x, aStartPoint.y, angle );
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}
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// push last point (end point)
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aBuffer.push_back( aEndPoint );
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return 1;
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}
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MODULE* MWAVE::CreateMicrowaveInductor( INDUCTOR_PATTERN& inductorPattern,
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PCB_EDIT_FRAME* aPcbFrame, wxString& aErrorMessage )
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{
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/* Build a microwave inductor footprint.
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* - Length Mself.lng
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* - Extremities Mself.m_Start and Mself.m_End
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* We must determine:
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* Mself.nbrin = number of segments perpendicular to the direction
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* (The coil nbrin will demicercles + 1 + 2 1 / 4 circle)
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* Mself.lbrin = length of a strand
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* Mself.radius = radius of rounded parts of the coil
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* Mself.delta = segments extremities connection between him and the coil even
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*
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* The equations are
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* Mself.m_Size.x = 2 * Mself.radius + Mself.lbrin
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* Mself.m_Size.y * Mself.delta = 2 + 2 * Mself.nbrin * Mself.radius
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* Mself.lng = 2 * Mself.delta / / connections to the coil
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+ (Mself.nbrin-2) * Mself.lbrin / / length of the strands except 1st and last
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+ (Mself.nbrin 1) * (PI * Mself.radius) / / length of rounded
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* Mself.lbrin + / 2 - Melf.radius * 2) / / length of 1st and last bit
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*
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* The constraints are:
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* Nbrin >= 2
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* Mself.radius < Mself.m_Size.x
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* Mself.m_Size.y = Mself.radius * 4 + 2 * Mself.raccord
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* Mself.lbrin> Mself.radius * 2
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*
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* The calculation is conducted in the following way:
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* Initially:
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* Nbrin = 2
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* Radius = 4 * m_Size.x (arbitrarily fixed value)
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* Then:
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* Increasing the number of segments to the desired length
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* (Radius decreases if necessary)
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*/
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D_PAD* pad;
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int ll;
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wxString msg;
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auto pt = inductorPattern.m_End - inductorPattern.m_Start;
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int min_len = KiROUND( EuclideanNorm( pt ) );
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inductorPattern.m_length = min_len;
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// Enter the desired length.
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msg = StringFromValue( g_UserUnit, inductorPattern.m_length );
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2017-02-23 06:23:17 +00:00
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wxTextEntryDialog dlg( nullptr, wxEmptyString, _( "Length of Trace:" ), msg );
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2017-02-23 08:00:37 +00:00
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if( dlg.ShowModal() != wxID_OK )
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2017-02-23 06:23:17 +00:00
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return nullptr; // canceled by user
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2017-02-23 08:00:37 +00:00
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msg = dlg.GetValue();
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inductorPattern.m_length = ValueFromString( g_UserUnit, msg );
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// Control values (ii = minimum length)
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if( inductorPattern.m_length < min_len )
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{
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aErrorMessage = _( "Requested length < minimum length" );
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2017-02-23 06:23:17 +00:00
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return nullptr;
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2017-02-23 08:00:37 +00:00
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}
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// Calculate the elements.
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std::vector <wxPoint> buffer;
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ll = BuildCornersList_S_Shape( buffer, inductorPattern.m_Start,
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inductorPattern.m_End, inductorPattern.m_length,
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inductorPattern.m_Width );
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if( !ll )
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{
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aErrorMessage = _( "Requested length too large" );
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2017-02-23 06:23:17 +00:00
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return nullptr;
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2017-02-23 08:00:37 +00:00
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}
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// Generate footprint. the value is also used as footprint name.
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2017-02-23 06:23:17 +00:00
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msg = "L";
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wxTextEntryDialog cmpdlg( nullptr, wxEmptyString, _( "Component Value:" ), msg );
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cmpdlg.SetTextValidator( FILE_NAME_CHAR_VALIDATOR( &msg ) );
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if( ( cmpdlg.ShowModal() != wxID_OK ) || msg.IsEmpty() )
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2017-02-23 06:23:17 +00:00
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return nullptr; // Aborted by user
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2017-02-23 08:00:37 +00:00
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MODULE* module = aPcbFrame->CreateNewModule( msg );
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// here the module is already in the BOARD, CreateNewModule() does that.
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module->SetFPID( LIB_ID( std::string( "mw_inductor" ) ) );
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module->SetAttributes( MOD_VIRTUAL | MOD_CMS );
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module->ClearFlags();
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module->SetPosition( inductorPattern.m_End );
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|
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// Generate segments
|
|
|
|
for( unsigned jj = 1; jj < buffer.size(); jj++ )
|
|
|
|
{
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|
|
|
EDGE_MODULE* PtSegm;
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|
|
|
PtSegm = new EDGE_MODULE( module );
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|
|
|
PtSegm->SetStart( buffer[jj - 1] );
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|
PtSegm->SetEnd( buffer[jj] );
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|
|
|
PtSegm->SetWidth( inductorPattern.m_Width );
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|
|
|
PtSegm->SetLayer( module->GetLayer() );
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|
|
|
PtSegm->SetShape( S_SEGMENT );
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|
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PtSegm->SetStart0( PtSegm->GetStart() - module->GetPosition() );
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|
PtSegm->SetEnd0( PtSegm->GetEnd() - module->GetPosition() );
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|
|
|
module->GraphicalItems().PushBack( PtSegm );
|
|
|
|
}
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|
|
|
|
|
|
|
// Place a pad on each end of coil.
|
|
|
|
pad = new D_PAD( module );
|
|
|
|
|
|
|
|
module->Pads().PushFront( pad );
|
|
|
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|
|
|
|
pad->SetPadName( "1" );
|
|
|
|
pad->SetPosition( inductorPattern.m_End );
|
|
|
|
pad->SetPos0( pad->GetPosition() - module->GetPosition() );
|
|
|
|
|
|
|
|
pad->SetSize( wxSize( inductorPattern.m_Width, inductorPattern.m_Width ) );
|
|
|
|
|
|
|
|
pad->SetLayerSet( LSET( module->GetLayer() ) );
|
|
|
|
pad->SetAttribute( PAD_ATTRIB_SMD );
|
|
|
|
pad->SetShape( PAD_SHAPE_CIRCLE );
|
|
|
|
|
|
|
|
D_PAD* newpad = new D_PAD( *pad );
|
|
|
|
|
|
|
|
module->Pads().Insert( newpad, pad->Next() );
|
|
|
|
|
|
|
|
pad = newpad;
|
|
|
|
pad->SetPadName( "2" );
|
|
|
|
pad->SetPosition( inductorPattern.m_Start );
|
|
|
|
pad->SetPos0( pad->GetPosition() - module->GetPosition() );
|
|
|
|
|
|
|
|
// Modify text positions.
|
|
|
|
wxPoint refPos( ( inductorPattern.m_Start.x + inductorPattern.m_End.x ) / 2,
|
|
|
|
( inductorPattern.m_Start.y + inductorPattern.m_End.y ) / 2 );
|
|
|
|
|
|
|
|
wxPoint valPos = refPos;
|
|
|
|
|
|
|
|
refPos.y -= module->Reference().GetTextSize().y;
|
|
|
|
module->Reference().SetPosition( refPos );
|
|
|
|
valPos.y += module->Value().GetTextSize().y;
|
|
|
|
module->Value().SetPosition( valPos );
|
|
|
|
|
|
|
|
module->CalculateBoundingBox();
|
|
|
|
return module;
|
|
|
|
}
|