kopia lustrzana https://gitlab.com/gerbolyze/gerbonara
622 wiersze
27 KiB
Python
622 wiersze
27 KiB
Python
#!/usr/bin/env python3
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import subprocess
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import sys
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import os
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from math import *
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from pathlib import Path
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from itertools import cycle
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from scipy.constants import mu_0
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import matplotlib as mpl
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from gerbonara.cad.kicad import pcb as kicad_pcb
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from gerbonara.cad.kicad import footprints as kicad_fp
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from gerbonara.cad.kicad import graphical_primitives as kicad_gr
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from gerbonara.cad.kicad import primitives as kicad_pr
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from gerbonara.utils import Tag
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from gerbonara import graphic_primitives as gp
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import click
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__version__ = '1.0.0'
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def point_line_distance(p, l1, l2):
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x0, y0 = p
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x1, y1 = l1
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x2, y2 = l2
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# https://en.wikipedia.org/wiki/Distance_from_a_point_to_a_line
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return abs((x2-x1)*(y1-y0) - (x1-x0)*(y2-y1)) / sqrt((x2-x1)**2 + (y2-y1)**2)
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def line_line_intersection(l1, l2):
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p1, p2 = l1
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p3, p4 = l2
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x1, y1 = p1
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x2, y2 = p2
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x3, y3 = p3
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x4, y4 = p4
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# https://en.wikipedia.org/wiki/Line%E2%80%93line_intersection
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px = ((x1*y2-y1*x2)*(x3-x4)-(x1-x2)*(x3*y4-y3*x4))/((x1-x2)*(y3-y4)-(y1-y2)*(x3-x4))
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py = ((x1*y2-y1*x2)*(y3-y4)-(y1-y2)*(x3*y4-y3*x4))/((x1-x2)*(y3-y4)-(y1-y2)*(x3-x4))
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return px, py
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def angle_between_vectors(va, vb):
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angle = atan2(vb[1], vb[0]) - atan2(va[1], va[0])
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if angle < 0:
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angle += 2*pi
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return angle
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def traces_to_gmsh(traces, mesh_out, bbox, model_name='gerbonara_board', log=True, copper_thickness=35e-6, board_thickness=0.8, air_box_margin=5.0):
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import gmsh
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occ = gmsh.model.occ
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eps = 1e-6
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board_thickness -= 2*copper_thickness
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gmsh.initialize()
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gmsh.model.add('gerbonara_board')
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if log:
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gmsh.logger.start()
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trace_tags = {}
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trace_ends = set()
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render_cache = {}
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for i, tr in enumerate(traces):
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layer = tr[1].layer
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z0 = 0 if layer == 'F.Cu' else -(board_thickness+copper_thickness)
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prims = [prim
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for elem in tr
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for obj in elem.render(cache=render_cache)
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for prim in obj.to_primitives()]
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tags = []
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for prim in prims:
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if isinstance(prim, gp.Line):
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length = dist((prim.x1, prim.y1), (prim.x2, prim.y2))
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box_tag = occ.addBox(0, -prim.width/2, 0, length, prim.width, copper_thickness)
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angle = atan2(prim.y2 - prim.y1, prim.x2 - prim.x1)
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occ.rotate([(3, box_tag)], 0, 0, 0, 0, 0, 1, angle)
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occ.translate([(3, box_tag)], prim.x1, prim.y1, z0)
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tags.append(box_tag)
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for x, y in ((prim.x1, prim.y1), (prim.x2, prim.y2)):
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disc_id = (round(x, 3), round(y, 3), round(z0, 3), round(prim.width, 3))
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if disc_id in trace_ends:
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continue
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trace_ends.add(disc_id)
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cylinder_tag = occ.addCylinder(x, y, z0, 0, 0, copper_thickness, prim.width/2)
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tags.append(cylinder_tag)
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print('fusing', tags)
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tags, tag_map = occ.fuse([(3, tags[0])], [(3, tag) for tag in tags[1:]])
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print(tags)
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assert len(tags) == 1
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(_dim, tag), = tags
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trace_tags[i] = tag
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(x1, y1), (x2, y2) = bbox
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substrate = occ.addBox(x1, y1, -board_thickness, x2-x1, y2-y1, board_thickness)
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x1, y1 = x1-air_box_margin, y1-air_box_margin
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x2, y2 = x2+air_box_margin, y2+air_box_margin
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w, d = x2-x1, y2-y1
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z0 = -board_thickness-air_box_margin
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ab_h = board_thickness + 2*air_box_margin
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airbox = occ.addBox(x1, y1, z0, w, d, ab_h)
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print('Cutting airbox')
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occ.cut([(3, airbox)], [(3, tag) for tag in trace_tags.values()], removeObject=True, removeTool=False)
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print('Fragmenting')
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fragment_tags, fragment_hierarchy = occ.fragment([(3, airbox)], [(3, substrate)] + [(3, tag) for tag in trace_tags.values()])
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print('Synchronizing')
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occ.synchronize()
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substrate_physical = gmsh.model.add_physical_group(3, [substrate], name='substrate')
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airbox_physical = gmsh.model.add_physical_group(3, [airbox], name='airbox')
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trace_physical_surfaces = [
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gmsh.model.add_physical_group(2, list(gmsh.model.getAdjacencies(3, tag)[1]), name=f'trace{i}')
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for i, tag in trace_tags.items()]
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airbox_adjacent = set(gmsh.model.getAdjacencies(3, airbox)[1])
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in_bbox = {tag for _dim, tag in gmsh.model.getEntitiesInBoundingBox(x1+eps, y1+eps, z0+eps, x1+w-eps, y1+d-eps, z0+ab_h-eps, dim=22)}
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airbox_physical_surface = gmsh.model.add_physical_group(2, list(airbox_adjacent - in_bbox), name='airbox_surface')
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gmsh.option.setNumber('Mesh.MeshSizeFromCurvature', 90)
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gmsh.option.setNumber('Mesh.Smoothing', 10)
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gmsh.option.setNumber('Mesh.Algorithm3D', 10)
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gmsh.option.setNumber('Mesh.MeshSizeMax', 0.2e-3)
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gmsh.option.setNumber('General.NumThreads', 12)
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print('Meshing')
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gmsh.model.mesh.generate(dim=3)
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print('Writing')
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gmsh.write(str(mesh_out))
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class SVGPath:
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def __init__(self, **attrs):
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self.d = ''
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self.attrs = attrs
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def line(self, x, y):
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self.d += f'L {x} {y} '
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def move(self, x, y):
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self.d += f'M {x} {y} '
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def arc(self, x, y, r, large, sweep):
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self.d += f'A {r} {r} 0 {int(large)} {int(sweep)} {x} {y} '
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def close(self):
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self.d += 'Z '
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def __str__(self):
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attrs = ' '.join(f'{key.replace("_", "-")}="{value}"' for key, value in self.attrs.items())
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return f'<path {attrs} d="{self.d.rstrip()}"/>'
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class SVGCircle:
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def __init__(self, r, cx, cy, **attrs):
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self.r = r
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self.cx, self.cy = cx, cy
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self.attrs = attrs
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def __str__(self):
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attrs = ' '.join(f'{key.replace("_", "-")}="{value}"' for key, value in self.attrs.items())
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return f'<circle {attrs} r="{self.r}" cx="{self.cx}" cy="{self.cy}"/>'
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def svg_file(fn, stuff, vbw, vbh, vbx=0, vby=0):
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with open(fn, 'w') as f:
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f.write('<?xml version="1.0" standalone="no"?>\n')
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f.write('<!DOCTYPE svg PUBLIC "-//W3C//DTD SVG 1.1//EN" "http://www.w3.org/Graphics/SVG/1.1/DTD/svg11.dtd">\n')
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f.write(f'<svg version="1.1" width="{vbw*4}mm" height="{vbh*4}mm" viewBox="{vbx} {vby} {vbw} {vbh}" style="background-color: #333" xmlns="http://www.w3.org/2000/svg" xmlns:xlink="http://www.w3.org/1999/xlink">>\n')
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for foo in stuff:
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f.write(str(foo))
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f.write('</svg>\n')
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# https://en.wikipedia.org/wiki/Farey_sequence#Next_term
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def farey_sequence(n: int, descending: bool = False) -> None:
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"""Print the n'th Farey sequence. Allow for either ascending or descending."""
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a, b, c, d = 0, 1, 1, n
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if descending:
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a, c = 1, n - 1
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#print(f"{a}/{b}")
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yield a, b
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while c <= n and not descending or a > 0 and descending:
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k = (n + b) // d
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a, b, c, d = c, d, k * c - a, k * d - b
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#print(f"{a}/{b}")
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yield a, b
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def divisors(n, max_b=10):
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for a, b in farey_sequence(n):
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if a == n and b < max_b:
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yield b
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if b == n and a < max_b:
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yield a
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def print_valid_twists(ctx, param, value):
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if not value or ctx.resilient_parsing:
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return
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print(f'Valid twist counts for {value} turns:', file=sys.stderr)
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for d in divisors(value, value):
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print(f' {d}', file=sys.stderr)
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click.echo()
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ctx.exit()
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@click.command()
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@click.argument('outfile', required=False, type=click.Path(writable=True, dir_okay=False, path_type=Path))
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@click.option('--footprint-name', help="Name for the generated footprint. Default: Output file name sans extension.")
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@click.option('--layer-pair', default='F.Cu,B.Cu', help="Target KiCad layer pair for the generated footprint, comma-separated. Default: F.Cu/B.Cu.")
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@click.option('--turns', type=int, default=5, help='Number of turns')
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@click.option('--pcb/--footprint', default=False, help='Generate a KiCad PCB instead of a footprint')
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@click.option('--outer-diameter', type=float, default=50, help='Outer diameter [mm]')
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@click.option('--inner-diameter', type=float, default=25, help='Inner diameter [mm]')
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@click.option('--trace-width', type=float, default=None)
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@click.option('--via-diameter', type=float, default=0.6)
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@click.option('--via-drill', type=float, default=0.3)
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@click.option('--via-offset', type=float, default=None, help='Radially offset vias from trace endpoints [mm]')
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@click.option('--keepout-zone/--no-keepout-zone', default=True, help='Add a keepout are to the footprint (default: yes)')
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@click.option('--keepout-margin', type=float, default=5, help='Margin between outside of coil and keepout area (mm, default: 5)')
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@click.option('--twists', type=int, default=1, help='Number of twists per revolution. Note that this number must be co-prime to the number of turns. Run with --show-twists to list valid values. (default: 1)')
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@click.option('--show-twists', callback=print_valid_twists, expose_value=False, type=int, is_eager=True, help='Calculate and show valid --twists counts for the given number of turns. Takes the number of turns as a value.')
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@click.option('--clearance', type=float, default=None)
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@click.option('--arc-tolerance', type=float, default=0.02)
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@click.option('--mesh-out', type=click.Path(writable=True, dir_okay=False, path_type=Path))
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@click.option('--clipboard/--no-clipboard', help='Use clipboard integration (requires wl-clipboard)')
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@click.option('--counter-clockwise/--clockwise', help='Direction of generated spiral. Default: clockwise when wound from the inside.')
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@click.version_option()
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def generate(outfile, turns, outer_diameter, inner_diameter, via_diameter, via_drill, via_offset, trace_width, clearance,
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footprint_name, layer_pair, twists, clipboard, counter_clockwise, keepout_zone, keepout_margin,
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arc_tolerance, pcb, mesh_out):
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if 'WAYLAND_DISPLAY' in os.environ:
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copy, paste, cliputil = ['wl-copy'], ['wl-paste'], 'xclip'
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else:
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copy, paste, cliputil = ['xclip', '-i', '-sel', 'clipboard'], ['xclip', '-o', '-sel' 'clipboard'], 'wl-clipboard'
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if gcd(twists, turns) != 1:
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raise click.ClickException('For the geometry to work out, the --twists parameter must be co-prime to --turns, i.e. the two must have 1 as their greatest common divisor. You can print valid values for --twists by running this command with --show-twists [turns number].')
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if mesh_out and not pcb:
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raise click.ClickException('--pcb is required when --mesh-out is used.')
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outer_radius = outer_diameter/2
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inner_radius = inner_diameter/2
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turns_per_layer = turns/2
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sweeping_angle = 2*pi * turns_per_layer / twists
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spiral_pitch = (outer_radius-inner_radius) / turns_per_layer
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c1 = inner_radius
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c2 = inner_radius + spiral_pitch
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alpha1 = atan((outer_radius - inner_radius) / sweeping_angle / c1)
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alpha2 = atan((outer_radius - inner_radius) / sweeping_angle / c2)
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alpha = (alpha1+alpha2)/2
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projected_spiral_pitch = spiral_pitch*cos(alpha)
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if trace_width is None and clearance is None:
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trace_width = 0.15
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print(f'Warning: Defaulting to {trace_width:.2f} mm trace width.', file=sys.stderr)
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if trace_width is None:
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if clearance > projected_spiral_pitch:
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raise click.ClickException(f'Error: Given clearance of {clearance:.2f} mm is larger than the projected spiral pitch of {projected_spiral_pitch:.2f} mm. Reduce clearance or increase the size of the coil.')
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trace_width = projected_spiral_pitch - clearance
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print(f'Calculated trace width for {clearance:.2f} mm clearance is {trace_width:.2f} mm.', file=sys.stderr)
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elif clearance is None:
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if trace_width > projected_spiral_pitch:
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raise click.ClickException(f'Error: Given trace width of {trace_width:.2f} mm is larger than the projected spiral pitch of {projected_spiral_pitch:.2f} mm. Reduce clearance or increase the size of the coil.')
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clearance = projected_spiral_pitch - trace_width
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print(f'Calculated clearance for {trace_width:.2f} mm trace width is {clearance:.2f} mm.', file=sys.stderr)
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else:
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if trace_width > projected_spiral_pitch:
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raise click.ClickException(f'Error: Given trace width of {trace_width:.2f} mm is larger than the projected spiral pitch of {projected_spiral_pitch:.2f} mm. Reduce clearance or increase the size of the coil.')
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clearance_actual = projected_spiral_pitch - trace_width
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if clearance_actual < clearance:
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raise click.ClickException(f'Error: Actual clearance for {trace_width:.2f} mm trace is {clearance_actual:.2f} mm, which is lower than the given clearance of {clearance:.2f} mm.')
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if via_diameter < trace_width:
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print(f'Clipping via diameter from {via_diameter:.2f} mm to trace width of {trace_width:.2f} mm.', file=sys.stderr)
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via_diameter = trace_width
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if via_offset is None:
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via_offset = max(0, (via_diameter-trace_width)/2)
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print(f'Autocalculated via offset {via_offset:.2f} mm', file=sys.stderr)
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inner_via_ring_radius = inner_radius - via_offset
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#print(f'{inner_radius=} {via_offset=} {via_diameter=}', file=sys.stderr)
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inner_via_angle = 2*asin((via_diameter + clearance)/2 / inner_via_ring_radius)
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outer_via_ring_radius = outer_radius + via_offset
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outer_via_angle = 2*asin((via_diameter + clearance)/2 / outer_via_ring_radius)
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print(f'Inner via ring @r={inner_via_ring_radius:.2f} mm (from {inner_radius:.2f} mm)', file=sys.stderr)
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print(f' {degrees(inner_via_angle):.1f} deg / via', file=sys.stderr)
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print(f'Outer via ring @r={outer_via_ring_radius:.2f} mm (from {outer_radius:.2f} mm)', file=sys.stderr)
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print(f' {degrees(outer_via_angle):.1f} deg / via', file=sys.stderr)
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if inner_via_angle*twists > 2*pi:
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min_dia = 2*((via_diameter + clearance) / (2*sin(pi / twists)) + via_offset)
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raise click.ClickException(f'Error: Overlapping vias in inner via ring. Calculated minimum inner diameter is {min_dia:.2f} mm.')
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pitch = clearance + trace_width
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t, _, b = layer_pair.partition(',')
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layer_pair = (t.strip(), b.strip())
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rainbow = '#817 #a35 #c66 #e94 #ed0 #9d5 #4d8 #2cb #0bc #09c #36b #639'.split()
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rainbow = rainbow[2::3] + rainbow[1::3] + rainbow[0::3]
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n = 5
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rainbow = rainbow[n:] + rainbow[:n]
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out_paths = []
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svg_stuff = [*out_paths]
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# See https://coil32.net/pcb-coil.html for details
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d_avg = (outer_diameter + inner_diameter)/2
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phi = (outer_diameter - inner_diameter) / (outer_diameter + inner_diameter)
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c1, c2, c3, c4 = 1.00, 2.46, 0.00, 0.20
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L = mu_0 * turns**2 * d_avg*1e3 * c1 / 2 * (log(c2/phi) + c3*phi + c4*phi**2)
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print(f'Outer diameter: {outer_diameter:g} mm', file=sys.stderr)
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print(f'Average diameter: {d_avg:g} mm', file=sys.stderr)
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print(f'Inner diameter: {inner_diameter:g} mm', file=sys.stderr)
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print(f'Fill factor: {phi:g}', file=sys.stderr)
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print(f'Approximate inductance: {L:g} µH', file=sys.stderr)
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make_pad = lambda num, layer, x, y: kicad_fp.Pad(
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number=str(num),
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type=kicad_fp.Atom.smd,
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shape=kicad_fp.Atom.circle,
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at=kicad_fp.AtPos(x=x, y=y),
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size=kicad_fp.XYCoord(x=trace_width, y=trace_width),
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layers=layer,
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clearance=clearance,
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zone_connect=0)
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make_line = lambda x1, y1, x2, y2, layer: kicad_fp.Line(
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start=kicad_fp.XYCoord(x=x1, y=y1),
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end=kicad_fp.XYCoord(x=x2, y=y2),
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layer=layer,
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stroke=kicad_fp.Stroke(width=trace_width))
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make_arc = lambda x1, y1, x2, y2, xm, ym, layer: kicad_fp.Arc(
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start=kicad_fp.XYCoord(x=x1, y=y1),
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mid=kicad_fp.XYCoord(x=xm, y=ym),
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end=kicad_fp.XYCoord(x=x2, y=y2),
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layer=layer,
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stroke=kicad_fp.Stroke(width=trace_width))
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make_via = lambda x, y, layers: kicad_fp.Pad(number="NC",
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type=kicad_fp.Atom.thru_hole,
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shape=kicad_fp.Atom.circle,
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at=kicad_fp.AtPos(x=x, y=y),
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size=kicad_fp.XYCoord(x=via_diameter, y=via_diameter),
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drill=kicad_fp.Drill(diameter=via_drill),
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layers=layers,
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clearance=clearance,
|
|
zone_connect=0)
|
|
|
|
use_arcs = not pcb
|
|
pads = []
|
|
lines = []
|
|
arcs = []
|
|
|
|
def arc_approximate(points, layer, tolerance=0.02, level=0):
|
|
indent = ' ' * level
|
|
#print(f'{indent}arc_approximate {len(points)=}', file=sys.stderr)
|
|
if len(points) < 3:
|
|
raise ValueError()
|
|
|
|
i_mid = len(points)//2
|
|
|
|
x0, y0 = points[0]
|
|
x1, y1 = points[i_mid]
|
|
x2, y2 = points[-1]
|
|
|
|
if len(points) < 5:
|
|
#print(f'{indent} -> interp last points', file=sys.stderr)
|
|
yield make_arc(x0, y0, x2, y2, x1, y1, layer)
|
|
|
|
# https://stackoverflow.com/questions/56224824/how-do-i-find-the-circumcenter-of-the-triangle-using-python-without-external-lib
|
|
d = 2 * (x0 * (y2 - y1) + x2 * (y1 - y0) + x1 * (y0 - y2))
|
|
cx = ((x0 * x0 + y0 * y0) * (y2 - y1) + (x2 * x2 + y2 * y2) * (y1 - y0) + (x1 * x1 + y1 * y1) * (y0 - y2)) / d
|
|
cy = ((x0 * x0 + y0 * y0) * (x1 - x2) + (x2 * x2 + y2 * y2) * (x0 - x1) + (x1 * x1 + y1 * y1) * (x2 - x0)) / d
|
|
r = dist((cx, cy), (x1, y1))
|
|
if any(abs(dist((px, py), (cx, cy)) - r) > tolerance for px, py in points):
|
|
#print(f'{indent} -> split', file=sys.stderr)
|
|
yield from arc_approximate(points[:i_mid+1], layer, tolerance, level+1)
|
|
yield from arc_approximate(points[i_mid:], layer, tolerance, level+1)
|
|
|
|
else:
|
|
yield make_arc(x0, y0, x2, y2, x1, y1, layer)
|
|
#print(f'{indent} -> good fit', file=sys.stderr)
|
|
|
|
def do_spiral(layer, r1, r2, a1, a2, start_frac, end_frac, fn=64):
|
|
fn = ceil(fn * (a2-a1)/(2*pi))
|
|
x0, y0 = cos(a1)*r1, sin(a1)*r1
|
|
direction = '↓' if r2 < r1 else '↑'
|
|
dr = 3 if r2 < r1 else -3
|
|
label = f'{direction} {degrees(a1):.0f}'
|
|
svg_stuff.append(Tag('text',
|
|
[label],
|
|
x=str(x0 + cos(a1)*dr),
|
|
y=str(y0 + sin(a1)*dr),
|
|
text_anchor='middle',
|
|
style=f'font: 1px bold sans-serif; fill: {rainbow[layer%len(rainbow)]}'))
|
|
|
|
xn, yn = x0, y0
|
|
points = [(x0, y0)]
|
|
dists = []
|
|
for i in range(fn):
|
|
r, g, b, _a = mpl.cm.plasma(start_frac + (end_frac - start_frac)/fn * (i + 0.5))
|
|
path = SVGPath(fill='none', stroke=f'#{round(r*255):02x}{round(g*255):02x}{round(b*255):02x}', stroke_width=trace_width, stroke_linejoin='round', stroke_linecap='round')
|
|
svg_stuff.append(path)
|
|
xp, yp = xn, yn
|
|
r = r1 + (i+1)*(r2-r1)/fn
|
|
a = a1 + (i+1)*(a2-a1)/fn
|
|
xn, yn = cos(a)*r, sin(a)*r
|
|
path.move(xp, yp)
|
|
path.line(xn, yn)
|
|
points.append((xn, yn))
|
|
dists.append(dist((xp, yp), (xn, yn)))
|
|
if not use_arcs:
|
|
lines.append(make_line(xp, yp, xn, yn, layer_pair[layer]))
|
|
|
|
if use_arcs:
|
|
arcs.extend(arc_approximate(points, layer_pair[layer], arc_tolerance))
|
|
|
|
svg_stuff.append(Tag('text',
|
|
[label],
|
|
x=str(xn + cos(a2)*-dr),
|
|
y=str(yn + sin(a2)*-dr + 1.2),
|
|
text_anchor='middle',
|
|
style=f'font: 1px bold sans-serif; fill: {rainbow[layer%len(rainbow)]}'))
|
|
|
|
return (x0, y0), (xn, yn), sum(dists)
|
|
|
|
sector_angle = 2*pi / twists
|
|
total_angle = twists*2*sweeping_angle
|
|
|
|
inverse = {}
|
|
for i in range(twists):
|
|
inverse[i*turns%twists] = i
|
|
|
|
svg_vias = []
|
|
for i in range(twists):
|
|
start_angle = i*sector_angle
|
|
fold_angle = start_angle + sweeping_angle
|
|
end_angle = fold_angle + sweeping_angle
|
|
|
|
x = inverse[i]*floor(2*sweeping_angle / (2*pi)) * 2*pi
|
|
(x0, y0), (xn, yn), clen = do_spiral(0, outer_radius, inner_radius, start_angle, fold_angle, (x + start_angle)/total_angle, (x + fold_angle)/total_angle)
|
|
do_spiral(1, inner_radius, outer_radius, fold_angle, end_angle, (x + fold_angle)/total_angle, (x + end_angle)/total_angle)
|
|
|
|
xv, yv = inner_via_ring_radius*cos(fold_angle), inner_via_ring_radius*sin(fold_angle)
|
|
pads.append(make_via(xv, yv, layer_pair))
|
|
if not isclose(via_offset, 0, abs_tol=1e-6):
|
|
lines.append(make_line(xn, yn, xv, yv, layer_pair[0]))
|
|
lines.append(make_line(xn, yn, xv, yv, layer_pair[1]))
|
|
svg_vias.append(Tag('circle', cx=xv, cy=yv, r=via_diameter/2, stroke='none', fill='white'))
|
|
svg_vias.append(Tag('circle', cx=xv, cy=yv, r=via_drill/2, stroke='none', fill='black'))
|
|
|
|
if i > 0:
|
|
xv, yv = outer_via_ring_radius*cos(start_angle), outer_via_ring_radius*sin(start_angle)
|
|
pads.append(make_via(xv, yv, layer_pair))
|
|
if not isclose(via_offset, 0, abs_tol=1e-6):
|
|
lines.append(make_line(x0, y0, xv, yv, layer_pair[0]))
|
|
lines.append(make_line(x0, y0, xv, yv, layer_pair[1]))
|
|
svg_vias.append(Tag('circle', cx=xv, cy=yv, r=via_diameter/2, stroke='none', fill='white'))
|
|
svg_vias.append(Tag('circle', cx=xv, cy=yv, r=via_drill/2, stroke='none', fill='black'))
|
|
|
|
print(f'Approximate track length: {clen*twists*2:.2f} mm', file=sys.stderr)
|
|
|
|
top_pad = make_pad(1, [layer_pair[0]], outer_radius, 0)
|
|
pads.append(top_pad)
|
|
bottom_pad = make_pad(2, [layer_pair[1]], outer_radius, 0)
|
|
pads.append(bottom_pad)
|
|
|
|
svg_stuff += svg_vias
|
|
|
|
svg_stuff.append(Tag('path', d=f'M {inner_radius} 0 L {outer_radius} 0', stroke=rainbow[n+1], fill='none',
|
|
stroke_width='0.05mm', stroke_linecap='round'))
|
|
ntraces = int(turns_per_layer)+1
|
|
alpha = [0] * ntraces
|
|
for i in range(ntraces):
|
|
c = inner_radius + (outer_radius-inner_radius) / turns_per_layer * i
|
|
#dalpha = dy / c
|
|
#dx / dalpha = (outer_radius - inner_radius) / sweeping_angle
|
|
#c * (dx / dy) = (outer_radius - inner_radius) / sweeping_angle
|
|
#dx / dy = (outer_radius - inner_radius) / sweeping_angle / c
|
|
dx = (outer_radius - inner_radius) / sweeping_angle / c
|
|
alpha[i] = atan(dx)
|
|
dy = 0.3
|
|
dx *= dy
|
|
r = trace_width/2 / cos(alpha[i])
|
|
svg_stuff.append(Tag('path', d=f'M {c-r+dx} {-dy} L {c-r-dx} {dy}', stroke=rainbow[n+1], fill='none',
|
|
stroke_width='0.05mm', stroke_linecap='round'))
|
|
svg_stuff.append(Tag('path', d=f'M {c+r+dx} {-dy} L {c+r-dx} {dy}', stroke=rainbow[n+1], fill='none',
|
|
stroke_width='0.05mm', stroke_linecap='round'))
|
|
|
|
#print(f'spiral angle {degrees(alpha[i]):.2f}', file=sys.stderr)
|
|
|
|
for i, (a1, a2) in enumerate(zip(alpha[::-1], alpha[1::])):
|
|
amean = (a2+a1)/2
|
|
pitch = (outer_radius - inner_radius) / turns_per_layer
|
|
clearance = pitch - trace_width
|
|
clearance *= cos(amean)
|
|
|
|
x, y = inner_radius + (i + 1/2)*pitch, -0.5
|
|
svg_stuff.append(Tag('text',
|
|
[f'{clearance:.5f}mm'],
|
|
x=x,
|
|
y=y,
|
|
text_anchor='start',
|
|
transform=f'rotate(-45 {x} {y})',
|
|
style=f'font: 1px bold sans-serif; fill: {rainbow[n+1]}'))
|
|
|
|
svg_file('/tmp/test.svg', svg_stuff, 100, 100, -50, -50)
|
|
|
|
if footprint_name:
|
|
name = footprint_name
|
|
elif outfile:
|
|
name = outfile.stem,
|
|
else:
|
|
name = 'generated_coil'
|
|
|
|
if keepout_zone:
|
|
r = outer_diameter/2 + keepout_margin
|
|
tol = 0.05 # mm
|
|
n = ceil(pi / acos(1 - tol/r))
|
|
pts = [(r*cos(a*2*pi/n), r*sin(a*2*pi/n)) for a in range(n)]
|
|
zones = [kicad_pr.Zone(layers=['*.Cu'],
|
|
hatch=kicad_pr.Hatch(),
|
|
filled_areas_thickness=False,
|
|
keepout=kicad_pr.ZoneKeepout(copperpour_allowed=False),
|
|
polygon=kicad_pr.ZonePolygon(pts=kicad_pr.PointList(xy=[kicad_pr.XYCoord(x=x, y=y) for x, y in pts])))]
|
|
else:
|
|
zones = []
|
|
|
|
if pcb:
|
|
obj = kicad_pcb.Board.empty_board(
|
|
zones=zones,
|
|
track_segments=[kicad_pcb.TrackSegment.from_footprint_line(line) for line in lines],
|
|
vias=[kicad_pcb.Via.from_pad(pad) for pad in pads if pad.type == kicad_pcb.Atom.thru_hole])
|
|
obj.rebuild_trace_index()
|
|
seg = obj.track_segments[-1]
|
|
traces = []
|
|
end = top_pad
|
|
layer = 'F.Cu'
|
|
while True:
|
|
tr = list(obj.find_connected_traces(end, layers=[layer]))
|
|
traces.append(tr)
|
|
if not isinstance(tr[-1], kicad_pcb.Via):
|
|
break
|
|
layer = 'B.Cu' if layer == 'F.Cu' else 'F.Cu'
|
|
end = tr[-1]
|
|
# remove start pad
|
|
traces[0] = traces[0][1:]
|
|
|
|
r = outer_diameter/2 + 20
|
|
traces_to_gmsh(traces, mesh_out, ((-r, -r), (r, r)))
|
|
|
|
# for trace in traces:
|
|
# print(f'Trace {i}', file=sys.stderr)
|
|
# print(f' Length: {len(trace)}', file=sys.stderr)
|
|
# print(f' Start: {trace[0]}', file=sys.stderr)
|
|
# print(f' End: {trace[-1]}', file=sys.stderr)
|
|
# print(f' Layer: {trace[1].layer}', file=sys.stderr)
|
|
|
|
#for e in obj.find_connected_traces(seg, layers=seg.layer_mask):
|
|
# print(getattr(e, 'layer', ''), str(e)[:80], file=sys.stderr)
|
|
#nodes, edges = obj.track_skeleton(pads[-1])
|
|
#for node, node_edges in edges.items():
|
|
# print(f'Node {node} with {len(node_edges)} edges', file=sys.stderr)
|
|
# for i, e in enumerate(node_edges):
|
|
# print(f' Edge {i}', file=sys.stderr)
|
|
# for elem in e:
|
|
# print(' ', elem, file=sys.stderr)
|
|
|
|
else:
|
|
obj = kicad_fp.Footprint(
|
|
name=name,
|
|
generator=kicad_fp.Atom('GerbonaraTwistedCoilGenV1'),
|
|
layer='F.Cu',
|
|
descr=f"{turns} turn {outer_diameter:.2f} mm diameter twisted coil footprint, inductance approximately {L:.6f} µH. Generated by gerbonara'c Twisted Coil generator, version {__version__}.",
|
|
clearance=clearance,
|
|
zone_connect=0,
|
|
lines=lines,
|
|
arcs=arcs,
|
|
pads=pads,
|
|
zones=zones,
|
|
)
|
|
|
|
if clipboard:
|
|
try:
|
|
data = obj.serialize()
|
|
print(f'Running {copy[0]}.', file=sys.stderr)
|
|
proc = subprocess.Popen(copy, stdin=subprocess.PIPE, text=True)
|
|
proc.communicate(data)
|
|
print('passed to wl-clip:', data)
|
|
except FileNotFoundError:
|
|
print(f'Error: --clipboard requires the {copy[0]} and {paste[0]} utilities from {cliputil} to be installed.', file=sys.stderr)
|
|
elif not outfile:
|
|
print(obj.serialize())
|
|
else:
|
|
obj.write(outfile)
|
|
|
|
if __name__ == '__main__':
|
|
generate()
|