#!/usr/bin/env python3 from collections import namedtuple from decimal import Decimal as Dec from math import sin, cos, pi from shapely.geometry import LineString, asPolygon, Point as sPoint import numpy as np """ Run as follows: ./measure.py | column -t -s $'\t' """ class Deg(namedtuple('Deg', ['deg', 'mm', 'ss'])): def __str__(self): return "%03d-%02d-%04.1f" % (self.deg, self.mm, self.ss) def hms(deg): assert isinstance(deg, Dec) pdeg, pmm = divmod(deg, 1) pmm = pmm * Dec(60) pmm, pss = divmod(pmm, 1) pss = pss * Dec(60) return Deg(pdeg, pmm, pss) def normalize(ang): while ang > 180: ang -= 360 while ang <= -180: ang += 360 return ang def guess(inp): if isinstance(inp, str) and '-' in inp: deg, mm, ss = inp.split('-') ddeg, dmm, dss = Dec(deg), Dec(mm), Dec(ss) return ddeg + dmm/60 + dss/3600 else: return Dec(instr) class Point(namedtuple('Point', ['acadx', 'acady'])): @property def lksx(self): return self.acady @property def lksy(self): return self.acadx class Vertex: def __init__(self, point, length, angle, dirang=Dec(), coords = Point(Dec(), Dec())): self.point = point self.len = length self.ang = angle self.dirang = dirang self.coords = coords self.dx, self.dy = Dec(), Dec() @property def xy(self): """xy returns a tuple of lksx and lksy coordinates""" return np.array([float(self.coords.lksx), float(self.coords.lksy)]) def heptagon(d1): angles = np.linspace(0, 2*pi, num=8) R = float(D1)/2/sin(pi/7) heptagon_xy = (np.array([np.cos(angles), np.sin(angles)])*R).T return asPolygon(heptagon_xy) juosta = namedtuple('juosta', ['plotis', 'kryptis', 'dashes', 'spalva']) kelias = namedtuple('kelias', ['virsunes', 'plotis', 'kat', 'dashes', 'spalva', 'juostos']) # Kategorijos KAT0, KAT1, KAT2, KAT3, KAT4 = range(5,0,-1) A = Dec('6.094') B = Dec('-2.923') C = Dec('-13.462') N = Dec('9.512') L1 = Dec('16.321') # === Kelias A-05 === L2 = Dec('9.109') L3 = Dec('4.819') # === Kelias A-08 === L4 = Dec('2.675') L5 = Dec('2.059') L6 = Dec('1.262') L7 = Dec('4.170') L8 = Dec('6.005') L9 = Dec('6.453') # === Griovys G-11 === L10 = Dec('4.882') L11 = Dec('3.305') L12 = Dec('2.210') L13 = Dec('4.381') A03_plotis = Dec('17.401') + A A05_plotis = Dec('13.705') + B A08_plotis = Dec('29.006') + C G11_plotis = Dec('14.776') + N # Directional coords + angle X11 = Dec('6091968.055') Y11 = Dec('485944.146') A11_2 = guess('70-16-17') vertices = [ # point len angle dirangle coords Vertex(11, Dec('164.126'), guess('103-03-03'), A11_2, Point(X11, Y11)), Vertex(2, Dec('149.851'), guess('218-27-42')), Vertex(19, Dec('82.384' ), guess('211-44-30')), Vertex(3, Dec('259.022'), guess('67-26-49' )), Vertex(24, Dec('319.331'), guess('67-33-06' )), Vertex(12, Dec('74.764' ), guess('279-03-59')), Vertex(13, Dec('81.640' ), guess('278-54-55')), Vertex(14, Dec('31.888' ), guess('119-27-45')), Vertex(15, Dec('84.073' ), guess('160-50-28')), Vertex(16, Dec('70.072' ), guess('207-42-31')), Vertex(17, Dec('73.378' ), guess('206-18-01')), Vertex(10, Dec('66.625' ), guess('90-55-10' )), Vertex(18, Dec('97.003' ), guess('100-18-10')), Vertex(9, Dec('121.003'), guess('148-30-56')), Vertex(8, Dec('131.915'), guess('285-20-57')), Vertex(23, Dec('102.086'), guess('29-44-22' )), Vertex(22, Dec('158.324'), guess('276-33-49')), Vertex(7, Dec('72.157' ), guess('82-07-47' )), Vertex(6, Dec('107.938'), guess('104-15-46')), Vertex(21, Dec('104.082'), guess('234-17-37')), Vertex(5, Dec('154.332'), guess('283-30-57')), Vertex(20, Dec('68.972' ), guess('152-15-58')), Vertex(1, Dec('151.531'), guess('101-20-01')), Vertex(4, Dec('179.336'), guess('150-15-41')), ] angle_sum = Dec(0) for v in vertices: angle_sum += v.ang theoretical_angle_sum = Dec(int((len(vertices)-2)*180)) for i, v in enumerate(vertices[1:]): prev = vertices[i] v.dirang = prev.dirang + 180 - v.ang v.dx = Dec(float(prev.len) * cos(float(prev.dirang) * pi/180)) v.dy = Dec(float(prev.len) * sin(float(prev.dirang) * pi/180)) v.coords = Point(prev.coords.acadx + v.dx, prev.coords.acady + v.dy) # 9-kampio krastine D1 D1 = Dec('174.667') + C # Daugiakampio pasukimo kampas (K1) K1 = Dec('13.147') + B # Atstumas iki tikrosios uzliejimo zonos (A1) (0.001 tikslumu) A1 = Dec('67.536') + B circle_radius = float(D1)/2/sin(pi/7)-float(A1) heptagon_area = heptagon(float(D1)).area circle_area = sPoint(0,0).buffer(circle_radius).area # Points is vertice map by id Points = {} for v in vertices: Points[v.point] = v CONTINUOUS = (1,0) DASHDOTX2 = (10,3,2,3) DASHED = (100,20) keliai = { 'A-08': kelias( virsunes=[1,2,3], plotis=A08_plotis, kat=KAT1, dashes=DASHDOTX2, spalva='xkcd:red', juostos=( juosta(L6+L5+L4, 'right', DASHED, 'xkcd:lightgreen'), juosta(L6+L5, 'right', DASHED, 'xkcd:lightgreen'), juosta(L6, 'right', CONTINUOUS, 'xkcd:black'), juosta(L7, 'left', CONTINUOUS, 'xkcd:black'), juosta(L7+L8, 'left', DASHED, 'xkcd:lightgreen'), juosta(L7+L8+L9, 'left', DASHED, 'xkcd:lightgreen'), ), ), 'A-05': kelias( virsunes=[4,5,6,7,8,9,10], plotis=A05_plotis, kat=KAT2, dashes=DASHDOTX2, spalva='xkcd:red', juostos=( juosta(L3, 'right', CONTINUOUS, 'xkcd:brown'), juosta(L2, 'left', CONTINUOUS, 'xkcd:brown'), ), ), 'A-03': kelias( virsunes=[11,12,13,14,15,16,17,18], plotis=A03_plotis, kat=KAT3, dashes=CONTINUOUS, spalva='xkcd:magenta', juostos=( juosta(L1, 'right', DASHED, 'xkcd:magenta'), juosta(0, 'left', DASHED, 'xkcd:white'), ), ), 'G-11': kelias( virsunes=[19,20,21,22,23,24], plotis=G11_plotis, kat=KAT4, dashes=CONTINUOUS, spalva='xkcd:red', juostos=( juosta(L10+L11, 'right', CONTINUOUS, 'xkcd:blue'), juosta(L11, 'right', CONTINUOUS, 'xkcd:lightblue'), juosta(L12, 'left', CONTINUOUS, 'xkcd:lightblue'), juosta(L12+L13, 'left', CONTINUOUS, 'xkcd:blue'), ), ), } keliu_ilgiai = {} for id, kelias in keliai.items(): keliu_ilgiai[id] = LineString([Points[i].xy for i in kelias.virsunes]).length if __name__ == '__main__': print("tšk. nr.\tišmatuotas kampas\tdirekcinis kampas\tilgis\tdx\tdy\tx\ty") for i, v in enumerate(vertices): print("\t".join([ "%d" % v.point, "%s" % str(hms(v.ang)), "%s" % str(hms(v.dirang)), "%.3f" % v.len, "%.3f" % v.dx, "%.3f" % v.dy, "%.3f" % v.coords.acadx, "%.3f" % v.coords.acady, ])) """acad coords for drawing nxt = vertices[0 if i == len(vertices) - 1 else i+1] pts = "%d-%d" % (v.point, nxt.point) draw = "@%.3f<%.4f" % (v.len, normalize(90 - v.dirang)) print("%5s: %19s acadcoords:(%.3f,%.3f)" % \ (pts, draw, v.coords.acadx, v.coords.acady)) """ (""" Kelio A-03 plotis = 17.401 + A = %.3f""" % A03_plotis + """ Kelio A-05 plotis = 13.705 + B = %.3f""" % A05_plotis + """ Kelio A-08 plotis = 29.006 + C = %.3f""" % A08_plotis + """ Griovio G-11 plotis = 14.776 + N = %.3f""" % G11_plotis + """ Prognozuojamo uzliejimo zona, tai taisyklingas 9-kampis 9-kampio krastine D1 = %.3f""" % D1 + """ Daugiakampio pasukimo kampas (K1) (0.0001 laipsnio tikslumu) K1 = %.4f""" % K1 + """ Tikroji uzliejimo zona, tai taisyklingas apskritimas, kurio centras TURI SUTAPTI su daugiakampio centru. Atstumas iki tikrosios uzliejimo zonos (A1) (0.001 tikslumu) A1 = %.3f""" % A1 + """ A-05: x(l) = %.3f""" % (A05_plotis*L3/(L2+L3)) + """ x(r) = %.3f""" % (A05_plotis*L2/(L2+L3)) + """ A-08: x(l) = %.3f""" % (A08_plotis*(L7+L8+L9)/(L7+L8+L9+L6+L5+L4)) + """ x(r) = %.3f""" % (A08_plotis*(L6+L5+L4)/(L7+L8+L9+L6+L5+L4)) + """ G-11: x(l) = %.3f""" % (G11_plotis*(L12+L13)/(L10+L11+L12+L13)) + """ x(r) = %.3f""" % (G11_plotis*(L10+L11)/(L10+L11+L12+L13)) + """ """)