2020-12-14 16:09:54 +02:00
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#!/usr/bin/python3
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import csv
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2020-12-16 17:57:53 +02:00
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from math import degrees, radians, tan, pi, log
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2020-12-14 16:09:54 +02:00
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from shapely.geometry import LineString
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import matplotlib.pyplot as plt
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phi_p, phi_s, dphi = 13, 49, 6
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lambda_v, lambda_r, dlambda = 0, 24, 6
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M = 25e6
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2020-12-16 17:57:53 +02:00
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phil = round((phi_p+phi_s)/2)
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nphi = int((phi_s-phi_p)/dphi)+1
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nlambda = int((lambda_r-lambda_v)/dlambda)+1
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2020-12-14 16:09:54 +02:00
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# label orientations
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W, E, N, S = (-25, -5), (10, -5), (-5, 10), (-5, -20)
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krasovskio = {}
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with open("krasovskio.csv") as f:
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for row in csv.DictReader(f):
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krasovskio[float(row['phi'])] = row
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2020-12-16 17:57:53 +02:00
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betamm = float(krasovskio[phil]["r"]) * 1000 / M
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2020-12-14 16:09:54 +02:00
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points = []
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for i in range(nphi):
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phid = phi_p + i*dphi
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2020-12-16 17:57:53 +02:00
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phi = radians(phid)
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U = tan(pi/4 + phi/2)
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xmm = betamm * log(U)
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2020-12-14 16:09:54 +02:00
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on_y = []
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for j in range(nlambda):
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lambdad = lambda_v + j*dlambda
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ymm = betamm * lambdad / degrees(1)
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on_y.append((ymm, xmm))
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points.append(on_y)
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fig, ax = plt.subplots()
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ax.set_aspect('equal')
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ax.axis("off")
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def annotate(ax, nr, point, heading):
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text = "{}°".format(nr)
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ax.annotate(text, point, textcoords="offset points", xytext=heading)
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# abscises
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for i in range(nphi):
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row = [points[i][j] for j in range(nlambda)]
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ax.plot(*(LineString(row).xy), color="xkcd:black", linewidth=.5)
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annotate(ax, phi_p+i*dphi, row[0], W)
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annotate(ax, phi_p+i*dphi, row[-1], E)
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# ordinates
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for i in range(nlambda):
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col = [points[j][i] for j in range(nphi)]
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ax.plot(*(LineString(col).xy), color="xkcd:black", linewidth=.5)
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annotate(ax, lambda_v+i*dlambda, col[0], S)
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annotate(ax, lambda_v+i*dlambda, col[-1], N)
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if __name__ == '__main__':
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plt.show()
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