'''
Created on 14. des. 2015
@author: pab
'''
import unittest
import numpy as np
from nvector.ngs import Geodesic
#from geographiclib.geodesic import Geodesic
#from geographiclib.geomath import Math
wgs84 = Geodesic(name='WGS84')
[docs]class GeodesicTest(unittest.TestCase):
testcases = [
[35.60777, -139.44815, 111.098748429560326,
-11.17491, -69.95921, 129.289270889708762,
8935244.5604818305, 80.50729714281974, 6273170.2055303837,
0.16606318447386067, 0.16479116945612937, 12841384694976.432],
[55.52454, 106.05087, 22.020059880982801,
77.03196, 197.18234, 109.112041110671519,
4105086.1713924406, 36.892740690445894, 3828869.3344387607,
0.80076349608092607, 0.80101006984201008, 61674961290615.615],
[-21.97856, 142.59065, -32.44456876433189,
41.84138, 98.56635, -41.84359951440466,
8394328.894657671, 75.62930491011522, 6161154.5773110616,
0.24816339233950381, 0.24930251203627892, -6637997720646.717],
[-66.99028, 112.2363, 173.73491240878403,
-12.70631, 285.90344, 2.512956620913668,
11150344.2312080241, 100.278634181155759, 6289939.5670446687,
-0.17199490274700385, -0.17722569526345708, -121287239862139.744],
[-17.42761, 173.34268, -159.033557661192928,
-15.84784, 5.93557, -20.787484651536988,
16076603.1631180673, 144.640108810286253, 3732902.1583877189,
-0.81273638700070476, -0.81299800519154474, 97825992354058.708],
[32.84994, 48.28919, 150.492927788121982,
-56.28556, 202.29132, 48.113449399816759,
16727068.9438164461, 150.565799985466607, 3147838.1910180939,
-0.87334918086923126, -0.86505036767110637, -72445258525585.010],
[6.96833, 52.74123, 92.581585386317712,
-7.39675, 206.17291, 90.721692165923907,
17102477.2496958388, 154.147366239113561, 2772035.6169917581,
-0.89991282520302447, -0.89986892177110739, -1311796973197.995],
[-50.56724, -16.30485, -105.439679907590164,
-33.56571, -94.97412, -47.348547835650331,
6455670.5118668696, 58.083719495371259, 5409150.7979815838,
0.53053508035997263, 0.52988722644436602, 41071447902810.047],
[-58.93002, -8.90775, 140.965397902500679,
-8.91104, 133.13503, 19.255429433416599,
11756066.0219864627, 105.755691241406877, 6151101.2270708536,
-0.26548622269867183, -0.27068483874510741, -86143460552774.735],
[-68.82867, -74.28391, 93.774347763114881,
-50.63005, -8.36685, 34.65564085411343,
3956936.926063544, 35.572254987389284, 3708890.9544062657,
0.81443963736383502, 0.81420859815358342, -41845309450093.787],
[-10.62672, -32.0898, -86.426713286747751,
5.883, -134.31681, -80.473780971034875,
11470869.3864563009, 103.387395634504061, 6184411.6622659713,
-0.23138683500430237, -0.23155097622286792, 4198803992123.548],
[-21.76221, 166.90563, 29.319421206936428,
48.72884, 213.97627, 43.508671946410168,
9098627.3986554915, 81.963476716121964, 6299240.9166992283,
0.13965943368590333, 0.14152969707656796, 10024709850277.476],
[-19.79938, -174.47484, 71.167275780171533,
-11.99349, -154.35109, 65.589099775199228,
2319004.8601169389, 20.896611684802389, 2267960.8703918325,
0.93427001867125849, 0.93424887135032789, -3935477535005.785],
[-11.95887, -116.94513, 92.712619830452549,
4.57352, 7.16501, 78.64960934409585,
13834722.5801401374, 124.688684161089762, 5228093.177931598,
-0.56879356755666463, -0.56918731952397221, -9919582785894.853],
[-87.85331, 85.66836, -65.120313040242748,
66.48646, 16.09921, -4.888658719272296,
17286615.3147144645, 155.58592449699137, 2635887.4729110181,
-0.90697975771398578, -0.91095608883042767, 42667211366919.534],
[1.74708, 128.32011, -101.584843631173858,
-11.16617, 11.87109, -86.325793296437476,
12942901.1241347408, 116.650512484301857, 5682744.8413270572,
-0.44857868222697644, -0.44824490340007729, 10763055294345.653],
[-25.72959, -144.90758, -153.647468693117198,
-57.70581, -269.17879, -48.343983158876487,
9413446.7452453107, 84.664533838404295, 6356176.6898881281,
0.09492245755254703, 0.09737058264766572, 74515122850712.444],
[-41.22777, 122.32875, 14.285113402275739,
-7.57291, 130.37946, 10.805303085187369,
3812686.035106021, 34.34330804743883, 3588703.8812128856,
0.82605222593217889, 0.82572158200920196, -2456961531057.857],
[11.01307, 138.25278, 79.43682622782374,
6.62726, 247.05981, 103.708090215522657,
11911190.819018408, 107.341669954114577, 6070904.722786735,
-0.29767608923657404, -0.29785143390252321, 17121631423099.696],
[-29.47124, 95.14681, -163.779130441688382,
-27.46601, -69.15955, -15.909335945554969,
13487015.8381145492, 121.294026715742277, 5481428.9945736388,
-0.51527225545373252, -0.51556587964721788, 104679964020340.318]]
[docs] def test_inverse(self):
for l in GeodesicTest.testcases:
lat1, lon1, azi1, lat2, lon2, azi2 = np.deg2rad(l[:6])
s12, a12, m12, M12, M21, S12 = l[6:]
inv = wgs84.inverse(lat1, lon1, lat2, lon2)
s122, faz, baz, a122= inv[:4]
baz = np.mod(baz+np.pi*2, np.pi*2) - np.pi
# self.assertAlmostEqual(lon2, inv["lon2"], delta=1e-13)
self.assertAlmostEqual(azi1, faz, delta=1e-10)
self.assertAlmostEqual(azi2, baz, delta=1e-10)
self.assertAlmostEqual(s12, s122, delta=1e-3)
self.assertAlmostEqual(a12, np.rad2deg(a122), delta=1e-7)
#self.assertAlmostEqual(m12, inv["m12"], delta=1e-8)
#self.assertAlmostEqual(M12, inv["M12"], delta=1e-15)
#self.assertAlmostEqual(M21, inv["M21"], delta=1e-15)
#self.assertAlmostEqual(S12, inv["S12"], delta=0.1)
[docs] def test_direct(self):
wgs84 = Geodesic(name='WGS84')
for l in GeodesicTest.testcases:
lat1, lon1, azi1, lat2, lon2, azi2 = np.deg2rad(l[:6])
lon2 = np.mod(lon2+np.pi, np.pi*2)-np.pi
s12, a12, m12, M12, M21, S12 = l[6:]
lat22, lon22, az22 = wgs84.direct(lat1, lon1, azi1, s12)
self.assertAlmostEqual(lat2, lat22, delta=1e-10)
self.assertAlmostEqual(lon2, lon22, delta=1e-10)
self.assertAlmostEqual(azi2, az22-np.pi, delta=1e-10)
#self.assertAlmostEqual(a12, dir["a12"], delta=1e-13)
#self.assertAlmostEqual(m12, dir["m12"], delta=1e-8)
#self.assertAlmostEqual(M12, dir["M12"], delta=1e-15)
#self.assertAlmostEqual(M21, dir["M21"], delta=1e-15)
#self.assertAlmostEqual(S12, dir["S12"], delta=0.1)
[docs]class GeodSolveTest(unittest.TestCase):
[docs] def test_GeodSolve0(self):
lat1, lon1, lat2, lon2 = np.deg2rad([40.6, -73.8, 49.01666667, 2.55])
s12, azi1, azi2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
azi2 = np.mod(azi2+np.pi*2, np.pi*2) - np.pi
self.assertAlmostEqual(np.rad2deg(azi1), 53.47022, delta=0.5e-5)
self.assertAlmostEqual(np.rad2deg(azi2), 111.59367, delta=0.5e-5)
self.assertAlmostEqual(s12, 5853226, delta=0.5)
[docs] def test_GeodSolve1(self):
lat1, lon1, az1 = np.deg2rad([40.63972222, -73.77888889, 53.5])
dir = wgs84.direct(lat1, lon1, az1, 5850e3)
lat2, lon2, az2 = np.rad2deg(dir)
az2 = np.mod(az2+360, 360)-180
self.assertAlmostEqual(lat2, 49.01467, delta=0.5e-5)
self.assertAlmostEqual(lon2, 2.56106, delta=0.5e-5)
self.assertAlmostEqual(az2, 111.62947, delta=0.5e-5)
[docs] def test_GeodSolve2(self):
# Check fix for antipodal prolate bug found 2010-09-04
geod = Geodesic(6.4e6, -1/150.0)
lat1, lon1, lat2, lon2 = np.deg2rad((0.07476, 0, -0.07476, 180))
s12, az1, az2 = geod.inverse(lat1, lon1, lat2, lon2)[:3]
az1, az2 = np.rad2deg((az1, az2))
az2 = np.mod(az2+360, 360)-180
self.assertAlmostEqual(az1, 90.00078, delta=0.5e-5)
self.assertAlmostEqual(az2, 90.00078, delta=0.5e-5)
self.assertAlmostEqual(s12, 20106193, delta=0.5)
lat1, lon1, lat2, lon2 = np.deg2rad((0.1, 0, -0.1, 180))
s12, az1, az2 = geod.inverse(lat1, lon1, lat2, lon2)[:3]
az1, az2 = np.rad2deg((az1, az2))
az2 = np.mod(az2+360, 360)-180
self.assertAlmostEqual(az1, 90.00105, delta=0.5e-5)
self.assertAlmostEqual(az2, 90.00105, delta=0.5e-5)
self.assertAlmostEqual(s12, 20106193, delta=0.5)
[docs] def test_GeodSolve4(self):
# Check fix for short line bug found 2010-05-21
lat1, lon1, lat2, lon2 = np.deg2rad((36.493349428792, 0,
36.49334942879201, .0000008))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 0.072, delta=0.5e-3)
[docs] def test_GeodSolve5(self):
# Check fix for point2=pole bug found 2010-05-03
lat1, lon1, az1 = np.deg2rad([0.01777745589997, 30, 0])
dir = wgs84.direct(lat1, lon1, az1, 10e6)
lat2, lon2, az2 = np.rad2deg(dir)
az2 = np.mod(az2+360, 360)-180
#dir = wgs84.direct(0.01777745589997, 30, 0, 10e6)
self.assertAlmostEqual(lat2, 90, delta=0.5e-5)
if lon2 < 0:
self.assertAlmostEqual(lon2, -150, delta=0.5e-5)
self.assertAlmostEqual(az2, -180, delta=0.5e-5)
else:
self.assertAlmostEqual(lon2, 30, delta=0.5e-5)
self.assertAlmostEqual(az2, 0, delta=0.5e-5)
[docs] def test_GeodSolve6(self):
# Check fix for volatile sbet12a bug found 2011-06-25 (gcc 4.4.4
# x86 -O3). Found again on 2012-03-27 with tdm-mingw32 (g++ 4.6.1).
lat1, lon1, lat2, lon2 = np.deg2rad((88.202499451857, 0,
-88.202499451857, 179.981022032992859592))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 20003898.214, delta=0.5e-3)
lat1, lon1, lat2, lon2 = np.deg2rad((89.262080389218, 0,
-89.262080389218, 179.992207982775375662))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 20003925.854, delta=0.5e-3)
lat1, lon1, lat2, lon2 = np.deg2rad((89.333123580033, 0,
-89.333123580032997687,
179.99295812360148422))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 20003926.881, delta=0.5e-3)
[docs] def test_GeodSolve9(self):
# Check fix for volatile x bug found 2011-06-25 (gcc 4.4.4 x86 -O3)
lat1, lon1, lat2, lon2 = np.deg2rad((56.320923501171, 0,
-56.320923501171, 179.664747671772880215))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 19993558.287, delta=0.5e-3)
[docs] def test_GeodSolve10(self):
# Check fix for adjust tol1_ bug found 2011-06-25 (Visual Studio
# 10 rel + debug)
lat1, lon1, lat2, lon2 = np.deg2rad((52.784459512564, 0,
-52.784459512563990912,
179.634407464943777557))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 19991596.095, delta=0.5e-3)
[docs] def test_GeodSolve11(self):
# Check fix for bet2 = -bet1 bug found 2011-06-25 (Visual Studio
# 10 rel + debug)
lat1, lon1, lat2, lon2 = np.deg2rad((48.522876735459, 0,
-48.52287673545898293,
179.599720456223079643))
s12, az1, az2 = wgs84.inverse(lat1, lon1, lat2, lon2)[:3]
self.assertAlmostEqual(s12, 19989144.774, delta=0.5e-3)
[docs] def test_GeodSolve12(self):
# Check fix for inverse geodesics on extreme prolate/oblate
# ellipsoids Reported 2012-08-29 Stefan Guenther
# <stefan.gunther@embl.de>; fixed 2012-10-07
geod = Geodesic(89.8, -1.83)
s12, az1, az2 = geod.inverse(0, 0, np.deg2rad(-10), np.deg2rad(160))[:3]
az1, az2 = np.rad2deg((az1, az2))
self.assertAlmostEqual(az1, 120.27, delta=1e-2)
self.assertAlmostEqual(az2, 105.15, delta=1e-2)
self.assertAlmostEqual(s12, 266.7, delta=1e-1)
[docs] def test_GeodSolve14(self):
# Check fix for inverse ignoring lon12 = nan
s12, az1, az2 = wgs84.inverse(0, 0, 1, np.nan)[:3]
self.assertTrue(np.isnan(az1))
self.assertTrue(np.isnan(az2))
self.assertTrue(np.isnan(s12))
# def test_GeodSolve15(self):
# # Initial implementation of Math::eatanhe was wrong for e^2 < 0. This
# # checks that this is fixed.
# geod = Geodesic(6.4e6, -1/150.0)
# dir = geod.direct(1, 2, 3, 4, Geodesic.AREA)
# self.assertAlmostEqual(dir["S12"], 23700, delta=0.5)
#
# def test_GeodSolve17(self):
# Check fix for LONG_UNROLL bug found on 2015-05-07
#
# dir = wgs84.direct(40, -75, -10, 2e7)
# self.assertAlmostEqual(lat2, -39, delta=1)
# self.assertAlmostEqual(lon2, -254, delta=1)
# self.assertAlmostEqual(az2, -170, delta=1)
# line = Geodesic.WGS84.Line(40, -75, -10)
# dir = line.Position(2e7, Geodesic.STANDARD | Geodesic.LONG_UNROLL)
# self.assertAlmostEqual(lat2, -39, delta=1)
# self.assertAlmostEqual(lon2, -254, delta=1)
# self.assertAlmostEqual(az2, -170, delta=1)
# dir = wgs84.direct(40, -75, -10, 2e7)
# self.assertAlmostEqual(lat2, -39, delta=1)
# self.assertAlmostEqual(lon2, 105, delta=1)
# self.assertAlmostEqual(az2, -170, delta=1)
# dir = line.Position(2e7)
# self.assertAlmostEqual(lat2, -39, delta=1)
# self.assertAlmostEqual(lon2, 105, delta=1)
# self.assertAlmostEqual(az2, -170, delta=1)
# #
# def test_GeodSolve26(self):
# # Check 0/0 problem with area calculation on sphere 2015-09-08
# geod = Geodesic(6.4e6, 0)
# inv = geod.Inverse(1, 2, 3, 4, Geodesic.AREA)
# self.assertAlmostEqual(inv["S12"], 49911046115.0, delta=0.5)
#
# def test_GeodSolve28(self):
# # Check for bad placement of assignment of r.a12 with |f| > 0.01 (bug in
# # Java implementation fixed on 2015-05-19).
# geod = Geodesic(6.4e6, 0.1)
# dir = geod.Direct(1, 2, 10, 5e6)
# self.assertAlmostEqual(dir["a12"], 48.55570690, delta=0.5e-8)
#
# def test_GeodSolve29(self):
# # Check longitude unrolling with inverse calculation 2015-09-16
# dir = wgs84.inverse(0, 539, 0, 181)
# self.assertAlmostEqual(dir["lon1"], 179, delta=1e-10)
# self.assertAlmostEqual(lon2, -179, delta=1e-10)
# self.assertAlmostEqual(dir["s12"], 222639, delta=0.5)
# dir = wgs84.inverse(0, 539, 0, 181,
# Geodesic.STANDARD | Geodesic.LONG_UNROLL)
# self.assertAlmostEqual(dir["lon1"], 539, delta=1e-10)
# self.assertAlmostEqual(lon2, 541, delta=1e-10)
# self.assertAlmostEqual(dir["s12"], 222639, delta=0.5)
#
[docs] def test_GeodSolve33(self):
# Check max(-0.0,+0.0) issues 2015-08-22 (triggered by bugs in
# Octave -- sind(-0.0) = +0.0 -- and in some version of Visual
# Studio -- fmod(-0.0, 360.0) = +0.0.
s12, az1, az2 = wgs84.inverse(0, 0, 0, np.deg2rad(179))[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -90.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 19926189, delta=0.5)
s12, az1, az2 = wgs84.inverse(0, 0, 0, np.deg2rad(179.5))[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 55.96650, delta=0.5e-4)
self.assertAlmostEqual(az2, -55.96649514, delta=0.5e-5)
self.assertAlmostEqual(s12, 19980862, delta=0.5)
s12, az1, az2 = wgs84.inverse(0, 0, 0, 180)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 0.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -180.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 20003931, delta=0.5)
s12, az1, az2 = wgs84.inverse(0, 0, np.deg2rad(1), np.deg2rad(180))
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 0.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -180.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 19893357, delta=0.5)
geod = Geodesic(6.4e6, 0)
s12, az1, az2 = geod.inverse(0, 0, 0, np.deg2rad(179))[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 19994492, delta=0.5)
s12, az1, az2 = geod.inverse(0, 0, 0, np.pi)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 0.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -180.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 20106193, delta=0.5)
s12, az1, az2 = geod.inverse(0, 0, np.deg2rad(1), np.pi)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 0.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -180.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 19994492, delta=0.5)
geod = Geodesic(6.4e6, -1/300.0)
s12, az1, az2 = geod.inverse(0, 0, 0, np.deg2rad(179))[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 19994492, delta=0.5)
s12, az1, az2 = geod.inverse(0, 0, 0, np.pi)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, 90.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 20106193, delta=0.5)
s12, az1, az2 = geod.inverse(0, 0, np.deg2rad(0.5), np.pi)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 33.02493, delta=0.5e-5)
self.assertAlmostEqual(az2, 146.97364, delta=0.5e-5)
self.assertAlmostEqual(s12, 20082617, delta=0.5)
s12, az1, az2 = geod.Inverse(0, 0, np.deg2rad(1), np.pi)[:3]
az1, az2 = np.rad2deg([az1, az2])
self.assertAlmostEqual(az1, 0.00000, delta=0.5e-5)
self.assertAlmostEqual(az2, -180.00000, delta=0.5e-5)
self.assertAlmostEqual(s12, 20027270, delta=0.5);
#
# def test_GeodSolve55(self):
# # Check fix for nan + point on equator or pole not returning all nans in
# # Geodesic::Inverse, found 2015-09-23.
# inv = wgs84.inverse(np.nan, 0, 0, 90)
# self.assertTrue(np.isnan(az1))
# self.assertTrue(np.isnan(az2))
# self.assertTrue(np.isnan(s12))
# inv = wgs84.inverse(np.nan, 0, 90, 9)
# self.assertTrue(np.isnan(az1))
# self.assertTrue(np.isnan(az2))
# self.assertTrue(np.isnan(s12))
if __name__ == "__main__":
#import sys;sys.argv = ['', 'Test.testName']
unittest.main()