Example #1
0
    def testEastCoastAnneal1(self):
        with open("InterfContour_EastCoast.txt", "r") as myfile:
            data = myfile.readlines()
        esc_loc_x = [x / 1000.0 for x in eval(data[0])]
        esc_loc_y = [x / 1000.0 for x in eval(data[1])]
        ship_loc_x = [x / 1000.0 for x in eval(data[2])]
        ship_loc_y = [x / 1000.0 for x in eval(data[3])]
        centers = []
        for i in range(0, len(esc_loc_x)):
            center = (esc_loc_x[i], esc_loc_y[i])
            centers.append(center)

        interference_contour = []
        for i in range(0, len(ship_loc_x)):
            p = (ship_loc_x[i], ship_loc_y[i])
            interference_contour.append(p)

        testName = "EastCoast"
        min_ctr_dist = 0
        coverage_file = "detection-coverage/ITMDetectionCoverage_60deg.json"
        poly = excessarea.generate_bounding_polygon(centers,
                                                    interference_contour)
        cover = antennacover.min_antenna_area_cover_anneal(
            centers, poly, coverage_file, min_center_distance=min_ctr_dist)
        printcover.printAntennaCover(testName, poly, centers, cover,
                                     coverage_file, min_ctr_dist)
Example #2
0
 def testEstuaryAnneal(self):
     """
     Test simulated annealing.
     """
     interference_contour = [(20, 55), (35, 65), (40, 60), (45, 65),
                             (50, 55)]
     possible_centers = [(20, 46), (25, 30), (30, 20), (40, 15), (50, 30),
                         (60, 50)]
     antennacover.NDIVISIONS = 200
     min_ctr_dist = 0
     coverage_file = "detection-coverage/ITMDetectionCoverage_60deg.json"
     testName = "Estuary"
     poly = excessarea.generate_bounding_polygon(possible_centers,
                                                 interference_contour)
     cover = antennacover.min_antenna_area_cover_greedy(
         possible_centers,
         poly,
         coverage_file,
         min_center_distance=min_ctr_dist)
     printcover.printAntennaCover(testName, poly, possible_centers, cover,
                                  coverage_file, min_ctr_dist)
     annealr = simannealer.SimAnneal(poly, coverage_file, cover)
     annealr.anneal()
     testName = "EstuaryAnneal"
     improved_cover = annealr.get_result()
     printcover.printAntennaCover(testName, poly, possible_centers,
                                  improved_cover, coverage_file,
                                  min_ctr_dist)
Example #3
0
    def testVBAnneal(self):
        # Convert all units to Km
        esc_loc_x = [
            x / 1000.0 for x in [
                1771380, 1769310, 1769790, 1768380, 1767390, 1764690, 1762020,
                1759920, 1753110, 1741950, 1752210, 1757010, 1761870, 1768230,
                1772820, 1777110, 1781610, 1786920, 1793220
            ]
        ]
        esc_loc_y = [
            y / 1000.0 for y in [
                1827030, 1817070, 1806990, 1797090, 1787100, 1776840, 1767270,
                1756950, 1746690, 1735050, 1727220, 1717290, 1707360, 1697370,
                1687320, 1677450, 1667400, 1657350, 1647360
            ]
        ]
        ship_loc_x = [
            x / 1000.0 for x in [
                1847012, 1844913, 1845660, 1834150, 1823280, 1811715, 1807512,
                1806671, 1810710, 1807769, 1817910, 1822503, 1827218, 1823623,
                1828432, 1842183, 1846928, 1852378, 1858591
            ]
        ]
        ship_loc_y = [
            y / 1000.0 for y in [
                1843636, 1833617, 1823583, 1811442, 1799284, 1787072, 1777140,
                1767066, 1759078, 1749183, 1741311, 1731358, 1721401, 1709309,
                1699318, 1691518, 1681523, 1671542, 1661589
            ]
        ]

        centers = []
        for i in range(0, len(esc_loc_x)):
            center = (esc_loc_x[i], esc_loc_y[i])
            centers.append(center)

        interference_contour = []
        for i in range(0, len(ship_loc_x)):
            p = (ship_loc_x[i], ship_loc_y[i])
            interference_contour.append(p)

        testName = "VirginiaBeach"
        min_ctr_dist = 60
        coverage_file = "detection-coverage/ITMDetectionCoverage_60deg.json"
        poly = excessarea.generate_bounding_polygon(centers,
                                                    interference_contour)
        cover = antennacover.min_antenna_area_cover_greedy(
            centers, poly, coverage_file, min_center_distance=min_ctr_dist)
        printcover.printAntennaCover(testName, poly, centers, cover,
                                     coverage_file, min_ctr_dist)
        testName = "VirginiaBeachAnneal"
        annealr = simannealer.SimAnneal(poly, coverage_file, cover)
        annealr.anneal()
        improved_cover = annealr.get_result()
        printcover.printAntennaCover(testName, poly, centers, improved_cover,
                                     coverage_file, min_ctr_dist)
Example #4
0
    def testEstuary(self):
        """
        Test for a deep estuary.
        """
        interference_contour = [(20, 55), (35, 65), (40, 60), (45, 65),
                                (50, 55)]
        centers = [(20, 46), (25, 30), (30, 20), (40, 15), (50, 30), (60, 50)]

        polygon = excessarea.generate_bounding_polygon(centers,
                                                       interference_contour)
        circ = circlecover.min_area_cover_greedy(centers,
                                                 polygon,
                                                 min_center_distance=0)
        testName = "Estuary"
        printcover.printCover(interference_contour, circ, centers, 0, [],
                              testName, AREA_COVER)
        for point in interference_contour:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)

        circ, included = circlecover.min_point_cover_greedy_with_fixed_discs(
            centers, interference_contour, min_center_distance=0)
        printcover.printCover(interference_contour, circ, centers, 0, [],
                              testName, FIXED_RADIUS)
        for point in interference_contour:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)

        circ, included = circlecover.min_line_cover_greedy(
            centers, interference_contour, min_center_distance=0)
        polygon = excessarea.generate_bounding_polygin(centers, line_endpoints)
        printcover.printCover(polygon, circ, centers, 0, [], testName,
                              VAR_RADIUS)
        for point in interference_contour:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)
Example #5
0
    def testSFAnneal(self):
        esc_loc_x = m_to_km([
            -2300850, -2297160, -2284680, -2283390, -2284800, -2289540,
            -2287620, -2287740, -2287620, -2291760, -2289540, -2283720,
            -2279730, -2254320, -2252430, -2253120, -2256900, -2273160,
            -2273970, -2273910
        ])
        esc_loc_y = m_to_km([
            1986840, 1977120, 1966620, 1957680, 1947570, 1937730, 1926720,
            1917720, 1907880, 1897830, 1887360, 1876560, 1867620, 1852470,
            1843620, 1833720, 1824660, 1817640, 1807710, 1797930
        ])
        ship_loc_x = m_to_km([
            -2414875, -2401190, -2405002, -2406089, -2407670, -2402495,
            -2402056, -2400759, -2390693, -2394883, -2393517, -2394351,
            -2393072, -2396507, -2393492, -2394127, -2399780, -2396297,
            -2387368, -2387021
        ])
        ship_loc_y = m_to_km([
            2019979, 2007266, 2001267, 1992909, 1982826, 1970152, 1959565,
            1950068, 1937330, 1927338, 1917048, 1908072, 1899767, 1892623,
            1883306, 1873335, 1864772, 1852304, 1839577, 1829662
        ])

        centers = []
        for i in range(0, len(esc_loc_x)):
            center = (esc_loc_x[i], esc_loc_y[i])
            centers.append(center)
        interference_contour = []
        for i in range(0, len(ship_loc_x)):
            p = (ship_loc_x[i], ship_loc_y[i])
            interference_contour.append(p)

        testName = "SanFrancisco"
        min_ctr_dist = 60
        coverage_file = "detection-coverage/ITMDetectionCoverage_60deg.json"
        poly = excessarea.generate_bounding_polygon(centers, line_endpoints)
        cover = antennacover.min_antenna_area_cover_greedy(
            centers, poly, coverage_file, min_center_distance=min_ctr_dist)
        printcover.printAntennaCover(testName, poly, centers, cover,
                                     coverage_file, min_ctr_dist)
        testName = "SanFranciscoAnneal"
        annealr = simannealer.SimAnneal(poly, coverage_file, cover)
        annealr.anneal()
        improved_cover = annealr.get_result()
        printcover.printAntennaCover(testName, poly, centers, improved_cover,
                                     coverage_file, min_ctr_dist)
Example #6
0
    def testMinimumCircleSetCoverForLineSetGreedy(self):
        print("testMinimumAreaCircleSetCoverForLineSetGreedy")
        line_endpoints = [[20, 80], [50, 70], [60, 60], [80, 50], [60, 40],
                          [80, 30], [100, 30], [90, 20]]
        centers = [(10, 70), (30, 60), (50, 55), (50, 30), (60, 20)]
        testName = "testMinimumCircleSetCoverForLineSetGreedy"
        circ, covered_segments = circlecover.min_line_cover_greedy(
            centers, line_endpoints)
        bp = excessarea.generate_bounding_polygon(line_endpoints, centers)
        printcover.printCover(bp, circ, centers, 0, covered_segments, testName,
                              VAR_RADIUS)
        self.assertTrue(len(circ) == len(covered_segments))
        # check that for every line segment, both endpoints are covered by
        # at least one circle in our solution.
        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)

        # Check if the segments in the cover are distinct subsets.
        for i in range(0, len(covered_segments)):
            for k in range(i + 1, len(covered_segments) - 1):
                for l in covered_segments[i]:
                    for m in covered_segments[k]:
                        self.assertFalse(l == m)

        circ, covered_points = circlecover.min_point_cover_greedy_with_fixed_discs(
            centers, line_endpoints)
        printcover.printCover(bp, circ, centers, 0, covered_segments, testName,
                              FIXED_RADIUS)
        # check that for every line segment, both endpoints are covered by
        # at least one circle in our solution.
        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)
Example #7
0
    def testMinimumCircleSetCoverForLineSetGreedy3(self):
        print("testMinimumCircleSetCoverForLineSetGreedy3")
        line_endpoints = [[20, 80], [50, 70]]
        centers = [(10, 70), (30, 60)]
        polygon_to_cover = excessarea.generate_bounding_polygin(
            centers, line_endpoints)
        circ = circlecover.min_area_cover_greedy(centers, polygon_to_cover)
        # check that for every line segment, both endpoints are covered by
        # at least one circle in our solution.
        testName = "testMinimumCircleSetCoverForLineSetGreedy3"
        bp = excessarea.generate_bounding_polygon(line_endpoints, centers)
        printcover.printCover(bp, circ, centers, 0, [], testName, AREA_COVER)

        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)
Example #8
0
 def testEstuary1(self):
     """
     Test for a deep estuary.
     """
     interference_contour = [(20, 55), (35, 65), (40, 60), (45, 65),
                             (50, 55)]
     possible_centers = [(20, 46), (25, 30), (30, 20), (40, 15), (50, 30),
                         (60, 50)]
     min_ctr_dist = 0
     poly = excessarea.generate_bounding_polygon(possible_centers,
                                                 interference_contour)
     cover = antennacover.min_antenna_area_cover_greedy(
         possible_centers,
         poly,
         "detection-coverage/ITMDetectionCoverage_90deg.json",
         min_center_distance=min_ctr_dist)
     testName = "Estuary"
     printcover.printAntennaCover(
         testName, poly, possible_centers, cover,
         "detection-coverage/ITMDetectionCoverage_90deg.json", min_ctr_dist)
Example #9
0
    def testMinimumCircleSetCoverForLineSetGreedy2(self):
        print("testMinimumCircleSetCoverForLineSetGreedy2")
        line_endpoints = [[20, 80], [50, 70]]
        centers = [(10, 70), (40, 60)]
        savedCentrs = list(centers)
        circ, segments = circlecover.min_line_cover_greedy(
            centers, line_endpoints)
        # check that for every line segment, both endpoints are covered by
        # at least one circle in our solution.
        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)

        testName = "testMinimumCircleSetCoverForLineSetGreedy2"
        bp = excessarea.generate_bounding_polygon(line_endpoints, centers)
        printcover.printCover(bp, circ, savedCentrs, 0, segments, testName,
                              VAR_RADIUS)
Example #10
0
    def testMinimumCircleSetCoverForLineSetGreedyRandom(self):
        print("testMinimumCircleSetCoverForLineSetGreedyRandom")
        line_endpoints = []
        line_segments = []
        random.seed(0)
        start = [100, 100]
        end = [200, 120]

        p1 = start[0]
        nsteps = 200
        for i in range(1, nsteps):
            p2 = random.randint(start[1], end[1])
            line_endpoints.append((p1, p2))
            p1 = start[0] + float(end[0] - start[0]) / float(nsteps) * i

        lineString = LineString(line_endpoints)
        centers = []
        x_coords = [random.randint(100, 200) for i in range(1, 150)]
        sorted_xcoords = sorted(x_coords)

        for p1 in sorted_xcoords:
            p2 = random.randint(90, 100)
            centers.append((p1, p2))

        for i in range(len(line_endpoints) - 1):
            line_segments.append(
                line.Line(line_endpoints[i], line_endpoints[i + 1]))
        circ, included = circlecover.min_line_cover_greedy(
            centers, line_endpoints, min_center_distance=20)
        testName = "LineCoverGreedyRandom"
        bp = excessarea.generate_bounding_polygon(line_endpoints, centers)
        printcover.printCover(bp, circ, centers, 20, included, testName,
                              VAR_RADIUS)

        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)

        u = Polygon()

        for c in circ:
            u = u.union(c.get_geometry())

        self.assertTrue(u.buffer(1).contains(lineString))

        # Check if the segments in the cover are distinct subsets.
        for i in range(0, len(included)):
            for k in range(i + 1, len(included) - 1):
                for l in included[i]:
                    for m in included[k]:
                        self.assertFalse(l == m)

        circ, included = circlecover.min_point_cover_greedy_with_fixed_discs(
            centers, line_endpoints, min_center_distance=20)
        for point in line_endpoints:
            flag = False
            for c in circ:
                if c.inside(point):
                    flag = True
                    break
            self.assertTrue(flag)
        bp = excessarea.generate_bounding_polygon(line_endpoints, centers)
        printcover.printCover(bp, circ, centers, 20, [], testName,
                              FIXED_RADIUS)