Beispiel #1
0
 def testPosition(self):
     pos = czml.Position()
     now = datetime.now()
     pos.epoch = now
     coords = [7.0, 0.0, 1.0, 2.0, 6.0, 3.0, 4.0, 5.0]
     pos.cartographicRadians = coords
     self.assertEqual(pos.data()['cartographicRadians'],
         coords)
     js = {'epoch': now.isoformat(), 'cartographicRadians': coords}
     self.assertEqual(pos.data(), js)
     self.assertEqual(pos.dumps(), json.dumps(js))
     pos.cartographicDegrees = coords
     self.assertEqual(pos.data()['cartographicDegrees'],
         coords)
     pos.cartesian = coords
     self.assertEqual(pos.data()['cartesian'],
         coords)
     pos2 = czml.Position()
     pos2.loads(pos.dumps())
     self.assertEqual(pos.data(), pos2.data())
Beispiel #2
0
def _filter_users_criteria(filters):
    try:
        users = db.session.query(Users.userid, Users.userpos,
                                 func.length(Users.userpos),
                                 func.twAvg(func.speed(Users.userpos))).filter(
                                     *filters, ).all()
    except:
        traceback.print_exc()
        return jsonify({"errors": [DATA_UNINITIALIZED_ERROR]}), 400

    # Import the library
    from czml import czml

    # Initialize a document
    doc = czml.CZML()

    # Create and append the document packet
    packet1 = czml.CZMLPacket(id='document', version='1.0')
    doc.packets.append(packet1)

    # Create and append a POINT packet
    packet3 = czml.CZMLPacket()

    for user_id, user, distance, speed in users:
        packet3.id = user_id
        pp = czml.Point()
        pp.color = {'rgba': [0, 255, 127, 55]}
        pp.outlineColor = {'rgba': [255, 0, 0, 128]}

        #varPos = czml.Position(cartographicDegrees=[2020-06-04T16:00:00Z,-56.189652081027,-34.8888227843656,0,2020-06-04T16:05:00Z,-56.189652081027,-34.8888227843656,0])
        pos = czml.Position()
        #coords = ['2020-06-04T16:00:00Z','-56.189652081027','-34.8888227843656','0','2020-06-04T16:05:00Z','-56.189652081027','-34.8888227843656','0']

        coords = serialize_trajectory(user)
        pos.epoch = coords['epoch']
        pos.cartographicDegrees = coords['cartographicDegrees']

        #varPos.cartographicDegrees = [2020-06-04T16:00:00Z,-56.189652081027,-34.8888227843656,0,2020-06-04T16:05:00Z,-56.189652081027,-34.8888227843656,0]

        #trayectoria = Path(pos,pp)
        packet3.position = pos
        packet3.point = pp

        #Path(pos, pp)

        #packet3.path = trayectoria
        #pp.Position = Position(varPos)
        doc.packets.append(packet3)

    # Write the CZML document to a file
    filename = "example.czml"
    doc.write(filename)

    return jsonify({
        "users": [{
            "id": user_id,
            "trajectory": serialize_trajectory(user),
            "distance": distance,
            "speed": speed,
        } for user_id, user, distance, speed in users]
    })
Beispiel #3
0
for segment in segments:
    points_db.append(segment.points)
    for point in segment.points:
        flat_points.append(point)
    coordinates.append(current_time)
    coordinates.append(segment.lat)
    coordinates.append(segment.long)
    coordinates.append(0)
    current_time += datetime.timedelta(minutes=180)
#

#
packet = czml.CZMLPacket(id=f"train", status="moving")
positions = czml.Positions(cartographicDegrees=flat_points)

packet.position = czml.Position(cartographicDegrees=coordinates)
print((points_db[0][-1], points_db[0][-2], 0))
print(points_db[0])
bb = czml.Billboard(scale=0.1, show=True)
bb.image = "https://terriamap.iorama.geosynergy.com.au/train_express.png"
bb.color = {'rgba': [255, 255, 255, 255]}
packet.billboard = bb

doc.packets.append(packet)
for index, rail in enumerate(payload):
    #  rail = segment.rail
    positions = multilinestring_to_positions(rail, False, index)

    packet = czml.CZMLPacket(
        id=rail['segment'].lower().replace(' ', ""),
        status="t")  #id=str(random.randint(0, 99999)), name=rail['segment'])
Beispiel #4
0
    def testCZMLPacket(self):
        p = czml.CZMLPacket(id='abc')
        self.assertEqual(p.dumps(), '{"id": "abc"}')
        bb = czml.Billboard()
        bb.image = 'http://localhost/img.png'
        bb.scale = 0.7
        bb.show = True
        p.billboard = bb
        self.assertEqual(p.data(),
            {'billboard': {'image': 'http://localhost/img.png',
            'scale': 0.7, 'show': True}, 'id': 'abc'})
        p2 = czml.CZMLPacket(id='abc')
        p2.loads(p.dumps())
        self.assertEqual(p.data(), p2.data())
        pos = czml.Position()
        coords = [7.0, 0.0, 1.0, 2.0, 6.0, 3.0, 4.0, 5.0]
        pos.cartesian = coords
        p.position = pos
        l = czml.Label()
        l.text = 'test label'
        l.show = False
        p.label = l
        self.assertEqual(p.data(),
            {'billboard': {'image': 'http://localhost/img.png',
            'scale': 0.7, 'show': True}, 'id': 'abc',
            'label': {'show': False, 'text': 'test label'},
            'position': {'cartesian': [7.0, 0.0, 1.0, 2.0, 6.0, 3.0, 4.0, 5.0]},
            })
        p2.loads(p.dumps())
        self.assertEqual(p.data(), p2.data())
        p3 = czml.CZMLPacket(id='cde')
        p3.point = {'color':
                    {'rgba': [0, 255, 127, 55]},
                    'show': True}
        self.assertEqual(p3.data(), {'id': 'cde',
                                    'point': {'color':
                                        {'rgba': [0, 255, 127, 55]},
                                        'show': True}})
        p32 = czml.CZMLPacket(id='abc')
        p32.loads(p3.dumps())
        self.assertEqual(p3.data(), p32.data())
        p4 = czml.CZMLPacket(id='defg')

        pl = czml.Polyline()
        pl.color = {'rgba': [0, 255, 127, 55]}
        pl.width = 10
        pl.outlineWidth = 2
        pl.show = True
        v = czml.VertexPositions()
        v.cartographicDegrees = [0.0, 0.0, .0, 1.0, 1.0, 1.0]
        p4.vertexPositions = v
        p4.polyline = pl
        self.assertEqual(p4.data(),
             {'polyline':
                {'color': {'rgba': [0, 255, 127, 55]},
                'width': 10,
                'outlineWidth': 2,
                'show': True},
            'id': 'defg',
            'vertexPositions':
                {'cartographicDegrees':
                    [0.0, 0.0, 0.0, 1.0, 1.0, 1.0]}
            })
        p42 = czml.CZMLPacket(id='abc')
        p42.loads(p4.dumps())
        self.assertEqual(p4.data(), p42.data())
        p5 = czml.CZMLPacket(id='efgh')
        p5.vertexPositions = v
        poly = czml.Polygon(color={'rgba': [0, 255, 127, 55]})
        p5.polygon = poly
        self.assertEqual(p5.data(),
            {'polygon':
                {'material':
                    {'solidColor':
                        {'color':
                            {'rgba': [0, 255, 127, 55]}}}},
                    'id': 'efgh',
                    'vertexPositions':
                        {'cartographicDegrees':
                            [0.0, 0.0, 0.0, 1.0, 1.0, 1.0]}})
        p52 = czml.CZMLPacket(id='abc')
        p52.loads(p5.dumps())
        self.assertEqual(p5.data(), p52.data())
        return p
Beispiel #5
0
    def testPath(self):

        # Create a new path
        sc = czml.SolidColor(color={'rgba': [0, 255, 127, 55]})
        m1 = czml.Material(solidColor=sc)
        c1 = [0, -62, 141, 0, 2, -51, 143, 0, 4, -40, 145, 0]
        v1 = czml.Position(cartographicDegrees=c1)
        p1 = czml.Path(show=True,
                       width=5,
                       leadTime=2,
                       trailTime=6,
                       resolution=3,
                       material=m1,
                       position=v1)
        self.assertEqual(
            p1.data(), {
                'show': True,
                'width': 5,
                'leadTime': 2,
                'trailTime': 6,
                'resolution': 3,
                'material': {
                    'solidColor': {
                        'color': {
                            'rgba': [0, 255, 127, 55]
                        }
                    },
                },
                'position': {
                    'cartographicDegrees':
                    [0, -62, 141, 0, 2, -51, 143, 0, 4, -40, 145, 0]
                },
            })

        # Create a new path from an existing path
        p2 = czml.Path()
        p2.loads(p1.dumps())
        self.assertEqual(p2.data(), p1.data())

        # Modify an existing path
        po = czml.PolylineOutline(color={'rgba': [0, 255, 127, 55]},
                                  outlineColor={'rgba': [0, 55, 127, 255]},
                                  outlineWidth=4)
        m2 = czml.Material(polylineOutline=po)
        c2 = [0, 1000, 7500, 90, 4, 2000, 6500, 50, 8, 3000, 5500, 20]
        v2 = czml.Position(cartesian=c2)
        p2.show = False
        p2.material = m2
        p2.position = v2
        self.assertEqual(
            p2.data(), {
                'show': False,
                'width': 5,
                'leadTime': 2,
                'trailTime': 6,
                'resolution': 3,
                'material': {
                    'polylineOutline': {
                        'color': {
                            'rgba': [0, 255, 127, 55]
                        },
                        'outlineColor': {
                            'rgba': [0, 55, 127, 255]
                        },
                        'outlineWidth': 4
                    },
                },
                'position': {
                    'cartesian':
                    [0, 1000, 7500, 90, 4, 2000, 6500, 50, 8, 3000, 5500, 20]
                },
            })

        # Add a path to a CZML packet
        packet = czml.CZMLPacket(id='abc')
        packet.path = p2
        self.assertEqual(
            packet.data(), {
                'id': 'abc',
                'path': {
                    'show': False,
                    'width': 5,
                    'leadTime': 2,
                    'trailTime': 6,
                    'resolution': 3,
                    'material': {
                        'polylineOutline': {
                            'color': {
                                'rgba': [0, 255, 127, 55]
                            },
                            'outlineColor': {
                                'rgba': [0, 55, 127, 255]
                            },
                            'outlineWidth': 4
                        },
                    },
                    'position': {
                        'cartesian': [
                            0, 1000, 7500, 90, 4, 2000, 6500, 50, 8, 3000,
                            5500, 20
                        ]
                    },
                },
            })
Beispiel #6
0
    def testEllipse(self):

        # Create a new ellipse
        sc = czml.SolidColor(color={'rgba': [127, 127, 127, 255]})
        mat1 = czml.Material(solidColor=sc)
        pts1 = [50, 20, 2]
        pos1 = czml.Position(cartographicDegrees=pts1)
        ell1 = czml.Ellipse(show=True,
                            fill=True,
                            height=50,
                            extrudedHeight=200,
                            outline=True,
                            outlineColor={'rgba': [0, 255, 127, 55]},
                            semiMajorAxis=150,
                            semiMinorAxis=75,
                            numberOfVerticalLines=800,
                            rotation=1.2,
                            material=mat1,
                            position=pos1)

        self.assertEqual(
            ell1.data(), {
                'show': True,
                'fill': True,
                'outline': True,
                'height': 50,
                'extrudedHeight': 200,
                'rotation': 1.2,
                'semiMajorAxis': 150,
                'semiMinorAxis': 75,
                'numberOfVerticalLines': 800,
                'outlineColor': {
                    'rgba': [0, 255, 127, 55]
                },
                'material': {
                    'solidColor': {
                        'color': {
                            'rgba': [127, 127, 127, 255]
                        }
                    },
                },
                'position': {
                    'cartographicDegrees': [50, 20, 2]
                },
            })

        # Create a new ellipse from an existing ellipse
        ell2 = czml.Ellipse()
        ell2.loads(ell1.dumps())
        self.assertEqual(ell2.data(), ell1.data())

        # Modify an existing ellipse
        strp = czml.Stripe(evenColor={'rgba': [127, 55, 255, 255]},
                           oddColor={'rgba': [127, 255, 55, 127]},
                           offset=1.3,
                           repeat=64,
                           orientation='VERTICAL')
        mat2 = czml.Material(stripe=strp)
        pts2 = [0, 1.5, 1.2, 0, 2, 1.6, 1.3, 0, 4, 1.5, 1.3, 0, 6, 1.6, 1.2, 0]
        pos2 = czml.Position(cartographicRadians=pts2)
        ell2.material = mat2
        ell2.position = pos2
        ell2.perPositionHeight = False
        ell2.height = 7
        ell2.extrudedHeight = 30
        ell2.semiMajorAxis = 600
        ell2.semiMinorAxis = 400
        self.assertEqual(
            ell2.data(), {
                'show': True,
                'fill': True,
                'outline': True,
                'height': 7,
                'extrudedHeight': 30,
                'rotation': 1.2,
                'semiMajorAxis': 600,
                'semiMinorAxis': 400,
                'numberOfVerticalLines': 800,
                'outlineColor': {
                    'rgba': [0, 255, 127, 55]
                },
                'material': {
                    'stripe': {
                        'evenColor': {
                            'rgba': [127, 55, 255, 255]
                        },
                        'oddColor': {
                            'rgba': [127, 255, 55, 127]
                        },
                        'offset': 1.3,
                        'repeat': 64,
                        'orientation': 'VERTICAL'
                    },
                },
                'position': {
                    'cartographicRadians': [
                        0, 1.5, 1.2, 0, 2, 1.6, 1.3, 0, 4, 1.5, 1.3, 0, 6, 1.6,
                        1.2, 0
                    ]
                },
            })

        # Add an ellipse to a CZML packet
        packet = czml.CZMLPacket(id='abc')
        packet.ellipse = ell2
        self.assertEqual(
            packet.data(), {
                'id': 'abc',
                'ellipse': {
                    'show': True,
                    'fill': True,
                    'outline': True,
                    'height': 7,
                    'extrudedHeight': 30,
                    'rotation': 1.2,
                    'semiMajorAxis': 600,
                    'semiMinorAxis': 400,
                    'numberOfVerticalLines': 800,
                    'outlineColor': {
                        'rgba': [0, 255, 127, 55]
                    },
                    'material': {
                        'stripe': {
                            'evenColor': {
                                'rgba': [127, 55, 255, 255]
                            },
                            'oddColor': {
                                'rgba': [127, 255, 55, 127]
                            },
                            'offset': 1.3,
                            'repeat': 64,
                            'orientation': 'VERTICAL'
                        },
                    },
                    'position': {
                        'cartographicRadians': [
                            0, 1.5, 1.2, 0, 2, 1.6, 1.3, 0, 4, 1.5, 1.3, 0, 6,
                            1.6, 1.2, 0
                        ]
                    },
                },
            })
Beispiel #7
0
    def czml(self):

        doc = czml.CZML();
        iso = self.date.isoformat()

        # Generate time-specific lists for various objects
        central_polyline_degrees = []
        north_polyline_degrees = []
        south_polyline_degrees = []
        ellipse_position = []
        ellipse_semiMajorAxis = []
        ellipse_semiMinorAxis = []
        ellipse_rotation = []

        for t in range(len(self.time)):

            time = iso + "T" + self.time[t] + ":00Z"

            # Define polyline waypoints only where data exist
            if self.position['north'][t] != None:
                north_polyline_degrees += [self.position['north'][t][0], self.position['north'][t][1], 0.0]
            if self.position['central'][t] != None:
                central_polyline_degrees += [self.position['central'][t][0], self.position['central'][t][1], 0.0]
            if self.position['south'][t] != None:
                south_polyline_degrees += [self.position['south'][t][0], self.position['south'][t][1], 0.0]

            # Define ellipse positions and attributes for every time in the interval, using limits where necessary
            use_limit = min(int(math.floor(t/(len(self.time)/2))),1)
            if self.position['north'][t] == None:
                north = self.limits['north'][use_limit]
            else:
                north = self.position['north'][t]
            if self.position['central'][t] == None:
                central = self.limits['central'][use_limit]
            else:
                central = self.position['central'][t]
            if self.position['south'][t] == None:
                south = self.limits['south'][use_limit]
            else:
                south = self.position['south'][t]

            # Approximate ellipse semiMajorAxis from vincenty distance between limit polylines
            north2 = (north[1], north[0])
            south2 = (south[1], south[0])
            semi_major_axis = vincenty(north2, south2).meters / 2

            # Approximate elipse semiMinorAxis from sun altitude (probably way wrong!)
            ellipse_axis_ratio = self.sun_altitude[t] / 90
            semi_minor_axis = semi_major_axis * ellipse_axis_ratio

            # Approximate ellipse rotation using basic spheroid (TODO: replace with WGS-84)
            # Calculate bearing in both directions and average them
            nlat = north[1]/180 * math.pi;
            nlon = north[0]/180 * math.pi;
            clat = central[1]/180 * math.pi;
            clon = central[0]/180 * math.pi;
            slat = south[1]/180 * math.pi;
            slon = south[0]/180 * math.pi;

            y = math.sin(slon-nlon) * math.cos(slat);
            x = math.cos(nlat) * math.sin(slat) - math.sin(nlat) * math.cos(slat) * math.cos(slon-nlon);
            initial_bearing = math.atan2(y, x)
            if (initial_bearing < 0):
                initial_bearing += math.pi * 2

            y = math.sin(nlon-slon) * math.cos(nlat);
            x = math.cos(slat) * math.sin(nlat) - math.sin(slat) * math.cos(nlat) * math.cos(nlon-slon);
            final_bearing = math.atan2(y, x) - math.pi
            if (final_bearing < 0):
                final_bearing += math.pi * 2

            rotation = -1 * ((initial_bearing + final_bearing) / 2 - (math.pi / 2))

            ellipse_position += [time, central[0], central[1], 0.0]
            ellipse_semiMajorAxis += [time, round(semi_major_axis, 3)]
            ellipse_semiMinorAxis += [time, round(semi_minor_axis, 3)]
            ellipse_rotation += [time, round(rotation, 3)]        

        # Generate document packet with clock
        start_time = iso + "T" + self.time[0] + ":00Z"
        end_time = iso + "T" + self.time[-1] + ":00Z"
        packet = czml.CZMLPacket(id='document',version='1.0')
        c = czml.Clock()
        c.multiplier = 300
        c.range = "LOOP_STOP"
        c.step = "SYSTEM_CLOCK_MULTIPLIER"
        c.currentTime = start_time
        c.interval = start_time + "/" + end_time
        packet.clock = c
        doc.packets.append(packet)

        # Generate a polyline packet for the north and south polylines, connected and filled
        limit_polyline_degrees = list(north_polyline_degrees)
        point = len(south_polyline_degrees)/3
        while (point > 0):
            offset = (point-1) * 3
            limit_polyline_degrees += [ south_polyline_degrees[offset],
                                        south_polyline_degrees[offset+1],
                                        south_polyline_degrees[offset+2] ]
            point -= 1
        packet_id = iso + '_bounds_polygon'
        packet = czml.CZMLPacket(id=packet_id)
        boc = czml.Color(rgba=(232, 72, 68, 255))
        bsc = czml.SolidColor(color=czml.Color(rgba=(0, 0, 0, 66)))
        bmat = czml.Material(solidColor=bsc)
        bdeg = limit_polyline_degrees
        bpos = czml.Positions(cartographicDegrees=bdeg)
        bpg = czml.Polygon(show=True, height=0, outline=True, outlineColor=boc, outlineWidth=2, material=bmat, positions=bpos)
        packet.polygon = bpg
        doc.packets.append(packet)

        # Generate central polyline packet
        packet_id = iso + '_central_polyline'
        packet = czml.CZMLPacket(id=packet_id)
        csc = czml.SolidColor(color=czml.Color(rgba=(241, 226, 57, 255)))
        cmat = czml.Material(solidColor=csc)
        cpos = czml.Positions(cartographicDegrees=central_polyline_degrees)
        cpl = czml.Polyline(show=True, width=4, followSurface=True, material=cmat, positions=cpos)
        packet.polyline = cpl
        doc.packets.append(packet)

        # Generate ellipse shadow packet
        packet_id = iso + '_shadow_ellipse'
        packet = czml.CZMLPacket(id=packet_id)
        esc = czml.SolidColor(color=czml.Color(rgba=(0, 0, 0, 160)))
        emat = czml.Material(solidColor=esc)
        xmaj = czml.Number(ellipse_semiMajorAxis)
        xmin = czml.Number(ellipse_semiMinorAxis)
        rot = czml.Number(ellipse_rotation)
        ell = czml.Ellipse(show=True, fill=True, granularity=0.002, material=emat, semiMajorAxis=xmaj, semiMinorAxis=xmin, rotation=rot)
        packet.ellipse = ell
        packet.position = czml.Position(cartographicDegrees=ellipse_position)
        doc.packets.append(packet)

        return list(doc.data())