Ejemplo n.º 1
0
def whittle(cloud, polygons):
    """
    Parameters
    ----------
    cloud : ndarray
        Mx3 array containing the point cloud. Columns are x, y, and z
        Should be centered about the origin
    polygons : list of ndarray
        Each array is Mx2 and represents a series of x, y points defining a
        polygon.

    Returns
    -------
    cloud : ndarray
        Mx3 array representing the points from the original cloud that are
        contained inside the 3d volume defined by the series of polygons
    """
    # Divide half the circle evenly among the polygons
    angle = np.pi / len(polygons)
    rotation_matrix = get_rotation_matrix(angle)
    for polygon in polygons:
        # Find and remove the points that fall outside the current projection
        mask = mlab.inside_poly(cloud[:, 1:], polygon)
        cloud = cloud[mask]
        1/0
        # Rotate the cloud and go to the next projection
        cloud = cloud.dot(rotation_matrix)
    return cloud
Ejemplo n.º 2
0
def whittle(cloud, polygons):
    """
    Parameters
    ----------
    cloud : ndarray
        Mx3 array containing the point cloud. Columns are x, y, and z
        Should be centered about the origin
    polygons : list of ndarray
        Each array is Mx2 and represents a series of x, y points defining a
        polygon.

    Returns
    -------
    cloud : ndarray
        Mx3 array representing the points from the original cloud that are
        contained inside the 3d volume defined by the series of polygons
    """
    # Divide half the circle evenly among the polygons
    angle = np.pi / len(polygons)
    rotation_matrix = get_rotation_matrix(angle)
    for polygon in polygons:
        # Find and remove the points that fall outside the current projection
        mask = mlab.inside_poly(cloud[:, 1:], polygon)
        cloud = cloud[mask]
        1/0
        # Rotate the cloud and go to the next projection
        cloud = cloud.dot(rotation_matrix)
    return cloud
Ejemplo n.º 3
0
 def polygon_average(self, pvert, bluered='blue'):
     """Averages within a polygon"""
     self.show_lines([
         numpy.array(pvert[0]).T,
     ],
                     edgecolor=bluered,
                     linewidth=2)
     avgfigure = mpl.figure()
     avgax = avgfigure.add_subplot(111)
     for i, hdu in enumerate(self.extra_hdus):
         points = self._get_points(hdu)
         vel = getaxes(hdu.header, 1)
         #mask = points_inside_poly(points, pvert[0])
         mask = inside_poly(points, pvert[0])
         navg = len(numpy.where(mask)[0])
         hdunew = hdu.data.copy()
         ny, nx, nv = hdunew.shape
         hdunew = hdunew.reshape((ny * nx), nv)
         poly_avg = hdunew[mask, :].mean(axis=0)
         avgax.plot(vel,
                    poly_avg,
                    linestyle='steps-mid',
                    label='%s %s polygon' %
                    (self._get_hdu_title(i), bluered))
     avgax.set_title("Average made from %s qualifying points" % navg)
     avgax.legend(loc='best')
     avgfigure.canvas.draw()
     self.refresh()
Ejemplo n.º 4
0
    def getdataInRect(self):
        # Get the data from the Graphicsitem
        self.getDataItem()
        x = self.dataxy[0]
        y = self.dataxy[1]
        # Rect Edges
        Xbl = (self.Coords[0], self.Coords[1])  # bottom left
        Xbr = (self.Coords[2], self.Coords[1])  # bottom right
        Xtr = (self.Coords[2], self.Coords[3])  # top right
        Xtl = (self.Coords[0], self.Coords[3])  # top left
        #Make a list of [(x0,y0),(x1,y1) ...]
        self.xy = list()
        for i in x:
            tmp = (x[i], y[i])
            self.xy.append(tmp)
#       exemple = inside_poly([(x0,y0),(x1,y1),...],[Xbl, Xbr, Xtr, Xtl])
        self.insideIndex = inside_poly(self.xy, [Xbl, Xbr, Xtr, Xtl])
    def getIntensity(self, lat, long):

        # TODO: Test
        long += 5.0
        lat += 10.0

        wind_kt = 0.0  # wind speed in knots
        for i in xrange(self.data.numRecords):
            if len(inside_poly([[long, lat]], self.data.shape(i).points)) > 0:
                # Find the wind corresponding to the bus latutude and longitude
                wind_kt = max(wind_kt, float(self.data.record(i)[1]))

        # Converting from knott to mph (1 kt = 1.15077945 miles per hour)
        wind_mph = wind_kt * 1.15077945
        # Converting from mph wind to mph gust (1 mph wind = 1.3 mph gust)
        gust_mph = wind_mph * 1.3

        return gust_mph
    def getdataInRect(self):
        # Get the data from the Graphicsitem
        self.getDataItem()
        x = self.dataxy[0]
        y = self.dataxy[1]

        # Rect Edges
        Xbl = (self.Coords[0], self.Coords[1])  # bottom left
        Xbr = (self.Coords[2], self.Coords[1])  # bottom right
        Xtr = (self.Coords[2], self.Coords[3])  # top right
        Xtl = (self.Coords[0], self.Coords[3])  # top left

        #Make a list of [(x0,y0),(x1,y1) ...]
        self.xy = list()
        for i in range(len(x)):
            tmp = (x[i], y[i])
            self.xy.append(tmp)

        # matplotlib inside_poly function gets
        # datapoints that are within polygon
        self.insideIndex = inside_poly(self.xy, [Xbl, Xbr, Xtr, Xtl])
Ejemplo n.º 7
0
def checkPointsInPolygon(polygon_list, points_list):
    inside = mlab.inside_poly(points_list, polygon_list);
    return inside;
Ejemplo n.º 8
0
def checkPointsInPolygon(polygon_list, points_list):
    inside = mlab.inside_poly(points_list, polygon_list)
    return inside