rothnic/CesiumCZMLOrientation.py

## CesiumCZMLOrientation.py
# Intended to convert a typical radar lla and az el to a cesium quaternion orientation for CZML
# Uses numpy, transformations.py (http://www.lfd.uci.edu/~gohlke/code/transformations.py.html),
#   and ecef.py (https://code.google.com/p/pysatel/source/browse/trunk/coord.py?r=22)

def azEl2Quaternion(lat, lon, alt, az, el):
    rotZ = rotation_matrix(math.radians(180+az), [0,0,1])
    rotY = rotation_matrix(math.radians(-(90+el)), [0,1,0])
    rotM = np.dot(rotZ, rotY)
    origin = geodetic2ecef(lat, lon, alt)
    origin = np.multiply(origin, 1000)
    locTransform = northEastDownToFixedFrame(origin)
    transMatrix = np.dot(locTransform, rotM)
    tempQ = quaternion_from_matrix(transMatrix)
    return [tempQ[1], tempQ[2], tempQ[3], tempQ[0]]

radar1 = azEl2Quaternion(42.3, -88.5, 0, -110, 20)
# Output: [-0.56863161832163933, -0.42476180301542149, 0.69877439159571153, 0.089161892050613742]
radar2 = azEl2Quaternion(36, -85, 0, -65, 20)
# Output(wrong): [-0.40704469036283503, -0.27047076453169133, 0.78617746720121096, 0.3782660117511954]
# Correct: [0.40704469036283503, 0.27047076453169133, -0.78617746720121096, 0.3782660117511954]

## cesiumNEDtoFixedFrame.py
# Partial implementation of Cesium's northEastDownToFixedFrame method from Javascript to Python

def northEastDownToFixedFrame(origin):
#
#         if (CesiumMath.equalsEpsilon(origin.x, 0.0, CesiumMath.EPSILON14) &&
#             CesiumMath.equalsEpsilon(origin.y, 0.0, CesiumMath.EPSILON14)) {
#             // The poles are special cases.  If x and y are zero, assume origin is at a pole.
#             var sign = CesiumMath.sign(origin.z);
#             if (!defined(result)) {
#                 return new Matrix4(
#                   -sign, 0.0,   0.0, origin.x,
#                     0.0, 1.0,   0.0, origin.y,
#                     0.0, 0.0, -sign, origin.z,
#                     0.0, 0.0,   0.0, 1.0);
#             }
#             result[0] = -sign;
#             result[1] = 0.0;
#             result[2] = 0.0;
#             result[3] = 0.0;
#             result[4] = 0.0;
#             result[5] = 1.0;
#             result[6] = 0.0;
#             result[7] = 0.0;
#             result[8] = 0.0;
#             result[9] = 0.0;
#             result[10] = -sign;
#             result[11] = 0.0;
#             result[12] = origin.x;
#             result[13] = origin.y;
#             result[14] = origin.z;
#             result[15] = 1.0;
#             return result;
#         }
#
    ellipsoid = np.array([6378137.0, 6378137.0, 6356752.3142451793])
    tangent = np.array([0,0,0])

    tangent[0] = -origin[1]
    tangent[1] = origin[0]
    tangent[2] = 0.0

    nnorm = np.array([(1/ellipsoid[0]**2),  (1/ellipsoid[1]**2), (1/ellipsoid[2]**2)])
    nnorm = np.mat(nnorm)
    normal = np.multiply(origin, nnorm)
    normal = normal/LA.norm(normal)
    tangent = tangent/LA.norm(tangent, 3)
    bitangent = np.cross(normal, tangent)
    normal = np.asarray(normal[0])
    normal = np.asarray(normal[0])
    bitangent = np.asarray(bitangent[0])

#         if (!defined(result)) {
#             return new Matrix4(
#                     bitangent.x, tangent.x, -normal.x, origin.x,
#                     bitangent.y, tangent.y, -normal.y, origin.y,
#                     bitangent.z, tangent.z, -normal.z, origin.z,
#                     0.0,       0.0,         0.0,      1.0);
#         }

    return np.array([[bitangent[0], tangent[0], -normal[0], origin[0]],
                    [bitangent[1], tangent[1], -normal[1], origin[1]],
                    [bitangent[2], tangent[2], -normal[2], origin[2]],
                    [0, 0, 0, 1]])
	# Intended to convert a typical radar lla and az el to a cesium quaternion orientation for CZML
	# Uses numpy, transformations.py (http://www.lfd.uci.edu/~gohlke/code/transformations.py.html),
	# and ecef.py (https://code.google.com/p/pysatel/source/browse/trunk/coord.py?r=22)

	def azEl2Quaternion(lat, lon, alt, az, el):
	rotZ = rotation_matrix(math.radians(180+az), [0,0,1])
	rotY = rotation_matrix(math.radians(-(90+el)), [0,1,0])
	rotM = np.dot(rotZ, rotY)
	origin = geodetic2ecef(lat, lon, alt)
	origin = np.multiply(origin, 1000)
	locTransform = northEastDownToFixedFrame(origin)
	transMatrix = np.dot(locTransform, rotM)
	tempQ = quaternion_from_matrix(transMatrix)
	return [tempQ[1], tempQ[2], tempQ[3], tempQ[0]]

	radar1 = azEl2Quaternion(42.3, -88.5, 0, -110, 20)
	# Output: [-0.56863161832163933, -0.42476180301542149, 0.69877439159571153, 0.089161892050613742]
	radar2 = azEl2Quaternion(36, -85, 0, -65, 20)
	# Output(wrong): [-0.40704469036283503, -0.27047076453169133, 0.78617746720121096, 0.3782660117511954]
	# Correct: [0.40704469036283503, 0.27047076453169133, -0.78617746720121096, 0.3782660117511954]
	# Partial implementation of Cesium's northEastDownToFixedFrame method from Javascript to Python

	def northEastDownToFixedFrame(origin):
	#
	# if (CesiumMath.equalsEpsilon(origin.x, 0.0, CesiumMath.EPSILON14) &&
	# CesiumMath.equalsEpsilon(origin.y, 0.0, CesiumMath.EPSILON14)) {
	# // The poles are special cases. If x and y are zero, assume origin is at a pole.
	# var sign = CesiumMath.sign(origin.z);
	# if (!defined(result)) {
	# return new Matrix4(
	# -sign, 0.0, 0.0, origin.x,
	# 0.0, 1.0, 0.0, origin.y,
	# 0.0, 0.0, -sign, origin.z,
	# 0.0, 0.0, 0.0, 1.0);
	# }
	# result[0] = -sign;
	# result[1] = 0.0;
	# result[2] = 0.0;
	# result[3] = 0.0;
	# result[4] = 0.0;
	# result[5] = 1.0;
	# result[6] = 0.0;
	# result[7] = 0.0;
	# result[8] = 0.0;
	# result[9] = 0.0;
	# result[10] = -sign;
	# result[11] = 0.0;
	# result[12] = origin.x;
	# result[13] = origin.y;
	# result[14] = origin.z;
	# result[15] = 1.0;
	# return result;
	# }
	#
	ellipsoid = np.array([6378137.0, 6378137.0, 6356752.3142451793])
	tangent = np.array([0,0,0])

	tangent[0] = -origin[1]
	tangent[1] = origin[0]
	tangent[2] = 0.0

	nnorm = np.array([(1/ellipsoid[0]2), (1/ellipsoid[1]2), (1/ellipsoid[2]**2)])
	nnorm = np.mat(nnorm)
	normal = np.multiply(origin, nnorm)
	normal = normal/LA.norm(normal)
	tangent = tangent/LA.norm(tangent, 3)
	bitangent = np.cross(normal, tangent)
	normal = np.asarray(normal[0])
	normal = np.asarray(normal[0])
	bitangent = np.asarray(bitangent[0])

	# if (!defined(result)) {
	# return new Matrix4(
	# bitangent.x, tangent.x, -normal.x, origin.x,
	# bitangent.y, tangent.y, -normal.y, origin.y,
	# bitangent.z, tangent.z, -normal.z, origin.z,
	# 0.0, 0.0, 0.0, 1.0);
	# }

	return np.array([[bitangent[0], tangent[0], -normal[0], origin[0]],
	[bitangent[1], tangent[1], -normal[1], origin[1]],
	[bitangent[2], tangent[2], -normal[2], origin[2]],
	[0, 0, 0, 1]])