""" GTSAM Copyright 2010-2019, Georgia Tech Research Corporation, Atlanta, Georgia 30332-0415 All Rights Reserved See LICENSE for the license information Unit tests for IMU numerical_derivative module. Author: Frank Dellaert & Joel Truher """ # pylint: disable=invalid-name, no-name-in-module import unittest import numpy as np from gtsam import Pose3, Rot3, Point3 from gtsam.utils.numerical_derivative import numericalDerivative11, numericalDerivative21, numericalDerivative22, numericalDerivative33 class TestNumericalDerivatives(unittest.TestCase): def test_numericalDerivative11_scalar(self): # Test function of one variable def h(x): return x ** 2 x = np.array([3.0]) # Analytical derivative: dh/dx = 2x analytical_derivative = np.array([[2.0 * x[0]]]) # Compute numerical derivative numerical_derivative = numericalDerivative11(h, x) # Check if numerical derivative is close to analytical derivative np.testing.assert_allclose( numerical_derivative, analytical_derivative, rtol=1e-5 ) def test_numericalDerivative11_vector(self): # Test function of one vector variable def h(x): return x ** 2 x = np.array([1.0, 2.0, 3.0]) # Analytical derivative: dh/dx = 2x analytical_derivative = np.diag(2.0 * x) numerical_derivative = numericalDerivative11(h, x) np.testing.assert_allclose( numerical_derivative, analytical_derivative, rtol=1e-5 ) def test_numericalDerivative21(self): # Test function of two variables, derivative with respect to first variable def h(x1, x2): return x1 * np.sin(x2) x1 = np.array([2.0]) x2 = np.array([np.pi / 4]) # Analytical derivative: dh/dx1 = sin(x2) analytical_derivative = np.array([[np.sin(x2[0])]]) numerical_derivative = numericalDerivative21(h, x1, x2) np.testing.assert_allclose( numerical_derivative, analytical_derivative, rtol=1e-5 ) def test_numericalDerivative22(self): # Test function of two variables, derivative with respect to second variable def h(x1, x2): return x1 * np.sin(x2) x1 = np.array([2.0]) x2 = np.array([np.pi / 4]) # Analytical derivative: dh/dx2 = x1 * cos(x2) analytical_derivative = np.array([[x1[0] * np.cos(x2[0])]]) numerical_derivative = numericalDerivative22(h, x1, x2) np.testing.assert_allclose( numerical_derivative, analytical_derivative, rtol=1e-5 ) def test_numericalDerivative33(self): # Test function of three variables, derivative with respect to third variable def h(x1, x2, x3): return x1 * x2 + np.exp(x3) x1 = np.array([1.0]) x2 = np.array([2.0]) x3 = np.array([0.5]) # Analytical derivative: dh/dx3 = exp(x3) analytical_derivative = np.array([[np.exp(x3[0])]]) numerical_derivative = numericalDerivative33(h, x1, x2, x3) np.testing.assert_allclose( numerical_derivative, analytical_derivative, rtol=1e-5 ) def test_numericalDerivative_with_pose(self): # Test function with manifold and vector inputs def h(pose:Pose3, point:np.ndarray): return pose.transformFrom(point) # Values from testPose3.cpp P = Point3(0.2,0.7,-2) R = Rot3.Rodrigues(0.3,0,0) P2 = Point3(3.5,-8.2,4.2) T = Pose3(R,P2) analytic_H1 = np.zeros((3,6), order='F', dtype=float) analytic_H2 = np.zeros((3,3), order='F', dtype=float) y = T.transformFrom(P, analytic_H1, analytic_H2) numerical_H1 = numericalDerivative21(h, T, P) numerical_H2 = numericalDerivative22(h, T, P) np.testing.assert_allclose(numerical_H1, analytic_H1, rtol=1e-5) np.testing.assert_allclose(numerical_H2, analytic_H2, rtol=1e-5) if __name__ == "__main__": unittest.main()