Esempio n. 1
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    def test_right_jacobians_of_boxminusr(self):
        for T1 in self.transforms:
            T2 = SE3.random()

            tau, Jr1 = T1.boxminusr(T2, Jr1=np.eye(6))
            dT = T2.inv() * T1
            _, Jr1_true = SE3.Log(dT, Jr=np.eye(6))

            _, Jr2 = T1.boxminusr(T2, Jr2=np.eye(6))
            _, Jr2_true = SE3.Log(dT, Jl=np.eye(6))

            np.testing.assert_allclose(Jr1_true, Jr1)
            np.testing.assert_allclose(-Jr2_true, Jr2)
Esempio n. 2
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    def test_right_jacobian_of_logarithm(self):
        for i in range(100):
            T = SE3.random()
            logT, Jr_inv = SE3.Log(T, Jr=np.eye(6))
            _, Jr = SE3.Exp(logT, Jr=np.eye(6))

            np.testing.assert_allclose(np.linalg.inv(Jr), Jr_inv)
Esempio n. 3
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def se3LogJacobian(T):
    Jr, Jl = np.eye(6), np.eye(6)

    tau = SE3.Log(T)
    dx = 1e-4
    for i in range(6):
        delta = np.zeros(6)
        delta[i] = dx

        Tr = T.boxplusr(delta)
        Tl = T.boxplusl(delta)

        vecr = SE3.Log(Tr) - tau
        vecl = SE3.Log(Tl) - tau

        Jr[:, i] = vecr / dx
        Jl[:, i] = vecl / dx

    return Jr, Jl
Esempio n. 4
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    T3, Jr1 = T.compose(T2, Jr=np.eye(6))
    T3, Jl1 = T.compose(T2, Jl=np.eye(6))
    T3, Jr2 = T.compose(T2, Jr2=np.eye(6))
    T3, Jl2 = T.compose(T2, Jl2=np.eye(6))
    Jr1n, Jl1n, Jr2n, Jl2n = se3ComposeJacobians(T, T2)

    # Exponential Jacobian works
    rho = np.random.uniform(-10, 10, size=3)
    theta = np.random.uniform(-np.pi, np.pi, size=3)
    tau = np.array([*rho, *theta])
    T, Jr = SE3.Exp(tau, Jr=np.eye(6))
    T, Jl = SE3.Exp(tau, Jl=np.eye(6))
    Jrn, Jln = se3ExpJacobian(tau)

    # Logarithm jacobian works
    tau, Jr = SE3.Log(T, Jr=np.eye(6))
    tau, Jl = SE3.Log(T, Jl=np.eye(6))
    Jrn, Jln = se3LogJacobian(T)
    debug = 1

    # Jacobians of transformation works
    pt = np.random.uniform(-10, 10, size=3)
    pt2, Jr = T.transa(pt, Jr=np.eye(6))
    pt2, Jl = T.transa(pt, Jl=np.eye(6))
    Jrn, Jln = transJacobian(T, pt)
    debug = 1
    # Jr = [T.R.T, -T.R.T @ skew(pt)]
    # Jl = [I_3, -skew(pt2)]

    # All other quat jacobians are a composition of the above jacobians