Пример #1
0
    def test_reg_grad_data2_2(self, data2):
        y = data2[:, -1:]
        X = data2[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = ones((n + 1, 1), dtype=float64)
        _lambda = 1000000

        assert_allclose([[-338407.808], [-759558338.468], [-1092403.298]],
                        reg_grad(X, y, theta, _lambda),
                        rtol=0,
                        atol=0.001)
Пример #2
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    def test_reg_grad_data2_1(self, data2):
        y = data2[:, -1:]
        X = data2[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = ones((n + 1, 1), dtype=float64)
        _lambda = 0

        assert_allclose([[-338407.808], [-759579615.064], [-1113679.894]],
                        reg_grad(X, y, theta, _lambda),
                        rtol=0,
                        atol=0.001)
Пример #3
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    def test_reg_grad_data1_3(self, data1):
        y = data1[:, -1:]
        X = data1[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = array([[-1], [2]])
        _lambda = 750

        assert_allclose([[9.480465], [104.783153]],
                        reg_grad(X, y, theta, _lambda),
                        rtol=0,
                        atol=0.001)
Пример #4
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    def test_reg_grad_data1_2(self, data1):
        y = data1[:, -1:]
        X = data1[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = ones((n + 1, 1), dtype=float64)
        _lambda = 100

        assert_allclose([[3.320665], [25.265821]],
                        reg_grad(X, y, theta, _lambda),
                        rtol=0,
                        atol=0.001)
Пример #5
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    def test_reg_grad_data2_3(self, data2):
        y = data2[:, -1:]
        X = data2[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = array([[-25.3], [32], [7.8]])
        _lambda = 1000000

        assert_allclose(
            [[-276391.444681], [-615660007.370213], [-740838.968085]],
            reg_grad(X, y, theta, _lambda),
            rtol=0,
            atol=0.001)
Пример #6
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    def test_reg_grad_data1_6(self, data1, err):
        y = data1[:, -1:]
        X = data1[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = array([[-12.4], [23.56]])
        _lambda = 943

        def J(theta):
            return reg_cost_func(X, y, theta, _lambda)

        assert_allclose(reg_grad(X, y, theta, _lambda),
                        numerical_grad(J, theta, err),
                        rtol=0,
                        atol=0.001)
Пример #7
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    def test_reg_grad_data1_4(self, data1, err):
        y = data1[:, -1:]
        X = data1[:, :-1]
        m, n = X.shape
        intercept = ones((m, 1), dtype=float64)
        X = append(intercept, X, axis=1)
        theta = -8.4 * ones((n + 1, 1), dtype=float64)
        _lambda = 0.762

        def J(theta):
            return reg_cost_func(X, y, theta, _lambda)

        assert_allclose(reg_grad(X, y, theta, _lambda),
                        numerical_grad(J, theta, err),
                        rtol=0,
                        atol=0.001)