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Python CombinedFunction.f方法代码示例

本文整理汇总了Python中parsimony.functions.CombinedFunction.f方法的典型用法代码示例。如果您正苦于以下问题:Python CombinedFunction.f方法的具体用法?Python CombinedFunction.f怎么用?Python CombinedFunction.f使用的例子?那么恭喜您, 这里精选的方法代码示例或许可以为您提供帮助。您也可以进一步了解该方法所在parsimony.functions.CombinedFunction的用法示例。


在下文中一共展示了CombinedFunction.f方法的6个代码示例,这些例子默认根据受欢迎程度排序。您可以为喜欢或者感觉有用的代码点赞,您的评价将有助于系统推荐出更棒的Python代码示例。

示例1: test_smooth_1D_l2

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_smooth_1D_l2(self):

        from parsimony.functions import CombinedFunction
        import parsimony.functions as functions
        import parsimony.functions.nesterov.grouptv as grouptv
        import parsimony.datasets.simulate.l1_l2_grouptvmu as l1_l2_grouptvmu
        import parsimony.utils.weights as weights

        np.random.seed(1337)

        n, p = 10, 15
        shape = (1, 1, p)

        l = 0.0
        k = 0.1  # Must have some regularisation for all variables.
        g = 0.9

        start_vector = weights.RandomUniformWeights(normalise=True)
        beta = start_vector.get_weights(p)

        rects = [[(0, 5)], [(4, 10)], [(13, 15)]]
                              # 0 [ 5 ] 0
                              # 1 [ 5 ] 0
                              # 2 [ 5 ] 0
                              # 3 [ 5 ] 0
                              # 4 [ 4 ] 0 / 1
        beta[:5, :] = 5.0     # 5 [ 3 ] 1
        beta[4, :] = 4.0      # 6 [ 3 ] 1
        beta[5:10, :] = 3.0   # 7 [ 3 ] 1
        beta[13:15, :] = 7.0  # 8 [ 3 ] 1
                              # 9 [ 3 ] 1
                              # 0 [ x ] -
                              # 1 [ x ] -
                              # 2 [ x ] -
                              # 3 [ 7 ] 2
                              # 4 [ 7 ] 2
        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        A = grouptv.linear_operator_from_rects(rects, shape)
        mu_min = 5e-8
        X, y, beta_star = l1_l2_grouptvmu.load(l=l, k=k, g=g, beta=beta,
                                               M=M, e=e, A=A, mu=mu_min,
                                               snr=snr)

        eps = 1e-5
        max_iter = 12000

        beta_start = start_vector.get_weights(p)

        mus = [5e-2, 5e-4, 5e-6, 5e-8]
        fista = FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
            function = CombinedFunction()
            function.add_loss(functions.losses.LinearRegression(X, y,
                                                                mean=False))
            function.add_penalty(grouptv.GroupTotalVariation(l=g,
                                                             A=A, mu=mu,
                                                             penalty_start=0))

            function.add_penalty(functions.penalties.L2Squared(l=k,
                                                             penalty_start=0))

            beta_parsimony = fista.run(function, beta_parsimony)

        berr = np.linalg.norm(beta_parsimony - beta_star)
#        print "berr:", berr
        assert berr < 5e-2

        f_parsimony = function.f(beta_parsimony)
        f_star = function.f(beta_star)
        ferr = abs(f_parsimony - f_star)
#        print "ferr:", ferr
        assert ferr < 5e-5
开发者ID:neurospin,项目名称:pylearn-parsimony,代码行数:84,代码来源:test_group_total_variation.py

示例2: test_combo_overlapping_nonsmooth

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_combo_overlapping_nonsmooth(self):

        import numpy as np
        from parsimony.functions import CombinedFunction
        import parsimony.algorithms.proximal as proximal
        import parsimony.functions as functions
        import parsimony.functions.nesterov.gl as gl
        import parsimony.datasets.simulate.l1_l2_gl as l1_l2_gl
        import parsimony.utils.start_vectors as start_vectors

        np.random.seed(42)

        # Note that p must be even!
        n, p = 25, 30
        groups = [range(0, 2 * p / 3), range(p / 3, p)]
        weights = [1.5, 0.5]

        A = gl.A_from_groups(p, groups=groups, weights=weights)

        l = 0.618
        k = 1.0 - l
        g = 2.718

        start_vector = start_vectors.RandomStartVector(normalise=True)
        beta = start_vector.get_vector(p)

        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        X, y, beta_star = l1_l2_gl.load(l, k, g, beta, M, e, A, snr=snr)

        eps = 1e-8
        max_iter = 10000

        beta_start = start_vector.get_vector(p)

        mus = [5e-0, 5e-2, 5e-4, 5e-6, 5e-8]
        fista = proximal.FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
#            function = functions.LinearRegressionL1L2GL(X, y, l, k, g,
#                                                        A=A, mu=mu,
#                                                        penalty_start=0)

            function = CombinedFunction()
            function.add_function(functions.losses.LinearRegression(X, y,
                                                               mean=False))
            function.add_penalty(functions.penalties.L2Squared(l=k))
            function.add_penalty(gl.GroupLassoOverlap(l=g, A=A, mu=mu,
                                                      penalty_start=0))
            function.add_prox(functions.penalties.L1(l=l))

            beta_parsimony = fista.run(function, beta_parsimony)

        berr = np.linalg.norm(beta_parsimony - beta_star)
#        print berr
        assert berr < 5e-3

        f_parsimony = function.f(beta_parsimony)
        f_star = function.f(beta_star)
#        print abs(f_parsimony - f_star)
        assert abs(f_parsimony - f_star) < 5e-6
开发者ID:neurospin,项目名称:pylearn-parsimony_history,代码行数:71,代码来源:test_group_lasso.py

示例3: test_smooth_2D_l1

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_smooth_2D_l1(self):

        from parsimony.functions import CombinedFunction
        import parsimony.functions as functions
        import parsimony.functions.nesterov.grouptv as grouptv
        import parsimony.datasets.simulate.l1_l2_grouptvmu as l1_l2_grouptvmu
        import parsimony.utils.weights as weights

        np.random.seed(1337)

        n, p = 10, 18
        shape = (1, 3, 6)

        l = 0.618
        k = 0.0
        g = 1.618

        start_vector = weights.ZerosWeights()
        beta = start_vector.get_weights(p)

        rects = [[(0, 1), (0, 3)], [(1, 2), (3, 6)]]

        beta = np.reshape(beta, shape[1:])
        beta[0:2, 0:4] = 1.0
        beta[1:3, 3:6] = 2.0
        beta[1, 3] = 1.5
        beta = np.reshape(beta, (p, 1))

        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        A = grouptv.linear_operator_from_rects(rects, shape)
        mu_min = 5e-8
        X, y, beta_star = l1_l2_grouptvmu.load(l=l, k=k, g=g, beta=beta,
                                               M=M, e=e, A=A, mu=mu_min,
                                               snr=snr)

        eps = 1e-5
        max_iter = 10000

        beta_start = start_vector.get_weights(p)

        mus = [5e-2, 5e-4, 5e-6, 5e-8]
        fista = FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
            function = CombinedFunction()
            function.add_loss(functions.losses.LinearRegression(X, y,
                                                                mean=False))
            function.add_penalty(grouptv.GroupTotalVariation(l=g,
                                                             A=A, mu=mu,
                                                             penalty_start=0))

            function.add_prox(functions.penalties.L1(l=l, penalty_start=0))

            beta_parsimony = fista.run(function, beta_parsimony)

        berr = np.linalg.norm(beta_parsimony - beta_star)
#        print "berr:", berr
        assert berr < 5e-2

        f_parsimony = function.f(beta_parsimony)
        f_star = function.f(beta_star)
        ferr = abs(f_parsimony - f_star)
#        print "ferr:", ferr
        assert ferr < 5e-5
开发者ID:neurospin,项目名称:pylearn-parsimony,代码行数:75,代码来源:test_group_total_variation.py

示例4: test_nonoverlapping_nonsmooth

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_nonoverlapping_nonsmooth(self):
        # Spams: http://spams-devel.gforge.inria.fr/doc-python/doc_spams.pdf

        import numpy as np
        from parsimony.functions import CombinedFunction
        import parsimony.algorithms.proximal as proximal
        import parsimony.functions as functions
        import parsimony.functions.nesterov.gl as gl
        import parsimony.datasets.simulate.l1_l2_gl as l1_l2_gl
        import parsimony.utils.start_vectors as start_vectors

        np.random.seed(42)

        # Note that p must be even!
        n, p = 25, 20
        groups = [range(0, p / 2), range(p / 2, p)]
#        weights = [1.5, 0.5]

        A = gl.A_from_groups(p, groups=groups)  # , weights=weights)

        l = 0.0
        k = 0.0
        g = 1.0

        start_vector = start_vectors.RandomStartVector(normalise=True)
        beta = start_vector.get_vector(p)

        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        X, y, beta_star = l1_l2_gl.load(l, k, g, beta, M, e, A, snr=snr)

        eps = 1e-8
        max_iter = 8500

        beta_start = start_vector.get_vector(p)

        mus = [5e-2, 5e-4, 5e-6, 5e-8]
        fista = proximal.FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
#            function = functions.LinearRegressionL1L2GL(X, y, l, k, g,
#                                                        A=A, mu=mu,
#                                                        penalty_start=0)

            function = CombinedFunction()
            function.add_function(functions.losses.LinearRegression(X, y,
                                                               mean=False))
            function.add_penalty(gl.GroupLassoOverlap(l=g, A=A, mu=mu,
                                                      penalty_start=0))

            beta_parsimony = fista.run(function, beta_parsimony)

        try:
            import spams

            params = {"loss": "square",
                      "regul": "group-lasso-l2",
                      "groups": np.array([1] * (p / 2) + [2] * (p / 2),
                                         dtype=np.int32),
                      "lambda1": g,
                      "max_it": max_iter,
                      "tol": eps,
                      "ista": False,
                      "numThreads": -1,
                     }
            beta_spams, optim_info = \
                    spams.fistaFlat(Y=np.asfortranarray(y),
                                    X=np.asfortranarray(X),
                                    W0=np.asfortranarray(beta_start),
                                    return_optim_info=True,
                                    **params)

        except ImportError:
            beta_spams = np.asarray([[14.01111427],
                                     [35.56508563],
                                     [27.38245962],
                                     [22.39716553],
                                     [5.835744940],
                                     [5.841502910],
                                     [2.172209350],
                                     [32.40227785],
                                     [22.48364756],
                                     [26.48822401],
                                     [0.770391500],
                                     [36.28288883],
                                     [31.14118214],
                                     [7.938279340],
                                     [6.800713150],
                                     [6.862914540],
                                     [11.38161678],
                                     [19.63087584],
                                     [16.15855845],
#.........这里部分代码省略.........
开发者ID:neurospin,项目名称:pylearn-parsimony_history,代码行数:103,代码来源:test_group_lasso.py

示例5: test_nonoverlapping_smooth

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_nonoverlapping_smooth(self):
        # Spams: http://spams-devel.gforge.inria.fr/doc-python/doc_spams.pdf

        import numpy as np
        from parsimony.functions import CombinedFunction
        import parsimony.algorithms.proximal as proximal
        import parsimony.functions as functions
        import parsimony.functions.nesterov.gl as gl
        import parsimony.datasets.simulate.l1_l2_glmu as l1_l2_glmu
        import parsimony.utils.start_vectors as start_vectors

        np.random.seed(42)

        # Note that p must be even!
        n, p = 25, 20
        groups = [range(0, p / 2), range(p / 2, p)]
#        weights = [1.5, 0.5]

        A = gl.A_from_groups(p, groups=groups)  # , weights=weights)

        l = 0.0
        k = 0.0
        g = 0.9

        start_vector = start_vectors.RandomStartVector(normalise=True)
        beta = start_vector.get_vector(p)

        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        mu_min = 5e-8
        X, y, beta_star = l1_l2_glmu.load(l, k, g, beta, M, e, A,
                                          mu=mu_min, snr=snr)

        eps = 1e-8
        max_iter = 18000

        beta_start = start_vector.get_vector(p)

        mus = [5e-0, 5e-2, 5e-4, 5e-6, 5e-8]
        fista = proximal.FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
#            function = functions.LinearRegressionL1L2GL(X, y, l, k, g,
#                                                        A=A, mu=mu,
#                                                        penalty_start=0)

            function = CombinedFunction()
            function.add_function(functions.losses.LinearRegression(X, y,
                                                               mean=False))
            function.add_penalty(gl.GroupLassoOverlap(l=g, A=A, mu=mu,
                                                      penalty_start=0))

            beta_parsimony = fista.run(function, beta_parsimony)

        try:
            import spams

            params = {"loss": "square",
                      "regul": "group-lasso-l2",
                      "groups": np.array([1] * (p / 2) + [2] * (p / 2),
                                         dtype=np.int32),
                      "lambda1": g,
                      "max_it": max_iter,
                      "tol": eps,
                      "ista": False,
                      "numThreads": -1,
                     }
            beta_spams, optim_info = \
                    spams.fistaFlat(Y=np.asfortranarray(y),
                                    X=np.asfortranarray(X),
                                    W0=np.asfortranarray(beta_start),
                                    return_optim_info=True,
                                    **params)
#            print beta_spams

        except ImportError:
            beta_spams = np.asarray([[15.56784201],
                                     [39.51679274],
                                     [30.42583205],
                                     [24.8816362],
                                     [6.48671072],
                                     [6.48350546],
                                     [2.41477318],
                                     [36.00285723],
                                     [24.98522184],
                                     [29.43128643],
                                     [0.85520539],
                                     [40.31463542],
                                     [34.60084146],
                                     [8.82322513],
                                     [7.55741642],
                                     [7.62364398],
#.........这里部分代码省略.........
开发者ID:neurospin,项目名称:pylearn-parsimony_history,代码行数:103,代码来源:test_group_lasso.py

示例6: test_overlapping_smooth

# 需要导入模块: from parsimony.functions import CombinedFunction [as 别名]
# 或者: from parsimony.functions.CombinedFunction import f [as 别名]
    def test_overlapping_smooth(self):

        import numpy as np
        from parsimony.functions import CombinedFunction
        import parsimony.functions as functions
        import parsimony.functions.nesterov.gl as gl
        import parsimony.datasets.simulate.l1_l2_glmu as l1_l2_glmu
        import parsimony.utils.weights as weights

        np.random.seed(314)

        # Note that p must be even!
        n, p = 25, 30
        groups = [list(range(0, 2 * int(p / 3))), list(range(int(p / 3), p))]
        group_weights = [1.5, 0.5]

        A = gl.linear_operator_from_groups(p, groups=groups,
                                           weights=group_weights)

        l = 0.0
        k = 0.0
        g = 0.9

        start_vector = weights.RandomUniformWeights(normalise=True)
        beta = start_vector.get_weights(p)

        alpha = 1.0
        Sigma = alpha * np.eye(p, p) \
              + (1.0 - alpha) * np.random.randn(p, p)
        mean = np.zeros(p)
        M = np.random.multivariate_normal(mean, Sigma, n)
        e = np.random.randn(n, 1)

        snr = 100.0

        mu_min = 5e-8
        X, y, beta_star = l1_l2_glmu.load(l, k, g, beta, M, e, A,
                                          mu=mu_min, snr=snr)

        eps = 1e-8
        max_iter = 15000

        beta_start = start_vector.get_weights(p)

        mus = [5e-0, 5e-2, 5e-4, 5e-6, 5e-8]
        fista = FISTA(eps=eps, max_iter=max_iter / len(mus))

        beta_parsimony = beta_start
        for mu in mus:
#            function = functions.LinearRegressionL1L2GL(X, y, l, k, g,
#                                                        A=A, mu=mu,
#                                                        penalty_start=0)

            function = CombinedFunction()
            function.add_loss(functions.losses.LinearRegression(X, y,
                                                                mean=False))
            function.add_penalty(gl.GroupLassoOverlap(l=g, A=A, mu=mu,
                                                      penalty_start=0))

            beta_parsimony = fista.run(function, beta_parsimony)

        berr = np.linalg.norm(beta_parsimony - beta_star)
#        print berr
        assert berr < 5e-2

        f_parsimony = function.f(beta_parsimony)
        f_star = function.f(beta_star)
#        print(abs(f_parsimony - f_star))
        assert abs(f_parsimony - f_star) < 5e-6
开发者ID:duchesnay,项目名称:pylearn-parsimony,代码行数:71,代码来源:test_group_lasso.py


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