How to use the pyglm.models.NegativeBinomialEigenmodelPopulation function in pyglm

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github slinderman / pyglm / test / profile_vb.py View on Github external
B      = true_model.B
    dt     = true_model.dt
    dt_max = true_model.dt_max

    ###########################################################
    # Create and fit a standard model for initialization
    ###########################################################
    with gzip.open(init_path, 'r') as f:
        init_model = cPickle.load(f)

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################

    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                            basis_hypers=true_model.basis_hypers,
                            observation_hypers=true_model.observation_hypers,
                            activation_hypers=true_model.activation_hypers,
                            weight_hypers=true_model.weight_hypers,
                            bias_hypers=true_model.bias_hypers,
                            network_hypers=true_model.network_hypers)
    test_model.add_data(S)

    # Initialize with the standard model
    test_model.initialize_with_standard_model(init_model)

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(S_test)

    ###########################################################
    # Fit the test model with Gibbs sampling
github slinderman / pyglm / experiments / synthetic / fit_vb.py View on Github external
algorithms=["bfgs"])

    T      = train.shape[0]
    N      = true_model.N
    B      = true_model.B
    dt     = true_model.dt
    dt_max = true_model.dt_max

    # Create and fit a standard model for initialization
    init_model = standard_results["bfgs"]

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################
    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                            basis_hypers=true_model.basis_hypers,
                            observation_hypers=true_model.observation_hypers,
                            activation_hypers=true_model.activation_hypers,
                            weight_hypers=true_model.weight_hypers,
                            bias_hypers=true_model.bias_hypers,
                            network_hypers=true_model.network_hypers)
    test_model.add_data(train)

    # Initialize with the standard model
    test_model.initialize_with_standard_model(init_model)

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(test)

    ###########################################################
    # Fit the test model with Gibbs sampling
github slinderman / pyglm / experiments / rgc / fit_rgc_nb_eigen_vb.py View on Github external
# Create and fit a standard model for initialization
    init_model = standard_results["bfgs"]

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################
    # Use the initial model to set hypers
    observation_hypers = {"xi": init_model.xi}
    bias_hypers = {"mu_0": init_model.bias.mean(),
                   "sigma_0": init_model.bias.var()}

    network_hypers = {"mu_0": init_model.W.mean(axis=(0,1)),
                      "Sigma_0": np.diag(init_model.W.var(axis=(0,1)))}

    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(
        N=N, dt=dt, dt_max=dt_max, B=B,
        basis_hypers=init_model.basis_hypers,
        observation_hypers=observation_hypers,
        bias_hypers=bias_hypers,
        network_hypers=network_hypers)
    test_model.add_data(train)

    # Initialize the test model parameters with the
    # parameters of the L1-regularized model
    test_model.initialize_with_standard_model(init_model)

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(test)


    ###########################################################
github slinderman / pyglm / experiments / synthetic / fit_mcmc.py View on Github external
algorithms=["bfgs"])

    T      = train.shape[0]
    N      = true_model.N
    B      = true_model.B
    dt     = true_model.dt
    dt_max = true_model.dt_max

    # Create and fit a standard model for initialization
    init_model = standard_results["bfgs"]

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################
    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                            basis_hypers=true_model.basis_hypers,
                            observation_hypers=true_model.observation_hypers,
                            activation_hypers=true_model.activation_hypers,
                            weight_hypers=true_model.weight_hypers,
                            bias_hypers=true_model.bias_hypers,
                            network_hypers=true_model.network_hypers)
    test_model.add_data(train)

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(test)

    # Initialize with the standard model
    test_model.initialize_with_standard_model(init_model)
    print "Init PLL: ", init_model.heldout_log_likelihood(test)
github slinderman / pyglm / experiments / rgc / fit_rgc_nb_eigen_svi.py View on Github external
# Create and fit a standard model for initialization
    init_model = standard_results["bfgs"]

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################
    # Use the initial model to set hypers
    observation_hypers = {"xi": init_model.xi}
    bias_hypers = {"mu_0": init_model.bias.mean(),
                   "sigma_0": init_model.bias.var()}

    network_hypers = {"mu_0": init_model.W.mean(axis=(0,1)),
                      "Sigma_0": np.diag(init_model.W.var(axis=(0,1)))}

    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(
        N=N, dt=dt, dt_max=dt_max, B=B,
        basis_hypers=init_model.basis_hypers,
        observation_hypers=observation_hypers,
        bias_hypers=bias_hypers,
        network_hypers=network_hypers)

    # Add the data in minibatches
    test_model.add_data(train, minibatchsize=1000)

    # Initialize the test model parameters with the
    # parameters of the L1-regularized model
    test_model.initialize_with_standard_model(init_model)

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(test)
github slinderman / pyglm / experiments / synthetic / generate_synthetic_negbinom_data.py View on Github external
dt_max = 10.0                                          # Max time of synaptic influence
    B = 1                                                   # Number of basis functions for the weights

    #   Bias hyperparameters
    bias_hypers = {"mu_0": -4.0, "sigma_0": 0.25}

    ###########################################################
    #   Network hyperparameters
    ###########################################################
    network_hypers = {"p": 0.01, "mu_0": 0.*np.ones(B), "Sigma_0": 1**2*np.eye(B),
                      "sigma_F": 1.0}

    ###########################################################
    # Create the model with these parameters
    ###########################################################
    true_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                                            bias_hypers=bias_hypers,
                                            network_hypers=network_hypers)

    ###########################################################
    #   Override the sample with some serious structure
    ###########################################################
    eigenmodel = true_model.network.adjacency_dist
    M = 4
    th = np.linspace(0,2*np.pi, M, endpoint=False)
    centers = np.hstack((np.cos(th)[:,None], np.sin(th)[:,None]))
    # centers = [[1,1], [1,-1], [-1,-1], [-1,1]]
    for m, center in enumerate(centers):
        start = m*N//M
        end = min((m+1)*N//M, N)
        eigenmodel.F[start:end, :] = \
            center + 0.1 * np.random.randn(end-start,2)
github slinderman / pyglm / experiments / synthetic / fit_svi.py View on Github external
algorithms=["bfgs"])

    T      = train.shape[0]
    N      = true_model.N
    B      = true_model.B
    dt     = true_model.dt
    dt_max = true_model.dt_max

    # Create and fit a standard model for initialization
    init_model = standard_results["bfgs"]

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################
    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                            basis_hypers=true_model.basis_hypers,
                            observation_hypers=true_model.observation_hypers,
                            activation_hypers=true_model.activation_hypers,
                            weight_hypers=true_model.weight_hypers,
                            bias_hypers=true_model.bias_hypers,
                            network_hypers={'p': 0.19})
                            # network_hypers=true_model.network_hypers)

    # Add the data in minibatches of 1000 time bins
    minibatchsize = 1000
    test_model.add_data(train, minibatchsize=minibatchsize)

    # Initialize with the standard model
    test_model.initialize_with_standard_model(init_model)
    test_model.resample_from_mf()
github slinderman / pyglm / examples / negbinom / vb_demo.py View on Github external
B      = true_model.B
    dt     = true_model.dt
    dt_max = true_model.dt_max

    ###########################################################
    # Create and fit a standard model for initialization
    ###########################################################
    with gzip.open(init_path, 'r') as f:
        init_model = cPickle.load(f)

    ###########################################################
    # Create a test spike-and-slab model
    ###########################################################

    # Copy the network hypers.
    test_model = NegativeBinomialEigenmodelPopulation(N=N, dt=dt, dt_max=dt_max, B=B,
                            basis_hypers=true_model.basis_hypers,
                            observation_hypers=true_model.observation_hypers,
                            activation_hypers=true_model.activation_hypers,
                            weight_hypers=true_model.weight_hypers,
                            bias_hypers=true_model.bias_hypers,
                            network_hypers=true_model.network_hypers)
    test_model.add_data(S)

    # Initialize with the standard model
    test_model.initialize_with_standard_model(init_model)
    test_model.resample_from_mf()

    # Convolve the test data for fast heldout likelihood calculations
    F_test = test_model.basis.convolve_with_basis(S_test)

    # Initialize plots