Example #1
0
def find_values(data, weights, output, level):

    if (level == 2):
        wynik = sigmoid(sum(weights * data))
        return wynik

    for i in range(len(weights)):
        output[i] = sigmoid(sum(weights[i] * data))

    return output
Example #2
0
  def lstm_cell_forward(self, xt, a_prev, c_prev):
    '''
    Arguments:
    xt -- your input data at timestep "t", numpy array of shape (n_x, m).
    a_prev -- Hidden state at timestep "t-1", numpy array of shape (n_a, m)
    c_prev -- Memory state at timestep "t-1", numpy array of shape (n_a, m)
    parameters -- python dictionary containing:
                        Wf -- Weight matrix of the forget gate, numpy array of shape (n_a, n_a + n_x)
                        bf -- Bias of the forget gate, numpy array of shape (n_a, 1)
                        Wi -- Weight matrix of the update gate, numpy array of shape (n_a, n_a + n_x)
                        bi -- Bias of the update gate, numpy array of shape (n_a, 1)
                        Wc -- Weight matrix of the first "tanh", numpy array of shape (n_a, n_a + n_x)
                        bc --  Bias of the first "tanh", numpy array of shape (n_a, 1)
                        Wo -- Weight matrix of the output gate, numpy array of shape (n_a, n_a + n_x)
                        bo --  Bias of the output gate, numpy array of shape (n_a, 1)
                        Wy -- Weight matrix relating the hidden-state to the output, numpy array of shape (n_y, n_a)
                        by -- Bias relating the hidden-state to the output, numpy array of shape (n_y, 1)

    Returns:
    a_next -- next hidden state, of shape (n_a, m)
    c_next -- next memory state, of shape (n_a, m)
    yt_pred -- prediction at timestep "t", numpy array of shape (n_y, m)
    cache -- tuple of values needed for the backward pass, contains (a_next, c_next, a_prev, c_prev, xt, parameters)

    Note: ft/it/ot stand for the forget/update/output gates, cct stands for the candidate value (c tilde),
          c stands for the memory value
    '''

    # Retrieve dimensions from shapes of xt and Wy
    n_x, m = xt.shape
    n_y, n_a = self.Wy.shape

    # Concatenate a_prev and xt (≈3 lines)
    concat = np.zeros([n_x + n_a, m])
    concat[: n_a, :] = a_prev
    concat[n_a:, :] = xt

    # Compute values for ft, it, cct, c_next, ot, a_next using the formulas given figure (4) (≈6 lines)
    ft = sigmoid(np.dot(self.Wf, concat) + self.bf)
    it = sigmoid(np.dot(self.Wi, concat) + self.bi)
    cct = np.tanh(np.dot(self.Wc, concat) + self.bc)
    c_next = ft * c_prev + it * cct
    ot = sigmoid(np.dot(self.Wo, concat) + self.bo)
    a_next = ot * np.tanh(c_next)

    # Compute prediction of the LSTM cell (≈1 line)
    yt_pred = softmax(np.dot(self.Wy, a_next) + self.by)

    # store values needed for backward propagation in cache
    cache = (a_next, c_next, a_prev, c_prev, ft, it, cct, ot, xt)

    return a_next, c_next, yt_pred, cache
Example #3
0
    def forward(self, inputs):
        '''
    Perform a forward pass of LSTM using the given inputs.
    :param inputs: is an array of one hot vectors with shape (input_size, 1).
    :return: final output and hidden state.
    '''
        n_y, n_h = self.Wy.shape
        y = np.zeros((n_y, 1))
        h = np.zeros((n_h, 1))
        c = np.zeros((n_h, 1))

        self.last_hs = {0: h}  # save hidden state
        self.last_cs = {0: c}  # save cell state

        self.last_inputs = inputs

        self.caches = {}

        # Perform each step of the LSTM
        for i, x in enumerate(inputs):
            n_x, m = x.shape

            # Concatenate hidden state and input
            concat = np.zeros((n_x + n_h, 1))
            concat[:n_h, :] = h
            concat[n_h:, :] = x

            ft = sigmoid(np.dot(self.Wf, concat) + self.bf)
            it = sigmoid(np.dot(self.Wi, concat) + self.bi)
            cct = np.tanh(np.dot(self.Wc, concat) + self.bc)
            c = ft * c + it * cct
            self.last_cs[i + 1] = c
            ot = sigmoid(np.dot(self.Wo, concat) + self.bo)
            h = ot * np.tanh(c)
            self.last_hs[i + 1] = h
            cache = (h, c, self.last_hs[i], self.last_cs[i], ft, it, cct, ot,
                     x)
            self.caches[i] = cache
        y = np.dot(self.Wy, h) + self.by
        return y
Example #4
0
    def run_model(self):
        if self.silent is False:
            print("Starting energy: {:.3e}".format(self.energy_start))
            print("Starting cluster distance: {:.3e}".format(self.cluster_dist_start))
            print("Running model ... ")

        RolemodelLearning.relax_structure(self)

        rolemodel_index = RolemodelLearning.choose_rolemodels(self)
        RolemodelLearning.plot_struct_clustering(self, rolemodel_index)

        for iteration in range(1, self.niter + 1):
            if self.silent is False:
                print("\tIteration {}".format(iteration))

            RolemodelLearning.rattle_structure(self)
            RolemodelLearning.minimize_cluster_distance(self)

            rolemodel_index = RolemodelLearning.choose_rolemodels(self)
            RolemodelLearning.plot_struct_clustering(self, rolemodel_index)

            RolemodelLearning.relax_structure(self)

            self.grades[rolemodel_index] += 2*sigmoid(self.energies[-3] - self.energies[-1]) - 1
            self.grade_results = np.append(self.grade_results, self.grades[np.newaxis], axis=0)
            rolemodel_index = RolemodelLearning.choose_rolemodels(self)
            RolemodelLearning.plot_struct_clustering(self, rolemodel_index)

            if self.global_minimum is not None and np.isclose(self.energies[-1], self.global_minimum, atol=self.atol):
                self.global_min_iter = iteration
                break

        if self.global_min_iter == 0:
            self.global_min_iter = 1.1 * self.niter

        if self.silent is False:
            print("Done!")
            if self.global_min_iter is not None:
                if self.global_min_iter < self.niter + 1:
                    print("\nThe global minimum was found at iteration number {}!".format(self.global_min_iter))
                else:
                    print("\nThe global minimum was not reached..")
            else:
                print("\nThe minimum energy is: {:.3e}".format(self.energy_opt))
                print("A change in energy is found to be: {:.3e}".format(self.energy_opt - self.energy_start))
                print("\nThe cluster distance is: {:.3e}".format(self.cluster_dist_opt))
                print("A change in cluster distance is found to be: {:.3e}".format(
                    self.cluster_dist_opt - self.cluster_dist_start)
                )
Example #5
0
 def predict(self, X):
     if self.weights is None:
         raise Exception("Not trained yet !")
     return maths.sigmoid(np.dot(X, self.weights) + self.bias)