Coursera deep learning 吴恩达 神经网络和深度学习 第四周 编程作业 Building your Deep Neural Network

3.1 - 2-layer Neural Network

def initialize_parameters(n_x, n_h, n_y):

    """

    Argument:

    n_x -- size of the input layer

    n_h -- size of the hidden layer

    n_y -- size of the output layer

    Returns:

    parameters -- python dictionary containing your parameters:

                    W1 -- weight matrix of shape (n_h, n_x)

                    b1 -- bias vector of shape (n_h, 1)

                    W2 -- weight matrix of shape (n_y, n_h)

                    b2 -- bias vector of shape (n_y, 1)

    """

    np.random.seed(1)

    ### START CODE HERE ### (≈ 4 lines of code)

    W1 = np.random.randn(n_h, n_x)*0.01

    b1 = np.zeros((n_h, 1))

    W2 = np.random.randn(n_y, n_h)*0.01

    b2 = np.zeros((n_y, 1))

    ### END CODE HERE ###

    assert(W1.shape == (n_h, n_x))

    assert(b1.shape == (n_h, 1))

    assert(W2.shape == (n_y, n_h))

    assert(b2.shape == (n_y, 1))

    parameters = {"W1": W1,

                  "b1": b1,

                  "W2": W2,

                  "b2": b2}

    return parameters   

3.2 - L-layer Neural Network

# GRADED FUNCTION: initialize_parameters_deep

def initialize_parameters_deep(layer_dims):

    """

    Arguments:

    layer_dims -- python array (list) containing the dimensions of each layer in our network

    Returns:

    parameters -- python dictionary containing your parameters "W1", "b1", ..., "WL", "bL":

                    Wl -- weight matrix of shape (layer_dims[l], layer_dims[l-1])

                    bl -- bias vector of shape (layer_dims[l], 1)

    """

    np.random.seed(3)

    parameters = {}

    L = len(layer_dims)            # number of layers in the network

    for l in range(1, L):

        ### START CODE HERE ### (≈ 2 lines of code)

        parameters['W' + str(l)] = np.random.randn(layer_dims[l], layer_dims[l-1]) * 0.01

        parameters['b' + str(l)] = np.zeros((layer_dims[l], 1))

        ### END CODE HERE ###

        assert(parameters['W' + str(l)].shape == (layer_dims[l], layer_dims[l-1]))

        assert(parameters['b' + str(l)].shape == (layer_dims[l], 1))

    return parameters

4.1 - Linear Forward

# GRADED FUNCTION: linear_forward

def linear_forward(A, W, b):

    """

    Implement the linear part of a layer's forward propagation.

    Arguments:

    A -- activations from previous layer (or input data): (size of previous layer, number of examples)

    W -- weights matrix: numpy array of shape (size of current layer, size of previous layer)

    b -- bias vector, numpy array of shape (size of the current layer, 1)

    Returns:

    Z -- the input of the activation function, also called pre-activation parameter

    cache -- a python dictionary containing "A", "W" and "b" ; stored for computing the backward pass efficiently

    """

    ### START CODE HERE ### (≈ 1 line of code)

    Z = np.dot(W, A) + b

    ### END CODE HERE ###

    assert(Z.shape == (W.shape[0], A.shape[1]))

    cache = (A, W, b)

    return Z, cache

4.2 - Linear-Activation Forward

# GRADED FUNCTION: linear_activation_forward

def linear_activation_forward(A_prev, W, b, activation):

    """

    Implement the forward propagation for the LINEAR->ACTIVATION layer

    Arguments:

    A_prev -- activations from previous layer (or input data): (size of previous layer, number of examples)

    W -- weights matrix: numpy array of shape (size of current layer, size of previous layer)

    b -- bias vector, numpy array of shape (size of the current layer, 1)

    activation -- the activation to be used in this layer, stored as a text string: "sigmoid" or "relu"

    Returns:

    A -- the output of the activation function, also called the post-activation value

    cache -- a python dictionary containing "linear_cache" and "activation_cache";

             stored for computing the backward pass efficiently

    """

    if activation == "sigmoid":

        # Inputs: "A_prev, W, b". Outputs: "A, activation_cache".

        ### START CODE HERE ### (≈ 2 lines of code)

        Z, linear_cache = linear_forward(A_prev, W, b)

        A, activation_cache = sigmoid(Z)

        ### END CODE HERE ###

    elif activation == "relu":

        # Inputs: "A_prev, W, b". Outputs: "A, activation_cache".

        ### START CODE HERE ### (≈ 2 lines of code)

        Z, linear_cache = linear_forward(A_prev, W, b)

        A, activation_cache = relu(Z)

        ### END CODE HERE ###

    assert (A.shape == (W.shape[0], A_prev.shape[1]))

    cache = (linear_cache, activation_cache)

    return A, cache

d) L-Layer Model

# GRADED FUNCTION: L_model_forward

def L_model_forward(X, parameters):

    """

    Implement forward propagation for the [LINEAR->RELU]*(L-1)->LINEAR->SIGMOID computation

    Arguments:

    X -- data, numpy array of shape (input size, number of examples)

    parameters -- output of initialize_parameters_deep()

    Returns:

    AL -- last post-activation value

    caches -- list of caches containing:

                every cache of linear_relu_forward() (there are L-1 of them, indexed from 0 to L-2)

                the cache of linear_sigmoid_forward() (there is one, indexed L-1)

    """

    caches = []

    A = X

    L = len(parameters) // 2                  # number of layers in the neural network

    # Implement [LINEAR -> RELU]*(L-1). Add "cache" to the "caches" list.

    for l in range(1, L):

        A_prev = A

        ### START CODE HERE ### (≈ 2 lines of code)

        A, cache = linear_activation_forward(A_prev , parameters["W" + str(l)], parameters["b" + str(l)], activation = 'relu')

        caches.append(cache)

        ### END CODE HERE ###

    # Implement LINEAR -> SIGMOID. Add "cache" to the "caches" list.

    ### START CODE HERE ### (≈ 2 lines of code)

    AL, cache = linear_activation_forward(A, parameters["W" + str(L)], parameters["b" + str(L)], activation = 'sigmoid')

    caches.append(cache)

    ### END CODE HERE ###

    assert(AL.shape == (1,X.shape[1]))

    return AL, caches

5 - Cost function

def compute_cost(AL, Y):

    """

    Implement the cost function defined by equation (7).

    Arguments:

    AL -- probability vector corresponding to your label predictions, shape (1, number of examples)

    Y -- true "label" vector (for example: containing 0 if non-cat, 1 if cat), shape (1, number of examples)

    Returns:

    cost -- cross-entropy cost

    """

    m = Y.shape[1]

    # Compute loss from aL and y.

    ### START CODE HERE ### (≈ 1 lines of code)

    cost = - np.sum(np.multiply(np.log(AL),Y) + np.multiply(np.log(1 - AL),1 - Y)) / m

    ### END CODE HERE ###

    cost = np.squeeze(cost)      # To make sure your cost's shape is what we expect (e.g. this turns [[17]] into 17).

    assert(cost.shape == ())

    return cost

6.1 - Linear backward

def linear_backward(dZ, cache):

    """

    Implement the linear portion of backward propagation for a single layer (layer l)

    Arguments:

    dZ -- Gradient of the cost with respect to the linear output (of current layer l)

    cache -- tuple of values (A_prev, W, b) coming from the forward propagation in the current layer

    Returns:

    dA_prev -- Gradient of the cost with respect to the activation (of the previous layer l-1), same shape as A_prev

    dW -- Gradient of the cost with respect to W (current layer l), same shape as W

    db -- Gradient of the cost with respect to b (current layer l), same shape as b

    """

    A_prev, W, b = cache

    m = A_prev.shape[1]

    ### START CODE HERE ### (≈ 3 lines of code)

    dW = np.dot(dZ, A_prev.T) / m

    db = np.sum(dZ, axis = 1, keepdims = True) / m

    dA_prev = np.dot(W.T, dZ)

    ### END CODE HERE ###

    assert (dA_prev.shape == A_prev.shape)

    assert (dW.shape == W.shape)

    assert (db.shape == b.shape)

    return dA_prev, dW, db

6.2 - Linear-Activation backward

def linear_activation_backward(dA, cache, activation):

    """

    Implement the backward propagation for the LINEAR->ACTIVATION layer.

    Arguments:

    dA -- post-activation gradient for current layer l

    cache -- tuple of values (linear_cache, activation_cache) we store for computing backward propagation efficiently

    activation -- the activation to be used in this layer, stored as a text string: "sigmoid" or "relu"

    Returns:

    dA_prev -- Gradient of the cost with respect to the activation (of the previous layer l-1), same shape as A_prev

    dW -- Gradient of the cost with respect to W (current layer l), same shape as W

    db -- Gradient of the cost with respect to b (current layer l), same shape as b

    """

    linear_cache, activation_cache = cache

    if activation == "relu":

        ### START CODE HERE ### (≈ 2 lines of code)

        dZ = relu_backward(dA, activation_cache)

        dA_prev, dW, db = linear_backward(dZ, linear_cache)

        ### END CODE HERE ###

    elif activation == "sigmoid":

        ### START CODE HERE ### (≈ 2 lines of code)

        dZ = sigmoid_backward(dA, activation_cache)

        dA_prev, dW, db = linear_backward(dZ, linear_cache)

        ### END CODE HERE ###

    return dA_prev, dW, db

6.3 - L-Model Backward

def L_model_backward(AL, Y, caches):

    """

    Implement the backward propagation for the [LINEAR->RELU] * (L-1) -> LINEAR -> SIGMOID group

    Arguments:

    AL -- probability vector, output of the forward propagation (L_model_forward())

    Y -- true "label" vector (containing 0 if non-cat, 1 if cat)

    caches -- list of caches containing:

                every cache of linear_activation_forward() with "relu" (it's caches[l], for l in range(L-1) i.e l = 0...L-2)

                the cache of linear_activation_forward() with "sigmoid" (it's caches[L-1])

    Returns:

    grads -- A dictionary with the gradients

             grads["dA" + str(l)] = ...

             grads["dW" + str(l)] = ...

             grads["db" + str(l)] = ...

    """

    grads = {}

    L = len(caches) # the number of layers

    m = AL.shape[1]

    Y = Y.reshape(AL.shape) # after this line, Y is the same shape as AL

    # Initializing the backpropagation

    ### START CODE HERE ### (1 line of code)

    dAL = - (np.divide(Y, AL) - np.divide(1 - Y, 1 - AL))

    ### END CODE HERE ###

    # Lth layer (SIGMOID -> LINEAR) gradients. Inputs: "AL, Y, caches". Outputs: "grads["dAL"], grads["dWL"], grads["dbL"]

    ### START CODE HERE ### (approx. 2 lines)

    current_cache =  caches[L-1]

    grads["dA" + str(L)], grads["dW" + str(L)], grads["db" + str(L)] = linear_activation_backward(dAL, current_cache, activation = "sigmoid")

    ### END CODE HERE ###

    for l in reversed(range(L-1)):

        # lth layer: (RELU -> LINEAR) gradients.

        # Inputs: "grads["dA" + str(l + 2)], caches". Outputs: "grads["dA" + str(l + 1)] , grads["dW" + str(l + 1)] , grads["db" + str(l + 1)]

        ### START CODE HERE ### (approx. 5 lines)

        current_cache = caches[l]

        dA_prev_temp, dW_temp, db_temp = linear_activation_backward(grads["dA" + str(l + 2)], current_cache, activation = "relu")

        grads["dA" + str(l + 1)] = dA_prev_temp

        grads["dW" + str(l + 1)] = dW_temp

        grads["db" + str(l + 1)] = db_temp

        ### END CODE HERE ###

    return grads

6.4 - Update Parameters

def update_parameters(parameters, grads, learning_rate):

    """

    Update parameters using gradient descent

    Arguments:

    parameters -- python dictionary containing your parameters

    grads -- python dictionary containing your gradients, output of L_model_backward

    Returns:

    parameters -- python dictionary containing your updated parameters

                  parameters["W" + str(l)] = ...

                  parameters["b" + str(l)] = ...

    """

    L = len(parameters) // 2 # number of layers in the neural network

    # Update rule for each parameter. Use a for loop.

    ### START CODE HERE ### (≈ 3 lines of code)

    for l in range(L):

        parameters["W" + str(l+1)] = parameters["W" + str(l+1)] - learning_rate * grads["dW" + str(l+1)]

        parameters["b" + str(l+1)] = parameters["b" + str(l+1)] - learning_rate * grads["db" + str(l+1)]

    ### END CODE HERE ###

    return parameters

deep neural network-Application V3

def two_layer_model(X, Y, layers_dims, learning_rate = 0.0075, num_iterations = 3000, print_cost=False):

    """

    Implements a two-layer neural network: LINEAR->RELU->LINEAR->SIGMOID.

    Arguments:

    X -- input data, of shape (n_x, number of examples)

    Y -- true "label" vector (containing 0 if cat, 1 if non-cat), of shape (1, number of examples)

    layers_dims -- dimensions of the layers (n_x, n_h, n_y)

    num_iterations -- number of iterations of the optimization loop

    learning_rate -- learning rate of the gradient descent update rule

    print_cost -- If set to True, this will print the cost every 100 iterations

    Returns:

    parameters -- a dictionary containing W1, W2, b1, and b2

    """

    np.random.seed(1)

    grads = {}

    costs = []                              # to keep track of the cost

    m = X.shape[1]                           # number of examples

    (n_x, n_h, n_y) = layers_dims

    # Initialize parameters dictionary, by calling one of the functions you'd previously implemented

    ### START CODE HERE ### (≈ 1 line of code)

    parameters = initialize_parameters(n_x, n_h, n_y)

    ### END CODE HERE ###

    # Get W1, b1, W2 and b2 from the dictionary parameters.

    W1 = parameters["W1"]

    b1 = parameters["b1"]

    W2 = parameters["W2"]

    b2 = parameters["b2"]

    # Loop (gradient descent)

    for i in range(0, num_iterations):

        # Forward propagation: LINEAR -> RELU -> LINEAR -> SIGMOID. Inputs: "X, W1, b1". Output: "A1, cache1, A2, cache2".

        ### START CODE HERE ### (≈ 2 lines of code)

        A1, cache1 = linear_activation_forward(X, W1, b1, 'relu')

        A2, cache2 = linear_activation_forward(A1, W2, b2, 'sigmoid')

        ### END CODE HERE ###

        # Compute cost

        ### START CODE HERE ### (≈ 1 line of code)

        cost = compute_cost(A2, Y)

        ### END CODE HERE ###

        # Initializing backward propagation

        dA2 = - (np.divide(Y, A2) - np.divide(1 - Y, 1 - A2))

        # Backward propagation. Inputs: "dA2, cache2, cache1". Outputs: "dA1, dW2, db2; also dA0 (not used), dW1, db1".

        ### START CODE HERE ### (≈ 2 lines of code)

        dA1, dW2, db2 = linear_activation_backward(dA2, cache2, 'sigmoid')

        dA0, dW1, db1 = linear_activation_backward(dA1, cache1, 'relu')

        ### END CODE HERE ###

        # Set grads['dWl'] to dW1, grads['db1'] to db1, grads['dW2'] to dW2, grads['db2'] to db2

        grads['dW1'] = dW1

        grads['db1'] = db1

        grads['dW2'] = dW2

        grads['db2'] = db2

        # Update parameters.

        ### START CODE HERE ### (approx. 1 line of code)

        parameters = update_parameters(parameters, grads, learning_rate)

        ### END CODE HERE ###

        # Retrieve W1, b1, W2, b2 from parameters

        W1 = parameters["W1"]

        b1 = parameters["b1"]

        W2 = parameters["W2"]

        b2 = parameters["b2"]

        # Print the cost every 100 training example

        if print_cost and i % 100 == 0:

            print("Cost after iteration {}: {}".format(i, np.squeeze(cost)))

        if print_cost and i % 100 == 0:

            costs.append(cost)

    # plot the cost

    plt.plot(np.squeeze(costs))

    plt.ylabel('cost')

    plt.xlabel('iterations (per tens)')

    plt.title("Learning rate =" + str(learning_rate))

    plt.show()

    return parameters

L-layer Neural Network

def L_layer_model(X, Y, layers_dims, learning_rate = 0.0075, num_iterations = 3000, print_cost=False):#lr was 0.009

    """

    Implements a L-layer neural network: [LINEAR->RELU]*(L-1)->LINEAR->SIGMOID.

    Arguments:

    X -- data, numpy array of shape (number of examples, num_px * num_px * 3)

    Y -- true "label" vector (containing 0 if cat, 1 if non-cat), of shape (1, number of examples)

    layers_dims -- list containing the input size and each layer size, of length (number of layers + 1).

    learning_rate -- learning rate of the gradient descent update rule

    num_iterations -- number of iterations of the optimization loop

    print_cost -- if True, it prints the cost every 100 steps

    Returns:

    parameters -- parameters learnt by the model. They can then be used to predict.

    """

    np.random.seed(1)

    costs = []                         # keep track of cost

    # Parameters initialization.

    ### START CODE HERE ###

    parameters = initialize_parameters_deep(layers_dims)

    ### END CODE HERE ###

    # Loop (gradient descent)

    for i in range(0, num_iterations):

        # Forward propagation: [LINEAR -> RELU]*(L-1) -> LINEAR -> SIGMOID.

        ### START CODE HERE ### (≈ 1 line of code)

        AL, caches = L_model_forward(X, parameters)

        ### END CODE HERE ###

        # Compute cost.

        ### START CODE HERE ### (≈ 1 line of code)

        cost = compute_cost(AL, Y)

        ### END CODE HERE ###

        # Backward propagation.

        ### START CODE HERE ### (≈ 1 line of code)

        grads = L_model_backward(AL, Y, caches)

        ### END CODE HERE ###

        # Update parameters.

        ### START CODE HERE ### (≈ 1 line of code)

        parameters = update_parameters(parameters, grads, learning_rate)

        ### END CODE HERE ###

        # Print the cost every 100 training example

        if print_cost and i % 100 == 0:

            print ("Cost after iteration %i: %f" %(i, cost))

        if print_cost and i % 100 == 0:

            costs.append(cost)

    # plot the cost

    plt.plot(np.squeeze(costs))

    plt.ylabel('cost')

    plt.xlabel('iterations (per tens)')

    plt.title("Learning rate =" + str(learning_rate))

    plt.show()

    return parameters

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