吴恩达老师深度学习第一课第四周（1-4）资源文件资源-CSDN文库

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在深度学习领域，吴恩达老师是一位非常知名的专家，他的课程深受全球学习者喜爱。"吴恩达老师深度学习第一课第四周（1-4）资源文件"是他在讲解深度学习基础时提供的一系列配套代码资源，旨在帮助学生更好地理解和实践所学知识。这些资源包括了三个Python文件：dnn_utils_v2.py、testCases_v3.py和dnn_app_utils_v2.py，下面我们将详细探讨这些文件中的关键知识点。 1. **dnn_utils_v2.py**：这个文件通常包含了深度学习中常用的辅助函数，比如数据预处理、模型评估、损失计算等。在深度学习中，数据预处理是非常重要的一环，它能确保输入数据符合模型的需求。可能包含的函数有归一化、标准化、数据集划分等。另外，模型评估函数可以用于计算预测结果与实际结果的差距，如准确率、精确率、召回率等。损失函数则衡量模型预测与真实值之间的差异，如均方误差或交叉熵。 2. **testCases_v3.py**：这个文件很可能是测试用例集合，用于验证代码的正确性。在深度学习项目中，编写单元测试和集成测试是必不可少的步骤，可以确保代码按照预期工作，避免潜在的错误。测试用例通常包含各种边界条件和异常情况，以覆盖所有可能的输入情况。通过运行这些测试，开发者可以快速定位和修复问题，保证代码的质量。 3. **dnn_app_utils_v2.py**：此文件可能包含了深度神经网络（DNN）应用相关的工具函数，比如构建网络结构、训练循环、模型保存与加载等。深度神经网络由多层神经元组成，每个层通过前向传播进行计算，训练过程则是通过反向传播优化权重。这个文件可能包含搭建模型的函数，如定义卷积层、全连接层、池化层等。此外，训练循环中可能包括了批量梯度下降、优化器的选择（如SGD、Adam）、学习率调整策略等。模型的保存和加载功能则方便模型的持续训练或部署。综合这三个文件，我们可以推测这是深度学习基础课程中关于如何实现和使用DNN的实践部分，涵盖数据处理、模型构建、训练和评估的整个流程。学习并理解这些代码将有助于深入掌握深度学习的基本概念和技术，为后续的深度学习项目打下坚实的基础。

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1-4.zip （3个子文件）

dnn_app_utils_v2.py 12KB

testCases_v3.py 3KB

dnn_utils_v2.py 2KB

# -*- coding: utf-8 -*- """ Created on Tue Apr 17 22:29:26 2018 @author: StephenGai """ import numpy as np import matplotlib.pyplot as plt from testCases_v3 import * from dnn_utils_v2 import sigmoid, sigmoid_backward, relu, relu_backward # GRADED FUNCTION: initialize_parameters 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 # 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]) / np.sqrt(layer_dims[l-1]) 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 # 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 # 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 # 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 1 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)], "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)], "sigmoid") caches.append(cache) ### END CODE HERE ### assert(AL.shape == (1,X.shape[1])) return AL, caches # GRADED FUNCTION: compute_cost 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 # GRADED FUNCTION: 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

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