mnist.rar_DHZ_MNIST_neuralnetwork_卷积神经网络资源-CSDN文库

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标题中的“mnist.rar_DHZ_MNIST_neural network_卷积神经网络”指的是一个关于DHZ（可能是个人或团队的缩写）利用MNIST数据集进行卷积神经网络（CNN）实践的项目。MNIST数据集是机器学习领域一个经典的图像识别数据集，主要包含手写数字的灰度图像，常用于训练和测试各种图像识别模型。描述中的“convolutional neural network”即卷积神经网络，是深度学习中一种重要的模型，特别适合处理图像数据。CNN通过卷积层、池化层、全连接层等结构，能够有效地捕获图像中的空间特征，从而在图像分类和识别任务上表现出色。卷积神经网络的基本结构包括： 1. **卷积层（Convolutional Layer）**：使用可学习的滤波器（Filter）对输入图像进行扫描，提取特征。滤波器在图像上滑动并进行点乘运算，生成特征映射。 2. **激活函数（Activation Function）**：如ReLU（Rectified Linear Unit），用于引入非线性，使得模型能学习更复杂的特征。 3. **池化层（Pooling Layer）**：通常使用最大池化或平均池化，减少计算量并保持关键特征，防止过拟合。 4. **归一化层（Normalization Layer）**：如Batch Normalization，可以加速训练过程并提高模型稳定性。 5. **全连接层（Fully Connected Layer）**：将前面层的输出转换为分类所需的概率分布。在MNIST数据集上应用CNN，通常会先进行预处理，例如将图像归一化到0-1之间，然后构建CNN模型，包括多个卷积层和池化层，最后接全连接层进行分类。模型训练过程中，会使用梯度下降优化算法更新权重，如Adam或SGD，并采用交叉熵损失函数评估分类效果。文件“mnist.py”很可能是实现这个CNN模型的Python代码，其中可能包含了加载MNIST数据集、定义CNN模型结构、训练模型、验证和测试的函数。代码中可能会用到TensorFlow、Keras或PyTorch等深度学习框架。在实际操作中，可能会遇到的问题包括模型过拟合、训练速度慢、准确率提升困难等，解决这些问题的方法有正则化、数据增强、使用预训练模型等。在MNIST这样的简单数据集上，往往能得到较高的准确率，但实际应用中需要考虑更复杂的模型结构和更丰富的数据集来应对实际问题。

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mnist.rar （1个子文件）

mnist.py 5KB

from __future__ import absolute_import from __future__ import division from __future__ import print_function import numpy as np import aaaa as tf tf.logging.set_verbosity(tf.logging.INFO) def cnn_model_fn(features, labels, mode): """Model function for CNN.""" # Input Layer # Reshape X to 4-D tensor: [batch_size, width, height, channels] # MNIST images are 28x28 pixels, and have one color channel input_layer = tf.reshape(features["x"], [-1, 28, 28, 1]) # Convolutional Layer #1 # Computes 32 features using a 5x5 filter with ReLU activation. # Padding is added to preserve width and height. # Input Tensor Shape: [batch_size, 28, 28, 1] # Output Tensor Shape: [batch_size, 28, 28, 32] conv1 = tf.layers.conv2d( inputs=input_layer, filters=32, kernel_size=[5, 5], padding="same", activation=tf.nn.relu) # Pooling Layer #1 # First max pooling layer with a 2x2 filter and stride of 2 # Input Tensor Shape: [batch_size, 28, 28, 32] # Output Tensor Shape: [batch_size, 14, 14, 32] pool1 = tf.layers.max_pooling2d(inputs=conv1, pool_size=[2, 2], strides=2) # Convolutional Layer #2 # Computes 64 features using a 5x5 filter. # Padding is added to preserve width and height. # Input Tensor Shape: [batch_size, 14, 14, 32] # Output Tensor Shape: [batch_size, 14, 14, 64] conv2 = tf.layers.conv2d( inputs=pool1, filters=64, kernel_size=[5, 5], padding="same", activation=tf.nn.relu) # Pooling Layer #2 # Second max pooling layer with a 2x2 filter and stride of 2 # Input Tensor Shape: [batch_size, 14, 14, 64] # Output Tensor Shape: [batch_size, 7, 7, 64] pool2 = tf.layers.max_pooling2d(inputs=conv2, pool_size=[2, 2], strides=2) # Flatten tensor into a batch of vectors # Input Tensor Shape: [batch_size, 7, 7, 64] # Output Tensor Shape: [batch_size, 7 * 7 * 64] pool2_flat = tf.reshape(pool2, [-1, 7 * 7 * 64]) # Dense Layer # Densely connected layer with 1024 neurons # Input Tensor Shape: [batch_size, 7 * 7 * 64] # Output Tensor Shape: [batch_size, 1024] dense = tf.layers.dense(inputs=pool2_flat, units=1024, activation=tf.nn.relu) # Add dropout operation; 0.6 probability that element will be kept dropout = tf.layers.dropout( inputs=dense, rate=0.4, training=mode == tf.estimator.ModeKeys.TRAIN) # Logits layer # Input Tensor Shape: [batch_size, 1024] # Output Tensor Shape: [batch_size, 10] logits = tf.layers.dense(inputs=dropout, units=10) predictions = { # Generate predictions (for PREDICT and EVAL mode) "classes": tf.argmax(input=logits, axis=1), # Add `softmax_tensor` to the graph. It is used for PREDICT and by the # `logging_hook`. "probabilities": tf.nn.softmax(logits, name="softmax_tensor") } if mode == tf.estimator.ModeKeys.PREDICT: return tf.estimator.EstimatorSpec(mode=mode, predictions=predictions) # Calculate Loss (for both TRAIN and EVAL modes) loss = tf.losses.sparse_softmax_cross_entropy(labels=labels, logits=logits) # Configure the Training Op (for TRAIN mode) if mode == tf.estimator.ModeKeys.TRAIN: optimizer = tf.train.GradientDescentOptimizer(learning_rate=0.001) train_op = optimizer.minimize( loss=loss, global_step=tf.train.get_global_step()) return tf.estimator.EstimatorSpec(mode=mode, loss=loss, train_op=train_op) # Add evaluation metrics (for EVAL mode) eval_metric_ops = { "accuracy": tf.metrics.accuracy( labels=labels, predictions=predictions["classes"])} return tf.estimator.EstimatorSpec( mode=mode, loss=loss, eval_metric_ops=eval_metric_ops) def main(unused_argv): # Load training and eval data mnist = tf.contrib.learn.datasets.load_dataset("mnist") train_data = mnist.train.images # Returns np.array train_labels = np.asarray(mnist.train.labels, dtype=np.int32) eval_data = mnist.test.images # Returns np.array eval_labels = np.asarray(mnist.test.labels, dtype=np.int32) # Create the Estimator mnist_classifier = tf.estimator.Estimator( model_fn=cnn_model_fn, model_dir="/tmp/mnist_convnet_model") # Set up logging for predictions # Log the values in the "Softmax" tensor with label "probabilities" tensors_to_log = {"probabilities": "softmax_tensor"} logging_hook = tf.train.LoggingTensorHook( tensors=tensors_to_log, every_n_iter=50) # Train the model train_input_fn = tf.estimator.inputs.numpy_input_fn( x={"x": train_data}, y=train_labels, batch_size=100, num_epochs=None, shuffle=True) mnist_classifier.train( input_fn=train_input_fn, steps=20000, hooks=[logging_hook]) # Evaluate the model and print results eval_input_fn = tf.estimator.inputs.numpy_input_fn( x={"x": eval_data}, y=eval_labels, num_epochs=1, shuffle=False) eval_results = mnist_classifier.evaluate(input_fn=eval_input_fn) print(eval_results) if __name__ == "__main__": tf.app.run()

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