- TensorFlow Tutorial
- TensorFlow - Home
- TensorFlow - Introduction
- TensorFlow - Installation
- Understanding Artificial Intelligence
- Mathematical Foundations
- Machine Learning & Deep Learning
- TensorFlow - Basics
- Convolutional Neural Networks
- Recurrent Neural Networks
- TensorBoard Visualization
- TensorFlow - Word Embedding
- Single Layer Perceptron
- TensorFlow - Linear Regression
- TFLearn and its installation
- CNN and RNN Difference
- TensorFlow - Keras
- TensorFlow - Distributed Computing
- TensorFlow - Exporting
- Multi-Layer Perceptron Learning
- Hidden Layers of Perceptron
- TensorFlow - Optimizers
- TensorFlow - XOR Implementation
- Gradient Descent Optimization
- TensorFlow - Forming Graphs
- Image Recognition using TensorFlow
- Recommendations for Neural Network Training
- TensorFlow Useful Resources
- TensorFlow - Quick Guide
- TensorFlow - Useful Resources
- TensorFlow - Discussion
TensorFlow - Hidden Layers of Perceptron
In this chapter, we will be focus on the network we will have to learn from known set of points called x and f(x). A single hidden layer will build this simple network.
The code for the explanation of hidden layers of perceptron is as shown below −
#Importing the necessary modules import tensorflow as tf import numpy as np import math, random import matplotlib.pyplot as plt np.random.seed(1000) function_to_learn = lambda x: np.cos(x) + 0.1*np.random.randn(*x.shape) layer_1_neurons = 10 NUM_points = 1000 #Training the parameters batch_size = 100 NUM_EPOCHS = 1500 all_x = np.float32(np.random.uniform(-2*math.pi, 2*math.pi, (1, NUM_points))).T np.random.shuffle(all_x) train_size = int(900) #Training the first 700 points in the given set x_training = all_x[:train_size] y_training = function_to_learn(x_training) #Training the last 300 points in the given set x_validation = all_x[train_size:] y_validation = function_to_learn(x_validation) plt.figure(1) plt.scatter(x_training, y_training, c = 'blue', label = 'train') plt.scatter(x_validation, y_validation, c = 'pink', label = 'validation') plt.legend() plt.show() X = tf.placeholder(tf.float32, [None, 1], name = "X") Y = tf.placeholder(tf.float32, [None, 1], name = "Y") #first layer #Number of neurons = 10 w_h = tf.Variable( tf.random_uniform([1, layer_1_neurons],\ minval = -1, maxval = 1, dtype = tf.float32)) b_h = tf.Variable(tf.zeros([1, layer_1_neurons], dtype = tf.float32)) h = tf.nn.sigmoid(tf.matmul(X, w_h) + b_h) #output layer #Number of neurons = 10 w_o = tf.Variable( tf.random_uniform([layer_1_neurons, 1],\ minval = -1, maxval = 1, dtype = tf.float32)) b_o = tf.Variable(tf.zeros([1, 1], dtype = tf.float32)) #build the model model = tf.matmul(h, w_o) + b_o #minimize the cost function (model - Y) train_op = tf.train.AdamOptimizer().minimize(tf.nn.l2_loss(model - Y)) #Start the Learning phase sess = tf.Session() sess.run(tf.initialize_all_variables()) errors = [] for i in range(NUM_EPOCHS): for start, end in zip(range(0, len(x_training), batch_size),\ range(batch_size, len(x_training), batch_size)): sess.run(train_op, feed_dict = {X: x_training[start:end],\ Y: y_training[start:end]}) cost = sess.run(tf.nn.l2_loss(model - y_validation),\ feed_dict = {X:x_validation}) errors.append(cost) if i%100 == 0: print("epoch %d, cost = %g" % (i, cost)) plt.plot(errors,label='MLP Function Approximation') plt.xlabel('epochs') plt.ylabel('cost') plt.legend() plt.show()
Output
Following is the representation of function layer approximation −
Here two data are represented in shape of W. The two data are: train and validation which are represented in distinct colors as visible in legend section.
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