Added experiments until 5.

2025-11-16 22:00:08 -05:00 · 2025-11-16 22:00:08 -05:00 · 97f9db293d
commit 97f9db293d
parent 901f472da1
20 changed files with 1066 additions and 24 deletions
--- a/experiment-2.py
+++ b/experiment-2.py
@ -0,0 +1,240 @@
+import numpy as np
+import matplotlib.pyplot as plt
+from torchvision import datasets
+import os
+
+class MLP_leaky_tanh:
+    def __init__(self, input_size, hidden_size1, hidden_size2, output_size, weight_scale, activation_type):
+        self.activation_type = activation_type
+
+        # initializes weights and biases for each layer
+        self.W1 = np.random.randn(input_size, hidden_size1) * weight_scale
+        self.b1 = np.zeros((1, hidden_size1))
+        self.W2 = np.random.randn(hidden_size1, hidden_size2) * weight_scale
+        self.b2 = np.zeros((1, hidden_size2))
+        self.W3 = np.random.randn(hidden_size2, output_size) * weight_scale
+        self.b3 = np.zeros((1, output_size))
+
+    def forward(self, x, alpha=0):
+        # forwards pass through the network
+        self.x = x  # input for backpropagation
+        self.z1 = x @ self.W1 + self.b1  # linear transformation for layer 1
+        self.a1 = self.activation(self.z1, alpha)  # ReLU activation
+        self.z2 = self.a1 @ self.W2 + self.b2  # linear transformation for layer 2
+        self.a2 = self.activation(self.z2, alpha)  # ReLU activation
+        self.z3 = self.a2 @ self.W3 + self.b3  # linear transformation for layer 3
+        self.a3 = self.softmax(self.z3)  # applies softmax to get class probabilities
+        return self.a3  # output of the network
+
+    def backward(self, y, lr, alpha=0):
+        # backwards pass for weight updates using gradient descent
+        m = y.shape[0]
+        y_one_hot = self.one_hot_encode(y, self.W3.shape[1]) # converts labels to one-hot encoding
+
+        # computes gradients for each layer
+        dz3 = self.a3 - y_one_hot  # gradient for output layer
+        dw3 = (self.a2.T @ dz3) / m
+        db3 = np.sum(dz3, axis=0, keepdims=True) / m
+
+        dz2 = (dz3 @ self.W3.T) * self.activation_deriv(self.z2, alpha)  # gradient for layer 2
+        dw2 = (self.a1.T @ dz2) / m
+        db2 = np.sum(dz2, axis=0, keepdims=True) / m
+
+        dz1 = (dz2 @ self.W2.T) * self.activation_deriv(self.z1, alpha)  # gradient for layer 1
+        dw1 = (self.x.T @ dz1) / m
+        db1 = np.sum(dz1, axis=0, keepdims=True) / m
+
+        # updates weights and biases using gradient descent
+        self.W3 -= lr * dw3
+        self.b3 -= lr * db3
+        self.W2 -= lr * dw2
+        self.b2 -= lr * db2
+        self.W1 -= lr * dw1
+        self.b1 -= lr * db1
+
+    def activation(self, x, alpha=0):
+        # chooses activation function based on `activation_type`
+        if self.activation_type == 'leaky-relu':
+            return self.Lrelu(x, alpha)
+        elif self.activation_type == 'tanh':
+            return self.tanh(x)
+        else:
+            raise ValueError("Invalid activation type")
+
+    def activation_deriv(self, x, alpha):
+        # derivatives for the chosen activation function
+        if self.activation_type == 'leaky-relu':
+            return self.Lrelu_deriv(x, alpha)
+        elif self.activation_type == 'tanh':
+            return self.tanh_deriv(x)
+        else:
+            raise ValueError("Invalid activation type")
+
+    @staticmethod
+    def Lrelu(x, alpha=0):
+        # leaky ReLU activation
+        return np.where(x > 0, x, alpha * x)
+
+    @staticmethod
+    def Lrelu_deriv(x, alpha=0):
+        # derivation of leaky ReLU activation for backpropagation
+        return np.where(x > 0, 1, alpha)
+
+    @staticmethod
+    def tanh(x):
+        # tanh formula
+        return (np.exp(x) - np.exp(-x)) / (np.exp(x) + np.exp(-x))
+
+    @staticmethod
+    def tanh_deriv(x):
+        # derivation of tanh for backpropagation
+        return 1 - ((np.exp(x) - np.exp(-x)) / (np.exp(x) + np.exp(-x))) ** 2
+
+    @staticmethod
+    def softmax(x):
+        # softmax function normalizes outputs to probabilities
+        e_x = np.exp(x - np.max(x, axis=1, keepdims=True))  # exponentiates inputs
+        return e_x / np.sum(e_x, axis=1, keepdims=True) # normalizes to get probabilities
+
+    @staticmethod
+    def one_hot_encode(y, num_classes):
+        # converts labels to one-hot encoded format
+        return np.eye(num_classes)[y]
+
+    @staticmethod
+    def cross_entropy_loss(y, y_hat):
+        # computes cross-entropy loss between true labels and predicted probabilities
+        m = y.shape[0]
+        m = y.shape[0]
+        eps = 1e-12
+        y_hat_clipped = np.clip(y_hat, eps, 1. - eps)
+        log_probs = -np.log(y_hat_clipped[np.arange(m), y])
+        return np.mean(log_probs)
+
+    def fit(self, x_train, y_train, x_val, y_val, lr, epochs, batch_size, activation_type, alpha=0):
+        train_losses = []
+        val_accuracies = []
+
+        for epoch in range(1, epochs + 1):
+            perm = np.random.permutation(x_train.shape[0]) # Shuffle the training data
+            x_train_shuffled, y_train_shuffled = x_train[perm], y_train[perm]
+
+            epoch_loss = 0.0
+            num_batches = int(np.ceil(x_train.shape[0] / batch_size))
+
+            for i in range(num_batches):
+                start = i * batch_size
+                end = start + batch_size
+                x_batch = x_train_shuffled[start:end] # batch of inputs
+                y_batch = y_train_shuffled[start:end] # batch of labels
+
+                # Forward pass, backward pass, and weight update
+                self.forward(x_batch, alpha)
+                self.backward(y_batch, lr, alpha)
+
+                epoch_loss += self.cross_entropy_loss(y_batch, self.a3) # updating the epoch loss
+
+            epoch_loss /= num_batches # average loss is defined
+            train_losses.append(epoch_loss)
+
+            val_pred = self.predict(x_val, alpha)
+            val_acc = np.mean(val_pred == y_val)
+            val_accuracies.append(val_acc) \
+
+            print(f"Epoch {epoch:02d} | Training Loss: {epoch_loss:.4f} | Value Accuracy: {val_acc:.4f}")
+
+        self.plot_graph(train_losses, val_accuracies, activation_type)
+        return val_accuracies[-1]
+
+    def plot_graph(self, train_losses, val_accuracies, activation_type):
+        if not os.path.exists('results'):
+            os.makedirs('results') # creates results director
+
+        fig, ax1 = plt.subplots() # initializes the plot
+
+        ax1.set_xlabel('Epochs')
+        ax1.set_ylabel('Training Loss', color='tab:blue')
+        ax1.plot(range(1, len(train_losses) + 1), train_losses, color='tab:blue', label='Training Loss')
+        ax1.tick_params(axis='y', labelcolor='tab:blue') # defines loss subplot
+
+        ax2 = ax1.twinx()
+        ax2.set_ylabel('Validation Accuracy', color='tab:orange')
+        ax2.plot(range(1, len(val_accuracies) + 1), val_accuracies, color='tab:orange', label='Validation Accuracy')
+        ax2.tick_params(axis='y', labelcolor='tab:orange') # defines accuracy subplot
+
+        plt.title('Training Loss and Validation Accuracy over Epochs')
+
+        result_path = 'results/experiment-2-' + activation_type + '.png' # defines the file name
+        fig.savefig(result_path)
+        print(f"Graph saved to: {result_path}")
+
+    def predict(self, x, alpha=0): # predicts class labels for the input data
+        probs = self.forward(x, alpha)  # forwards pass to get probabilities
+        return np.argmax(probs, axis=1)  # returns the class with highest probability
+
+# acquiring the FashionMNIST dataset
+train_set = datasets.FashionMNIST(root='.', train=True, download=True)
+test_set = datasets.FashionMNIST(root='.', train=False, download=True)
+
+# preprocessing the data by flattening images and normalizing them.
+x_train = train_set.data.numpy().reshape(-1, 28 * 28).astype(np.float32) / 255.0
+y_train = train_set.targets.numpy()
+
+x_test = test_set.data.numpy().reshape(-1, 28 * 28).astype(np.float32) / 255.0
+y_test = test_set.targets.numpy()
+
+# MLP initialization (tanh instead of ReLu)
+mlp_tanh = MLP_leaky_tanh(
+    input_size=28 * 28,
+    hidden_size1=256,
+    hidden_size2=256,
+    output_size=10,
+    weight_scale=1e-2,
+    activation_type='tanh'
+)
+
+# trains the model
+mlp_tanh.fit(
+    x_train=x_train,
+    y_train=y_train,
+    x_val=x_test,
+    y_val=y_test,
+    lr=1e-2,
+    epochs=10,
+    batch_size=256,
+    activation_type='tanh'
+)
+
+# tests the model
+test_pred_tanh = mlp_tanh.predict(x_test)
+test_acc_tanh = np.mean(test_pred_tanh == y_test)
+print(f"\nFinal test accuracy: {test_acc_tanh:.4f}")
+
+# MLP initialization (leaky ReLu instead of ReLu)
+mlp_Lrelu = MLP_leaky_tanh(
+    input_size=28 * 28,
+    hidden_size1=256,
+    hidden_size2=256,
+    output_size=10,
+    weight_scale=1e-2,
+    activation_type='leaky-relu'
+)
+alpha = 0.01
+
+# trains the model
+mlp_Lrelu.fit(
+    x_train=x_train,
+    y_train=y_train,
+    x_val=x_test,
+    y_val=y_test,
+    lr=1e-2,
+    epochs=10,
+    batch_size=256,
+    activation_type='leaky-relu',
+    alpha=alpha
+)
+
+# tests the model
+test_pred_Lrelu = mlp_Lrelu.predict(x_test, alpha)
+test_acc_Lrelu = np.mean(test_pred_Lrelu == y_test)
+print(f"\nFinal test accuracy: {test_acc_Lrelu:.4f}")