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### CSCI 4750/5750: regression models
import gradio as gr
import matplotlib
import matplotlib.pyplot as plt
import numpy as np
from sklearn.linear_model import LinearRegression
def cal_mse(X,y,b,w):
thetas = np.array([[b], [w]])
X_b = np.c_[np.ones((len(X), 1)), X] # add x0 = 1 to each instance
y_predict = X_b.dot(thetas)
mse = np.mean((y_predict-y)**2)
return mse
def gradient_descent(intercept=4, slope=3, intercept_random=4, slope_random=3, gradient_descent=False, learning_rate= 0.01, iteration=100):
### (1) generate simulated data points
X = 2 * np.random.rand(100, 1)
y = intercept + slope * X + np.random.randn(100, 1)
### (2) fit regression model
lin_reg = LinearRegression()
lin_reg.fit(X, y)
### (3) make a prediction on training data
y_predict = lin_reg.predict(X)
y_predict
### (4) Draw baseline linear Line
fig = plt.figure(figsize=(12,20))
plt.subplot(3,1,1)
plt.plot(X, y_predict, "r-", linewidth=2, label = "Line of best fit")
plt.plot(X, y, "b.")
### (4.2) Draw random line
if intercept_random != intercept or slope_random != slope: #avoid overlap
X_new = np.array([[0], [2]])
X_new_b = np.c_[np.ones((2, 1)), X_new] # add x0 = 1 to each instance
y_predict = X_new_b.dot(np.array([intercept_random, slope_random]))
plt.plot(X_new, y_predict, "g-", linewidth=2, label = "Random line")
### (4.3) Apply gradient desc
if gradient_descent:
b = intercept_random
w = slope_random
lr = learning_rate # learning rate
iteration = iteration
# Store initial values for plotting.
b_history = [b]
w_history = [w]
train_mse = []
# Iterations
for i in range(iteration):
b_grad = 0.0
w_grad = 0.0
for n in range(len(X)):
b_grad = b_grad - (y[n,0] - b - w*X[n,0])*1.0
w_grad = w_grad - (y[n,0] - b - w*X[n,0])*X[n,0]
b_grad /= len(X)
w_grad /= len(X)
# Update parameters.
b = b - lr * b_grad
w = w - lr * w_grad
# Store parameters for plotting
b_history.append(b)
w_history.append(w)
train_mse.append(cal_mse(X,y,b,w))
if i == int(iteration/4):
X_tmp = np.array([[0], [2]])
X_tmp_b = np.c_[np.ones((2, 1)), X_tmp] # add x0 = 1 to each instance
y_predict_tmp = X_tmp_b.dot(np.array([b, w]))
plt.plot(X_tmp, y_predict_tmp, "brown", linewidth=2, label = "Fitted line in iteration "+str(i))
if i == int(iteration/3):
X_tmp = np.array([[0], [2]])
X_tmp_b = np.c_[np.ones((2, 1)), X_tmp] # add x0 = 1 to each instance
y_predict_tmp = X_tmp_b.dot(np.array([b, w]))
plt.plot(X_tmp, y_predict_tmp, "blue", linewidth=2, label = "Fitted line in iteration "+str(i))
if i == int(iteration/2):
X_tmp = np.array([[0], [2]])
X_tmp_b = np.c_[np.ones((2, 1)), X_tmp] # add x0 = 1 to each instance
y_predict_tmp = X_tmp_b.dot(np.array([b, w]))
plt.plot(X_tmp, y_predict_tmp, "gray", linewidth=2, label = "Fitted line in iteration "+str(i))
if i == int(iteration-1):
X_tmp = np.array([[0], [2]])
X_tmp_b = np.c_[np.ones((2, 1)), X_tmp] # add x0 = 1 to each instance
y_predict_tmp = X_tmp_b.dot(np.array([b, w]))
plt.plot(X_tmp, y_predict_tmp, "black", linewidth=2, label = "Fitted line in iteration "+str(i))
plt.xlabel("$x_1$", fontsize=22)
plt.ylabel("$y$", rotation=0, fontsize=22)
plt.xticks(fontsize=18)
plt.yticks(fontsize=18)
plt.axis([np.min(X)*0.1, np.max(X)*1.1, np.min(y)*0.1, np.max(y)*1.1])
plt.title("Linear Regression model predictions", fontsize=22)
plt.legend(fontsize=18)
### (5) Visualize loss function
plt.subplot(3,1,2)
### (5.1) generate grid of parameters
b = np.arange(-10,10,0.1) #bias
w = np.arange(-10,10,0.1) #weight
### (5.2) Calculate MSE over parameters
Z = np.zeros((len(w), len(b)))
for i in range(len(w)):
for j in range(len(b)):
w0 = w[i]
b0 = b[j]
Z[i][j] = cal_mse(X, y, b0, w0)
### (5.3) Get optimal parameters
theta0_best = lin_reg.intercept_[0]
theta1_best = lin_reg.coef_[0][0]
### (5.4) Draw the contour graph
plt.contourf(b,w,Z, 50, alpha=0.5, cmap=plt.get_cmap('jet'))
### (5.5) Add optimal loss
plt.plot(theta0_best, theta1_best, 'x', ms=12, markeredgewidth=3, color='orange')
plt.text(theta0_best, theta1_best,'MSE:'+str(np.round(cal_mse(X,y,theta0_best, theta1_best),2)), color='red', fontsize=22)
### (5.6) Add loss of random lines
if intercept_random != intercept or slope_random != slope: #avoid overlap
plt.plot(intercept_random, slope_random, 'o', ms=5, markeredgewidth=3, color='orange')
plt.text(intercept_random, slope_random,'MSE:'+str(np.round(cal_mse(X,y,intercept_random, slope_random),2)), fontsize=22)
### (5.7) draw gradient updates
if gradient_descent:
plt.plot(b_history, w_history, 'o-', ms=3, lw=1.5, color='black')
plt.title("Visualization of Gradient Descent Process", fontsize=22)
plt.xlabel("$Intercept$", fontsize=22)
plt.ylabel("$Slope$", rotation=0, fontsize=22)
plt.xticks(fontsize=18)
plt.yticks(fontsize=18)
plt.xlim(-10,10)
plt.ylim(-10,10)
### 6. Visualize the learning curves
if gradient_descent:
plt.subplot(3,1,3)
plt.plot(train_mse,label="train_loss (lr="+str(learning_rate)+")")
plt.xlabel('Iteration',fontweight="bold",fontsize = 22)
plt.ylabel('Loss',fontweight="bold",fontsize = 22)
plt.title("Learning curve: Loss VS Epochs",fontweight="bold",fontsize = 22)
plt.legend(fontsize=18)
plt.xticks(fontsize=18)
plt.yticks(fontsize=18)
#plt.show()
fig.tight_layout()
plt.savefig('plot_line.png', dpi=300)
return 'plot_line.png'
#### Define input component
input_intercept = gr.Slider(1, 8, step=0.5, value=1, label='(Baseline) Intercept')
input_slope = gr.Slider(-8, 8, step=0.5, value=2, label='(Baseline) Slope')
input_intercept_random = gr.Slider(-8, 8, step=0.5, value=2, label='(Random) Intercept')
input_slope_random = gr.Slider(-8, 8, step=0.5, value=-1, label='(Random) Slope')
input_gradients = gr.Checkbox(label="Apply Gradient Descent")
input_learningrate = gr.Slider(0,1, step=0.001, value=0.005, label='Learning Rate')
input_iteration = gr.Slider(1, 1000, step=5, value=200, label='Iteration')
#### Define output component
output_plot1 = gr.Image(label="Regression plot")
### configure gradio, detailed can be found at https://www.gradio.app/docs/#i_slider
interface = gr.Interface(fn=gradient_descent,
inputs=[input_intercept, input_slope, input_intercept_random, input_slope_random, input_gradients, input_learningrate, input_iteration],
outputs=[output_plot1],
examples_per_page = 2,
examples = [[4, 3, -7, -5, True, 0.0001, 100], [1, 2, -7, -8, False, 0.0001, 100]],
title="ML Demo: Regression models \n (Function approximation by Gradient Descent)",
description= "Click examples to generate random dataset and select gradient descent parameters",
theme = 'huggingface',
#layout = 'vertical'
)
interface.launch(debug=True)
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