转载链接:http://www.cnblogs.com/tornadomeet/archive/2013/03/15/2961660.html
前言
本文是多元线性回归的练习,这里练习的是最简单的二元线性回归,参考斯坦福大学的教学网http://openclassroom.stanford.edu/MainFolder/DocumentPage.php?course=DeepLearning&doc=exercises/ex2/ex2.html。本题给出的是50个数据样本点,其中x为这50个小朋友到的年龄,年龄为2岁到8岁,年龄可有小数形式呈现。Y为这50个小朋友对应的身高,当然也是小数形式表示的。现在的问题是要根据这50个训练样本,估计出3.5岁和7岁时小孩子的身高。通过画出训练样本点的分布凭直觉可以发现这是一个典型的线性回归问题。
matlab函数介绍:
legend:
比如legend('Training data', 'Linear regression'),它表示的是标出图像中各曲线标志所代表的意义,这里图像的第一条曲线(其实是离散的点)表示的是训练样本数据,第二条曲线(其实是一条直线)表示的是回归曲线。
hold on, hold off:
hold on指在前一幅图的情况下打开画纸,允许在上面继续画曲线。hold off指关闭前一副画的画纸。
linspace:
比如linspace(-3, 3, 100)指的是给出-3到3之间的100个数,均匀的选取,即线性的选取。
logspace:
比如logspace(-2, 2, 15),指的是在10^(-2)到10^(2)之间选取15个数,这些数按照指数大小来选取,即指数部分是均匀选取的,但是由于都取了10为底的指数,所以最终是服从指数分布选取的。
实验结果:
训练样本散点和回归曲线预测图:
损失函数与参数之间的曲面图:
损失函数的等高线图:
程序代码及注释:
(1)采用正规方程求解:
%%方法一
x = load('ex2x.dat');
y = load('ex2y.dat');
plot(x,y,'*')
xlabel('height')
ylabel('age')
x = [ones(size(x),),x];
w=inv(x'*x)*x'*y
hold on
%plot(x,0.0639*x+0.7502)
plot(x(:,),0.0639*x(:,)+0.7502)%更正后的代码
(2)采用BGD方法:
% Exercise Linear Regression % Data is roughly based on CDC growth figures
% for boys
%
% x refers to a boy's age
% y is a boy's height in meters
% clear all; close all; clc
x = load('ex2x.dat'); y = load('ex2y.dat'); m = length(y); % number of training examples % Plot the training data
figure; % open a new figure window
plot(x, y, 'o');
ylabel('Height in meters')
xlabel('Age in years') % Gradient descent
x = [ones(m, ) x]; % Add a column of ones to x
theta = zeros(size(x(,:)))'; % initialize fitting parameters
MAX_ITR = ;
alpha = 0.07; for num_iterations = :MAX_ITR
% This is a vectorized version of the
% gradient descent update formula
% It's also fine to use the summation formula from the videos % Here is the gradient
grad = (/m).* x' * ((x * theta) - y); % Here is the actual update
theta = theta - alpha .* grad; % Sequential update: The wrong way to do gradient descent
% grad1 = (/m).* x(:,)' * ((x * theta) - y);
% theta() = theta() + alpha*grad1;
% grad2 = (/m).* x(:,)' * ((x * theta) - y);
% theta() = theta() + alpha*grad2;
end
% print theta to screen
theta % Plot the linear fit
hold on; % keep previous plot visible
plot(x(:,), x*theta, '-')
legend('Training data', 'Linear regression')%标出图像中各曲线标志所代表的意义
hold off % don't overlay any more plots on this figure,指关掉前面的那幅图 % Closed form solution for reference
% You will learn about this method in future videos
exact_theta = (x' * x)\x' * y % Predict values for age 3.5 and
predict1 = [, 3.5] *theta
predict2 = [, ] * theta % Calculate J matrix % Grid over which we will calculate J
theta0_vals = linspace(-, , );
theta1_vals = linspace(-, , ); % initialize J_vals to a matrix of 's
J_vals = zeros(length(theta0_vals), length(theta1_vals)); for i = :length(theta0_vals)
for j = :length(theta1_vals)
t = [theta0_vals(i); theta1_vals(j)];
J_vals(i,j) = (0.5/m) .* (x * t - y)' * (x * t - y);
end
end %Surf() :绘制某一区间内的完整曲面;matlab的surf函数中是在z的线性存储中,先固定y然后移动x,顺序选取。也就是说,Z(i,j)是在x(j),y(i)时候选取的。所以必须在绘制图形的时候对z转置
J_vals = J_vals';
% Surface plot
figure;
surf(theta0_vals, theta1_vals, J_vals)
xlabel('\theta_0'); ylabel('\theta_1'); % Contour plot
figure;
% Plot J_vals as contours spaced logarithmically between 0.01 and
contour(theta0_vals, theta1_vals, J_vals, logspace(-, , ))%画出等高线
xlabel('\theta_0'); ylabel('\theta_1');%类似于转义字符,但是最多只能是到参数0~
参考资料: