Difference between revisions of "FctExampleCode"
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function [b,bse,res,n,rss,r2] = OLSest(y,x,output); | function [b,bse,res,n,rss,r2] = OLSest(y,x,output); | ||
% This function performs an OLS estimation | % This function performs an OLS estimation | ||
| + | % function [b,bse,res,n,rss,r2] = OLSest(y,x,output) | ||
% input: y, vector with dependent variable | % input: y, vector with dependent variable | ||
% x, matrix with explanatory variable | % x, matrix with explanatory variable | ||
Revision as of 20:21, 29 September 2012
Example MATLAB Code
This code is to be used with the Function discussion.
FunctionExample.m
Copy this code into a m file which you call FunctionExample.m.
% This code loads data from a spreadsheet and uses OLSest to run a
% regresion
[data,titles]=xlsread('OLSexample.xls');
n = size(data,1);
depvar = data(:,1);
expvar = [ones(n,1) data(:,2:end)];
[bhat,bhatse,resids,obs,resss,rsq] = OLSest(depvar,expvar,0);
disp(bhat);
temp = 2;
OLSest.m
Copy this code into a m file which you call OLSest.m.
function [b,bse,res,n,rss,r2] = OLSest(y,x,output);
% This function performs an OLS estimation
% function [b,bse,res,n,rss,r2] = OLSest(y,x,output)
% input: y, vector with dependent variable
% x, matrix with explanatory variable
% function will automatically add a constant if the first col
% is not a vector of ones
% output, 1 = printed output
% output: b, estimated parameters
% bse, standard errors for bhat
% res, estimated residuals
% n, number of observations used
% rss, residual sum of squares
% r2, Rsquared
% select those rows that have observations for all variables
ninit = length(y);
testnan = [isnan(y) isnan(x)];
testnan = (sum(testnan,2)==0);
y = y(testnan);
x = x(testnan,:);
% test whether first column is vector of ones
temp = (x(x(:,1)==1));
if length(temp) ~= length(x)
x = [ones(length(x),1) x]; % add constant of not included in x
end
[n,k] = size(x); % sample size - n, number of explan vars (incl constant) - k
xxi = inv(x'*x); % Note that this is the inefficient way of calculating
% the inverse of x'*x, but as xxi is required later for
% the calculation of bse, we are not really loosing
% anything
b = xxi*x'*y;
res = y - x*b;
rss = res'*res;
ssq = rss/(n-k);
s = sqrt(ssq);
bse = ssq*xxi;
bse = sqrt(diag(bse));
tstat = b./bse;
pval = 2*(1-tcdf(abs(tstat),n-k));
ym = y - mean(y);
r2 = 1 - (res'*res)/(ym'*ym);
adjr2 = 1 - (n-1)*(1-r2)/(n-k);
fstat = ((((ym'*ym))-(res'*res))/(k-1))/((res'*res)/(n-k));
pvalf = 1- fcdf(fstat,k-1,n-k);
dw = corrcoef([res(1:end-1) res(2:end)]);
dw = 2*(1-dw(2,1));
if output
fprintf('===========================================================\n');
fprintf('===== Regression Output ==================================\n');
fprintf('Obs used = %4.0f, missing obs = %4.0f \n',n,(ninit-n));
fprintf('Rsquared = %5.4f \n',r2);
fprintf('adj_Rsq = %5.4f \n',adjr2);
fprintf('===== Estimated Model Parameters ==========================\n');
fprintf('= Par se(Par) t(Par) pval ==================\n');
format short;
disp([b bse tstat pval]);
fprintf('===== Model Statistics ====================================\n');
fprintf(' Fstat = %5.4f (%5.4f)\n',[fstat;pvalf]);
fprintf(' standard error = %5.4f\n',sqrt(ssq));
fprintf(' RSS = %5.4f\n',rss);
fprintf(' Durbin-Watson = %5.4f\n',dw);
fprintf('===========================================================\n');
end
temp = 2;
Copy this code into a m file which you call FunctionExample.m.
% This code loads data from a spreadsheet and uses OLSest to run a
% regresion
[data,titles]=xlsread('OLSexample.xls');
n = size(data,1);
depvar = data(:,1);
expvar = [ones(n,1) data(:,2:end)];
[bhat,bhatse,resids,obs,resss,rsq] = OLSest(depvar,expvar,0);
disp(bhat);
temp = 2;OLSest.m
Copy this code into a m file which you call OLSest.m.
function [b,bse,res,n,rss,r2] = OLSest(y,x,output);
% This function performs an OLS estimation
% function [b,bse,res,n,rss,r2] = OLSest(y,x,output)
% input: y, vector with dependent variable
% x, matrix with explanatory variable
% function will automatically add a constant if the first col
% is not a vector of ones
% output, 1 = printed output
% output: b, estimated parameters
% bse, standard errors for bhat
% res, estimated residuals
% n, number of observations used
% rss, residual sum of squares
% r2, Rsquared
% select those rows that have observations for all variables
ninit = length(y);
testnan = [isnan(y) isnan(x)];
testnan = (sum(testnan,2)==0);
y = y(testnan);
x = x(testnan,:);
% test whether first column is vector of ones
temp = (x(x(:,1)==1));
if length(temp) ~= length(x)
x = [ones(length(x),1) x]; % add constant of not included in x
end
[n,k] = size(x); % sample size - n, number of explan vars (incl constant) - k
xxi = inv(x'*x); % Note that this is the inefficient way of calculating
% the inverse of x'*x, but as xxi is required later for
% the calculation of bse, we are not really loosing
% anything
b = xxi*x'*y;
res = y - x*b;
rss = res'*res;
ssq = rss/(n-k);
s = sqrt(ssq);
bse = ssq*xxi;
bse = sqrt(diag(bse));
tstat = b./bse;
pval = 2*(1-tcdf(abs(tstat),n-k));
ym = y - mean(y);
r2 = 1 - (res'*res)/(ym'*ym);
adjr2 = 1 - (n-1)*(1-r2)/(n-k);
fstat = ((((ym'*ym))-(res'*res))/(k-1))/((res'*res)/(n-k));
pvalf = 1- fcdf(fstat,k-1,n-k);
dw = corrcoef([res(1:end-1) res(2:end)]);
dw = 2*(1-dw(2,1));
if output
fprintf('===========================================================\n');
fprintf('===== Regression Output ==================================\n');
fprintf('Obs used = %4.0f, missing obs = %4.0f \n',n,(ninit-n));
fprintf('Rsquared = %5.4f \n',r2);
fprintf('adj_Rsq = %5.4f \n',adjr2);
fprintf('===== Estimated Model Parameters ==========================\n');
fprintf('= Par se(Par) t(Par) pval ==================\n');
format short;
disp([b bse tstat pval]);
fprintf('===== Model Statistics ====================================\n');
fprintf(' Fstat = %5.4f (%5.4f)\n',[fstat;pvalf]);
fprintf(' standard error = %5.4f\n',sqrt(ssq));
fprintf(' RSS = %5.4f\n',rss);
fprintf(' Durbin-Watson = %5.4f\n',dw);
fprintf('===========================================================\n');
end
temp = 2;
