clc
clear all
format short
%To solve the LPP by Simplex Method
%Min z=x1-3x2+2x3
%Subject to 3x1-x2+2x3<=7
%-2x1+4x2<=12
%-4x1+3x2+8x3<=10
%x1,x2,x3>=0
%First to change the objective function from minimization to maximization
%Max z=-x1+3x2-2x3
%To input parameters
C=[-1 3 -2]
info=[3 -1 2;-2 4 0; -4 3 8]
b=[7; 12; 10]
NOVariables=size(info,2)
s=eye(size(info,1))
A=[info s b]
Cost=zeros(1,size(A,2))
Cost(1:NOVariables)=C
BV=NOVariables+1:size(A,2)-1
%To calculate Z-Row(Zj-Cj)
ZRow=Cost(BV)*A-Cost
%To print the table
ZjCj=[ZRow; A]
SimpTable=array2table(ZjCj)
SimpTable.Properties.VariableNames(1:size(ZjCj,2))={'x_1','x_2','x_3','s_1','s_2','s_3','Sol'}
%Simplex Table Starts
Run=true;
while Run
if any(ZRow<0) %To check any negative value is there
fprintf('The current BFS is not optimal \n')
fprintf('\n=========The next iteration continues========\n')
disp('Old Basic Variable (BV)=')
disp(BV)
% To find entering Variable
ZC=ZRow(1:end-1)
[EnterCol, Pvt_Col]=min(ZC)
fprintf('The most negative element in Z-Row is %d Corresponding to Column %d \n', EnterCol, Pvt_Col)
fprintf('Entering Variable is %d \n', Pvt_Col)
%To find the leaving variable
sol=A(:,end)
Column=A(:,Pvt_Col)
if all(Column<=0)
error('LPP has unbounded solution. All entries <= 0 in column %d', Pvt_Col)
else
% To check minimum ratio is with positive entering column entries
for i=1:size(Column,1)
if Column(i)>0
ratio(i)=sol(i)./Column(i)
else
ratio(i)=inf
end
end
%To finding minimum ratio
[MinRatio, Pvt_Row]=min(ratio)
fprintf('Minimum ratio corresponding to pivot row is %d \n', Pvt_Row)
fprintf('Leaving Variable is %d \n', BV(Pvt_Row))
end
BV(Pvt_Row)=Pvt_Col
disp('New Basic Variables (BV) =')
disp(BV)
%Pivot Key
Pvt_Key=A(Pvt_Row,Pvt_Col)
%Update Table for next iteration
A(Pvt_Row,:)=A(Pvt_Row,:)./Pvt_Key
for i=1:size(A,1)
if i~=Pvt_Row
A(i,:)=A(i,:)-A(i,Pvt_Col).*A(Pvt_Row,:)
end
ZRow=ZRow-ZRow(Pvt_Col).*A(Pvt_Row,:)
%To print the updated table
ZjCj=[ZRow;A]
SimpTable=array2table(ZjCj)
SimpTable.Properties.VariableNames(1:size(ZjCj,2))={'x_1','x_2','x_3','s_1','s_2','s_3','Sol'}
BFS=zeros(1,size(A,2))
BFS(BV)=A(:,end)
BFS(end)=sum(BFS.*Cost)
CurrentBFS=array2table(BFS)
CurrentBFS.Properties.VariableNames(1:size(CurrentBFS,2))={'x_1','x_2','x_3','s_1','s_2','s_3','Sol'}
end
else
Run=false
fprintf('The current BFS is optimal and Optimality is reached \n')
end
end
