Answer to Question #221270 in Operations Research for Viy

"\\text{The initial tableau for this problem is: }\\\\\\begin{matrix} & &&&140 \\\\\\hline &&&&160\\\\\\hline&&&&50\\\\\\hline100&100&50&100 \\end{matrix} \\\\\\text{Using North-west corner method, we locate the upper-most variable$(X_{1A})$ in the }\\\\\\text{tableau and set it to the min(100,140) = 100 and we cancel out column 1} \\\\\\begin{matrix} 100& &&&40 \\\\\\hline &&&&160\\\\\\hline&&&&50\\\\\\hline X&100&50&100 \\end{matrix} \\\\\\text{Repeating the process, we obtain the following tableaus} \\\\\\begin{matrix} 100& 40&&&X\\\\\\hline &&&&160\\\\\\hline&&&&50\\\\\\hline X&60&50&100 \\end{matrix} \\\\\\begin{matrix} 100& 40&&&X\\\\\\hline &&&&100\\\\\\hline&&&&50\\\\\\hline X&X&50&100 \\end{matrix} \\\\ \\\\\\begin{matrix} 100& 40&&&X\\\\\\hline &60&50&&50\\\\\\hline&&&&50\\\\\\hline X&X&X&100 \\end{matrix} \\\\\\begin{matrix} 100& 40&&&X\\\\\\hline &60&50&50&X\\\\\\hline&&&&50\\\\\\hline X&X&X&50 \\end{matrix} \\\\\\begin{matrix} 100& 40&&&X\\\\\\hline &60&50&50&X\\\\\\hline&&&50&X\\\\\\hline X&X&X&X \\end{matrix} \\\\\\text{Therefore, the solution is feasible, the solution is $X_{1A}=100,X_{1B}=40,X_{2B}=60$,}\\\\\\text{$X_{2C}=50,X_{2D}=50,X_{3D}=50,C=5570$} \\\\\\text{We locate the smallest cost(10) at $X_{2A}$ in our initial matrix, we then set the value of $X_{2A}$}\\\\\\text{to the min(100,160). Next,we cross out column 1 and reduce $S_2$(160) to 160-100=60. We }\\\\\\text{repeat the process for the remaining uncrossed out rows and columns to obtain the final tableau}\\\\ \\\\\\begin{matrix} & 100&&40&X\\\\\\hline 100 &&&60&X\\\\\\hline&0&50&&X\\\\\\hline X&X&X&X \\end{matrix} \\\\\\text{Therefore, the initial feasible solution is }\\\\X_{1B}=100,X_{1D}=40,X_{2A}=100,X_{2D}=60, X_{3B}=0,X_{3C}=50,z=5430 \\\\\\text{Next, we use the Vogel's approximation method to find the basic feasible solution. We }\\\\\\text{compute the penalties by computing the difference between the smallest numbers in each}\\\\\\text{row, we select the row with the largest penalty, after which we select the variable with }\\\\\\text{the smallest value.}\\\\\\text{From the table below, column 3 has the largest penalty, we choose $X_{3C}$ since has the smallest}\\\\\\text{cost} \\\\\\begin{matrix} 14 & 25&13&18&140 &&&14-13=1 \\\\\\hline 10 &12&13&11&160&&&11-10=1\\\\\\hline15&20&11&25&50&&&15-11=4\\\\\\hline100&100&50&100&&& \\end{matrix} \\\\\\text{Repeating the process, we obtain the final tableau} \\\\\\begin{matrix} 100 &&&40&X\\\\\\hline &100&&60&X\\\\\\hline0&&50&&X\\\\\\hline X&X&X&X \\end{matrix} \\\\X_{1A}=100,X_{1D}=40,X_{2B}=100,X_{2D}=60, X_{3A}=0,X_{3C}=50,z=4530"