I'm trying to create a program that takes a square (n-by-n) matrix as input, and if it is invertible, will LU decompose the matrix using Gaussian Elimination.

Here is my problem: in class we learned that it is better to change rows so that your pivot is always the largest number (in absolute value) in its column. For example, if the matrix was `A = [1,2;3,4]`

then switching rows it is `[3,4;1,2]`

and then we can proceed with the Gaussian elimination.

My code works properly for matrices that don't require row changes, but for ones that do, it does not. This is my code:

```
function newgauss(A)
[rows,columns]=size(A);
P=eye(rows,columns); %P is permutation matrix
if(det(A)==0) %% determinante is 0 means no single solution
disp('No solutions or infinite number of solutions')
return;
end
U=A;
L=eye(rows,columns);
pivot=1;
while(pivot<rows)
max=abs(U(pivot,pivot));
maxi=0;%%find maximum abs value in column pivot
for i=pivot+1:rows
if(abs(U(i,pivot))>max)
max=abs(U(i,pivot));
maxi=i;
end
end %%if needed then switch
if(maxi~=0)
temp=U(pivot,:);
U(pivot,:)=U(maxi,:);
U(maxi,:)=temp;
temp=P(pivot,:);
P(pivot,:)=P(maxi,:);
P(maxi,:)=temp;
end %%Grade the column pivot using gauss elimination
for i=pivot+1:rows
num=U(i,pivot)/U(pivot,pivot);
U(i,:)=U(i,:)-num*U(pivot,:);
L(i,pivot)=num;
end
pivot=pivot+1;
end
disp('PA is:');
disp(P*A);
disp('LU is:');
disp(L*U);
end
```

Clarification: since we are switching rows, we are looking to decompose `P`

(permutation matrix) times `A`

, and not the original `A`

that we had as input.

Explanation of the code:

- First I check if the matrix is invertible, if it isn't, stop. If it is, pivot is (1,1)
- I find the largest number in column 1, and switch rows
- Grade column 1 using Gaussian elimination, turning all but the spot (1,1) to zero
- Pivot is now (2,2), find largest number in column 2... Rinse, repeat

`maxi~=0`

, use a threshold. Also avoid using variable names that are also names of builtin functions (`max`

), it is just confusing – Amro Jul 22 '13 at 1:01