# How does GNU Octave matrix division work? Getting unexpected behaviour.

In GNU Octave, How does matrix division work?

``````1./[1;1]
``````

I accidentally did

``````1/[1;1]
``````

To my surprise this yields:

``````[0.5, 0.5]
``````

The transverse case:

``````1/[1,1]
``````

gives the expected:

``````error: operator /: nonconformant arguments (op1 is 1x1, op2 is 1x2)
``````

Can someone explain the [0.5, 0.5] result?

-

this is a answer i got from Alan Boulton at the coursera machine learning course discussion forum:

The gist of the idea is that x / y is defined quite generally so that it can deal with matrices. Conceptually the / operator is trying to return x∗y−1 (or x * inv(y) in Octave-speak), as in the following example:

``````octave:1> eye(2)/[1 2;3 4]
ans =
-2.00000   1.00000
1.50000  -0.50000

octave:2> inv([1 2;3 4])
ans =
-2.00000   1.00000
1.50000  -0.50000
``````

The trickiness happens when y is a column vector, in which case the inv(y) is undefined, so pinv(y), the psuedoinverse of y, is used.

``````octave:1> pinv([1;2])
ans =
0.20000   0.40000

octave:2> 1/[1;2]
ans =
0.20000   0.40000
``````

The vector y needs to be compatible with x so that x * pinv(y) is well-defined. So it's ok if y is a row vector, so long as x is compatible. See the following Octave session for illustration:

``````octave:18> pinv([1 2])
ans =
0.20000
0.40000

octave:19> 1/[1 2]
error: operator /: nonconformant arguments (op1 is 1x1, op2 is 1x2)
octave:19> eye(2)/[1 2]
ans =
0.20000
0.40000

octave:20> eye(2)/[1;2]
error: operator /: nonconformant arguments (op1 is 2x2, op2 is 2x1)
octave:20> 1/[1;2]
ans =
0.20000   0.40000
``````
-

## Matrix division with Octave explained:

A formal description of Octave Matrix Division from here

http://www.gnu.org/software/octave/doc/interpreter/Arithmetic-Ops.html

``````x / y
Right division. This is conceptually equivalent to the expression
(inverse (y') * x')'

But it is computed without forming the inverse of y'.

If the system is not square, or if the coefficient matrix is
singular, a minimum norm solution is computed.
``````

What that means is that these two should be the same:

``````[3 4]/[4 5; 6 7]
ans =
1.50000  -0.50000

(inverse([4 5; 6 7]') * [3 4]')'
ans =
1.50000  -0.50000
``````

First, understand that Octave matrix division is not commutative, just like matrix Multiplication is not commutative.

That means A / B does not equal B / A

``````1/[1;1]
ans =
0.50000   0.50000

[1;1]/1
ans =
1
1
``````

One divided by a matrix with a single value one is one:

``````1/[1]
ans = 1
``````

One divided by a matrix with a single value three is 0.33333:

``````1/[3]
ans = .33333
``````

One divided by a (1x2) matrix:

``````1/[1;1]
ans =
0.50000   0.50000

Equivalent:

([1/2;1/2] * 1)'
ans =
0.50000   0.50000
``````

Notice above, like the instructions said, we are taking the norm of the vector. So you see how the `[1;1]` was turned into `[1/2; 1/2]`. The '2' comes from the length of the vector, the 1 comes from the supplied vector. We'll do another:

One divided by a (1x3) matrix:

``````1/[1;1;1]
ans =
0.33333   0.33333   0.33333
``````

Equivalent:

`````` ([1/3;1/3;1/3] * 1)'
ans =
0.33333   0.33333   0.33333
``````

What if one of the elements are negative...

``````1/[1;1;-1]
ans =
0.33333   0.33333  -0.33333
``````

Equivalent:

``````([1/3;1/3;-1/3] * 1)'
ans =
0.33333   0.33333  -0.33333
``````

So now you have a general idea of what Octave is doing when you don't supply it a square matrix. To understand what Octave matrix division does when you pass it a square matrix you need to understand what the inverse function is doing.

I've been normalizing your vectors by hand, if you want octave to do them you can add packages to do so, I think the following package will do what I've been doing with the vector normalization:

http://octave.sourceforge.net/geometry/function/normalizeVector.html

So now you can convert the division into an equivalent multiplication. Read this article on how matrix multiplication works, and you can backtrack and figure out what is going on under the hood of a matrix division.

http://www.purplemath.com/modules/mtrxmult2.htm

-
and the case: 1/[1,1]? –  eyaler Sep 4 '12 at 21:06