# cosine similarity optimized implementation

I am trying to understand this optimized code to find cosine similarity between users matrix.

``````def fast_similarity(ratings,epsilon=1e-9):
# epsilon -> small number for handling dived-by-zero errors
sim = ratings.T.dot(ratings) + epsilon
norms = np.array([np.sqrt(np.diagonal(sim))])
return (sim / norms / norms.T)
``````

If ratings =

``````           items
u  [
s    [1,2,3]
e    [4,5,6]
r    [7,8,9]
s  ]
``````

nomrs will be equal to = [1^2 + 5^2 + 9^2]

but why we are writing sim/norms/norms.T to calculate cosine similarity? Any help is appreciated.

Going through the code we have that:

$sim = result^{T}result$

And this means that, one the diagonal of the `sim` matrix we have the result of the multiplication of each column.

You can give it a try if you want using a simple matrix:

$let \ A \ be \begin{bmatrix} 1 & 2 & 3 \\ 4 & 5 & 6 \\ 7 & 8 & 9 \end{bmatrix} so \ if \ we \ compute \ A^{T}A \ it \ will \ be \begin{bmatrix} 66 & 78 & 90 \\ 78 & 93 & 108 \\ 90 & 108 & 126 \end{bmatrix}$

And you can easily check that this gram matrix (that's how this matrix product is named) has this property.

Now the code defines `norms` that is nothing but an array taking the diagonal of our `gram matrix` and apply a sqrt on each element of it.

This will give us an array containing the norm value for each column:

$norm(i) = \sqrt{\sum_{j} column(i)(j)^{2}}$

So basically the `norms` vector contains the norm value of each column of the `result` matrix.

Once we have all those data we can evaluate the cosine similarity between those users, so we know that cosine similarity is evaluated like:

$similarity = \frac{A*B}{\left \| A \right \|*\left \| B \right \|}$

Note that : $A*A = A^{T}*A$

So we have that our similarity is going to be:

$similarity = \frac{A^{T}*A}{\left \| A^{T} \right \|*\left \| A \right \|}$

So we just have to substitute the terms with our code variable to get:

$similarity = \frac{sim}{norms*norms^{T}}$

And this explain why you have this line of code:

``````return sim / norms / norms.T
``````

EDIT: Since it seems that I was not clear, every time I am talking about matrix multiplication in this answer I am reffering to the `DOT PRODUCT` of two matrices.

This actually means that when it's written A*B we actually develop and solve as A.T * B

• You meant `A * B = transpose(A) * A`? Mar 29, 2017 at 9:29
• we are talking about `dot product` Mar 29, 2017 at 9:34
• Then it would be better, if you explicitly specify. Mar 29, 2017 at 9:36
• how you are substituting norms = A.T since norms in above example = [66,93,126] and A.T is 3x3 matrix as shown above Mar 29, 2017 at 9:46
• where did you read norms = A.T? I wrote: `the code defines norms that is nothing but an array taking the diagonal of our gram matrix and apply a sqrt on each element of it.` Mar 29, 2017 at 9:49