# 2-D convolution as a matrix-matrix multiplication [closed]

I know that, in the 1D case, the convolution between two vectors, `a` and `b`, can be computed as `conv(a, b)`, but also as the product between the `T_a` and `b`, where `T_a` is the corresponding Toeplitz matrix for `a`.

Is it possible to extend this idea to 2D?

Given `a = [5 1 3; 1 1 2; 2 1 3]` and `b=[4 3; 1 2]`, is it possible to convert `a` in a Toeplitz matrix and compute the matrix-matrix product between `T_a` and `b` as in the 1-D case?

• – nbro
Jun 14, 2020 at 13:59
• I’m voting to close this question because it is not about programming as defined in the help center but about ML theory and/or methodology - please see the intro and NOTE in the `deep-learning` tag info. Jun 28, 2021 at 16:01

Yes, it is possible and you should also use a doubly block circulant matrix (which is a special case of Toeplitz matrix). I will give you an example with a small size of kernel and the input, but it is possible to construct Toeplitz matrix for any kernel. So you have a 2d input `x` and 2d kernel `k` and you want to calculate the convolution `x * k`. Also let's assume that `k` is already flipped. Let's also assume that `x` is of size `n×n` and `k` is `m×m`.

So you unroll `k` into a sparse matrix of size `(n-m+1)^2 × n^2`, and unroll `x` into a long vector `n^2 × 1`. You compute a multiplication of this sparse matrix with a vector and convert the resulting vector (which will have a size `(n-m+1)^2 × 1`) into a `n-m+1` square matrix.

I am pretty sure this is hard to understand just from reading. So here is an example for 2×2 kernel and 3×3 input.

*

Here is a constructed matrix with a vector:

which is equal to .

And this is the same result you would have got by doing a sliding window of `k` over `x`.

• There would have to be some sort of reshaping at the end correct? That last vector is 4 x 1 but the result of the convolution would be 2 x 2 Jun 12, 2017 at 17:11
• @jvans yes, in the end you should reshape your vector. It is written here: convert the resulting vector (which will have a size (n-m+1)^2 X 1) into a n-m+1 square matrix Jun 12, 2017 at 18:14
• In your example this is not a Toeplitz matrix. So you answer is only partially correct, is it ? Mar 14, 2018 at 17:18
• What you mean by `Also let's assume that k is already flipped`? Is it because we want to perform correlation instead of convolution? What is `flipped` in terms of numpy operations? Sep 9, 2018 at 16:47
• So what are the details? How should `k` be unrolled into a sparse matrix? Sep 25, 2019 at 0:50

## 1- Define Input and Filter

Let I be the input signal and F be the filter or kernel.

## 2- Calculate the final output size

If the I is m1 x n1 and F is m2 x n2 the size of the output will be:

## 3- Zero-pad the filter matrix

Zero pad the filter to make it the same size as the output.

## 5- Create a doubly blocked Toeplitz matrix

Now all these small Toeplitz matrices should be arranged in a big doubly blocked Toeplitz matrix.

## 7- Multiply doubly blocked toeplitz matrix with vectorized input signal

This multiplication gives the convolution result.

## 8- Last step: reshape the result to a matrix form

For more details and python code take a look at my github repository:

Step by step explanation of 2D convolution implemented as matrix multiplication using toeplitz matrices in python

• I think there is an error. The first element of the result should be 10*0 + 20*0 + 30*0 +40*1 = 40. The element in position 2,2 should be 1*10 + 2*20 + 4*30 + 5*40 = 370. I think your result is correct for a matrix F equal to [40 30; 20 10] that is exactly F flipping both rows and columns. There is therefore an error in the procedure
– Luca
Jun 13, 2019 at 16:10
• It is doing convolution (mathematical convolution, not cross-correlation), so if you are doing it by hand, you need to flip the filter both vertically and horizontally. You can find more information on my GitHub repo. Jun 13, 2019 at 16:15
• This is a great explanation of 2D convolution as a matrix operation. Is there a way to represent "mode='same'" also? (i.e. keeping the output shape the same as the image)? Apr 14, 2021 at 21:33
• @ajl123 I think it should be. I'll work on it if I get time. Please feel free to dig into the code and math and send me a pull request on Github if you get the answer. Apr 14, 2021 at 22:09
• shouldn't the dimension of the resulting matrix decrease? Apr 27, 2021 at 12:53

If you unravel k to a m^2 vector and unroll X, you would then get:

• a `m**2` vector`k`
• a `((n-m)**2, m**2)` matrix for `unrolled_X`

where `unrolled_X` could be obtained by the following Python code:

``````from numpy import zeros

def unroll_matrix(X, m):
flat_X = X.flatten()
n = X.shape[0]
unrolled_X = zeros(((n - m) ** 2, m**2))
skipped = 0
for i in range(n ** 2):
if (i % n) < n - m and ((i / n) % n) < n - m:
for j in range(m):
for l in range(m):
unrolled_X[i - skipped, j * m + l] = flat_X[i + j * n + l]
else:
skipped += 1
return unrolled_X
``````

Unrolling X and not k allows a more compact representation (smaller matrices) than the other way around for each X - but you need to unroll each X. You could prefer unrolling k depending on what you want to do.

Here, the `unrolled_X` is not sparse, whereas `unrolled_k` would be sparse, but of size `((n-m+1)^2,n^2)` as @Salvador Dali mentioned.

Unrolling `k` could be done like this:

``````from scipy.sparse import lil_matrix
from numpy import zeros
import scipy

def unroll_kernel(kernel, n, sparse=True):

m = kernel.shape[0]
if sparse:
unrolled_K = lil_matrix(((n - m)**2, n**2))
else:
unrolled_K = zeros(((n - m)**2, n**2))

skipped = 0
for i in range(n ** 2):
if (i % n) < n - m and((i / n) % n) < n - m:
for j in range(m):
for l in range(m):
unrolled_K[i - skipped, i + j * n + l] = kernel[j, l]
else:
skipped += 1
return unrolled_K
``````

The code shown above doesn't produce the unrolled matrix of the right dimensions. The dimension should be (n-k+1)*(m-k+1), (k)(k). k: filter dimension, n: num rows in input matrix, m: num columns.

``````def unfold_matrix(X, k):
n, m = X.shape[0:2]
xx = zeros(((n - k + 1) * (m - k + 1), k**2))
row_num = 0
def make_row(x):
return x.flatten()

for i in range(n- k+ 1):
for j in range(m - k + 1):
#collect block of m*m elements and convert to row
xx[row_num,:] = make_row(X[i:i+k, j:j+k])
row_num = row_num + 1

return xx
``````

For more details, see my blog post:

http://www.telesens.co/2018/04/09/initializing-weights-for-the-convolutional-and-fully-connected-layers/