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I'm wondering if there is a simple way to multiply a numpy matrix by a scalar. Essentially I want all values to be multiplied by the constant 40. This would be an nxn matrix with 40's on the diagonal, but I'm wondering if there is a simpler function to use to scale this matrix. Or how would I go about making a matrix with the same shape as my other matrix and fill in its diagonal?

Sorry if this seems a bit basic, but for some reason I couldn't find this in the doc.

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2 Answers

If you want a matrix with 40 on the diagonal and zeros everywhere else, you can use NumPy's function fill_diagonal() on a matrix of zeros. You can thus directly do:

N = 100; value = 40
b = np.fill_diagonal(np.zeros((N, N)), value)

This involves only setting elements to a certain value, and is therefore likely to be faster than code involving multiplying all the elements of a matrix by a constant. This approach also has the advantage of showing explicitly that you fill the diagonal with a specific value.

If you want the diagonal matrix b to be of the same size as another matrix a, you can use the following shortcut (no need for an explicit size N):

b = np.fill_diagonal(np.zeros_like(a), value)
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Easy:

N = 100
a = np.eye(N) # Diagonal Identity 100x100 array
b = 40*a # multiply by a scalar

If you actually want a numpy matrix vs an array, you can do a = np.asmatrix(np.eye(N)) instead. But in general * is element-wise multiplication in numpy.

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If performance is an issue, the OP may not want to create a copy b, in which case a*=40 will scale the array in-place. –  Paul May 2 '11 at 1:11
    
b = np.diag((40*a,)*N) –  cgohlke May 4 '11 at 4:46
    
numpy.fill_diagonal() is specifically meant to fill the diagonal with a given element. As a consequence, it is more explicit and faster than constructing the identity matrix and then multiplying all its elements by a constant. –  EOL Apr 9 '13 at 2:41
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