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I am trying to generate symmetric matrices in numpy. Specifically, these matrices are to have random places entries, and in each entry the contents can be random. Along the main diagonal we are not concerned with what enties are in there, so I have randomized those as well.

The approach I have taken is to first generate a nxn all zero matrix and simply loop over the indices of the matrices. However, given considering looping is relatively expensive in python, I'm wondering if I can acheive the same thing without using python's for loops.

Is there some things built into numpy that allow me to acheive my goal more efficiently?

Here is my current code:

import numpy as np
import random

def empty(x, y):
    return x*0

b = np.fromfunction(empty, (n, n), dtype = int)

for i in range(0, n):
    for j in range(0, n):
        if i == j:
            b[i][j] = random.randrange(-2000, 2000)
            switch = random.random()
            if switch > random.random():
                a = random.randrange(-2000, 2000)
                b[i][j] = a
                b[j][i] = a
                b[i][j] = 0
                b[j][i] = 0
share|improve this question
up vote 9 down vote accepted

You could just do something like:

import numpy as np

N = 100
b = np.random.random_integers(-2000,2000,size=(N,N))
b_symm = (b + b.T)/2

Where you can choose from whatever distribution you want in the np.random or equivalent scipy module.

Update: If you are trying to build graph-like structures, definitely check out the networkx package:


which has a number of built-in routines to build graphs:


Also if you want to add some number of randomly placed zeros, you can always generate a random set of indices and replace the values with zero.

share|improve this answer
Thanks! That is an efficient solution. However, is there some way I can get it to place zeros in places randomly? This matrix is supposed to represent an kind of adjacency matrix for a graph, so having a matrix with randomly distributed zero's is preferable. – Ryan May 29 '12 at 21:43
@Ryan: Do you care what kind of distribution the random entries have? If you add b + b.T, you will get a non-uniform distribution concentrated around 0. – unutbu May 29 '12 at 21:56
I am verifying some properties of matrices. Its more an effort to provide convincing evidence of some mathematical properties, so the distribution here is not so important. Thanks though! – Ryan May 30 '12 at 1:17
@unutbu , true, use np.tril(a) + np.tril(a, -1).T then. – Ben Usman Dec 6 '14 at 11:57

I'd better do:

a = np.random.rand(N, N)
m = np.tril(a) + np.tril(a, -1).T

because in this case all elements of a matrix are from same distribution (uniform in this case).

share|improve this answer

If you don't mind having zeros on the diagonal you could use the following snippet:

def random_symmetric_matrix(n):
    _R = np.random.uniform(-1,1,n*(n-1)/2)
    P = np.zeros((n,n))
    P[np.triu_indices(n, 1)] = _R
    P[np.tril_indices(n, -1)] = P.T[np.tril_indices(n, -1)]
    return P

Note that you only need to generate n*(n-1)/2 random variables due to the symmetry.

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