I'd like to generate matrices of size mxn and rank r, with elements coming from a specified finite set, e.g. {0,1} or {1,2,3,4,5}. I want them to be "random" in some very loose sense of that word, i.e. I want to get a variety of possible outputs from the algorithm with distribution vaguely similar to the distribution of all matrices over that set of elements with the specified rank.

In fact, I don't actually care that it has rank r, just that it's close to a matrix of rank r (measured by the Frobenius norm).

When the set at hand is the reals, I've been doing the following, which is perfectly adequate for my needs: generate matrices U of size mxr and V of nxr, with elements independently sampled from e.g. Normal(0, 2). Then U V' is an mxn matrix of rank r (well, <= r, but I think it's r with high probability).

If I just do that and then round to binary / 1-5, though, the rank increases.

It's also possible to get a lower-rank approximation to a matrix by doing an SVD and taking the first r singular values. Those values, though, won't lie in the desired set, and rounding them will again increase the rank.

This question is related, but accepted answer isn't "random," and the other answer suggests SVD, which doesn't work here as noted.

One possibility I've thought of is to make r linearly independent row or column vectors from the set and then get the rest of the matrix by linear combinations of those. I'm not really clear, though, either on how to get "random" linearly independent vectors, or how to combine them in a quasirandom way after that.

(Not that it's super-relevant, but I'm doing this in numpy.)

Update: I've tried the approach suggested by EMS in the comments, with this simple implementation:

real = np.dot(np.random.normal(0, 1, (10, 3)), np.random.normal(0, 1, (3, 10)))
bin = (real > .5).astype(int)
rank = np.linalg.matrix_rank(bin)
niter = 0

while rank > des_rank:
    cand_changes = np.zeros((21, 5))
    for n in range(20):
        i, j = random.randrange(5), random.randrange(5)
        v = 1 - bin[i,j]
        x = bin.copy()
        x[i, j] = v
        x_rank = np.linalg.matrix_rank(x)
        cand_changes[n,:] = (i, j, v, x_rank, max((rank + 1e-4) - x_rank, 0))
    cand_changes[-1,:] = (0, 0, bin[0,0], rank, 1e-4)

    cdf = np.cumsum(cand_changes[:,-1])
    cdf /= cdf[-1]
    i, j, v, rank, score = cand_changes[np.searchsorted(cdf, random.random()), :]
    bin[i, j] = v
    niter += 1
    if niter % 1000 == 0:
        print(niter, rank)

It works quickly for small matrices but falls apart for e.g. 10x10 -- it seems to get stuck at rank 6 or 7, at least for hundreds of thousands of iterations.

It seems like this might work better with a better (ie less-flat) objective function, but I don't know what that would be.

I've also tried a simple rejection method for building up the matrix:

def fill_matrix(m, n, r, vals):
    assert m >= r and n >= r
    trans = False
    if m > n: # more columns than rows I think is better
        m, n = n, m
        trans = True

    get_vec = lambda: np.array([random.choice(vals) for i in range(n)])

    vecs = []
    n_rejects = 0

    # fill in r linearly independent rows
    while len(vecs) < r:
        v = get_vec()
        if np.linalg.matrix_rank(np.vstack(vecs + [v])) > len(vecs):
            n_rejects += 1
    print("have {} independent ({} rejects)".format(r, n_rejects))

    # fill in the rest of the dependent rows
    while len(vecs) < m:
        v = get_vec()
        if np.linalg.matrix_rank(np.vstack(vecs + [v])) > len(vecs):
            n_rejects += 1
            if n_rejects % 1000 == 0:
    print("done ({} total rejects)".format(n_rejects))

    m = np.vstack(vecs)
    return m.T if trans else m

This works okay for e.g. 10x10 binary matrices with any rank, but not for 0-4 matrices or much larger binaries with lower rank. (For example, getting a 20x20 binary matrix of rank 15 took me 42,000 rejections; with 20x20 of rank 10, it took 1.2 million.)

This is clearly because the space spanned by the first r rows is too small a portion of the space I'm sampling from, e.g. {0,1}^10, in these cases.

We want the intersection of the span of the first r rows with the set of valid values. So we could try sampling from the span and looking for valid values, but since the span involves real-valued coefficients that's never going to find us valid vectors (even if we normalize so that e.g. the first component is in the valid set).

Maybe this can be formulated as an integer programming problem, or something?

  • When your matrix is defined over finite sets, like {0,1} or {1,2,3,4,5} are you also using operations that are consistent with a vector space on top of those sets? If not, you're going to have problems. (e.g., you'd have to do arithmetic mod 5 on the elements {0,1,2,3,4} to get a valid group of matrices over that set. You can't use real-valued arithmetic and expect your random draws, linear combinations, etc., to be closed.) – ely Apr 12 '12 at 22:24
  • @EMS Sorry, forgot to mention that I'm using the normal real vector space. That's what I want: a matrix over R but whose elements come from these finite sets. If I did the linear combination thing, I'd obviously have to be careful to do it in such a way that the elements still lie in the set in question, but I want the rank w.r.t. the reals to be r. – Dougal Apr 12 '12 at 22:25
  • I don't think you can mix-and-match the underlying field like that. If the definition of linear independence includes real-valued coefficients on the entries in the rows/columns of your matrix, then the span of some columns can be huge subsets of the matrices over R, not the matrices over your finite set. If you're treating the matrices like they must be over that finite set, then you have to treat the operations on the matrix entries in a way that's consistent with that finite set. You need the set {0,1,2,3,4} equipped with its own addition and multiplication. – ely Apr 12 '12 at 22:29
  • Clearly matrices over R with binary or 1-5 values of given ranks r exist; I need a way to generate them. I don't think I can find them for a given rank in e.g. Z_5, because that's not the same thing: (1,2) and (2,1) are linearly independent over the reals but dependent over Z_3, since 2*(1,2)=(2,1). – Dougal Apr 12 '12 at 22:33
  • 1
    Actually, probably a really good way to try to sample this is with the Metropolis-Hastings algorithm. Make a random initial guess matrix with entries only from your finite set, and that at each iteration, select a random place to change (swapping its entry for another one from the finite set). Compute some measure of the change that 'measures' linear independence, and accept the change proportionally to that measure. You'll reject often, but after a lot of iterations, you'll have something extremely close to what you want. – ely Apr 12 '12 at 22:49

My friend, Daniel Johnson who commented above, came up with an idea but I see he never posted it. It's not very fleshed-out, but you might be able to adapt it.

If A is m-by-r and B is r-by-n and both have rank r then AB has rank r. Now, we just have to pick A and B such that AB has values only in the given set. The simplest case is S = {0,1,2,...,j}.

One choice would be to make A binary with appropriate row/col sums that guaranteed the correct rank and B with column sums adding to no more than j (so that each term in the product is in S) and row sums picked to cause rank r (or at least encourage it as rejection can be used).

I just think that we can come up with two independent sampling schemes on A and B that are less complicated and quicker than trying to attack the whole matrix at once. Unfortunately, all my matrix sampling code is on the other computer. I know it generalized easily to allowing entries in a bigger set than {0,1} (i.e. S), but I can't remember how the computation scaled with m*n.


How about like this?

rank = 30
n1 = 100; n2 = 100
from sklearn.decomposition import NMF
model = NMF(n_components=rank, init='random', random_state=0)
U = model.fit_transform(np.random.randint(1, 5, size=(n1, n2)))
V = model.components_
M = np.around(U) @ np.around(V)
  • This is an interesting approach, but (a) it gives a bunch of elements that are too large (for one run np.bincount(M.astype(int).ravel()) gives [1496, 3057, 2973, 1720, 597, 134, 21, 2], where that last number means there are two 7s), and (b) the rank ended up being 29 rather than 30. – Dougal Mar 29 '18 at 17:18
  • (In any case, I'm a good six years past the project where I wanted this. But still.) – Dougal Mar 29 '18 at 17:19
  • Mmm.. I see. Thanks for the feedback. – diadochos Apr 3 '18 at 11:31

I am not sure how useful this solution will be, but you can construct a matrix that will allow you to search for the solution on another matrix with only 0 and 1 as entries. If you search randomly on the binary matrix, it is equivalent to randomly modifying the elements of the final matrix, but it is possible to come up with some rules to do better than a random search.

If you want to generate an m-by-n matrix over the element set E with elements ei, 0<=i<k, you start off with the m-by-k*m matrix, A:

Generator matrix

Clearly, this matrix has rank m. Now, you can construct another matrix, B, that has 1s at certain locations to pick the elements from the set E. The structure of this matrix is:

Selector matrix

Each Bi is a k-by-n matrix. So, the size of AB is m-by-n and rank(AB) is min(m, rank(B)). If we want the output matrix to have only elements from our set, E, then each column of Bi has to have exactly one element set to 1, and the rest set to 0.

If you want to search for a certain rank on B randomly, you need to start off with a valid B with max rank, and rotate a random column j of a random Bi by a random amount. This is equivalent to changing column i row j of A*B to a random element from our set, so it is not a very useful method.

However, you can do certain tricks with the matrices. For example, if k is 2, and there are no overlaps on first rows of B0 and B1, you can generate a linearly dependent row by adding the first rows of these two sub-matrices. The second row will also be linearly dependent on rows of these two matrices. I am not sure if this will easily generalize to k larger than 2, but I am sure there will be other tricks you can employ.

For example, one simple method to generate at most rank k (when m is k+1) is to get a random valid B0, keep rotating all rows of this matrix up to get B1 to Bm-2, set first row of Bm-1 to all 1, and the remaining rows to all 0. The rank cannot be less than k (assuming n > k), because B_0 columns have exactly 1 nonzero element. The remaining rows of the matrices are all linear combinations (in fact exact copies for almost all submatrices) of these rows. The first row of the last submatrix is the sum of all rows of the first submatrix, and the remaining rows of it are all zeros. For larger values of m, you can use permutations of rows of B0 instead of simple rotation.

Once you generate one matrix that satisfies the rank constraint, you may get away with randomly shuffling the rows and columns of it to generate others.

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