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Let's consider square matrix

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(n is a dimension of the matrix E and fixed (for example n = 4 or n=5)). Matrix entries a_{ij} satisfy following conditions:

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The task is to generate all matrices E. My question is how to do that? Is there any common approach or algorithm? Is that even possible? What to start with?

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What is the dimension of your matrices? n * n? –  Carsten Jun 10 '13 at 6:58
    
Yes. It is n * n. We are considering that matrices for fixed dimension, for example n = 4 and generating them. –  ArtyMathJava Jun 10 '13 at 7:01
    
It is useful to consider matrix size and element range separately. Look at the matrices E(n,k) of dimension n with elements that range in 0..k that satisfy your condition. Suppose you can generate all of them. Now what do you need to generate all of E(n+1,k)? –  n.m. Jun 10 '13 at 7:13
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Of course there's no need to consider anything if you can solve the problem without it. –  n.m. Jun 10 '13 at 17:03
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@RBarryYoung: which condition says something about a(0,0) + a(1,1)? –  n.m. Jun 10 '13 at 18:00

1 Answer 1

up vote 6 down vote accepted

Naive solution

A naive solution to consider is to generate every possible n-by-n matrix E where each component is a nonnegative integer no greater than n, then take from those only the matrices that satisfy the additional constraints. What would be the complexity of that?

Each component can take on n + 1 values, and there are n^2 components, so there are O((n+1)^(n^2)) candidate matrices. That has an insanely high growth rate.

Link: WolframAlpha analysis of (n+1)^(n^2)

I think it's safe to safe that this not a feasible approach.

Better solution

A better solution follows. It involves a lot of math.

Let S be the set of all matrices E that satisfy your requirements. Let N = {1, 2, ..., n}.

Definitions:

  • Let a metric on N to have the usual definition, except with the requirement of symmetry omitted.

  • Let I and J partition the set N. Let D(I,J) be the n x n matrix that has D_ij = 1 when i is in I and j is in J, and D_ij = 0 otherwise.

  • Let A and B be in S. Then A is adjacent to B if and only if there exist I and J partitioning N such that A + D(I,J) = B.

    We say A and B are adjacent if and only if A is adjacent to B or B is adjacent to A.

  • Two matrices A and B in S are path-connected if and only if there exists a sequence of adjacent elements of S between them.

  • Let the function M(E) denote the sum of the elements of matrix E.

Lemma 1:
E = D(I,J) is a metric on N.

Proof:
This is a trivial statement except for the case of an edge going from I to J. Let i be in I and j be in J. Then E_ij = 1 by definition of D(I,J). Let k be in N. If k is in I, then E_ik = 0 and E_kj = 1, so E_ik + E_kj >= E_ij. If k is in J, then E_ik = 1 and E_kj = 0, so E_ij + E_kj >= E_ij.

Lemma 2:
Let E be in S such that E != zeros(n,n). Then there exist I and J partitioning N such that E' = E - D(I,J) is in S with M(E') < M(E).

Proof:
Let (i,j) be such that E_ij > 0. Let I be the subset of N that can be reached from i by a directed path of cost 0. I cannot be empty, because i is in I. I cannot be N, because j is not in I. This is because E satisfies the triangle inequality and E_ij > 0.

Let J = N - I. Then I and J are both nonempty and partition N. By the definition of I, there does not exist any (x,y) such that E_xy = 0 and x is in I and y is in J. Therefore E_xy >= 1 for all x in I and y in J.

Thus E' = E - D(I,J) >= 0. That M(E') < M(E) is obvious, because all we have done is subtract from elements of E to get E'. Now, since E is a metric on N and D(I,J) is a metric on N (by Lemma 1) and E >= D(I,J), we have E' is a metric on N. Therefore E' is in S.

Theorem:
Let E be in S. Then E and zeros(n,n) are path-connected.

Proof (by induction):
If E = zeros(n,n), then the statement is trivial.

Suppose E != zeros(n,n). Let M(E) be the sum of the values in E. Then, by induction, we can assume that the statement is true for any matrix E' having M(E') < M(E).

Since E != zeros(n,n), by Lemma 2 we have some E' in S such that M(E') < M(E). Then by the inductive hypothesis E' is path-connected to zeros(n,n). Therefore E is path-connected to zeros(n,n).

Corollary:
The set S is path-connected.

Proof:
Let A and B be in S. By the Theorem, A and B are both path-connected to zeros(n,n). Therefore A is path-connected to B.

Algorithm

The Corollary tells us that everything in S is path-connected. So an effective way to discover all of the elements of S is to perform a breadth-first search over the graph defined by the following.

  • The elements of S are the nodes of the graph
  • Nodes of the graph are connected by an edge if and only if they are adjacent

Given a node E, you can find all of the (potentially) unvisited neighbors of E by simply enumerating all of the possible matrices D(I,J) (of which there are 2^n) and generating E' = E + D(I,J) for each. Enumerating the D(I,J) should be relatively straightforward (there is one for every possible subset I of D, except for the empty set and D).

Note that, in the preceding paragraph, E and D(I,J) are both metrics on N. So when you generate E' = E + D(I,J), you don't have to check that it satisfies the triangle inequality - E' is the sum of two metrics, so it is a metric. To check that E' is in S, all you have to do is verify that the maximum element in E' does not exceed n.

You can start the breadth-first search from any element of S and be guaranteed that you won't miss any of S. So you can start the search with zeros(n,n).


Be aware that the cardinality of the set S grows extremely fast as n increases, so computing the entire set S will only be tractable for small n.

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