This sounds like a "weighted clique" problem: find e.g.
r=5 people in a network with maximim compatibility / max sum of C(5,2) pair weights.

Google "weighted clique" algorithm -"clique percolation" → 3k hits.

BUT I would go with Justin Peel's method
because it's understandable and controllable

(take the n2 best pairs, from them the best n3 triples ...
adjust n2 n3 ... to easily tradeoff runtime / quality of results.)

Added 18may, a cut at an implementation follows.

@Jose, it would be interesting to see what nbest[] sequence works for you.

```
#!/usr/bin/env python
""" cliq.py: grow high-weight 2 3 4 5-cliques, taking nbest at each stage
weight ab = dist[a,b] -- a symmetric numpy array, diag << 0
weight abc, abcd ... = sum weight all pairs
C[2] = [ (dist[j,k], (j,k)) ... ] nbest[2] pairs
C[3] = [ (cliqwt(j,k,l), (j,k,l)) ... ] nbest[3] triples
...
run time ~ N * (N + nbest[2] + nbest[3] ...)
keywords: weighted-clique heuristic python
"""
# cf "graph clustering algorithm"
from __future__ import division
import numpy as np
__version__ = "denis 18may 2010"
me = __file__.split('/') [-1]
def cliqdistances( cliq, dist ):
return sorted( [dist[j,k] for j in cliq for k in cliq if j < k], reverse=True )
def maxarray2( a, n ):
""" -> max n [ (a[j,k], (j,k)) ...] j <= k, a symmetric """
jkflat = np.argsort( a, axis=None )[:-2*n:-1]
jks = [np.unravel_index( jk, a.shape ) for jk in jkflat]
return [(a[j,k], (j,k)) for j,k in jks if j <= k] [:n]
def _str( iter, fmt="%.2g" ):
return " ".join( fmt % x for x in iter )
#...............................................................................
def maxweightcliques( dist, nbest, r, verbose=10 ):
def cliqwt( cliq, p ):
return sum( dist[c,p] for c in cliq ) # << 0 if p in c
def growcliqs( cliqs, nbest ):
""" [(cliqweight, n-cliq) ...] -> nbest [(cliqweight, n+1 cliq) ...] """
# heapq the nbest ? here just gen all N * |cliqs|, sort
all = []
dups = set()
for w, c in cliqs:
for p in xrange(N):
# fast gen [sorted c+p ...] with small sorted c ?
cp = c + [p]
cp.sort()
tup = tuple(cp)
if tup in dups: continue
dups.add( tup )
all.append( (w + cliqwt(c, p), cp ))
all.sort( reverse=True )
if verbose:
print "growcliqs: %s" % _str( w for w,c in all[:verbose] ) ,
print " best: %s" % _str( cliqdistances( all[0][1], dist )[:10])
return all[:nbest]
np.fill_diagonal( dist, -1e10 ) # so cliqwt( c, p in c ) << 0
C = (r+1) * [(0, None)] # [(cliqweight, cliq-tuple) ...]
# C[1] = [(0, (p,)) for p in xrange(N)]
C[2] = [(w, list(pair)) for w, pair in maxarray2( dist, nbest[2] )]
for j in range( 3, r+1 ):
C[j] = growcliqs( C[j-1], nbest[j] )
return C
#...............................................................................
if __name__ == "__main__":
import sys
N = 100
r = 5 # max clique size
nbest = 10
verbose = 0
seed = 1
exec "\n".join( sys.argv[1:] ) # N= ...
np.random.seed(seed)
nbest = [0, 0, N//2] + (r - 2) * [nbest] # ?
print "%s N=%d r=%d nbest=%s" % (me, N, r, nbest)
# random graphs w cluster parameters ?
dist = np.random.exponential( 1, (N,N) )
dist = (dist + dist.T) / 2
for j in range( 0, N, r ):
dist[j:j+r, j:j+r] += 2 # see if we get r in a row
# dist = np.ones( (N,N) )
cliqs = maxweightcliques( dist, nbest, r, verbose )[-1] # [ (wt, cliq) ... ]
print "Clique weight, clique, distances within clique"
print 50 * "-"
for w,c in cliqs:
print "%5.3g %s %s" % (
w, _str( c, fmt="%d" ), _str( cliqdistances( c, dist )[:10]))
```