For large r
and b
you can use a method called MonteCarlo integration, see e.g. Monte Carlo integration on Wikipedia (and/or chapter 3.1.2 of SICP) to compute the sum. For small r
and b
and significantly different nodefailure probabilities p[i]
the exact method is superior. The exact definition of small and large will depend on a couple of factors and is best tried out experimentally.
Specific sample code: This is a very basic sample code (in Python) to demonstrate how such a procedure could work:
def montecarlo(p, rb, N):
"""Corresponds to the binomial coefficient formula."""
import random
succ = 0
# Run N samples
for i in xrange(N):
# Generate a single test case
alivenum = 0
for j in xrange(rb):
if random.random()<p: alivenum += 1
# If the test case succeeds, increase succ
if alivenum >= b: succ += 1
# The final result is the number of successful cases/number of total cases
# (I.e., a probability between 0 and 1)
return float(succ)/N
The function corresponds to the binomial test case and runs N
tests, checking if b
nodes out of r*b
nodes are alive with a probability of failure of p
. A few experiments will convince you that you need values of N
in the range of thousands of samples before you can get any reasonable results, but in principle the complexity is O(N*r*b)
. The accuracy of the result scales as sqrt(N)
, i.e., to increase accuracy by a factor of two you need to increase N
by a factor of four. For sufficiently large r*b
this method will be clearly superior.
Extension of the approximation: You obviously need to design the test case such, that it respects all the properties of the system. You have suggested a couple of extensions, some of which can be easily implemented while others can not. Let me give you a couple of suggestions:
1) In the case of distinct but uncorrelated p[i]
, the changes of the above code are minimal: In the function head you pass an array instead of a single float p
and you replace the line if random.random()<p: alivenum += 1
by
if random.random()<p[j]: alivenum += 1
2) In the case of correlated p[i]
you need additional information about the system. The situation I was referring to in my comment could be a network like this:
ABC
 
D E

FGH

J
In this case A
might be the "root node" and a failure of node D
could imply the automatic failure with 100% probability of nodes F
, G
, H
and J
; while a failure of node F
would automatically bring down G
, H
and J
etc. At least this was the case I was referring to in my comment (which is a plausible interpretation since you talk about a tree structure of probabilities in the original question). In such a situation you would need modify the code that p
refers to a tree structure and for j in ...
traverses the tree, skipping the lower branches from the current node as soon as a test fails. The resulting test is still whether alivenum >= b
as before, of course.
3) This approach will fail if the network is a cyclic graph that cannot be represented by a tree structure. In such a case you need to first create graph nodes that are either dead or alive and then run a routing algorithm on the graph to count the number of unique, reachable nodes. This won't increase the timecomplexity of the algorithm, but obviously the code complexity.
4) Time dependence is a nontrivial, but possible modification if you know the m.t.b.f/r (meantimesbetweenfailures/repairs) since this can give you the probabilities p
of either the treestructure or the uncorrelated linear p[i]
by a sum of exponentials. You will then have to run the MCprocedure at different times with the corresponding results for p
.
5) If you merely have the log files (as hinted in your last paragraph) it will require a substantial modification of the approach which is beyond what I can do on this board. The logfiles would need to be sufficiently thorough to allow to reconstruct a model for the network graph (and thus the graph of p
) as well as the individual values of all nodes of p
. Otherwise, accuracy would be unreliable. These logfiles would also need to be substantially longer than the timescales of failures and repairs, an assumptions which may not be realistic in reallife networks.
measurementdate
as an additional property. This introduces a timescale into the system, where previously the system was assumed to be static. Previously, a node was either alive (probabilityp
) or dead (probability1p
). With a timescale the system may no longer be static and a certain meantimebetweenfailures (for switchingalive
nodes todead
) and meantimebetweenrepairs (the reverse) may become meaningful. If you have this situation, the probability for restoring a file becomes timedependent. – user8472 Jun 28 '10 at 10:01p
and1p
, all of which become measurable quantities with a mean value (which may be nodedependent as you have pointed out) and an uncertainty (which reduces to zero if your log becomes long enough). I am pointing this out because in this case the question would be quite different from the original one (where you merely asked for a simplification formula in a specific situation). – user8472 Jun 28 '10 at 10:08