Suppose I have a a graph with 2^N - 1 nodes, numbered 1 to 2^N - 1. Node i "depends on" node j if all the bits in the binary representation of j that are 1, are also 1 in the binary representation of i. So, for instance, if N=3, then node 7 depends on all other nodes. Node 6 depends on nodes 4 and 2.

The problem is eliminating nodes. I can eliminate a node if no other nodes depend on it. No nodes depend on 7; so I can eliminate 7. After eliminating 7, I can eliminate 6, 5, and 3, etc. What I'd like is to find an efficient algorithm for listing all the possible unique elimination paths. (that is, 7-6-5 is the same as 7-5-6, so we only need to list one of the two). I have a dumb algorithm already, but I think there must be a better way.

I have three related questions:

Does this problem have a general name?

What's the best way to solve it?

Is there a general formula for the number of unique elimination paths?

Edit: I should note that a node cannot depend on itself, by definition.

Edit2: Let `S = {s_1, s_2, s_3,...,s_m}`

be the set of all `m`

valid elimination paths. `s_i`

and `s_j`

are "equivalent" (for my purposes) iff the two eliminations `s_i`

and `s_j`

would lead to the same graph after elimination. I suppose to be clearer I could say that what I want is the set of all unique *graphs* resulting from valid elimination steps.

Edit3: Note that elimination paths may be different lengths. For N=2, the 5 valid elimination paths are `(),(3),(3,2),(3,1),(3,2,1)`

. For N=3, there are 19 unique paths.

Edit4: Re: my application - the application is in statistics. Given N factors, there are 2^N - 1 possible terms in statistical model (see http://en.wikipedia.org/wiki/Analysis_of_variance#ANOVA_for_multiple_factors) that can contain the main effects (the factors alone) and various (2,3,... way) interactions between the factors. But an interaction can only be present in a model if all sub-interactions (or main effects) are present. For three factors `a`

, `b`

, and `c`

, for example, the 3 way interaction `a:b:c`

can only be in present if all the constituent two-way interactions (`a:b`

, `a:c`

, `b:c`

) are present (and likewise for the two-ways). Thus, the model `a + b + c + a:b + a:b:c`

would not be allowed. I'm looking for a quick way to generate all *valid* models.

`7-6-5`

and`7-5-6`

are the same, why wouldn't (imaginary paths)`7-6-5-4-3-2-1`

and`7-6-4-5-3-1-2`

be the same? – Shahbaz Jan 27 '14 at 10:07`7-6-4-5-3-1-2`

is not an elimination path. You can't eliminate 4 before 5, because 5 depends on 4. – richarddmorey Jan 27 '14 at 10:15