i have several elements A,B,C,AB,ABC,.. (see image below) where each element either exists or not. the rule that governs this system is as follows: if AB exists, then A and B must also exist. generally speaking if a tupel exists, all smaller tupels which are subsets of this tupel must also exist. furthermore if a tupel does not exist, all tupels which make up a superset of this tupel do not exist.
Example: Given ABC exists then A, B, C, AB, AC, BC exist too. Given BC does not exist then ABC,BCD,ABCD do not exist either.
now what i struggle with is, how do i calculate e.g. P(AB|A,B,!ABC) which means the probability that AB exists, given A exists, B exists and ABC does not exist. foreach element i have a basic starting probability p(X) which tells me how likely it is for X to exists given NO constraints. and usually i check the existence of A,B,C,D,ABCD beforehand so the system has boundaries.
my problem is that this is a cyclic network. i would be very grateful for any help as i tried solving this problem for the last couple of weeks without success. i only want to calculate the probability that one element exists, given any situation/constraint. note that elements like AB and !BD are not independent.