I'm not sure about 'prior art' in this domain, but I guess I can think of a 'straightforward solution'.

- Find the best path in the Graph 1 (the first graph)
separately, as shown in the 'Picture Example'. Compute the cost
function for this path, say CF1.
- Find the number of coloured nodes in Graph 1's optimal path.
- For all coloured nodes in Graph 1, remove all alternate connection
from Graph 2, i.e, ensure that a path in Graph 2 has to go through
the coloured nodes used in Graph 1.
- Find the optimal path in Graph 2 and compute its cost function, say
CF2.
- Compute CF1 + CF2
- Repeat steps 1 to 5, but this time start with Graph 2 and then match
Graph 1's coloured nodes with Graph 2's initial optimal path.

The lowest value of CF1+CF2 would give you a set of feasible path.

Basically, you plan the path for one of the graph and get the other graph to comply with its set of linked nodes and the check the combined cost function. Then repeat for the other graph. Find the best combination that works.

In general, for n graphs, you would have to perform n^2 shortest path computations, which is obviously very bad. But it should work, as a naive idea.

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Here's my modified version of the previous algorithm for weighted graph:

Assumption : We are working with 'n' graphs, all of them are weighted and all of them contains equal and fixed number of 'stages'.

All the starting nodes are described as S1, S2, S3…. Sn.
All the terminal nodes are described as e1, e2, e3….. en.

Initiate an empty priority queue (PQ) [preferably using binary/fibonacci min heap] that will contain paths (collection of nodes) and their corresponding priority will be denoted by the cumulative sum of their **path weights**]

Insert all starting nodes - S1, S2, S3…. Sn into PQ, the priority of each individual nodes set to zero.

Pop the path with the lowest weight (say it belongs to graph number 'k') and expand it's children. Let there be 'p' children nodes. [If there are no more stages to expand into, delete that path from the priority queue. This way, if the total size of the queue becomes zero, then there are no feasible path between S and e]

For i = 1 to n for all i not equal to k, repeat:

4a. Check which of the p paths are **feasible** in the remaining (n-1) graphs.

4b. Insert all the **feasible** paths to PQ (after computing their priorities).

4c. If one of the **feasible** paths end up in ek : then mark that path as 'PathOptimal' and go to 5.
else : go to 3.

For i = 1 to n for all i not equal to k : find the corresponding paths in each graph against 'PathOptimal' and report them as the output.

Here, the concept of *path weights* has to be implemented correctly.
Path weight will be equal to: sum of weights of the edges contained in that path + sum of weights of edges contained in all sibling paths in the remaining (n-1) graph.

The concept of *feasibility* will be your business rule, i.e if a children is a coloured node, the corresponding children of the previous path in all other (n-1) graphs has to be of the same colour. If it not a coloured node, it's sibling children will have to be non-coloured.

[Please let me know if you figure out any obvious flaw in the algorithm since I just made it up. Also, since this has been heavily borrowed from Dijkstra's, let me know if you could figure a method for speeding this up.]

*P.S:- However, I must mention that given the scope of your problem, I'd rather use genetic algorithm for solving this than going by a deterministic method.*