In order to be well prepared for my spring quarter exams right now I'm studying and experimenting with graph problems.
I already got familiar to typical problems like the "Traveling Salesman" but when I took a deeper look into the "chinese postman problem" and its variations I immediately felt like an important aspect of the problem was missing: The aspect of having a limited capacity, thus the need to return to the office station after a certain number n of letters is successfully delivered (in order to get new ones). What about finding the shortest path then?
I was very intrigued with the CPP because of its relevancy and easy applicability for real life but I think adding this aspect would make it even more real life applicable.
I would be thankful for any help on how to find the shortest path in an undirected graph that visits every edge at least once (CPP) the the constraint of having to return to the starting point (post station) after a certain number of letters is delivered.
EDIT (description of originial CPP): "The chinese postman problem or route inspection problem is to find a shortest closed path or circuit that visits every edge of a (connected) undirected graph. When the graph has an Eulerian circuit (a closed walk that covers every edge once), that circuit is an optimal solution. If the graph is not Eulerian, it must contain vertices of odd degree. By the handshaking lemma, there must be an even number of these vertices. To solve the postman problem we first find a smallest T-join. We make the graph Eulerian by doubling of the T-join. The solution to the postman problem in the original graph is obtained by finding an Eulerian circuit for the new graph." Src: wikipedia.org