I had a question regarding designing an algorithm to make a bipartite graph acyclic. I hope someone could help me out here. The problem statement is described below:

Consider an undirected bipartite graph G = (U,V,E), where U = {u_1, u_2, ...u_M} is a set of M nodes, V = {v_1, v_2, ..., v_N} is a set of N nodes, and E is the set of edges connecting nodes in U to nodes in V. For simplicity, assume that the graph is connected and cyclic, i.e., has cycles.

The aim is to design an algorithm that eliminate cycles and reduces the graph to a tree or forest as follows. The algorithm proceeds in rounds. A round is described as choosing each node u_i, i = 1, 2, ..., M, in U and removing an edge connected to it. In case a node u_i is isolated (i.e., it has no edges connected to it) we ignore it and proceed. This way at most M edges are removed in each round. The algorithm stops when the graph reduces to a tree or forest at the end of some round.

I wish to know if it is possible to have a polynomial-time algorithm (in M, N) for designing the rounds such that the number of rounds is minimized (for reducing the graph to a tree/forest).

round is described as choosing each node..., so knowing the problem you think what he meant to say is "round is describe as choosinganode..." – Benjamin Gruenbaum Feb 4 '13 at 16:46