This may be solved in linear time using dynamic programming.

A connected graph with N vertices and N edges contains exactly one cycle. Start with detecting this cycle (with the help of depth-first search).

Then remove any edge on this cycle. Two vertices incident to this edge are **u** and **v**. After this edge removal, we have a tree. Interpret it as a rooted tree with the root **u**.

Dynamic programming recurrence for this tree may be defined this way:

**w**_{0}[k] = 0 (for leaf nodes)
**w**_{1}[k] = vertex_cost (for leaf nodes)
**w**_{0}[k] = **w**_{1}[k+1] (for nodes with one descendant)
**w**_{1}[k] = vertex_cost + min(**w**_{0}[k+1], **w**_{1}[k+1]) (for nodes with one descendant)
**w**_{0}[k] = sum(**w**_{1}[k+1], **x**_{1}[k+1], ...) (for branch nodes)
**w**_{1}[k] = vertex_cost + sum(min(**w**_{0}[k+1], **w**_{1}[k+1]), min(**x**_{0}[k+1], **x**_{1}[k+1]), ...)

Here `k`

is the node depth (distance from root), **w**_{0} is cost of the sub-tree starting from node **w** when **w** is not in the "subset", **w**_{1} is cost of the sub-tree starting from node **w** when **w** is in the "subset".

For each node only two values should be calculated: **w**_{0} and **w**_{1}. But for nodes that were on the cycle we need 4 values: **w**_{i,j}, where i=0 if node **v** is not in the "subset", i=1 if node **v** is in the "subset", j=0 if current node is not in the "subset", j=1 if current node is in the "subset".

Optimal cost of the "subset" is determined as min(**u**_{0,1}, **u**_{1,0}, **u**_{1,1}). To get the "subset" itself, store back-pointers along with each sub-tree cost, and use them to reconstruct the subset.