I have a graph *G* which consists only of star graphs. A star graph consists of one central node having edges to every other node in it. Let *H _{1}, H_{2},…,H_{n}* be different star graphs of different sizes which are present in

*G*. We call the set of all nodes which are centres in any star graph

*R*.

Now suppose these star graphs are building edges to other star graphs such that no edge is incident between any nodes in *R*. Then, how many edges exist at maximum between the nodes in *R* and the nodes which are not in *R*, if the graph should remain planar?

I want the upper bound on the number of such edges. One upper bound that I have in mind is: consider them as bipartite planar graph where *R* is one set of vertices and rest of the vertices form another set *A*. We are interested in edges between these sets (*R* and *A*). Since it is planar bipartite, the number of such edges is bounded by twice the number of nodes in *G*.

What I feel is that is there a better bound, maybe twice the nodes in *A* plus the number of nodes in *R*.

In case you can disprove my intuition, then that would also be good. Hopefully some of you can come up with a good bound along with some relevant arguments.