The diameter of random spanning trees interpolating between the UST and the MST of the complete graph

Abstract

We introduce WSTβn(Kn) as the weighted spanning tree of the complete graph Kn w.r.t. the random electric network of conductances \(-βnUe)\e∈ E(Kn) with Unif[0,1] i.i.d. Ue's. Moving from βn 0 to faster and faster growing βn's, the model interpolates between the uniform and the minimum spanning trees: WST0(Kn)=UST(Kn), and there are phase transitions for WSTβn(Kn) behaving more and more like MST(Kn): - around βn=n3+o(1) regarding the agreement of the two standard algorithms generating these models : Aldous-Broder and Prim's invasion algorithms, - around βn=n2+o(1) regarding the models consisting of exactly the same edges, and - around βn=n1+o(1) regarding the expected total length E[Σe∈ WSTβn(Kn)Ue]. But most importantly, we study the global geometry of the model: we prove that the typical diameter of WSTβn(Kn) grows like (n1/3) for βn n4/3+o(1) likewise the MST(Kn) case, and it grows like (n1/2) for βn n1+o(1) similarly to the UST(Kn) case. For βn=nα with 1<α<4/3, the behavior of the typical diameter is a more delicate open question, but we conjecture that its exponent strictly between 1/2 and 1/3.

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