On a quantum-classical correspondence: from graphs to manifolds

Abstract

We establish conditions for which graph Laplacians λ,ε on compact, boundaryless, smooth submanifolds M of Euclidean space are semiclassical pseudodifferential operators (): essentially, that the graph Laplacian's kernel bandwidth (bias term) ε decays faster than the semiclassical parameter h, i.e., h ε and we compute the symbol. Coupling this with Egorov's theorem and coherent states h localized at (x0, 0) ∈ T*M, we show that with Uλ,εt := e-i t λ,ε spectrally defined, the (co-)geodesic flow t on T*M is approximated by Uλ,ε-t Oph(a) Uλ,εt h, h = a t(x0, 0) + O(h). Then, we turn to the discrete setting: for λ,ε,N a normalized graph Laplacian defined on a set of N points x1, …, xN sampled i.i.d. from a probability distribution with smooth density, we establish Bernstein-type lower bounds on the probability that ||Uλ,ε,Nt[u] - Uλ,εt[u]||L∞ ≤ δ with Uλ,ε,Nt := e-i t λ,ε,N. We apply this to coherent states to show that the geodesic flow on M can be approximated by matrix dynamics on the discrete sample set, namely that with high probability, ct,N-1 Σj=1N |Uλ,ε,Nt[h](xj)|2 u(xj) = u(xt) + O(h) for ct,N := Σj=1N |Uλ,ε,Nt[h](xj)|2 and xt the projection of t(x0, 0) onto M.

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