Complexity Bounds for Hamiltonian Simulation in Unitary Representations

Abstract

For any unitary representation on a finite-dimensional Hilbert space \(V\) with differential \(d : g u(V)\) for the Lie algebra g, we consider the Hamiltonian evolution \[ UX(t) ((tX)) = et\,d(X), t∈R. \] For any complexification XC = X0 + Σα∈ xα Eα associated with the root system , we introduce the numerical invariants %root activity and root curvature functionals align* Ap(X) & (Σα∈ |xα|p \,\|d(Eα)\|opp)1/p, 1 p<∞\\ C(X) & (Σα∈ |α(X0)|2\,|xα|2 \,\|d(Eα)\|op2)1/2, align* where \(\|·\|op\) is the operator norm on \(End(V)\). We first describe how the Hamiltonian \(d(X)\) is distributed along the directions of root spaces gα. Our main result shows that for each fixed \(X∈g\) there exists a constant \(CX>0\) such that \[ \| et(d(X0)+d(Xroot)) - et2d(X0) et d(Xroot) et2d(X0) \|op CX\,t3\,(C(X)+A1(Xroot)) \] for all sufficiently small \(|t|\). We also introduce a root-gate circuit model and test this on spin-chain Hamiltonians on \((C2) n⊂su(2n)\), where root spaces are spanned by matrix units, \(Ap\), and \(C\), which gives sharper complexity bounds and dimension-free representation-theoretic invariants.

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