English

Black-box Hamiltonian simulation and unitary implementation

Quantum Physics 2018-08-02 v4

Abstract

We present general methods for simulating black-box Hamiltonians using quantum walks. These techniques have two main applications: simulating sparse Hamiltonians and implementing black-box unitary operations. In particular, we give the best known simulation of sparse Hamiltonians with constant precision. Our method has complexity linear in both the sparseness D (the maximum number of nonzero elements in a column) and the evolution time t, whereas previous methods had complexity scaling as D^4 and were superlinear in t. We also consider the task of implementing an arbitrary unitary operation given a black-box description of its matrix elements. Whereas standard methods for performing an explicitly specified N x N unitary operation use O(N^2) elementary gates, we show that a black-box unitary can be performed with bounded error using O(N^{2/3} (log log N)^{4/3}) queries to its matrix elements. In fact, except for pathological cases, it appears that most unitaries can be performed with only O(sqrt{N}) queries, which is optimal.

Keywords

Cite

@article{arxiv.0910.4157,
  title  = {Black-box Hamiltonian simulation and unitary implementation},
  author = {Dominic W. Berry and Andrew M. Childs},
  journal= {arXiv preprint arXiv:0910.4157},
  year   = {2018}
}

Comments

19 pages, 3 figures, minor corrections

R2 v1 2026-06-21T14:01:43.673Z