TY - GEN
T1 - Rigorous rg algorithms and area laws for low energy eigenstates in 1D
AU - Arad, Itai
AU - Landau, Zeph
AU - Vazirani, Umesh
AU - Vidick, Thomas
N1 - Funding Information: ∗ I. Arad’s research was partially performed at the Centre for Quantum Technologies, funded by the Singapore Ministry of Education and the National Research Foundation, also through the Tier 3 Grant random numbers from quantum processes. † The author acknowledges support by ARO Grant W911NF-12-1-0541, NSF Grant CCF-1410022 and Templeton Foundation Grant 52536. ‡ The author acknowledges support by ARO Grant W911NF-12-1-0541, NSF Grant CCF-1410022 and Templeton Foundation Grant 52536. § T. Vidick was partially supported by the IQIM, an NSF Physics FrontiersCenter (NFS Grant PHY-1125565) with support of the Gordon and Betty Moore Foundation (GBMF-12500028).
PY - 2017/11/1
Y1 - 2017/11/1
N2 - One of the central challenges in the study of quantum many-body systems is the complexity of simulating them on a classical computer. A recent advance [8] gave a polynomial time algorithm to compute a succinct classical description for unique ground states of gapped 1D quantum systems. Despite this progress many questions remained unresolved, including whether there exist rigorous efficient algorithms when the ground space is degenerate (and poly(n) dimensional), or for the poly(n) lowest energy states for 1D systems, or even whether such states admit succinct classical descriptions or area laws. In this paper we give a new algorithm for finding low energy states for 1D systems, based on a rigorously justified renormalization group (RG)-Type transformation. In the process we resolve some of the aforementioned open questions, including giving a polynomial time algorithm for poly(n) degenerate ground spaces and an nO(log n) algorithm for the poly(n) lowest energy states for 1D systems (under a mild density condition). We note that for these classes of systems the existence of a succinct classical description and area laws were not rigorously proved before this work. The algorithms are natural and efficient, and for the case of finding unique ground states for frustration-free Hamiltonians the running time is O(nM(n)), where M(n) is the time required to multiply two n × n matrices.
AB - One of the central challenges in the study of quantum many-body systems is the complexity of simulating them on a classical computer. A recent advance [8] gave a polynomial time algorithm to compute a succinct classical description for unique ground states of gapped 1D quantum systems. Despite this progress many questions remained unresolved, including whether there exist rigorous efficient algorithms when the ground space is degenerate (and poly(n) dimensional), or for the poly(n) lowest energy states for 1D systems, or even whether such states admit succinct classical descriptions or area laws. In this paper we give a new algorithm for finding low energy states for 1D systems, based on a rigorously justified renormalization group (RG)-Type transformation. In the process we resolve some of the aforementioned open questions, including giving a polynomial time algorithm for poly(n) degenerate ground spaces and an nO(log n) algorithm for the poly(n) lowest energy states for 1D systems (under a mild density condition). We note that for these classes of systems the existence of a succinct classical description and area laws were not rigorously proved before this work. The algorithms are natural and efficient, and for the case of finding unique ground states for frustration-free Hamiltonians the running time is O(nM(n)), where M(n) is the time required to multiply two n × n matrices.
KW - Hamiltonian complexity
KW - algorithm
KW - area law
KW - gapped ground states
UR - http://www.scopus.com/inward/record.url?scp=85038600801&partnerID=8YFLogxK
U2 - 10.4230/LIPIcs.ITCS.2017.46
DO - 10.4230/LIPIcs.ITCS.2017.46
M3 - منشور من مؤتمر
T3 - Leibniz International Proceedings in Informatics, LIPIcs
BT - 8th Innovations in Theoretical Computer Science Conference, ITCS 2017
A2 - Papadimitriou, Christos H.
T2 - 8th Innovations in Theoretical Computer Science Conference, ITCS 2017
Y2 - 9 January 2017 through 11 January 2017
ER -