English

Parallelizable adiabatic gate teleportation

Quantum Physics 2015-12-16 v2

Abstract

We introduce a twisted Heisenberg-type interaction Hamiltonian, a Heisenberg-type spin interaction where the coordinates of the second qubit are twisted according to a unitary gate. We develop parallelizable adiabatic gate teleportation (PAGT) where a sequence of unitary gates is performed in a single step of the adiabatic process. In PAGT, numeric calculations suggest the necessary time for the adiabatic evolution implementing a sequence of LL unitary gates increases at most as O(L5)O(L^5). However, we show that it has the interesting property that it can map the temporal order of gates to the spatial order of interactions specified by the final Hamiltonian. Using this property, we present a controlled-PAGT scheme to manipulate the order of gates by a control-qubit. In the controlled-PAGT scheme, two differently ordered sequential unitary gates FGFG and GFGF are coherently performed depending on the state of a control-qubit by simultaneously applying the twisted Heisenberg-type interaction Hamiltonians implementing unitary gates FF and GG. We investigate why the twisted Heisenberg-type interaction Hamiltonian allows PAGT. We show that the twisted Heisenberg-type interaction Hamiltonian has an ability to perform a transposed unitary gate by just modifying the space ordering of the final Hamiltonian implementing a unitary gate in adiabatic gate teleportation. The dynamics generated by the time-reversed Hamiltonian represented by the transposed unitary gate enables deterministic simulation of a postselected event of parallelized gate teleportation in adiabatic implementation.

Keywords

Cite

@article{arxiv.1310.4061,
  title  = {Parallelizable adiabatic gate teleportation},
  author = {Kosuke Nakago and Michal Hajdušek and Shojun Nakayama and Mio Murao},
  journal= {arXiv preprint arXiv:1310.4061},
  year   = {2015}
}

Comments

20 pages, 11 figures, 1 table

R2 v1 2026-06-22T01:47:27.810Z