Higher-order product formulas for double bracket iteration quantum algorithms
This work aims to study the effects of adding higher-order terms into the group commutator formula in the previously studied double-bracket iterations (DBI) quantum algorithm. In particular, the effects of adding a six-gate third-order product formula, S3, is studied and compared to the previousl...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/175695 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This work aims to study the effects of adding higher-order terms into the group commutator
formula in the previously studied double-bracket iterations (DBI) quantum algorithm. In
particular, the effects of adding a six-gate third-order product formula, S3, is studied and
compared to the previously studied DBI algorithm for second-order S2 group commutator
terms. In the original study, double-bracket iterations for constructing diagonalizing quantum
circuits were implemented. The method involves interleaving evolutions generated by the
input Hamiltonian with variational choices of diagonal evolutions during implementation on a
quantum computer. To address near-term implementation challenges, the proposal includes
optimizations for diagonal evolution generators and recursion step durations. Numerical
examples demonstrate that even with a limited number of recursion steps, double-bracket
iterations possess sufficient expressive power to approximate eigenstates of relevant quantum
models. Importantly, this method overcomes train ability limitations associated with brute force optimization of unstructured circuits and presents a more feasible implementation
compared to quantum phase estimation. The study not only paves the way for practical
near-term quantum computing experiments but also expands the quantum computing toolkit
by introducing purposeful quantum algorithms based on double-bracket flows. |
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