Controlled gate networks reduce two-qubit gate counts for linear combinations of unitary operators in quantum circuits, shown in variational calculations, rodeo eigenvalue estimation, and lattice nucleon evolution on real hardware.
Faster Phase Estimation
2 Pith papers cite this work. Polarity classification is still indexing.
2
Pith papers citing it
abstract
We develop several algorithms for performing quantum phase estimation based on basic measurements and classical post-processing. We present a pedagogical review of quantum phase estimation and simulate the algorithm to numerically determine its scaling in circuit depth and width. We show that the use of purely random measurements requires a number of measurements that is optimal up to constant factors, albeit at the cost of exponential classical post-processing; the method can also be used to improve classical signal processing. We then develop a quantum algorithm for phase estimation that yields an asymptotic improvement in runtime, coming within a factor of log* of the minimum number of measurements required while still requiring only minimal classical post-processing. The corresponding quantum circuit requires asymptotically lower depth and width (number of qubits) than quantum phase estimation.
citation-role summary
background 1
citation-polarity summary
roles
background 1polarities
background 1representative citing papers
Hybrid Path-Sums offer a new symbolic framework with rewriting rules and assertions to represent, simplify, and verify properties of hybrid quantum-classical programs.
citing papers explorer
-
Controlled Gate Networks: Theory and Application to Eigenvalue Estimation
Controlled gate networks reduce two-qubit gate counts for linear combinations of unitary operators in quantum circuits, shown in variational calculations, rodeo eigenvalue estimation, and lattice nucleon evolution on real hardware.
-
Hybrid Path-Sums for Hybrid Quantum Programs
Hybrid Path-Sums offer a new symbolic framework with rewriting rules and assertions to represent, simplify, and verify properties of hybrid quantum-classical programs.