Noise tailoring for Robust Amplitude Estimation
- URL: http://arxiv.org/abs/2208.11797v1
- Date: Wed, 24 Aug 2022 23:51:21 GMT
- Title: Noise tailoring for Robust Amplitude Estimation
- Authors: Archismita Dalal and Amara Katabarwa
- Abstract summary: A universal fault-tolerant quantum computer holds the promise to speed up computational problems that are otherwise intractable on classical computers.
For the next decade or so, our access is restricted to noisy intermediate-scale quantum (NISQ) computers and, perhaps, early fault tolerant (EFT) quantum computers.
This motivates the development of many near-term quantum algorithms including robust amplitude estimation (RAE)
We show that our noise-tailored RAE algorithm is able to regain improvements in both bias and precision that are expected for RAE.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: A universal fault-tolerant quantum computer holds the promise to speed up
computational problems that are otherwise intractable on classical computers;
however, for the next decade or so, our access is restricted to noisy
intermediate-scale quantum (NISQ) computers and, perhaps, early fault tolerant
(EFT) quantum computers. This motivates the development of many near-term
quantum algorithms including robust amplitude estimation (RAE), which is a
quantum-enhanced algorithm for estimating expectation values. One obstacle to
using RAE has been a paucity of ways of getting realistic error models
incorporated into this algorithm. So far the impact of device noise on RAE is
incorporated into one of its subroutines as an exponential decay model, which
is unrealistic for NISQ devices and, maybe, for EFT devices; this hinders the
performance of RAE. Rather than trying to explicitly model realistic noise
effects, which may be infeasible, we circumvent this obstacle by tailoring
device noise to generate an effective noise model, whose impact on RAE closely
resembles that of the exponential decay model. Using noisy simulations, we show
that our noise-tailored RAE algorithm is able to regain improvements in both
bias and precision that are expected for RAE. Additionally, on IBM's quantum
computer our algorithm demonstrates advantage over the standard estimation
technique in reducing bias. Thus, our work extends the feasibility of RAE on
NISQ computers, consequently bringing us one step closer towards achieving
quantum advantage using these devices.
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