For quantum computers to successfully solve real-world problems, it is necessary to tackle
the challenge of noise: the errors that occur in elementary physical components due to …

Benchmarking and characterizing quantum states and logic gates is essential in the
development of devices for quantum computing. We introduce a Bayesian approach to self …

The existing body of research on quantum embedding techniques is not only confined in
scope but also lacks a comprehensive understanding of the intricacies of the quantum …

Quantum computers are inhibited by physical errors that occur during computation. For this
reason, the development of increasingly sophisticated error characterization and error …

Characterizing temporally correlated noise and “non-Markovian” qubit dynamics is a key
prerequisite for achieving noise-tailored error mitigation and optimal device performance …

Some of the most problematic issues that limit the implementation of applications on Noisy
Intermediate Scale Quantum (NISQ) machines are the adverse impacts of both incoherent …

State preparation and measurement errors are commonly regarded as indistinguishable.
The problem of distinguishing state preparation errors from measurement errors is important …

We present a general denoising algorithm for performing $\textit {simultaneous tomography}
$ of quantum states and measurement noise. This algorithm allows us to fully characterize …

The strong requirement for high-performing quantum computing led to intensive research on
novel quantum platforms in the last decades. The circuital nature of Josephson-based …

Present-day quantum devices require precise implementation of desired quantum channels.
To characterize the quality of implementation one uses the average operation fidelity F …