Classical simulation of quantum computers will continue to play an essential role in the
progress of quantum information science, both for numerical studies of quantum algorithms …

Due to several physical limitations in the realization of quantum hardware, today's quantum
computers are qualified as noisy intermediate-scale quantum (NISQ) hardware. NISQ …

Rapid progress in the physical implementation of quantum computers gave birth to multiple
recent quantum machines implemented with superconducting technology. In these NISQ …

With the potential of quantum algorithms to solve intractable classical problems, quantum
computing is rapidly evolving, and more algorithms are being developed and optimized …

Simulating quantum systems is one of the most important potential applications of quantum
computers. The high-level circuit defining the simulation needs to be compiled into one that …

Quantum computing represents a paradigm shift in computation, offering the potential to
solve complex problems intractable for classical computers. Although current quantum …

Modular quantum computing architectures are a promising alternative to monolithic QPU
(Quantum Processing Unit) designs for scaling up quantum devices. They refer to a set of …

Quantum computers are constantly growing in their number of qubits, but continue to suffer
from restrictions such as the limited pairs of qubits that may interact with each other. Thus far …

Solving optimization problems on near term quantum devices requires developing error
mitigation techniques to cope with hardware decoherence and dephasing processes. We …

Variational Quantum Algorithms (VQA) are promising to demonstrate quantum advantages
on near-term devices. Designing ansatz, a variational circuit with parameterized gates, is of …