The accurate implementation of quantum gates is essential for the realisation of quantum algorithms and digital quantum simulations. This accuracy may be increased on noisy hardware through the variational optimisation of gates, however the experimental realisation of such a protocol is impeded by the large effort required to estimate the fidelity of an implemented gate. With a hierarchy of approximations we find a faithful approximation to the quantum process fidelity that can be estimated experimentally with reduced effort. Its practical use is demonstrated with the optimisation of a three-qubit quantum gate on a commercially available quantum processor
Producing useful quantum information devices requires efficiently assessing control of quantum syste...
The quantum volume test is a full-system benchmark for quantum computers that is sensitive to qubit ...
We compare and contrast the error probability and fidelity as measures of the quality of the receive...
International audienceThe accurate implementation of quantum gates is essential for the realization ...
Quantum computers have the potential to bring about a new age of technology, but in order for them t...
Quantum computers have the potential to outperform classical computers in a range of computational t...
Remarkable experimental advances in quantum computing are exemplified by recent announcements of imp...
As quantum devices are progressively scaled and refined, quantum codes will become indispensable to ...
The quality of quantum information processing devices has been improving at an unprecedented speed. ...
In theory, perfect quantum computers can solve certain problems that are con- sidered intractable wi...
Trading fidelity for scale enables approximate classical simulators such as matrix product states (M...
To run a quantum program in the real device, the compiler maps the logical qubits to physical qubits...
Accurate and precise control of large quantum systems is paramount to achieve practical advantages o...
An important step in building a quantum computer is calibrating experimentally implemented quantum g...
We present a post-compilation quantum circuit optimization technique that takes into account the var...
Producing useful quantum information devices requires efficiently assessing control of quantum syste...
The quantum volume test is a full-system benchmark for quantum computers that is sensitive to qubit ...
We compare and contrast the error probability and fidelity as measures of the quality of the receive...
International audienceThe accurate implementation of quantum gates is essential for the realization ...
Quantum computers have the potential to bring about a new age of technology, but in order for them t...
Quantum computers have the potential to outperform classical computers in a range of computational t...
Remarkable experimental advances in quantum computing are exemplified by recent announcements of imp...
As quantum devices are progressively scaled and refined, quantum codes will become indispensable to ...
The quality of quantum information processing devices has been improving at an unprecedented speed. ...
In theory, perfect quantum computers can solve certain problems that are con- sidered intractable wi...
Trading fidelity for scale enables approximate classical simulators such as matrix product states (M...
To run a quantum program in the real device, the compiler maps the logical qubits to physical qubits...
Accurate and precise control of large quantum systems is paramount to achieve practical advantages o...
An important step in building a quantum computer is calibrating experimentally implemented quantum g...
We present a post-compilation quantum circuit optimization technique that takes into account the var...
Producing useful quantum information devices requires efficiently assessing control of quantum syste...
The quantum volume test is a full-system benchmark for quantum computers that is sensitive to qubit ...
We compare and contrast the error probability and fidelity as measures of the quality of the receive...