Quantum optimal control, a toolbox for devising and implementing the shapes of external
fields that accomplish given tasks in the operation of a quantum device in the best way …

As quantum information processors grow in quantum bit (qubit) count and functionality, the
control and measurement system becomes a limiting factor to large-scale extensibility. To …

The ability to execute high-fidelity operations is crucial to scaling up quantum devices to
large numbers of qubits. However, signal distortions originating from nonlinear components …

Sažetak Quantum computing was proposed to simulate processes that surpass the
capabilities of its counterpart, classical computing. Utilizing the principles of quantum …

Towards the practical use of quantum computers in the NISQ era, as well as the realization
of fault-tolerant quantum computers that utilize quantum error correction codes, pressing …

As the number of qubits in nascent quantum processing units increases, the connectorized
RF (radio frequency) analog circuits used in first generation experiments become …

Reaching useful fault-tolerant quantum computation relies on successfully implementing
quantum error correction (QEC). In QEC, quantum gates and measurements are performed …

Quantum technologies, such as communication, computing, and sensing, offer vast
opportunities for advanced research and development. While an open-source ethos …

Quantum technologies such as communications, computing, and sensing offer vast
opportunities for advanced research and development. While an open-source ethos …

The precise implementation and manipulation of quantum gates is key to extracting
advantages from future quantum technologies. Achieving this requires very accurate control …