Quantum computing promises an effective way to solve targeted problems that are
classically intractable. Among them, quantum computers built with superconducting qubits …

As current Noisy Intermediate Scale Quantum (NISQ) devices suffer from decoherence
errors, any delay in the instruction execution of quantum control microarchitecture can lead …

Quantum computing devices based on superconducting quantum circuits have rapidly
developed in the last few years. The building blocks-superconducting qubits, quantum …

Quantum computers promise to solve certain problems that are intractable for classical
computers, such as factoring large numbers and simulating quantum systems. To date …

In state-of-the-art superconducting quantum processors, each qubit is controlled by at least
one control line that delivers control pulses generated at room temperature to qubits at …

The advancement of scalable quantum information processing relies on the accurate and
parallel manipulation of a vast number of qubits, potentially reaching into the millions …

More computational resources (ie, more physical qubits and qubit connections) on a
superconducting quantum processor not only improve the performance but also result in …

In this era of incessant advancements in quantum computing, bridging the gap between
quantum algorithms' hardware requisites and available devices has become crucial. A prime …

As the number of qubits in quantum computing increases, the scalability of existing qubit
circuit structures and control systems may become insufficient for large-scale expansion and …

Single-flux-quantum (SFQ) logic operating in a 4.2-kelvin environment with a
superconducting state is a promising candidate for achieving extremely high-performance …