Optimizing Superconducting Qubit Performance: A Theoretical Framework for Design, Analysis, and Calibration

TL;DR

This paper presents a comprehensive theoretical framework for designing, analyzing, and calibrating superconducting qubits, aiming to improve their performance and scalability in quantum computing.

Contribution

It introduces a novel, step-by-step framework covering circuit design, electromagnetic and spectral analysis, and pulse calibration for superconducting qubits.

Findings

Framework closely matches experimental results for Transmon and Fluxonium qubits.

Optimized qubit parameters lead to improved coherence times and gate fidelities.

Method enhances the scalability prospects of superconducting quantum processors.

Abstract

Designing a qubit architecture is one of the most critical challenges in achieving scalable and fault-tolerant quantum computing as the performance of a quantum computer is heavily dependent on the coherence times, connectivity and low noise environments. Superconducting qubits have emerged as a frontrunner among many competing technologies, primarily because of their speed of operations, relatively well-developed and offer a promising path toward scalability. Here, we address the challenges of optimizing superconducting qubit hardware through the development of a comprehensive theoretical framework that spans the entire process - from design to the calibration of hardware through quantum gate execution. We develop this framework in four key steps: circuit design, electromagnetic analysis, spectral analysis, and pulse sequencing with calibration. We first refine the qubit's core components - such as capacitance, Josephson junctions, and resonators - to set the foundation for strong performance. The electromagnetic analysis, using the Lumped Oscillator model, allows us to map out the capacitance matrix, ensuring that we minimize spectral dispersion while maximizing coherence times. Following this, we conduct spectral analysis to fine-tune the qubit's frequency spectrum and coherence properties, ensuring that the qubit parameters are optimized. Finally, we focus on pulse sequencing, including pulse-width optimization, DRAG optimization, and randomized benchmarking, to achieve high gate fidelity. We applied this framework to both Transmon and Fluxonium qubits, obtaining results that closely match those found in experimental studies. This work provides a detailed and practical approach to the design, optimization, and calibration of superconducting qubits, contributing to the broader effort to develop scalable quantum computing technologies.