Dr Mustafa Bakr

Efficient characterization of qudit logical gates with gate set tomography using an error-free Virtual-Z-gate model

(2022)

Authors:

Shuxiang Cao, Deep Lall, Mustafa Bakr, Giulio Campanaro, Simone Fasciati, James Wills, Vivek Chidambaram, Boris Shteynas, Ivan Rungger, Peter Leek

Improving dispersive readout of a superconducting qubit by machine learning on path signature

Authors:

Shuxiang Cao, Zhen Shao, Jian-Qing Zheng, Mustafa Bakr, Peter Leek, Terry Lyons

Abstract:

One major challenge that arises from quantum computing is to implement fast, high-accuracy quantum state readout. For superconducting circuits, this problem reduces to a time series classification problem on readout signals. We propose that using path signature methods to extract features can enhance existing techniques for quantum state discrimination. We demonstrate the superior performance of our proposed approach over conventional methods in distinguishing three different quantum states on real experimental data from a superconducting transmon qubit.

Efficient Characterization of Qudit Logical Gates with Gate Set Tomography Using an Error-Free Virtual Z Gate Model.

Physical review letters 133:12 (2024) 120802

Authors:

Shuxiang Cao, Deep Lall, Mustafa Bakr, Giulio Campanaro, Simone D Fasciati, James Wills, Vivek Chidambaram, Boris Shteynas, Ivan Rungger, Peter J Leek

Abstract:

Gate set tomography (GST) characterizes the process matrix of quantum logic gates, along with measurement and state preparation errors in quantum processors. GST typically requires extensive data collection and significant computational resources for model estimation. We propose a more efficient GST approach for qudits, utilizing the qudit Hadamard and virtual Z gates to construct fiducials while assuming virtual Z gates are error-free. Our method reduces the computational costs of estimating characterization results, making GST more practical at scale. We experimentally demonstrate the applicability of this approach on a superconducting transmon qutrit.

Emulating two qubits with a four-level transmon qudit for variational quantum algorithms

(2023)

Authors:

Shuxiang Cao, Mustafa Bakr, Giulio Campanaro, Simone D Fasciati, James Wills, Deep Lall, Boris Shteynas, Vivek Chidambaram, Ivan Rungger, Peter Leek

Encoding optimization for quantum machine learning demonstrated on a superconducting transmon qutrit

Quantum Science and Technology IOP Publishing 9:4 (2024) 045037

Authors:

Shuxiang Cao, Weixi Zhang, Jules Tilly, Abhishek Agarwal, Mustafa Bakr, Giulio Campanaro, Simone Diego Fasciati, James Wills, Boris Shteynas, Vivek Chidambaram, Peter J Leek, Ivan Rungger

Abstract:

A qutrit represents a three-level quantum system, so that one qutrit can encode more information than a qubit, which corresponds to a two-level quantum system. This work investigates the potential of qutrit circuits in machine learning classification applications. We propose and evaluate different data-encoding schemes for qutrits, and find that the classification accuracy varies significantly depending on the used encoding. We therefore propose a training method for encoding optimization that allows to consistently achieve high classification accuracy, and show that it can also improve the performance within a data re-uploading approach. Our theoretical analysis and numerical simulations indicate that the qutrit classifier can achieve high classification accuracy using fewer components than a comparable qubit system. We showcase the qutrit classification using the encoding optimization method on a superconducting transmon qutrit, demonstrating the practicality of the proposed method on noisy hardware. Our work demonstrates high-precision ternary classification using fewer circuit elements, establishing qutrit quantum circuits as a viable and efficient tool for quantum machine learning applications.