Related papers: Identifiability and Characterization of Transmon Qutrits Through Bayesian Experimental Design

Identifiability and Characterization of Transmon Qutrits Through Bayesian Experimental Design

URL: http://arxiv.org/abs/2312.10233v2
Date: Sat, 13 Apr 2024 05:54:57 GMT
Title: Identifiability and Characterization of Transmon Qutrits Through Bayesian Experimental Design
Authors: Sohail Reddy,
Abstract summary: We present an online, Bayesian approach for quantum characterization of qutrit systems. Unlike most characterization protocols that provide point-estimates of the parameters, the proposed approach is able to estimate their probability distribution. We provide a mathematical proof of the theoretical identifiability of the model parameters and present conditions on the quantum state under which the parameters are identifiable.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Robust control of a quantum system is essential to utilize the current noisy quantum hardware to their full potential, such as quantum algorithms. To achieve such a goal, systematic search for an optimal control for any given experiment is essential. Design of optimal control pulses require accurate numerical models, and therefore, accurate characterization of the system parameters. We present an online, Bayesian approach for quantum characterization of qutrit systems which automatically and systematically identifies the optimal experiments that provide maximum information on the system parameters, thereby greatly reducing the number of experiments that need to be performed on the quantum testbed. Unlike most characterization protocols that provide point-estimates of the parameters, the proposed approach is able to estimate their probability distribution. The applicability of the Bayesian experimental design technique was demonstrated on test problems where each experiment was defined by a parameterized control pulse. In addition to this, we also presented an approach for iterative pulse extension which is robust under uncertainties in transition frequencies and coherence times, and shot noise, despite being initialized with wide uninformative priors. Furthermore, we provide a mathematical proof of the theoretical identifiability of the model parameters and present conditions on the quantum state under which the parameters are identifiable. The proof and conditions for identifiability are presented for both closed and open quantum systems using the Schroedinger equation and the Lindblad master equation respectively.

Related papers

Differentiable master equation solver for quantum device characterisation [0.0]
Differentiable models of physical systems provide a powerful platform for gradient-based algorithms. Quantum systems present a particular challenge for such characterisation and control. We present a versatile differentiable quantum master equation solver, and incorporate this solver into a framework for device characterisation.
arXiv Detail & Related papers (2024-03-07T17:23:56Z)
Finding the optimal probe state for multiparameter quantum metrology using conic programming [61.98670278625053]
We present a conic programming framework that allows us to determine the optimal probe state for the corresponding precision bounds. We also apply our theory to analyze the canonical field sensing problem using entangled quantum probe states.
arXiv Detail & Related papers (2024-01-11T12:47:29Z)
Characterization of overparametrization in the simulation of realistic quantum systems [0.0]
Quantum computing devices require exceptional control of their experimental parameters to prepare quantum states and simulate other quantum systems. Classical optimization procedures used to find such optimal control parameters, have been shown in idealized settings to exhibit different regimes of learning. Our results demonstrate that parametersatze can mitigate entropic effects from their environment, offering tantalizing opportunities for their application and experimental realization in near term quantum devices.
arXiv Detail & Related papers (2024-01-10T19:00:16Z)
Quantum hypothesis testing via robust quantum control [8.087946804627284]
We introduce a robust control approach optimized for a range of signal noise, demonstrating superior robustness beyond the predefined tolerance window. On average, both the optimal control and robust control show improvements over the uncontrolled schemes for various dephasing or decay rates.
arXiv Detail & Related papers (2023-09-11T16:19:41Z)
Importance sampling for stochastic quantum simulations [68.8204255655161]
We introduce the qDrift protocol, which builds random product formulas by sampling from the Hamiltonian according to the coefficients. We show that the simulation cost can be reduced while achieving the same accuracy, by considering the individual simulation cost during the sampling stage. Results are confirmed by numerical simulations performed on a lattice nuclear effective field theory.
arXiv Detail & Related papers (2022-12-12T15:06:32Z)
Benchmarking Quantum Simulators using Ergodic Quantum Dynamics [4.2392660892009255]
We analyze a sample-efficient protocol to estimate the fidelity between an experimentally prepared state and an ideal state. We numerically demonstrate our protocol for a variety of quantum simulator platforms.
arXiv Detail & Related papers (2022-05-24T17:18:18Z)
Dynamical learning of a photonics quantum-state engineering process [48.7576911714538]
Experimentally engineering high-dimensional quantum states is a crucial task for several quantum information protocols. We implement an automated adaptive optimization protocol to engineer photonic Orbital Angular Momentum (OAM) states. This approach represents a powerful tool for automated optimizations of noisy experimental tasks for quantum information protocols and technologies.
arXiv Detail & Related papers (2022-01-14T19:24:31Z)
Experimental Bayesian calibration of trapped ion entangling operations [48.43720700248091]
We develop and characterize an efficient calibration protocol to automatically estimate and adjust experimental parameters of the widely used Molmer-Sorensen entangling gate operation. We experimentally demonstrate a median gate infidelity of $1.3(1)cdot10-3$, requiring only $1200pm500$ experimental cycles, while completing the entire gate calibration procedure in less than one minute.
arXiv Detail & Related papers (2021-12-02T16:59:00Z)
Bosonic field digitization for quantum computers [62.997667081978825]
We address the representation of lattice bosonic fields in a discretized field amplitude basis. We develop methods to predict error scaling and present efficient qubit implementation strategies.
arXiv Detail & Related papers (2021-08-24T15:30:04Z)
Assessment of weak-coupling approximations on a driven two-level system under dissipation [58.720142291102135]
We study a driven qubit through the numerically exact and non-perturbative method known as the Liouville-von equation with dissipation. We propose a metric that may be used in experiments to map the regime of validity of the Lindblad equation in predicting the steady state of the driven qubit.
arXiv Detail & Related papers (2020-11-11T22:45:57Z)
Discrete Adjoints for Accurate Numerical Optimization with Application to Quantum Control [0.0]
This paper considers the optimal control problem for realizing logical gates in a closed quantum system. The system is discretized with the Stormer-Verlet scheme, which is a symplectic partitioned Runge-Kutta method. A parameterization of the control functions based on B-splines with built-in carrier waves is also introduced.
arXiv Detail & Related papers (2020-01-04T00:02:23Z)

This list is automatically generated from the titles and abstracts of the papers in this site.