Related papers: Neural network based deep learning analysis of semiconductor quantum dot qubits for automated control

Neural network based deep learning analysis of semiconductor quantum dot qubits for automated control

URL: http://arxiv.org/abs/2405.04524v1
Date: Tue, 7 May 2024 17:56:12 GMT
Title: Neural network based deep learning analysis of semiconductor quantum dot qubits for automated control
Authors: Jacob R. Taylor, Sankar Das Sarma,
Abstract summary: We introduce a novel methodology that employs machine learning, specifically convolutional neural networks (CNNs), to discern the disorder landscape in the parameters of the disordered extended Hubbard model. Remarkably, our CNN can process site-specific disorder in Hubbard parameters, including variations in hopping constants. Our approach allows for the tuning of five or more quantum dots at a time, effectively addressing the often-overlooked issue of crosstalk.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Machine learning offers a largely unexplored avenue for improving noisy disordered devices in physics using automated algorithms. Through simulations that include disorder in physical devices, particularly quantum devices, there is potential to learn about disordered landscapes and subsequently tune devices based on those insights. In this work, we introduce a novel methodology that employs machine learning, specifically convolutional neural networks (CNNs), to discern the disorder landscape in the parameters of the disordered extended Hubbard model underlying the semiconductor quantum dot spin qubit architectures. This technique takes advantage of experimentally obtainable charge stability diagrams from neighboring quantum dot pairs, enabling the CNN to accurately identify disorder in each parameter of the extended Hubbard model. Remarkably, our CNN can process site-specific disorder in Hubbard parameters, including variations in hopping constants, on-site potentials (gate voltages), and both intra-site and inter-site Coulomb terms. This advancement facilitates the prediction of spatially dependent disorder across all parameters simultaneously with high accuracy ($R^2>0.994$) and fewer parameter constraints, marking a significant improvement over previous methods that were focused only on analyzing on-site potentials at low coupling. Furthermore, our approach allows for the tuning of five or more quantum dots at a time, effectively addressing the often-overlooked issue of crosstalk. Not only does our method streamline the tuning process, potentially enabling fully automated adjustments, but it also introduces a "no trust" verification method to rigorously validate the neural network's predictions. Ultimately, this work aims to lay the groundwork for generalizing our method to tackle a broad spectrum of physical problems.

Related papers

Quantum-enhanced learning with a controllable bosonic variational sensor network [0.40964539027092906]
Supervised learning assisted by an entangled sensor network (SLAEN) We propose a SLAEN capable of handling nonlinear data classification tasks. We uncover a threshold phenomenon in classification error -- when the energy of probes exceeds a certain threshold, the error drastically to zero.
arXiv Detail & Related papers (2024-04-28T19:41:40Z)
Projective Quantum Eigensolver via Adiabatically Decoupled Subsystem Evolution: a Resource Efficient Approach to Molecular Energetics in Noisy Quantum Computers [0.0]
We develop a projective formalism that aims to compute ground-state energies of molecular systems accurately using Noisy Intermediate Scale Quantum (NISQ) hardware. We demonstrate the method's superior performance under noise while concurrently ensuring requisite accuracy in future fault-tolerant systems.
arXiv Detail & Related papers (2024-03-13T13:27:40Z)
Optical Quantum Sensing for Agnostic Environments via Deep Learning [59.088205627308]
We introduce an innovative Deep Learning-based Quantum Sensing scheme. It enables optical quantum sensors to attain Heisenberg limit (HL) in agnostic environments. Our findings offer a new lens through which to accelerate optical quantum sensing tasks.
arXiv Detail & Related papers (2023-11-13T09:46:05Z)
Deep Quantum Error Correction [73.54643419792453]
Quantum error correction codes (QECC) are a key component for realizing the potential of quantum computing. In this work, we efficiently train novel emphend-to-end deep quantum error decoders. The proposed method demonstrates the power of neural decoders for QECC by achieving state-of-the-art accuracy.
arXiv Detail & Related papers (2023-01-27T08:16:26Z)
Neural networks for Bayesian quantum many-body magnetometry [0.0]
Entangled quantum many-body systems can be used as sensors that enable the estimation of parameters with a precision larger than that achievable with ensembles of individual quantum detectors. This entails a complexity that can hinder the applicability of Bayesian inference techniques. We show how to circumvent these issues by using neural networks that faithfully reproduce the dynamics of quantum many-body sensors.
arXiv Detail & Related papers (2022-12-22T22:13:49Z)
Towards Neural Variational Monte Carlo That Scales Linearly with System Size [67.09349921751341]
Quantum many-body problems are central to demystifying some exotic quantum phenomena, e.g., high-temperature superconductors. The combination of neural networks (NN) for representing quantum states, and the Variational Monte Carlo (VMC) algorithm, has been shown to be a promising method for solving such problems. We propose a NN architecture called Vector-Quantized Neural Quantum States (VQ-NQS) that utilizes vector-quantization techniques to leverage redundancies in the local-energy calculations of the VMC algorithm.
arXiv Detail & Related papers (2022-12-21T19:00:04Z)
Improved Tomographic Estimates by Specialised Neural Networks [0.0]
We show that a neural network (NN) can improve the tomographic estimate of parameters by including a convolutional stage. We demonstrate that a stable and reliable operation is achievable by training the network only with simulated data.
arXiv Detail & Related papers (2022-11-21T17:15:23Z)
Neural network enhanced measurement efficiency for molecular groundstates [63.36515347329037]
We adapt common neural network models to learn complex groundstate wavefunctions for several molecular qubit Hamiltonians. We find that using a neural network model provides a robust improvement over using single-copy measurement outcomes alone to reconstruct observables.
arXiv Detail & Related papers (2022-06-30T17:45:05Z)
Simulating the Mott transition on a noisy digital quantum computer via Cartan-based fast-forwarding circuits [62.73367618671969]
Dynamical mean-field theory (DMFT) maps the local Green's function of the Hubbard model to that of the Anderson impurity model. Quantum and hybrid quantum-classical algorithms have been proposed to efficiently solve impurity models. This work presents the first computation of the Mott phase transition using noisy digital quantum hardware.
arXiv Detail & Related papers (2021-12-10T17:32:15Z)
Variational learning of quantum ground states on spiking neuromorphic hardware [0.0]
High-dimensional sampling spaces and transient autocorrelations confront neural networks with a challenging computational bottleneck. Compared to conventional neural networks, physical-model devices offer a fast, efficient and inherently parallel substrate. We demonstrate the ability of a neuromorphic chip to represent the ground states of quantum spin models by variational energy minimization.
arXiv Detail & Related papers (2021-09-30T14:39:45Z)
Quantum-tailored machine-learning characterization of a superconducting qubit [50.591267188664666]
We develop an approach to characterize the dynamics of a quantum device and learn device parameters. This approach outperforms physics-agnostic recurrent neural networks trained on numerically generated and experimental data. This demonstration shows how leveraging domain knowledge improves the accuracy and efficiency of this characterization task.
arXiv Detail & Related papers (2021-06-24T15:58:57Z)

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

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.