Related papers: Concept learning of parameterized quantum models from limited measurements

Concept learning of parameterized quantum models from limited measurements

URL: http://arxiv.org/abs/2408.05116v1
Date: Fri, 9 Aug 2024 15:07:42 GMT
Title: Concept learning of parameterized quantum models from limited measurements
Authors: Beng Yee Gan, Po-Wei Huang, Elies Gil-Fuster, Patrick Rebentrost,
Abstract summary: We take the probabilistic nature of quantum measurements into account in classical modelling and discuss these quantities under a single unified learning framework. We provide provable guarantees for learning parameterized quantum models that also quantify the asymmetrical effects and interplay of the two variables on the performance of learning algorithms. Our work provides new tools to analyse the operational influence of finite measurement noise in the classical learning of quantum systems.
Score: 0.7499722271664147
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Classical learning of the expectation values of observables for quantum states is a natural variant of learning quantum states or channels. While learning-theoretic frameworks establish the sample complexity and the number of measurement shots per sample required for learning such statistical quantities, the interplay between these two variables has not been adequately quantified before. In this work, we take the probabilistic nature of quantum measurements into account in classical modelling and discuss these quantities under a single unified learning framework. We provide provable guarantees for learning parameterized quantum models that also quantify the asymmetrical effects and interplay of the two variables on the performance of learning algorithms. These results show that while increasing the sample size enhances the learning performance of classical machines, even with single-shot estimates, the improvements from increasing measurements become asymptotically trivial beyond a constant factor. We further apply our framework and theoretical guarantees to study the impact of measurement noise on the classical surrogation of parameterized quantum circuit models. Our work provides new tools to analyse the operational influence of finite measurement noise in the classical learning of quantum systems.

Related papers

Entanglement-induced provable and robust quantum learning advantages [0.0]
We rigorously establish a noise-robust, unconditional quantum learning advantage in terms of expressivity, inference speed, and training efficiency. Our proof is information-theoretic and pinpoints the origin of this advantage.
arXiv Detail & Related papers (2024-10-04T02:39:07Z)
Flexible Error Mitigation of Quantum Processes with Data Augmentation Empowered Neural Model [9.857921247636451]
We propose a data augmentation empowered neural model for error mitigation (DAEM) Our model does not require any prior knowledge about the specific noise type and measurement settings. It can estimate noise-free statistics solely from the noisy measurement results of the target quantum process.
arXiv Detail & Related papers (2023-11-03T05:52:14Z)
Learning quantum properties from short-range correlations using multi-task networks [3.7228085662092845]
We introduce a neural network model that can predict various quantum properties of many-body quantum states with constant correlation length. The model is based on the technique of multi-task learning, which we show to offer several advantages over traditional single-task approaches.
arXiv Detail & Related papers (2023-10-18T08:53:23Z)
Quantum data learning for quantum simulations in high-energy physics [55.41644538483948]
We explore the applicability of quantum-data learning to practical problems in high-energy physics. We make use of ansatz based on quantum convolutional neural networks and numerically show that it is capable of recognizing quantum phases of ground states. The observation of non-trivial learning properties demonstrated in these benchmarks will motivate further exploration of the quantum-data learning architecture in high-energy physics.
arXiv Detail & Related papers (2023-06-29T18:00:01Z)
Transition Role of Entangled Data in Quantum Machine Learning [51.6526011493678]
Entanglement serves as the resource to empower quantum computing. Recent progress has highlighted its positive impact on learning quantum dynamics. We establish a quantum no-free-lunch (NFL) theorem for learning quantum dynamics using entangled data.
arXiv Detail & Related papers (2023-06-06T08:06:43Z)
Classical-to-Quantum Transfer Learning Facilitates Machine Learning with Variational Quantum Circuit [62.55763504085508]
We prove that a classical-to-quantum transfer learning architecture using a Variational Quantum Circuit (VQC) improves the representation and generalization (estimation error) capabilities of the VQC model. We show that the architecture of classical-to-quantum transfer learning leverages pre-trained classical generative AI models, making it easier to find the optimal parameters for the VQC in the training stage.
arXiv Detail & Related papers (2023-05-18T03:08:18Z)
Anticipative measurements in hybrid quantum-classical computation [68.8204255655161]
We present an approach where the quantum computation is supplemented by a classical result. Taking advantage of its anticipation also leads to a new type of quantum measurements, which we call anticipative. In an anticipative quantum measurement the combination of the results from classical and quantum computations happens only in the end.
arXiv Detail & Related papers (2022-09-12T15:47:44Z)
Quantum Local Differential Privacy and Quantum Statistical Query Model [0.7673339435080445]
Quantum statistical queries provide a theoretical framework for investigating the computational power of a learner with limited quantum resources. In this work, we establish an equivalence between quantum statistical queries and quantum differential privacy in the local model. We consider the task of quantum multi-party computation under local differential privacy.
arXiv Detail & Related papers (2022-03-07T18:38:02Z)
Generalization Metrics for Practical Quantum Advantage in Generative Models [68.8204255655161]
Generative modeling is a widely accepted natural use case for quantum computers. We construct a simple and unambiguous approach to probe practical quantum advantage for generative modeling by measuring the algorithm's generalization performance. Our simulation results show that our quantum-inspired models have up to a $68 times$ enhancement in generating unseen unique and valid samples.
arXiv Detail & Related papers (2022-01-21T16:35:35Z)
Quantum algorithms for quantum dynamics: A performance study on the spin-boson model [68.8204255655161]
Quantum algorithms for quantum dynamics simulations are traditionally based on implementing a Trotter-approximation of the time-evolution operator. variational quantum algorithms have become an indispensable alternative, enabling small-scale simulations on present-day hardware. We show that, despite providing a clear reduction of quantum gate cost, the variational method in its current implementation is unlikely to lead to a quantum advantage.
arXiv Detail & Related papers (2021-08-09T18:00:05Z)
Importance sampling of randomized measurements for probing entanglement [0.0]
We show that combining randomized measurement protocols with importance sampling allows for characterizing entanglement in significantly larger quantum systems. A drastic reduction of statistical errors is obtained using machine-learning and tensor networks using partial information on the quantum state.
arXiv Detail & Related papers (2021-02-26T14:55:53Z)

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