Meta-learning of Gibbs states for many-body Hamiltonians with applications to Quantum Boltzmann Machines
Ruchira V Bhat, Rahul Bhowmick, Avinash Singh, Krishna Kumar Sabapathy
TL;DR
This paper introduces meta-learning algorithms for efficient quantum Gibbs state preparation on NISQ devices, enabling scalable quantum Boltzmann machine training with significant speedups and improved accuracy.
Contribution
It presents two novel meta-learning algorithms, Meta-VQT and NN-Meta VQT, for thermal state preparation, extending their application to quantum Boltzmann machines with demonstrated efficiency gains.
Findings
Successfully prepared Gibbs states for 8-qubit models
Achieved 30-fold speedup over existing methods
Enhanced training efficiency and accuracy of Quantum Boltzmann Machines
Abstract
The preparation of quantum Gibbs states is a fundamental challenge in quantum computing, essential for applications ranging from modeling open quantum systems to quantum machine learning. Building on the Meta-Variational Quantum Eigensolver framework proposed by Cervera-Lierta et al.(2021) and a problem driven ansatz design, we introduce two meta-learning algorithms: Meta-Variational Quantum Thermalizer (Meta-VQT) and Neural Network Meta-VQT (NN-Meta VQT) for efficient thermal state preparation of parametrized Hamiltonians on Noisy Intermediate-Scale Quantum (NISQ) devices. Meta-VQT utilizes a fully quantum ansatz, while NN Meta-VQT integrates a quantum classical hybrid architecture. Both leverage collective optimization over training sets to generalize Gibbs state preparation to unseen parameters. We validate our methods on upto 8-qubit Transverse Field Ising Model and the 2-qubit…
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Taxonomy
TopicsQuantum Computing Algorithms and Architecture · Quantum many-body systems · Machine Learning in Materials Science