In this thesis, I explore the domain of hybrid quantum-classical computation, the foremost approach for utilizing Noisy Intermediate-Scale Quantum (NISQ) devices. The opening chapter presents an overview of Variational Quantum Algorithms (VQAs), highlighting the primary algorithmic challenges. It offers an in-depth review of the Quantum Approximate Optimization Algorithm (QAOA), discussing its variants for ground state preparation. In the second chapter, we apply QAOA for the supervised learning of a simple Binary Neural Network. This model represents an idealized yet prototypical example of classical combinatorial optimization problems involving multi-spin interactions. In the following chapters, the discussion shifts toward quantum many-body ground state preparation, focusing on the one-dimensional Heisenberg XYZ model and the longitudinal-transverse-field Ising model (LTFIM). We have developed a novel technique that, at any point in the phase diagram, leverages the transferability of a specific class of optimal schedules from systems with small to those with larger numbers of qubits. This approach mitigates trainability issues, specifically vanishing gradients (Barren Plateaus). Next, we tailor a QAOA scheme to characterize a topological quantum phase transition within a lattice gauge theory model. This investigation is particularly significant due to its implications for high-energy physics and relevance to quantum error correction and surface codes. In the concluding chapter, I propose new stimulating research directions and help to identify core challenges and unresolved questions in variational quantum computing that transcend any particular application domain.

Quantum Approximate Optimization Algorithm and Variational Quantum Computing: from binary neural networks to ground state preparation / Torta, Pietro. - (2024 Apr 09).

Quantum Approximate Optimization Algorithm and Variational Quantum Computing: from binary neural networks to ground state preparation

TORTA, PIETRO
2024-04-09

Abstract

In this thesis, I explore the domain of hybrid quantum-classical computation, the foremost approach for utilizing Noisy Intermediate-Scale Quantum (NISQ) devices. The opening chapter presents an overview of Variational Quantum Algorithms (VQAs), highlighting the primary algorithmic challenges. It offers an in-depth review of the Quantum Approximate Optimization Algorithm (QAOA), discussing its variants for ground state preparation. In the second chapter, we apply QAOA for the supervised learning of a simple Binary Neural Network. This model represents an idealized yet prototypical example of classical combinatorial optimization problems involving multi-spin interactions. In the following chapters, the discussion shifts toward quantum many-body ground state preparation, focusing on the one-dimensional Heisenberg XYZ model and the longitudinal-transverse-field Ising model (LTFIM). We have developed a novel technique that, at any point in the phase diagram, leverages the transferability of a specific class of optimal schedules from systems with small to those with larger numbers of qubits. This approach mitigates trainability issues, specifically vanishing gradients (Barren Plateaus). Next, we tailor a QAOA scheme to characterize a topological quantum phase transition within a lattice gauge theory model. This investigation is particularly significant due to its implications for high-energy physics and relevance to quantum error correction and surface codes. In the concluding chapter, I propose new stimulating research directions and help to identify core challenges and unresolved questions in variational quantum computing that transcend any particular application domain.
9-apr-2024
Santoro, Giuseppe Ernesto
Torta, Pietro
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.11767/138170
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