Automated Ansatz Generation Using Neural Networks for Fermi-Hubbard Simulation
Session Number
2
Advisor(s)
Doug Strain, IMSA
Location
IN2 Commons
Discipline
Business
Start Date
15-4-2026 11:10 AM
End Date
15-4-2026 11:55 AM
Abstract
Quantum algorithms offer the hope to potentially solve computationally expensive problems that are too difficult for classical computers. Superposition and entanglement allow these algorithms to use quantum states to better approximate heuristic solutions. However, current hardware limitations face significant challenges from gate noise and short coherence times, forcing optimized circuits to be created. The Fermi-Hubbard model is a system used to determine the ground state energy of molecules by capturing the behavior of interacting particles in lattice systems. Many classically complex optimization problems can be run on this model, allowing them to be studied using similar computational approaches. However, quantum simulation methods depend on carefully designed variational circuits, known as ansatz structures, within algorithms such as the Variational Quantum Eigensolver. Ansatz creation requires meticulously following minimal gradients, which oftentimes results in the occurrence of a barren plateau. This work aims to investigate the effectiveness of a machine learning-based approach to generating stable, effective quantum circuits to simulate mapped problems on the Fermi-Hubbard model using a deep neural network. By deriving circuit parameters from the energy of the system, this study evaluates the performance of the generated circuits based on their ability to reach ground state convergence with strong gradients.
Automated Ansatz Generation Using Neural Networks for Fermi-Hubbard Simulation
IN2 Commons
Quantum algorithms offer the hope to potentially solve computationally expensive problems that are too difficult for classical computers. Superposition and entanglement allow these algorithms to use quantum states to better approximate heuristic solutions. However, current hardware limitations face significant challenges from gate noise and short coherence times, forcing optimized circuits to be created. The Fermi-Hubbard model is a system used to determine the ground state energy of molecules by capturing the behavior of interacting particles in lattice systems. Many classically complex optimization problems can be run on this model, allowing them to be studied using similar computational approaches. However, quantum simulation methods depend on carefully designed variational circuits, known as ansatz structures, within algorithms such as the Variational Quantum Eigensolver. Ansatz creation requires meticulously following minimal gradients, which oftentimes results in the occurrence of a barren plateau. This work aims to investigate the effectiveness of a machine learning-based approach to generating stable, effective quantum circuits to simulate mapped problems on the Fermi-Hubbard model using a deep neural network. By deriving circuit parameters from the energy of the system, this study evaluates the performance of the generated circuits based on their ability to reach ground state convergence with strong gradients.