Quantum-Classical Hybrid Molecular Autoencoder for Advancing Classical Decoding

Authors

  • Afrar Jahin Augusta University
  • Yi Pan University Of Georgia
  • Yingfeng Wang University of Tennessee at Chattanooga
  • Tianming Liu University of Georgia
  • Wei Zhang Augusta University

DOI:

https://doi.org/10.1609/aaaiss.v7i1.36907

Abstract

Although recent advances in quantum machine learning (QML) offer significant potential for enhancing generative models, particularly in molecular design, a large array of classical approaches still face challenges in achieving high fidelity and validity. In particular, the integration of QML with sequence-based tasks, such as Simplified Molecular Input Line Entry System (SMILES) string reconstruction, remains underexplored and usually suffers from fidelity degradation. In this work, we propose a hybrid quantum-classical architecture for SMILES reconstruction that integrates quantum encoding with classical sequence modeling to improve quantum fidelity and classical similarity. Our approach achieves a quantum fidelity of approximately 84% and a classical reconstruction similarity of 60%, surpassing existing quantum baselines. Our work lays a promising foundation for future QML applications, striking a balance between expressive quantum representations and classical sequence models and catalyzing broader research on quantum-aware sequence models for molecular and drug discovery.
AAAI Fall Symposium 2025 Proceedings Cover

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Published

2025-11-23

How to Cite

Jahin, A., Pan, Y., Wang, Y., Liu, T., & Zhang, W. (2025). Quantum-Classical Hybrid Molecular Autoencoder for Advancing Classical Decoding. Proceedings of the AAAI Symposium Series, 7(1), 368–373. https://doi.org/10.1609/aaaiss.v7i1.36907

Issue

Vol. 7 No. 1: Proceedings of the 2025 AAAI Fall Symposium Series

Section

First AAAI Symposium on Quantum Information & Machine Learning (QIML): Bridging Quantum Computing and Artificial Intelligence