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Improving Quantum Recurrent Neural Networks with Amplitude Encoding

Quantum Physics 2026-01-09 v2

Abstract

Quantum machine learning holds promise for advancing time series forecasting. The Quantum Recurrent Neural Network (QRNN), inspired by classical RNNs, encodes temporal data into quantum states that are periodically input into a quantum circuit. While prior QRNN work has predominantly used angle encoding, alternative encoding strategies like amplitude encoding remain underexplored due to their high computational complexity. In this paper, we evaluate and improve amplitude-based QRNNs using EnQode, a recently introduced method for approximate amplitude encoding. We propose a simple pre-processing technique that augments amplitude encoded inputs with their pre-normalized magnitudes, leading to improved generalization on two real world data sets. Additionally, we introduce a novel circuit architecture for the QRNN that is mathematically equivalent to the original model but achieves a substantial reduction in circuit depth. Together, these contributions demonstrate practical improvements to QRNN design in both model performance and quantum resource efficiency.

Keywords

Cite

@article{arxiv.2508.16784,
  title  = {Improving Quantum Recurrent Neural Networks with Amplitude Encoding},
  author = {Jack Morgan and Hamed Mohammadbagherpoor and Eric Ghysels},
  journal= {arXiv preprint arXiv:2508.16784},
  year   = {2026}
}

Comments

17 pages, 7 Figures

R2 v1 2026-07-01T05:02:27.831Z