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Main Authors: Kverne, Christopher, Akewar, Mayur, Huo, Yuqian, Patel, Tirthak, Bhimani, Janki
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.11383
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author Kverne, Christopher
Akewar, Mayur
Huo, Yuqian
Patel, Tirthak
Bhimani, Janki
author_facet Kverne, Christopher
Akewar, Mayur
Huo, Yuqian
Patel, Tirthak
Bhimani, Janki
contents The training of Quantum Neural Networks (QNNs) is hindered by the high computational cost of gradient estimation and the barren plateau problem, where optimization landscapes become intractably flat. To address these challenges, we introduce Weighted Stochastic Block Descent (WSBD), a novel optimizer with a dynamic, parameter-wise freezing strategy. WSBD intelligently focuses computational resources by identifying and temporarily freezing less influential parameters based on a gradient-derived importance score. This approach significantly reduces the number of forward passes required per training step and helps navigate the optimization landscape more effectively. Unlike pruning or layer-wise freezing, WSBD maintains full expressive capacity while adapting throughout training. Our extensive evaluation shows that WSBD converges on average 63.9% faster than Adam for the popular ground-state-energy problem, an advantage that grows with QNN size. We provide a formal convergence proof for WSBD and show that parameter-wise freezing outperforms traditional layer-wise approaches in QNNs. Project page: https://github.com/Damrl-lab/WSBD-Stochastic-Freezing-Optimizer.
format Preprint
id arxiv_https___arxiv_org_abs_2602_11383
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle WSBD: Freezing-Based Optimizer for Quantum Neural Networks
Kverne, Christopher
Akewar, Mayur
Huo, Yuqian
Patel, Tirthak
Bhimani, Janki
Machine Learning
Quantum Physics
The training of Quantum Neural Networks (QNNs) is hindered by the high computational cost of gradient estimation and the barren plateau problem, where optimization landscapes become intractably flat. To address these challenges, we introduce Weighted Stochastic Block Descent (WSBD), a novel optimizer with a dynamic, parameter-wise freezing strategy. WSBD intelligently focuses computational resources by identifying and temporarily freezing less influential parameters based on a gradient-derived importance score. This approach significantly reduces the number of forward passes required per training step and helps navigate the optimization landscape more effectively. Unlike pruning or layer-wise freezing, WSBD maintains full expressive capacity while adapting throughout training. Our extensive evaluation shows that WSBD converges on average 63.9% faster than Adam for the popular ground-state-energy problem, an advantage that grows with QNN size. We provide a formal convergence proof for WSBD and show that parameter-wise freezing outperforms traditional layer-wise approaches in QNNs. Project page: https://github.com/Damrl-lab/WSBD-Stochastic-Freezing-Optimizer.
title WSBD: Freezing-Based Optimizer for Quantum Neural Networks
topic Machine Learning
Quantum Physics
url https://arxiv.org/abs/2602.11383