Overcoming Barren Plateaus in Variational Quantum Circuits using a Two-Step Least Squares Approach
- URL: http://arxiv.org/abs/2601.18060v1
- Date: Mon, 26 Jan 2026 01:29:02 GMT
- Title: Overcoming Barren Plateaus in Variational Quantum Circuits using a Two-Step Least Squares Approach
- Authors: Francis Boabang, Samuel Asante Gyamerah,
- Abstract summary: Variational Quantum Algorithms are a vital part of quantum computing.<n>As algorithms scale up, they cannot escape the barren-plateau phenomenon.<n>We introduce a two-stage framework to overcome the plateau problem.
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- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Variational Quantum Algorithms are a vital part of quantum computing. It is a blend of quantum and classical methods for tackling tough problems in machine learning, chemistry, and combinatorial optimization. Yet as these algorithms scale up, they cannot escape the barren-plateau phenomenon. As systems grow, gradients can vanish so quickly that training deep or randomly initialized circuits becomes nearly impossible. To overcome the barren plateau problem, we introduce a two-stage optimization framework. First comes the convex initialization stage. Here, we shape the quantum energy landscape, the Hilmaton landscape, into a smooth, low-energy basin. This step makes gradients easier to spot and keeps noise from derailing the process. Once we have gotten a stable gradient flow, we move to the second stage: nonconvex refinement. In this phase, we allow the algorithm to explore different energy minima, thereby making the model more expressive. Finally, we used our two-stage solution to perform quantum cryptanalysis of the quantum key distribution protocol (i.e., BB84) to determine the optimal cloning strategies. The simulation results showed that our proposed two-stage solution outperforms its random initialization counterpart.
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