Decoding surface codes with deep reinforcement learning and
probabilistic policy reuse
- URL: http://arxiv.org/abs/2212.11890v1
- Date: Thu, 22 Dec 2022 17:24:32 GMT
- Title: Decoding surface codes with deep reinforcement learning and
probabilistic policy reuse
- Authors: Elisha Siddiqui Matekole, Esther Ye, Ramya Iyer, and Samuel Yen-Chi
Chen
- Abstract summary: Current quantum hardware, also known as noisy intermediate-scale quantum computers (NISQ), are still unable to carry out computations faithfully.
Recent developments of machine learning (ML)-based techniques especially the reinforcement learning (RL) methods have been applied to the decoding problem.
We propose a continual reinforcement learning method to address these decoding challenges.
- Score: 0.5999777817331317
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum computing (QC) promises significant advantages on certain hard
computational tasks over classical computers. However, current quantum
hardware, also known as noisy intermediate-scale quantum computers (NISQ), are
still unable to carry out computations faithfully mainly because of the lack of
quantum error correction (QEC) capability. A significant amount of theoretical
studies have provided various types of QEC codes; one of the notable
topological codes is the surface code, and its features, such as the
requirement of only nearest-neighboring two-qubit control gates and a large
error threshold, make it a leading candidate for scalable quantum computation.
Recent developments of machine learning (ML)-based techniques especially the
reinforcement learning (RL) methods have been applied to the decoding problem
and have already made certain progress. Nevertheless, the device noise pattern
may change over time, making trained decoder models ineffective. In this paper,
we propose a continual reinforcement learning method to address these decoding
challenges. Specifically, we implement double deep Q-learning with
probabilistic policy reuse (DDQN-PPR) model to learn surface code decoding
strategies for quantum environments with varying noise patterns. Through
numerical simulations, we show that the proposed DDQN-PPR model can
significantly reduce the computational complexity. Moreover, increasing the
number of trained policies can further improve the agent's performance. Our
results open a way to build more capable RL agents which can leverage
previously gained knowledge to tackle QEC challenges.
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