MADQRL: Distributed Quantum Reinforcement Learning Framework For Multi-agent Environments
2026 Β· Abhishek Sawaika, Samuel Yen-Chi Chen, Udaya Parampalli, et al.
Abstract
Reinforcement learning (RL) is one of the most practical ways to learn from real-life use-cases. Motivated from the cognitive methods used by humans makes it a widely acceptable strategy in the field of artificial intelligence. Most of the environments used for RL are often high-dimensional, and traditional RL algorithms becomes computationally expensive and challenging to effectively learn from such systems. Recent advancements in practical demonstration of quantum computing (QC) theories, such as compact encoding, enhanced representation and learning algorithms, random sampling, or the inherent stochastic nature of quantum systems, have opened up new directions to tackle these challenges. Quantum reinforcement learning (QRL) is seeking significant traction over the past few years. However, the current state of quantum hardware is not enough to cater for such high-dimensional environments with complex multi-agent setup. To tackle this issue, we propose a distributed framework for QRL
Authors
(none)
Tags
Stats
Related papers
- An Introduction To Quantum Reinforcement Learning (QRL) (2024)0.00
- Quantum-train-based Distributed Multi-agent Reinforcement Learning (2024)7.16
- Efficient Quantum Recurrent Reinforcement Learning Via Quantum Reservoir Computing (2023)0.00
- Towards Multi-agent Reinforcement Learning Using Quantum Boltzmann Machines (2021)0.00
- Quantum Framework For Reinforcement Learning: Integrating Markov Decision Process, Quantum Arithmetic, And Trajectory Search (2024)0.00
- Eqmarl: Entangled Quantum Multi-agent Reinforcement Learning For Distributed Cooperation Over Quantum Channels (2024)0.00
- Learning To Coordinate Via Quantum Entanglement In Multi-agent Reinforcement Learning (2026)0.00
- Hybrid Quantum-classical Algorithm For Near-optimal Planning In Pomdps (2025)0.00