Optimization Theory Based Deep Reinforcement Learning for Resource
Allocation in Ultra-Reliable Wireless Networked Control Systems
- URL: http://arxiv.org/abs/2311.16895v2
- Date: Tue, 19 Dec 2023 15:26:36 GMT
- Title: Optimization Theory Based Deep Reinforcement Learning for Resource
Allocation in Ultra-Reliable Wireless Networked Control Systems
- Authors: Hamida Qumber Ali, Amirhassan Babazadeh Darabi, Sinem Coleri
- Abstract summary: This paper introduces a novel optimization theory based deep reinforcement learning (DRL) framework for the joint design of controller and communication systems.
The objective of minimum power consumption is targeted while satisfying the schedulability and rate constraints of the communication system.
- Score: 10.177917426690701
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The design of Wireless Networked Control System (WNCS) requires addressing
critical interactions between control and communication systems with minimal
complexity and communication overhead while providing ultra-high reliability.
This paper introduces a novel optimization theory based deep reinforcement
learning (DRL) framework for the joint design of controller and communication
systems. The objective of minimum power consumption is targeted while
satisfying the schedulability and rate constraints of the communication system
in the finite blocklength regime and stability constraint of the control
system. Decision variables include the sampling period in the control system,
and blocklength and packet error probability in the communication system. The
proposed framework contains two stages: optimization theory and DRL. In the
optimization theory stage, following the formulation of the joint optimization
problem, optimality conditions are derived to find the mathematical relations
between the optimal values of the decision variables. These relations allow the
decomposition of the problem into multiple building blocks. In the DRL stage,
the blocks that are simplified but not tractable are replaced by DRL. Via
extensive simulations, the proposed optimization theory based DRL approach is
demonstrated to outperform the optimization theory and pure DRL based
approaches, with close to optimal performance and much lower complexity.
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