Doctoral Defense - Hrishikesh Dutta

About the Event

The Department of Electrical and Computer Engineering
Michigan State University
Ph.D. Dissertation Defense

Tuesday, May 7, 2024, at 3:00 pm
Engineering Building Room 2108 and Zoom
Contact Department or Advisor for Zoom Information



ABSTRACT

MULTI-AGENT REINFORCEMENT LEARNING FOR NETWORK PROTOCOL SYNTHESIS


By: Hrishikesh Dutta


Advisor: Dr. Subir Biswas

The proliferation of Internet-of-Things (IoTs) and Wireless Sensor Networks (WSNs) has led to the widespread deployment of devices and sensors across various domains like wearables, smart cities, agriculture, and health monitoring. These networks usually comprise of resource-constrained nodes with ultra-thin energy budget. As a result, it is important to design network protocols that can judiciously utilize the available networking resources while minimizing energy consumption and maintaining network performance. The standardized protocols often underperform under general conditions because of their inability to adapt to changing networking conditions, including topological and traffic heterogeneities and various other dynamics. In this thesis, we develop a novel paradigm of learning-enabled network protocol synthesis to address these shortcomings.

The key concept here is that each node, equipped with a Reinforcement Learning (RL) engine, learns to find situation-specific protocol logic for network performance improvement. The nodes’ behavior in different heterogeneous and dynamic network conditions are formulated as a Markov Decision Process (MDP), which is then solved using RL and its variants. The paradigm is implemented in a decentralized setting, where each node learns its policies independently without centralized arbitration. To handle the challenges of limited information visibility in partially connected mesh networks in such decentralized settings, different design techniques including confidence-informed parameter computation and localized information driven updates, have been employed. We specifically focus on developing frameworks for synthesizing access control protocols that deal with network performance improvement from multiple perspectives, viz., network throughput, access delay, energy efficiency and wireless bandwidth usage.

A multitude of learning innovations has been adopted to explore the protocol synthesis concept in a diverse set of MAC arrangements. First, the framework is developed for random access MAC setting, where the learning-driven logic is shown to be able to minimize collisions with a fair share of wireless bandwidth in the network. A hysteresis-learning enabled design is exploited for handling the trade-off between convergence time and performance in a distributed setting. Next, the ability of the learning-driven protocols is explored in TDMA-based MAC arrangement for enabling decentralized slot scheduling and transmit-sleep-listen decision making. We demonstrate how the proposed approach, using a multi-tier learning module and context-specific decision making, enables the nodes to make judicious transmission/sleep decisions on-the-fly to reduce energy expenditure while maintaining network performance. The multi-tier learning framework, comprising of cooperative Multi-Armed Bandits (MAB) and RL agents, solve a multidimensional network performance optimization problem. This system is then improved from scalability and adaptability perspective by employing a Contextual Deep Reinforcement Learning (CDRL) framework. The energy management framework is then extended for energy-harvesting networks with spatiotemporal energy profiles. A learning confidence parameter-guided update rule is developed to make the framework robust to unreliability of RL observables. Finally, the thesis investigates protocol robustness against malicious agents, thus demonstrating versatility and adaptability of learning-driven protocol synthesis in hostile networking environments.

Persons with disabilities have the right to request and receive reasonable accommodation. Please call the Department of Electrical and Computer Engineering at 355-5066 at least one day prior to the seminar; requests received after this date will be met when possible.