All events are in Central time unless specified.
Presentation

Ph.D. Dissertation Defense: Warnakulasuriya Chandima Fernando

Date:
Time:
2:00 pm – 3:00 pm
Schorr Center Room: 211
1100 T St
Lincoln NE 68588
Additional Info: SHOR
Ph.D. Dissertation Defense: Warnakulasuriya Chandima Fernando
Tuesday, December 13th, 2022
2:00 PM
Location: 211 Schorr Center and Zoom
Zoom: https://unl.zoom.us/j/94162678117

“Resource-Aware Development of Distributed Multi-UAS Control Algorithms”

Distributed Unmanned Aerial Systems (UAS) are limited in computational resources, communication resources, and energy resources, which in turn drastically reduce their utility in multi-UAS applications. Orthodox countermeasures which include adding additional computational devices, advanced communication devices, or heavier batteries with more power, inversely co-relate to the performance of the UAS. The reason being the added weight and the increased power requirements offset the additional resources the countermeasures provide. Hence, the feasible solution is to intelligently utilize the limited resources available. We present the resource-aware development of distributed multi-UAS control algorithms as the pathway toward intelligent resource utilization.

This dissertation first introduces co-regulation techniques to dynamically allocate resources in distributed multi-agent systems controlled by consensus algorithms. Our need-based resource allocation shows significant savings in resources and a shorter time to convergence of the consensus algorithm whilst providing the user the option to adjust the controller gains for the user’s desired level of performance. We prove that our co-regulation techniques are robust to delays in communication. Our second contribution is a novel algorithm that combines consensus algorithms with active learning to drastically reduce the resource and time costs of re-training the convolutional neural network. Our final contribution is a series of resource-aware design decisions on the successful implementation of a hierarchical reinforcement learning-based linear quadratic integral(HRL-LQI) controller on a swarm of four UAS systems.

Committee:
Dr. Justin Bradley, Co-Chair
Dr. Carrick Detweiler, Co-Chair
Dr. Leen-Kiat Soh
Dr. Piyush Grover
Dr. Jemen George

Download this event to my calendar