Accuracy-Aware MLLM Task Offloading and Resource Allocation in UAV-Assisted Satellite Edge Computing

Збережено в:

Бібліографічні деталі
Опубліковано в::	Drones vol. 9, no. 7 (2025), p. 500-525
Автор:	Yan Huabing
Інші автори:	Huang Hualong, Zhao Zijia, Wang, Zhi, Zhao Zitian
Опубліковано:	MDPI AG
Предмети:	Internet of Things Adaptability Bandwidths Optimization techniques Real time Edge computing Resource allocation Mobile computing Adaptation Remote monitoring Unmanned aerial vehicles Machine learning Low earth orbit satellites Energy consumption Low earth orbits Nonlinear programming Distributed processing Efficiency Scheduling Dynamic programming Large language models Artificial intelligence Cloud computing Decision making Optimization Network latency Computation offloading Variables Algorithms Mixed integer
Онлайн доступ:	Citation/Abstract Full Text + Graphics Full Text - PDF
Теги:	Додати тег Немає тегів, Будьте першим, хто поставить тег для цього запису!

Опис
Короткий огляд:	This paper presents a novel framework for optimizing multimodal large language model (MLLM) inference through task offloading and resource allocation in UAV-assisted satellite edge computing (SEC) networks. MLLMs leverage transformer architectures to integrate heterogeneous data modalities for IoT applications, particularly real-time monitoring in remote areas. However, cloud computing dependency introduces latency, bandwidth, and privacy challenges, while IoT device limitations require efficient distributed computing solutions. SEC, utilizing low-earth orbit (LEO) satellites and unmanned aerial vehicles (UAVs), extends mobile edge computing to provide ubiquitous computational resources for remote IoTDs. We formulate the joint optimization of MLLM task offloading and resource allocation as a mixed-integer nonlinear programming (MINLP) problem, minimizing latency and energy consumption while optimizing offloading decisions, power allocation, and UAV trajectories. To address the dynamic SEC environment characterized by satellite mobility, we propose an action-decoupled soft actor–critic (AD-SAC) algorithm with discrete–continuous hybrid action spaces. The simulation results demonstrate that our approach significantly outperforms conventional deep reinforcement learning methods in convergence and system cost reduction compared to baseline algorithms.
ISSN:	2504-446X
DOI:	10.3390/drones9070500
Джерело:	Advanced Technologies & Aerospace Database