UAV-enabled Computing Power Networks: Task Completion Probability Analysis

TL;DR

This paper introduces a framework for UAV-enabled computing networks that uses stochastic models to analyze task completion probability, demonstrating the importance of balancing communication and computational resources for improved performance.

Contribution

It proposes a novel analytical approach to evaluate UAV-enabled computing networks using task completion probability, incorporating stochastic geometry and processes.

Findings

Distribution of computing nodes significantly improves performance.

Balancing communication and computational capabilities is crucial.

Analytical expressions enable performance assessment under complex dynamics.

Abstract

This paper presents an innovative framework that synergistically enhances computing performance through ubiquitous computing power distribution and dynamic computing node accessibility control via adaptive unmanned aerial vehicle (UAV) positioning, establishing UAV-enabled Computing Power Networks (UAV-CPNs). In UAV-CPNs, UAVs function as dynamic aerial relays, outsourcing tasks generated in the request zone to an expanded service zone, consisting of a diverse range of computing devices, from vehicles with onboard computational capabilities and edge servers to dedicated computing nodes. This approach has the potential to alleviate communication bottlenecks in traditional computing power networks and overcome the "island effect" observed in multi-access edge computing. However, how to quantify the network performance under the complex spatio-temporal dynamics of both communication and computing power is a significant challenge, which introduces intricacies beyond those found in conventional networks. To address this, in this paper, we introduce task completion probability as the primary performance metric for evaluating the ability of UAV-CPNs to complete ground users' tasks within specified end-to-end latency requirements. Utilizing theories from stochastic processes and stochastic geometry, we derive analytical expressions that facilitate the assessment of this metric. Our numerical results emphasize that striking a delicate balance between communication and computational capabilities is essential for enhancing the performance of UAV-CPNs. Moreover, our findings show significant performance gains from the widespread distribution of computing nodes.