Goal-Oriented Middleware Filtering at Transport Layer Based on Value of Updates

TL;DR

This paper introduces a goal-oriented middleware filtering mechanism at the transport layer for CPS and IoT applications, which improves control performance by evaluating the value of updates and discarding unnecessary packets.

Contribution

It presents a novel transport layer protocol that uses Value of Updates (VoU) to optimize network traffic and enhance control stability in heterogeneous IoT environments.

Findings

Achieves approximately 60% better control stability compared to naive approaches.

Effectively manages network traffic by filtering updates based on their predicted contribution.

Demonstrates improved performance across diverse hardware and network setups.

Abstract

This work explores employing the concept of goal-oriented (GO) semantic communication for real-time monitoring and control. Generally, GO communication advocates for the deep integration of application targets into the network design. We consider CPS and IoT applications where sensors generate a tremendous amount of network traffic toward monitors or controllers. Here, the practical introduction of GO communication must address several challenges. These include stringent timing requirements, challenging network setups, and limited computing and communication capabilities of the devices involved. Moreover, real-life CPS deployments often rely on heterogeneous communication standards prompted by specific hardware. To address these issues, we introduce a middleware design of a GO distributed Transport Layer (TL) framework for control applications. It offers end-to-end performance improvements for diverse setups and transmitting hardware. The proposed TL protocol evaluates the Value of sampled state Updates (VoU) for the application goal. It decides whether to admit or discard the corresponding packets, thus offloading the network. VoU captures the contribution of utilizing the updates at the receiver into the application's performance. We introduce a belief network and the augmentation procedure used by the sensor to predict the evolution of the control process, including possible delays and losses of status updates in the network. The prediction is made either using a control model dynamics or a Long-Short Term Memory neural network approach. We test the performance of the proposed TL in the experimental framework using Industrial IoT Zolertia ReMote sensors. We show that while existing approaches fail to deliver sufficient control performance, our VoU-based TL scheme ensures stability and performs $\sim$$60\%$ better than the naive GO TL we proposed in our previous work.