Gradient-based adaptive modeling for IoT data transmission reduction

PDF / 1,598,748 Bytes
14 Pages / 595.276 x 790.866 pts Page_size
64 Downloads / 187 Views

(0123456789().,-volV)(0123456789(). ,- volV)

Gradient-based adaptive modeling for IoT data transmission reduction Pei Heng Li1

•

Hee Yong Youn2

Springer Science+Business Media, LLC, part of Springer Nature 2020

Abstract Spatial and temporal correlation between sensor observations in an Internet of Things environment can be exploited to eliminate unnecessary transmissions. Transmitting less data certainly contributes to meet the growing need for energysaving and robust transmissions, thus prolong the lifespan of the entire WSN. Spatiotemporal correlation-based dual prediction (DP) and data compression (DC) schemes aim to reduce the amount of data transmission while ensuring data accuracy. In practice, however, the existing methods restrict the stability of the system when the model hyper-parameters are uncertain. Thus adaptive model has lately attracted extensive attention for the development of resource-constrained WSN. In this paper, we propose a gradient-based adaptive model that implements both schemes in a two-tier data reduction framework. To the best of our knowledge, the proposed scheme is the first attempt to introduce adaptiveness into both the DP and DC schemes by using a simple gradient optimization method. Gradient-based Optimal Step-size LMS (GO-LMS) is introduced to make the DP aspects adaptive, while a Gradient-based Adaptive PCA (GA-PCA) approach is used for the DC aspects. The Barzilai–Borwein method is incorporated into the gradient optimization to enable adaptive computation of the step-size for each iteration. Through extensive simulations, the developed framework was found to outperform other state-of-the-art schemes in terms of both the transmission reduction ratio and data recovery accuracy. Keywords Adaptive modeling Data transmission reduction Gradient optimization Internet of Things (IoT) Spatiotemporal correlation

1 Introduction In recent years, considerable attention has been paid to energy-efficient IoT because they can be used for a wide range of different applications in smart homes, disaster detection, traffic management, environmental monitoring, etc. In particular, IoT-based WSN has been widely adopted in different application environments. However, a large amount of redundant data transmitted through the network results in network delay, data congestion and energy dissipation, which hinders the development of resource-

& Pei Heng Li [email protected] Hee Yong Youn [email protected] 1

Department of Electrical and Computer Engineering, Sungkyunkwan University, Suwon, Korea

2

College of Software, Sungkyunkwan University, Suwon, Korea

constrained WSN. There is therefore an urgent need to develop effective ways of preventing unnecessary transmissions to meet the growing need for energy-saving and robust transmission in WSN [1]. Nevertheless, the existing methods have higher computational cost and complexity, and restrict the stability of the system when the model hyper-parameters are uncertain. Thus, non-parametric adaptive model has lately become a popular resea

Data Loading...

Gradient-based adaptive modeling for IoT data transmission reduction

Recommend Documents

Data Reduction Techniques in Fog Data Analytics for IoT Applications

Modeling the NB-IoT Transmission Process with Intermittent Network Availability

Enhanced Lightweight Algorithm to Secure Data Transmission in IoT Systems

Energy efficient compressive sensing with predictive model for IoT based medical data transmission

Blockchain-Based Sybil-Secure Data Transmission (SSDT) IoT Framework for Smart City Applications

Secure Big Data Transmission with Trust Management for the Internet of Things (IoT)

Data Transmission

Adaptive Tuning Parameters for Data Transmission over IEEE-802.15.4 Wireless Sensors Network

IoT data stream analytics

Data Reduction

ASCRClu: an adaptive subspace combination and reduction algorithm for clustering of high-dimensional data

Nested Petri Nets for Adaptive Process Modeling