Litcius/Paper detail

Adaptive Mini-Batch Gradient-Ascent-Based Localization for Indoor IoT Networks Under Rayleigh Fading Conditions

Ankur Pandey, Piyush Tiwary, Sudhir Kumar, Sajal K. Das

2020IEEE Internet of Things Journal19 citationsDOI

Abstract

Location estimation in an indoor Internet-of-Things (IoT) environment is a challenging task due to multipath signals and obstacles that cause shadowing and fading effects, and change the received signal power considerably. Most of the existing path-loss-based localization methods assume only a lognormal shadowing model and ignore small scale fading effects. This article considers a generic combined lognormal shadowing and Rayleigh fading model for efficient localization of smart devices in an indoor IoT environment. In particular, the maximum likelihood estimate of the location and path-loss exponent (PLE), and Cramer-Rao lower bound (CRLB) are derived. The localization parameters are estimated using a novel adaptive mini-batch gradient ascent method that maximizes the log-likelihood function with an appropriate batch size based on the convergence factor. Hence, the proposed method addresses the challenge of an arbitrary selection of a fixed batch size for a gradient ascent method by utilizing this convergence factor. Performance evaluation by a simulation study and real experiments from an indoor IoT testbed provide a more accurate joint estimation of model parameters and smart device localization.

Topics & Concepts

FadingComputer scienceRayleigh fadingMultipath propagationPath lossConvergence (economics)AlgorithmWirelessTelecommunicationsEconomic growthEconomicsDecoding methodsChannel (broadcasting)Indoor and Outdoor Localization TechnologiesUnderwater Vehicles and Communication SystemsSpeech and Audio Processing