Optimization-Oriented RAW Modeling of IEEE 802.11ah Heterogeneous Networks

The new medium access method of IEEE 802.11ah, called restricted access window (RAW), divides stations into different groups, and only allows stations in the same group to access the channel simultaneously, in order to reduce collisions and thus achieve better performance (e.g., throughput). However...

Full description

Saved in:
Bibliographic Details
Published in:IEEE internet of things journal 2019-12, Vol.6 (6), p.10597-10609
Main Authors: Tian, Le, Lopez-Aguilera, Elena, Garcia-Villegas, Eduard, Mehari, Michael Tetemke, De Poorter, Eli, Latre, Steven, Famaey, Jeroen
Format: Article
Language:English
Subjects:
Algorithms
Complex systems
Complexity
Computer simulation
Convergence
Data models
Data points
Heterogeneous networks
IEEE 802.11ah
Internet of Things
Load modeling
Mathematical model
Mathematical models
Networks
Optimization
Predictive models
restricted access window (RAW)
Stations
surrogate model
Throughput
Training
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The new medium access method of IEEE 802.11ah, called restricted access window (RAW), divides stations into different groups, and only allows stations in the same group to access the channel simultaneously, in order to reduce collisions and thus achieve better performance (e.g., throughput). However, the existing station grouping strategies only support homogeneous scenarios where all stations use the same modulation and coding scheme (MCS) and packet size. A surrogate model is an efficient mathematical model that represents the behavior of a complex system, trained with a limited set of labeled input-output data samples. In this article, we present a surrogate model that can accurately predict RAW performance under a given RAW configuration in heterogeneous networks. Different from the homogeneous scenario, heterogeneous networks are defined by a large number of parameters, leading to an enormous design space, i.e., the order of 10 17 possible data points. This is too big to achieve feasible training convergence. In this article, we present a novel training methodology that leads to a new design space with highly reduced size, i.e., the order of 10 5 data points. The surrogate model converges when less than 6000 labeled data points are used for training, which is only a tiny portion of the whole design space. The results show that, the relative error between model prediction and simulation results is less than 0.1 for 95% of the data points, in the areas of the design space studied. Its low complexity and high precision make the proposed model a valuable tool to develop real-time RAW optimization algorithms for heterogeneous IEEE 802.11ah networks.
ISSN:2327-4662
2327-4662
DOI:10.1109/JIOT.2019.2940251