A survey on node localization technologies in UWSNs: Potential solutions, recent advancements, and future directions

Summary Location‐based underwater communication applications such as strategic surveillance, disaster prevention, marine research, and mine detection have given the field of underwater wireless sensor networks (UWSN) a head start. Node localization is a prerequisite for accurate data collection, tar...

Full description

Saved in:
Bibliographic Details
Published in:International journal of communication systems 2024-11, Vol.37 (16), p.n/a
Main Authors: Nain, Mamta, Goyal, Nitin, Dhurandher, Sanjay Kumar, Dave, Mayank, Verma, Anil Kumar, Malik, Amita
Format: Article
Language:English
Subjects:
Accuracy
Acoustic attenuation
Acoustic propagation
Acoustic properties
Algorithms
autonomous underwater vehicle
Data collection
Energy consumption
Localization
Marine technology
Mine detection
Nodes
Optimization techniques
routing
sensor network
Signal strength
Underwater communication
UWSN
Wireless sensor networks
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Summary Location‐based underwater communication applications such as strategic surveillance, disaster prevention, marine research, and mine detection have given the field of underwater wireless sensor networks (UWSN) a head start. Node localization is a prerequisite for accurate data collection, target monitoring, and network management in UWSNs. However, the unique characteristics of the underwater environment, such as signal attenuation, multipath propagation, and variable acoustic properties, pose a major challenge to effective node localization. Accurate sensor node location data is essential for successful underwater data collection, but difficult to achieve as the GPS system cannot be used in an underwater environment. In this paper, existing node localization techniques such as ALS, SLUM, MASL, SLMP, UDB, USP, etc., and recent advances such as the fusion of range‐based and range‐free techniques, the fusion of RSSI and AoA to improve localization accuracy by using directional information in addition to signal strength, and the use of optimization techniques such as PSO, COA, and WOA algorithms to improve the accuracy of the applied node localization algorithm, e.g., TP‐TSFLA, and challenges related to UWSN are discussed. Also, different localization algorithms that affect the accuracy of UWSN localization techniques have been evaluated and compared with NS2 in terms of localization error, localization coverage, energy consumption, and average communication cost metrics. In addition, this paper also provides an up‐to‐date investigation of localization techniques. Finally, the tools available for simulation are presented, followed by open research questions that need to be addressed in the localization of nodes. A comparative and all‐inclusive study of different localization techniques is provided, along with details in the form of a table based on some parameters such as the state of the nodes, advantages, and disadvantages. Also, the influence of architecture arrangement on node localization is studied in detail to see how architecture influences localization techniques in UWSN. Numerous UWSN simulation tools were investigated and some of the node localization algorithms were compared and harmonized using the NS2 simulator. Challenges and applications in the field of UWSN are also recognized and addressed.
ISSN:1074-5351
1099-1131
DOI:10.1002/dac.5915