Energy-efficient collection scheme based on compressive sensing in underwater wireless sensor networks for environment monitoring over fading channels
References
[1]
Rodolfo W.L. Coutinho, et al., Underwater wireless sensor networks: a new challenge for topology control based systems, ACM Comput. Surv. 51 (1) (2018) 1–36.
[2]
Khalid Mahmood Awan, et al., Underwater wireless sensor networks: a review of recent issues and challenges, Wirel. Commun. Mob. Comput. 2019 (2019).
[3]
Salvador Climent, et al., Underwater acoustic wireless sensor networks: advances and future trends in physical, MAC and routing layers, Sensors 14 (1) (2014) 795–833.
[4]
Khandaker Foysal Haque, K. Habibul Kabir, Ahmed Abdelgawad, Advancement of routing protocols and applications of underwater wireless sensor network (UWSN): a survey, J. Sens. Actuator Netw. 9 (2) (2020) 19.
[5]
S. El-Rabaie, et al., Underwater wireless sensor networks (UWSN), architecture, routing protocols, simulation and modeling tools, localization, security issues and some novel trends, Netw. Commun. Eng. 7 (8) (2015) 335–354.
[6]
Tifenn Rault, Abdelmadjid Bouabdallah, Yacine Challal, Energy efficiency in wireless sensor networks: a top-down survey, Comput. Netw. 67 (2014) 104–122.
[7]
Naveed Ilyas, et al., AEDG: AUV-aided Efficient Data Gathering Routing Protocol for Underwater Wireless Sensor Networks, 2015, ANT/SEIT.
[8]
Muhammad Khalid, et al., E2MR: energy-efficient multipath routing protocol for underwater wireless sensor networks, IET Netw. 8 (2019) 321–328.
[9]
Xiaoxiao Zhuo, et al., AUV-aided energy-efficient data collection in underwater acoustic sensor networks, IEEE Int. Things J. 7 (10) (2020) 10010–10022.
[10]
Meihuang Wang, et al., Node energy consumption balanced multi-hop transmission for underwater acoustic sensor networks based on clustering algorithm, IEEE Access 8 (2020) 191231–191241.
[11]
Keyu Chen, et al., A survey on MAC protocols for underwater wireless sensor networks, IEEE Commun. Surv. Tutor. 16 (3) (2014) 1433–1447.
[12]
David L. Donoho, Compressed sensing, IEEE Trans. Inf. Theory 52 (4) (2006) 1289–1306.
[13]
Richard G. Baraniuk, Compressive sensing [lecture notes], IEEE Signal Process. Mag. 24 (4) (2007) 118–121.
[14]
Emmanuel J. Candes, Michael B. Wakin, An introduction to compressive sampling, IEEE Signal Process. Mag. 25 (2) (2008) 21–30.
[15]
Fatemeh Fazel, Maryam Fazel, Milica Stojanovic, Compressed sensing in random access networks with applications to underwater monitoring, Phys. Commun. 5 (2) (2012) 148–160.
[16]
Urbashi Mitra, et al., Structured sparse methods for active ocean observation systems with communication constraints, IEEE Commun. Mag. 53 (11) (2015) 88–96.
[17]
Fatemeh Fazel, Maryam Fazel, Milica Stojanovic, Random access compressed sensing for energy-efficient underwater sensor networks, IEEE J. Sel. Areas Commun. 29 (8) (2011) 1660–1670.
[18]
Huseyin Emre Erdem, Huseyin Ugur Yildiz, Vehbi Cagri Gungor, On the lifetime of compressive sensing based energy harvesting in underwater sensor networks, IEEE Sens. J. 19 (12) (2019) 4680–4687.
[19]
Rahul Mourya, et al., Ocean monitoring framework based on compressive sensing using acoustic sensor networks, in: OCEANS 2018 MTS/IEEE, IEEE, Charleston, 2018.
[20]
Xinbin Li, et al., Energy-efficient and secure transmission scheme based on chaotic compressive sensing in underwater wireless sensor networks, Digit. Signal Process. 81 (2018) 129–137.
[21]
Sadanand Yadav, Vinay Kumar, Hybrid compressive sensing enabled energy efficient transmission of multi-hop clustered UWSNs, AEÜ, Int. J. Electron. Commun. 110 (2019).
[22]
Hongzhi Lin, et al., Energy-efficient compressed data aggregation in underwater acoustic sensor networks, Wirel. Netw. 22 (6) (2016) 1985–1997.
[23]
Deqing Wang, et al., Energy-efficient distributed compressed sensing data aggregation for cluster-based underwater acoustic sensor networks, Int. J. Distrib. Sens. Netw. 12 (3) (2016).
[24]
Fei-Yun Wu, Yan-Chong Song, Kunde Yang, An effective framework for underwater acoustic data acquisition, Appl. Acoust. 182 (2021).
[25]
Erdal Panayirci, et al., Sparse channel estimation for OFDM-based underwater acoustic systems in Rician fading with a new OMP-MAP algorithm, IEEE Trans. Signal Process. 67 (6) (2019) 1550–1565.
[26]
Cecilia Carbonelli, et al., Error propagation analysis for underwater cooperative multi-hop communications, Ad Hoc Netw. 7 (2009) 759–769.
[27]
M. Schwartz, Mobile Wireless Communications, Cambridge University Press, Cambridge, 2005.
[28]
Joel A. Tropp, Anna C. Gilbert, Signal recovery from random measurements via orthogonal matching pursuit, IEEE Trans. Inf. Theory 53 (12) (2007) 4655–4666.
[29]
Thomas Blumensath, Mike E. Davies, Iterative hard thresholding for compressed sensing, Appl. Comput. Harmon. Anal. 27 (3) (2009) 265–274.
[30]
G. Hosein Mohimani, Massoud Babaie-Zadeh, Christian Jutten, Fast sparse representation based on smoothed l0 norm, in: International Conference on Independent Component Analysis and Signal Separation, Springer, Berlin, Heidelberg, 2007.
[31]
Fatemeh Fazel, Maryam Fazel, Milica Stojanovic, Random access compressed sensing over fading and noisy communication channels, IEEE Trans. Wirel. Commun. 12 (5) (2013) 2114–2125.
[32]
Muhammad Yousuf Irfan Zia, Javier Poncela, Pablo Otero, State-of-the-art underwater acoustic communication modems: classifications, analyses and design challenges, Wirel. Pers. Commun. 116 (2) (2021) 1325–1360.
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Published: 01 July 2022
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