Underwater Acoustic Propagation using Monterey-Miami Parabolic Equation in Shallow Water Kayeli Bay Buru Distric

Rayi Khasanah Lalita; Henry M Manik; Irsan S Brojonegoro

doi:10.30871/jagi.v7i2.2802

Rayi Khasanah Lalita Graduate School of Marine Technology Faculty of Fisheries and Marine Sciences IPB University
Henry M Manik Department of Marine Science and Technology, Faculty of Fisheries and Marine Sciences, IPB University
Irsan S Brojonegoro Ocean Engineering Department, Bandung Institute of Technology, Jl. Ganesha 10 Bandung

DOI: https://doi.org/10.30871/jagi.v7i2.2802

Keywords: Acoustics propagation, shallow water, ray tracing, sediment, frequency

Abstract

Indonesia's geographical position is an advantage compared to other countries, both in terms of geoeconomics, geopolitics and geostrategy. For this reason, it is necessary to develop and use acoustic methods to describe underwater features, carry out underwater communications or to measure oceanographic variables at sea. This research was intended to provide an analytical and visual graphical description with the aim that it can be used for various purposes both in the research, military and other marine fields, as well as to analyze the influence of sediment and different frequencies on acoustic propagation patterns in shallow waters of Kayeli Bay. This research was conducted using CTD data from Kayeli Bay, which is a body of water in Buru Regency, Maluku Province and is located between 3° 15' 55'' – 3° 22' 50" S and 127° 01'35" – 127° 01' 35 "E, using the Monterey-Miami parabolic equation method using 4 types of sediment and 3 different frequencies as model input. From the results of this research it can be concluded that the propagation of sound waves in shallow seas is greatly influenced by the type of sediment and frequenty used. Changes in acoustic impedance at the bottom of the water and within the water column can significantly influence the behavior of acoustic waves in shallow water environments, and accurate acoustic impedance data are critical for effective ray tracing modelling.

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References

Carey William M. Doutt James, Evans Richard, Dillman Lynne. 2003. Shallow-Water Sound Transmission Measurements Taken On The New Jersey Continental Shelf. SACLANTCEN CP-42

Etter P.C. 2003. Underwater Acoustic Modelling and Simulation. London. CRC Press

Ha Yonghoon. 2000. Java-based implementation of Monterey-Miami Parabolic Equation (MMPE) model with enhanced visualization and improved method of environmental definition. (thesis).

Liu Dai, Li Zhenglin, Wang Guangxu, Liu Yunfeng. 2021. Sound Propagation with Undulating Bottom in Shallow Water. Journal Of Marine Science And Engineering Volume 9(9).

Marsetio. 2014. Sea Power Indonesia. Universitas Pertahanan.

Manik H.M. 2016. Acoustical Measurement and Biot Model for Coral Reef Detection and Quantification. Advance in Acoustics and Vibration 2016(17), 1-11

Manik H.M, & Apdillah Dony. 2020. Remote Sensing of Seagrass and Seabed using Acoustic Technology in Bintan Seawater, Indonesia. Pertanika Journal of Sciense & Technology. Vol 28(2), 421-439

Peter L. Nielsen, Finn B. Jensen. 2004. Prediction of low-frequency acoustic propagation in shallow water.

Ramdhani Haqqu. 2014. Deteksi Dan Karakterisasi Akustik Sedimen Dasar Laut Dengan Teknologi Seismik Dangkal Di Bangka Belitung. (thesis)

Smith, Kevin B. 2001. Shallow Water Acoustic Predictions Using A Split-Step Fourier Parabolic Equation Model. Journal of Computational Acoustics, Vol. 9(1), 243–285 @ IMACS

Sukmono, S. (2000). Seismic Inversion for Reservoir Characterization. Dept. of Geophysical Engineering. ITB.