IDENTIFIKASI PROFIL DASAR LAUT MENGGUNAKAN INSTRUMEN SIDE SCAN SONAR DENGAN METODE BEAM PATTERN DISCRETE-EQUI-SPACED UNSHADED LINE ARRAY

Muhammad Zainuddin Lubis, Wenang Anurogo

Abstract


Laut Punggur merupakan laut yang terletak di Batam, Kepulauan Riau yang mempunyai beragam habitat objek,dan bentuk struktur bawah laut yang memiliki dinamika laut yang sangat tinggi. Side scan sonar (SSS) merupakan instrumen pengembangan sistem sonar yang mampu menunjukkan dalam gambar dua dimensional permukaan dasar laut dengan kondisi kontur, topografi, dan target secara bersamaan. Metode Beam Pattern Discrete-Equi-Spaced Unshaded Line Array digunakan untuk menghitung beam pattern dua dimensi yang tergantung pada sudut dari gelombang suara yang masuk dari sumbu array yang diterima tergantung pada sudut di mana sinar suara pada array. Penelitian ini dilakukan pada Desember 2016 di laut Punggur,Batam, Kepulauan Riau-Indonesia, dengan koordinat 104 ° 08,7102 E dan 1° 03,2448 N sampai 1 ° 03.3977 N dan 104 ° 08,8133 E, menggunakan instrumen Side Scan Sonar C-Max CM2 Tow fish dengan frekuensi 325 kHz. Hasil yang diperoleh dari perekaman terdapat 7 target, dan Beam pattern dari metode Beam Discrete-Equi-Spaced Unshaded Line Array target 4 memiliki nilai tertinggi pada directivity Pattern yaitu 21.08 dB. Hasil model beam pattern ini memiliki nilai pusat pada incidence angle (o) terhadap Directivity pattern (dB) tidak berada di nilai 0 ataupun pada pusat beam pattern yang dihasilkan pada target 6 dengan nilai incident angle -1.5 o dan 1.5o mengalami penurunan hingga -40 dB. Karakteristik sedimen dasar perairan di laut punggur ditemukan lebih banyak pasir. Hasil metode Beam Discrete-Equi-Spaced Unshaded Line Array ditemukan bangkai kapal tenggelam.

Kata Kunci: Side Scan Sonar, Beam Pattern Discrete-Equi-Spaced Unshaded Line Array, Incidence angle, Directivity pattern

 

IDENTIFICATION OF SEABED PROFILE USING SIDE SCAN SONAR INSTRUMENT WITH PATTERN DISCRETE-EQUI-SPACED UNSHADED LINE ARRAY METHOD

Riau Islands is an island that has a variety of habitat objects, and forms of submarine structures that have a very high ocean dynamics, Punggur Sea is the sea which was a sea of Riau Island in Indonesia. Side scan sonar (SSS) is an instrument based on sonar system wich capable of showing the image of two-dimensional surface of the seabed with contour conditions, topography, and the underwater target simultaneously. Beam Pattern Discrete-equispaced unshaded Line Array Method is used to compute the two-dimensional beam pattern which depends on the angle of the incoming sound waves from the axis of the array are acceptable depending on the angle at which the sound beam array. This research was conducted in December 2016 in the sea Punggur, Batam, Riau Islands-Indonesia, with coordinate system  104 ° 08,7102 E and 1° 03,2448 N until 1 ° 03.3977N and 104 ° 08,8133 E,  using Side Scan Sonar Tow C-Max CM2 fish instruments with a frequency of 325 kHz. The Results obtained from the recording there are 7 targets, and Beam pattern of Discrete-Beam method Equi-Spaced unshaded Line Array in targets 4 have the highest value in the Pattern is 21:08 dB directivity. The results of the model's beam pattern have anaxis value at the incidence angle (o) of the directivity pattern (dB) are not on the value 0 or the central beam pattern generated on the target 6 with incident angle -1.5 o and 1.5o have declined by -40 dB. Characteristics of bottom sediment in the sea waters Punggur found more sand.Discrete-method result Beam Equi-Spaced unshaded Line Array discovered the sunken wreck.


Keywords: Side Scan Sonar, Beam Pattern Discrete-Equi-Spaced Unshaded Line Array, Incidence angle, Directivity pattern


References


Bachtiar, I., Damar, A., & Zamani, N. P. (2012). Assessing Ecological Resilience of Indonesian Coral Reefs. Journal of Coastal Development, 14(3), 214-222.

Bartholomä, A. (2006). Acoustic bottom detection and seabed classification in the German Bight, southern North Sea. Geo-Marine Letters, 26(3), 177.

Jain, A. D., & Makris, N. C. (2016). Maximum Likelihood Deconvolution of Beamformed Images with Signal-Dependent Speckle Fluctuations from Gaussian Random Fields: With Application to Ocean Acoustic Waveguide Remote Sensing (OAWRS). Remote Sensing, 8(9), 694.

Kenny, A. J., Cato, I., Desprez, M., Fader, G., Schüttenhelm, R. T. E., & Side, J. (2003). An overview of seabed-mapping technologies in the context of marine habitat classification. ICES Journal of Marine Science: Journal du Conseil, 60(2), 411-418.

Lubis, M. Z., & Anurogo, W. (2016). Fish stock estimation in Sikka Regency Waters, Indonesia using Single Beam Echosounder (Cruz Pro fish finder PcFF-80) with hydroacoustic survey method. Aceh Journal of Animal Science, 1(2).

Lubis, M. Z., & Pujiyati, S. (2016). Detection Backscatter Value of Mangrove Crab (Scylla Sp.) Using Cruzpro Fishfinder Pcff-80 Hydroacoustic Instrument. J. Biosens. Bioelectron, 7(2), 2.

Lubis, M. Z., Wulandari, P. D., Mujahid, M., Hargreaves, J., & Pant, V. (2016). Echo Processing and Identifying Surface and Bottom Layer with Simrad Ek/Ey 500. Journal of Biosensors and Bioelectronics, 7(3), 1000212.

Lubis, M. Z., Anurogo, W., Khoirunnisa, H., Irawan, S., Gustin, O., & Roziqin, A. (2017). Using Side-Scan Sonar instrument to Characterize and map of seabed identification target in Punggur Sea of the Riau Islands, Indonesia. Journal of Geoscience, Engineering, Environment, and Technology, 2(1), 1-8.

Manik, H. M. (2011). Underwater acoustic detection and signal processing near the seabed. INTECH Open Access Publisher.

Manik, H.M. (2015). Underwater Remote Sensing of Fish and Seabed Using Acoustic Technology In Seribu Island Indonesia. International Journal of Oceans and Oceanography, 9, 77-95.

Minarto, E., Surbakti, H., Vorandra, E., Pin, T. G., Musli, M., & Saputra, E. (2008). Kaitan Aktivitas Vulkanik dengan Distribusi Sedimen dan Kandungan Suspensi di Perairan Selat Sunda. Jakarta (ID): Publikasi pelayaran kebangsaan P2O LIPI.

Pujiyati, S., Hestirianoto, T., Wulandari, P. D., & Lubis, M. Z. (2016). Fish Stock Estimation by Using the Hydroacoustic Survey Method in Sikka Regency Waters, Indonesia. J. Fisheries Livest Prod, 4(193), 2.

Simmonds, J., & MacLennan, D. N. (2008). Fisheries acoustics: theory and practice. John Wiley & Sons.

Hansen, R. E. (2011). Introduction to synthetic aperture sonar, in Sonar Systems. Edited by Nikolai Kolev. First Edition. InTech, Croatia. Hal. : 1-25.

Haykin, S. (1985). Array signal processing. Englewood Cliffs, NJ, Prentice-Hall, Inc., 1985, 493 p. For individual items see A85-43961 to A85-43963., 1.

Urick, R. J. (1983). Principles of underwater acoustics.




DOI: https://doi.org/10.21107/jk.v10i1.2563

Refbacks

  • There are currently no refbacks.


Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.




 INDEXED BY: