• Journal of the Korean Society of Fisheries and Ocean Technology
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• v.14 no.1
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• pp.15-36
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• 1978

Underwater sounds of some fishes and crabs were analyzed in the laboratory. The behavioral responses to the playback sounds of their feeding and croaking sound were investigated. The samples used in the experiment were as follows: Nibea albiflora, seriola quinqueradiata, Navodon modestus, Fugu xanthopterus, chrysophrys major, Scylla serrata, Telmessus acutidens, Charybdis japonica, and Portunus trituberculatus. The feeding and croaking sounds of the samples were recorded by a tape recorder through a hydrophone in an anechoic aquarium. The sound intensity level was measured by means of a sound level meter at an anechoic chamber. The frequency, intensity and wave form of various sounds were analyzed with an analyzing system consisting of a 1/3 octave filter set, a high speed level recorder, an amplifier, an octave band analyzer and an oscilloscope. The most successful recording was edited into a sequence of sound track which repeats sound emitting for 5 to 7 seconds after pausing for 5 to 7 seconds. The sequence was then reproduced into an anechoic aquarium through the under water speaker. The experimental anechoic aquarium used for the sample fishes was divided into the four sections with any three screens selected from 40$\times$40mm, 60$\times$60mm, 80$\times$80mm and 100$\times$100mm mushes according to the species of the fishes, besides that for crabs were not sectioned. The results of the investigation are as follows: 1. Of the feeding sound of fish, the frequency of wave from of the sound produced by Nibea albiflora and seriola quinqucradiata was 125～250Hz, that by Navodon modestus 63～125Hz, and that by Fugu xanthopterus 400～500Hz. The pressure level of the feeding sound produced by Nibea albiflora and Seriola quinqueradiata was 56～62db, that by Navodon modestus 57～59db, and that by Fugu xanthopterus 60～64db. 2. Of the croaking sound of Nibea albiflora, the frequency of the sound was 125～250Hz almost equivalent to that of feeding sound, and the pressure level was 62～63db, slightly higher than that of feeding sound. 3. Of the croaking sounds of crabs, the frequency of the sound produced by scylla serrata was 125～250Hz, that by Charybdis japonica and Telmessus acutidens 500～1,000Hz, and that by Portunus trituberculatus 250～500Hz. The pressure level of the croaking sound by Scylla serrata was 68～70db, and that by Charybdis japonica, Telmessus acutidens and Portuens trituberculatus 50～62db. 4. Phonotactic responses of Nibea albiflora and Seriola quinqueradiata to the feeding sounds produced by their own species, the same body length were conspicuous with the phonotactic index of 56～87%, but that of Navodon modestus, Chrysophrys major and Fugu xanthopterus were hardly recognized. 5. Phonotactic responses of the sample fishes to the sinusoidal sound with the frequency range of 50 to 9,000 Hz were observed not conspicuous. 6. Phonotactic responses of Portunus trituberculatus to the croaking sounds produced by their own species was varied in the range of 40～100%, according to the carapace length and the sex.

• The Journal of the Acoustical Society of Korea
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• v.32 no.1
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• pp.32-42
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• 2013

Typical underwater piezoelectric spherical sensors are omni-directional, thus can measure the scalar quantity sound-pressure-magnitude only with the limitation not being able to measure the direction of the incoming wave. This paper proposes a method to simultaneously measure both the magnitude and direction of the sound wave with the spherical sensor. The method divides the piezoceramic sphere of the sensor into eight elements, and distinguishes the magnitude and direction of the sound pressure by combining the output voltage of the elements in a particular manner. Further, through the analysis of the sensitivity variation in relation to the structural parameters like radius and thickness of the piezoceramic sphere, we have suggested the way to improve the sensitivity of the vector sensor.

• The Journal of the Acoustical Society of Korea
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• v.36 no.6
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• pp.419-424
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• 2017

TDoA (Time Difference-of Arrival) or DoA (Direction-of-Arrival) can be used for source localization. However, the localizing performance is dependent on relative position between source and receivers, receivers' geometric structure, sound speed, and so on. In this paper we propose a source localization method with enhanced performance that combines multiple information. The proposed method uses the time TDoA, DoA and sound speed as variables. LM (Levenberg-Marquardt) method which is one of nonlinear optimizations is applied. The performances of the proposed method was evaluated by simulation. As result of simulation, the proposed method has the lower average localizing error performance than the previous method.

• The Journal of the Acoustical Society of Korea
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• v.38 no.6
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• pp.621-629
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• 2019

A logical measure is suggested to estimate an accurate Sound Speed Profile (SSP) for the unusual variation of salinity in the Yellow Sea. Based on National Aeronautics and Space Administration (NASA)'s Aqua and Soil Moisture Active Passive (SMAP) satellite data, this measure identifies the area of temperature inversion effect and expansion of low salinity (<30.5 psu) water. Subsequently, on the area, the Conductivity, Temperature, and Depth (CTD) mounted unmanned maritime system estimates accurate SSP. In order to carry out this measure conveniently, a flow chart is demonstrated in this research. By using this measure which finds the high variational salinity area, the inaccuracy issue for calculating SSP from Expandable Bathy Thermograph (XBT) is expected to be solved.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.10 no.4
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• pp.227-235
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• 1977

The noise pressure scattered underwater on account of the engine revolution of a pole and liner, Kwan-Ak-San(G. T. 234.96), was measured at the locations of Lat. $34^{\circ}47'N$, Long. $128^{\circ}53'E$ on the 16th of August 1976 and Lat. $34^{\circ}27'N$, Long. $128^{\circ}23'E$ on the 28th of July, 1977. The noise pressure passed through each observation point (Nos. 1 to 5), which was established at every 10m distance at circumference of outside hull was recorded when the vessel was cruising and drifted. In case of drifting, the revolution of engine was fixed at 600 r. p. m. and the noise was recorded at every 10 m distance apart from observation point No. 3 in both horizontal and vertical directions with $90^{\circ}$ toward the stern-bow line. In case of cruising, the engine was kept in a full speed at 700 r.p.m. and the sounds passed through underwater in 1 m depth were also recorded while the vessel moved back and forth. The noise pressure was analyzed with sound level meter (Bruel & Kjar 2205, measuring range 37-140 dB) at the anechoic chamber in the Institute of Marine Science, National Fisheries University of Busan. The frequency and sound waves of the noise were analyzed in the Laboratory of Navigation Instrument. From the results, the noise pressure was closely related to the engine revolution shelving that the noise pressure marked 100 dB when .400 r. p. m. and increase of 100 r. p. m. resulted in 1 dB increase in noise pressure and the maximum appeared at 600 r. p. m. (Fig.5). When the engine revolution was fixed at 700 r. p. m., the noise pressures passed through each observation point (Nos. 1 to 5) placed at circumference of out side hull were 75,78,76,74 and 68 dB, the highest at No.2, in case of keeping under way while 75,76,77,70 and 67 dB, the highest at No.3 in case of drifting respectively (Fig.5). When the vessel plyed 1,400 m distance at 700 r.p.m., the noise pressure were 67 dB at the point 0 m, 64 dB at 600m and 56 dB at 1,400m on forward while 72 at 0 m, 66 at 600 m and 57 dB at 1,400 m on backward respectively indicating the Doppler effects 5 dB at 0 m and 3 dB at 200 m(Fig.6). The noise pressures passed through the points apart 1,10,20,30,40 and 50 m depth underwater from the observation point No.7 (horizontal distance 20 m from the point No.3) were 68,75,62,59,55 and 51 dB respectively as the vessel was being drifted maintaining the engine revolution at 600 r. p. m. (Fig. 8-B) whereas the noise pressures at the observation points Nos.6,7,8,9 and 10 of 10 m depth underwater were 64,75,55,58,58 and 52 dB respectively(Fig.8-A).

• Proceedings of the Acoustical Society of Korea Conference
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• autumn
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• pp.293-298
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• 1999

본 논문은 수중음의 안정적 실시간 인식을 위한 새로운 음원 인식 알고리즘을 다루고 있다 본 논문에서 이용된 주파수인식 알고리즘은 크게 네 부분으로 구성되어 있는데 1)입력된 음파 신호를 duty cycle $50\%$의 디지털 신호로 바꾸고 기준 주파수의 음원을 duty cycle $50\%$, 위상차 0도 90도 180도 270도의 디지털 신호를 생성하는 부분, 2)입력된 음파신호를 4가지 위상의 각 기준신호와 배타적 논리합을 구하는 부분, 3)두 번째에서 만들어진 각 신호를 적분회로에 통과시키는 부분, 4)세 번째에서 발생한 각 신호중 최대값을 추출하여 입력된 음파신호의 주파수를 인식하는 부분으로 이루어져 있다. 이 회로에 대한 수치 해석을 통하여 각 부분의 특성치에 대한 최적 값 및 성능을 검증하였으며, 이의 결과를 각각 computer 수치 시험, 실제 회로 실험과 비교하였다.

• Proceedings of the Acoustical Society of Korea Conference
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• spring
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• pp.199-202
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• 2004

해양에서 연구목적으로 저주파 음원으로 사용하고 있는 폭발성 음원(SUS: Signals, Underwater Sound)의 신호특성을 파악하기 위해 1999년 9월에 동해의 대륙사면에서 1마일에서 80 마일까지 약 1에서 5마일의 정해진 간격으로 SUS를 투하하여 발생된 음향신호를 거리 및 수신수심별로 수신하였다. 주파수 필터를 사용하여 분석한 결과, 1 kHz이상의 고주파수 성분이 폭발시에 먼저 방출되며 저주파수 신호는 뒤이어 발생됨을 확인하였다. 이것은 폭약이 폭발시에 일어나는 메카니즘과 관련이 있는 것으로 사료된다. 거리의 증가에 따라 잔향의 영향을 받아 뒤이어 수신되는 파속(wave packet)들을 확인할 수 있었으며, 신호에 많은 영향을 주고 있었으나 잔향 분석은 여기서는 제외하였다. 본 연구는 실해역에서의 SUS신호에 관한 많은 자료를 분석한 것으로서 그 신호특성에 관한 이번 고찰은 해양음파전달시 사용하는 SUS 음향신호 해석에 많은 도움을 줄 것으로 기대한다.

• Proceedings of the Acoustical Society of Korea Conference
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• autumn
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• pp.405-406
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• 2004

지금까지 해양과 해양에서 음향현상의 가시화는 정적이고 평면적이어서 시,공간적으로 끊임없이 변화하고 있는 현상을 이해하는데 어려움이 있었다. 최근에 가상현실에 대한 많은 관심과 연구로 과학적 가시화 기술은 많은 발전을 가져와 그 적용역역을 점차로 넓혀가고 있다. 이에 지금까지 평면적이고 정적이었던 수중에서의 음향현상도 이를 이용하여 구체적이고, 공간적이고 동적인 표출이 가능하게 되었다. 이러한 접근으로 눈에 보이지 않는 바닷속과 그 안에서의 음향현상을 마치 우리가 살고 있는 실제 공간처럼 3 차원적으로 표현 함으로서 해양에서 일어나는 음향현상에 대한 연구/분석의 현실성을 높일 수 있게 되었다. 3 차원 개체로서 입체화 된 음파전달 현상의 가시화로부터 또다른 정보를 얻을 수 있는 가능성에 대해서 검토해 보고자 한다.

• Journal of the Korean Society of Fisheries and Ocean Technology
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• v.22 no.4
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• pp.98-103
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• 1986

The passive acoustic system only has generally used in fish detection. But the passive acoustic system has not been tried in fishing since Freytag has proposed a possibilities of the passive detection of fishes in 1963. This paper describes the .feasible aspects of fish detection by listening of the sound they make. The passive acoustic system accompanied the active acoustic system may expand the range of detection and compensate for lack of capabilities each other, but there are some difficulties in noise rejection because the fre9uency range of ship noises covers the whole range vf biological sounds. The attempt to collect useful informations from underwater would be greatly contributed in fisheries.

• Proceedings of the Korean Society for Noise and Vibration Engineering Conference
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• 2001.05a
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• pp.342-349
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• 2001

Water tunnel에서 반향음의 영향을 효과적으로 배제하고 수중 소음원의 위치 및 소음 수준을 계측하기 위하여 하이드로폰 어레이 시스템을 개발하였다. 계측 시스템의 신호 대 잡음비를 개선하기위해 48채널의 하이드로폰 어레이를 사용하였고, 당사 고유의 하이드로폰 설치 방법을 개발하였다. 개발된 설치 방법은 터널 벽면의 난류 변동 압력의 영향을 감소시켜 200Hz-1KHz 영역에서 통상적이 설치 방법 대비 약 20㏈ 의 신호 대 잡음비 개선 효과를 얻었다. 또한 40KHz 이상의 주파수까지의 수중 방사 소음 계측을 위하여 100kS/s의 고속 동시 데이터 획득 장치를 개발하였다. 개발된 하이드로폰 어레이 시스템은 성능 시험을 통하여 20KHz 이내의 주파수 영역에서 단일 소음원의 위치를 비교적 정확하게 찾아낼 수 있었다.