Research has been conducted on acoustic metamaterials that control the transmission characteristics of reflected and refracted waves using phase delay by resonators. Using one-dimensional theory, the phase delay equations for the 1/4 wavelength and Helmholtz resonator are presented. These one-dimensional analysis results are compared with the results predicted by three-dimensional FEM. The advantages and disadvantages of 1/4 wavelength and Helmholtz resonator were confirmed in implementing phase delay. An acoustic metamaterial with a refraction angle of 30° was manufactured using multiple tubes and then the sound pressure distribution was measured. A relatively large sound pressure was measured at the target position of 30°, which was compared with the 3D FEM analysis results. Simulations confirmed that a phase delay range closer to 2π was more effective in refraction, but varying the number of resonators was found to have minimal impact on which additional research is needed for generalization.

본 연구의 목적은 생물음향탐지기법을 적용해 국내에서 국지적인 위치에 서식하는 참깽깽매미의 번식울음을 분석하여 서식지 분포를 확인하고 영향 요인을 분석하는데 목적이 있다. 연구대상지는 전국 보호지역 20개소를 선정하였다. 번식울음 분석기간은 2017년부터 2021년까지 4년(2020년 제외)이었다. 번식울음 녹음은 각 연구대상지에 생물음향 녹음장비를 설치하여 시간당 1분씩 365일 수집하였다. 기후 데이터는 온도, 습도, 강수량, 전운량, 일조량 등 기상청에서 데이터를 제공받아 분석하였다. 연구 결과, 참깽깽매미 서식처는 연구대상지 20개소 중 강원도 고지대 4개 국립공원(설악 산, 오대산, 치악산, 태백산)에서만 확인되었다. 4년간 참깽깽매미 번식울음 시기는 8월 5일에서 9월 28일 사이였고, 번식울음 기간은 31~52일이었다. 참깽깽매미 출현시기 내 온도 분석 결과, 참깽깽매미는 최저 13.1°C, 최고 35.3°C 사이의 온도에서 주로 번식울음을 내었고, 번식울음 일주기 시간대(09~16시)의 평균기온은 24.4~24.9°C로 나타났다. 참깽깽매미가 출현한 연구대상지 4개소의 2019년 번식울음 일주기를 분석한 결과, 참깽깽매미는 06~16시까지 번식울음 을 내었고 11~12시경 피크를 보였다. 참깽깽매미의 출현기간 내 참매미, 애매미, 유지매미, 늦털매미 4종이 공통 출현하였다. 로지스틱 회귀분석 결과, 참깽깽매미의 번식울음에 영향을 끼치는 환경요인은 일조량으로 나타났다. 종간영향에 있어서 다른 공통출현종 4종(참매미, 애매미, 유지매미, 늦털매미)과 종간영향을 주고 받았음을 확인하였다. 이상의 내용을 종합하였을 때, 참깽깽매미는 우리나라에서 강원도 고지대를 중심으로 한정적으로 서식하며 다른 종과 비교하여 낮은 온도에서 번식울음을 내고 있는 것으로 나타났다. 본 결과는 향후 참깽깽매미 연구를 위한 기초자료로 활용이 가능하다.

In this study, the target strength for multi-frequency (38 kHz, 120 kHz, 200 kHz) of juvenile silverfish (Pleuragramma antarcticum) was estimated using by the KRM (Kirchhoff-ray mode) model. The body shape of the silverfish was described by a picture and the body length of nine individuals ranged in 1.8 cm to 8.8 cm. The maximum TScm according to the total length for the constant term (b20) was – 92.93 dB at 38 kHz, – 86.63 dB at 120 kHz, and – 85.89 dB at 200 kHz, respectively. The averaged TScm according to total length for the constant term (b20) was – 100.0 dB at 38 kHz, – 93.0 dB at 120 kHz, and – 106.9 dB at 200 kHz, respectively.

In this study, Target strength for multi-frequency (38 kHz, 70 kHz, 120 kHz and 200 kHz) of chub mackerel (Scomber japonicus) was estimated using by the KRM model. The body shape of the Chub mackerel was described by an X-ray system and the body length of 20 individuals ranged from 16 cm to 28 cm. The swimbladder tilt angle ranged between – 8 and – 14°, the maximum TS value according to the swimming angle of chub mackerel was – 33.0 dB at – 11°. The averaged TScm according to fork length was – 66.02 dB at 38 kHz, – 66.50 dB at 70 kHz, – 66.00 dB at 120 kHz and – 67.35 dB at 200kHz, respectively.

본 연구는 국내 매미아과를 대상으로 번식울음 시기를 전국적으로 관측하여 종별 출현 시기 및 서식지 분포 특성을 밝히는데 그 목적이 있다. 연구대상지는 전국 보호지역 19개소이었다. 매미 번식울음 수집기간은 2019년 12개월간이었다. 매미 번식울음 녹음은 매시간당 1분씩 WAV, 44,100Hz 포맷으로 생물음향 측정장비를 설치하여 녹음하였다. 온도는 미기상 측정장비를 이용하여 시간당 1~2회씩 기록하였다. 연구대상종은 국내 매미아과 9종이었다. 번식울음 분석은 매미종별 번식울음 시종점을 기록하였다. 분석 결과, 연구대상지 19개소에서 출현한 매미는 9종이었다. 종별 번식울음 시기는 말매미(7/12~9/30), 애매미(7/27~10/20), 참매미(7/25~10/9), 유지매미(7/28~9/5), 털매미(7/3~9/29), 늦털매미(9/14~10/30), 소요산매미(6/26~8/2), 참깽깽매미(7/27~9/28), 쓰름매미(8/8~9/11) 순이었다. 종별 번식울음 기간은 35일(쓰름매미)~89일 (털매미) 사이었고 평균 62일이었다. 종별 서식지 해발고도는 말매미(5~386m), 애매미(7~759m), 참매미(7~967m), 유지매 미(42~700m), 털매미(7~700m), 늦털매미(5~759m), 소요산매미(7~759m), 참깽깽매미(397~967m), 쓰름매미(7~42m) 순이었다. 종별 서식지 평균온도는 말매미(23.9℃), 애매미(21.8℃), 참매미(22℃), 유지매미(23℃), 털매미(22.9℃), 늦털매미 (14.6℃), 소요산매미(20.6℃), 참깽깽매미(19.3℃), 쓰름매미(24.4℃) 순이었다. 종별 서식지 분포는 애매미, 참매미, 털매미 는 전국 15개소 이상 분포하였다. 말매미는 서남부 저지대에 분포하였다. 유지매미는 한반도 서부 지역에 분포하였다. 늦털매미는 고산지대와 동남부 일부를 제외한 지역에 분포하였다. 소요산매미는 산지에 가까운 지역에 분포하였다. 참깽깽매미는 고산지대에 국지적으로 분포하였다. 쓰름매미는 평지형 습지에 국지적으로 분포하였다.

Most of speakers, the con-paper (con shape) or vibration plate generate the sound by reciprocating motion which is received vibrating signal from voice coil. On the other hand, the vibration speaker that reproduces sound by attaching a vibration head to some materials such as wood, plastic, glass plate, etc. instead of cone paper or vibration plate generates different sound timbres depending on the attached materials with vibration head. so we can hear a variety of timbres than ordinary speakers. In this study, the characteristics of vibration and sound propagation according to various materials attached to the vibration head of the vibration speaker were experimentally investigated and this sound propagation characteristics were compare with woofer speaker and micro speaker. As a result of sound propagation characteristics of vibration speaker, the reproduction ability of low frequency band wes inferior to compared than woofer speaker and micro speaker. This is judged to be due to the material characteristics of glass and wood which are source of the sound propagation. As compare with 1kHz sine tone, the woofer speaker has not generated the high order harmonic component, but the glass plate and wood plate used with the vibration speaker head have generated the high order harmonic component at a level that can not be ignored. According to above results, the vibration speaker will be had a low articulation of sound because the higher volume to generate the high distortion.

In order to collect basic information of response behavior of red seabream (Pagrus major) during pilling, works for constructing wind power station in Byeonsan Peninsular, Korea were investigated. Four cultured red seabream CRB1 to CRB4 [total length (TL): 27.1 ± 1.0 cm; body weight: 359 ± 30 g] were tagged with an acoustic tag and used in experiment. CRB1 and CRB2 to CBR4 were released on the sea surface at same time around the constructing site of the wind power plant on September 22, 2017 and July 18, 2018, respectively. The tracking of the CRB1 to CRB2 and CRB3 to CRB4 were conducted for two hours, approximately, using VR100 receiver including a directional hydrophone and VR2W receivers array consisted of 19 presence/absence receivers (VR2W receivers), respectively. The underwater noise level before (no pile driving works) and during pile driving works was measured 116.0-118.0 dB (re 1Pa) and a maximum of 160 dB (re 1Pa), respectively. CRB1 moved about 6.0 km with average swimming speed of 80.2 ± 20.5 cm/s for 2.1 hours without pile driving work. The average water depth of the sea bed on the route of CRB1 was 9.1 ± 0.4 m. CRB2 moved about 7.3 km with the average swimming speed of 96.8 ± 27.1 cm/s for 2.1 hours with pile driving work. The water depth of the sea bed on the route of CRB2 was 11.9 ± 0.6 m. At results of the Rayleigh’s z-test two fishes CRB1 and CRB2 showed significant directionality in the movement (p < 0.01). Movement mean angles of CRB1 and CRB2 were 92.7 and 251.8°, respectively. CRB2, CRB3 and CRB4 exhibited the escaping behavioral response from the noise of source during the pile driving work. The swimming speed of the CRB2 exposed on the heavy underwater noise stimuli due to the pile driving work was 1.21 times faster than that of the CRB1 exposed on the ambient underwater

본 연구는 생물음향 녹음기술을 이용하여 야행성 조류의 울음을 탐지하여 종을 식별하고, 종별 생태적 특성을 분석하는데 목적이 있다. 연구대상지는 설악산국립공원, 국립생태원, 무등산국립공원 3개소였다. 분석기간은 설악산은 2018년 4월 중순부 터 2019년 3월 초, 국립생태원은 2018년 2월 말부터 2019년 2월 중순, 무등산은 2018년 2월 중순부터 8월 말까지였다. 주요 연구결과는 다음과 같다. 첫 번째, 탐지가 확인된 야생조류 종 수는 쏙독새, 소쩍새, 호랑지빠귀, 수리부엉이, 긴점박이올 빼미로 총 5종이다. 두 번째, 종별 번식울음 기간은 쏙독새는 5월 초부터 8월 초, 소쩍새는 4월 초부터 9월 말, 호랑지빠귀는 3월 초부터 10월 초, 수리부엉이는 9월 말부터 2월 초, 긴점박이올빼미는 1월 중순부터 3월 초까지였다. 세 번째, 종별 번식울음 일주기는 세 지역의 관찰대상종 모두 16시부터 다음 날 10시 사이로 형성이 됐고, 빈도가 높게 나타나는 시간대는 20시부터 다음 날 06시 사이에 형성되었다. 네 번째, 종별 일 누적 울음빈도와 강수량은 상관관계를 나타내지 않았다. 다섯 번째, 종별 울음이 탐지된 기간 동안의 평균기온은 긴점박이올빼미는 -4.00℃, 수리부엉이는 2.58℃, 호랑지빠귀는 13.66℃, 소쩍새는 19.50℃, 쏙독새는 20.77℃였고, 분산분석 결과 종별 울음이 평균기온에서 차이가 있는 것으로 나타났다. 그 결과, 긴점박이올빼미, 수리부엉이, 호랑지빠귀, 소쩍새-쏙독새 4개의 그룹 순으로 낮은 온도에서 나타났다. 연구를 통해 확인된 종별 번식울음 기간은 종별 울음이 탐지된 기간 중 울음빈도가 높게 나타난 기간이다. 이는 종마다 알려진 번식기간에 속하는 결과이기 때문에 생물음향 모니터링 기법을 이용하여 울음기간을 확인했을 때 울음빈도가 높게 형성되는 기간을 번식기간으로 볼 수 있음을 확인했다. 본 연구는 한국의 야행성 조류를 대상으로 생물음향 녹음기술을 이용하여 종을 식별하고, 종별 생태적 특성을 밝힌 초기 논문이라는 점에서 의미가 있다.

Acoustic surveys were conducted in the seas surround the South Korea (South Sea A, South Sea B (waters around the Jeju Island), West Sea and East Sea) in spring and autumn in 2016. First, the vertical and horizontal distributions of fisheries resources animals were examined. In most cases vertical acoustic biomass was high in surface water and mid-water layers other than South Sea A in autumn and West Sea. The highest vertical acoustic biomass showed at the depth of 70-80 m in the South Sea A in spring (274.4 m2/nmi2) and the lowest one was 10-20 m in the West Sea in autumn (0.4 m2/nmi2). With regard to the horizontal distributions of fisheries resources animals, in the South Sea A, the acoustic biomass was high in eastern and central part of the South Sea and the northeast of Jeju Island (505.4-4099.1 m2/nmi2) in spring while it was high in eastern South Sea and the coastal water of Yeosu in autumn (1046.9-2958.3 m2/nmi2). In the South Sea B, the acoustic biomass was occurred high in the southern and western seas of Jeju Island in spring (201.0-1444.9 m2/nmi2) and in the southern of Jeju Island in autumn (203.7-1440.9 m2/nmi2). On the other hand, the West Sea showed very low acoustic biomass in spring (average NASC of 1.1 m2/nmi2), yet high acoustic biomass in the vicinity of 37 N in autumn (562.6-3764.2 m2/nmi2). The East Sea had high acoustic biomass in the coastal seas of Busan, Ulsan and Pohang in spring (258.7~976.4 m2/nmi2) and of Goseong, Gangneung, Donghae, Pohang and Busan in autumn (267.3-1196.3 m2/nmi2). During survey periods, fish schools were observed only in the South Sea A and the East Sea in spring and the West Sea in autumn. Fish schools in the South Sea A in spring were small size (333.2 ± 763.2 m2) but had a strong SV (–49.5 ± 5.3 dB). In the East Sea, fish schools in spring had low SV (–60.5 ± 14.5 dB) yet had large sizes (537.9 ± 1111.5 m2) and were distributed in the deep water depth (83.5 ± 33.5 m). Fish schools in the West Sea in autumn had strong SV (–49.6 ± 7.4 dB) and large sizes (507.1 ± 941.8 m2). It was the first time for three seas surrounded South Korea to be conducted by acoustic surveys to understand the distribution and aggregation characteristics of fisheries resources animals. The results of this study would be beneficially used for planning a future survey combined acoustic method and mid-water trawling, particularly deciding a survey location, a time period, and a targeting water depth.