利用闭腔和开腔亥姆霍兹谐振器估算水下鱼类体积

Q2 Engineering
Stephen N. Njane , Yoshiaki Shinohara , Naoshi Kondo , Yuichi Ogawa , Tetsuhito Suzuki , Takahisa Nishizu
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引用次数: 1

摘要

体积是决定水产品密度的一个重要参数。然而,由于这些产品在形状和大小上的膨胀变化,很难精确估计它们在水中的体积。在这项研究中,我们提出了一种称为亥姆霍兹共振的技术来估计水中鱼类的体积。为了做到这一点,设计了一个封闭腔谐振器,并将其用作水下原型,以展示鱼类体积测量的潜力。然而,这种封闭腔谐振器由于需要打开,插入鱼样品并关闭以进行测量而受阻。作为一种潜在的更可行的替代方案,一种开放腔谐振器被开发出来,它可以在不关闭或锁定腔的情况下测量鱼。此外,这有可能自动估计鱼的体积,鱼可以通过谐振器腔腔一侧的开口进行测量。与闭腔谐振器相似,随着取样鱼体积的增加,开腔谐振器中的谐振频率降低。模型鱼(硬骨鱼)前房的粘性鱼肉和弹性鱼鳔引起了共振频率的阻尼。利用经验方程,得到了一个精度为0.99的线性回归模型(r²)。水下开腔亥姆霍兹谐振器具有测量鱼类体积的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Underwater fish volume estimation using closed and open cavity Helmholtz resonators

Volume is an important parameter in determining the density of aquatic products. However, due to the distended variation in shape and size of these products, it is difficult to precisely estimate their volume in water. In this study, we proposed a technique known as Helmholtz resonance for estimating the volume of fish in water. In order to do this, a closed cavity resonator was designed and utilised as an underwater prototype to demonstrate the potential for fish volume measurement. However, such a closed cavity resonator is thwarted by the need to open, insert the fish samples and close for measurement to be done. As a potentially more viable alternative, an open cavity resonator, which would allow fish to be measured without the need to close or lock the cavity was developed. Furthermore, this has the potential for automatic fish volume estimation where fish can pass through such an opening on the side of the resonator's cavity for measurement. Similar to the closed cavity resonator, as the volume of sampled fish increased, resonance frequency decreased in the open cavity resonator. The damping of the resonance frequency was caused by the viscous fish flesh and the elastic swim bladder in the anterior chamber of the model fish, a teleostean fish. By use of empirical equations, a linear regression model (R-squared) with an accuracy of 0.99 in the open cavity resonator was obtained. An underwater open cavity Helmholtz resonator has the potential for fish volume measurement.

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来源期刊
Engineering in Agriculture, Environment and Food
Engineering in Agriculture, Environment and Food Engineering-Industrial and Manufacturing Engineering
CiteScore
1.00
自引率
0.00%
发文量
4
期刊介绍: Engineering in Agriculture, Environment and Food (EAEF) is devoted to the advancement and dissemination of scientific and technical knowledge concerning agricultural machinery, tillage, terramechanics, precision farming, agricultural instrumentation, sensors, bio-robotics, systems automation, processing of agricultural products and foods, quality evaluation and food safety, waste treatment and management, environmental control, energy utilization agricultural systems engineering, bio-informatics, computer simulation, computational mechanics, farm work systems and mechanized cropping. It is an international English E-journal published and distributed by the Asian Agricultural and Biological Engineering Association (AABEA). Authors should submit the manuscript file written by MS Word through a web site. The manuscript must be approved by the author''s organization prior to submission if required. Contact the societies which you belong to, if you have any question on manuscript submission or on the Journal EAEF.
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