bioacoustics

简明释义

英[ˌbaɪəʊəˈkuːstɪks]美[ˌbaɪoʊəˈkuːstɪks]

n. [生物物理] 生物声学

英英释义

单词用法

同义词

反义词

例句

1.Clark, director of the bioacoustics research program at Cornell University, the area over which whales in coastal waters can hear one another shrinks to only 10 to 20 percent of its natural extent.

克拉克——康内尔大学生物听力研究项目主管说，近岸海水的鲸鱼出没区域能听到自然范围内仅仅10%到20%的收缩声。

2.Clark, director of the bioacoustics research program at Cornell University, the area over which whales in coastal waters can hear one another shrinks to only 10 to 20 percent of its natural extent.

克拉克——康内尔大学生物听力研究项目主管说，近岸海水的鲸鱼出没区域能听到自然范围内仅仅10%到20%的收缩声。

3.Birdsong is one of the most active domains in bioacoustics.

鸟声研究则是生物声学研究中最为活跃的领域之一。

4.Researchers in the field of bioacoustics study how animals communicate through sound.

生物声学领域的研究人员研究动物如何通过声音进行交流。

5.Using bioacoustics, scientists can monitor the health of ecosystems by listening to animal calls.

科学家可以通过监听动物的叫声，利用生物声学来监测生态系统的健康。

6.The study of bioacoustics has revealed the complex communication systems of whales.

生物声学的研究揭示了鲸鱼复杂的沟通系统。

7.Conservationists use bioacoustics to track endangered species in their natural habitats.

保护主义者利用生物声学来追踪栖息在自然栖息地中的濒危物种。

8.The bioacoustics of marine life can provide insight into their behavior and habitat.

海洋生物的生物声学可以提供关于它们行为和栖息地的见解。

作文

The field of bioacoustics is an exciting and rapidly evolving area of study that combines biology and acoustics to explore how living organisms use sound in their natural environments. Bioacoustics involves the analysis of sounds produced by animals, including vocalizations, echolocation, and other forms of communication. This interdisciplinary approach not only helps us understand the behavior and ecology of various species but also sheds light on the impacts of environmental changes on wildlife. One of the most fascinating aspects of bioacoustics is its application in conservation efforts. By monitoring the sounds of endangered species, researchers can gather crucial data about their population dynamics and habitat use. For instance, scientists have used acoustic monitoring to track the calls of whales, which has provided insights into their migratory patterns and social structures. This information is invaluable for developing effective conservation strategies aimed at protecting these magnificent creatures and their habitats.Moreover, bioacoustics plays a significant role in understanding the effects of human activity on wildlife. Noise pollution from urban development, transportation, and industrial activities can disrupt the natural soundscapes that many animals rely on for communication and navigation. Studies have shown that increased noise levels can lead to stress and altered behavior in various species, ultimately affecting their survival. By employing bioacoustics techniques, researchers can assess the impact of such disturbances and advocate for measures to mitigate their effects, thus promoting a healthier coexistence between humans and wildlife.In addition to conservation, bioacoustics has applications in agriculture and fisheries. Farmers are increasingly using acoustic monitoring to manage livestock health and productivity. For example, changes in vocalization patterns can indicate stress or illness in animals, allowing farmers to intervene promptly. Similarly, in fisheries, understanding the acoustic signals of fish can improve sustainable fishing practices and help maintain healthy fish populations.The technological advancements in bioacoustics have made it easier than ever to collect and analyze sound data. With the advent of high-quality recording devices and sophisticated software for sound analysis, researchers can now capture and interpret complex acoustic signals with remarkable precision. This has opened new avenues for research, allowing scientists to uncover previously hidden aspects of animal behavior and communication.Furthermore, bioacoustics has implications beyond just wildlife studies; it also intersects with fields like medicine and robotics. For instance, researchers are exploring how understanding animal communication can inspire new technologies in human communication systems or even lead to innovations in bio-inspired robotics. The study of sound produced by animals might provide insights into developing machines that can mimic these behaviors, enhancing their functionality in various applications.In conclusion, bioacoustics is a vital field that bridges the gap between biology and technology, offering profound insights into the lives of animals and the ecosystems they inhabit. As we continue to face challenges such as climate change and habitat loss, the knowledge gained through bioacoustics will be essential for informing conservation efforts and fostering a sustainable future for both wildlife and humans. Embracing this interdisciplinary approach will undoubtedly lead to a deeper understanding of the natural world and our place within it.

生物声学（bioacoustics）是一个令人兴奋且快速发展的研究领域，它结合了生物学和声学，探索生物如何在自然环境中使用声音。生物声学（bioacoustics）涉及对动物产生的声音进行分析，包括发声、回声定位和其他形式的交流。这种跨学科的方法不仅有助于我们理解各种物种的行为和生态，还揭示了环境变化对野生动物的影响。生物声学（bioacoustics）最引人入胜的方面之一是其在保护工作中的应用。通过监测濒危物种的声音，研究人员可以收集有关其种群动态和栖息地使用的关键数据。例如，科学家们利用声学监测追踪鲸鱼的叫声，这为了解它们的迁徙模式和社会结构提供了见解。这些信息对于制定有效的保护策略以保护这些宏伟生物及其栖息地至关重要。此外，生物声学（bioacoustics）在理解人类活动对野生动物影响方面也发挥了重要作用。来自城市发展、交通和工业活动的噪音污染会干扰许多动物依赖的自然声景，从而影响其交流和导航。研究表明，噪音水平的增加可能导致各种物种的压力和行为改变，最终影响其生存。通过采用生物声学（bioacoustics）技术，研究人员可以评估这种干扰的影响，并倡导采取措施来减轻其影响，从而促进人类与野生动物之间更健康的共存。除了保护，生物声学（bioacoustics）在农业和渔业中也有应用。农民越来越多地使用声学监测来管理牲畜的健康和生产力。例如，发声模式的变化可以表明动物的压力或疾病，使农民能够及时干预。同样，在渔业中，了解鱼类的声学信号可以改善可持续捕鱼实践，帮助维持健康的鱼群。生物声学（bioacoustics）的技术进步使得收集和分析声音数据变得比以往任何时候都容易。随着高质量录音设备和复杂的软件用于声音分析的出现，研究人员现在可以以惊人的精度捕捉和解释复杂的声学信号。这为研究开辟了新的途径，使科学家能够揭示动物行为和交流的先前隐藏的方面。此外，生物声学（bioacoustics）不仅限于野生动物研究；它还与医学和机器人等领域交叉。例如，研究人员正在探索如何理解动物交流可以激励人类通信系统的新技术，甚至导致生物启发机器人创新。对动物产生的声音的研究可能会提供洞察力，以开发能够模仿这些行为的机器，从而增强其在各种应用中的功能。总之，生物声学（bioacoustics）是一个重要的领域，它架起了生物学和技术之间的桥梁，提供了对动物及其栖息地生态系统生活的深刻见解。随着我们继续面临气候变化和栖息地丧失等挑战，通过生物声学（bioacoustics）获得的知识将对指导保护工作和促进人类与野生动物的可持续未来至关重要。接受这种跨学科的方法无疑将导致对自然世界及我们在其中的位置的更深刻理解。