ommateum

简明释义

英[ˌɒməˈtiːəm]美[ˌɑməˈtiəm]

n. [昆] 复眼

复 数 o m m a t e a

英英释义

单词用法

同义词

反义词

例句

1.One point-detector imitates facet in ommateum , image detector imitates one whole ommateum , and it's visual function. Object's 3-D information is got using two point-detectors.

一个点源头模拟了复眼中的一个单眼，成像头模拟了整只复眼对环境和目标的成像，利用两个点源头的信息可以得到目标的三维空间方位信息。

2.One point-detector imitates facet in ommateum , image detector imitates one whole ommateum , and it's visual function. Object's 3-D information is got using two point-detectors.

一个点源头模拟了复眼中的一个单眼，成像头模拟了整只复眼对环境和目标的成像，利用两个点源头的信息可以得到目标的三维空间方位信息。

3.The ommatidial surface ultrastructure of ommateum of 6 butterfly species were observed with scanning electronic microscope.

利用扫描电子显微镜观察了6种蝶复眼小眼面的表面结构。

4.So this paper does certain researches on ommateum and some ATR techniques are proposed in this paper.

基于这一点，本文在对复眼的研究及讨论的基础上，提出了一些自动目标识别的技术。

5.The scientist studied the structure of the ommateum to understand its role in the insect's vision.

科学家研究了ommateum的结构，以了解它在昆虫视觉中的作用。

6.In certain species, the ommateum is responsible for detecting movement in the environment.

在某些物种中，ommateum负责检测环境中的运动。

7.The intricate design of the ommateum allows for a wide field of view.

复杂的ommateum设计允许广阔的视野。

8.Researchers are exploring how the ommateum contributes to the navigation abilities of certain insects.

研究人员正在探索ommateum如何促进某些昆虫的导航能力。

9.The ommateum consists of multiple lenses that work together to form images.

ommateum由多个镜头组成，这些镜头共同工作以形成图像。

作文

In the fascinating world of biology, there are numerous terms that describe the intricate structures of living organisms. One such term is ommateum, which refers to the complex, often multi-faceted eyes found in certain arthropods, particularly in insects and crustaceans. These eyes are composed of numerous individual units called ommatidia, each contributing to the overall visual perception of the creature. The study of ommateum provides insights into how these animals perceive their environment, navigate through their habitats, and interact with other species. Understanding the structure of the ommateum can reveal a lot about the evolutionary adaptations of different species. For instance, dragonflies possess highly developed ommateum that allow them to have nearly a 360-degree field of vision. This adaptation is crucial for hunting and avoiding predators. In contrast, some species of crustaceans have ommateum that are more specialized for detecting movement in water, which aids them in finding food and avoiding dangers in their aquatic environments. The role of ommateum extends beyond mere vision; it also plays a significant part in the behavior and survival of these creatures. For example, the ability to detect polarized light through their ommateum helps some insects navigate using the sun's position, allowing them to travel long distances without getting lost. This remarkable adaptation showcases the complexity of nature and the various ways organisms have evolved to thrive in their specific niches. Moreover, research into ommateum has implications for technology and design. Scientists and engineers study the optical properties of these compound eyes to develop advanced imaging systems and cameras that mimic the capabilities of insect vision. By understanding how ommateum works, we can create devices that enhance our own visual technologies, leading to better surveillance systems, improved medical imaging, and even innovations in robotics. In conclusion, the term ommateum encapsulates a vital aspect of biological diversity and adaptation. Through the lens of this unique eye structure, we gain a deeper appreciation for the complexities of life on Earth. By studying ommateum, we not only learn about the creatures that possess them but also uncover valuable knowledge that can be applied to various fields, from biology to engineering. The study of ommateum is a testament to the interconnectedness of life and the endless possibilities that arise from understanding the natural world around us.

在生物学的迷人世界中，有许多术语描述生物体复杂的结构。其中一个术语是ommateum，指的是某些节肢动物，特别是昆虫和甲壳类动物中发现的复杂的、通常是多面的眼睛。这些眼睛由许多个称为小眼的单元组成，每个单元都对生物的整体视觉感知做出贡献。对ommateum的研究提供了对这些动物如何感知环境、在栖息地中导航以及与其他物种互动的深入见解。 理解ommateum的结构可以揭示不同物种的进化适应。例如，蜻蜓拥有高度发达的ommateum，使它们几乎能够拥有360度的视野。这种适应对于捕猎和避免捕食者至关重要。相比之下，一些甲壳类动物的ommateum更专门化，用于检测水中的运动，帮助它们寻找食物和避免在水生环境中的危险。 ommateum的作用不仅限于视觉；它还在这些生物的行为和生存中发挥着重要作用。例如，通过他们的ommateum检测偏振光的能力，帮助一些昆虫利用太阳的位置进行导航，使它们能够在不迷路的情况下长途旅行。这种显著的适应展示了自然的复杂性以及生物如何演变以在特定生态位中茁壮成长。 此外，对ommateum的研究对技术和设计也有影响。科学家和工程师研究这些复眼的光学特性，以开发先进的成像系统和模仿昆虫视觉能力的相机。通过理解ommateum的工作原理，我们可以创造出增强我们自身视觉技术的设备，从而改善监控系统、提高医学成像，甚至在机器人技术中进行创新。 总之，术语ommateum概括了生物多样性和适应性的重要方面。通过这一独特眼睛结构的视角，我们对地球上生命的复杂性有了更深刻的认识。通过研究ommateum，我们不仅了解了拥有这些结构的生物，还揭示了可以应用于各个领域的宝贵知识，从生物学到工程学。对ommateum的研究证明了生命的相互联系以及理解我们周围自然世界所带来的无尽可能性。