movable appendage

简明释义

活动附体

英英释义

例句

1.In robotics, engineers often focus on the mechanics of a movable appendage to improve functionality.

在机器人技术中，工程师通常关注可移动的附肢的机械结构，以提高功能性。

2.The robot's design includes a movable appendage that allows it to reach objects in tight spaces.

机器人的设计包括一个可移动的附肢，使其能够在狭小的空间中获取物体。

3.In marine biology, the octopus is known for its movable appendages that help it navigate through water.

在海洋生物学中，章鱼以其可移动的附肢而闻名，这帮助它在水中导航。

4.The artist created a sculpture with a movable appendage that interacts with viewers.

艺术家创作了一件雕塑，它有一个与观众互动的可移动的附肢。

5.The drone features a movable appendage that can adjust its camera angle for better aerial photography.

这款无人机配备了一个可移动的附肢，可以调整摄像头角度，以便更好地进行空中摄影。

作文

In the fascinating world of biology, many organisms possess unique features that enable them to thrive in their environments. One such feature is the movable appendage, which refers to a limb or structure that can be moved and manipulated for various functions. These appendages play crucial roles in locomotion, feeding, and interaction with the environment. For instance, consider the octopus, an extraordinary marine creature known for its intelligence and adaptability. The octopus has eight arms, each equipped with numerous suckers, making them perfect examples of movable appendages. These arms allow the octopus to navigate through complex underwater terrains, capture prey, and even escape predators. Another interesting example of movable appendages can be found in insects. Many insects have antennae, which are flexible sensory organs that help them detect changes in their surroundings. These antennae can move independently, allowing the insect to gather information about food sources, mates, and potential threats. This adaptability is essential for survival, showcasing how movable appendages are not just for mobility but also for enhancing an organism's ability to interact with its environment.Birds are another group of animals that exhibit remarkable movable appendages. Their wings, while primarily used for flight, also serve various other functions. For example, birds use their wings to regulate body temperature, communicate with others, and attract mates through elaborate displays. The versatility of these movable appendages highlights the evolutionary advantages they provide, enabling birds to occupy diverse ecological niches.In the realm of robotics, the concept of movable appendages has inspired engineers and designers to create machines that mimic the movements of living organisms. Robotic arms, for instance, are designed to perform tasks that require precision and dexterity, much like the limbs of animals. These robotic appendages can be programmed to carry out complex operations in manufacturing, surgery, and even exploration of hazardous environments. By studying the mechanics of biological movable appendages, researchers can improve the functionality and efficiency of robotic systems.In conclusion, movable appendages are integral to the survival and success of many species across the animal kingdom. From the agile arms of an octopus to the sensitive antennae of insects and the versatile wings of birds, these structures facilitate movement, communication, and interaction with the environment. Furthermore, the study of movable appendages extends beyond biology, influencing advancements in technology and robotics. As we continue to explore the intricate designs of nature, we gain valuable insights that can inspire innovation and enhance our understanding of the world around us.

在生物学的迷人世界中，许多生物拥有独特的特征，使它们能够在环境中茁壮成长。其中一个特征是可动附肢，指的是可以移动和操控的肢体或结构。这些附肢在运动、觅食和与环境互动中发挥着至关重要的作用。例如，考虑章鱼，这种以智力和适应性而闻名的非凡海洋生物。章鱼有八条手臂，每条手臂上都配有众多吸盘，是可动附肢的完美例子。这些手臂使章鱼能够在复杂的水下地形中导航，捕捉猎物，甚至逃避捕食者。另一个有趣的可动附肢例子可以在昆虫中找到。许多昆虫都有触角，这些灵活的感官器官帮助它们检测周围环境的变化。这些触角可以独立移动，使昆虫能够收集有关食物来源、配偶和潜在威胁的信息。这种适应能力对生存至关重要，展示了可动附肢不仅用于运动，还增强了生物与环境互动的能力。鸟类是另一类展示出卓越可动附肢的动物。它们的翅膀虽然主要用于飞行，但也具有多种其他功能。例如，鸟类利用翅膀调节体温，与其他鸟类交流，并通过华丽的展示吸引配偶。这些可动附肢的多功能性突显了它们所提供的进化优势，使鸟类能够占据多样的生态位。在机器人领域，可动附肢的概念激励工程师和设计师创造模仿生物运动的机器。机器人手臂就是一个例子，旨在执行需要精确和灵活性的任务，就像动物的肢体一样。这些机器人附肢可以被编程以在制造、外科手术甚至探索危险环境中执行复杂操作。通过研究生物可动附肢的机制，研究人员可以改善机器人系统的功能和效率。总之，可动附肢是许多物种在动物王国中生存和成功的关键。从章鱼的灵活手臂到昆虫的敏感触角，再到鸟类的多功能翅膀，这些结构促进了运动、沟通和与环境的互动。此外，可动附肢的研究超越了生物学，影响着技术和机器人领域的进步。随着我们继续探索自然的复杂设计，我们获得了宝贵的见解，可以激励创新并增强我们对周围世界的理解。