gyrostat

简明释义

英[ˈdʒaɪərəʊstæt]美[ˈdʒaɪrəˌstæt]

n. [航][水运] 陀螺体；[航] 回转仪

英英释义

单词用法

同义词

反义词

例句

1.In this paper the motion of a torque - free asymmetric gyrostat with a mass - eccentric rotor is discussed.

本文讨论无力矩条件下带有质量偏心轴对称转子的非对称陀螺体的运动。

2.In this paper the motion of a torque - free asymmetric gyrostat with a mass - eccentric rotor is discussed.

本文讨论无力矩条件下带有质量偏心轴对称转子的非对称陀螺体的运动。

3.The global characters of the permanent rotations of a free gyrostat is analysed in present paper.

本文分析自由陀螺体永久转动的全局特性。

4.The spacecraft's stability was ensured by the use of a gyrostat 陀螺仪 that maintained its orientation in space.

航天器的稳定性是通过使用一个gyrostat 陀螺仪来保持其在太空中的方向。

5.In robotics, a gyrostat 陀螺仪 is essential for precise movement and balance.

在机器人技术中，gyrostat 陀螺仪 对于精确的运动和平衡至关重要。

6.The gyrostat 陀螺仪 helps the drone stabilize itself during flight, reducing turbulence effects.

该gyrostat 陀螺仪 帮助无人机在飞行中保持稳定，减少湍流影响。

7.Engineers designed the new bicycle with a gyrostat 陀螺仪 to enhance rider stability.

工程师设计了这款新自行车，配备了一个gyrostat 陀螺仪 来增强骑行者的稳定性。

8.The gyrostat 陀螺仪 in the navigation system allows for accurate tracking of direction.

导航系统中的gyrostat 陀螺仪 允许准确跟踪方向。

作文

The concept of a gyrostat is fascinating and plays a crucial role in various fields of science and engineering. A gyrostat is essentially a device that utilizes the principles of angular momentum to maintain its orientation in space. This characteristic makes it invaluable in applications such as navigation systems, robotics, and aerospace engineering. Understanding how a gyrostat functions can provide insights into its practical uses and significance in modern technology. At its core, a gyrostat consists of a spinning rotor mounted on a gimbal, allowing it to rotate freely in multiple directions. The spinning motion creates stability due to the conservation of angular momentum, meaning that the gyrostat resists changes to its axis of rotation. This property is what makes gyrostats essential for stabilizing platforms, such as those used in aircraft and spacecraft. For instance, in aviation, a gyrostat can help maintain an aircraft's orientation during flight, providing pilots with crucial data about their position and movement. In addition to aviation, gyrostats are also widely used in robotics. Robots equipped with gyrostats can achieve greater precision and balance, especially when navigating uneven terrains or performing complex tasks. By integrating a gyrostat into a robot's design, engineers can enhance its ability to maintain stability and control, which is vital for tasks that require a high degree of accuracy. Moreover, the use of gyrostats extends to consumer electronics as well. Many smartphones and gaming devices incorporate gyrostats to detect orientation and motion, enabling features like screen rotation and motion-based controls. This integration highlights the versatility of gyrostats and their importance in enhancing user experience in everyday technology. The study of gyrostats also opens up discussions about the underlying physics principles, particularly those related to rotational dynamics and inertia. By examining how a gyrostat behaves under various conditions, students and professionals can gain a deeper understanding of fundamental concepts in physics. This knowledge can be applied not only in theoretical contexts but also in practical scenarios where stability and balance are critical. In conclusion, the gyrostat is more than just a mechanical device; it embodies principles of physics that have vast applications across different industries. From aviation and robotics to consumer electronics, gyrostats play a pivotal role in ensuring stability and precision. As technology continues to evolve, the relevance of gyrostats is likely to grow, making it essential for future engineers and scientists to comprehend their functionality and applications. Understanding the workings of a gyrostat not only enriches our knowledge of physics but also inspires innovation in the development of new technologies that rely on these remarkable devices.

陀螺仪的概念是迷人的，在科学和工程的各个领域中发挥着至关重要的作用。gyrostat 本质上是一个利用角动量原理来维持其在空间中方向的设备。这一特性使其在导航系统、机器人技术和航空航天工程等应用中变得不可或缺。理解 gyrostat 的功能可以提供对其实际用途和在现代技术中重要性的洞察。 从本质上讲，gyrostat 由一个旋转的转子和一个允许其在多个方向自由旋转的万向节组成。旋转运动由于角动量守恒而产生稳定性，这意味着 gyrostat 抵抗其旋转轴的变化。这一特性使得 gyrostat 对于稳定平台至关重要，例如用于飞机和航天器的那些。例如，在航空领域，gyrostat 可以帮助保持飞机在飞行中的方向，为飞行员提供有关其位置和运动的重要数据。 除了航空，gyrostat 还广泛应用于机器人技术。配备 gyrostat 的机器人能够实现更高的精度和平衡，特别是在不平坦的地形上导航或执行复杂任务时。通过将 gyrostat 集成到机器人的设计中，工程师可以增强其保持稳定性和控制能力，这对于需要高度准确性的任务至关重要。 此外，gyrostat 的使用还扩展到消费电子产品。许多智能手机和游戏设备都集成了 gyrostat 来检测方向和运动，从而启用屏幕旋转和基于运动的控制等功能。这种集成突显了 gyrostat 的多功能性及其在提升日常技术用户体验中的重要性。 对 gyrostat 的研究也开启了关于基础物理原理的讨论，特别是与旋转动态和惯性相关的原理。通过考察 gyrostat 在各种条件下的行为，学生和专业人员可以更深入地理解物理学中的基本概念。这些知识不仅可以应用于理论背景，还可以应用于在稳定性和平衡至关重要的实际场景。 总之，gyrostat 不仅仅是一个机械装置；它体现了在不同工业中具有广泛应用的物理原理。从航空和机器人到消费电子，gyrostat 在确保稳定性和精确性方面发挥着关键作用。随着技术的不断发展，gyrostat 的相关性可能会增加，因此未来的工程师和科学家必须理解其功能和应用。理解 gyrostat 的工作原理不仅丰富了我们对物理学的知识，还激励着创新，推动依赖这些卓越设备的新技术的发展。