gyroscope

简明释义

英[ˈdʒaɪrəskəʊp]美[ˈdʒaɪrəskoʊp]

n. 陀螺仪；[航] 回转仪

复 数 g y r o s c o p e s

英英释义

单词用法

同义词

反义词

例句

1.The iPad, for instance, allows users to send e-mails, watch movies, even play gyroscope-enhanced games.

比如，iPad平板电脑支持用户发送电子邮件，看电影，甚至可以玩增强版的Gyro陀螺仪游戏。

2.Attach an inertial gyroscope to the ThinkPad and scan the map in rotate, as well as tilt and roll.

将一个惯性陀螺仪连接到ThinkPad，并通过转动、倾斜和翻转动作扫描地图。

3.This paper is a experimental report about Characteristics of the tracking rates of the gas-dynamic free rotor gyroscope.

本文是有关动压气浮自由转子陀螺仪的跟踪速率特性的实验总结报告。

4.It is impossible to design a gyroscope which would meet all these requirements, and a compromise is always necessary.

不可能设计一个能满足所有这些要求的陀螺，因此折衷常常是必要的。

5.Drag onto the page to add a gyro, gyroscope, or gyrocompass.

拖到绘图页后，可以添加回转仪、陀螺仪或回转罗盘。

6.But since the crisis took hold, the macroeconomic gyroscope has begun to level out dramatically.

但自从经济危机来临之后，宏观经济开始显著地趋于稳定。

7.Micromachined vibrating gyroscope is a new type inertial component.

微机械振动陀螺是新型的惯性元件。

8.It has a gyroscope in the headpiece as well, so you can move your cursor by moving your head.

它有一个陀螺仪的头巾一样，所以你可以移动光标移动你的头。

9.The gyroscope compass makes the vessels keep on the fixed course voluntarily.

陀螺罗盘自动使船只保持在预定的航线上。

10.The airplane's stability is enhanced by the use of a gyroscope.

飞机的稳定性通过使用一个陀螺仪得到了增强。

11.Modern smartphones often include a gyroscope to improve gaming experiences.

现代智能手机通常包含一个陀螺仪以改善游戏体验。

12.A gyroscope helps ships maintain their balance in rough seas.

在恶劣海况下，陀螺仪帮助船只保持平衡。

13.Robots use a gyroscope for precise movement and orientation.

机器人使用陀螺仪进行精确的移动和定位。

14.The drone's flight stability is largely due to its onboard gyroscope.

无人机的飞行稳定性很大程度上归功于其机载的陀螺仪。

作文

The concept of a gyroscope is fascinating and has significant applications in various fields, including aviation, navigation, and even consumer electronics. A gyroscope is a device that utilizes the principles of angular momentum to maintain orientation and stability. It consists of a spinning wheel or rotor mounted in such a way that its axis of rotation can take any orientation. This unique feature allows the gyroscope to resist changes to its orientation when external forces are applied, making it an essential component in many modern technologies. In aviation, for example, aircraft rely heavily on gyroscopes for flight stability and control. The instruments in the cockpit, such as the artificial horizon and attitude indicator, use gyroscopes to provide pilots with critical information about the aircraft's orientation relative to the earth's surface. When a plane banks or turns, the gyroscope helps to keep track of the aircraft's position, ensuring that pilots can navigate safely through various weather conditions and air traffic. Similarly, in the field of navigation, gyroscopes are integral to inertial navigation systems (INS). These systems are used in submarines, spacecraft, and missiles to determine their position and orientation without relying on external references like GPS. The gyroscope measures the rate of rotation around different axes, allowing the system to calculate changes in position over time. This capability is crucial for missions where GPS signals may be unavailable or unreliable. Consumer electronics have also embraced the technology of gyroscopes. For instance, smartphones and tablets often include microelectromechanical systems (MEMS) gyroscopes that enable features like screen rotation, motion-based gaming, and augmented reality applications. These tiny gyroscopes detect the orientation of the device and make real-time adjustments, enhancing user experience and functionality. Moreover, the advancements in gyroscope technology have led to the development of more compact and efficient devices. Modern gyroscopes can be miniaturized to fit into small gadgets while maintaining high accuracy and performance. This miniaturization has opened up new possibilities for innovation across various industries, from robotics to virtual reality. Despite their widespread use, many people may not fully understand how gyroscopes work. At their core, gyroscopes operate based on the conservation of angular momentum, which states that an object in motion will remain in motion unless acted upon by an external force. When the rotor of a gyroscope spins, it creates a stable reference point that resists changes in its orientation. This property is what makes gyroscopes so valuable in applications that require precise control and stability. In conclusion, the gyroscope is a remarkable invention that has transformed how we navigate and interact with the world around us. Its applications in aviation, navigation, and consumer electronics showcase its versatility and importance in modern technology. As we continue to innovate and push the boundaries of what is possible, the role of gyroscopes will undoubtedly expand, leading to even more exciting developments in the future.

陀螺仪的概念令人着迷，并在航空、导航甚至消费电子等多个领域具有重要应用。陀螺仪是一种利用角动量原理来维持方向和稳定性的设备。它由一个旋转的轮子或转子组成，安装方式使其旋转轴可以采取任何方向。这一独特特性使得陀螺仪在施加外力时能够抵抗方向的变化，这使其成为许多现代技术中不可或缺的组件。 例如，在航空领域，飞机在飞行稳定性和控制方面严重依赖陀螺仪。驾驶舱中的仪器，如人工地平仪和姿态指示器，使用陀螺仪为飞行员提供有关飞机相对于地球表面的方向的重要信息。当飞机倾斜或转弯时，陀螺仪帮助跟踪飞机的位置，确保飞行员能够安全地穿越各种天气条件和空中交通。 同样，在导航领域，陀螺仪是惯性导航系统（INS）的核心。这些系统用于潜艇、航天器和导弹，以在不依赖外部参考（如GPS）的情况下确定其位置和方向。陀螺仪测量围绕不同轴的旋转速率，使系统能够计算随时间变化的位置。这种能力对于GPS信号可能不可用或不可靠的任务至关重要。 消费电子产品也采用了陀螺仪技术。例如，智能手机和平板电脑通常包括微机电系统（MEMS）陀螺仪，使得屏幕旋转、基于运动的游戏和增强现实应用等功能成为可能。这些微小的陀螺仪检测设备的方向并进行实时调整，从而增强用户体验和功能。 此外，陀螺仪技术的进步导致了更紧凑和高效设备的发展。现代的陀螺仪可以被微型化到适合小型设备，同时保持高精度和性能。这种微型化为各个行业的创新开辟了新的可能性，从机器人技术到虚拟现实。 尽管它们被广泛使用，但许多人可能并不完全理解陀螺仪的工作原理。从本质上讲，陀螺仪基于角动量守恒的原理运作，该原理指出，运动中的物体将保持运动，除非受到外力的作用。当陀螺仪的转子旋转时，它创建一个稳定的参考点，抵抗方向的变化。这一特性使得陀螺仪在需要精确控制和稳定性的应用中极具价值。 总之，陀螺仪是一项了不起的发明，改变了我们导航和与周围世界互动的方式。它在航空、导航和消费电子中的应用展示了它的多功能性和在现代技术中的重要性。随着我们不断创新并推动可能性的边界，陀螺仪的角色无疑会扩大，未来将带来更多令人兴奋的发展。