gyroscopes

简明释义

英[ˈjaɪrəʊskəʊps]美[ˈjaɪrəˌskoʊps]

n. 陀螺仪（gyroscope 的复数）

英英释义

单词用法

同义词

反义词

例句

1.Gyroscopes are used in navigational instruments for ships, aircraft, and spacecraft.

陀螺仪用于船舶、飞机和宇宙飞船中的导航设备。

2.Many now contain sensors such as accelerometers (which detect whether a gadget is being held vertically or horizontally), gyroscopes and compasses.

现在，许多智能手机内置传感器，如加速计（探测设备是被横置还是竖置），回转仪和指南针。

3.By the sketch of structure of lateral comb drive micromechanical silicon gyroscopes, the authors have fully explained the working laws of this kind of gyroscope.

通过硅微型梳状线振动驱动式陀螺仪的结构示意图，介绍了该陀螺仪的工作特点。

4.Without new batteries and new gyroscopes it would lose both the power and the ability to point in the right direction.

如果没有新的电池和陀螺仪，哈勃将失去动力并且无法指向正确的方向。

5.Should the gyroscopes break down, the celestial system would take over.

如果陀螺仪发生故障，天体导航系统就会接替它继续进行工作。

6.The principle, characteristics, classification and key technologies of fiber-optic gyroscopes are summarized.

综述了光纤陀螺的基本原理，主要特点，分类情况及关键技术。

7.The drone uses gyroscopes to maintain its stability during flight.

这架无人机使用陀螺仪在飞行过程中保持稳定。

8.In smartphones, gyroscopes help improve the accuracy of motion sensing.

在智能手机中，陀螺仪有助于提高运动感应的准确性。

9.Modern airplanes are equipped with advanced gyroscopes for navigation.

现代飞机配备了先进的陀螺仪用于导航。

10.Robots often incorporate gyroscopes to enhance their balance and movement.

机器人通常结合陀螺仪来增强其平衡和运动能力。

11.Self-driving cars utilize gyroscopes to detect orientation and position.

自动驾驶汽车利用陀螺仪来检测方向和位置。

作文

In the modern world, technology has become an integral part of our daily lives. One fascinating component of this technology is the gyroscopes (陀螺仪), which are devices used to measure or maintain orientation and angular velocity. These instruments have a wide range of applications, from navigation systems in aircraft to stabilizing cameras and smartphones. Understanding how gyroscopes (陀螺仪) work can provide insight into their importance in various fields. The basic principle behind gyroscopes (陀螺仪) is the conservation of angular momentum. When a spinning wheel or disk is set in motion, it tends to maintain its position relative to its axis of rotation. This property allows gyroscopes (陀螺仪) to resist changes in orientation, making them incredibly useful for navigation. For instance, in aviation, pilots rely on gyroscopes (陀螺仪) to determine their aircraft's attitude and direction, especially when visibility is poor. In addition to aviation, gyroscopes (陀螺仪) are also crucial in the field of robotics. Many autonomous robots use gyroscopes (陀螺仪) to maintain balance and navigate through their environment. For example, self-driving cars utilize a combination of gyroscopes (陀螺仪) and other sensors to accurately gauge their position and movement, ensuring safe and efficient travel. The application of gyroscopes (陀螺仪) extends to consumer electronics as well. Smartphones and tablets are equipped with gyroscopes (陀螺仪) that enhance user experience by enabling features such as screen rotation, motion-based gaming, and augmented reality. The integration of gyroscopes (陀螺仪) in these devices demonstrates how they have become a fundamental aspect of modern technology. Moreover, the advancements in gyroscopes (陀螺仪) technology have led to the development of smaller and more efficient models, such as microelectromechanical systems (MEMS) gyroscopes (陀螺仪). These tiny devices are now commonly found in everyday gadgets, making precise motion detection accessible to a broader audience. As technology continues to evolve, the role of gyroscopes (陀螺仪) will undoubtedly expand, paving the way for new innovations in various sectors. In conclusion, gyroscopes (陀螺仪) play a vital role in numerous applications across different industries. Their ability to maintain orientation and measure angular velocity makes them essential for navigation, robotics, and consumer electronics. As we continue to explore and develop new technologies, understanding the significance of gyroscopes (陀螺仪) will help us appreciate their impact on our daily lives and the future of innovation.

在现代世界中，技术已成为我们日常生活中不可或缺的一部分。一个引人入胜的技术组成部分是gyroscopes（陀螺仪），这是一种用于测量或保持方向和角速度的设备。这些仪器有广泛的应用，从飞机的导航系统到稳定相机和智能手机。理解gyroscopes（陀螺仪）的工作原理可以提供对其在各个领域重要性的深入了解。 gyroscopes（陀螺仪）背后的基本原理是角动量守恒。当一个旋转的轮子或盘子开始运动时，它倾向于保持相对于其旋转轴的位置。这个特性使得gyroscopes（陀螺仪）能够抵抗方向的变化，使它们在导航中极为有用。例如，在航空领域，飞行员依赖gyroscopes（陀螺仪）来确定他们飞机的姿态和方向，尤其是在能见度较差的情况下。 除了航空，gyroscopes（陀螺仪）在机器人领域也至关重要。许多自主机器人使用gyroscopes（陀螺仪）来保持平衡并在环境中导航。例如，自动驾驶汽车利用gyroscopes（陀螺仪）和其他传感器的组合来准确评估其位置和运动，确保安全高效的旅行。 gyroscopes（陀螺仪）的应用还扩展到了消费电子产品。智能手机和平板电脑配备了gyroscopes（陀螺仪），通过屏幕旋转、基于运动的游戏和增强现实等功能提升用户体验。将gyroscopes（陀螺仪）集成到这些设备中，展示了它们如何成为现代技术的基础部分。 此外，gyroscopes（陀螺仪）技术的进步导致了更小、更高效模型的发展，如微机电系统（MEMS）gyroscopes（陀螺仪）。这些微型设备现在普遍存在于日常小工具中，使精确的运动检测对更广泛的受众变得可及。随着技术的不断发展，gyroscopes（陀螺仪）的角色无疑将扩大，为各个行业的新创新铺平道路。 总之，gyroscopes（陀螺仪）在各个行业的众多应用中发挥着至关重要的作用。它们保持方向和测量角速度的能力使它们在导航、机器人和消费电子产品中必不可少。随着我们继续探索和开发新技术，理解gyroscopes（陀螺仪）的重要性将帮助我们欣赏它们对我们日常生活和未来创新的影响。