gyroscopic

简明释义

英[ˌdʒaɪrəˈskɒpɪk]美[ˌdʒaɪrəˈskɑːpɪk]

adj. 回转仪的，[航][水运] 陀螺的

英英释义

单词用法

同义词

反义词

例句

1.Nongyroscopic north seeking system spurn the costly gyroscopic, so the produce cost decrease greatly.

非陀螺寻北系统摒弃了昂贵的陀螺，从而使制造成本大为下降。

2.Time shortly after the earth had taken its gyroscopic lean - when the Gulf Stream was parting ways with the Japanese current.

这是地球呈陀螺仪状倾斜后不久的事情，当时墨西哥湾流同日本湾流分道扬镳了。

3.Study proves that use of gyroscopic theodolite can decrease the error propagation in the underground traverses survey.

研究说明陀螺经纬仪的使用，可以减少地下导线测量的误差传播。

4.This paper introduces a kind of dynamical tuning gyroscopic logging technology to re survey the well body track in cased production and injection Wells.

文章介绍了一种用于已下套管的油水井重新测量其井身轨迹的动力调谐陀螺测井技术。

5.This gyroscopic motion is called precession.

此陀螺运动叫做进动。

6.In this paper the asymptotic stability of the partially damped linear mechanical system with gyroscopic forces is studied.

本文研究了非完全阻尼(部分阻尼)情况下力学系统的渐近稳定性问题。

7.The control flow of decreasing gyroscopic coupling is presented.

给出了减小陀螺效应耦合的控制流程。

8.The airplane's gyroscopic 陀螺仪的 instruments help pilots maintain stability during flight.

飞机的gyroscopic 陀螺仪的仪器帮助飞行员在飞行中保持稳定。

9.A gyroscopic 陀螺的 sensor is essential for modern smartphones to detect orientation.

现代智能手机需要一个gyroscopic 陀螺的传感器来检测方向。

10.The gyroscopic 陀螺的 effect allows bicycles to remain upright when in motion.

由于gyroscopic 陀螺的效应，自行车在运动时能够保持直立。

11.Robots often use gyroscopic 陀螺的 technology to navigate complex environments.

机器人通常使用gyroscopic 陀螺的技术在复杂环境中导航。

12.The gyroscopic 陀螺的 stabilizer in the camera helps to reduce motion blur.

相机中的gyroscopic 陀螺的稳定器有助于减少运动模糊。

作文

The concept of balance and stability is crucial in various fields, from aviation to robotics. One fascinating principle that contributes to these aspects is the gyroscopic (陀螺仪的) effect. A gyroscope is a device that uses the principles of angular momentum to maintain its orientation. This principle can be observed in many everyday applications, such as in airplanes, where it helps pilots maintain level flight, or in smartphones, where it aids in navigation and gaming experiences. In aviation, the gyroscopic (陀螺仪的) effect plays a vital role in ensuring the stability of an aircraft. When a plane is in flight, it is subjected to various forces that can cause it to pitch, roll, or yaw. The gyroscope helps counteract these movements by providing a stable reference point. For instance, if a pilot makes a turn, the gyroscope will resist the change in orientation, allowing for smoother transitions and better control of the aircraft. This is particularly important during adverse weather conditions when maintaining stability is essential for safety. Similarly, in the world of robotics, the gyroscopic (陀螺仪的) technology is integral to the development of autonomous vehicles and drones. These machines rely on gyroscopes to navigate complex environments and maintain their balance. For example, a drone equipped with gyroscopic (陀螺仪的) sensors can stabilize itself against wind gusts, ensuring that it remains steady while capturing high-quality aerial footage. Without this technology, flying robots would struggle to maintain their positions, leading to erratic movements and potential crashes. Moreover, the gyroscopic (陀螺仪的) effect is not limited to large machines; it can also be found in smaller devices like smartphones. Modern smartphones are equipped with accelerometers and gyroscopes that work together to enhance user experience. For instance, when you tilt your phone while playing a game, the gyroscopic (陀螺仪的) sensor detects the change in orientation and adjusts the gameplay accordingly. This interaction between physical movement and digital response creates a more immersive experience for users. The implications of gyroscopic (陀螺仪的) technology extend beyond just stability and navigation. It also has applications in various scientific fields, including physics and engineering. Researchers utilize gyroscopes to study rotational motion and angular momentum, which are fundamental concepts in understanding the behavior of objects in motion. By analyzing data collected from gyroscopic (陀螺仪的) instruments, scientists can gain insights into phenomena such as planetary rotation and satellite positioning. In conclusion, the gyroscopic (陀螺仪的) effect is a remarkable principle that enhances stability and control in numerous applications, from aviation to robotics and consumer electronics. Its ability to maintain orientation and resist changes in motion is invaluable in ensuring safety and efficiency. As technology continues to advance, the significance of gyroscopic (陀螺仪的) systems will only grow, paving the way for new innovations and improved designs across various industries.