陀螺作为导航系统中的重要传感器最早应用于航海导航，随着科技的发展，它在

As an important sensor in the navigation system, the gyroscope was first used in marine navigation. With the development of science and technology, it has also been widely used in related fields such as aviation, aerospace, missiles, automobiles, etc. [1-4] that require orientation and balance. However, the gyro system is a typical nonlinear chaotic system. In recent years, the control of the chaotic behavior of the gyro system has attracted more and more attention from researchers. So far, there have been many methods to control the occurrence of chaotic behavior, such as OGY control [5], linear feedback control [6], adaptive control [7], sliding mode control [8-10], etc.

Gyro, as an important sensor in navigation system, is first used in navigation and navigation, and with the development of science and technology, it has also been widely used in the related fields of aviation, aerospace, missile, automobile and other related fields such as orientation and balance. However, the gyro system is a typical nonlinear chaotic system, in recent years, the control of the chaotic behavior of the gyro system has been paid more and more attention by researchers. So far, there have been many methods to control the occurrence of chaotic behavior, such as OGY control, linear feedback control, adaptive control, sliding mode control, etc.

As an important sensor in navigation system, gyroscope was first used in navigation. With the development of science and technology, it has been widely used in aviation, aerospace, missile, automobile and other related fields requiring orientation and balance. However, the gyro system is a typical nonlinear chaotic system. In recent years, more and more attention has been paid to the control of the chaotic behavior of the gyroscope system. So far, there are many methods to control chaotic behavior, such as ogy control [5], linear feedback control [6], adaptive control [7], sliding mode control [8-10], etc