GPS定姿系统/捷联惯性导航系统组合技术研究

研究了GPS定姿系统和捷联惯性导航系统二者的组合技术 :根据传递对准技术 ,研究了GPS定姿系统在捷联惯性导航系统的初始对准中的应用 ;根据空间几何约束 ,研究了模糊度的搜索算法 ,以提高定姿系统的计算效率和稳定性。实验证明 ,方案切实可行 ,收到了良好的效果。     

一体化小型星敏感器

星敏感器是当前广泛应用于航天器姿态确定的高精度光学敏感器。小型化、低功耗、高实时性是现阶段星敏感器发展的共同特点。本文介绍了一种由我所研制的一体化小型星敏感器 ,包括主要技术指标、工作原理和系统组成等     

闭路制导下提高姿态控制精度方案研究

为满足闭路制导对姿态跟踪精度的要求 ,本报告提出了一种新的控制方案 ,即具有积分性质的姿态控制方案 ,对其进行了详细的理论分析 ,并在此方案基础上完成了某型号稳定性分析 ,进行了数学仿真试验验证 ,结果表明 ,在不损失原方案裕度的基础上 ,姿态偏差得到了有效控制     

航天器上升段轨道快速重构算法

针对航天器上升飞行过程中由于干扰的影响导致实际轨道偏离初始设计轨道的问题,提出了基于状态量提前修正的航天器上升段轨道快速重构算法。使用该算法对大气干扰下上升段轨道进行了快速重构仿真分析,结果表明,该算法能够综合考虑上升段飞行过程的状态量约束、终端约束、入轨精度、重构时间等因素,实现快速重构。     

Attitude coordination for spacecraft formation with multiple communication delays

Communication delays are inherently present in information exchange between spacecraft and have an effect on the control performance of spacecraft formation. In this work, attitude coordination control of spacecraft formation is addressed, which is in the presence of multiple communication delays between spacecraft. Virtual system-based approach is utilized in case that a constant reference attitude is available to only a part of the spacecraft. The feedback from the virtual systems to the spacecraft formation is introduced to maintain the formation. Using backstepping control method, input torque of each spacecraft is designed such that the attitude of each spacecraft converges asymptotically to the states of its corresponding virtual system. Furthermore, the backstepping technique and the Lyapunov–Krasovskii method contribute to the control law design when the reference attitude is time-varying and can be obtained by each spacecraft. Finally, effectiveness of the proposed methodology is illustrated by the numerical simulations of a spacecraft formation.     

重力扰动对高精度惯性导航初始对准 的影响与补偿

初始对准时, 通常是基于地球参考椭球, 用正常重力公式计算重力矢量, 而实际情况下地球内部质量分布不均匀,实际重力包含正常重力和重力扰动。重力扰动 包括参考椭球面切线方向的分量（垂线偏差）和法线方向分量（重力异常）。研究重力 扰动下的初始对准,导出了重力扰动下水平姿态误差角与垂线偏差大小等值。重力扰动 下初始对准的方法是利用EGM2008 地球重力场模型计算出对准点的重力扰动并从加速度 计中剔除掉。仿真分析表明,补偿重力扰动后可提高初始对准精度。     

Accurate attitude estimation of HB2 standard model based on QNCF in hypersonic wind tunnel test

The accuracy of the HB2 standard model attitude measurement has an important impact on the hypersonic wind tunnel data assessment. The limited size of the model and the existence of external vibrations make it challenging to obtain real-time reliable attitude measurement. To reduce the influence of attitude errors on test results, this paper proposes a Quaternion Nonlinear Complementary Filter (QNCF) attitude determination algorithm based on Microelectromechanical Inertial Measurement Unit (MEMS-IMU). Firstly, the threshold-based PI control strategy is adopted to eliminate noise effect according to the Acceleration Magnitude Detector (AMD). Then, the flexible quaternion method is updated to carry out attitude estimation which is operational and easy to be embedded in the Field Programmable Gate Array (FPGA). Finally, a high-precision three-axis turntable test and a hypersonic wind tunnel test are performed. The results show that the pitch-roll attitude errors are within 0.05° and 0.08° in the high-precision three-axis turntable test in a calculation time of 100 s respectively, and the attitude error is within 0.3° after the elastic angle correction in the hypersonic wind tunnel test. The proposed method can provide accurate real-time attitude reference for the analysis of the actual movement of the model, exhibiting certain engineering application value with robustness and simplicity.     

一种基于串级线性自抗扰控制的四旋翼无人机控制方法

提出了一种基于串级线性自抗扰控制器的四旋翼无人机控制方法。根据建立的紊流模型形成了干扰风,在干扰风的环境下建立了四旋翼的运动学模型,并设计了一个串级的线性自抗扰控制器,其中外环采用位置控制,内环采用姿态控制。对比了该控制器与非线性自抗扰控制器和经典PID控制器在无风干扰和有风干扰下无人机的定点悬停的性能。仿真试验结果表明,无论是在无风干扰下还是在有风干扰下,该控制器的性能均好于非线性自抗扰控制器和PID控制器,具有较好的鲁棒性,能够运用到各种类型的旋翼无人机的工程控制中。     

Virtual baseline method for Beidou attitude determination – An improved long-short baseline ambiguity resolution method

Ambiguity resolution (AR) is a critical step for successful attitude determination using carrier phase measurements of a satellite navigation system such as Beidou. This paper proposes an improved method for AR in support of Beidou attitude determination based on the concept of a “virtual baseline”. In the traditional long-short baseline method, the short baseline is limited to a length less than half of the carrier wave length of the Beidou signals. In the proposed method, a virtual short baseline is formed by differencing two collinear baselines. The AR equations for virtual short and long baselines are derived and the factors impacting the AR accuracy are analysed. Numerical simulation studies were carried out to evaluate the performance of the proposed AR method. The simulation results confirmed that the proposed method is an improvement over the traditional approach -- not only is it easier to deploy collinear antennas but also it keeps the capability of epoch-by-epoch AR, which makes it immune to cycle slips and there is no need for initialisation of ambiguity searching.     

Jitter reduction of a reaction wheel by management of angular momentum using magnetic torquers in nano- and micro-satellites

Nowadays, nano- and micro-satellites, which are smaller than conventional large satellites, provide access to space to many satellite developers, and they are attracting interest as an application of space development because development is possible over shorter time period at a lower cost. In most of these nano- and micro-satellite missions, the satellites generally must meet strict attitude requirements for obtaining scientific data under strict constraints of power consumption, space, and weight. In many satellite missions, the jitter of a reaction wheel degrades the performance of the mission detectors and attitude sensors; therefore, jitter should be controlled or isolated to reduce its effect on sensor devices. In conventional standard-sized satellites, tip-tilt mirrors (TTMs) and isolators are used for controlling or isolating the vibrations from reaction wheels; however, it is difficult to use these devices for nano- and micro-satellite missions under the strict power, space, and mass constraints. In this research, the jitter of reaction wheels is reduced by using accurate sensors, small reaction wheels, and slow rotation frequency reaction wheel instead of TTMs and isolators. The objective of a reaction wheel in many satellite missions is the management of the satellite’s angular momentum, which increases because of attitude disturbances. If the magnitude of the disturbance is reduced in orbit or on the ground, the magnitude of the angular momentum that the reaction wheels gain from attitude disturbances in orbit becomes smaller; therefore, satellites can stabilize their attitude using only smaller reaction wheels or slow rotation speed, which cause relatively smaller vibration. In nano- and micro-satellite missions, the dominant attitude disturbance is a magnetic torque, which can be cancelled by using magnetic actuators. With the magnetic compensation, the satellite reduces the angular momentum that the reaction wheels gain, and therefore, satellites do not require large reaction wheels and higher rotation speed, which cause jitter. As a result, the satellite can reduce the effect of jitter without using conventional isolators and TTMs. Hence, the satellites can achieve precise attitude control under low power, space, and mass constraints using this proposed method. Through the example of an astronomical observation mission using nano- and micro-satellites, it is demonstrated that the jitter reduction using small reaction wheels is feasible in nano- and micro-satellites.