球面收敛二元矢量喷管气动及红外特性研究:模拟高空状态

针对高空状态下球面收敛二元矢量喷管排气系统,通过数值模拟研究了喷管俯仰偏转角对排气系统气动和红外辐射特性的影响,并与地面状态进行了对比分析.在该研究参数范围内,研究结果表明:在俯仰偏转角为20°范围内,俯仰偏转对排气系统推力系数和总压恢复系数的影响微弱,气动推力矢量角与俯仰偏转角几乎相等,高空状态下,喷管的推力系数和总压恢复系数下降0.5%与1.1%；热喷流峰值红外辐射强度仅为地面状态的12%~24%,排气系统的总体红外辐射强度峰值与地面状态下的比值峰值在0.35~0.45之间；随着下俯仰偏转角的增加,排气系统红外辐射峰值呈现下降的趋势.      

Novel orbit-attitude combination mode for solar power satellites to reduce mass and fuel

Solar power satellite receives great attention because it can release the energy crisis and environmental problems in the future. However, the launch and maintenance costs are tremendous due to the large system mass and large fuel consumption to counteract space perturbations. To reduce mass and fuel, a novel quasi-Sun-pointing attitude in Sun-frozen orbit is proposed. The Sun-frozen orbit has a nonzero eccentricity vector that always points towards the Sun. The quasi-Sun-pointing attitude is a periodic solution of the Sun-pointing attitude angle. Although about 3 % electricity must be given up because of the variation of Sun-pointing attitude angle, little control action is required to deal with the solar radiation pressure and gravity-gradient torque. The algorithm to obtain initial conditions is proposed. The influences of system parameters and structural flexibilities are studied. Simulation results reveal that the quasi-Sun-pointing attitude in Sun-frozen orbit dramatically reduce fuel consumption, the dry mass, and complexity of the control system. In addition, structural vibration is hardly induced by the gravity-gradient torque. Thus, the bending stiffness as well as the mass of the supporting structure can be reduced.     

Distributed fixed-time attitude coordinated control for multiple spacecraft with actuator saturation

This paper investigates the distributed fixed-time attitude coordinated control problem for multiple spacecraft subject to actuator saturation under the directed topology. First, a distributed fixed-time observer is presented for each follower spacecraft to estimate the leader spacecraft’s states. Compared with the commonly used fixed-time observer, the settling time of the proposed fixed-time observer can be easily adjusted by some free design parameters. Next, a distributed fixed-time control ...     

FY-3D 中分辨率成像仪图像地理定位误差来源分析

以风云三号D星（FY-3D）中分辨率成像仪（MERSI）的图像地理定位为背景，针对现阶段FY-3D图像与海岸线匹配时误差表现为周期性振荡的现象，从卫星轨道和姿态控制的角度出发，分析了当前卫星运行策略对图像地理定位精度的影响。首先，建立了当前FY-3D卫星动力学模型和成像模型；然后，以FY-3D/MERSI真实遥感图像为基础，分析姿轨控分系统对遥感图像周期性定位造成的误差；最后，通过对比数值仿真结果与真实图像数据，对来自姿轨控分系统的图像定位误差来源进行了验证。研究表明，姿轨控分系统的轨道、姿态预报误差以及载荷安装误差都会导致成像基准产生偏差，进而使图像的地理定位误差呈现周期性振荡现象。     

基于强化学习的航天器姿态控制器设计

航天器在轨执行某些任务时，其质量参数会发生未知变化，传统控制方法在这种情况下控制效果不佳。本文提出基于强化学习的航天器姿态控制器设计方法，该方法在姿态控制器训练过程中不需要对航天器进行动力学建模，不依赖航天器的质量参数。当质量参数发生较大未知变化时，训练好的控制器仍然可以保持较好的控制效果。仿真测试表明:使用基于强化学习方法训练的控制器确实具有良好的鲁棒性。此外，回报函数的设计会明显影响姿态控制器的训练，因此对不同的回报函数设计进行了研究。     

敏捷SAR卫星平台载荷一体化控制方法研究

面向具备波束指向捷变能力的小型化敏捷合成孔径雷达(SAR)卫星成像需求,提出了通过平台姿态敏捷机动和载荷波束捷变扫描一体化控制实现条带成像、多条带拼接成像、滑动聚束成像等传统成像模式的方法。针对配合成像过程提出的大角度机动和高精度高稳定度连续指向跟踪控制要求,采用5个单框架控制力矩陀螺(SGCMG)组成的"五面锥"构形控制力矩陀螺群作为执行机构,设计了基于姿态四元数和角速度反馈的改进型递阶饱和控制器,实现了平台的敏捷机动和对目标的稳定跟踪指向。数学仿真结果表明:该控制系统有效可行。     

Adaptive sliding mode fault-tolerant control for satellite attitude tracking system

In this paper, an adaptive modified sliding mode control approach is developed for attitude tracking of a nano-satellite with three magnetorquers and one reaction wheel. A sliding variable is chosen based on finite-time convergence of the nano-satellite attitude tracking error and avoiding the singularity of the control signal. The control gain of the proposed method is developed adaptively to reduce the tracking error and improve the closed-loop control performance. The sliding variable and adaptive parameter are also employed in the reaching phase of the control law to decrease the chattering phenomenon. In addition, the finite-time convergence of attitude variables in the presence of actuator faults, inertia uncertainty, and external disturbances is proved using the extended Lyapunov theorem. The simulations are conducted to evaluate the performance of the proposed method according to different evaluation criteria. Monte Carlo simulations are also used to survey the reliability of the system in the presence of the mentioned condition.     

Installation error calibration for MEMS angular measurement system in hypersonic wind tunnel

The accuracy of model attitude measurement has an important impact on wind tunnel test results. Microelectromechanical System Inertial Measurement Unit (MEMS IMU) provides a feasible way to measure model attitudes with high accuracy. However, the installation error between MEMS IMU coordinate system and the body coordinate system of test models can make the accuracy of the model attitude measurement decrease. In wind tunnel tests, the installation error depends on the relationship between the IMU and the model mechanism before tests. Therefore, in-field calibration in wind tunnel tests is necessary to reduce installation errors. To improve attitude measurement accuracy, the least squares quaternion calibration method based on MEMS IMU and six-position calibration procedure are proposed. High-precision three-axis turntable tests are performed. The pitch accuracy after calibration is higher than that before calibration in the angle of attack sweeping tests. The Root-Mean-Square Errors (RMSE) in the roll and yaw are within 0.01°, which are smaller than those before calibration. In the roll sweeping tests, RMSE of three attitude angles decrease significantly. In hypersonic wind tunnel tests, the pitch errors before and after calibration are within 0.05° and 0.02° in the angle of attack sweeping tests without wind. In five angle of attack sweeping tests with wind, the deviation between the mean of the pitch and the pitch after the elastic angle correction is within 0.03° and the standard deviation of five tests is within 0.01°. The proposed method is confirmed to enhance the accuracy of attitude measurement effectively, which is convenient for engineering applications.     

运载火箭姿态控制多速率陀螺融合方法

针对柔性火箭姿态测量中弹性信号会严重影响姿控系统设计和稳定性的问题，提出基于遗传算法的速率陀螺融合方法。首先，以降低姿控回路摆角指令传递函数的弹性峰值为目标，提出多速率陀螺融合方法的目标函数;其次，将多速率陀螺融合方法转化为多约束非线性规划问题，采用遗传算法求解多速率陀螺融合方法;最后，研究多速率陀螺融合方法对火箭姿态控制回路弹性信号的影响，以及对火箭控制器性能的影响。仿真结果表明:多速率陀螺融合方法可以有效减弱火箭姿态控制回路中的弹性信号，提高火箭控制器的性能，以增强火箭姿控系统的稳定性，降低火箭控制器设计难度。