改进的绳系卫星系统距离速率控制律

为扩大绳系卫星系统(TSS)控制的稳定域,提出了一种改进距离速率控制算法。根据TSS动力学方程及构造的二阶稳定系统,给出了修正的控制模型。讨论了稳定释放角度和释放/回收速度的影响,并研究了固定绳索长度系留控制方案。算例表明该方法可显著扩大稳定域,提高释放速度。     

模糊控制技术在运载火箭姿态控制中的应用

将模糊控制理论用于运载火箭的姿态控制系统设计。以俯仰通道为例，给出了模糊控制系统框图、模糊控制器的设计及其改进。仿真结果表明，所设计的运载火箭姿态模糊控制系统简单，对内外干扰具有较强的鲁棒性。     

绕飞轨道(绕飞角＞360°)动力学和控制策略--微小卫星一种新的应用概念

本文研究微小卫星围绕空间站飞行，监视空间站运行和外观状态，减少航天员舱外活动。这是小卫星一种新的应用概念。文章主要研究绕飞轨道动力学和稳定性，以及在有摄动情况下保持绕飞轨道的控制策略。这种控制策略所消耗燃料非常少，根据仿真实验结果，绕飞卫星一个月时间仅消耗燃料的速度增量约为３～４ｍ／ｓ。     

翼伞归航准则及测风原理探讨

翼伞作为一种新型气动力减速器日渐受到空间回收技术重视。文中给出了具有非比例自动归航控制的翼伞系统的归航准则(考虑到风的影响)以及利用GPS测量数据计算风场的公式。     

大型柔性空间结构分散固定模的研究

采用速度和位置的加权和作为反馈量构成大型柔性空间结构分散控制律时的分散固定模问题，是文献［１］中采用位置输出作为反馈量时的分散固定模结论的进一步推广。     

空间停靠动力学和控制

本文研究空间停靠是广义的，它包括停留和靠近两个内容。本文首先研究空间靠近动力学方程；其次讨论保持点的动力学特性和保持点轨迹稳定的必要条件；最后介绍靠近段安全可靠的控制策略，其中包括主动稳定保持点轨迹的控制方案。     

地空导弹气压舵机仿真数学模型及其校准

本文给出了某种地一空导弹气压舵机的仿真数学模型,此模型计入了一些重要的非线性因素;介绍了空载校准,仿真试验和导弹飞行验证的综合校准此模型的方法。飞行试验表明此模型具有较高的置信度。     

单框架控制力矩陀螺系统的构形分析

根据构形效率、奇异面的复杂度等指标，针对成对安装和非成对对称安装的几种常见构形，进行了分析评价，认为正十二面体构形是系统运行中的一种较理想的构形，但就研究本身而言，金字塔构形的分析和研究具有一定的代表性，对其它构形的分析和操纵也具有一定的指导意义。     

End-to-end validation process for the INTA-Nanosat-1B Attitude Control System

This paper describes the end-to-end validation process for the Attitude Control Subsystem (ACS) of the satellite INTA-NanoSat-1B (NS-1B). This satellite was launched on July 2009 and it has been fully operative since then. The development of its ACS modules required an exhaustive integration and a system-level validation program. Some of the tests were centred on the validation of the drivers of sensors and actuators and were carried out over the flying model of the satellite. Others, more complex, constituted end-to-end tests where the concurrency of modules, the real-time control requirements and even the well-formedness of the telemetry data were verified. This work presents an incremental and highly automatised way for performing the ACS validation program based on two development suites and an end-to-end validation environment. The validation environment combines a Flat Satellite (FlatSat) configuration and a real-time emulator working in closed-loop. The FlatSat is built using the NS-1B Qualification Model (QM) hardware and it can run a complete version of the on-board software with the ACS modules fully integrated. The real-time emulator, running on an industrial PC, samples the actuation signals and emulates the sensors signals to close the control loop with the FlatSat. This validation environment constitutes a low-cost alternative to the classical three axes tilt table, with the advantage of being easily configured for working under specific orbit conditions, in accordance with any of the selected tests. The approach has been successfully applied to the NS-1B in order to verify different ACS modes under multiple orbit scenarios, providing an exhaustive coverage and reducing the risk of eventual errors during the satellite's lifetime. The strategy was applied also during the validation of the maintenance and reconfiguration procedures required once the satellite was launched. This paper describes in detail the complete ACS validation process that was performed and it shows the most relevant errors detected and fixed during testing. Finally it summarises some of the most significant conclusions.     

地球静止轨道自旋卫星姿态确定及控制策略

本文从工程应用的角度详尽地介绍了地球静止轨道自旋卫星姿态原理及确定方法,以我国在轨运行的风云二号卫星为例,给出了大量工程实测数据,并给出姿态控制实施策略,它们已经成功地运用到我国在轨自旋同步卫星的管理。