Optimal guidance based on receding horizon control for low-thrust transfer to libration point orbits

This paper addresses the design and computation of a guidance law for a transfer mission from an orbit near the Earth to a halo orbit around the libration point L₂ in the Sun–Earth system. The guidance law, which is designed based on receding horizon control and compensates for launch velocity errors that are introduced by inaccuracies of the launch vehicle, is solved using the generating function method. During the design of the closed-loop guidance law, the entire transfer mission, which is considered a nonlinear optimal control problem, is evaluated to obtain a nominal reference trajectory. Using the launch velocity errors and the uncertainty of the model, a spacecraft controlled by the proposed guidance law tracks the reference trajectory. Furthermore, the original Riccati differential equation in the receding horizon control algorithm is replaced by an equivalent convenient form of the Riccati differential equation that is based on the generating function. The high-efficiency solution of the equivalent equation avoids the online direct integration of the original Riccati differential equation, which significantly increases the computational efficiency for the receding horizon control problem. Numerical simulations using a nonlinear bicircular four-body model demonstrate the capabilities of the proposed receding horizon guidance law for the transfer mission. In addition, the generating function method improves the computational efficiency by at least one order of magnitude over the backward sweep method in solving the receding horizon control problem.     

Long term dynamics and optimal control of nano-satellite deorbit using a short electrodynamic tether

This paper studies the long term dynamics and optimal control of a nano-satellite deorbit by a short electrodynamic tether. The long term deorbit process is discretized into intervals and within each interval a two-phase optimal control law is proposed to achieve libration stability and fast deorbit simultaneously. The first-phase formulates an open-loop fast-deorbit control trajectory by a simplified model that assumes the slow-varying orbital elements of electrodynamic tethered system as constant and ignores perturbation forces other than the electrodynamic force. The second phase tracks the optimal trajectory derived in the first phase by a finite receding horizon control method while considering a full dynamic model of electrodynamic tether system. Both optimal control problems are solved by direct collocation method base on the Hermite–Simpson discretization schemes with coincident nodes. The resulting piecewise nonlinear programing problems in the sequential intervals reduces the problem size and improve the computational efficiency, which enable an on-orbit control application. Numerical results for deorbit control of a short electrodynamic tethered nano-satellite system in both equatorial and highly inclined orbits demonstrate the efficiency of the proposed control method. An optimal balance between the libration stability and a fast deorbit of satellite with minimum control efforts is achieved.     

空间电子对抗系统研究

在详细分析电子战具体内涵的演变和特点基础上,进而阐述了空间信息战的作战理论发展脉络,分析空间电子对抗技术装备状况和发展趋势,以空间态势感知、防御性空间对抗、进攻性空间对抗等三个方面的任务需求作为出发点,提出空间电子对抗系统建设方案、体系架构和关键技术。     

浅谈即兴讲话的技巧

论文根据笔者多年的实践,对即兴讲话的选题、构思、开场白、结尾、表达及训练的技巧进行了初浅探索。     

便携式相控阵探伤仪在复合材料检测中的应用

相控阵探伤仪能够通过图像的形式直观地显示缺陷,并通过线性B扫描图或扇形图显示一定区域范围内的缺陷,有利于对缺陷的评判.     

基于多传感器的裂纹扩展监测研究

疲劳裂纹扩展是结构健康监测的主要问题之一，为了保证金属结构的可靠和安全运行，实时监测结构的疲劳裂纹扩展过程十分必要。针对结构裂纹扩展的问题，采用压电传感器（PZT）和电阻应变片两种传感器，提出结合能够连续监测结构损伤的被动监测方法以及对微小损伤敏感的主动监测方法对裂纹扩展进行综合监测，以提高裂纹扩展的监测水平。采用随机森林算法对裂纹长度进行识别，并使用D-S证据理论对两种传感器的识别结果进行数据融合，得到比单一传感器更准确、可靠的裂纹扩展识别结果。进行了基于应变和主动Lamb波的裂纹扩展监测实验研究，验证了该方法对提高裂纹扩展监测识别准确率的有效性和实用性。     

Applied superconductivity and superfluidity for the exploration of the Moon and Mars.

We discuss how superconductivity and superfluidity can be applied to solve the challenges in the exploration of the Moon and Mars. High sensitivity instruments using phenomena of superconductivity and superfluidity can potentially make significant contributions to the fields of navigation, automation, habitation, and resource location. Using the quantum nature of superconductivity, lightweight and very sensitive diagnostic tools can be made to monitor the health of astronauts. Moreover, the Moon and Mars offer a unique environment for scientific exploration. We also discuss how powerful superconducting instruments may enable scientists to seek answers to several profound questions about nature. These answers will not only deepen our appreciation of the universe, they may also open the door to paradigm-shifting technologies.     

Review of uncertainty-based multidisciplinary design optimization methods for aerospace vehicles

This paper presents a comprehensive review of Uncertainty-Based Multidisciplinary Design Optimization (UMDO) theory and the state of the art in UMDO methods for aerospace vehicles. UMDO has been widely acknowledged as an advanced methodology to address competing objectives of aerospace vehicle design, such as performance, cost, reliability and robustness. However the major challenges of UMDO, namely the computational complexity and organizational complexity caused by both time-consuming disciplinary analysis models and UMDO algorithms, still greatly hamper its application in aerospace engineering. In recent years there is a surge of research in this field aiming at solving these problems. The purpose of this paper is to review these existing approaches systematically, highlight research challenges and opportunities, and help guide future efforts. Firstly, the UMDO theory preliminaries are introduced to clarify the basic UMDO concepts and mathematical formulations, as well as provide a panoramic view of the general UMDO solving process. Then following the UMDO solving process, research progress of each key step is separately surveyed and discussed, specifically including uncertainty modeling, uncertainty propagation and analysis, optimization under uncertainty, and UMDO procedure. Finally some conclusions are given, and future research trends and prospects are discussed.     

用于信道盲均衡的基于软判决导向的LS算法

本文提出两种改进的基于软判决导向的最小平方均衡法。一种采用横向结构，另一种采用格式结构。这两种均衡算法的判决误差形式不同于一般的判决误差形式，它们的表达式是一种更为复杂的连续函数形式。通过计算机仿真，我们发现，采用横向结构的这种改进算法无论对于最小相位还是非最小相位信道的均衡均有较好的性能，而采用格形结构的这种改进算法的性能在非最小相位信道下的性能反而不如传统的格形算法。     

基于小型三坐标测量机的机械研究

从三坐标测量机的实际设计出发,通过对小型三坐标测量机的机械分析和实验,对三坐标测量机的设计提供理论基础的分析和可行的思路。