Preparation of the Biochip experiment on the EXPOSE-R2 mission outside the International Space Station

Biochips might be suited for planetary exploration. Indeed, they present great potential for the search for biomarkers – molecules that are the sign of past or present life in space – thanks to their size (miniaturized devices) and sensitivity. Their detection principle is based on the recognition of a target molecule by affinity receptors fixed on a solid surface. Consequently, one of the main concerns when developing such a system is the behavior of the biological receptors in a space environment. In this paper, we describe the preparation of an experiment planned to be part of the EXPOSE-R2 mission, which will be conducted on the EXPOSE-R facility, outside the International Space Station (ISS), in order to study the resistance of biochip models to space constraints (especially cosmic radiation and thermal cycling). This experiment overcomes the limits of ground tests which do not reproduce exactly the space parameters. Indeed, contrary to ground experiments where constraints are applied individually and in a limited time, the biochip models on the ISS will be exposed to cumulated constraints during several months. Finally, this ISS experiment is a necessary step towards planetary exploration as it will help assessing whether a biochip can be used for future exploration missions.     

多导弹齐射攻击协同制导(英文)

Cooperative guidance problems of multiple missiles are considered in this article. A cooperative guidance scheme, where coordination algorithms and local guidance laws are combined together, is proposed. This scheme actually builds up a hierarchical cooperative guidance architecture, which may provide a general solution to the multimissile cooperative guidance problems. In the case of salvo attacks which require missiles to hit the target simultaneously, both centralized and distributed coordination algorithms are derived based on the impact-time-control guidance （ITCG） law. Numerical simulations are performed to demonstrate the effectiveness of the proposed approaches.     

A review of topology optimization for additive manufacturing: Status and challenges

Topology optimization was developed as an advanced structural design methodology to generate innovative lightweight and high-performance configurations that are difficult to obtain with conventional ideas. Additive manufacturing is an advanced manufacturing technique building as-designed structures via layer-by-layer joining material, providing an alternative pattern for complex components. The integration of topology optimization and additive manufacturing can make the most of their advantages and potentials, and has wide application prospects in modern manufacturing. This article reviews the main content and applications of the research on the integration of topology optimization and additive manufacturing in recent years, including multi-scale or hierarchical structural optimization design and topology optimization considering additive manufacturing constraints. Meanwhile, some challenges of structural design approaches for additive manufacturing are discussed, such as the performance characterization and scale effects of additively manufactured lattice structures, the anisotropy and fatigue performance of additively manufactured material, and additively manufactured functionally graded material issues, etc. It is shown that in the research of topology optimization for additive manufacturing, the integration of material, structure, process and performance is important to pursue high-performance, multi-functional and lightweight production. This article provides a reference for further related research and aerospace applications.     

最小数据丢失量的地月中继卫星任务调度研究

月球背面的探测器必须依靠地月中继卫星进行数据传输与通信。地月中继任务包括实时性任务和延迟容忍类任务,如数传任务。当探测器等待传输的数据量超出用户存储容量时,延迟容忍类任务会由于探测器本地存储资源不足和地月中继卫星天线资源受限而无法完成,导致任务数据丢失,所以需要设计一种合理的地月中继任务调度策略,提高地月中继卫星的资源利用率,减少数据的丢失。对地月中继卫星任务调度进行了研究,在分析地月中继卫星数传任务的特点及用户的存储限制的基础上,以最小化数据丢失量为优化目标,建立了地月中继卫星任务调度模型,并设计了一种基于离散烟花算法（DFWA）的地月中继卫星任务调度算法。仿真数据分析表明,基于离散烟花算法的地月中继卫星任务调度算法在求解结果上优于遗传算法,是一种合理、有效的调度方法。     

基于模因算法的飞机装配序列规划

针对飞机制造的装配序列规划问题,提出一种基于模因算法的飞机部件装配序列规划方法。在装配优先约束矩阵和非正交干涉矩阵的基础上构建装配规划模型,以飞机零部件间的装配方向和装配工具的差异性来构建适应度函数。在非干涉解空间中进行全局搜索,获得较优的装配规划方案,通过二叉树中序遍历法将较优的方案转化为可行解,再经过交叉操作和变异操作后,在可行解空间内进行局部搜索,最终获取较优的装配方案。以某型号的飞机舱门装配为例,通过与传统遗传算法对比,证实模因算法在飞机装配序列规划中的可行性和有效性。     

基于高斯伪谱法的翼伞系统复杂多约束轨迹规划

翼伞系统在实际环境中飞行时易受到风场以及地形环境等复杂干扰的影响,无法精确归航,控制难度较大。针对该问题,提出了一种针对复杂多约束条件的翼伞系统的最优控制轨迹规划方法,可同时实现翼伞系统在复杂环境下逆风对准、精确着陆以及控制量全局最优的控制目标。首先,建立了风场干扰下的翼伞系统模型;然后,通过引入地形环境曲面,将复杂环境转化为实时路径约束,将轨迹着陆偏差以及逆风雀降转化为终端约束,并考虑控制量消耗最小为目标函数,以此将复杂环境下的翼伞系统的轨迹优化转化为一系列非线性的带有复杂约束的最优控制问题;最后,采用高斯伪谱法将多约束最优控制问题转化为易于求解的非线性规划问题。通过设立3组复杂环境仿真实例和实验验证,表明本文方法使翼伞系统在多种较恶劣的复杂环境中有效应对多类约束条件,规划出控制量全局最优的可行轨迹。与已有的混沌粒子群优化算法相比,本文方法具有较好的最优性和较高的精度。     

基于粒子群算法的多波位高度估计方法

为解决雷达斜视模式下对目标区域的高度估计问题,提出了一种基于粒子群算法的多波位高度估计方法。利用粒子群优化算法建立约束条件和目标函数,通过多次迭代使目标函数趋于一个最优值,同时得到高度的最优解。利用粒子群优化算法求解多波位测高方程组可减小方程组近似处理误差。此外,利用粒子群优化算法可随时更改波位数目,增强了该测高方法使用的灵活性,有效提高了高度估计精度。通过理论仿真和实测数据仿真分析,验证了粒子群优化算法在求解多波位测高方程组时的有效性。结果表明:该方法具有较高的高度估计精度。     

再入轨迹多约束模型预测静态凸规划方法

针对大升阻比可重复使用飞行器再入滑翔轨迹规划问题,提出了一种基于自适应分段Chebychev伪谱离散的多约束模型预测静态凸规划算法(P-CMPCP),实现了全量终端状态约束及多过程约束作用下再入轨迹的高精度迭代解算。考虑倾侧角翻转导致控制量不连续,传统规划方法难以同时严格满足终端位置、角度约束,且过程约束易超限,采用自适应分段伪谱离散策略,构建全程飞行状态及过程性能指标约束对各配点处控制调整量的敏感度关系,从而将非线性最优控制问题转化为静态凸规划问题,并利用内点法对各分段控制量进行了协调优化。本文所提方法无需对动力学模型进行简化或近似处理,即能以少量积分运算使轨迹满足再入全量模型约束,且控制量平滑,数值精度优于传统规划方法。     

多约束条件下的制导律研究综述

随着导弹等制导武器机动能力的增强,制导精度的提高,多约束条件下的制导律研究成为精确制导研究的新热点。简要介绍了多约束条件下的制导问题,重点评述了近年来多约束条件下的制导律研究情况,对目前多约束条件下的制导律设计进行了比较详细的研究,系统分析了各种方法的优缺点,并分析了其可能的研究内容动态和方向,为精确制导技术的发展提供了参考和借鉴。     

Footprint Problem with Angle of Attack Optimization for High Lifting Reentry Vehicle

A formal analysis to footprint problem with effects of angle of attack (AOA) is presented. First a flexible and rapid standardized method for footprint generation is developed. Zero bank angle control strategy and the maximum crossrange method are used to obtain virtual target set; afterward, closed-loop bank angle guidance law is used to find footprint by solving closest approach problem for each element in virtual target set. Then based on quasi-equilibrium glide condition, the typical inequality reentry trajectory constraints are converted to angle of attack lower boundary constraint. Constrained by the lower boundary, an original and practical angle of attack parametric method is proposed. By using parametric angle of attack profile, optimization algorithm for angle of attack is designed and the impact of angle of attack to footprint is discussed. Simulations with different angle of attack profiles are presented to demonstrate the performance of the proposed footprint solution method and validity of optimal algorithm.