空间飞行器控制软件的动态自适应演化方法

空间飞行器在太空飞行过程中需要满足多任务、多工作模式以及大范围机动的需求,其控制系统在大范围机动飞行条件下存在大量的外界干扰和内部参数不确定,同时飞行器的自适应过程受限于资源,人工干预难度大,并且现有的成熟的动态自适应方法并不一定适合空间飞行器控制软件进行自主控制,所以目前对自主控制系统软件的动态自适应调整方法提出了更...     

Reliability assessment of engine electronic controllers based on Bayesian deep learning and cloud computing

The reliability of an Engine Electronic Controller (EEC) attracts attention, which has a critical impact on aircraft engine safety. Reliability assessment is an important part of the design phase. However, the complex composition of EEC and the characteristic of the Phased-Mission System (PMS) lead to the difficulty of assessment. This paper puts forward an advanced approach, considering the complex products and uncertain mission profiles to evaluate the Mean Time Between Failures (MTBF) in the design phase. The failure mechanisms of complex components are deduced by Bayesian Deep Learning (BDL) intelligent algorithm. And copious samples of reliability simulation are solved by cloud computing technology. Based on the result of BDL and cloud computing, simulations are conducted with the Physics of Failure (PoF) theory and Failure Behavior Model (FBM). This reliability assessment approach can evaluate MTBF of electronic products without reference to physical tests. Finally, an EEC is applied to verify the effectiveness and accuracy of the method.     

基于在线学习RBF神经网络的故障预报

提出了一种基于在线学习神经网络的故障预报方法.该方法在网络设计过程中结合了"添加"准则和基于对网络输出贡献相对较小的"剪枝"准则."添加"过程中利用隐层的最大输出判断神经元的活跃性;"剪枝"过程中加入了滑动窗口,避免了误"剪枝".同时,调整过程只对输出响应比较大的神经元进行,大大减少了计算量,提高了实时性.仿真结果表明,利用该算法能够对一类带时变参数的非线性系统进行故障预报.     

Aircraft Requirement Verification Method Based on RequirementsVerification and Traceability Matrix(RVTM)

需求验证的目的是确定每一层级的需求都被系统很好地满足,是需求开发的重要一环。通过设计一种可追溯验证矩阵:需求验证和可追湖矩阵(RVTM),实现各层级需求在研制各阶段的针对性验证,明确各层级需求之间的关系,提高需求验证的准确性和完整性。采用调研国内外先进需求验证方式,结合工程实践总结的方法,定义需求验证节点,设计一系列需求验证方法及相应证据,定义需求验证原则及需求验证流程,完成对-种 RVTM 的设计,为未来飞机需求开发提供有力支撑。     

基于改进SSD算法的航拍目标检测算法研究

研究基于深度学习技术的无人机航拍图像目标检测算法,首先介绍目标检测算法SSD(Single Shot MultiBox Detector),并对其特征提取网络进行改进,采用稠密特征提取网络替换原网络的主干特征提取网络,提高算法的特征提取能力,从而提升了算法的检测精度。针对网络实时性问题,在算法中引入分组卷积,极大地减少了网络参数量,提升了网络推理速度。为解决训练中出现的正负样本不均衡问题,利用焦点损失（Focal Loss）改进了原算法的损失函数,进一步提升了网络的收敛速度和精度。最后,通过仿真验证了改进算法在目标检测精度上的优越性。     

行星软着陆GPS有模型强化学习制导方法

由于距离地球较远、测控延时误差较大、飞行环境十分复杂且难以提前预测，行星软着陆的自主制导技术目前存在水平位置估计困难、导航参考信息匮乏、复杂地形着陆困难等挑战。针对行星软着陆存在的困难和挑战，提出了基于引导策略搜索算法的有模型强化学习制导方法，实现了着陆器在初始状态受到扰动时，无需重新规划，仍能在满足约束条件的情况下降落在指定位置。该方法将迭代线性二次调节器作为控制器，产生初始轨迹；其次，使用多层神经网络拟合制导策略；最后，利用控制器监督策略学习，进而收敛产生可行策略。针对行星表面软着陆的仿真验证结果显示该算法仅通过几次循环，即可以实现初始状态变化的快速软着陆。一方面表明了基于有模型强化学习的数据高效利用率，另一方面也证明了强化学习方法在深空探测领域中具有广阔的应用前景。     

基于PCA-MPSO-ELM的空战目标威胁评估

目标威胁评估是空战对抗过程中的关键环节。由于影响空战目标威胁评估的因素复杂多样，且指标之间存在相关性，导致传统的评估算法无法得到准确客观的评估结果。由此，提出了一种基于主成分分析法和改进粒子群算法优化的极限学习机（PCA-MPSO-ELM）的目标威胁评估算法。首先，综合分析了影响目标威胁程度的指标，利用主成分分析法对原始评估指标进行线性变化处理得到综合变量，消除了评估指标之间的相关性，实现了对评估数据的降维；在此基础上，构建ELM神经网络并利用改进的粒子群算法优化极限学习机的输入权值和阈值，提高了目标威胁评估模型的精度。最后，在空战训练测量仪中选取空战对抗数据，利用威胁指数法构造了目标威胁评估样本数据，通过仿真实验分析了PCA-MPSO-ELM算法的精度和实时性，结果表明所提算法可以快速准确地进行空战目标威胁评估。     

自主空战技术中的机动决策:进展与展望

自主空战（AAC）是指飞机依靠机载等相关设备，自主进行战场感知、决策及控制，以执飞空战的技术，其核心是机动决策模块。针对该模块的研究，调研了国内外的现有方法，并按照有关方法的核心内涵，将其分为基于数学求解、机器搜索、以及数据驱动3类分别简要概述；针对每一类方法列出了具有代表性的示例技术，并讨论了其优缺点。指出了自主空战决策的研究应立足现有相关方法及技术基础，同时积极吸纳机器学习、人工智能等新兴技术，合理利用各类方法的优点，取长补短，实现自主空战决策的长足发展；有关于该研究设想的关键科学问题及其潜在解决方案也在文中进行了初步讨论。希冀基于针对自主空战决策研究框架及实现方法的概念性讨论，促进其技术发展，推广相关思路在有关国家安全、国民经济建设等领域的应用，以满足国家重大需求和工程实践。     

Heading south with a north-up map: A choice processing analysis of map alignment effects

This study employed an information accumulation model of choice reaction times to investigate alignment effects in mental representations of maps. University students studied a map from a single orientation (with north at the top). In a subsequent two-choice reaction time task, the students’ spatial knowledge of the map was assessed employing spatial left/right judgments, which were made from imagined perspectives that were either north-aligned or south-aligned. Data showed a standard alignment effect, favoring north- over south-aligned trials. To examine the locus of this effect, data were fit using the Linear Ballistic Accumulator (LBA) model of speeded decisions (Brown & Heathcote, 2008). Of interest were three model parameters: drift rate, the speed at which evidence accumulates toward a response; response threshold, the amount of evidence demanded from the decision maker before selecting a response; and non-decision time, the time consumed by pre- and postdecisional processes. The best-fitting model suggested that non-decision time accounted for the alignment effect. The difference in non-decision time between north and south-aligned judgments suggests a mental alignment stage on south-aligned trials, accounting for the longer reaction times for judgements misaligned with the presented north orientation of the map.     

Multi-block SSD based on small object detection for UAV railway scene surveillance

A method of multi-block Single Shot MultiBox Detector (SSD) based on small object detection is proposed to the railway scene of unmanned aerial vehicle surveillance. To address the limitation of small object detection, a multi-block SSD mechanism, which consists of three steps, is designed. First, the original input images are segmented into several overlapped patches. Second, each patch is separately fed into an SSD to detect the objects. Third, the patches are merged together through two stages. In the first stage, the truncated object of the sub-layer detection result is spliced. In the second stage, a sub-layer suppression and filtering algorithm applying the concept of non-maximum suppression is utilized to remove the overlapped boxes of sub-layers. The boxes that are not detected in the main-layer are retained. In addition, no sufficient labeled training samples of railway circumstance are available, thereby hindering the deployment of SSD. A two-stage training strategy leveraging to transfer learning is adopted to solve this issue. The deep learning model is preliminarily trained using labeled data of numerous auxiliaries, and then it is refined using only a few samples of railway scene. A railway spot in China, which is easily damaged by landslides, is investigated as a case study. Experimental results show that the proposed multi-block SSD method produces an overall accuracy of 96.6% and obtains an improvement of up to 9.2% compared with the traditional SSD.