月表陨坑检测轻量化深度学习方法

针对目前基于深度学习的陨坑检测方法存在的模型参数量大和检测速度慢的问题，提出了一种轻量化的深度学习陨坑检测方法。首先，采用通道剪枝方法删减卷积神经网络中冗余的卷积核，得到结构紧凑高效的陨坑检测模型。然后，使用轻量化的深度可分离卷积操作替换基础陨坑检测模型中的标准卷积操作，进一步降低了模型的复杂度。仿真实验结果表明，所提出的轻量化陨坑检测模型能够保证较高的像素预测精度，并且能够适应亮度、图像噪声等干扰因素的影响。同时，与轻量化处理前的模型相比，参数量减少了99.2%，检测速度提升了94%。     

基于自适应预测校正的月球软着陆制导控制方法

应用自适应预测制导方法，研究月球软着陆过程中的制导控制问题。作为一种具有逻辑结构的构造性方法，本文概述了自适应预测制导方法的实现步骤。针对月球软着陆过程中制导控制量少于被控制量这一“欠驱动”问题，在已有的基于一阶特征模型的全系数自适应预测校正方法的基础上，将输入输出相等的系统拓展为输入少于输出的“欠驱动”系统，以满足对位置、速度矢量同时进行制导控制的需要。本文针对初始状态误差、推力偏差、质量偏差以及比冲偏差下的软着陆过程，进行了Monte Carlo仿真分析，结果表明，自适应预测制导方法可有效用于月球软着陆过程的制导控制，且具有较高的精度和较强的鲁棒性。     

某大型飞机后缘襟翼气动/机构综合优化设计

大型飞机增升装置的研制不仅需要其提供足够的气动性能,也需要对噪声、舒适性等进行综合考量设计,而增升装置是提高大型飞机综合性能的重要系统,也是目前技术发展亟待研究和解决的重要问题。对于增升装置机构设计,通过设计较为简单的铰链襟翼机构来引导襟翼达到较优位置,然后选择气动性能较好的位置作为新的优化位置,求得较优机构位置。机构位置改变结合气动性能验证需要进行大量的迭代计算以及结果优化,因此以机构设计为基础,探究多目标优化计算的新方法,最终实现气动结构一体化设计目标。选用铰链式后缘襟翼为研究对象,综合考量后缘襟翼旋转与扰流板下偏联合运动对于气动性能影响,利用所研究方法,对其进行气动机构一体化设计并得出设计结果。     

Pneumatic pressure control based on improved NMPC and its application to aeroengine surge simulation

In the semi-physical simulation of aeroengines, using the pneumatic pressure servo control technology to provide realistic pneumatic excitation to the sensors and electronic controller can improve the confidence of the simulation and reduce the test cost and risk. However, the existing methods could not satisfy the precise simulation of large-amplitude and high-frequency pulsating pressure during aeroengine surge. In this paper, a pneumatic pressure control system with asymmetric groups of the High-Speed on–off Valve (HSV) is designed, and an Improved Nonlinear Model Predictive Control (INMPC) method is proposed. First, the volumetric flow characteristics of HSV are tested and analyzed with Pulse Width Modulation (PWM) signal input. Then, a simplified HSV model with the volume flow characteristic correction is developed. Based on these, an integrated model for the whole system is further established and used as the prediction model in INMPC. To improve the computational speed of the rolling optimization process, the mapping scheme from control signal to PWM duty cycle of HSVs and the objective function with exterior penalty function are designed. Finally, the random step, sinusoidal and real engine surge data are set as the reference pressure in multiple comparative experiments to verify the effectiveness of the pressure tracking system.     

MC-LRF based pose measurement system for shipborne aircraft automatic landing

Due to the portability and anti-interference ability, vision-based shipborne aircraft automatic landing systems have attracted the attention of researchers. In this paper, a Monocular Camera and Laser Range Finder (MC-LRF)-based pose measurement system is designed for shipborne aircraft automatic landing. First, the system represents the target ship using a set of sparse landmarks, and a two-stage model is adopted to detect landmarks on the target ship. The rough 6D pose is measured by solving a Perspective-n-Point problem. Then, once the rough pose is measured, a region-based pose refinement is used to continuously track the 6D pose in the subsequent image sequences. To address the low accuracy of monocular pose measurement in the depth direction, the designed system adopts a laser range finder to obtain an accurate range value. The measured rough pose is iteratively optimized using the accurate range measurement. Experimental results on synthetic and real images show that the system achieves robust and precise pose measurement of the target ship during automatic landing. The measurement means error is within 0.4° in rotation, and 0.2% in translation, meeting the requirements for automatic fixed-wing aircraft landing.Received 5 July 2022; revised 19 August 2022; accepted 27 September 2022.     

面向视觉着陆的高精度结构化约束特征点研究

为提高视觉着陆过程中无人机的相对定位精度,选取视觉图像中的直线交点作为结构化约束特征点,设计了基于梯度一致性的边缘检测算法,并结合Shi-Tomasi角点检测算法进行结构化约束特征点的粗定位。对LSD直线检测算法进行改进并设计了亚像素角点定位精度改进算法,在结构化约束特征点粗定位的基础上,将其精度提高到亚像素级。基于实际场景中固有约束的结构化约束特征点具有鲁棒性、旋转和尺度不变性,抗干扰能力更强,其高精度定位有利于提高视觉着陆相对定位的精度与可靠性。     

民用飞机吊挂应急断离设计研究

应急断离设计是民用飞机吊挂设计的关键技术之一,从收集到的相关机型应急着陆事故论述吊挂应急断离设计的结构设计要求,分析波音公司和麦道公司的典型机型吊挂设计方案,提出了我国大型民用飞机吊挂应急断离设计方案的建议。     

Performance analysis of the vectorized high order expansions method in the accurate landing problem of reusable boosters

This paper addresses the design of the terminal phase maneuver of the booster landing in the presence of initial deviations and uncertainties. The primary purpose of this study is to evaluate the effectiveness of the vectorized high order expansions method to extract commands and near-optimal trajectory, while the accurate satisfaction of the terminal conditions is of great importance. After reviewing high order expansions methods, the Vectorized High Order Expansions method is briefly discussed. Then, the solution for the booster landing problem is extracted up to the third order. To study the solution quality in the presence of uncertainties, mass, density, and gravity are assumed to be constant in extracting the 3rd order solution. The assumptions however are eliminated in the simulations, and the effectiveness of high order expansions solution is studied subjectively and numerically in the presence of initial deviations and uncertainties. After implementing simulations and considering different assumptions, it will be shown that the 3rd order solution holds a desirable quality in accurately satisfying final conditions in presence of uncertainties and initial deviations and provides far better results than the 1st order solution. Moreover, in this paper, a novel method is proposed for online updating, and the performance and effect of this modification are studied using simulations. Reviewing the results of the 3rd order solution combined with the online update strategy, it becomes clear that the implementation of the online update significantly reduces landing point errors and improves the performance of the high order method. Furthermore, the study compares the performance of this strategy with the well-known state-dependent Riccati equation method to better evaluate the effectiveness of the proposed approach.     

地外天体着陆巡视探测自主智能技术进展

以月球、火星和小行星等地外天体着陆巡视探测任务为背景，对自主智能技术的发展现状、应用情况与未来趋势进行了分析研究。回顾了目前国内外地外天体着陆巡视探测任务的实施情况；从导航定位与环境感知、轨迹优化与制导控制、自主探测与路径规划、故障诊断与自主处理等四个方面，阐述了该领域自主智能技术的研究现状，并对未来发展态势进行了展望。     

飞翼布局无人机着舰飞行动力学分析

飞翼布局无人机具有独特的气动特性,研究飞翼布局无人机着舰飞行动力学特性对设计无人机着舰控制律具有重要意义。针对飞翼布局无人机着舰下滑飞行过程,建立六自由度飞行动力学模型,并通过对着舰飞行轨迹稳定性的分析,根据飞行品质对飞行轨迹稳定性的约束,计算达到一级飞行品质要求的着舰飞行速度。通过配平计算和小扰动线性化处理,得到无人机着舰下滑运动线性模型,并分析无人机纵向和横航向的固有模态特性。结果表明,飞翼无人机着舰下滑过程中,纵向的长、短周期模态及横航向的滚转和螺旋模态收敛但收敛慢,荷兰滚模态发散。