冷却抑制二元收扩喷管红外特征的模型实验与数值研究

为研究二元收扩喷管排气系统的红外特征及其采取冷却措施后的红外抑制效果,设计了带有冷却结构的喷管实验模型,测量了3组实验状态下的喷管壁面温度和红外辐射强度分布,分析了喷管腔体内各部件的辐射贡献大小。研究结果表明:二元收扩喷管排气系统的积分辐射强度在0°方向上最大,并且随着角度的增大而减小;扩张板的壁面温度下降21.1%,侧壁的壁面温度下降26.6%,可使积分辐射强度降低11.5%~31.9%;在扩张段冷却的基础上,中心锥的壁面温度下降9%,可使积分辐射强度降低21.7%~38.9%。     

一种基于双模式成像的遥感图像去运动模糊方法

对地观测载荷大多工作在颤振环境之中,这种颤振造成光轴偏移、像面抖动,由此产生的运动模糊对高分辨率成像与高精度探测产生了极为不利的影响。对空间相机像面去模糊的工作,大致分为两种方案：一种为硬件实时探测加硬件实时补偿,另一种为硬件实时探测加事后软件补偿。文章提出通过主成像相机的双成像模式获得低信噪比无抖动图像和正常信噪比模糊图像,利用图像处理手段从这一对图像中求得抖动信息（模糊核）,并以此为先验知识指导模糊图像的复原,抑制像面抖动。这种方法既不需要补偿器件,也不需要探测元件和探测支路,并在图像迭代处理过程中不断修正模糊核,在初始模糊核有一定误差的情况下,同样可望取得良好的像面去模糊效果,对于遥感图像像质提高具有潜在的应用价值。     

空间相机匀速扫描干扰补偿控制方法

针对空间相机匀速扫描中的周期干扰,研究永磁同步电机(PMSM)抗扰控制问题.为了解决传统状态观测器与内模原理补偿方法形式复杂、计算量大的问题,结合敏感器测量输出和系统模型推导出干扰量,并在重构干扰的基础上,采用超前输入补偿策略快速抑制扰动影响.该方法形式简洁,计算量小,经数学仿真和试验验证,可有效抑制系统正弦扰动,改善...     

Numerical study of a trapezoidal bypass dual throat nozzle

Bypass Dual Throat Nozzle (BDTN) is a novel type of fluidic thrust vectoring nozzle. To improve the infrared stealth performance of BDTN, a nozzle based on BDTN is proposed and numerically simulated. Each cross-section along the x-axis of the novel nozzle becomes a trapezoid, which is named “BDTN-TRA.” The main numerical simulation results show that BDTN-TRA can produce a thrust vectoring angle when the upper or lower bypass valve is open. The angle difference between the two conditions mentioned above is usually approximately 1°–2°. Even if the two bypasses are closed, BDTN-TRA can produce a small thrust vectoring angle at around 3°–5°. When the sidewall angle increases from 60° to 90°, the thrust coefficient and thrust vectoring angle under each work condition usually decrease. A larger aspect ratio indicates better performance. As the aspect ratio increases over 7.2, the performance of BDTN-TRA is quite close to that of BDTN with rectangular cross-sections at the same aspect ratio. These features will benefit the control and trimming for future aircraft design, especially for the flying wing layout aircraft. Last but not least, BDTN-TRA has a more extraordinary mixing performance compared with BDTN. The distributions of static temperature and axial velocity along the x-axis of BDTN-TRA with sidewall angle of 60° decrease faster than those of BDTN. When the total temperature of the inlet equals 1600 K, the static temperature difference between BDTN-TRA with sidewall angles of 60° and 90° is over 360 K at twice the length of the nozzle downstream of the nozzle exit, which is the reflection for excellent infrared stealth for the fighter.     

基于飞行时间相机的非合作慢旋卫星稠密重建研究

针对非合作慢旋卫星的模型重建问题，提出基于飞行时间(time-of-flight, TOF)相机和同时定位与制图(simultaneous localization and mapping, SLAM)的稠密重建方法。基于预先检测与自适应阈值方法提高旋转提取与描述(oriented fast and rotated brief, ORB)的特征尺度适应性。利用运动度量方法选取关键帧。利用子模型拼接方法加快重建效率。利用仿真环境制作非合作慢旋卫星的数据集。仿真实验结果表明:该方法能够实现长时间稳定地工作，可在3 min内重建出卫星模型的稠密点云，点云密度大于5 000，重建误差小于5 cm。利用机械臂、卫星模型及光学暗室搭建半物理实验系统，表明算法的精度及抗噪声能力基本满足非合作目标感知的任务的需求。     

星载“偏振交火”传感器设计及初步在轨应用

针对近地表细颗粒物含量的卫星遥感精度问题，系统提出了“偏振交火”的卫星遥感策略和模型，开发了高精度偏振扫描仪(POSP)和多角度偏振成像仪(DPC)双偏振载荷套件，装载在大气环境监测卫星上并成功发射。本文在介绍“偏振交火”原理的基础上，系统论述了载荷工程的实现方法和在轨应用方法，初步展示和评估了在轨应用效果。在轨初步应用结果显示:双偏振载荷间能够实现稳定交火工作，视场匹配精度优于0.077 POSP像元;基于L1级数据初步开展了双偏振载荷间的辐射和偏振交叉定标/验证，共有波段拟合优度(R²)分别达到0.999和0.993;基于“偏振交火”载荷观测数据融合反演的近地表PM2.5与地基网络监测结果的相关性为0.684，偏差落在期望误差(EE)范围内的比例为88.36%。初步在轨结果达到了预期应用目标，显示了“偏振交火”方案在气溶胶污染监测方面的应用潜力。     

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.     

激光、红外隐身兼容涂料的前景分析

红外探测技术、激光探测技术、电子战等因素使得红外波段中的隐身技术变得更为重要。在同一波段范围同时达到红外与激光的隐身兼容是热平衡理论所面临的难题。要做到红外和激光的隐身兼容，就必须克服两者对材料的一对矛盾要求。在分别介绍了红外、激光隐身的原理后，提出了红外激光复合隐身的设想，并分析了两种央技术的互相制约及兼容的可能性。     

Selective thermal emission and infrared camouflage based on layered media

Infrared camouflage based on artificial thermal metasurfaces has recently attracted significant attention. By eliminating thermal radiation differences between the object and the background, it is possible to hide a given object from infrared detection. Infrared camouflage is an important element that increases the survivability of aircraft and missiles, by reducing target susceptibility to infrared guided threats. Herein, a simple and practicable design is theoretically presented based on a multilayer film for infrared stealth, with distinctive advantages of scalability, flexible fabrication, and structural simplicity. The multilayer medium consists of silicon substrate, carbon layer and zinc sulfide film, the optical properties of which are determined by transfer matrix method. By locally changing the thickness of the coating film, the spatial tunability and continuity in thermal emission are demonstrated. A continuous change of emissive power is further obtained and consequently implemented to achieve thermal camouflage functionality. In addition, other functionalities, like thermal illusion and thermal coding, are demonstrated by thickness-engineered multilayer films.