未来航空新兴技术概念内涵及识别方法

针对目前各种航空新兴技术识别方法纷繁复杂、层出不穷的现状,文中系统分析了以专家知识经验见长的定性识别方法,以科技期刊文献计量为主的客观定量识别方法,结合定性和定量多种方法组合识别的方法同时进行了对比分析,给出了各种方法的优点和缺点。系统梳理了兰德公司、DARPA,战略与国际研究中心(CSIS)、中国航空研究院(CAE)等国内外一些情报研究机构经常采用的资源组成、识别流程、识别方法、识别成果。最后提出了关于新兴航空技术识别方法的思考,期望对相关新兴技术研究起到一定的参考作用。     

关于军用航空认知战的顶层思考

军用航空认知战已成为现代战争的重要组成部分。随着科技的发展和战争形态的变化,认知战已经从传统战争策略中脱颖而出,成为一种具有重要战略意义的武器。旨在探讨军用航空认知战的概念内涵、基本原理、策略、技术,探讨了应对军用航空认知战的策略和措施,包括加强情报收集和分析、提高欺骗识别能力等。最后,总结了军用航空认知战的重要性和挑战性,并提出了未来研究和发展的建议和前景展望。     

多孔介质对圆柱-翼型干涉噪声的影响

采用LES（large eddy simulation）+FW-H（Ffowcs Williams-Hawkings）方程，研究了圆柱表面使用不同PPI（pore number per inch）和厚度的多孔介质对圆柱尾迹及圆柱-翼型干涉噪声的影响，探索了多孔介质的降噪规律和机理。结果表明：多孔介质能稳定圆柱表面的剪切层，抑制旋涡脱落，从而削弱尾迹对下游翼型的影响，圆柱单音噪声最大可降79 dB，翼型单音峰值降低13.22 dB，宽频噪声降低20 dB；多孔材料PPI的变化对降噪效果影响较小，而厚度是影响流场模态、降噪效果及气动性能的一个关键参数；多孔材料厚度合适时，圆柱-翼型流场形态为“剪切层模态”，可有效降低湍流干涉噪声；多孔材料厚度较小时，发现了一种流场形态，即“剪切层-尾迹模态”，导致翼型噪声增大；合适的多孔介质厚度不仅降噪效果显著，对圆柱-翼型的气动性能也有改善作用。     

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.