非对称变翼飞行器复合控制系统设计

针对非对称变翼飞行器的姿态控制问题，提出了一种复合控制系统的设计方法。基于非对称变翼的姿态动力学模型，将变翼作为一种主动控制方式，提出了非对称变翼的使用条件，并采用逻辑函数设计了气动舵和变翼的复合控制分配策略。利用扩张干扰观测器估计了变翼过程中的扰动，采用全局滑动模态的变结构控制方法，设计了姿态复合控制系统，抑制了变形过程中参数的剧烈变化和变形引起的附加扰动。通过仿真，一方面与固定翼飞行器对比，校验了非对称变翼控制的有效性；另一方面通过气动数据的正负拉偏，验证了控制器对气动参数的摄动有良好的鲁棒性。     

带攻角约束的高超声速飞行器自适应反步控制器设计

针对带攻角(AOA)约束的高超声速飞行器控制问题，提出一种基于非对称时变障碍函数的非线性自适应反步控制方法。首先，将飞行器模型化为严反馈形式，以反步法为基础进行控制器设计。然后通过光滑饱和函数对名义攻角指令信号进行限幅，并保证限幅信号的可导性，限幅产生的误差通过设计辅助系统进行补偿。进而使用障碍函数对攻角指令跟踪误差进行非对称时变约束。针对不确定性和干扰，设计新型自适应律对集中干扰上界进行估计并补偿。最终通过Lyapunov理论证明了闭环系统状态量一致最终有界并且攻角始终满足时变约束。仿真结果表明，本文方法能够在满足攻角约束基础上保证良好跟踪性能。     

Numerical investigation of the impact of asymmetric fuel injection on shock train characteristics

Numerical simulations are carried out to investigate the impact of asymmetric fuel injection on shock train characteristics using the commercial-code FLUENT. The asymmetry of fuel injection is examined by changing the fuel flow rates of the upper and lower wall fuel injectors. The numerical approach solves the two-dimensional Reynolds-averaged Navier–Stokes (RANS) equations, supplemented with a k-ω model of turbulence. As a result, different ways of fuel injections will always lead to shock train transitions, with the variations of shock train structure, strength and leading edge position. For symmetric fuel injection, the flowfield of the isolator is quite asymmetric with the boundary layer of the upper wall side developing much stronger than that of the lower wall, which is due to the heterogeneity of the incoming flow. Regarding to asymmetric fuel injection with more of lower wall side, though the pressures in the combustor are nearly the same, the first shock of the shock train converts between ‘Distinct symmetric X type shock’ and ‘Obscure and weaker asymmetric shock’ and the shock train leading edge moves upstream with the increase of the asymmetry level. With regard to asymmetric fuel injection with more of upper wall side, ‘incomplete asymmetric X type shock’ occurs and the shock train structures keep nearly the same with low level of fuel injection asymmetry. Unexpected results like unstart will happen when increasing the level of fuel injection asymmetry. And the isolator will come back to normal state by decreasing the differential of upper and lower wall sides fuel injections.     

一种适用于地球空间传感器网络的TCP Vegas模型

针对地球空间传感器网络中由正反向链路带宽不对称引起的正向链路吞吐量下降问题，提出一种基于时延且能够维持反向链路确认频率的拥塞控制模型。该模型基于反向链路中确认分组的排队时延，在反向链路发生拥塞时，降低确认分组的发送频率，以缓解反向链路的拥塞程度；而在反向链路没有发生拥塞时，加快确认分组的发送频率，以提高正向链路中数据分组的吞吐量。同时，该模型将确认分组的延迟发送时间追加到最小往返时延中，提高了最小往返时延的准确程度，从而提升模型的正向链路拥塞控制效果。仿真试验结果表明，该模型可以有效地解决由于反向链路拥塞所造成的正向链路吞吐量低的问题。     

对“小不对称物体配平性能风洞实验研究”一文的异议

原文所述的实验方法和所列的结果都是正确的,但文中所写的数学方程和公式是不当的,本文对此提出了异议,供商榷。     

一种非对称PCMA信号盲分离算法

针对卫星通信中非对称成对载波多址(PCMA)信号的盲分离问题，提出一种基于同步挤压小波变换(SWT)的盲分离算法。该算法在混合多个信号前提下，首先按强信号进行同步，接着采用同步挤压小波变换提取时频曲线，最后去除混合信号中的噪声与强信号主频外的弱信号干扰，降低了强信号解调误码率。该算法具有在不具备协作通信方发送的信息序列的先验条件下，实现了非对称PCMA信号盲分离的特点。仿真结果表明，经本文算法处理后强信号解调误码性能比对混合信号直接硬判决时有较大提升。     

基于多天线中继的卫星-地面混合无线通信系统上行链路性能分析

研究了Rayleigh Rician非对称衰落信道下,以基站作为固定增益放大转发(AF)中继的卫星-地面混合无线通信系统上行链路性能。首先利用信道状态信息(CSI)得到中继配置多天线时系统的最大输出等效信噪比(SNR)。基于特殊函数推导出系统中断概率(OP)和概率密度函数(PDF)的解析表达式,并进一步得到各种调制方式下系统平均误符号率(ASER)的理论计算公式。最后通过无穷级数展开推导出高信噪比时平均误符号率的渐近闭合表达式,分析系统能获得的分集增益和阵列增益。计算机仿真表明所提出的性能分析方法的正确性,分析了天线数量和信道参数对卫星-地面混合无线通信系统性能的影响,为实际系统设计提供了参考和依据。     

An experimental investigation on static directional stability

A generic aircraft usually loses its static directional stability at moderate angle of attack (typically 20–30?). In this research, wind tunnel studies were performed using an aircraft model with moderate swept wing and a conventional vertical tail. The purpose of this study was to investigate flow mechanisms responsible for static directional stability. Measurements of force, surface pressure and spatial flow field were carried out for angles of attack from 0? to 46? and sideslip angles from ?8? to 8?. Results of the wind tunnel experiments show that the vertical tail is the main contributor to static directional stability, while the fuselage is the main contributor to static directional instabil-ity of the model. In the sideslip attitude for moderate angles of attack, the fuselage vortex and the wing vortex merged together and changed asymmetrically as angle of attack increased on the wind-ward side and leeward side of the vertical tail. The separated asymmetrical vortex flow around the vertical tail is the main reason for reduction in the static directional stability. Compared with the wing vortices, the fuselage vortices are more concentrated and closer to the vertical tail, so the yaw-ing moment of vertical tail is more unstable than that when the wings are absent. On the other hand, the attached asymmetrical flow over the fuselage in sideslip leads to the static directional instability of the fuselage being exacerbated. It is mainly due to the predominant model contour blockage effect on the windward side flow over the model in sideslip, which is strongly affected by angle of attack.     

Relationship of the diffuse aurora and SAR arc dynamics to substorms and storms

Investigation results of a diffuse aurora (DA) and stable auroral red (SAR) arc dynamics based on spectrophotometric observations at the Yakutsk meridian (199°E geomagnetic longitude) are presented. The relationship of an equatorward extension of DA in the 557.7 nm emission to a substorm growth phase during the magnetospheric convection intensification after the turn of IMF B_Z to the south is shown. The formation of SAR arc during the substorm expansion phase is investigated. The association of SAR arc dynamics with the development of asymmetric ring current (substorm injection) during the main phase of a storm is analyzed. It is shown how the pulsating precipitations of energetic ring current particles develop in the outer plasmasphere based on photometric observations.     

Simulation of asymmetric landing and typical ground maneuvers for large transport aircraft

It is important to determine static and dynamic ground loads for the aircraft ground maneuvers accurately in the design phase. Simulation of the important operational cases is a better way compared to the tests on real aircraft to investigate these loads at a reasonable cost. In this paper, the simulation of an asymmetric landing case and typical ground maneuvers for large transport aircraft is presented. The aircraft models are built in the multibody simulation tool SIMPACK. The tire model implemented in SIMPACK includes lateral dynamics of the tire. Cornering, braked runs and pushback are simulated as typical ground maneuvers. For simulation of braking, a simple but effective Antilock Braking System (ABS) algorithm is implemented. The article is based on the work done in cooperation between DLR and Airbus in the Flexible Aircraft 2 project.