Carrier phase prediction method for GNSS precise positioning in challenging environment

Since the signals of global navigation satellite system (GNSS) are blocked frequently in challenging environments, the discontinuous carrier phases seriously affect the application of GNSS precise positioning. To improve the carrier phase continuity, this paper proposes a carrier phase prediction method based on carrier open-loop tracking. In the open-loop tracking mode, the carrier numerically controlled oscillator (NCO) is controlled by the predicted Doppler, but not by the loop filter output. To improve the phase prediction effective time, accurate receiver clock drift estimation is studied in the prediction method. The phase prediction performance is tested on GNSS software receiver. In the phase prediction effective time tests, open-loop processes were set for the tested channel. The test results show that, when some satellite signals are blocked in 15?s, the probability of carrier phase error less than quarter cycles is more than 94%. In the real time kinematic (RTK) positioning tests, some satellite signals are blocked in 10–15?s repeatedly. The test results show that, the carrier phase continuity is basically not affected by the signal interruption, and the RTK can almost keep continuous centimeter-level positioning accuracy without re-fixing the integer ambiguity.     

Orbit determination and prediction of GEO satellite of BeiDou during repositioning maneuver

In order to establish a continuous GEO satellite orbit during repositioning maneuvers, a suitable maneuver force model has been established associated with an optimal orbit determination method and strategy. A continuous increasing acceleration is established by constructing a constant force that is equivalent to the pulse force, with the mass of the satellite decreasing throughout maneuver. This acceleration can be added to other accelerations, such as solar radiation, to obtain the continuous acceleration of the satellite. The orbit determination method and strategy are illuminated, with subsequent assessment of the orbit being determined and predicted accordingly. The orbit of the GEO satellite during repositioning maneuver can be determined and predicted by using C-Band pseudo-range observations of the BeiDou GEO satellite with COSPAR ID 2010-001A in 2011 and 2012. The results indicate that observations before maneuver do affect orbit determination and prediction, and should therefore be selected appropriately. A more precise orbit and prediction can be obtained compared to common short arc methods when observations starting 1 day prior the maneuver and 2 h after the maneuver are adopted in POD (Precise Orbit Determination). The achieved URE (User Range Error) under non-consideration of satellite clock errors is better than 2 m within the first 2 h after maneuver, and less than 3 m for further 2 h of orbit prediction.     

Generalized Kutta–Joukowski theorem for multi-vortex and multi-airfoil flow with vortex production——A general model

By using a special momentum approach and with the help of interchange between singularity velocity and induced flow velocity, we derive in a physical way explicit force formulas for twodimensional inviscid flow involving multiple bound and free vortices, multiple airfoils, and vortex production. These force formulas hold individually for each airfoil thus allowing for force decomposition, and the contributions to forces from singularities(such as bound and image vortices,sources, and doublets) and bodies out of an airfoil are related to their induced velocities at the locations of singularities inside this airfoil. The force contribution due to vortex production is related to the vortex production rate and the distance between each pair of vortices in production, thus frameindependent. The formulas are validated against a number of standard problems. These force formulas, which generalize the classic Kutta–Joukowski theorem(for a single bound vortex) and the recent generalized Lagally theorem(for problems without a bound vortex and vortex production) to more general cases, can be used to identify or understand the roles of outside vortices and bodies on the forces of the actual body, optimize arrangement of outside vortices and bodies for force enhancement or reduction, and derive analytical force formulas once the flow field is given or known.     

Numerical analysis and optimization of boundary layer suction on airfoils

Numerical approach of hybrid laminar flow control(HLFC) is investigated for the suction hole with a width between 0.5 mm and 7 mm. The accuracy of Menter and Langtry’s transition model applied for simulating the flow with boundary layer suction is validated. The experiment data are compared with the computational results. The solutions show that this transition model can predict the transition position with suction control accurately. A well designed laminar airfoil is selected in the present research. For suction control with a single hole, the physical mechanism of suction control, including the impact of suction coefficient and the width and position of the suction hole on control results, is analyzed. The single hole simulation results indicate that it is favorable for transition delay and drag reduction to increase the suction coefficient and set the hole position closer to the trailing edge properly. The modified radial basis function(RBF) neural network and the modified differential evolution algorithm are used to optimize the design for suction control with three holes. The design variables are suction coefficient, hole width, hole position and hole spacing. The optimization target is to obtain the minimum drag coefficient. After optimization,the transition delay can be up to 17% and the aerodynamic drag coefficient can decrease by 12.1%.     

Specific grinding energy and surface roughness of nanoparticle jet minimum quantity lubrication in grinding

Nanoparticles with the anti-wear and friction reducing features were applied as cooling lubricant in the grinding fluid. Dry grinding, flood grinding, minimal quantity of lubrication（MQL）, and nanoparticle jet MQL were used in the grinding experiments. The specific grinding energy of dry grinding, flood grinding and MQL were 84, 29.8, 45.5 J/mm³, respectively. The specific grinding energy significantly decreased to 32.7 J/mm³ in nanoparticle MQL. Compared with dry grinding, the surface roughness values of flood grinding, MQL, and nanoparticle jet MQL were significantly reduced with the surface topography profile values reduced by 11%, 2.5%, and 10%,respectively, and the ten point height of microcosmic unflatness values reduced by 1.5%, 0.5%,and 1.3%, respectively. These results verified the satisfactory lubrication effects of nanoparticle MQL. MoS₂, carbon nanotube（CNT）, and ZrO₂ nanoparticles were also added in the grinding fluid of nanoparticle jet MQL to analyze their grinding surface lubrication effects. The specific grinding energy of MoS₂ nanoparticle was only 32.7 J/mm³, which was 8.22% and 10.39% lower than those of the other two nanoparticles. Moreover, the surface roughness of workpiece was also smaller with MoS₂ nanoparticle, which indicated its remarkable lubrication effects. Furthermore,the role of MoS₂ particles in the grinding surface lubrication at different nanoparticle volume concentrations was analyzed. MoS₂ volume concentrations of 1%, 2%, and 3% were used.Experimental results revealed that the specific grinding energy and the workpiece surface roughness initially increased and then decreased as MoS₂ nanoparticle volume concentration increased.Satisfactory grinding surface lubrication effects were obtained with 2% MoS₂ nanoparticle volume concentration.     

直接侧向力/气动力复合控制影响因素研究

为分析直接侧向力/气动力复合控制中的影响因素对控制效果的影响,给出了复合控制拦截器的典型布局,建立了直接侧向力/气动力复合控制分配模型;采用自适应动态逆方法形成虚拟控制律实现拦截器姿态控制,并进行了仿真验证与分析。仿真结果表明,不同发动机总数、发动机开关机周期和推力大小等因素对最终控制效果有直接的影响,且发动机开关机周期与推力的共同作用对控制效果影响明显。     

某型航空发动机宽弦风扇叶片强度分析

针对某型航空发动机,考虑到离心力和气动力共同作用的影响,对该型发动机风扇叶片进行了有限元建模和强度分析,其中对气动力的加载进行了适当的简化。计算结果表明,该型叶片具有较高的静强度储备;应力集中区域在风扇叶片叶盆靠近叶根的区域,是叶片的几何形状以及离心力和气动力共同作用的结果。     

TC4钛合金材料采用金刚石砂轮磨削时的工艺参数优化

钛合金材料在航空器和发动机中的应用极为广泛,涡扇发动机中低压压气机静子叶片基本由钛合金材料制成,由于钛合金的磨削性能较差,对选用金刚石砂轮进行钛合金材料磨削时的主要工艺影响因素（如进给速度、磨抛深度等）进行了试验分析,优选出更适用于金刚石砂轮磨削钛合金的工艺参数,该参数不仅能够用于自研的双面仿形抛修设备,还可以对其他型号磨床磨削钛合金材料时的工艺参数选择提供指导。     

飞机静力试验中机翼的载荷分配研究

针对飞机静力试验加载的问题,为使得试验加载力反映飞机受力特性,由载荷分配前输入的典型剖面上剪力、弯矩、扭矩推导出相邻剖面之间的剪力、弯矩、扭矩,通过构造带内力约束的拉格朗日极值函数求出试验加载力,将载荷分配前输入的内力与试验载荷分配后产生的内力进行对比分析,可以得出:通过构造带内力约束的拉格拉日极值函数法分配得到的试验载荷符合载荷的传递,能够满足飞机静力试验加载的要求,可以用于飞机静力试验的加载。     

连续变迎角测力试验技术在大型暂冲式跨声速风洞中的应用

由于暂冲式高速风洞运行时间短暂,普遍采用阶梯变迎角方式进行静态测力试验,其试验信息量难以满足先进飞行器研制的试验需求。为在暂冲式高速风洞中获得更为详尽的气动力信息,在2．4m跨声速风洞中进行了连续变迎角测力试验技术应用研究。主要介绍了该项试验技术的基本特点,给出了J7标模的主要试验结果。结果表明,该项试验技术获得的气动力数据与常规阶梯方式具有很好的一致性,可以满足工程实用的要求。