成果附录

成果附录

附录1　代表性论文目录

[1]　Mao X, Cao W. Prediction of hypersonic boundary layer transition on sharp wedge f low considering variable specif ic heat [J]. Applied Mathematics and Mechanics, 2014, 35(2):143-154.

[2]　Sun C H. Physical implication of two problems in transition prediction of boundary layers based on linear stability theory [J]. Science China: Physics, Mechanics & Astronomy, 2014,57(5): 950-962.

[3]　张永明， 周恒. PSE在超音速边界层二次失稳问题中的应用[J]. 应用数学和力学，2008， 29（1）： 1-7.

[4]　张永明， 周恒. PSE在可压缩边界层转捩问题中的应用[J]. 应用数学和力学， 2008，29（7）： 757-763.

[5]　董明， 周恒. 超声速钝锥湍流边界层DNS入口边界条件的研究[J]. 应用数学和力学，2008， 29（8）： 893-904.

[6]　苏彩虹， 周恒. 超音速和高超音速有攻角圆锥边界层的转捩预测[J]. 中国科学： 物理学力学天文学， 2009， 39（6）： 874-882.

[7]　曹伟. 高超声速边界层的转捩问题[J]. 空气动力学学报， 2009， 27（5）： 516-523.

[8]　董明， 周恒. 高超声速湍流边界层中由高温引起的变比热效应及其计算[J]. 中国科学： 物理学力学天文学， 2010， 40（11）： 1431-1440.

[9]　董明， 周恒. 高超音速湍流边界层气动热计算中湍流模式的改进[J]. 中国科学： 物理学力学天文学， 2010， 40（2）： 231-241.

[10]　董明， 张永明， 周恒. 计算可压缩边界层转捩及湍流的一种新方法——PSE+DNS[J].应用数学和力学， 2008， 29（12）： 1387-1394.

[11] L eng J S, Lan X, Liu Y J, et al. Shape-memory polymers and their composites: Stimulus methods and applications [J]. Progress in Materials Science, 2011, 56(7): 1077-1135.

[12]　Chen Y J, Sun J, Liu Y J, et al. Experiment and analysis of f luidic f lexible matrix composite((FMC)-M-2) tube [J]. Journal of Intelligent Material Systems and Structures, 2012, 23(3):279-290.

[13]　陈钱， 尹维龙， 白鹏， 等. 变后掠变展长翼身组合体系统设计与特性分析[J]. 航空学报， 2010， 31（3）： 506-513.

[14] 杨文超， 杨剑挺， 王进， 等. 变弯度机翼准定常流动分离特性的实验研究[J]. 中国科学： 物理学力学天文学， 2012， 42（5）： 531-537.

[15] 董二宝， 许昊， 李永新， 等. 单曲柄双摇杆机构同步性能优化[J]. 机械工程学报，2010， 46（7）： 22-26.

[16]　徐国武， 白鹏， 石文. 二维翼型可变形方案初步研究[J]. 力学季刊， 2011， 32（4）：570-576.

[17] 陈钱， 白鹏， 李锋. 飞行器变后掠过程非定常气动特性形成机理[J]. 力学学报， 2013，45（3）： 307-313.

[18] 陈钱， 白鹏， 尹维龙. 飞机外翼段大尺度剪切式变后掠设计与分析[J]. 空气动力学学报， 2012， 31（1）： 40-46.

[19]　尹维龙. 关节式准柔性后缘翼型的气动特性分析[J]. 哈尔滨工业大学学报， 2010，42（1）： 1758-1761.

[20] 白鹏， 陈钱， 刘欣煜， 等. 滑动蒙皮变后掠气动力非定常滞回与线性模型[J]. 力学学报， 2011， 43（6）： 1020-1029.

[21] 李素循. 近空间飞行器的气动复合控制原理及研究进展[J]. 力学进展， 2009， 39（6）：740-755.

[22]　刘耀峰， 薄靖龙. 侧向喷流干扰流场建立与消退过程数值模拟[J]. 宇航学报， 2015，36（8）： 877-894.

[23] 李素循. 吉林陨石熔壳结构的观测[C]//第九届全国实验流体力学学术会议， 杭州，2013.

[24] 李素循， 师军， 郭孝国. 高速流绕平板边界层特性研究[J]. 气体物理， 2016， 1（6）： 1-4.

[25] Z hao L, Zhao X J, Li S X. Fluctuating pressure inside/outside the f low separation region in high speed f low f ield [J]. Journal of Aerospace Science and Technology, 2015, 1:18-26.

[26] L i S X, Guo X G. Blunt f in induced shock wave/lam inar and transition boundary layer interaction in hypersonic flow [C]// The 13th Asian Congress of Fluid M echanics,Bangladesh, 2010.

[27] L i S X, Wang K, Ni Z Y. The visualization of three-dimension shock wave structure in hypersonic f low using schlieren photography and laser vapor screen technique [C]// The 11th Asian Symposium on Visualization, Japan, 2011.

[28]　Ma J K, Li S X, Guo X G. Visualization of unsteady laminar separated f low induced by a swept blunt f in [C]// The 12th Asian Symposium of Visualization, Taiwan, 2013.

[29]　Li S X. Visualization in super/hypersonic f low [C]// The 12th Asian Symposium of Visualization,Taiwan, 2013.

[30]　Ma J K, Li S X. Heat f lux measurement in separated f low f ield induced by a swept blunt f in [C]// 4th International Conference on Experimental Fluid Mechanics, Beijing, 2014.

[31]　Wang Z H, Bao L, Tong B G. Theoretical modeling of chemical nonequilibrium stagnation point boundary layer heat transfer under raref ied conditions [J]. Science China: Physics,Mechanics & Astronomy, 2013, 56(5): 866-874.

[32]　Wang Z H, Bao L, Tong B G. An analytical study on nonequilibrium dissociating gas f low behind a strong bow shockwave under rarefied conditions [J]. Science China: Physics,Mechanics & Astronomy, 2013, 56(4): 671-679.

[33]　Wang Z H, Lin B, Tong B G. Rarefaction criterion and non-Fourier heat transfer in hypersonic raref ied f lows [J]. Physics of Fluids, 2010, 22(12): 1-7.

[34]　Chen X X, Wang Z H, Yu Y L. Nonlinear shear and heat transfer in hypersonic raref ied f lows past f lat plates [J]. AIAA Journal, 2015, 53(2): 413-420.

[35]　Wang Z H, Lin B, Tong B G. Variation character of stagnation point heat f lux for hypersonic pointed bodies from continuum to raref ied f low states and its bridge function study [J].Science China: Physics, Mechanics & Astronomy, 2009, 52(12): 2007-2015.

[36]　Li B M, Bao L, Tong B B. Physical criterion study on forward stagnation point heat f lux CFD computations at hypersonic speeds [J]. Applied Mathematics and Mechanics, 2010,31(7): 839-850.

[37]　Chen H, Bao L. Mechanics of unsteady aerodynamic heating w ith sudden change in surface temperature [J]. Applied Mathematics and Mechanics, 2009, 30(2): 163-174.

[38]　Wang Z H, Bao L, Tong B G. Theoretical modeling of the chemical non-equilibrium f low behind a normal shock wave [J]. AIAA Journal, 2012, 50(2): 494-499.

[39]　Wang Z H. Theoretical Modelling of Aeroheating on Sharpened Noses Under Raref ied Gas Effects and Nonequilibrium Real Gas Effects [M]. Berlin: Springer Theses, 2015.

[40]　王智慧， 鲍麟. 具有局部稀薄气体效应的高超声速尖锥气动加热特征研究[J]. 计算物理， 2010， 27（1）： 59-64.

[41]　Liu X L, Zhang S H, Zhang H X, et al. A new class of central compact schemes w ith spectral-like resolution II: Hybrid weighted nonlinear schemes [J]. Journal of Computational Physics, 2015, 284: 133-154.

[42]　Liu X L, Zhang S H, Zhang H X, et al. A new class of central compact schemes w ith spectral-like resolution I: Linear schemes [J]. Journal of Computational Physics, 2013,248: 235-256.

[43]　Zhang L P, Chang X H, Duan X P, et al. Applications of dynam ic hybrid grid method for three-dimensional moving/deform ing boundary problems [J]. Computers & Fluids, 2012,62: 45-63.

[44]　Zhang S H, Li H, Liu X L, et al. Classif ication and sound generation of two-dimensional interaction of two Taylor vortices [J]. Physics of Fluids, 2013, 25(5): 1-34.

[45]　Zhang S H, Deng X G, Mao M L, et al. Improvement of convergence to steady state solutions of Euler equations w ith weighted compact nonlinear schemes [J]. Acta Mathematicae Applicatae Sinica, 2013, 29(3): 449-464.

[46]　Zhang L P, Zhao Z, Chang X H, et al. A 3D hybrid grid generation technique and a multigrid/parallel algorithm based on anisotropic agglomeration approach [J]. Chinese Journal of Aeronautics, 2013, 26(1): 47-62.

[47]　Sun D, Li Q, Zhang H X. Detached-eddy simulations on massively separated f lows over a 76/40°double-delta w ing [J]. Aerospace Science and Technology, 2013, 30(1): 33-45.

[48]　Li Q, Sun D, Zhang H X. Detached-eddy simulations and analyses on new vortical f lows over a 76/40° double delta w ing [J]. Science China: Physics, Mechanics & Astronomy,2013, 56(6): 1062-1073.

[49]　Zhang S H, Jiang S F, Shu C W. Improvement of convergence to steady state solutions of Euler equations w ith the WENO schemes [J]. Journal of Scientif ic Computing, 2011,47(2): 216-238.

[50]　张来平， 马戎， 常兴华， 等. 虚拟飞行中气动、运动和控制耦合的数值模拟技术[J].力学进展， 2014， 44： 376-417.

[51]　Yuan Y M, Zhang T C, Yao W, et al. Study on f lame stabilization in a dual-mode combustor using optical measurements [J]. Journal of Propulsion and Power, 2015, 31(6): 1524-1532.

[52]　Li L, Wang J, Fan X J. Development of integrated high temperature sensor for simultaneous measurement of wall heat flux and temperature [J]. Review of Scientific Instruments,2012, 83(7): 1-11.

[53]　Zhang T C, Wang J, Fan X J. Combustion of vaporized kerosene in supersonic model combustors w ith dislocated dual cavities [J]. Journal of Propulsion and Power, 2014,30(5): 1152-1161.

[54]　俞刚， 范学军. 超声速燃烧与高超声速推进[J]. 力学进展， 2013， 43（5）： 449-471.

[55]　袁越明， 杨猛， 张泰昌， 等. 脉冲纹影技术及其在超声速燃烧室流场显示中的应用[J].推进技术， 2013， 34（1）： 42-46.

[56]　王新竹， 张泰昌， 陆阳， 等. 主动冷却燃烧室燃烧与传热耦合过程迭代分析设计方法[J].推进技术， 2014， 35（2）： 214-220.

[57]　李晓鹏， 张泰昌， 齐力， 等. 超声速燃烧中的特征尺度及影响因素[J]. 航空动力学报，2013， 28（7）： 1458-1466.

[58]　李龙， 范学军， 王晶. 高温壁面热流与温度一体化测量传感器研究[J]. 实验流体力学，2012， 26（1）： 93-99.

[59]　王振国， 杨揖心， 梁剑寒， 等. 超声速气流中稳焰凹腔吹熄极限分析与建模[J]. 技术科学， 2014， 44（9）： 961-972.

[60]　Zhang T C, Wang J, Li Q, et al. Blowout lim its of cavity-stabilized f lame of supercritical kerosene in supersonic combustors [J]. Journal of Propulsion and Power, 2014, 30(5):1161-1167.

[61]　Zhang C H, Li B, Rao B, et al. A shock tube study of the autoignition characteristics of RP-3 jet fuel [J]. Science Direct, 2015, 35: 3151-3158.

[62] W ang Q D, Fang Y M, Wang F, et al. Skeletal mechanism generation for high-temperature oxidation of kerosene surrogates [J]. Combustion and Flame, 2012, 159(1): 91-102.

[63]　Cheng X M, Wang Q D, Li J Q, et al. ReaxFF molecular dynamics simulations of oxidation of toluene at high temperatures [J]. Journal of Physical Chemistry A, 2012, 116(40):9811-9818.

[64]　Wang Q D, Wang J B, Li J Q, et al. Reactive molecular dynamics simulation and chemical kinetic modeling of pyrolysis and combustion of n-dodecane [J]. Combustion and Flame,2011, 158(2): 217-226.

[65]　Xiong S Z, Yao Q, Li Z R, et al. Reaction of ketenyl radical w ith hydroxyl radical over C2H2O2potential energy surface: A theoretical study [J]. Combustion and Flame, 2014,161(4): 885-897.

[66]　Lia A K, Jiao Y, Li S H, et al. Flux projection tree method for mechanism reduction [J].Energy & Fuels, 2014, 28(8): 5426-5433.

[67]　Rao F, Li B, Li P, et al. Shock-tube study of the ignition of gas-phase 1,3,5- trimethylbenzene in air [J]. Energy & Fuels, 2014, 28(11): 6707-6713.

[68] Z hang C H, Li P, Li Y L, et al. Shock-tube study of dimethoxymethane ignition at high temperatures [J]. Energy & Fuels, 2014, 28(7): 4603-4610.

[69]　Gong C M, Ning H B, Xu J Q, et al. Experimental and modeling study of thermal and catalytic cracking of n-decane [J]. Journal of Analytical and Applied Pyrolysis, 2014,110: 1-37.

[70]　Guo J J, Wang J B, Hua X X, et al. Mechanism construction and simulation for high-temperature combustion of n-propylcyclohexane [J]. Chem ical Research in Chinese Universities, 2014, 30(3): 480-488.

[71]　Wang H B, Qin L, Sun M B, et al. A hybrid LES (Large Eddy Simulation)/assumed sub-grid PDF (Probability Density Function) model for supersonic turbulent combustion [J]. Science China: Technological Sciences, 2011, 54(10): 2694-2707.

[72]　Sun M B, Gong C, Zhang S H, et al. Spark ignition process in a scram jet combustor fueled by hydrogen and equipped w ith multi-cavities at Mach 4 f light condition [J]. Experimental Thermal and Fluid Science, 2012, 43: 90-96.

[73]　Han X, Zhou J, Lin Z Y, et al. Def lagration-to-detonation transition induced by hot jets in a supersonic prem ixed airstream [J]. Chinese Physics Letters, 2013, 30(5): 1-3.

[74] H an X, Zhou J, Lin Z Y. Experimental investigations of detonation initiation by hot jets in supersonic prem ixed f lows [J]. Chinese Physics B, 2012, 21(12): 1-5.

[75] W ang H B, Qin L, Sun M, et al. A dynam ic pressure-sink method for improving large eddy simulation and hybrid Reynolds-averaged Navier-Stokes-large eddy simulation of wall-bounded f low s [J]. Journal of Aerospace Engineering, 2012, 226(9): 1107-1120.

[76] S un M B, Lei J, Wu H Y, et al. Flow patterns and mixing characteristics of gaseous fuel multiple injections in a non-reacting supersonic combustor [J]. Heat and Mass Transfer,2011, 47(11): 1499-1516.

[77] L iang J H, Cai X D, Li Z Y, et al. Effects of a hot jet on detonation initiation and propagation in supersonic combustible mixtures [J]. Acta Astronautica, 2014, 105(1): 265-277.

[78]　Cai X D, Liang J H, Lin Z Y, et al. Parametric study of detonation initiation using a hot jet in supersonic combustible mixtures [J]. Aerospace Science and Technology, 2014, 39:442-455.

[79]　Cai X D, Liang J H, Lin Z Y, et al. Adaptive mesh ref inement based numerical simulation of detonation initiation in supersonic combustible mixtures using a hot jet [J]. Journal of Aerospace Engineering, 2015, 28(1): 1-36.

[80]　Cai X D, Liang J H, Lin Z Y, et al. Detonation initiation and propagation in nonuniform supersonic combustible mixtures [J]. Combustion Science and Technology, 2015, 187(4):525-536.

[81]　向有志， 张堃元， 王磊， 等. 壁面压升可控的高超轴对称进气道优化设计[J]. 航空动力学报， 2011， 26（10）： 2193-2199.

[82] 张林， 张堃元， 王磊， 等. 高超弯曲激波二维进气道初步研究[J]. 航空动力学报， 2011，26（11）： 2556-2562.

[83] 南向军， 张堃元， 金志光. 基于反正切曲线压升规律设计高超内收缩进气道[J]. 航空动力学报， 2016， 26（11）： 2571-2577.

[84]　苏纬仪， 张新宇， 张堃元. 洛仑兹力控制高超声速进气道边界层分离的数值模拟[J].推进技术， 2011， 32（1）： 36-41.

[85] 苏纬仪， 张堃元， 金志光. 高超声速进气道附面层分离无源被动控制[J]. 推进技术，2011， 32（4）： 455-450.

[86] 苏纬仪， 张堃元， 金志光. 基于遗传算法的高超声速曲面压缩进气道反设计[J].推进技术， 2011， 32（5）： 601-605.

[87]　南向军， 张堃元， 金志光， 等. 矩形转圆形高超声速内收缩进气道数值及试验研究[J].航空学报， 2011， 32（6）： 988-996.

[88] 苏纬仪， 张堃元， 金志光. 一种抑制激波-边界层相互作用的新型无源被动控制[J].空气动力学报， 2011， 29（6）： 738-743.

[89]　刘凯礼， 张堃元. 二元高超声速进气道动态攻角特性风洞实验[J]. 推进技术， 2012，33（1）： 14-19.

[90]　南向军， 张堃元. 采用新型基准流场的高超声速内收缩进气道性能分析[J]. 宇航学报，2012， 33（2）： 254-259.

[91]　Wang X H, Wang J Z. Partial integrated m issile guidance and control w ith f inite time convergence [J]. Journal of Guidance, Control and Dynamics, 2013, 36(5): 1399-1411.

[92]　Cui L, Yang Y. Disturbance rejection and robust least-squares control allocation in f light control system [J]. Journal of Guidance, Control and Dynamics, 2011, 34(6): 1632-1645.

[93]　Duan Z S, Huang L, Yao Y, et al. On the effects of redundant control inputs [J]. Automatica,2012, 48(9): 2168-2174.

[94]　Wei Q K, Niu Z G, Chen B, et al. Bang-bang control applied in airfoil roll control w ith plasma actuators [J]. Journal of Aircraft, 2013, 50(2): 670-677.

[95]　Song Lei, Yang J Y. An improved approach to robust stability analysis and controller synthesis for LPV systems [J]. International Journal of Robust and Nonlinear Control,2011, 21(13): 1574-1586.

[96]　黄琳， 段志生， 杨剑影. 近空间高超声速飞行器对控制科学的挑战[J]. 控制理论与应用， 2011， 28（10）： 1496-1505.

[97]　陈琛， 王鑫， 闫杰. 升力体构型高超声速飞行器模态稳定性分析[J]. 西北工业大学学报， 2010， 28（3）： 327-331.

[98]　闫斌斌， 孟中杰， 王鑫， 等. 抑制高超声速飞行器级间分离气动干扰的预置舵偏设计方法[J]. 西北工业大学学报， 2011， 29（5）： 757-760.

[99]　张辉， 王鑫， 李杰， 等. 升力体构型高超声速飞行器气动特性分析[J]. 飞行力学， 2013，31（2）： 118-122.

[100]　孟中杰， 闫杰. 弹性高超声速飞行器建模及精细姿态控制[J]. 宇航学报， 2011，32（8）： 1683-1687.

[101]　孟中杰， 闫杰. 高超声速弹性飞行器振动模态自适应抑制技术[J]. 宇航学报， 2011，32（10）： 2164-2168.

[102]　谭毅龙， 闫杰. 针对高超声速飞行器的非线性动态逆最优控制[J]. 导弹与航天运载技术， 2011（1）： 36-39.

[103]　宋磊， 杨剑影， 段志生. 多模型切换系统H∞鲁棒控制器的设计与应用[J]. 控制理论与应用， 2010， 27（11）： 1531-1536.

[104]　Song L, Yang J Y. Smooth sw itching output tracking control for LPV systems [J]. Asian Journal of Control, 2012, 14(6): 1710-1716.

[105]　Zhao Y Y, Yang J Y, Wen G H. H∞control for uncertain sw itched nonlinear singular systems w ith time delay [J]. Nonlinear Dynamics, 2013, 74(3): 649-665.

[106]　Zhang Y, Song J S, Ren Z. Neural network dynamic inversion w ith application to reentry process of a hypersonic vehicle [C]// International Conference on Advanced Computational Intelligence, Nanjing, 2012.

[107]　Song J H, Liu H T, Ren Z. Self-regulation controller design based on disturbance estimation for reusable launch vehicle [C]// International Conference on Automatic Control and Artif icial Intelligence, Xiamen, 2012.

[108]　Song J H, Ren Z, Shen Z. Self-regulation control scheme for reusable launch vehicle reentry attitude control [C]// International Conference on Advanced Computational Intelligence,Nanjing, 2012.

[109]　Peng J, Qu X, Ren Z. Fuzzy sliding mode control design for reusable launch vehicles [C]//International Conference on Advanced Computational Intelligence, Nanjing, 2012.

[110]　雷正东， 杨剑影， 赵阳阳. 基于挠性吸气式高超声速飞行器的传感器容错控制[J].航空兵器， 2012（2）： 3-9.

[111]　张臻， 王玉坤， 毛剑琴. 基于模糊树逆方法的高超飞行器变质心控制[J]. 信息科学，2012， 42（11）： 1379-1390.

[112]　Zhang Z, Chen Q W, Mao J Q. Generalized Prandtl-Ishlinskii model for rate-dependent hysteresis-modeling and its inverse compensation for giant magnetostrictive actuator [C]//Proceeding of the 31st Chinese Control Conference, Hefei, 2012.

[113]　Zhang W, Zhang Z, Mao J Q, et al. Modeling and control of rate-dependent hysteresis based on Hammerstein-like system by using fuzzy tree method [C]// Proceeding of the 31st Chinese Control Conference, Hefei, 2012.

[114]　Wu Z G, Yang C. A new approach for aeroelastic robust stability analysis [J]. Chinese Journal of Aeronautics, 2008, 21(5): 417-422.

[115]　Zhang X T, Wu Z G, Yang C. New f lutter-suppression method for a m issile f in w ith an actuator [J]. Journal of Aircraft, 2013, 50(3): 989-995.

[116]　Yang C, Yang Y X, Wu Z G. Shape sensitivity analysis of f lutter characteristics of a low aspect ratio supersonic w ing using analytical method [J]. Science China: Technological Sciences, 2012, 55(12): 3370-3377.

[117]　Wan Z Q, Liang L, Yang C. Method of the jig shape design for a f lexible w ing [J]. Journal of Aircraft, 2014, 51(1): 327-331.

[118]　Wan Z Q, Wang Y K, Liu Y Z, et al. A high-eff iciency aerothermoelastic analysis method [J].Science China: Physics, Mechanics & Astronomy, 2014, 57(6): 1111-1118.

[119]　Wu Z Z, Yang N, Yang C. Identif ication of nonlinear multi-degree-of freedom structures based on Hilbert transformation [J]. Science China: Physics, Mechanics & Astronomy, 2014,57(9): 1725-1736.

[120]　Wan Z Q, Zhang B C, Du Z L, et al. Aeroelastic two-level optim ization for prelim inary design of w ing structures considering robust constraints [J]. Chinese Journal of Aeronautics,2014, 27(2): 259-265.

[121]　吴志刚， 樊龙飞， 杨超， 等. 推力耦合的高超声速飞行器气动伺服弹性研究[J].航空学报， 2012， 33（8）： 1355-1363.

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