近断层危害场三维数值模拟及其并行处理研究
|
摘要
活动断层是引起地震发生的根源。地震灾害是群灾之首。因地震的突发性和不可抗拒性,从而产生巨大危害。大量的震害资料表明,地震时沿断层线的破坏最为严重,人员伤亡也明显地大于断层两侧的其它区域。十五期间,国家投巨资在全国24个大中城市开展城市活断层探测与地震危害性评价工作。淄博市重点活动断裂(张店-仁河断裂)近断层危害场数值模拟属山东省地震局“十五”重点项目计划。
本文所完成的主要工作有:
(一)首先搜集日本和我国台湾等地典型地震的研究资料,对典型地震活断层近断层危害性影响场进行初步分析;分析和比较近断层地震动的研究方法;总结了近断层强地震动特征,包括上盘效应、竖向效应、破裂方向性效应以及滑冲效应等等。
(二)在淄博市活断层探测和地震小区划研究的基础上,建立了淄博市重点活动断裂(张店-仁河断裂)地震危害性评价的地质-构造三维结构模型。在实际模拟时,根据隐伏断层位置、上断点埋深以及介质分层,共考虑了五个试验段,并针对每一个试验段不同倾角、不同倾向的情况分别建立了三维地质模型,包括大规模计算的地质模型在内总共十六个模型。特别是在模拟土的性质时采用了摩尔-库伦模型进行计算,与以往的仅仅采用弹性模型计算相比,更符合实际。
(三)采用显式拉格朗日有限差分法,通过对每一个试验段的不同倾角、不同倾向的七种模型施加不同的地震波荷载,得到了张店-仁河断裂近断层地震危害场的数值模拟结果,包括各种情况下的变形场、应力场、位移场和加速度场,数值模拟结果均以图形化的方式显示出来。由于显式拉格朗日有限差分法在求解运动基本方程过程中,不需要形成总刚度矩阵,而是在每一个时间步修正坐标,位移增量加到坐标上,使网格移动和材料变形,每一步本构公式是小应变,但在很多步之后等价于大应变公式。计算结果能表现出接触块体相互运动和变形的特征,并且由于不解总刚度方程,便于在计算机上实现,计算速度快,占用存储空间小。
(四)本论文给出了基于区域分解算法的一种有限元并行算法,先将偏微分方程求解区域划分为若干个子区域,然后在各个子区域并行求解。结合大型稀疏矩阵方程组的并行共轭梯度算法,编制了基于Linux操作系统,适用于PC集群的并行有限元计算程序,来对第四章所建立的地质模型进行计算模拟,得到了张店-仁河断裂近断层地震危害场的数值模拟结果,并行程序大大节省了计算时间,具有很好的加速比。由于有限元法更适用于空间变化复杂的介质,能够便利地处理自由表面,精确计算面波的传播,计算精度高。很适宜在分布式内存的PC集群上方便地进行并行计算,因此对于大规模模型可以提高计算速度,非常适用于大规模地球介质模型地震波动场数值计算。
(五)通过对有限差分与有限元模拟结果的分析检验,计算结果与近断层强地震动基本特征的吻合,较好的反映了近断层强地震动的盆地效应、方向性效应、上盘效应等基本特征,验证了我们模拟结果的合理性和方法的可信性,同时也证明了震源模型与传播介质模型建立和参数设置的合理性。本文的计算结果可以为防震减灾和工程设计提供指导和参考。
另外,模拟中还存在需要进一步改进和加强研究的地方。例如,需要在建立三维地震构造模型方面多做研究,地震构造模型的科学性如何,直接制约、影响到计算结果,其中任何一个参数的变动,将会导致产出结果变化。因此,地震地表变形带的预测是一项综合性很强的工作,需要不同的专业的科研人员的密切配合。但作者相信,这些都会随着资料的积累和研究的深入逐步得到解决,使近断层强地震动模拟更加完善。
Active fault is the root cause to earthquake.Disaster Earthquake is in the first place of disasters.Earthquake is unexpected and irresistible,so it can have tremendous harm.A lot of damage data indicate that earthquakes along the fault lines make the most serious damage,casualties is obviously greater than other regions on both sides of the fault.During the 10th Five-Year Plan period,China invested in the 24 large and medium-sized cities in urban areas to active fault detection and evaluation of seismic danger.The numerical simulation of near-fault endangered field of the focus active faults in Zibo City(Zhangdian-Renhe fault) against near-fault is a priority "Ten-five" project of Shandong Seismological Bureau.
The main works completed in this paper include:
1) The typical seismic data of many districts is collected,such as Japan and Taiwan,and preliminary analysis of the typical active Near-fault endangered field is made.The research methods of the near-fault ground motion are systemically reviewed and compared.The basic characteristics of near-fault ground motion are summarized,such as the hanging wall effect,the vertical effect,the rupture directivity effect,the fling step effect and so on.
2) Based on the correlative data and geology information of moderate and upwards earthquakes of Zibo City,sixteen 3D geology models of the main active fault of Zibo City(Zhangdian-Renhe Fault) are created according to the nearby and on the base of active fault detection and the small-area earthquake analyses.Especially, Moore-Coulomb model is used in the simulation of the nature of soil,it is more realistic than only adopting a flexible model in the past.
3) Explicit Lagrangian finite difference method is adopted because it is needn't to form the stiffness matrix in solving the basic equation of the process of movement. Numerical simulations of the near-fault disservice field are performed.The simulation results,including the various circumstances deformation,stress,displacement,and acceleration field,numerical simulation results are graphically displayed.The results can show the characteristics of mutual contact blocks' movement and deformation, and because of the stiffness puzzling equation in the computer easy to achieve, calculation is fast and taking up small storage space.
4) In this paper,a FEM parallel algorithm based on a domain decomposition algorithm is given,parallel finite element calculation procedure based on Linux operating system is developed for PC cluster.Through the simulation calculation to the geological models established in ChapterⅣ,the numerical simulation results are got.The procedure has a good parallel speedup.The finite element method(FEM) is more suitable to the medium with complex space changes,more convenient to deal with the free surface,and it can get accurate calculation of wave propagation.FEM is very suitable for the PC cluster with distributed memory,can increase the calculation speed for large-scale Earth's medium model.
5) Through the analysis of the simulation results,it is obviously that the results better reflect the basic features of near-fault seismic,such as the basin effect,the vertical effect,the hanging wall effect,and so on.The results can provide guidance and reference for Earthquake Disaster Mitigation and engineering design.
In addition,it is necessary to further improve and research more on many aspect of simulation.For example,more research is needed in building three-dimensional structural model of the earthquake,because the scientific nature of the seismic model constraints and affects the calculated results directly,any of these parameters change, the results will change.Therefore,prediction of surface deformation zone in earthquake is a very complex task,it is required that different professional research staff cooperated closely.With the accumulation of information and in-depth research, these will be gradually resolved and the simulation of near-fault ground motion will be more complete.
本文所完成的主要工作有:
(一)首先搜集日本和我国台湾等地典型地震的研究资料,对典型地震活断层近断层危害性影响场进行初步分析;分析和比较近断层地震动的研究方法;总结了近断层强地震动特征,包括上盘效应、竖向效应、破裂方向性效应以及滑冲效应等等。
(二)在淄博市活断层探测和地震小区划研究的基础上,建立了淄博市重点活动断裂(张店-仁河断裂)地震危害性评价的地质-构造三维结构模型。在实际模拟时,根据隐伏断层位置、上断点埋深以及介质分层,共考虑了五个试验段,并针对每一个试验段不同倾角、不同倾向的情况分别建立了三维地质模型,包括大规模计算的地质模型在内总共十六个模型。特别是在模拟土的性质时采用了摩尔-库伦模型进行计算,与以往的仅仅采用弹性模型计算相比,更符合实际。
(三)采用显式拉格朗日有限差分法,通过对每一个试验段的不同倾角、不同倾向的七种模型施加不同的地震波荷载,得到了张店-仁河断裂近断层地震危害场的数值模拟结果,包括各种情况下的变形场、应力场、位移场和加速度场,数值模拟结果均以图形化的方式显示出来。由于显式拉格朗日有限差分法在求解运动基本方程过程中,不需要形成总刚度矩阵,而是在每一个时间步修正坐标,位移增量加到坐标上,使网格移动和材料变形,每一步本构公式是小应变,但在很多步之后等价于大应变公式。计算结果能表现出接触块体相互运动和变形的特征,并且由于不解总刚度方程,便于在计算机上实现,计算速度快,占用存储空间小。
(四)本论文给出了基于区域分解算法的一种有限元并行算法,先将偏微分方程求解区域划分为若干个子区域,然后在各个子区域并行求解。结合大型稀疏矩阵方程组的并行共轭梯度算法,编制了基于Linux操作系统,适用于PC集群的并行有限元计算程序,来对第四章所建立的地质模型进行计算模拟,得到了张店-仁河断裂近断层地震危害场的数值模拟结果,并行程序大大节省了计算时间,具有很好的加速比。由于有限元法更适用于空间变化复杂的介质,能够便利地处理自由表面,精确计算面波的传播,计算精度高。很适宜在分布式内存的PC集群上方便地进行并行计算,因此对于大规模模型可以提高计算速度,非常适用于大规模地球介质模型地震波动场数值计算。
(五)通过对有限差分与有限元模拟结果的分析检验,计算结果与近断层强地震动基本特征的吻合,较好的反映了近断层强地震动的盆地效应、方向性效应、上盘效应等基本特征,验证了我们模拟结果的合理性和方法的可信性,同时也证明了震源模型与传播介质模型建立和参数设置的合理性。本文的计算结果可以为防震减灾和工程设计提供指导和参考。
另外,模拟中还存在需要进一步改进和加强研究的地方。例如,需要在建立三维地震构造模型方面多做研究,地震构造模型的科学性如何,直接制约、影响到计算结果,其中任何一个参数的变动,将会导致产出结果变化。因此,地震地表变形带的预测是一项综合性很强的工作,需要不同的专业的科研人员的密切配合。但作者相信,这些都会随着资料的积累和研究的深入逐步得到解决,使近断层强地震动模拟更加完善。
Active fault is the root cause to earthquake.Disaster Earthquake is in the first place of disasters.Earthquake is unexpected and irresistible,so it can have tremendous harm.A lot of damage data indicate that earthquakes along the fault lines make the most serious damage,casualties is obviously greater than other regions on both sides of the fault.During the 10th Five-Year Plan period,China invested in the 24 large and medium-sized cities in urban areas to active fault detection and evaluation of seismic danger.The numerical simulation of near-fault endangered field of the focus active faults in Zibo City(Zhangdian-Renhe fault) against near-fault is a priority "Ten-five" project of Shandong Seismological Bureau.
The main works completed in this paper include:
1) The typical seismic data of many districts is collected,such as Japan and Taiwan,and preliminary analysis of the typical active Near-fault endangered field is made.The research methods of the near-fault ground motion are systemically reviewed and compared.The basic characteristics of near-fault ground motion are summarized,such as the hanging wall effect,the vertical effect,the rupture directivity effect,the fling step effect and so on.
2) Based on the correlative data and geology information of moderate and upwards earthquakes of Zibo City,sixteen 3D geology models of the main active fault of Zibo City(Zhangdian-Renhe Fault) are created according to the nearby and on the base of active fault detection and the small-area earthquake analyses.Especially, Moore-Coulomb model is used in the simulation of the nature of soil,it is more realistic than only adopting a flexible model in the past.
3) Explicit Lagrangian finite difference method is adopted because it is needn't to form the stiffness matrix in solving the basic equation of the process of movement. Numerical simulations of the near-fault disservice field are performed.The simulation results,including the various circumstances deformation,stress,displacement,and acceleration field,numerical simulation results are graphically displayed.The results can show the characteristics of mutual contact blocks' movement and deformation, and because of the stiffness puzzling equation in the computer easy to achieve, calculation is fast and taking up small storage space.
4) In this paper,a FEM parallel algorithm based on a domain decomposition algorithm is given,parallel finite element calculation procedure based on Linux operating system is developed for PC cluster.Through the simulation calculation to the geological models established in ChapterⅣ,the numerical simulation results are got.The procedure has a good parallel speedup.The finite element method(FEM) is more suitable to the medium with complex space changes,more convenient to deal with the free surface,and it can get accurate calculation of wave propagation.FEM is very suitable for the PC cluster with distributed memory,can increase the calculation speed for large-scale Earth's medium model.
5) Through the analysis of the simulation results,it is obviously that the results better reflect the basic features of near-fault seismic,such as the basin effect,the vertical effect,the hanging wall effect,and so on.The results can provide guidance and reference for Earthquake Disaster Mitigation and engineering design.
In addition,it is necessary to further improve and research more on many aspect of simulation.For example,more research is needed in building three-dimensional structural model of the earthquake,because the scientific nature of the seismic model constraints and affects the calculated results directly,any of these parameters change, the results will change.Therefore,prediction of surface deformation zone in earthquake is a very complex task,it is required that different professional research staff cooperated closely.With the accumulation of information and in-depth research, these will be gradually resolved and the simulation of near-fault ground motion will be more complete.
引文
[1]王彦斌,李建成.1999年台湾集集大地震的地表断层破裂特征[J].地震地质,2000(22):98-103.
[2]彭承光,李运贵,卢帮华,邱奕超.台湾集集7.6级地震车笼埔发震断层场地灾害综述[J].地震科技情报,2000(9):9-13.
[3]太田阳子,黄振义.台湾中部9.21集集大地震的地震断层[J].地震科技情报,2001(2):22-24.
[4]王国权,周锡元,马宗晋,曾德民.921台湾地震近断层强地面运动的周期和幅值特性[J].工程抗震,2001,3(1):30-36.
[5]俞言祥,高孟潭.台湾集集地震近场地震动的上盘效应[J].地震学报,2001(23):616-621.
[6]D.D.Oglesby,S.M.Day.断层几何对1999年集集(台湾)地震的影响[J].世界地震译从,2002(6):38-42.
[7]D.D.Oglesby,R.J.Archuleta,S.B.Nielsen.Earthquake on dipping fault:the effects of broken symmetry[J].Science,1996,280:1055-1059.
[8]王国权,周锡元.台湾集集地震近断层强震地面运动加速度时程的随机特性[J].防灾减灾工程学报,2003(23):10-19.
[9]刘文兵,马丽.台湾集集和华北大同地震序列的定量模型分析[J].地震,2004(24):156-162.
[10]王国权,周锡元.921台湾集集地震近断层强震记录的基线校正[J].地震地质,2004,3(26):2-14.
[11]徐龙军,谢礼立.集集地震近断层地震动频谱特性[J].地震学报,2005(27):657-665.
[12]周仕勇,陈晓非.近震源破裂过程反演研究—9.21中国台湾集集地震破裂过程的近场反演[J].中国科学D辑,2006(36):49-58.
[13]M.N.Toks.1999年8月17日土耳其伊兹米特地震的初步报告[J].地壳构造与地壳应力,2000(2):28-32.
[14]张敏政,刘洁平.土耳其伊兹米特地震(1999,M7.4)的强地震动[J].世界地震工程,2000(16):2-7.
[15]韩竹军,张国民.伊兹米特地震发生的构造环境分析[J].国际地震动态,2000(1):2-7.
[16]韩竹军,苗崇刚.伊兹米特地震地表破裂带和发震构造特点[J].国际地震动态,2000(1):8-12.
[17]M.W esterhaus,R.Yilmaz,J.Zschau.1990年代期间b值和地壳形变的相关变化能够确定1999年8月17日伊兹米特特MW=7.4级地震的破裂起始[J].世界地震译丛,2003(4):7-22.
[18]杨光,沈繁銮.日本阪神地震灾害的一些调查统计数据[J].华南地震,2005(25):84-86.
[19]曹炳政,刘晶波.神户大开地铁车站的地震反应分析[J].地震工程与工程振动,2002(22):103-107.
[20]邓起东.2002.中国活动构造研究的进展与展望[J].地质论评,48(2):168-177.
[21]董敏煌.2000.地震勘探[M],东营:石油大学出版社.
[22]黄瑞树,冉洪流,高峥.1993.中国大陆地震震级和地震活动断层长度的关系讨论[J].地震地质,15(4):396-400.
[23]张晓志,谢礼立.采用显式有限元方法求解开放系统动力响应的主要环节和问题[J].地震工程与工程振动,2005(02):.
[24]张晓志,谢礼立,王海云,胡进军.近断层强地面运动影响场显式有限元数值模拟的示意性算例[J].地震工程与工程振动,2005(06).
[25]刘启方,袁一凡,金星,丁海平.近断层地震动的基本特征[J].地震工程与工程振动,2006,26(1):1-10.
[26]刘启方,丁海平,袁一凡(2003),三维地震断层动力破裂的显式有限元解法[J].地震工程与工程震动,2003,23(4):22-28.
[27]高孟潭,俞言祥,张晓梅,吴健,胡平,丁彦慧.北京地区地震动的三维有限差分模拟[J].中国地震,2002(04).
[28]郭恩栋,邵广彪,薄景山,石兆吉(2002),覆盖土层场地地震断裂反应分析方法[J].地震工程与工程振动,22(5),122-126.
[29]谢礼立,陶夏新,王国新.强地震动估计和地震危险性评定[J].东北地震研究,2001,(01).
[30]倪永军,朱晞.近断层地震的加速度峰值比和反应谱分析[J].北京交通大学学报,2004,(04).
[31]许力生,俞言祥,陈运泰.中国强地面运动研究进展[J].地震学报,2003,(05).
[32]M.Bouchon,Aki.Discrete wave number representation of seismic source wave fields[J].Bull.Seism.Soc.Am,1977,67:259-277.
[33]K.W.Campbell.Near-source attenuation of peak horizontal acceleration.Bulletin of the Seismological Society of America,1981,71,(6):2039-2070.
[34]N.Ambraseys,J.Bommer.The attenuation of ground acceleration in Europe[J].Earthquake Engineering and Structural Dynamics,1991,20(12):1179-1202.
[35]K.W.Campbell.Empirical near-source attenuations for horizontal and vertical components of peak ground acceleration,peak ground velocity,and pseudoabsolute acceleration response spectra[J].Seismological Research Letters,1997,68(1):154-179.
[36]P.G.Somerville,N.F.Smith,R.W.Graves,et al.Modifications of empirical strong ground motion attenuation relations to include the amplitude and duration effects of rupture directivity[J].Seismological Research Letters,1997,68(1):199-222.
[37]L.S.Chien.Parallel Processing techniques for finite element analysis of nonlinear large truss structures[J].Computers and Structures,1989,31:1023-1029.
[38]CHEN Pei-Shan,S.J.Duda.Fracture mechanics rupture model of earthquakes and an esumate of ambient shear stress[J].Phys Earth Planet Inter,1996,93(3-4):299-308.
[39]D.M.Boore,W.B.Joyner,T.E.Fumal.Equations for estimating horizontal response spectra and peak acceleration from Western North American earthquakes:A summary of recent work[J].Seismological Research Letters,1997,68(1):128-153.
[40]T.Mikumo,T.Miyatake.Dynamical rupture process on a three-dimensional fault with non-uniform frictions and near field seismic waves[J].Geophys.J.R.Soc,1978,54:417-438.
[41]P.G.Okubo,J.H.Dieterich.Effect of physical fault properties on frictional instabilities produced on simulated faults.J.Geophys.Res,1984,89(B7):5817-5827.
[42]S.Das,K.Aki.A numerical study of two-dimensional spontaneous rupture propagation[J].Geophys.J.R.Astr.Soc,1977,50:643-668.
[43]W.J.Renton.Aerospace and structures:where are we headed[J].International Journal of Solids and Structures,2001,38:3309-3319.
[44]廖振鹏,魏颖.设计地震加速度的合成[J].地震工程和工程震动,1988,18(5).
[45]金星.重大工程场地设计地震余地震动场的研究[D],中国地震局工程力学研究所博士学位论文,1992.
[46]金星(1994),地震动随机场的物理模拟[J].地震工程与工程震动,14(3):11-19.
[47]金星,陈超,张明宇,震源对地震动空间相关性影响的定量研究[J].地震工程与工程振动,2000,20(3):1-10.
[48]李小军.一维土层地震反应线性化计算程序,地震小区划—理论与实践,地震出版社.1989.
[49]廖振鹏.近场波动问题的有限元解法[J].地震工程与工程震动,1984(4):1-13.
[50]廖振鹏,刘晶波,波动有限元模拟的基本问题,中国科学(B),1992(8):874-882.
[51]廖振鹏.工程波动理论导引(第二版)[M].北京,科学出版社.2002.
[52]李世愚,陈运泰,地震震源研究[J].地震学报,2003,25(5):453-464.
[53]胡聿贤.地震工程学[M],地震出版社.1988.
[54]刘启方.断层附近强地面运动的初步研究[D].中国地震局工程力学研究所硕士学位论文.2001.
[55]刘启方,袁一凡,金星,断层附近地震动空间分布[J].地震学报,2004,26(2):183-192.
[56]刘启方.基于运动学和动力学展源模型的近断层地展动研究[D]:[博士学位论文].哈尔滨:中国地震局工程力学研究所.2005.
[57]陶夏新,王国新.近场强地震动模拟中对破裂的方向性效应和上盘效应的表达[J]地震学报,2003(02).
[58]宋惠珍,袁岩光,黄立人等.1976年唐山7.8级地震震源过程的研究[J].地震地质,1988,10(4):98-108.
[59]袁岩光,宋惠珍.受压斜裂纹稳定扩展过程的有限元法模拟及其讨论[J].现代地壳运 动研究,1989(4):69-77.
[60]曾海容.裂纹扩展与固液耦合三维有限单元正反演模型研究[D].北京:国家地震周地质研究所.1996.
[61]郭继武,冯小川.地基与基础[M].北京:清华大学出版社,1993:30-90.
[62]GUO Ji-wu,FENG Xiao-chuan.Groundwork and foundation[M].Bering:Tsinghua University Press,1993:30-90.
[63]杨绍普,申永军.滞后非线性系统的分岔与奇异性[M].北京:科学出版社,2003.
[64]宋惠珍,曾海容,剡公瑞.逆冲断层应力场的数值模拟[J].地震地质,1999,21(3):275-282.
[65]张玉娥,白宝鸿.地铁列车振动对隧道结构激振荷载的模拟[J].振动与冲击,2000,19(3):68-76.
[66]李德武,高峰.隧道基底结构列车振动现场测试与分析[J].甘肃科学学报,1999.
[67]王泳嘉,刑纪波.离散单元法同拉格朗日元法及其在岩土力学中的应用[J].岩土力学,1995,16(2):1-14.
[68]Babak Alavi and Helmut Krawinkler.Consideration of Near-Fault Ground Motion Effects in Seismic Design[J].12th World Conference on Earthquake Engineering,2000.
[69]崔培新.地铁列车振动异常问题探讨[J].铁道车辆,2001,39(12):18-21.
[70]曾国平,刘忠,徐家礼译.塑性力学有限元理论与应用[M].北京:兵器工业出版社,1989.112-379.
[71]潘昌实,张弥,吴鸿庆.隧道力学数值方法[M].北京:中国铁道出版社,1995,63-124.
[72]土动力学工程应用实例与分析[M].北京:中国建筑工业出版社,1998,186-196.
[73]任永生,周建鹏.汽车半主动悬架技术研究综述[J].振动与冲击,2006,25(3):162-165.
[74]翁建生,胡海岩.磁流变液体的流变力学特性试验和建模[J].应用力学学报,2000,17(3):1-5
[75]罗架洪.矩阵分析引论[M].华南理工大学出版社,2005.
[76]赵学仁.弹性力学基础[M].北京:北京理工大学出版社,1994
[77]刘波,韩彦辉.FLAC原理、实例与应用指南[M].北京:人民交通出版社,2005.
[78]黄润秋,许强.显式拉格朗日差分分析在岩石边坡工程中的应用[J].岩石力学与工程 学报,1995,14(4):346-354.
[79]赵和平,黄宏成,习纲,张建武.非线性弹簧汽车悬架动态特性研究[J].机械强度,2001,23(2):165-67.
[80]张东升,连志斌.桑塔纳2000型轿车的前悬架锤击法模态实验研究[J].汽车研究与开发,1999(1):23-27.
[81]刘继国,曾亚武.FLAC3D在深基坑开挖与支护数值模拟中的应用[J].岩土力学,2006,27(3):505-508.
[82]李亚荣,荣代潞,韩晓明.近断层水库大坝的震后变形问题分析[J].西北地震学报,2006,28(2):123-128.
[83]姚兰予,聂永安,赵根模.半无限空间中剪切断层错动产生的应力场[J].西北地震学报,2000,22(1):16-23.
[84]叶绍松,阮祥发,赵燕.有限元法在结构分析中的应用[J].机械研究与应用,2005,(04).
[85]陈乐生.第一讲什么是有限元方法[J].木工机床,2006,(02).
[86]张永刚.有限元法发展及其应用[J].科技情报开发与经济,2007,(11).
[87]于亚婷,杜平安,王振伟.有限元法的应用现状研究[J].机械设计,2005,(03).
[88]姜京伟,程阔.有限元网格划分剖析[J].山西交通科技,2007,(05).
[89]仇亚萍,黄俐军,冯立飞.基于ANSYS的有限元网格划分方法[J].机械管理开发,2007,(06).
[90]邢福生.结构有限元技术及其发展[J].水科学与工程技术,2005,(S1).
[91]高攀,黄放.有限元方法的发展状况和应用[J].电机技术,1999,(02).
[92]金杨洁.齿轮强度的有限元分析[J].汽齿科技,2007,(01).
[93]赵亚敏,唐习龙.基于ANSYS钢筋混凝土梁开裂有限元模拟研究[J].西部探矿工程,2007,(12).
[94]陈国良编著.并行算法的设计与分析[M],高等教育出版社,1994.
[95]程正兴编著.小波分析与应用[M],西安交通大学出版社,2000.
[96]都志辉编著.高性能计算并行编程技术—MPI并行程序设计,清华大学出版社,2001.
[97]陈国良编著.并行计算—结构·算法·编程[M],高等教育出版社,1999.
[98]莫则尧等编著.可扩展并行算法的设计与分析[[M],国防工业出版社,2001.
[99]李晓梅等编著.并行计算与偏微分方程数值解[M],国防科技大学出版社,1990.
[100]董小社编.并行编程技术培训教材,国家高性能计算中心(西安),2000.
[101]苏德富,梁正友,华云,并行计算技术及其应用[M],重庆大学出版社,2001.
[102]刘耀儒,周维垣,杨强,陈新.三维有限元并行计算及其工程应用[J].岩石力学与工程学报,2005,(14).
[103]王浩然,朱国荣,江思珉,王敏.基于区域分解法的地下水有限元并行数值模拟[J].南京大学学报(自然科学版),2005,(03)
[104]杨绍国,周熙襄.区域分解法地震正演模拟方法研究[J].地球物理学报,1996,(05)
[105]周叔子,曾金平,单桂华.用区域分解法计算最小曲面问题[J].数值计算与计算机应用,2002,(03)
[106]戴培良,沈树民.基于非协调元的区域分解法[J].计算数学,1995,(01)
[107]梁国平,梁平.杂交有限元的区域分解法[J].计算数学,1989,(03)
[108]黄建国.基于非协调元的区域分解法——强重迭情形[J].计算数学,1995,(01)
[109]陈绍炳.求热传导方程数值解并行算法[J].大学数学,1997,(02)
[110]周永霞,瞿建武,任安禄.粘性不可压缩三维流场分块算法研究[J].浙江大学学报(工学版),2002,(01)
[111]朱景辉.有限差分法中的区域分解算法[J].厦门大学学报(自然科学版),1995,(04)
[112]刘金朝,梁国平,胡齐芽.依赖时间的Lagrange乘子区域分解法的显式格式[J].计算数学,2001,(01)
[113]唐立民,陈万吉,刘迎曦.有限元分析中的拟协调元[J].大连理工大学学报,1980,(02).
[114]罗恩,魏文郎.弹性薄板弯曲分析的一种改进的三角形单元[J].华南理工大学学报(自然科学版),1979,(04).
[115]陈绍春,石钟慈.构造单元刚度矩阵的双参数法[J].计算数学,1991,(03).
[116]余天堂,姜弘道.有限元并行程序设计与实现[J].数值计算与计算机应用,2000,(02).
[117]程昭,陈胜宏,田胜利,葛修润.大规模p型有限元方程组的修正SSOR-PCG解法[J].上海交通大学学报,2002,(11).
[118]钟萍,邓联.对Choleski-PCG Newton算法的一些改进[J].中国农业大学学报,1999,(04).
[119]亓文果,金先龙,张晓云.冲击-接触问题有限元仿真的并行计算[J].振动与冲击,2006,(04).
[120]郑超,张建海.预处理共轭梯度法在岩土工程有限元中的应用[J].岩石力学与工程学报,2007,(S1).
[121]陈荣征,李代平,黄健.并行PCG算法在电法勘探中的应用研究[J].微计算机信息,2007,(12).
[122]雍进军,杨一都.基于PVM的m-Step Jacobi PCG方法网上并行求解有限元方程[J].贵州师范大学学报(自然科学版),2007,(01).
[123]付朝江,张武.结构有限元分析并行处理的研究进展[J].力学进展,2006,(03).
[124]刘耀儒,杨强,薛利军,周维垣.基于三维非线性有限元的边坡稳定分析方法[J].岩土力学,2007,(09).
[125]余天堂,姜弘道.基于PVM的网络并行子结构共轭梯度法[J].工程力学,2001,(05).
[126]赵文涛,王正华,刘仲,杨晓东.并行处理方法在液体火箭发动机三维数值模拟中的应用[J].国防科技大学学报,1999,(04).
[127]乐志华,程建钢,姚振汉.网络机群下多项式预处理EBE-PCG并行算法设计与实现[J].工程力学,2002,(05).
[128]刘杰,胡庆丰,韩国兴,迟利华.分布式存储环境下非平衡刚性方程组的数值并行计算[J].计算物理,2002,(01).
[129]黄孝成,廖道训.分布式并行计算的力学计算模型[J].华中科技大学学报,2001,(02).
[130]曹银锋,郑军,李光耀,钟志华.薄板冲压成形过程的并行有限元仿真技术[J].机械工程学报,2003,(07).
[131]G.Karypis,V.Kumar.A fast and high quality multilevel scheme for partitioning irregular graphs[J].SIAM J.Sci.Comput,1998,20(1):359-392.
[132]M.Al-Nasra,D.T.Nguyen.An algorithm for domain decomposition in finite element analysis[J].Computers & Structures 1991,39(3/4):277-289.
[133]H.Shang-Hsien.Evaluation of automatic domain partitioning algorithms for parallel finite element analysis[J].International Journal for Numerical Methods in Engineering,1997,40:1025-1051.
[134]B.Hendrickson,R.Leland.The chaco user's guide:version 2.0.Technical report SAND94-2692[R].Sandia National Laboratories,Albuquerque,NM,1994.
[135]G Karypis,V Kumar.Metis manual,http://glaros.dtc.umn.edu/gkhome/metis/metis/download.
[136]黄平,罗风光,曹明翠,王江义.一种宽带光总线互连网络机群系统设计[J].激光技术,2004,(02).
[137]孟庆平,刘淘英,李恪.机群系统管理的研究和实现[J].计算机科学,2003,(04).
[138]侯晓吻,张林波,张云泉.万亿次机群系统高性能应用软件运行现状分析[J].计算机工程,2005,(22).
[139]颜启华.机群系统网络通信性能的研究[J].计算机时代,2004,(01).
[140]邢座程,张民选,谢伦国,周兴铭.基于硬件虚拟接口结构的系统域网络设计[J].计算机学报,2006,(03).
[141]韩卫,刘昱琨,陈渝,都志辉.基于虚拟接口架构(VIA)的Benchmark的设计实现及性能测试与分析[J].科学技术与工程,2004,(06).
[142]高维成,刘伟,孙毅.利用约束试验提取自由结构模态参数的方法综述[J].强度与环境,2006,(01).
[143]邵小军,岳珠峰,刘永寿.对称削层复合材料结构的有限元分析[J].强度与环境,2006,(01).
[144]张建文,陈军,王强.并行程序加速比计算和分析[J].科技广场,2006,(01)
[145]张健飞,姜弘道.有限元并行计算的预处理[J].计算力学学报,2003,(04)
[146]孟凡忠.弹塑性有限变形理论和有限元方法[M].清华大学出版社,1985.
[147]欧阳鬯,马文华.弹性塑性有限元[M].湖南科学技术出版社,1983.
[148]D.Zois.Parallel processing techniques for FE analysis:Stiffness Loads and stress evaluation [J]. Computers and Structures, 1988, 29: 247-260.
[149] D. Zois. Parallel processing techniques for FE analysis: System solution [J]. Computers and Structures, 1988, 29: 261-274.
[150] C. H. Farhat. A parallel active column equation solver [J]. Computer s and Structures, 1988,29:261-274.
[151] I. S. Duff. Parallel implementation of mutifrontal schemes [J]. Parallel Computing, 1989, 3: 193-204.
[152] R. Voigt. The influence of vector computer architecture on numerical algorithms [J]. High Speed Computer and rithm Organization, Academic Press, New York, 1977.
[153] R. James. McCombs, Andreas Stathopoulos. Parallel, multigrain iterative solvers for hiding network latencies on MPPs and networks of clusters [J]. Parallel Computing, 2003, 29(9): 1237-1259.
[154] C. H. Farhat. A general approach to nonlinear FE computations on shared-memory multiprocessors [J], Comput. Meth. Appl. Engin, 1989, 72: 153-171.
[155] E. Barragy, Graham, F. Carey. A parallel element-by-element solution scheme [J]. International Journal For Numerical Methods In Engineering, 1988, 26: 2367-2382.
[156] A. Gullerud, R. J. Dodds. MPI based implementation of a PCG solver using an EBE architecture and preconditioner for implicit 3D finite element analysis [J]. Computers Structures, 2001, 79:553-575.
[157] A. Khan, B. Topping. Parallel finite element analysis using Jacobi-conditioned conjugate gradient algorithm [J]. Advances in Engineering Software, 1996, 25: 309-319.
[158] K. Chung, O. Richmond. Ideal forming-I, Homogeneous deformation with minimum plastic work. Int. Mech. Sci, 1992, 34(7): 575-591.
[159] C. A. Duarte I. Babuka and J. T. Oden. Generalized finite element methods for three-dimensional structural mechanics problems [J]. Computers and Structures, 2000, 77 (2): 215-232.
[160] C. A. Duarte, O.N. Hamzeh, T. J. Liszka, W. W. Tworzydlo. A generalized finite element method for the simulation of three-dimensional dynamic crack propagation [J]. Compu. Methods Appli. Mech. Engrg, 2001, 1909: 2227-2262.
[161] T. Strouboulis, I. Babuska, K. Copps. The design and analysis of the generalized finite element method [J]. Computational Methods in Applied Mathematics, 2000, 181: 43-69.
[162] T. Strouboulis, K. Copps, I. abuska. The generalized finite element method [J]. Comput Meth Appl Mech Engrg, 2001, 190:4081-193.
[163] A. K. Noor, et al. Structures technology for future aerospace systems [J]. Computers & Structures, 2000, 74(6).
[164] A.K.Noor. New computing systems and future highperformance computing environment and their impact on structural analysis and design [J]. Computers & Structures, 1997, 64(1): 1-30.
[165] D. Kennedy, WJ.Watkins, F.W.Williams. Hybrid parallel computation of transcendental structural eigenvalues [J]. AIAA Journal, 1995, 33(11): 2194-2198.
[166] I.W. Lee, M.C. Kim, A.R.Robinson. Determination of the natural frequencies and mode shapes for large structures by accelerated Newton-Raphon method [J]. Computer & Structure, 1997, 63(1): 61-68.
[2]彭承光,李运贵,卢帮华,邱奕超.台湾集集7.6级地震车笼埔发震断层场地灾害综述[J].地震科技情报,2000(9):9-13.
[3]太田阳子,黄振义.台湾中部9.21集集大地震的地震断层[J].地震科技情报,2001(2):22-24.
[4]王国权,周锡元,马宗晋,曾德民.921台湾地震近断层强地面运动的周期和幅值特性[J].工程抗震,2001,3(1):30-36.
[5]俞言祥,高孟潭.台湾集集地震近场地震动的上盘效应[J].地震学报,2001(23):616-621.
[6]D.D.Oglesby,S.M.Day.断层几何对1999年集集(台湾)地震的影响[J].世界地震译从,2002(6):38-42.
[7]D.D.Oglesby,R.J.Archuleta,S.B.Nielsen.Earthquake on dipping fault:the effects of broken symmetry[J].Science,1996,280:1055-1059.
[8]王国权,周锡元.台湾集集地震近断层强震地面运动加速度时程的随机特性[J].防灾减灾工程学报,2003(23):10-19.
[9]刘文兵,马丽.台湾集集和华北大同地震序列的定量模型分析[J].地震,2004(24):156-162.
[10]王国权,周锡元.921台湾集集地震近断层强震记录的基线校正[J].地震地质,2004,3(26):2-14.
[11]徐龙军,谢礼立.集集地震近断层地震动频谱特性[J].地震学报,2005(27):657-665.
[12]周仕勇,陈晓非.近震源破裂过程反演研究—9.21中国台湾集集地震破裂过程的近场反演[J].中国科学D辑,2006(36):49-58.
[13]M.N.Toks.1999年8月17日土耳其伊兹米特地震的初步报告[J].地壳构造与地壳应力,2000(2):28-32.
[14]张敏政,刘洁平.土耳其伊兹米特地震(1999,M7.4)的强地震动[J].世界地震工程,2000(16):2-7.
[15]韩竹军,张国民.伊兹米特地震发生的构造环境分析[J].国际地震动态,2000(1):2-7.
[16]韩竹军,苗崇刚.伊兹米特地震地表破裂带和发震构造特点[J].国际地震动态,2000(1):8-12.
[17]M.W esterhaus,R.Yilmaz,J.Zschau.1990年代期间b值和地壳形变的相关变化能够确定1999年8月17日伊兹米特特MW=7.4级地震的破裂起始[J].世界地震译丛,2003(4):7-22.
[18]杨光,沈繁銮.日本阪神地震灾害的一些调查统计数据[J].华南地震,2005(25):84-86.
[19]曹炳政,刘晶波.神户大开地铁车站的地震反应分析[J].地震工程与工程振动,2002(22):103-107.
[20]邓起东.2002.中国活动构造研究的进展与展望[J].地质论评,48(2):168-177.
[21]董敏煌.2000.地震勘探[M],东营:石油大学出版社.
[22]黄瑞树,冉洪流,高峥.1993.中国大陆地震震级和地震活动断层长度的关系讨论[J].地震地质,15(4):396-400.
[23]张晓志,谢礼立.采用显式有限元方法求解开放系统动力响应的主要环节和问题[J].地震工程与工程振动,2005(02):.
[24]张晓志,谢礼立,王海云,胡进军.近断层强地面运动影响场显式有限元数值模拟的示意性算例[J].地震工程与工程振动,2005(06).
[25]刘启方,袁一凡,金星,丁海平.近断层地震动的基本特征[J].地震工程与工程振动,2006,26(1):1-10.
[26]刘启方,丁海平,袁一凡(2003),三维地震断层动力破裂的显式有限元解法[J].地震工程与工程震动,2003,23(4):22-28.
[27]高孟潭,俞言祥,张晓梅,吴健,胡平,丁彦慧.北京地区地震动的三维有限差分模拟[J].中国地震,2002(04).
[28]郭恩栋,邵广彪,薄景山,石兆吉(2002),覆盖土层场地地震断裂反应分析方法[J].地震工程与工程振动,22(5),122-126.
[29]谢礼立,陶夏新,王国新.强地震动估计和地震危险性评定[J].东北地震研究,2001,(01).
[30]倪永军,朱晞.近断层地震的加速度峰值比和反应谱分析[J].北京交通大学学报,2004,(04).
[31]许力生,俞言祥,陈运泰.中国强地面运动研究进展[J].地震学报,2003,(05).
[32]M.Bouchon,Aki.Discrete wave number representation of seismic source wave fields[J].Bull.Seism.Soc.Am,1977,67:259-277.
[33]K.W.Campbell.Near-source attenuation of peak horizontal acceleration.Bulletin of the Seismological Society of America,1981,71,(6):2039-2070.
[34]N.Ambraseys,J.Bommer.The attenuation of ground acceleration in Europe[J].Earthquake Engineering and Structural Dynamics,1991,20(12):1179-1202.
[35]K.W.Campbell.Empirical near-source attenuations for horizontal and vertical components of peak ground acceleration,peak ground velocity,and pseudoabsolute acceleration response spectra[J].Seismological Research Letters,1997,68(1):154-179.
[36]P.G.Somerville,N.F.Smith,R.W.Graves,et al.Modifications of empirical strong ground motion attenuation relations to include the amplitude and duration effects of rupture directivity[J].Seismological Research Letters,1997,68(1):199-222.
[37]L.S.Chien.Parallel Processing techniques for finite element analysis of nonlinear large truss structures[J].Computers and Structures,1989,31:1023-1029.
[38]CHEN Pei-Shan,S.J.Duda.Fracture mechanics rupture model of earthquakes and an esumate of ambient shear stress[J].Phys Earth Planet Inter,1996,93(3-4):299-308.
[39]D.M.Boore,W.B.Joyner,T.E.Fumal.Equations for estimating horizontal response spectra and peak acceleration from Western North American earthquakes:A summary of recent work[J].Seismological Research Letters,1997,68(1):128-153.
[40]T.Mikumo,T.Miyatake.Dynamical rupture process on a three-dimensional fault with non-uniform frictions and near field seismic waves[J].Geophys.J.R.Soc,1978,54:417-438.
[41]P.G.Okubo,J.H.Dieterich.Effect of physical fault properties on frictional instabilities produced on simulated faults.J.Geophys.Res,1984,89(B7):5817-5827.
[42]S.Das,K.Aki.A numerical study of two-dimensional spontaneous rupture propagation[J].Geophys.J.R.Astr.Soc,1977,50:643-668.
[43]W.J.Renton.Aerospace and structures:where are we headed[J].International Journal of Solids and Structures,2001,38:3309-3319.
[44]廖振鹏,魏颖.设计地震加速度的合成[J].地震工程和工程震动,1988,18(5).
[45]金星.重大工程场地设计地震余地震动场的研究[D],中国地震局工程力学研究所博士学位论文,1992.
[46]金星(1994),地震动随机场的物理模拟[J].地震工程与工程震动,14(3):11-19.
[47]金星,陈超,张明宇,震源对地震动空间相关性影响的定量研究[J].地震工程与工程振动,2000,20(3):1-10.
[48]李小军.一维土层地震反应线性化计算程序,地震小区划—理论与实践,地震出版社.1989.
[49]廖振鹏.近场波动问题的有限元解法[J].地震工程与工程震动,1984(4):1-13.
[50]廖振鹏,刘晶波,波动有限元模拟的基本问题,中国科学(B),1992(8):874-882.
[51]廖振鹏.工程波动理论导引(第二版)[M].北京,科学出版社.2002.
[52]李世愚,陈运泰,地震震源研究[J].地震学报,2003,25(5):453-464.
[53]胡聿贤.地震工程学[M],地震出版社.1988.
[54]刘启方.断层附近强地面运动的初步研究[D].中国地震局工程力学研究所硕士学位论文.2001.
[55]刘启方,袁一凡,金星,断层附近地震动空间分布[J].地震学报,2004,26(2):183-192.
[56]刘启方.基于运动学和动力学展源模型的近断层地展动研究[D]:[博士学位论文].哈尔滨:中国地震局工程力学研究所.2005.
[57]陶夏新,王国新.近场强地震动模拟中对破裂的方向性效应和上盘效应的表达[J]地震学报,2003(02).
[58]宋惠珍,袁岩光,黄立人等.1976年唐山7.8级地震震源过程的研究[J].地震地质,1988,10(4):98-108.
[59]袁岩光,宋惠珍.受压斜裂纹稳定扩展过程的有限元法模拟及其讨论[J].现代地壳运 动研究,1989(4):69-77.
[60]曾海容.裂纹扩展与固液耦合三维有限单元正反演模型研究[D].北京:国家地震周地质研究所.1996.
[61]郭继武,冯小川.地基与基础[M].北京:清华大学出版社,1993:30-90.
[62]GUO Ji-wu,FENG Xiao-chuan.Groundwork and foundation[M].Bering:Tsinghua University Press,1993:30-90.
[63]杨绍普,申永军.滞后非线性系统的分岔与奇异性[M].北京:科学出版社,2003.
[64]宋惠珍,曾海容,剡公瑞.逆冲断层应力场的数值模拟[J].地震地质,1999,21(3):275-282.
[65]张玉娥,白宝鸿.地铁列车振动对隧道结构激振荷载的模拟[J].振动与冲击,2000,19(3):68-76.
[66]李德武,高峰.隧道基底结构列车振动现场测试与分析[J].甘肃科学学报,1999.
[67]王泳嘉,刑纪波.离散单元法同拉格朗日元法及其在岩土力学中的应用[J].岩土力学,1995,16(2):1-14.
[68]Babak Alavi and Helmut Krawinkler.Consideration of Near-Fault Ground Motion Effects in Seismic Design[J].12th World Conference on Earthquake Engineering,2000.
[69]崔培新.地铁列车振动异常问题探讨[J].铁道车辆,2001,39(12):18-21.
[70]曾国平,刘忠,徐家礼译.塑性力学有限元理论与应用[M].北京:兵器工业出版社,1989.112-379.
[71]潘昌实,张弥,吴鸿庆.隧道力学数值方法[M].北京:中国铁道出版社,1995,63-124.
[72]土动力学工程应用实例与分析[M].北京:中国建筑工业出版社,1998,186-196.
[73]任永生,周建鹏.汽车半主动悬架技术研究综述[J].振动与冲击,2006,25(3):162-165.
[74]翁建生,胡海岩.磁流变液体的流变力学特性试验和建模[J].应用力学学报,2000,17(3):1-5
[75]罗架洪.矩阵分析引论[M].华南理工大学出版社,2005.
[76]赵学仁.弹性力学基础[M].北京:北京理工大学出版社,1994
[77]刘波,韩彦辉.FLAC原理、实例与应用指南[M].北京:人民交通出版社,2005.
[78]黄润秋,许强.显式拉格朗日差分分析在岩石边坡工程中的应用[J].岩石力学与工程 学报,1995,14(4):346-354.
[79]赵和平,黄宏成,习纲,张建武.非线性弹簧汽车悬架动态特性研究[J].机械强度,2001,23(2):165-67.
[80]张东升,连志斌.桑塔纳2000型轿车的前悬架锤击法模态实验研究[J].汽车研究与开发,1999(1):23-27.
[81]刘继国,曾亚武.FLAC3D在深基坑开挖与支护数值模拟中的应用[J].岩土力学,2006,27(3):505-508.
[82]李亚荣,荣代潞,韩晓明.近断层水库大坝的震后变形问题分析[J].西北地震学报,2006,28(2):123-128.
[83]姚兰予,聂永安,赵根模.半无限空间中剪切断层错动产生的应力场[J].西北地震学报,2000,22(1):16-23.
[84]叶绍松,阮祥发,赵燕.有限元法在结构分析中的应用[J].机械研究与应用,2005,(04).
[85]陈乐生.第一讲什么是有限元方法[J].木工机床,2006,(02).
[86]张永刚.有限元法发展及其应用[J].科技情报开发与经济,2007,(11).
[87]于亚婷,杜平安,王振伟.有限元法的应用现状研究[J].机械设计,2005,(03).
[88]姜京伟,程阔.有限元网格划分剖析[J].山西交通科技,2007,(05).
[89]仇亚萍,黄俐军,冯立飞.基于ANSYS的有限元网格划分方法[J].机械管理开发,2007,(06).
[90]邢福生.结构有限元技术及其发展[J].水科学与工程技术,2005,(S1).
[91]高攀,黄放.有限元方法的发展状况和应用[J].电机技术,1999,(02).
[92]金杨洁.齿轮强度的有限元分析[J].汽齿科技,2007,(01).
[93]赵亚敏,唐习龙.基于ANSYS钢筋混凝土梁开裂有限元模拟研究[J].西部探矿工程,2007,(12).
[94]陈国良编著.并行算法的设计与分析[M],高等教育出版社,1994.
[95]程正兴编著.小波分析与应用[M],西安交通大学出版社,2000.
[96]都志辉编著.高性能计算并行编程技术—MPI并行程序设计,清华大学出版社,2001.
[97]陈国良编著.并行计算—结构·算法·编程[M],高等教育出版社,1999.
[98]莫则尧等编著.可扩展并行算法的设计与分析[[M],国防工业出版社,2001.
[99]李晓梅等编著.并行计算与偏微分方程数值解[M],国防科技大学出版社,1990.
[100]董小社编.并行编程技术培训教材,国家高性能计算中心(西安),2000.
[101]苏德富,梁正友,华云,并行计算技术及其应用[M],重庆大学出版社,2001.
[102]刘耀儒,周维垣,杨强,陈新.三维有限元并行计算及其工程应用[J].岩石力学与工程学报,2005,(14).
[103]王浩然,朱国荣,江思珉,王敏.基于区域分解法的地下水有限元并行数值模拟[J].南京大学学报(自然科学版),2005,(03)
[104]杨绍国,周熙襄.区域分解法地震正演模拟方法研究[J].地球物理学报,1996,(05)
[105]周叔子,曾金平,单桂华.用区域分解法计算最小曲面问题[J].数值计算与计算机应用,2002,(03)
[106]戴培良,沈树民.基于非协调元的区域分解法[J].计算数学,1995,(01)
[107]梁国平,梁平.杂交有限元的区域分解法[J].计算数学,1989,(03)
[108]黄建国.基于非协调元的区域分解法——强重迭情形[J].计算数学,1995,(01)
[109]陈绍炳.求热传导方程数值解并行算法[J].大学数学,1997,(02)
[110]周永霞,瞿建武,任安禄.粘性不可压缩三维流场分块算法研究[J].浙江大学学报(工学版),2002,(01)
[111]朱景辉.有限差分法中的区域分解算法[J].厦门大学学报(自然科学版),1995,(04)
[112]刘金朝,梁国平,胡齐芽.依赖时间的Lagrange乘子区域分解法的显式格式[J].计算数学,2001,(01)
[113]唐立民,陈万吉,刘迎曦.有限元分析中的拟协调元[J].大连理工大学学报,1980,(02).
[114]罗恩,魏文郎.弹性薄板弯曲分析的一种改进的三角形单元[J].华南理工大学学报(自然科学版),1979,(04).
[115]陈绍春,石钟慈.构造单元刚度矩阵的双参数法[J].计算数学,1991,(03).
[116]余天堂,姜弘道.有限元并行程序设计与实现[J].数值计算与计算机应用,2000,(02).
[117]程昭,陈胜宏,田胜利,葛修润.大规模p型有限元方程组的修正SSOR-PCG解法[J].上海交通大学学报,2002,(11).
[118]钟萍,邓联.对Choleski-PCG Newton算法的一些改进[J].中国农业大学学报,1999,(04).
[119]亓文果,金先龙,张晓云.冲击-接触问题有限元仿真的并行计算[J].振动与冲击,2006,(04).
[120]郑超,张建海.预处理共轭梯度法在岩土工程有限元中的应用[J].岩石力学与工程学报,2007,(S1).
[121]陈荣征,李代平,黄健.并行PCG算法在电法勘探中的应用研究[J].微计算机信息,2007,(12).
[122]雍进军,杨一都.基于PVM的m-Step Jacobi PCG方法网上并行求解有限元方程[J].贵州师范大学学报(自然科学版),2007,(01).
[123]付朝江,张武.结构有限元分析并行处理的研究进展[J].力学进展,2006,(03).
[124]刘耀儒,杨强,薛利军,周维垣.基于三维非线性有限元的边坡稳定分析方法[J].岩土力学,2007,(09).
[125]余天堂,姜弘道.基于PVM的网络并行子结构共轭梯度法[J].工程力学,2001,(05).
[126]赵文涛,王正华,刘仲,杨晓东.并行处理方法在液体火箭发动机三维数值模拟中的应用[J].国防科技大学学报,1999,(04).
[127]乐志华,程建钢,姚振汉.网络机群下多项式预处理EBE-PCG并行算法设计与实现[J].工程力学,2002,(05).
[128]刘杰,胡庆丰,韩国兴,迟利华.分布式存储环境下非平衡刚性方程组的数值并行计算[J].计算物理,2002,(01).
[129]黄孝成,廖道训.分布式并行计算的力学计算模型[J].华中科技大学学报,2001,(02).
[130]曹银锋,郑军,李光耀,钟志华.薄板冲压成形过程的并行有限元仿真技术[J].机械工程学报,2003,(07).
[131]G.Karypis,V.Kumar.A fast and high quality multilevel scheme for partitioning irregular graphs[J].SIAM J.Sci.Comput,1998,20(1):359-392.
[132]M.Al-Nasra,D.T.Nguyen.An algorithm for domain decomposition in finite element analysis[J].Computers & Structures 1991,39(3/4):277-289.
[133]H.Shang-Hsien.Evaluation of automatic domain partitioning algorithms for parallel finite element analysis[J].International Journal for Numerical Methods in Engineering,1997,40:1025-1051.
[134]B.Hendrickson,R.Leland.The chaco user's guide:version 2.0.Technical report SAND94-2692[R].Sandia National Laboratories,Albuquerque,NM,1994.
[135]G Karypis,V Kumar.Metis manual,http://glaros.dtc.umn.edu/gkhome/metis/metis/download.
[136]黄平,罗风光,曹明翠,王江义.一种宽带光总线互连网络机群系统设计[J].激光技术,2004,(02).
[137]孟庆平,刘淘英,李恪.机群系统管理的研究和实现[J].计算机科学,2003,(04).
[138]侯晓吻,张林波,张云泉.万亿次机群系统高性能应用软件运行现状分析[J].计算机工程,2005,(22).
[139]颜启华.机群系统网络通信性能的研究[J].计算机时代,2004,(01).
[140]邢座程,张民选,谢伦国,周兴铭.基于硬件虚拟接口结构的系统域网络设计[J].计算机学报,2006,(03).
[141]韩卫,刘昱琨,陈渝,都志辉.基于虚拟接口架构(VIA)的Benchmark的设计实现及性能测试与分析[J].科学技术与工程,2004,(06).
[142]高维成,刘伟,孙毅.利用约束试验提取自由结构模态参数的方法综述[J].强度与环境,2006,(01).
[143]邵小军,岳珠峰,刘永寿.对称削层复合材料结构的有限元分析[J].强度与环境,2006,(01).
[144]张建文,陈军,王强.并行程序加速比计算和分析[J].科技广场,2006,(01)
[145]张健飞,姜弘道.有限元并行计算的预处理[J].计算力学学报,2003,(04)
[146]孟凡忠.弹塑性有限变形理论和有限元方法[M].清华大学出版社,1985.
[147]欧阳鬯,马文华.弹性塑性有限元[M].湖南科学技术出版社,1983.
[148]D.Zois.Parallel processing techniques for FE analysis:Stiffness Loads and stress evaluation [J]. Computers and Structures, 1988, 29: 247-260.
[149] D. Zois. Parallel processing techniques for FE analysis: System solution [J]. Computers and Structures, 1988, 29: 261-274.
[150] C. H. Farhat. A parallel active column equation solver [J]. Computer s and Structures, 1988,29:261-274.
[151] I. S. Duff. Parallel implementation of mutifrontal schemes [J]. Parallel Computing, 1989, 3: 193-204.
[152] R. Voigt. The influence of vector computer architecture on numerical algorithms [J]. High Speed Computer and rithm Organization, Academic Press, New York, 1977.
[153] R. James. McCombs, Andreas Stathopoulos. Parallel, multigrain iterative solvers for hiding network latencies on MPPs and networks of clusters [J]. Parallel Computing, 2003, 29(9): 1237-1259.
[154] C. H. Farhat. A general approach to nonlinear FE computations on shared-memory multiprocessors [J], Comput. Meth. Appl. Engin, 1989, 72: 153-171.
[155] E. Barragy, Graham, F. Carey. A parallel element-by-element solution scheme [J]. International Journal For Numerical Methods In Engineering, 1988, 26: 2367-2382.
[156] A. Gullerud, R. J. Dodds. MPI based implementation of a PCG solver using an EBE architecture and preconditioner for implicit 3D finite element analysis [J]. Computers Structures, 2001, 79:553-575.
[157] A. Khan, B. Topping. Parallel finite element analysis using Jacobi-conditioned conjugate gradient algorithm [J]. Advances in Engineering Software, 1996, 25: 309-319.
[158] K. Chung, O. Richmond. Ideal forming-I, Homogeneous deformation with minimum plastic work. Int. Mech. Sci, 1992, 34(7): 575-591.
[159] C. A. Duarte I. Babuka and J. T. Oden. Generalized finite element methods for three-dimensional structural mechanics problems [J]. Computers and Structures, 2000, 77 (2): 215-232.
[160] C. A. Duarte, O.N. Hamzeh, T. J. Liszka, W. W. Tworzydlo. A generalized finite element method for the simulation of three-dimensional dynamic crack propagation [J]. Compu. Methods Appli. Mech. Engrg, 2001, 1909: 2227-2262.
[161] T. Strouboulis, I. Babuska, K. Copps. The design and analysis of the generalized finite element method [J]. Computational Methods in Applied Mathematics, 2000, 181: 43-69.
[162] T. Strouboulis, K. Copps, I. abuska. The generalized finite element method [J]. Comput Meth Appl Mech Engrg, 2001, 190:4081-193.
[163] A. K. Noor, et al. Structures technology for future aerospace systems [J]. Computers & Structures, 2000, 74(6).
[164] A.K.Noor. New computing systems and future highperformance computing environment and their impact on structural analysis and design [J]. Computers & Structures, 1997, 64(1): 1-30.
[165] D. Kennedy, WJ.Watkins, F.W.Williams. Hybrid parallel computation of transcendental structural eigenvalues [J]. AIAA Journal, 1995, 33(11): 2194-2198.
[166] I.W. Lee, M.C. Kim, A.R.Robinson. Determination of the natural frequencies and mode shapes for large structures by accelerated Newton-Raphon method [J]. Computer & Structure, 1997, 63(1): 61-68.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |