重构山体表面的非线性多重网格有限元反演算法

数学物理学报 ›› 2011, Vol. 31 ›› Issue (6): 1479-1489.

重构山体表面的非线性多重网格有限元反演算法

窦以鑫|韩波

哈尔滨工业大学数学系哈尔滨 150001

收稿日期:2010-08-24 修回日期:2011-12-01 出版日期:2011-12-25 发布日期:2011-12-25
基金资助:
中央高校基本科研业务费专项资金(2009051)资助

A Nonlinear Multigrid-FEM Inversion Algorithm for Reconstruction of a Mountain Surface

DOU Yi-Xin, HAN Bo

Department of Mathematics, Harbin Institute of Technology, Harbin 150001

Received:2010-08-24 Revised:2011-12-01 Online:2011-12-25 Published:2011-12-25
Supported by:
中央高校基本科研业务费专项资金(2009051)资助

摘要/Abstract

摘要：

山体重构模型是由两个过程构成:一个是山体内部的热对流扩散过程, 另一个是山体表面运动过程. 前者是描述三位空间中岩石温度变化规律, 后者则是描述二维空间中山体表面演变规律. 山体表面重构过程归结为求解该耦合方程的反演问题. 从数值计算的角度来讲, 求解该问题会遇到一些困难, 例如:优化非凸罚函数和大计算量的问题. 为了避免这些问题, 本文建议利用非线性多重网格有限元反演算法重构山体表面. 数值算例表明该算法具有很好的稳定性和收敛性.

关键词: 山体表面模型, 反问题, 非线性多重网格有限元

Abstract:

The modeling of reconstruction of a mountain surface is made of two processes: a thermal convection diffusion process inside a mountain and a mountain surface moving process. The former one describes the change of temperature of rocks in three dimensional spatial domain, and the latter one explains the evolution of a mountain surface in two dimensional spatial domain. The reconstruction of a mountain surface comes down to solving the inverse problem for this coupled system. From the point of view of numerical computation,
the authors shall experience some difficulties, for example, solving optimization of a non-convex cost functional and huge computational cost. In order to circumvent the difficulties above, the authors propose a nonlinear multigrid-FEM inversion algorithm to reconstruct a mountain surface. Numerical experiments show that this algorithm is efficient for this coupled system.

Key words: Modeling of Mountain Surface, Inverse Problem, Nonlinear Multigrid-FEM Inversion Algorithm

中图分类号:

65M32

窦以鑫, 韩波. 重构山体表面的非线性多重网格有限元反演算法[J]. 数学物理学报, 2011, 31(6): 1479-1489.

DOU Yi-Xin, HAN Bo. A Nonlinear Multigrid-FEM Inversion Algorithm for Reconstruction of a Mountain Surface[J]. Acta mathematica scientia,Series A, 2011, 31(6): 1479-1489.

参考文献

[1] Braun J. Quantifying the effect of recent relief changes on age-elevation relationships. Earth and Planetary Science Letters, 2002, 200: 331--343

[2] Braun J. Estimating exhumation rate and relief evolution by spectral analysis of age-elevation datasets. Terra Nova, 2002, 14: 210--214

[3] Braun J, Beek P V D, Batt G. Quantitative Thermochronology: Numerical Methods for the Interpretation of Thermochronological Data.
UK: Cambridge University Press, 2006: 33--48

[4] Ehlers T A, Chaudhri T, Kumar S, Fuller C W, Willett S D, Ketcham R, Brandon M T, Belton D, Kohn B, Gleadow A J, Dunai T, Fu F. Computational tools for low-temperature thermochronometer interpretation. Reviews in Mineralogy and Geochemistry, 2005, 58： 589--622

[5] Meesters A G C A, Dunai T J. Sloving the production-diffusion equation for finite diffusion domains of various shapes Part II:
Applications to cases with α-ejection and non-homogeneous distribution of the source. Chemical Geology, 2002a, 186: 347--363

[6] Reiners P W, Ehlers T A, Zeitler P. Past, present, and future of thermochronology. Reviews in Mineralogy and Geochemistry, 2005, 58: 1--18

[7] Ehlers T A, Farley K A. Apatite (U-Th)/He thermochronometry: methods and applications to problems in tectonic and surface processes. Earth and Planetary Science Letters, 2003, 206: 1--14

[8] House M A, Farley K A, Kohn B P. An empirical test of helium diffusion in spatite: borehole data from the Otway Basin, Australia. Earth
and Planetary Science Letters, 1999, 170: 463--474

[9] Reich M, Ewing R C, Ehlers T A, Becker U. Low-temperature anisotropic diffusion of helium in zircon: Implications for zircon (U-Th)/He thermochronometry. Geochemica Cosmochemica Acta, 2007, 71: 3119--3130

[10] Stockli D F, Linn J K, Dumitru T A. Calibration of the apatite (U-Th)/He thermochronometer on an exhumed fault block. White Mountains, California Geology, 2000, 28: 961--1056

[11] Warnock A C, Zeitler P, Wolf R A, Bergman S C. An evaluation of low-temperature apatite U-Th/He thermochronometry. Geochimica Cosmochimica Acta, 1997, 61: 5371--5377

[12] Chang Y, Xu C H, Peter W R, Zhou Z Y. The exhumation evolution of the Micang Shan-Hannan uplift since Cretaceous: Evidence from apatite (U-Th)/He dating. Chinese J Geophys (in Chinese), 2010, 53: 912--919

[13] Tomkin J H, Braun J. The influence of alpine glaciation on the relief of tectonically active mountain belts. American Journal of Science, 2002, 302: 169--190

[14] Oh S, Milstein A B, Bouman C A, Webb K J. A general framework for nonlinear multigrid inversion. IEEE Transactions on Image Processing, 2005, 14: 125--140

[15] Oh S, Milstein A B, Bouman C A, Webb K J. Multigrid algorithms for optimizations and inverse problems. In Proc the SPIE/IS&T Conference on Computational Imaging Santa Clara, CA, USA, 2003, 20-25: 59--70

[16] Nash S G. A multigrid approach to discretized optimization problems. J of Optimization Methods and Software, 2000, 14: 99--116

[17] Borcea L. Nonlinear multigrid for imaging electrical conductivity and permittivity at low frequency. Inverse Problems, 2001, 17: 329--359

[18] Bao G, Dou Y X, Ehlers T A, Li P J, Wang Y B, Xu Z F. Quantifying tectonic and geomorphic interpretations of thermochronometer data with inverse problem theory. Communications in Computational Physics, 2011, 9: 129--146

[19] Persson P, Strang G. A simple mesh generator in Matlab. SIAM Rev, 2004, 46: 329--345

[20] Brenner S C, Scott L R. The Mathematical Theory of Finite Element Methods. New York: Springer-Verlag, 2002

[21] Thomée V. Galerkin Finite Element Methods for Parabolic Problems. New York: Springer-Verlag, 1997

[22] 李红芳, 傅初黎, 熊向团, 南楠.一类求解抛物型方程侧边值问题的最优滤波方法. 数学物理学报,2009, 29A(1): 245--252

[23] Briggs W L, Henson V E, McCormick S F. A Multigrid Tutorial.Philadelphia: SIAM, 2000

[24] Engl H W, Hanke M, Neubauer A. Convergence rates for Tikhonov regulariza tion of nonlinear ill-posed problem. Inverse Problems, 1989, 5: 523--540