Geometric Optics for Surface Waves in Nonlinear Elasticity(Memoirs of the American Mathematical Society)
具有非线性弹性的表面波的几何光学
数学分析
¥
848.00
售 价:
¥
678.00
优惠
平台大促 低至8折优惠
发货周期:国外库房发货,通常付款后3-5周到货!
出版时间
2020年04月30日
装 帧
平装
页 码
143
语 种
英文
综合评分
暂无评分
- 图书详情
- 目次
- 买家须知
- 书评(0)
- 权威书评(0)
图书简介
This work is devoted to the analysis of high frequency solutions to the equations of nonlinear elasticity in a half-space. The authors consider surface waves (or more precisely, Rayleigh waves) arising in the general class of isotropic hyperelastic models, which includes in particular the Saint Venant-Kirchhoff system. Work has been done by a number of authors since the 1980s on the formulation and well-posedness of a nonlinear evolution equation whose (exact) solution gives the leading term of an approximate Rayleigh wave solution to the underlying elasticity equations. This evolution equation, which is referred to as ``the amplitude equation’’, is an integrodifferential equation of nonlocal Burgers type. The authors begin by reviewing and providing some extensions of the theory of the amplitude equation. The remainder of the paper is devoted to a rigorous proof in 2D that exact, highly oscillatory, Rayleigh wave solutions $u^{varepsilon} $ to the nonlinear elasticity equations exist on a fixed time interval independent of the wavelength $varepsilon $, and that the approximate Rayleigh wave solution provided by the analysis of the amplitude equation is indeed close in a precise sense to $u^{varepsilon}$ on a time interval independent of $varepsilon $. This paper focuses mainly on the case of Rayleigh waves that are pulses, which have profiles with continuous Fourier spectrum, but the authors’ method applies equally well to the case of wavetrains, whose Fourier spectrum is discrete.
本书暂无推荐
本书暂无推荐
看了又看
- 上一个
