Friday, October 9, 2015

调和映射 that M is made of rubber and N made of marble (their shapes given by their respective metrics),


    Harmonic map (调和映射)


    Posted on 2011-12-24 15:48 无忧consume 阅读(65) 评论(0) 编辑 收藏
    Harmonic map 
    This article is about harmonic maps between Riemannian manifolds. For harmonic functions, see harmonic function.
    A (smooth) map φ:MN between Riemannian manifolds M and N is called harmonic if it is a critical point of the Dirichlet energy functional
    E(\varphi) = \int_M \|d\varphi\|^2\, d\operatorname{Vol}.
    This functional E will be defined precisely below—one way of understanding it is to imagine that M is made of rubber and N made of marble (their shapes given by their respective metrics), and that the map φ:MN prescribes how one "applies" the rubber onto the marble: E(φ) then represents the total amount of elastic potential energyresulting from tension in the rubber. In these terms, φ is a harmonic map if the rubber, when "released" but still constrained to stay everywhere in contact with the marble, already finds itself in a position of equilibrium and therefore does not "snap" into a different shape.
    Harmonic maps are the 'least expanding' maps in orthogonal directions.
    Existence of harmonic maps from a complete Riemannian manifold to a complete Riemannian manifold of non-positive sectional curvature was proved by Eells & Sampson (1964).

    Given Riemannian manifolds (M,g)(N,h) and φ as above, the energy density of φ at a point x in M is defined as[edit]Mathematical definition
    e(\varphi) = \frac12\|d\varphi\|^2
    where the \|d\varphi\|^2 is the squared norm of the differential of φ, with respect to the induced metric on the bundle T*M⊗φ−1TN. The total energy of φ is given by integrating the density over M
    E(\varphi) = \int_M e(\varphi)\, dv_g = \frac{1}{2} \int_M \|d\varphi\|^2\, dv_g
    where dvg denotes the measure on M induced by its metric. This generalizes the classical Dirichlet energy.
    The energy density can be written more explicitly as
    e(\varphi) = \frac12\operatorname{trace}_g\varphi^*h.
    Using the Einstein summation convention, in local coordinates the right hand side of this equality reads
    e(\varphi) = \frac12g^{ij}h_{\alpha\beta}\frac{\partial\varphi^\alpha}{\partial x^i}\frac{\partial\varphi^\beta}{\partial x^j}.
    If M is compact, then φ is called a harmonic map if it is a critical point of the energy functional E. This definition is extended to the case where M is not compact by requiring the restriction of φ to every compact domain to be harmonic, or, more typically, requiring that φ be a critical point of the energy functional in the Sobolev spaceH1,2(M,N).
    Equivalently, the map φ is harmonic if it satisfies the Euler-Lagrange equations associated to the functional E. These equations read
    \tau(\varphi)\ \stackrel{\text{def}}{=}\ \operatorname{trace}_g\nabla d\varphi = 0
    where ∇ is the connection on the vector bundle T*M⊗φ−1(TN) induced by the Levi-Civita connections on M and N. The quantity τ(φ) is a section of the bundle φ−1(TN) known as the tension field of φ. In terms of the physical analogy, it corresponds to the direction in which the "rubber" manifold M will tend to move in N in seeking the energy-minimizing configuration.
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