A conformal differential invariant and the conformal rigidity of hypersurfaces
Abstract
For a hypersurface V of a conformal space, we introduce a conformal differential invariant I = h2/g, where g and h are the first and the second fundamental forms of V connected by the apolarity condition. This invariant is called the conformal quadratic element of V. The solution of the problem of conformal rigidity is presented in the framework of conformal differential geometry and connected with the conformal quadratic element of V. The main theorem states: Let n ≥ 4 and V and V' be two nonisotropic hypersurfaces without umbilical points in a conformal space Cn or a pseudoconformal space Cnq of signature (p, q), p = n - q. Suppose that there is a one-to-one correspondence f: V ---> V' between points of these hypersurfaces, and in the corresponding points of V and V' the following condition holds: I' = f* I, where f*: T (V) ---> T (V) is a mapping induced by the correspondence f. Then the hypersurfaces V and V' are conformally equivalent.
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