Roberts' type embeddings and conversion of the transversal Tverberg's theorem

Abstract

Here are two of our main results: Theorem 1. Let X be a normal space with dim X=n and m≥ n+1. Then the space C*(X,Rm) of all bounded maps from X into Rm equipped with the uniform convergence topology contains a dense Gδ-subset consisting of maps g such that g(X)d is at most (n+d-m)-dimensional for every d-dimensional plane d in Rm, where m-n≤ d≤ m. Theorem 2. Let X be a metrizable compactum with dim X≤ n and m≥ n+1. Then, C(X,Rm) contains a dense Gδ-subset of maps g such that for any integers t,d,T with 0≤ t≤ d≤ m-n-1 and d≤ T≤ m and any d-plane d⊂ Rm parallel to some coordinate planes t⊂T in Rm, the inverse image g-1(d) has at most q points, where q=d+1-t+n+(n+T-m)(d-t)m-n-d if n≥ (m-n-T)(d-t) and q=1+nm-n-T otherwise. In case m=2n+1, the combination of Theorem 1 and the Nobeling--Pontryagin embedding theorem provides a generalization of a theorem due to Roberts. Theorem 2 extends the following results: the N\"obeling--Pontryagin embedding theorem (d=0, m=T≥ 2n+1); Hurewicz's theorem about mappings into an Euclidean space with preimages of small cardinality (d=0, n+1≤ m=T≤ 2n); Boltyanski's theorem about k-regular maps (d=k-1, t=0, T=m≥ nk+n+k) and Goodsell's theorem about existence of special embeddings (t=0, T=m). An infinite-dimensional analogue of Theorem 2 is also established. Our results are based on Theorem 1.1 below which is considered as a converse assertion of the transversal Tverberg's theorem and implies the Berkowitz-Roy theorem.

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