{"title":"Higher derivatives of functions with given critical points and values","authors":"G. Goldman, Y. Yomdin","doi":"10.1007/s40687-024-00448-9","DOIUrl":null,"url":null,"abstract":"<p>Let <span>\\(f: B^n \\rightarrow {{\\mathbb {R}}}\\)</span> be a <span>\\(d+1\\)</span> times continuously differentiable function on the unit ball <span>\\(B^n\\)</span>, with <span>\\(\\mathrm{max\\,}_{z\\in B^n} \\Vert f(z) \\Vert =1\\)</span>. A well-known fact is that if <i>f</i> vanishes on a set <span>\\(Z\\subset B^n\\)</span> with a non-empty interior, then for each <span>\\(k=1,\\ldots ,d+1\\)</span> the norm of the <i>k</i>-th derivative <span>\\(||f^{(k)}||\\)</span> is at least <span>\\(M=M(n,k)>0\\)</span>. A natural question to ask is “what happens for other sets <i>Z</i>?”. This question was partially answered in Goldman and Yomdin (Lower bounds for high derivatives of smooth functions with given zeros. arXiv:2402.01388), Yomdin (Anal Math Phys 11:89, 2021), Yomdin (J Singul 25:443–455, 2022) and Yomdin (Higher derivatives of functions vanishing on a given set. arXiv:2108.02459v1). In the present paper, we ask a similar (and closely related) question: what happens with the high-order derivatives of <i>f</i>, if its gradient vanishes on a given set <span>\\(\\Sigma \\)</span>? And what conclusions for the high-order derivatives of <i>f</i> can be obtained from the analysis of the metric geometry of the “critical values set” <span>\\(f(\\Sigma )\\)</span>? In the present paper, we provide some initial answers to these questions.</p>","PeriodicalId":48561,"journal":{"name":"Research in the Mathematical Sciences","volume":"27 1","pages":""},"PeriodicalIF":1.2000,"publicationDate":"2024-05-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Research in the Mathematical Sciences","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1007/s40687-024-00448-9","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS","Score":null,"Total":0}
引用次数: 0
Abstract
Let \(f: B^n \rightarrow {{\mathbb {R}}}\) be a \(d+1\) times continuously differentiable function on the unit ball \(B^n\), with \(\mathrm{max\,}_{z\in B^n} \Vert f(z) \Vert =1\). A well-known fact is that if f vanishes on a set \(Z\subset B^n\) with a non-empty interior, then for each \(k=1,\ldots ,d+1\) the norm of the k-th derivative \(||f^{(k)}||\) is at least \(M=M(n,k)>0\). A natural question to ask is “what happens for other sets Z?”. This question was partially answered in Goldman and Yomdin (Lower bounds for high derivatives of smooth functions with given zeros. arXiv:2402.01388), Yomdin (Anal Math Phys 11:89, 2021), Yomdin (J Singul 25:443–455, 2022) and Yomdin (Higher derivatives of functions vanishing on a given set. arXiv:2108.02459v1). In the present paper, we ask a similar (and closely related) question: what happens with the high-order derivatives of f, if its gradient vanishes on a given set \(\Sigma \)? And what conclusions for the high-order derivatives of f can be obtained from the analysis of the metric geometry of the “critical values set” \(f(\Sigma )\)? In the present paper, we provide some initial answers to these questions.
让(f: B^n 是单位球上的(d+1)次连续可微分函数,其中({mathrm{max\,}_{z\in B^n}\f(z) =1)。一个众所周知的事实是,如果f在一个具有非空内部的集合(Z子集B^n)上消失,那么对于每一个(k=1,dots ,d+1),k-导数\(||f^{(k)}||||)的规范至少是\(M=M(n,k)>0\).一个自然的问题是 "其他集合 Z 会怎样?这个问题在 Goldman 和 Yomdin (Lower bounds for high derivatives of smooth functions with given zeros. arXiv:2402.01388), Yomdin (Anal Math Phys 11:89, 2021), Yomdin (J Singul 25:443-455, 2022) 和 Yomdin (Higher derivatives of functions vanishing on a given set. arXiv:2108.02459v1) 中得到了部分回答。在本文中,我们提出了一个类似(且密切相关)的问题:如果 f 的梯度在给定集合 \(\Sigma \) 上消失,那么 f 的高阶导数会发生什么变化?通过对 "临界值集"\(f(\Sigma )\的度量几何的分析,可以得到关于 f 的高阶导数的哪些结论?)在本文中,我们将为这些问题提供一些初步的答案。
期刊介绍:
Research in the Mathematical Sciences is an international, peer-reviewed hybrid journal covering the full scope of Theoretical Mathematics, Applied Mathematics, and Theoretical Computer Science. The Mission of the Journal is to publish high-quality original articles that make a significant contribution to the research areas of both theoretical and applied mathematics and theoretical computer science.
This journal is an efficient enterprise where the editors play a central role in soliciting the best research papers, and where editorial decisions are reached in a timely fashion. Research in the Mathematical Sciences does not have a length restriction and encourages the submission of longer articles in which more complex and detailed analysis and proofing of theorems is required. It also publishes shorter research communications (Letters) covering nascent research in some of the hottest areas of mathematical research. This journal will publish the highest quality papers in all of the traditional areas of applied and theoretical areas of mathematics and computer science, and it will actively seek to publish seminal papers in the most emerging and interdisciplinary areas in all of the mathematical sciences. Research in the Mathematical Sciences wishes to lead the way by promoting the highest quality research of this type.
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