Devon N. Munger, Andrew L. Nickerson, Pietro Paparella
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Although not the intent of their work, this initiated the process of proving Ito's theorem and hence providing another proof of the Karpelevič theorem.</p><p>The purpose of this work is to continue this effort by showing that an arc appears in the prescribed sector. To this end, it is shown that there is a continuous function <span><math><mi>λ</mi><mo>:</mo><mo>[</mo><mn>0</mn><mo>,</mo><mn>1</mn><mo>]</mo><mo>⟶</mo><mi>C</mi></math></span> such that <span><math><msup><mrow><mi>P</mi></mrow><mrow><mi>I</mi></mrow></msup><mo>(</mo><mi>λ</mi><mo>(</mo><mi>α</mi><mo>)</mo><mo>)</mo><mo>=</mo><mn>0</mn></math></span>, <span><math><mo>∀</mo><mi>α</mi><mo>∈</mo><mo>[</mo><mn>0</mn><mo>,</mo><mn>1</mn><mo>]</mo></math></span>, where <span><math><msup><mrow><mi>P</mi></mrow><mrow><mi>I</mi></mrow></msup></math></span> is a Type I reduced Ito polynomial. It is also shown that these arcs are simple. 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引用次数: 0
摘要
卡尔佩列维奇定理关于随机矩阵特征值在复平面中的位置(称为卡尔佩列维奇区域)的陈述冗长而复杂,其证明方法充其量也只是模糊不清。特别是,伊藤的定理断言卡尔佩列维奇区域的边界由弧线组成,而弧线的点满足多项式方程,该方程取决于弧线的端点。最近,约翰逊和帕帕雷拉证明了满足伊藤方程的点属于卡尔佩列夫区域。尽管这并不是他们工作的初衷,但这开启了证明伊藤定理的进程,从而为卡尔佩列维奇定理提供了另一个证明。为此,本文证明了存在连续函数 λ:[0,1]⟶C ,使得 PI(λ(α))=0, ∀α∈[0,1] ,其中 PI 是 I 型还原伊藤多项式。同时还证明了这些弧是简单的。最后,给出了一个基本论证,证明只要 n>3 时,卡尔佩列维奇区域边界上的点都是极值。
The statement of the Karpelevič theorem concerning the location of the eigenvalues of stochastic matrices in the complex plane (known as the Karpelevič region) is long and complicated and his proof methods are, at best, nebulous. Fortunately, an elegant simplification of the statement was provided by Ito—in particular, Ito's theorem asserts that the boundary of the Karpelevič region consists of arcs whose points satisfy a polynomial equation that depends on the endpoints of the arc. Unfortunately, Ito did not prove his version and only showed that it is equivalent.
More recently, Johnson and Paparella showed that points satisfying Ito's equation belong to the Karpelevič region. Although not the intent of their work, this initiated the process of proving Ito's theorem and hence providing another proof of the Karpelevič theorem.
The purpose of this work is to continue this effort by showing that an arc appears in the prescribed sector. To this end, it is shown that there is a continuous function such that , , where is a Type I reduced Ito polynomial. It is also shown that these arcs are simple. Finally, an elementary argument is given to show that points on the boundary of the Karpelevič region are extremal whenever .
期刊介绍:
Linear Algebra and its Applications publishes articles that contribute new information or new insights to matrix theory and finite dimensional linear algebra in their algebraic, arithmetic, combinatorial, geometric, or numerical aspects. It also publishes articles that give significant applications of matrix theory or linear algebra to other branches of mathematics and to other sciences. Articles that provide new information or perspectives on the historical development of matrix theory and linear algebra are also welcome. Expository articles which can serve as an introduction to a subject for workers in related areas and which bring one to the frontiers of research are encouraged. Reviews of books are published occasionally as are conference reports that provide an historical record of major meetings on matrix theory and linear algebra.
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