Root geometry of polynomial sequences II: Type (1,0)

Jonathan L. Gross; Toufik Mansour; Thomas W. Tucker; David G.L. Wang

doi:10.1016/j.jmaa.2016.04.033

Root geometry of polynomial sequences II: Type (1,0)

Jonathan L. Gross, Toufik Mansour, Thomas W. Tucker, David G.L. Wang^*

^*Corresponding author for this work

School of Mathematics and Statistics

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

We consider the sequence of polynomials W_n(x) defined by the recursion W_n(x)=(ax+b)W_n-1(x)+dW_n-2(x), with initial values W₀(x)=1 and W₁(x)=t(x-r), where a, b, d, t, r are real numbers, with a, t>0 and d<0. It is known that every polynomial W_n(x) is distinct-real-rooted. We find that, as n→∞, the smallest root of the polynomial W_n(x) converges decreasingly to a real number, and that the largest root converges increasingly to a real number. Moreover, by using the Dirichlet approximation theorem, we prove that for every integer j≥2, the jth smallest root of the polynomial W_n(x) converges as n→∞, and so does the jth largest root. It turns out that these two convergence points are independent of the numbers t, r, and the integer j. We obtain explicit expressions for the above four limit points.

Original language	English
Pages (from-to)	499-528
Number of pages	30
Journal	Journal of Mathematical Analysis and Applications
Volume	441
Issue number	2
DOIs	https://doi.org/10.1016/j.jmaa.2016.04.033
Publication status	Published - 15 Sept 2016

Keywords

Dirichlet's approximation theorem
Real-rooted polynomial
Recurrence
Root geometry

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@article{09d9cda9927041f2b31aa2a6f4b88d93,

title = "Root geometry of polynomial sequences II: Type (1,0)",

abstract = "We consider the sequence of polynomials Wn(x) defined by the recursion Wn(x)=(ax+b)Wn-1(x)+dWn-2(x), with initial values W0(x)=1 and W1(x)=t(x-r), where a, b, d, t, r are real numbers, with a, t>0 and d<0. It is known that every polynomial Wn(x) is distinct-real-rooted. We find that, as n→∞, the smallest root of the polynomial Wn(x) converges decreasingly to a real number, and that the largest root converges increasingly to a real number. Moreover, by using the Dirichlet approximation theorem, we prove that for every integer j≥2, the jth smallest root of the polynomial Wn(x) converges as n→∞, and so does the jth largest root. It turns out that these two convergence points are independent of the numbers t, r, and the integer j. We obtain explicit expressions for the above four limit points.",

keywords = "Dirichlet's approximation theorem, Real-rooted polynomial, Recurrence, Root geometry",

author = "Gross, {Jonathan L.} and Toufik Mansour and Tucker, {Thomas W.} and Wang, {David G.L.}",

note = "Publisher Copyright: {\textcopyright} 2016 Elsevier Inc.",

year = "2016",

month = sep,

day = "15",

doi = "10.1016/j.jmaa.2016.04.033",

language = "English",

volume = "441",

pages = "499--528",

journal = "Journal of Mathematical Analysis and Applications",

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TY - JOUR

T1 - Root geometry of polynomial sequences II

T2 - Type (1,0)

AU - Gross, Jonathan L.

AU - Mansour, Toufik

AU - Tucker, Thomas W.

AU - Wang, David G.L.

PY - 2016/9/15

Y1 - 2016/9/15

N2 - We consider the sequence of polynomials Wn(x) defined by the recursion Wn(x)=(ax+b)Wn-1(x)+dWn-2(x), with initial values W0(x)=1 and W1(x)=t(x-r), where a, b, d, t, r are real numbers, with a, t>0 and d<0. It is known that every polynomial Wn(x) is distinct-real-rooted. We find that, as n→∞, the smallest root of the polynomial Wn(x) converges decreasingly to a real number, and that the largest root converges increasingly to a real number. Moreover, by using the Dirichlet approximation theorem, we prove that for every integer j≥2, the jth smallest root of the polynomial Wn(x) converges as n→∞, and so does the jth largest root. It turns out that these two convergence points are independent of the numbers t, r, and the integer j. We obtain explicit expressions for the above four limit points.

AB - We consider the sequence of polynomials Wn(x) defined by the recursion Wn(x)=(ax+b)Wn-1(x)+dWn-2(x), with initial values W0(x)=1 and W1(x)=t(x-r), where a, b, d, t, r are real numbers, with a, t>0 and d<0. It is known that every polynomial Wn(x) is distinct-real-rooted. We find that, as n→∞, the smallest root of the polynomial Wn(x) converges decreasingly to a real number, and that the largest root converges increasingly to a real number. Moreover, by using the Dirichlet approximation theorem, we prove that for every integer j≥2, the jth smallest root of the polynomial Wn(x) converges as n→∞, and so does the jth largest root. It turns out that these two convergence points are independent of the numbers t, r, and the integer j. We obtain explicit expressions for the above four limit points.

KW - Dirichlet's approximation theorem

KW - Real-rooted polynomial

KW - Recurrence

KW - Root geometry

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U2 - 10.1016/j.jmaa.2016.04.033

DO - 10.1016/j.jmaa.2016.04.033

M3 - Article

AN - SCOPUS:84965014128

SN - 0022-247X

VL - 441

SP - 499

EP - 528

JO - Journal of Mathematical Analysis and Applications

JF - Journal of Mathematical Analysis and Applications

IS - 2

ER -

Root geometry of polynomial sequences II: Type (1,0)

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Keywords

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