On some extremal problems of approximation theory of functions on the real axis I

Let H(D) be the linear space of analytic functions on a domain D of ℂ endowed with the topology of locally uniform convergence and let H‘(D) be the topological dual space of H(D). For domains D which are symmetric with respect to the real axis we use the notation Furthermore, denote by S the set of all univalent mappings f defined on the unit disk Δ which are normalized by f (0) = 0 and f‘(0) =1.

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On Graeffe's Method for Complex Roots of Algebraic Equations

Mathematical Proceedings of the Cambridge Philosophical Society ◽

10.1017/s0305004100002802 ◽

1924 ◽

Vol 22 (2) ◽

pp. 83-87 ◽

Cited By ~ 13

Author(s):

S. Brodetsky ◽

G. Smeal

Keyword(s):

Nineteenth Century ◽

Real Axis ◽

Practical Method ◽

Algebraic Equations ◽

Argand Diagram ◽

Considerable Difficulty ◽

The Real ◽

Real Roots ◽

Bipolar Coordinates ◽

Complex Roots

The only really useful practical method for solving numerical algebraic equations of higher orders, possessing complex roots, is that devised by C. H. Graeffe early in the nineteenth century. When an equation with real coefficients has only one or two pairs of complex roots, the Graeffe process leads to the evaluation of these roots without great labour. If, however, the equation has a number of pairs of complex roots there is considerable difficulty in completing the solution: the moduli of the roots are found easily, but the evaluation of the arguments often leads to long and wearisome calculations. The best method that has yet been suggested for overcoming this difficulty is that by C. Runge (Praxis der Gleichungen, Sammlung Schubert). It consists in making a change in the origin of the Argand diagram by shifting it to some other point on the real axis of the original Argand plane. The new moduli and the old moduli of the complex roots can then be used as bipolar coordinates for deducing the complex roots completely: this also checks the real roots.

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Reflection coefficient beyond all orders for singular problems. III. Essential singularities on the real axis

Journal of Mathematical Physics ◽

10.1063/1.529917 ◽

1992 ◽

Vol 33 (1) ◽

pp. 37-43 ◽

Cited By ~ 1

Author(s):

Jishan Hu

Keyword(s):

Reflection Coefficient ◽

Real Axis ◽

Singular Problems ◽

The Real

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Interaction between a nanocrack with surface elasticity and a screw dislocation

Mathematics and Mechanics of Solids ◽

10.1177/1081286515574147 ◽

2016 ◽

Vol 22 (2) ◽

pp. 131-143 ◽

Cited By ~ 10

Author(s):

Xu Wang ◽

Hui Fan

Keyword(s):

Screw Dislocation ◽

Real Axis ◽

Analytical Study ◽

Logarithmic Singularity ◽

Surface Elasticity ◽

Spontaneous Generation ◽

The Real ◽

Crack Tips ◽

Interaction Problem ◽

The Continuum

In the present analytical study, we consider the problem of a nanocrack with surface elasticity interacting with a screw dislocation. The surface elasticity is incorporated by using the continuum-based surface/interface model of Gurtin and Murdoch. By considering both distributed screw dislocations and line forces on the crack, we reduce the interaction problem to two decoupled first-order Cauchy singular integro-differential equations which can be numerically solved by the collocation method. The analysis indicates that if the dislocation is on the real axis where the crack is located, the stresses at the crack tips only exhibit the weak logarithmic singularity; if the dislocation is not on the real axis, however, the stresses exhibit both the weak logarithmic and the strong square-root singularities. Our result suggests that the surface effects of the crack will make the fracture more ductile. The criterion for the spontaneous generation of dislocations at the crack tip is proposed.

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Successive coefficients of close-to-convex functions

Forum Mathematicum ◽

10.1515/forum-2020-0092 ◽

2020 ◽

Vol 32 (5) ◽

pp. 1131-1141 ◽

Cited By ~ 2

Author(s):

Paweł Zaprawa

Keyword(s):

Real Axis ◽

Convex Functions ◽

Positive Direction ◽

The Real ◽

Coefficient Problems ◽

The Difference

AbstractIn this paper we discuss coefficient problems for functions in the class {{\mathcal{C}}_{0}(k)}. This family is a subset of {{\mathcal{C}}}, the class of close-to-convex functions, consisting of functions which are convex in the positive direction of the real axis. Our main aim is to find some bounds of the difference of successive coefficients depending on the fixed second coefficient. Under this assumption we also estimate {|a_{n+1}|-|a_{n}|} and {|a_{n}|}. Moreover, it is proved that {\operatorname{Re}\{a_{n}\}\geq 0} for all {f\in{\mathcal{C}}_{0}(k)}.

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Zeros of Dirichlet L-functions near the Real Axis and Chebyshev's Bias

Journal of Number Theory ◽

10.1006/jnth.2000.2601 ◽

2001 ◽

Vol 87 (1) ◽

pp. 54-76 ◽

Cited By ~ 4

Author(s):

Carter Bays ◽

Kevin Ford ◽

Richard H Hudson ◽

Michael Rubinstein

Keyword(s):

Real Axis ◽

The Real

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Exact Solutions of Some Extremal Problems of Approximation Theory

Springer Proceedings in Mathematics - Approximation Theory XIII: San Antonio 2010 ◽

10.1007/978-1-4614-0772-0_13 ◽

2011 ◽

pp. 221-229

Author(s):

A. L. Lukashov

Keyword(s):

Exact Solutions ◽

Approximation Theory ◽

Extremal Problems

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Pseudo-hermitian random matrix theory: a review

Journal of Physics Conference Series ◽

10.1088/1742-6596/2038/1/012009 ◽

2021 ◽

Vol 2038 (1) ◽

pp. 012009

Author(s):

Joshua Feinberg ◽

Roman Riser

Keyword(s):

Real Axis ◽

Complex Plane ◽

Random Matrix Theory ◽

Random Matrix ◽

Matrix Theory ◽

Complex Conjugate ◽

Indefinite Metric ◽

The Real ◽

New Type ◽

Diagrammatic Method

Abstract We review our recent results on pseudo-hermitian random matrix theory which were hitherto presented in various conferences and talks. (Detailed accounts of our work will appear soon in separate publications.) Following an introduction of this new type of random matrices, we focus on two specific models of matrices which are pseudo-hermitian with respect to a given indefinite metric B. Eigenvalues of pseudo-hermitian matrices are either real, or come in complex-conjugate pairs. The diagrammatic method is applied to deriving explicit analytical expressions for the density of eigenvalues in the complex plane and on the real axis, in the large-N, planar limit. In one of the models we discuss, the metric B depends on a certain real parameter t. As t varies, the model exhibits various ‘phase transitions’ associated with eigenvalues flowing from the complex plane onto the real axis, causing disjoint eigenvalue support intervals to merge. Our analytical results agree well with presented numerical simulations.

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