The Real and Complex Number Systems

2008 ◽  
pp. 231-250
Author(s):  
Alexander S. Poznyak
Keyword(s):  
Complex Number ◽  
The Real ◽  
Number Systems

scholarly journals Approximate Closed-Form Formulas for the Zeros of the Bessel Polynomials

2012 ◽  
Vol 2012 ◽  
pp. 1-10
Author(s):  
Rafael G. Campos ◽  
Marisol L. Calderón
Keyword(s):  
Closed Form ◽  
Complex Plane ◽  
Complex Number ◽  
Bessel Polynomials ◽  
The Real ◽  
Bessel Polynomial ◽  
Limit Points ◽  
Electrostatic Interpretation ◽  
Approximate Expressions

We find approximate expressionsx̃(k,n,a)andỹ(k,n,a)for the real and imaginary parts of thekth zerozk=xk+iykof the Bessel polynomialyn(x;a). To obtain these closed-form formulas we use the fact that the points of well-defined curves in the complex plane are limit points of the zeros of the normalized Bessel polynomials. Thus, these zeros are first computed numerically through an implementation of the electrostatic interpretation formulas and then, a fit to the real and imaginary parts as functions ofk,nandais obtained. It is shown that the resulting complex numberx̃(k,n,a)+iỹ(k,n,a)isO(1/n2)-convergent tozkfor fixedk.

scholarly journals Some inequalities in Pseudo-Hilbert spaces

2011 ◽  
Vol 42 (4) ◽  
pp. 483-492
Author(s):  
Loredana Ciurdariu
Keyword(s):  
Linear Space ◽  
Number Field ◽  
Hilbert Spaces ◽  
Complex Number ◽  
Normed Linear Space ◽  
Normed Algebra ◽  
The Real ◽  
Complex Number Field

The aim of this paper is to obtain new versions of the reverse of the generalized triangle inequalities given in \cite{SSDNA}, %[4],and \cite{SSDPR} %[5] if the pair $(a_i,x_i),\;i\in\{1,\ldots,n\}$ from Theorem 1 of \cite{SSDNA} %[4] belongs to ${\mathbb C}\times\mathcal H $, where $\mathcal H$ is a Loynes $Z$-space instead of ${\mathbb K}\times X$, $X$ being a normed linear space and ${\mathbb K}$ is the field of scalars. By comparison, in \cite{SSDNA} %[4] the pair $(a_i,x_i),\;i\in\{1,\ldots,n\}$ belongs to $A^2$, where $A$ is a normed algebra over the real or complex number field ${\mathbb K}.$ The results will be given in Theorem 1, Theorem 3, Remark 2 and Corollary 3 which represent other interesting variants of Theorem 2.1, Remark 2.2, Theorem 3.2 and Theorem 3.4., see \cite{SSDNA}. %[4].

Event Structure without naïve Physics

2019 ◽  
pp. 170-204
Author(s):  
Henk J. Verkuyl
Keyword(s):  
Building Block ◽  
Event Structure ◽  
Cognitive Capacity ◽  
The Real ◽  
Real Nature ◽  
Number Systems ◽  
Naive Physics

What is the real nature of the aspectual division between perfective and imperfective as revealed by the well-known in/for-test? The answer is founded on the idea that this division between completion and incompletion mirrors our cognitive capacity to shift between discreteness and continuity as expressed in the number systems N and R. To get at the real contribution of a verb to aspectual information, the first step is to determine the basic atemporal building block making a tenseless verb stative or non-stative. For this, verbhood is to be understood aspectually in a very strict way abstracting from the contribution of arguments. It follows that one has to get ‘below’ event structure in order to see why the in/for-test works as it turns out to do (or in some cases not).

scholarly journals A Note on Resultants of Equations in a Cyclic Number System

1932 ◽  
Vol 3 (1) ◽  
pp. 26-29
Author(s):  
R. Wilson
Keyword(s):  
Division Algebra ◽  
Complex Number ◽  
Number System ◽  
Number Systems ◽  
Image Position

§ 1. Introduction. Little is known concerning the theory of resultants of equations other than in the complex number system. The cyclic number systems provide a simple example which is not a division algebra. In such a system with n units er. any number y ≡ y0 + y1e1 + y2e2 + … + yn−1en−1 has coefficients yr drawn from a field, and the units satisfy the product law:

Forced Torsional Vibrations With Damping: An Extension of Holzer’s Method

1946 ◽  
Vol 13 (4) ◽  
pp. A276-A280
Author(s):  
J. P. Den Hartog ◽  
J. P. Li
Keyword(s):  
Distributed Systems ◽  
Imaginary Part ◽  
Complex Number ◽  
Torsional Vibrations ◽  
The Real ◽  
Damped Systems

Abstract An extension of Holzer’s method is given for the case of damped systems of discreet as well as of uniformly distributed inertias and flexibilities. For discreet systems the modification in the Holzer table consists of replacing I by I − jc0/ω, and of replacing k by k + jωci, whereby most numbers in the tables become complex. The meaning of the real part of any complex number is that quantity which is in time-phase with the motion at the free end, while the imaginary part is 90 deg out of time-phase with that motion. For distributed systems the results are given by Equations [12] and [12a] for a free forward end; by Equations [13] and [13a] for a damped forward end, while the letters a and b appearing in these results are defined by Equations [8] and [8a].

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