2018
DOI: 10.1049/iet-cds.2018.5123
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On boundary analysis for derivative of driving point impedance functions and its circuit applications

Abstract: In this study, a boundary analysis is carried out for the derivative of driving point impedance (DPI) functions, which is mainly used for the synthesis of networks containing resistor-inductor, resistor-capacitor and resistor-inductor-capacitor circuits. It is known that DPI function, Z(s), is an analytic function defined on the right half of the s-plane. In this study, the authors present four theorems using the modulus of the derivative of DPI function, |Z′(0)|, by assuming the Z(s) function is also analytic… Show more

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Cited by 10 publications
(5 citation statements)
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References 19 publications
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“…An extension of the realizability conditions, as given in Örnek and Düzenli, to the nonrational functions requires that each and every approximant is convergent and realizable (as stated above). Therefore, for the function N ( s ) to be realizable, P n ( s ) must be a polynomial with positive coefficients for all n ; then, using , we can prove the theorem that, if the coefficients of P n ( s ) are positive for all n and scriptGfalse[Nfalse(sfalse)false]false(xfalse) is positive for x ∈ ζ , then Q n ( s ) is a polynomial with positive coefficients. The degree of Q n ( s ) is one less than the degree of P n ( s ). …”
Section: Generalized Synthesis Methods and Synthesis Criteriamentioning
confidence: 99%
See 1 more Smart Citation
“…An extension of the realizability conditions, as given in Örnek and Düzenli, to the nonrational functions requires that each and every approximant is convergent and realizable (as stated above). Therefore, for the function N ( s ) to be realizable, P n ( s ) must be a polynomial with positive coefficients for all n ; then, using , we can prove the theorem that, if the coefficients of P n ( s ) are positive for all n and scriptGfalse[Nfalse(sfalse)false]false(xfalse) is positive for x ∈ ζ , then Q n ( s ) is a polynomial with positive coefficients. The degree of Q n ( s ) is one less than the degree of P n ( s ). …”
Section: Generalized Synthesis Methods and Synthesis Criteriamentioning
confidence: 99%
“…Finite subset of an RL ladder circuit for the Lambert W function An extension of the realizability conditions, as given in Örnek and Düzenli, 23 to the nonrational functions requires that each and every approximant is convergent and realizable (as stated above). Therefore, for the function N(s) to be realizable, P n (s) must be a polynomial with positive coefficients for all n; then, using (8), we can prove the theorem that, if the coefficients of P n (s) are positive for all n and [N(s)](x) is positive for x ∈ , then 1.…”
Section: Figurementioning
confidence: 99%
“…( ) süren nokta empedans fonksiyonunun türevinin modülünün sıfır noktasındaki değeri, yani | ′(0)| göz önüne alınarak üç teorem içerisinde ′( ) için üç alt sınır sunulmaktadır. [9] ve [10]…”
Section: Buradaunclassified
“…Usage of positive real function and boundary analysis of these functions for circuit synthesis can be given as an exemplary application of the Schwarz lemma in electrical engineering. Furthermore, it is also used for analysis of transfer functions in control engineering and multi-notch filter design in signal processing [14][15][16].…”
Section: Introductionmentioning
confidence: 99%