Add to ORKGSelf-similar electric circuits that represent three-dimensional models of different physical processes (phenomena of dielectric relaxation, electrochemical processes, etc.) are considered. For the first time, exact functional equations for the overall conductance (admittance) Y(jω) of these resistance-capacitance circuits are derived and solved. Based on the self-similar structure of circuits, it is shown that in the frequency range, admittance represents a sum of fractional-exponential expressions with one real and a pair of complex-conjugate exponents (in further text, complex exponents). Thus, it is demonstrated that the set of processes occurring in different parts of the circuit and associated with charge transfer (capacitance C) and e...
In this paper, the self-similar functional circuit models of arteries are proposed for bioinspired h...
We examine the most simple and deterministic model of partial-discharge phenomena, or the three-cap...
Abstract. The generalised resistance between connected points a distance 4 apart on fractal networks...
Self-similar electric circuits that represent three-dimensional models of different physical process...
In the first section of this work is further analyzed the theories of differential equations and the...
The current flows in a porous media is a very complex nature phenomenon, and it is very difficult to...
Response of an electrode under finite charge transfer rate is strongly influenced by morphological a...
International audienceA new modeling approach for electrical networks is introduced in this paper ba...
The equivalent resistance of a fractal-like network is calculated by means of approaches similar to ...
An intuitive model is proposed in this paper to describe the electrical behavior of certain ultracap...
Article Outline Glossary I. Definition of the Subject II. Introduction to Current Flows III. Solving...
This work is focused on computer simulations of fractal capacitors. The geometry of capacitors and i...
Understanding an electrode-electrolyte interface (EEI) behavior is a valuable tool in several areas ...
Fractal electrode designs are proposed for electrochemical devices. A zeroth-order approximation fra...
This generalization incorporates various phenomenological components involved in complete dynamical ...
In this paper, the self-similar functional circuit models of arteries are proposed for bioinspired h...
We examine the most simple and deterministic model of partial-discharge phenomena, or the three-cap...
Abstract. The generalised resistance between connected points a distance 4 apart on fractal networks...
Self-similar electric circuits that represent three-dimensional models of different physical process...
In the first section of this work is further analyzed the theories of differential equations and the...
The current flows in a porous media is a very complex nature phenomenon, and it is very difficult to...
Response of an electrode under finite charge transfer rate is strongly influenced by morphological a...
International audienceA new modeling approach for electrical networks is introduced in this paper ba...
The equivalent resistance of a fractal-like network is calculated by means of approaches similar to ...
An intuitive model is proposed in this paper to describe the electrical behavior of certain ultracap...
Article Outline Glossary I. Definition of the Subject II. Introduction to Current Flows III. Solving...
This work is focused on computer simulations of fractal capacitors. The geometry of capacitors and i...
Understanding an electrode-electrolyte interface (EEI) behavior is a valuable tool in several areas ...
Fractal electrode designs are proposed for electrochemical devices. A zeroth-order approximation fra...
This generalization incorporates various phenomenological components involved in complete dynamical ...
In this paper, the self-similar functional circuit models of arteries are proposed for bioinspired h...
We examine the most simple and deterministic model of partial-discharge phenomena, or the three-cap...
Abstract. The generalised resistance between connected points a distance 4 apart on fractal networks...