Abstract
This study proposes a new approach for the optimization of phase and magnitude responses of fractional-order capacitive and inductive elements based on the mixed integer-order genetic algorithm (GA), over a bandwidth of four-decade, and operating up to 1 GHz with a low phase error of approximately ±1°. It provides a phase optimization in the desired bandwidth with minimal branch number and avoids the use of negative component values, and any complex mathematical analysis. Standardized, IEC 60063 compliant commercially available passive component values are used; hence, no correction on passive elements is required. To the best knowledge of the authors, this approach is proposed for the first time in the literature. As validation, we present numerical simulations using MATLAB ® and experimental measurement results, in particular, the Foster-II and Valsa structures with five branches for precise and/or high-frequency applications. Indeed, the results demonstrate excellent performance and significant improvements over the Oustaloup approximation, the Valsa recursive algorithm, and the continued fraction expansion and the adaptability of the GA-based design with five different types of distributed RC/RL network.
Highlights
Tremendous efforts have been made to design fractional-order elements (FOEs)
The impedance of Type IV FOEs, i.e. fractional-order capacitors (FOCs), is provided with an order of −1 < α < 0 and pseudocapacitance of Cα = 1/K, whereas fractional-order inductors (FOIs) in quadrant I (Type I) have an order of 0 < α < 1 and pseudoinductance of Lα = K. These two FOEs are the key components in fractional-order circuit design and our main object of investigation in this work
BRIEF DISCUSSION OF RESULTS Table 3 compares the performance of RC networks built using Oustaloup, Continued Fraction Expansion (CFE), Recursive Algorithms (RAs), and the genetic algorithm (GA)
Summary
Tremendous efforts have been made to design fractional-order elements (FOEs). The impedance of Type IV FOEs, i.e. fractional-order capacitors (FOCs), is provided with an order of −1 < α < 0 and pseudocapacitance of Cα = 1/K , whereas fractional-order inductors (FOIs) in quadrant I (Type I) have an order of 0 < α < 1 and pseudoinductance of Lα = K These two FOEs are the key components in fractional-order circuit design and our main object of investigation in this work. Their characteristics such as pseudocapacitance, pseudoinductance, constant phase zone (CPZ), constant phase angle
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