Nature inspired algorithm based design of near ideal fractional order low pass Chebyshev filters and their realization using OTAs and CCII

IF 2.2 3区工程技术 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Integration-The Vlsi Journal Pub Date : 2024-03-25 DOI:10.1016/j.vlsi.2024.102185

Ritu Daryani, Bhawna Aggarwal

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引用次数: 0

Abstract

Fractional order filters offer greater freedom of design and a precise control over stopband attenuation in electronic circuits and systems. This paper presents the design of a fractional order low pass Chebyshev filter (FOLCF) that achieves near-ideal response characteristics. The methodology introduced utilizes metaheuristic optimization methods, including particle swarm optimization, firefly algorithm, and grey wolf optimization. These techniques are employed to precisely adjust the filter coefficients for the orders (1+α), (2+α), and (3+α). The adjustment is carried out by comparing the desired behaviour of the FOLCF with generalized fractional order low pass transfer functions. Throughout these instances, the parameter α is varied within the range of (0, 1). The designed filters are then tested and compared on the basis of various factors. Simulation results demonstrate that the designed filters closely follow the behaviour of an ideal Chebyshev filter with maximum passband and stopband magnitude errors being −31.93 dB and −52.74 dB respectively for (1+α) order filters. These values for (2+α) and (3+α) order FOLCF have been observed to be −30.04 dB and −55.91 dB; −17.72 dB and −49.52 dB respectively. Furthermore, it has been observed that the proposed work outperforms existing state-of-the-art approaches in various aspects, including magnitude error, stopband attenuation, and cut-off frequency. The stability of the designed filters has been verified through stability analysis. Additionally, practical feasibility of the proposed FOLCF is demonstrated through SPICE simulations for α = [0.2,0.5,0.8] using second generation current conveyor (CCII) and operational transconductance amplifier (OTA) based topologies while approximating the constant phase element using fifth order continued fraction expansion. The SPICE implementations closely follow the behaviour of ideal filter with −48.67 dB and −62.8 dB as mean square errors for CCII and OTA circuits respectively, showcasing the proposed filters' superiority and practical applicability in advanced electronic design.

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基于自然启发算法的近理想分数阶低通切比雪夫滤波器设计及其利用 OTA 和 CCII 的实现

分数阶滤波器为设计提供了更大的自由度，并能精确控制电子电路和系统中的阻带衰减。本文介绍了一种分数阶低通切比雪夫滤波器（FOLCF）的设计，它能实现接近理想的响应特性。所介绍的方法利用了元启发式优化方法，包括粒子群优化、萤火虫算法和灰狼优化。这些技术用于精确调整 (1+α)、(2+α) 和 (3+α) 阶的滤波器系数。调整是通过比较 FOLCF 与广义分数阶低通滤波器的理想行为来进行的。在整个过程中，参数 α 在 (0, 1) 的范围内变化。然后，根据各种因素对所设计的滤波器进行测试和比较。仿真结果表明，所设计的滤波器非常接近理想的切比雪夫滤波器，对于 (1+α) 阶滤波器，最大通带和止带幅度误差分别为 -31.93 dB 和 -52.74 dB。对于 (2+α) 和 (3+α) 阶 FOLCF，这些数值分别为 -30.04 dB 和 -55.91 dB；-17.72 dB 和 -49.52 dB。此外，研究还发现，所提出的方法在幅度误差、阻带衰减和截止频率等各个方面都优于现有的最先进方法。通过稳定性分析，验证了所设计滤波器的稳定性。此外，通过使用基于第二代电流传输器（CCII）和运算跨导放大器（OTA）的拓扑结构对 α = [0.2,0.5,0.8]进行 SPICE 仿真，同时使用五阶续分数扩展近似恒定相位元素，证明了所提出的 FOLCF 的实际可行性。SPICE 实现与理想滤波器的行为密切相关，CCII 和 OTA 电路的均方误差分别为 -48.67 dB 和 -62.8 dB，显示了所提出的滤波器在高级电子设计中的优越性和实用性。

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来源期刊

Integration-The Vlsi Journal 工程技术-工程：电子与电气

CiteScore

3.80

自引率

5.30%

发文量

107

审稿时长

6 months

期刊介绍： Integration''s aim is to cover every aspect of the VLSI area, with an emphasis on cross-fertilization between various fields of science, and the design, verification, test and applications of integrated circuits and systems, as well as closely related topics in process and device technologies. Individual issues will feature peer-reviewed tutorials and articles as well as reviews of recent publications. The intended coverage of the journal can be assessed by examining the following (non-exclusive) list of topics: Specification methods and languages; Analog/Digital Integrated Circuits and Systems; VLSI architectures; Algorithms, methods and tools for modeling, simulation, synthesis and verification of integrated circuits and systems of any complexity; Embedded systems; High-level synthesis for VLSI systems; Logic synthesis and finite automata; Testing, design-for-test and test generation algorithms; Physical design; Formal verification; Algorithms implemented in VLSI systems; Systems engineering; Heterogeneous systems.