使用单个有源元件的电子可调谐接地和浮动电容倍增器

IF 1.2 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS Journal of Electrical and Computer Engineering Pub Date : 2024-05-23 DOI:10.1155/2024/6628863
Nuttapon Seechaiya, Winai Jaikla, Amornchai Chaichana, Phamorn Silapan, Piya Supavarasuwat, Peerawut Suwanjan
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引用次数: 0

摘要

电容倍增器是一种有源电路,专门用于将无源电容器的电容增大到明显更高的电容水平。本文提出使用电压差分差动放大器(VDDDA)这一电子可控有源器件来设计接地和浮动电容倍增器。本研究提出的电容乘法器非常简单,由一个 VDDDA、一个电阻器和一个电容器组成。乘法因子 (Kc) 可通过调节外部偏置电流 (IB) 进行电子控制。它为现代模拟信号处理系统提供了一种利用微控制器进行控制的简便方法。乘法系数可调整为小于或大于 1 的值,从而拓宽了用途的多样性。利用 Zc-VDDDA 可以轻松地将接地电容乘法器转换为浮动乘法器。我们使用 PSpice 仿真和从商用集成电路中实现的 VDDDA 进行实验,以测试拟议电容乘法器的性能。乘法系数可通过电子方式调节,近似范围为 0.56 至 13.94。工作频率范围约为三个频率十年。此外,还研究并证明了利用所提出的电容乘法器实现滞后和领先移相器的方法。结果表明,滞后相移和领先相移可通过拟议电容乘法器的乘法系数进行电子调整。
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Electronically Tunable Grounded and Floating Capacitance Multipliers Using a Single Active Element
A capacitance multiplier is an active circuit designed specifically to increase the capacitance of a passive capacitor to a significantly higher capacitance level. In this paper, the use of a voltage differencing differential difference amplifier (VDDDA), an electronically controllable active device for designing grounded and floating capacitance multipliers, is proposed. The capacitance multipliers proposed in this study are extremely simple and consist of a VDDDA, a resistor, and a capacitor. The multiplication factor (Kc) can be electronically controlled by adjusting the external bias current (IB). It offers an easy way of controlling it by utilizing a microcontroller for modern analog signal processing systems. The multiplication factor has the potential to be adjusted to a value that is either less than or greater than one, hence widening the variety of uses. The grounded capacitance multiplier can be easily transformed into a floating one by utilizing Zc-VDDDA. PSpice simulation and experimentation with a VDDDA realized from commercially available integrated circuits were used to test the performance of the proposed capacitance multipliers. The multiplication factor is electronically adjustable, ranging in approximation from 0.56 to 13.94. The operating frequency range is approximately three frequency decades. The realization of the lagging and leading phase shifters using the proposed capacitance multiplier is also examined and proven. The results reveal that the lagging and leading phase shifts are electronically tuned via the multiplication factor of the proposed capacitance multipliers.
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来源期刊
Journal of Electrical and Computer Engineering
Journal of Electrical and Computer Engineering COMPUTER SCIENCE, INFORMATION SYSTEMS-
CiteScore
4.20
自引率
0.00%
发文量
152
审稿时长
19 weeks
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