The design of a fully balanced current–tunable active RC integrator

Q3 Engineering
Sittisak Roungrid, Chadarat Khwunnak, Samran Lertkonsarn
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引用次数: 2

Abstract

The design of the active RC integrator presented in this research utilizes a fully balanced technique and current-tunable frequencies to create the active RC integrator and reliable circuit. The circuit is made up of six npn bipolar junction transistors (BJT), six resistors (R), and a capacitor (C), with the fully balanced technique used to make the circuit structure uncomplicated and symmetrical with signal differencing. This approach results in a low number of internal devices in the circuit, making it an attractive option for integrated circuit (IC) development. One of the key features of the fully balanced current-tunable active RC integrator is its ability to be frequency-tunable with bias current (If). This feature enables the circuit to be used in a variety of applications, including filter circuits, communication signal generators, instrumentation signal generators, and various automatic controls. The fully balanced design also ensures that the circuit is stable and robust, even in the presence of device parameter variations. To evaluate the performance of the active RC integrator, simulations were conducted using Pspice. The results show that a fully current-tunable active RC integrator can be precisely tuned with the active bias to a value consistent with the theoretically calculated value. This demonstrates the efficiency and reliability of the circuit design and simulation method. The Monte Carlo (MC) method was also used to analyze the circuit performance in cases where the resistor (R) and capacitor (C) device had a 10 percent error and the transistor gain (β) was set to an error of 50 percent. The MC analysis showed that the phase shift (degree) and magnitude (dB) of the circuit were stable, and the circuit's performance was not significantly impacted by the device parameter variations. This further demonstrates the robustness and versatility of the fully balanced current-tunable active RC integrator design. Finally, harmonic distortion was evaluated to confirm the performance of the designed and developed fully balanced current-tunable active RC integrator. The results showed low levels of harmonic distortion, which indicates that the circuit is suitable for high-performance applications that require low distortion
全平衡电流可调有源RC积分器的设计
本研究提出的有源RC积分器设计采用全平衡技术和电流可调频率来创建有源RC积分器和可靠电路。该电路由6个npn双极结晶体管(BJT)、6个电阻器(R)和1个电容(C)组成,采用了全平衡技术,使电路结构简单、对称、信号差分。这种方法导致电路中的内部器件数量少,使其成为集成电路(IC)开发的一个有吸引力的选择。全平衡电流可调谐有源RC积分器的关键特性之一是它能够随偏置电流(If)进行频率可调谐。该功能使电路可用于各种应用,包括滤波电路,通信信号发生器,仪表信号发生器和各种自动控制。完全平衡的设计也确保了电路的稳定性和鲁棒性,即使在存在器件参数变化的情况下。为了评估有源RC积分器的性能,利用Pspice进行了仿真。结果表明,电流完全可调的有源RC积分器可以精确地将有源偏置调谐到与理论计算值一致的值。验证了电路设计和仿真方法的有效性和可靠性。在电阻(R)和电容(C)器件误差为10%,晶体管增益(β)设置为误差为50%的情况下,还使用蒙特卡罗(MC)方法来分析电路性能。MC分析表明,电路的相移(度)和幅值(dB)是稳定的,电路的性能不受器件参数变化的显著影响。这进一步证明了完全平衡电流可调谐有源RC积分器设计的稳健性和多功能性。最后,对谐波失真进行了评估,以验证所设计和开发的全平衡电流可调谐有源RC积分器的性能。结果表明,该电路具有较低的谐波失真水平,适用于要求低失真的高性能应用
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
EUREKA: Physics and Engineering
EUREKA: Physics and Engineering Engineering-Engineering (all)
CiteScore
1.90
自引率
0.00%
发文量
78
审稿时长
12 weeks
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