基于物联网传感器的生物医学应用量子天线数学建模与参数分析

Ram Krishna, R. Yaduvanshi, Harendra Singh, A. Rana, Nitin Goyal, Ravinder Kumar
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引用次数: 0

摘要

本文推导了一种串联和并联R-L-C高通滤波器电路的等效组合,用于基于物联网(IoT)的传感器的纳米(量子)天线,用于医疗线手术中的快速数据或器官图像显示。所提出的方法利用特征模式的样本频率行为来开发一个基本的构建块,该构建块叠加以创建完整的响应。谐振频率、输入阻抗和品质因数已经与基本和高阶谐振模式一起进行了评估。质量因子、带宽、谐振频率和高阶选择性之间的关系,在滤波器的增加阶数、质量因子以及奇数和偶数谐波因子方面增加了量子电路。因此,频率系数的基本电路推导因子用多项式展开,然后将其表示为一个简单的有理函数,从中计算基本电路参数。在该电路中,每个电路的元件的输入阻抗是复杂的。输入阻抗的实部取决于频率,取决于电阻器的频率正值或负值,阻抗的虚部由于频率值而建模电感器或电容器。在截止频率511 THz时,z11和VSWR参数为34Ω 和1.11。通过计算R、L、C等电参数,在5 THz、10 THz和500 THz下对所提出的量子DRA进行了测试,与现有的模型相比,模型性能相当好。动态阻抗取决于趋肤效应,并加强了下面的详细讨论。光学或量子DRA在生物医学工程、快速无线通信和光学图像解决方案中用作光学传感器。分析物材料已用于监测频率偏差。
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Mathematical modeling and parameter analysis of quantum antenna for IoT sensor-based biomedical applications
In this paper, an equivalent combination of series and parallel R-L-C high-pass filter circuit is derived for a nano (quantum) antenna for the Internet of thing (IoT) based sensors for speedy data or organ image displaying in medical line surgeries. The proposed method utilized the sample frequency behavior of characteristics mode to develop a fundamental building block that superimposes to create the complete response. The resonance frequency, input impedance, and quality factor have been evaluated along with basic and higher-order resonating modes. The relation between quality factor, bandwidth, resonance frequency, and selectivity for higher order, increases the quantum circuits in terms of increased order of a filter, quality factor, and odd and even harmonics factors. Therefore, the basic circuits derivation factor of frequency coefficients are expanded in terms of polynomials and then they are expressed as a simple rational function from which the basic circuit parameters are calculated. In this circuit input impedance of each circuit’s element is complex. The real part of input impedance depends on frequency, depending on the frequency positive or negative value of the resistor, and the imaginary part of impedance modelling an inductor or capacitor due to the value of frequency. At cutoff frequency 511 THz, z11 and VSWR parameters are 34 Ω and 1.11, respectively. The proposed quantum DRA is tested at 5 THz, 10 THz, and 500 THz by calculating the electrical parameters like R, L, C and model performance is quite good as compared to existing ones. The dynamic impedance is dependent on the skin effect and enhances the detailed discussion below. The utilization of optical or quantum DRAs is as optical sensors in biomedical engineering, speedy wireless communication, and optical image solutions. Analyte material has been used for monitoring frequency deviation.
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