To predict the characteristic impedance of the microstrip transmission line using supervised machine learning regression techniques

IF 1.2 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS INTERNATIONAL JOURNAL OF COMPUTER APPLICATIONS IN TECHNOLOGY Pub Date : 2023-01-01 DOI:10.1504/ijcat.2023.133037

Mohammad Ahmad Ansari, Krishnan Rajkumar, Poonam Agarwal

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Abstract

In this paper, supervised machine learning regression techniques: Support Vector Machine (SVM), Random Forest and Deep Neural Network (DNN) models, are demonstrated to predict the characteristic impedance of the microstrip transmission line. Here, microstrip transmission line width, substrate height and substrate dielectric constant are taken as the input and characteristics impedance as the output parameter. To train the models, the data set is created using microstrip transmission line analytical models. DNN models are developed using Feed-forward Back-propagation learning algorithm, where 'adam' is used as optimiser and 'relu' as the activation function. The regression predictive model of SVM and Random Forest model of ensemble learning using bagging technique are developed. It is found that minimum MSE of DNN model is 0.04191 with high execution time 1114.179655 sec, whereas SVM model shows low execution time of 0.8327 sec with MSE of 0.49. Random Forest model showed the MSE of 0.14 with execution time 1.4296 sec.

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利用监督式机器学习回归技术预测微带传输线的特性阻抗

本文演示了监督机器学习回归技术:支持向量机(SVM)、随机森林和深度神经网络(DNN)模型，以预测微带传输线的特性阻抗。这里以微带传输线宽度、衬底高度和衬底介电常数为输入参数，特性阻抗为输出参数。为了训练模型，使用微带传输线分析模型创建数据集。DNN模型使用前馈反向传播学习算法开发，其中“adam”用作优化器，“relu”用作激活函数。提出了基于支持向量机的回归预测模型和基于bagging技术的集成学习随机森林模型。结果表明，DNN模型的最小MSE为0.04191，执行时间为1114.179655秒，而SVM模型的最小MSE为0.8327秒，执行时间为0.49。随机森林模型显示，MSE为0.14，执行时间为1.4296秒。

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来源期刊

INTERNATIONAL JOURNAL OF COMPUTER APPLICATIONS IN TECHNOLOGY COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS-

CiteScore

2.80

自引率

45.50%

发文量

期刊介绍： IJCAT addresses issues of computer applications, information and communication systems, software engineering and management, CAD/CAM/CAE, numerical analysis and simulations, finite element methods and analyses, robotics, computer applications in multimedia and new technologies, computer aided learning and training. Topics covered include: -Computer applications in engineering and technology- Computer control system design- CAD/CAM, CAE, CIM and robotics- Computer applications in knowledge-based and expert systems- Computer applications in information technology and communication- Computer-integrated material processing (CIMP)- Computer-aided learning (CAL)- Computer modelling and simulation- Synthetic approach for engineering- Man-machine interface- Software engineering and management- Management techniques and methods- Human computer interaction- Real-time systems