Tree-Based Machine Learning Models with Optuna in Predicting Impedance Values for Circuit Analysis

The transmission characteristics of the printed circuit board (PCB) ensure signal integrity and support the entire circuit system, with impedance matching being critical in the design of high-speed PCB circuits. Because the factors affecting impedance are closely related to the PCB production proces...

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Bibliographic Details
Published in:Micromachines (Basel) 2023-01, Vol.14 (2), p.265
Main Authors: Lai, Jung-Pin, Lin, Ying-Lei, Lin, Ho-Chuan, Shih, Chih-Yuan, Wang, Yu-Po, Pai, Ping-Feng
Format: Article
Language:English
Subjects:
Algorithms
Circuit boards
Circuit design
Circuit printing
Decision trees
Design
Electric power
Electricity generation
Error analysis
Ethical aspects
Forecasting
Genetic algorithms
Impedance matching
integrated circuit
Machine learning
Manufacturing
Mathematical models
Model accuracy
Neural networks
Optimization algorithms
Optuna
packaging and testing
Printed circuit boards
Printed circuits
Root-mean-square errors
Semiconductors
Signal integrity
Simulation
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Summary:The transmission characteristics of the printed circuit board (PCB) ensure signal integrity and support the entire circuit system, with impedance matching being critical in the design of high-speed PCB circuits. Because the factors affecting impedance are closely related to the PCB production process, circuit designers and manufacturers must work together to adjust the target impedance to maintain signal integrity. Five machine learning models, including decision tree (DT), random forest (RF), extreme gradient boosting (XGBoost), categorical boosting (CatBoost), and light gradient boosting machine (LightGBM), were used to forecast target impedance values. Furthermore, the Optuna algorithm is used to determine forecasting model hyperparameters. This study applied tree-based machine learning techniques with Optuna to predict impedance. The results revealed that five tree-based machine learning models with Optuna can generate satisfying forecasting accuracy in terms of three measurements, including mean absolute percentage error ( ), root mean square error ( ), and coefficient of determination (R2). Meanwhile, the LightGBM model with Optuna outperformed the other models. In addition, by using Optuna to tune the parameters of machine learning models, the accuracy of impedance matching can be increased. Thus, the results of this study suggest that the tree-based machine learning techniques with Optuna are a viable and promising alternative for predicting impedance values for circuit analysis.
ISSN:2072-666X
2072-666X
DOI:10.3390/mi14020265