Dataset description

In our study, we have used three datasets, Dataset 1 for slot antenna, Dataset 2 for microstrip patch antenna, and Dataset 3 for bowtie antenna to compare the performance of different ML algorithms. Among these three datasets, dataset 1 of slot antenna [Reference Shreya38] is a publicly available dataset. The samples of dataset 2 of the microstrip antenna and dataset 3 of the bowtie antenna are simulated and collected using MATLAB for experimental purposes. In our simulated dataset, sample points were generated with all possible combinations of the input parameters like the dimension of the antenna, which increased at a fixed step size. The values of the antenna strength (in dB) is extracted for these sample points for a frequency range of step size 0.1 GHz. As most of the mobile services, like Long-Term Evolution (LTE) and mid-band 5G, operate in microwave frequency spectrum range from 1.5 to 3.5 GHz, we selected this frequency range as our operation frequency in the experiment.

Dataset 2 was simulated on a CPU using Ryzen 5700 U microprocessor with 16 GB RAM. The system took around 3 hours to generate the dataset. Dataset 3 was generated with the system having Ryzen 1600C CPU with Nvidia RTX2060 super graphics card with 16 GB RAM. The dataset was generated in about 30 minutes. Simulating these models is challenging and requires high computational cost and time, which can vary from about 15 seconds to more than few days, based on the model specification [Reference Koziel, Belen, Çaliskan and Mahouti14]. The proposed approach can be applied to efficiently design the antenna using the information learned from these generated data without the need to simulate more to generate new data.

The details about the three datasets, including their features and the collection process, are described below.

Dataset 1 – slot antenna

This dataset [Reference Shreya38] is a publicly available dataset of slot antenna, which consists of 1267 samples with five different features (slot length, slot width, patch length, patch width, and frequency) and strength. The whole frequency range for the sample is between 1.5 and 3.5 GHz. Each parameter of the sample is increased by 0.5 mm. The signal strength of the antenna is simulated for each combination of input parameters. The slot length is from 0 to 85 mm; slot width is from 0 to 115 mm; patch length is from 29.4 to 87 mm; and patch width is from 26 to 130 mm. This dataset was created by using HFSS software. Figure 4 [Reference Balanis39] shows the general structure of a slot antenna.

Figure 4. Slot antenna.

Dataset 2 – microstrip patch antenna

This dataset consists of 10,453 samples with three input design features of patch antenna (patch length, patch width, and frequency). The total frequency range that we used for simulating the antenna parameters in the design is also from 1.5 to 3.5 GHz. MATLAB Simulink Antenna Toolbox was used to simulate the samples to generate the output signal strength for all combinations of input design parameters. The patch length and patch width were increased by a step size of 0.01 mm, and frequency was increased by 0.1 GHz. All other values were kept to their default value during the simulation. Figure 5 [Reference Kashyap and Sandeep40] shows the general structure of the microstrip patch antenna.

Figure 5. Microstrip patch antenna.

Dataset 3 – bowtie antenna

The bowtie antenna is a simple antenna where the antenna feed is at the center of the antenna. This antenna is also called butterfly antenna or a biconical antenna. The angle between the two metal pieces (D) is dependent on the length and width of the antenna and is calculated by the equation.

(1)\begin{equation}D = 2 \times a\,\tan \left( {L/W} \right)\end{equation}

The bowtie antenna dataset consists of a total of 14,280 samples. This dataset also consists of three features (length, width, and frequency) as a design parameter. This dataset was also generated using MATLAB Simulink Antenna Toolbox. The length and width of the bowtie antenna were varied by increasing by 0.01 mm from 0 to a maximum value of 4 mm. The frequency also varied from 0.1 GHz in a range from 1.5 to 3.5 GHz. For each combination of these inputs, the signal strength was simulated for the bowtie antenna. All other parameters were kept to their default value during simulation in MATLAB. Figure 6 [Reference Balanis39] shows the general structure of the bowtie antenna. Table 1 shows a detailed comparison between these three datasets.

Figure 6. Planar bowtie antenna.

Table 1. Comparison of different parameters of three antenna datasets

Models used

In our initial experiment, we used 10 commonly used ML regression algorithms, LR, stochastic gradient descent (SGD) regressor, random forest (RF) regression, decision tree (DT) regressor, gradient boosting (GB), bagging regressor (BR), XGB regressor (XGB), support vector regressor (SVR), MLP regressor (MLP), and K Nearest Neighbors regressor (KNN). For uniform comparison, all the ML models were trained with the same training data and tested with the same testing data. We use ML regression models from the scikit-learn python library with hyperparameter tuning using Bayesian Optimization Algorithm for initial evaluation. The performance of the model with tuned hyperparameter is compared with the base model with default parameter value. The parameter of the base ML model is replaced with only those optimized parameters which improved the performance on the testing data. The models and its tuned hyperparameters used in the experiments are listed below.

• RF(n_estimators=8, max_depth=10, criterion= ‘squared_error’, min_samples_split=0.0021, min_samples_leaf=0.0005, ma_features=’log2’)

• DT(criterion=’squared_error’, max_features=’sqrt’, min_samples_leaf=0.00106, min_samples_split=0.00088, splitter=’best’)

• GB(criterion=’squared_error’, learning_rate=0.7, loss=’friedman_mse’, n_estimators=140, max_depth=50, max_features=None, min_samples_leaf=0.0144, min_samples_split=0.1808)

• BR(n_estimators=70)

• XGB(n_estimators= 1000, max_depth=5, eta=0.1)

• KNN(n_neighbors=3, weights=distance, algorithm=’kd_tree’, leaf_size=40).

Apart from the aforementioned, all other hyperparameters were used with their default values. Also, for dataset 2 (patch antenna) and dataset 3 (bowtie antenna), DT and RF were used with their default hyperparameters as the optimization techniques did not improve the model performance.

We used four ensemble methods that have been popular for regression process. In each ensemble model, we used three high-performance models determined from our preliminary study to predict the output. The details of these four ensemble methods are described below.

• • Averaging method: In this method, the model returns the average of the prediction of the three best performing for each antenna. This method reduces the variance, and the combined results is better than the individual output.

• • Stacking method: In this method, the whole dataset is divided into training and testing dataset. The three high performing ML models are trained individually on the training dataset as base model. This trained model is used to predict on the testing dataset. Then the predictions on the training data set are used as a feature to build the new meta-regression model. This model uses the training stacking features to train, and then the final model is used to predict the output on the test dataset.

• • Blending method: In blending method, we split the dataset into training, testing, and validation datasets. Then, we used the three top-performing ML regression algorithms to train on the testing dataset. The performance is tested on validation and test datasets. Based on the predictions of the individual models, the final model is built using the meta features. Then this model is used for predicting the output and for performance analysis.

• • Bagging method: In this method, the base model, XGBoost regressor method, is trained on bags, which are the subsets of the dataset made to the size of the whole dataset with replacements. These multiple bags that are created from the train dataset are trained on the base model individually. The output coming from all these experiments are combined to get the final output.

Evaluation metrics

To evaluate the performance of our ML models, we used two popular evaluation metrics: root mean square error (RMSE) score and R-squared (R ² or coefficient of determination) score, to measure the model performance in our testing data. In both these evaluation metrics, the target value is compared with the actual value to analyze the performance of the machine learning algorithms. RMSE metrics tell us about the average distance between the predicted and actual values and is calculated as:

(2)\begin{equation}{\textrm{RMSE}} = \sqrt {\mathop \sum {{\left( {{P_i}^2 - {Q_i}^2} \right)}^2}/n} \end{equation}

where ∑ is summation, P_i is the predicted value for ith observations, Q_i is the observed value for the ith observations, and N is the sample size.

R ² represents the proportion of the variance for a dependent variable that is explained by an independent variable or variable in a regression model. It measures how well the regression line approximates the actual data. The variance can be calculated as

(3)\begin{equation}{{\textrm{R}}^2} = 1 - {{\rm sum\, squared\, regression\left( {SSR} \right)} \over {\rm total\, sum\, of\, square\left( {SST} \right)}}\end{equation}

(4)\begin{equation}{R^2} = 1- \frac{ {\sum _{i = 1}^n{{\left( {{y_i} - \hat y} \right)}^2}}} {{\sum_{i = 1}^n{{\left( {{y_i} - \widehat {\bar y}} \right)}^2}}}\end{equation}

where y_i = actual y value, $\hat y$ = predicted y value, and $\widehat {\bar y}$ = mean of y value.