A Ray Tracing Tool for Propagation Modeling in Layered Media: A Case Study at the Chip Scale

Fuschini, Franco; Barbiroli, Marina; Bellanca, Gaetano; Calò, Giovanna; Nanni, Jacopo; Petruzzelli, V.

doi:10.1109/ojap.2022.3148855

Cited by 3 publications

(2 citation statements)

References 28 publications

(34 reference statements)

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“…Then, the computation of the rays' (EM field) contributions is based on geometrical optics (GO), uniform theory of diffraction for diffraction (UTD), and can also include diffuse scattering to some extent [18]. PL data, largeand small-scale fading, time/frequency/angular dispersion, and optical visibility can be investigated through RT in almost every propagation scenario and wireless application [19]- [21], as RT is a general-purpose approach. However, RT simulations often lead to large, sometimes prohibitive, computational costs and simulation time [22].…”

Section: Introductionmentioning

confidence: 99%

A Machine Learning Approach to Wireless Propagation Modeling in Industrial Environment

Zadeh,

Barbiroli,

Fuschini

2024

IEEE Open J. Antennas Propag.

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Wireless channel properties in industrial environments can differ from residential or office settings due to the considerable impact of heavy machinery that triggers intricate multipath propagation effects and strong blockage effects. Previous investigations on wireless propagation in factories often consisted of empirical models, that is simple analytical formulas based on measurement data. Unfortunately, they usually lack in flexibility, since they seldom include geometrical parameters describing the industrial scenario and therefore turn out reliable only in industrial scenarios sharing the same propagation characteristics as those where the measurements were performed. In response to this limitation, this article harnesses the power of Machine Learning to model propagation markers like path loss, shadowing, and delay spread in the industrial environment. By employing Machine Learning techniques, the objective is to achieve flexibility and adaptability in modeling, enabling the system to effectively generalize across diverse industrial scenarios. The proposed model relies on a combination of predictive algorithms, including a linear regression model and a Multi-Layer Perceptron, working collaboratively to model the relationship between the considered propagation markers and input features like frequency and machine size, spacing, and density. Results are in fair overall agreement with previous studies and highlight some trends about the sensitivity of the propagation parameters to the considered input features.

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Section: Introductionmentioning

confidence: 99%

A Machine Learning Approach to Wireless Propagation Modeling in Industrial Environment

Zadeh,

Barbiroli,

Fuschini

2024

IEEE Open J. Antennas Propag.

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“…For example, Giarola, Calvaceante and Tamir [ 16 ], et al divide the canopy into three layers of lossy medium, with each layer described as a unique dielectric to ensure that it is the same isotropic material considering the electromagnetic waves passing through each layer [ 17 , 18 ]. After each layer boundary, there are more detailed 4-layer models, which distinguish the canopy, branch and trunk, and more accurate modelling can be performed [ 19 – 21 ]. The second model treats vegetation as a whole without any separation.…”

Section: Introductionmentioning

confidence: 99%

Measurement, data analysis and modeling of electromagnetic wave propagation gain in a typical vegetation environment

Zhang

Wang

et al. 2023

PLoS ONE

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This paper takes the specific environment covered by vegetation as the research object, carries out modeling and analysis, takes the large-scale fading model of wireless channel as the basis of data processing, researches the transmission law of electromagnetic wave in a typical vegetation environment, which can be divided into four situations. The signal attenuation in each case is theoretically derived and numerically simulated. From the view point of supporting vegetation environment channel, the large-scale channel measurement system is built to meet the actual needs, such as bandwidth, frequency, vegetation coverage, etc. the final vegetation environment channel model under the large-scale fading model is obtained. The results show that the path gain of four scenarios respectively are 81.3 dB, 36.5 dB, 1.6 dB, 1.5 dB, the value of path gain index is within the range of 2~3.5, four scenarios shadow fading standard deviation values are 7.1, 4.8, 10.1, 9.2, reflects the change of received power at the point caused by random factors such as reflection, absorption and scattering. In addition, the proposed channel model improves the gain about 15% compared with the tradition SUI model within vegetation coverage scene. The design process of the proposed model is carried out in the order of "studied the existing foundation → analyzed the existing problems → proposed the optimization scheme → simulation and verification results → actual measurement system". The advantage of paper’s method is that, when the signal frequency, transceiver distance, antenna height and vegetation environment characteristic parameters are given, the statistical analysis results of wireless channel data are obtained. The purpose of the proposed work establishes a signal propagation prediction model under the vegetation environment, realizes a theoretical basis for channel simulation, and provides the basis of anti-fading technologies.

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Deep Neural Network for Indoor Positioning Based on Channel Impulse Response

Dao

Salman²

2022

2022 IEEE 27th International Conference on Emerging Technologies and Factory Automation (ETFA)

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A Ray Tracing Tool for Propagation Modeling in Layered Media: A Case Study at the Chip Scale

Cited by 3 publications

References 28 publications

A Machine Learning Approach to Wireless Propagation Modeling in Industrial Environment

A Machine Learning Approach to Wireless Propagation Modeling in Industrial Environment

Measurement, data analysis and modeling of electromagnetic wave propagation gain in a typical vegetation environment

Deep Neural Network for Indoor Positioning Based on Channel Impulse Response

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