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Related Concept Videos

Statistical Analysis: Overview01:11

Statistical Analysis: Overview

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When we take repeated measurements on the same or replicated samples, we will observe inconsistencies in the magnitude. These inconsistencies are called errors. To categorize and characterize these results and their errors, the researcher can use statistical analysis to determine the quality of the measurements and/or suitability of the methods.
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Regression Analysis01:11

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Regression analysis is a statistical tool that describes a mathematical relationship between a dependent variable and one or more independent variables.
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Reducing Line Loss01:18

Reducing Line Loss

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In a three-phase circuit, line loss is an indicator of energy dissipated as heat due to the resistance of transmission lines. To address this, incorporating transformers into the system—a step-up transformer at the source and a step-down transformer at the load—is a strategic solution. Two three-phase transformers are introduced to improve this.
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Variability: Analysis01:11

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Measures of variability are statistical metrics that reveal the dispersion pattern within a dataset. They are pivotal in biostatistics, providing insights into the heterogeneity within health and biological data. Variability signifies the degree to which data points diverge from one another, helping researchers understand the potential range of values and associated uncertainty within the data.
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Design Example: Analyzing Capacity Contours for Flood Risk Assessment01:17

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Flood risk assessment involves careful planning and analysis to ensure the safety of communities near water retention structures. Capacity contours are a vital tool in this process, as they illustrate the potential spread of water at specific levels in a given area. In the context of building a bund across a small valley, these contours play a critical role in evaluating the safety of nearby residential areas.In this example, the bund is intended to store stormwater in the valley. The engineers...
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The interval estimate of any variable is known as the prediction interval. It helps decide if a point estimate is dependable.
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Related Experiment Video

Updated: Jan 13, 2026

Continuous-Wave Propagation Channel-Sounding Measurement System - Testing, Verification, and Measurements
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Continuous-Wave Propagation Channel-Sounding Measurement System - Testing, Verification, and Measurements

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Explainable AI with EDA for V2I path loss prediction.

Mongi Ben Ameur1, Jalel Chebil1, Mohamed Hadi Habaebi2

  • 1NOCCS Laboratory, University of Sousse, Sousse, Tunisia.

Scientific Reports
|January 9, 2026
PubMed
Summary

This study introduces an explainable pathloss prediction framework for Vehicle-to-Infrastructure (V2I) communication. Interpretable machine learning models achieve high accuracy while providing transparent insights for V2X applications.

Keywords:
Channel modelingExplainable AI (ExAI)Path loss predictionV2I communications

Related Experiment Videos

Last Updated: Jan 13, 2026

Continuous-Wave Propagation Channel-Sounding Measurement System - Testing, Verification, and Measurements
09:36

Continuous-Wave Propagation Channel-Sounding Measurement System - Testing, Verification, and Measurements

Published on: June 25, 2021

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Area of Science:

  • Wireless Communications
  • Machine Learning
  • Signal Propagation

Background:

  • Accurate pathloss (PL) prediction is critical for reliable Vehicle-to-Infrastructure (V2I) communication in complex urban environments.
  • Traditional empirical models and black-box machine learning (ML) methods have limitations in accuracy, transparency, and suitability for safety-critical V2X applications.

Purpose of the Study:

  • To propose a fully explainable V2I PL prediction framework.
  • To enhance transparency and trustworthiness in V2X communication systems.
  • To provide robust global and local explanations of feature contributions in PL prediction.

Main Methods:

  • Integration of Exploratory Data Analysis (EDA), optimized Kalman filtering, and interpretable ML models (EBM, GAM, GNAM).
  • Validation using a large-scale dataset across 24 heterogeneous urban scenarios.
  • Evaluation through 5-fold cross-validation and multi-seed runs.

Main Results:

  • Interpretable models demonstrate competitive accuracy compared to black-box approaches.
  • The framework provides robust global and local explanations of feature contributions.
  • The proposed models are computationally feasible for real-time V2X deployment.

Conclusions:

  • The explainable V2I PL prediction framework offers a transparent and trustworthy solution for future 5G/6G systems.
  • Interpretable ML models are suitable for safety-critical V2X applications requiring explainability.
  • The study addresses computational, real-time, and ethical considerations for practical V2X deployment.