Accurate propagation modeling is paramount for effective radio deployments, coverage analysis, and interference mitigation in wireless communications. Path loss modeling, a widely adopted approach, enables generic predictions of signal power attenuation along wireless links, equipping network planners with essential insights into physical layer attributes. However, in non-line-of-sight (NLOS) scenarios, traditional models like Longley-Rice and free space path loss (FSPL) exhibit degraded accuracy due to their inability to account for signal attenuation and interference caused by electromagnetic interactions with terrain and clutter.
Conventional models require intricate knowledge of the entire path profile, including the complete spatial variation of terrain (DTM) and surface (DSM) data, effectively treating it as a one-dimensional problem. Alternatively, some models utilize thousands of features in two-dimensional (2D) and three-dimensional (3D) representations of terrain and clutter, performing point-to-multi-point predictions.
In this paper, researchers (Jonathan Ethier and Mathieu) have tried to answer a crucial question: “Can simple features derived from path profiles be used as the sole input to a predictor of path loss along a wireless link while still providing sufficient accuracy for predicting radio coverage?†To answer the question, they have employed
Machine learning (ML)-based modeling, comparing it against traditional approaches, andÂ
Emphasized the use of measurement data for training to ensure reliable ground truth.
Researchers leveraged the openly available ITU-R UK Ofcom drive test dataset for training and testing, consisting of measurements across various frequencies and geographically distinct sites. This dataset, comprising over 8.2 million measurements, served as the foundation for their work. Additionally, they utilized online databases of DTM and DSM to extract path profiles and derive features such as total obstacle depth along the direct path, terrain depth, and clutter depth.
The researchers explored three feature configurations:
Frequency and link distance
Frequency, link distance, and obstacle depth
Frequency, link distance, terrain depth, and clutter depth
These features were used as inputs to three different modeling techniques: curve-fit log regression, boosted trees (XGBoost), and fully-connected neural networks (FCNs).
To ensure robustness and avoid overfitting, the researchers employed a stringent round-robin approach, training the models on five cities and testing on the sixth, repeating this process six times. This minimized geographic adjacency and data leakage, providing a rigorous evaluation of model generalization.
The results revealed that the FCN model outperformed boosted trees and log regression, including more features leading to lower root mean squared errors (RMSEs). Introducing obstacle depth as a third feature significantly improved performance, reducing the RMSE by approximately 5 dB. However, separating obstacle depth into terrain and clutter depths yielded little improvements, potentially due to temporal mismatches between measurements and geospatial information.
Further analysis of the obstacle loss (the difference between the ML-predicted path loss and FSPL) revealed that the FCN model learned behaviors grounded in physics, with obstacle loss increasing as expected with increasing frequency and obstacle depth. However, limitations were observed, such as the influence of link distance on obstacle loss and non-zero obstacle loss for zero obstacle depth, which the researchers aim to address in future work.
The researchers demonstrated that simple scalar features describing terrain and clutter can be used to train accurate ML-based propagation models, yielding well-generalized models with RMSEs in the 6-8 dB range. This approach outperforms traditional models while relying on significantly fewer features than models using high-resolution imagery and detailed path profiles.
The implications of this work are far-reaching, as it paves the way for more efficient and accurate propagation modeling, ultimately enhancing wireless network planning, deployment, and optimization. By leveraging the power of machine learning and simplified features, the researchers have ushered in a new era of path loss modeling, revolutionizing the field and opening doors for future advancements.
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