The Influence of Terrain Scattering on Radio Links in Hilly/Mountainous Regions

Lu, Jonathan S.; Han, Xiao; Bertoni, H.L.

doi:10.1109/tap.2012.2231919

Cited by 25 publications

(7 citation statements)

References 16 publications

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“…This means that even if clustering is repeated for the same value of 'k', say n = 5, the resulting clusters are different each time. To address this issue, the method employed has been to iterate clustering multiple times for each value of 'k', say 20, and find the most optimum cluster by selecting the cluster that has the lowest Euclidean distance [6]. Each time the clustering process iterates, the centroids are randomized within the range of the dataset, ensuring that all of the possible combinations get explored.…”

Section: Iterative K-means Clusteringmentioning

confidence: 99%

See 1 more Smart Citation

Spatial Diversity Deconstruct of C-band Scatter Components in Multistatic RaDaR Datasets using Machine Learning Techniques

Sundaram¹,

Surej²,

Karthic³

et al. 2021

Preprint

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In complex application wherein the signal propagating through free space is subject to multipath interference due to scatter by line-of-sight and non-line-of-sight objects in the propagation channel. The aims is to identify scatter centers in the propagation channel and characterize them based on their subjective characteristics, interpreted based on machine learning algorithm operations. Data-driven models are employed, replacing the traditional analytical approaches, in order to profile the scatter centers as either of absorbing or reflecting types based on the manner in which the signals are affected. A typical multistatic detection scenario is reconstructed under controlled laboratory conditions in order to create spatially independent data sets, while operating in the C-band frequency. The outcomes of this study are then applied to identify the scatter centers based on the distinct signatures they register in the experimental data set. As a converse argument, the process of antenna pattern estimation can now be performed free of an anechoic chamber setup, which is time and cost insensitive. A greater relevance shall be in the context of mid-band 5G-NR cellular communication systems that need to optimize the distributed antenna location attributes on time and cost constrained scales before attempting a large-scale deployment.

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Section: Iterative K-means Clusteringmentioning

confidence: 99%

“…A geometrical model was developed by Lu et al [6] in which a 6 • 10 4 × 6 • 10 4 m 2 box had been centered is the setup within the 10 4 × 10 4 m 2 test region. The antennae were placed randomly within the box.…”

Section: Introductionmentioning

confidence: 99%

Spatial Diversity Deconstruct of C-band Scatter Components in Multistatic RaDaR Datasets using Machine Learning Techniques

Sundaram¹,

Surej²,

Karthic³

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…Finally, few papers focus on large‐scale maps, where detailed point clouds captured from ground are typically replaced by airborne lidar scans or radar elevation maps. Lu, Han, and Bertoni (2013) show that the terrain‐scattering effect in mountainous areas with sufficiently rough terrain is a significant contributor to the received signal power, apart from the ones which are dominant in flat‐terrain areas. They base their findings on simulations processing data from artificial terrain databases.…”

Section: Related Workmentioning

confidence: 99%

Radio propagation models for differential GNSS based on dense point clouds

Kubelka

Dandurand

Babin

et al. 2020

Journal of Field Robotics

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Accurate geolocation of mobile equipment operating in outdoor environments is an increasingly important question in robotics and automation. Modern geolocation systems, however, rely on the crucial ability for a mobile device to receive specific radio signals at all times. As such geolocation systems are increasingly deployed in harsh or difficult environments, for example, in the presence of tall buildings or dense forest, it becomes critical to predict how the environment will impact the propagation of these radio signals. To this effect, we present a new signal propagation model that can determine what areas would be favorable for global navigation satellite system (GNSS) positioning, based on a prior three-dimensional (3D) point cloud map of the environment. Our model can predict both the number of usable satellites for a GNSS receiver and the strength of the reference radio signal used in the differential GNSS scenario. Contrary to others, it takes into account both signal occlusion and absorption mechanisms, given the geometry and density of the point cloud map. We designed two rugged mobile data-collecting platforms, both to generate the 3D maps of the environment, as well as to gather various ground truth for GNSS satellite and local radio signals. Environments used for our field deployments included a boreal forest, a subarctic forest and diverse industrial areas. Experimental results indicate that our model performs well in both structured and unstructured environments, with median errors of 1.10 for the predicted number of satellites and 1.85 dBm for the strength of the differential GNSS correction signals.

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“…The work led to the development of a model that performs significantly better when compared to previously developed 2-D models. 3) A geometrical model was developed by Lu et al [9], and simulations were carried out using different artificial terrain databases. 4) Various model-driven approaches have been proposed…”

Section: Introductionmentioning

confidence: 99%

Microwave Tomography Data Deconstruct of Spatially Diverse C-Band Scatter Components Using Clustering Algorithms

et al. 2022

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Communication signals that propagate through free space are subject to multi-path interference due to scattering by various objects in the propagation channel. The effect is especially severe in complex situations in dense urban environments. To investigate the problem, a typical multi-static detection scenario is reconstructed under controlled laboratory conditions, from which suitable data sets are created. Data-driven models are then employed in EDGE computing platforms to profile the scatter centers based on the subjective manner in which they affect the signals. These have been interpreted primarily based on clustering algorithm (CA) operations -using a select suite of pre-processing models that effectively tame the variations in the C-band spatial-temporal data. A subset of the data of interest could then be subjected to an optional, compute-intensive machine learning (ML) approach. The relative advantages of the proposed method vis-a-vis an array of conventional schemes are highlighted, while also considering its carbon friendly attribute. Given the more significant association of the data to antenna radiation patterns, estimation of the latter can now be performed free of any anechoic chamber set up in a time and cost agnostic manner. The benefit of this work would lie in the realm of mid-band 5G-NR (and the future 6G) cellular communication systems deployment, where optimizing the distributed antenna location attributes on time and cost-constrained scales becomes imperative before any large-scale deployment. INDEX TERMSMicrowave radio communication, Multi-path channels, Pattern clustering methods, Radio propagation terrain factors, Scattering, Signal processing antennas 1 VOLUME XX, 2022

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The Influence of Terrain Scattering on Radio Links in Hilly/Mountainous Regions

Cited by 25 publications

References 16 publications

Spatial Diversity Deconstruct of C-band Scatter Components in Multistatic RaDaR Datasets using Machine Learning Techniques

Spatial Diversity Deconstruct of C-band Scatter Components in Multistatic RaDaR Datasets using Machine Learning Techniques

Radio propagation models for differential GNSS based on dense point clouds

Microwave Tomography Data Deconstruct of Spatially Diverse C-Band Scatter Components Using Clustering Algorithms

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