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Autor principal: Yajnanarayana, Vijaya
Formato: Preprint
Publicado: 2021
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Acceso en línea:https://arxiv.org/abs/2110.07262
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author Yajnanarayana, Vijaya
author_facet Yajnanarayana, Vijaya
contents Beyond 5G networks will operate at high frequencies with wide bandwidths. This brings both opportunities and challenges. Opportunities include high throughput connectivity with low latency. However, one of the main challenges in these networks is due to the high path loss at operating frequencies, which requires network to be deployed densely to provide coverage. Since these cells have small inter-site-distance (ISD), the dwell-time of the UEs in these cells are small, thus supporting mobility in these types of dense networks is a challenge and require frequent beam or cell reassignments. A pro-active mobility management scheme which exploits the trajectory can provide better prediction of cells and beams as UEs move in the coverage area. We propose an AI based method using sequence-to-sequence modeling for the estimation of handover cells/beams along with dwell-time using the trajectory information of the UE. Results indicate that for a dense deployment an accuracy of more than 90 percent can be achieved for handover cell estimation with very low mean absolute error (MAE) for dwell-time.
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publishDate 2021
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spellingShingle Proactive Mobility Management of UEs using Sequence-to-Sequence Modeling
Yajnanarayana, Vijaya
Information Theory
Beyond 5G networks will operate at high frequencies with wide bandwidths. This brings both opportunities and challenges. Opportunities include high throughput connectivity with low latency. However, one of the main challenges in these networks is due to the high path loss at operating frequencies, which requires network to be deployed densely to provide coverage. Since these cells have small inter-site-distance (ISD), the dwell-time of the UEs in these cells are small, thus supporting mobility in these types of dense networks is a challenge and require frequent beam or cell reassignments. A pro-active mobility management scheme which exploits the trajectory can provide better prediction of cells and beams as UEs move in the coverage area. We propose an AI based method using sequence-to-sequence modeling for the estimation of handover cells/beams along with dwell-time using the trajectory information of the UE. Results indicate that for a dense deployment an accuracy of more than 90 percent can be achieved for handover cell estimation with very low mean absolute error (MAE) for dwell-time.
title Proactive Mobility Management of UEs using Sequence-to-Sequence Modeling
topic Information Theory
url https://arxiv.org/abs/2110.07262