MIMO Multipath Component Clustering using k-Deep Autoencoder

Authors

  • Casey H. Atienza Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Sean David R. Aggabao Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Thrisha Mae T. Banguis Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Larie Joseph R. Lacsina Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Vianca D. Manalo Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Rhiz John P. Susi Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Emmanuel T. Trinidad Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines
  • Lawrence Materum International Centre, Tokyo City University, Tokyo, Japan

DOI:

https://doi.org/10.37934/aram.119.1.2736

Keywords:

Clustering, MIMO, Autoencoders, Wireless multipath component, Channel Modeling

Abstract

In modern wireless communication systems, accurate characterization of wireless propagation channels remains a significant challenge. In multiple-input multiple-output (MIMO) wireless systems, a double-directional channel can be achieved by utilizing multipath components' spatial and temporal properties (MPCs). Grouping the MPC can simplify the parameters as a trade-off between complexity and accuracy. This paper implements k-Deep Auto Encoder (k-DAE), AE+k-means, and K Power Means (KPM) clustering approaches and compares their performance in clustering wireless propagation multipaths in indoor and outdoor scenarios. The results show that AE+k-means performs better than k-DAE in indoor scenarios by 25.48%, while k-DAE performs 24.60 % better in outdoor scenarios. The KPM algorithm performs best in all indoor scenarios among the three algorithms, with a significant increase of 4.38% and 11.062% to AE+k-means and k-DAE, respectively. However, both k-DAE and AE+k-means have quite similar performance in outdoor scenarios. The study also highlights the first use of autoencoders in clustering the MPCs. The results indicate that k-DAE can be used as an alternative clustering method in channel modeling. Future works envisioned applying the approach to other wireless channel models.

Author Biographies

Casey H. Atienza, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019990731@dhvsu.edu.ph

Sean David R. Aggabao, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019990724@dhvsu.edu.ph

Thrisha Mae T. Banguis, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019993066@dhvsu.edu.ph

Larie Joseph R. Lacsina, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019990840@dhvsu.edu.ph

Vianca D. Manalo, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019990853@dhvsu.edu.ph

Rhiz John P. Susi, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

2019996517@dhvsu.edu.ph

Emmanuel T. Trinidad, Department of Electronics Engineering, Don Honorio Ventura State University, Bacolor, Pampanga, Philippines

ettrinidad@dhvsu.edu.ph

Lawrence Materum, International Centre, Tokyo City University, Tokyo, Japan

materuml@dlsu.edu.ph

Downloads

Published

2024-06-30

How to Cite

Casey H. Atienza, Sean David R. Aggabao, Thrisha Mae T. Banguis, Larie Joseph R. Lacsina, Vianca D. Manalo, Rhiz John P. Susi, Emmanuel T. Trinidad, & Lawrence Materum. (2024). MIMO Multipath Component Clustering using k-Deep Autoencoder. Journal of Advanced Research in Applied Mechanics, 119(1), 27–36. https://doi.org/10.37934/aram.119.1.2736

Issue

Vol. 119 No. 1: July (2024)

Section

Articles