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.

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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

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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

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Articles