An Improved Phase Noise Reduction in Millimeter-Wave FBMC Systems

E. Udayakumar; V. Krishnaveni

doi:10.2174/0126662558294490240916065547

ISSN: 2666-2558
E-ISSN: 2666-2566

An Improved Phase Noise Reduction in Millimeter-Wave FBMC Systems
Authors: E. Udayakumar¹ and V. Krishnaveni²
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¹ Department of ECE, KIT-Kalaignarkarunanidhi Institute of Technology, Coimbatore, Tamilnadu, India ; ² Department of ECE, PSG College of Technology, Coimbatore, Tamilnadu, India
Source: Recent Advances in Computer Science and Communications, Volume 18, Issue 5, Jul 2025, E26662558294490
DOI: https://doi.org/10.2174/0126662558294490240916065547
- Received: 09 Jan 2024
- Accepted: 31 May 2024
- Available online: 30 Sep 2024

Abstract

The next generation mobile network needs to have a spectrum above the 30 GHz radio band. The 5G system is a promising technology for future communication systems. It has been used in Device-to-Device (D2D) communications, IoT, Machine type communications (MTC), and wireless backhaul. The 5G is expected to have speeds of hundreds of times and satisfy the requirements of larger traffic density, low latency, connective density, higher capacity & reliability, data rate, super high mobility, etc. It is expected to have applications such as HD video, virtual reality & augmented reality, online games, and cloud desktops. For this, Millimeter wave (Mmwave) has been used for fifth-generation mobile networks. The millimeter wave has a frequency range from 30 to 300 GHz. When the usage of frequency is above 60 GHz, the band will acquire RF impairments such as PAPR, Phase noise, non-linearity, and phase and quadrature timing mismatch (IQTM). This article shows the Phase noise reduction in MIMO FBMC systems using Extended Kalman filter techniques.

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2025-11-04

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/content/journals/rascs/10.2174/0126662558294490240916065547

An Improved Phase Noise Reduction in Millimeter-Wave FBMC Systems

Recent Advances in Computer Science and Communications 18, E26662558294490 (2025); https://doi.org/10.2174/0126662558294490240916065547

/content/journals/rascs/10.2174/0126662558294490240916065547

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Article Type: Review Article

Keyword(s): D2D communications; extended kalman filter; FBMC systems; massive MIMO; Millimeter wave; phase noise

An Improved Phase Noise Reduction in Millimeter-Wave FBMC Systems

Abstract

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