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Low Complexity Rotation Algorithm for PAPR Reducing Performance in Partial Transmits Sequence

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Abstract

An Orthogonal frequency part multiplexing suffers from a considerable challenge due to a high peak to average power ratio (PAPR). Hence, an effective method such as partial transmits sequence (PTS) can avert this defiance by limit the design of PAPR. Therefore, an improving PAPR reduction performance via a novel approach is proposed by detaching each subblock into two parts furthermore exchanges the first sample with the final selection in each portion of the subblock to generate a new partitioning scheme. Several typical traditional segmentation schemes are used to analyze and apply the presented algorithm, such as adjacent, interleaving, and pseudo-random schemes. Besides, two scenarios are adopted based on simulation software in which the number of subcarriers is set to 128 and 256. Based on the results, a superior PAPR reduction performance is achieved based on the improved segmentation schemes regarding traditional strategies in both systems. Moreover, the enhanced adjusted PTS scheme poses a low computational complexity compared with that of the conventional schemes.

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Author information

Authors and Affiliations

  1. Department of Computer Engineering, University of Technology, Baghdad, Iraq

    Thamer Alameri

  2. Police College of Iraq, Baghdad, Iraq

    Thamer Alameri & Mothana L. Attiah

  3. Information Technology Research and Development Centre, University of Kufa, Kufa, Iraq

    Nabeel Salih Ali

  4. Department of Computer Engineering, Electrical Engineering Technical College, Middle Technical University, Baghdad, Iraq

    Mothana L. Attiah

  5. College of Administration and Economics, University of Babylon, Hillah, Iraq

    Mohammed Saad Talib

  6. State Company for Oil Projects (SCOP), Baghdad, Iraq

    Jawad Kadhim Mezaal

Authors
  1. Thamer Alameri
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Correspondence to Thamer Alameri.

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Alameri, T., Ali, N.S., Attiah, M.L. et al. Low Complexity Rotation Algorithm for PAPR Reducing Performance in Partial Transmits Sequence. Wireless Pers Commun 124, 1169–1190 (2022). https://doi.org/10.1007/s11277-021-09400-4

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