Serbest Uzay Optik Haberleşme Sistemlerinde Turbo Çarpım Kodların Performans Analizi

Year 2020, Volume: 10 Issue: 1, 45 - 48, 30.06.2020

Mert Bayraktar

Abstract

Bu makalede, turbo çarpım kodlarının(TPC) serbest uzay
optik(FSO) sistemlerinin performansa olan etkisi
incelenmiştir. Atmosfer modeli olarak log-normal dağılım
seçilmiştir. MATLAB benzetim çalışmaları zayıf ve orta
türbülansta gerçeklenmiştir. Turbo çarpım kodlarını
oluşturan kod bileşenleri, genişletilmiş hamming ve
genişletilmiş Bose–Chaudhuri–Hocquenghem(BCH)
kodları olark kullanılmıştır. Benzetim sonuçlarına göre,
özellikle orta türbülans altında TPC kullanımı ile
hedeflenen bit hata oranına(bit error rate(BER))ulaşırken
15dB’ye kadar kod kazancı sağlanabilmektedir. Bu kod
kazancı BCH tabanlı TPC kullanılırsa daha fazla iken
hamming tabanlı TPC kullanılırsa daha az olmaktadır.
Düşük kod oranlı ve BCH kod bileşeni ile oluşturulan TPC
ile 0dB sinyal-gürültü oranı(signal to noise ratio(SNR))
değerinde bile sistemin BER’i 10^-5 ’e düşebilmektedir.

Keywords

Turbo çarpım kodu, serbest uzay optik, bit hata oranı, atmosferik türbülans

Performance Analysis of Turbo Product Codes on Free Space Optics Communication Systems

Abstract

Inthisarticle, theeffect of turbo productcodes(TPC) overtheperformance of freespaceopticssystems is analyzed. Log-normal distribution is selected as theturbulence model. MATLAB simulationsarecarriedout in weak and moderate turbulence. Component codes which construct turbo product codes are used as extended hamming and extended Bose–Chaudhuri–Hocquenghem(BCH) codes. According to simulation results, it can be provided that up to15dB code gain to reach the target bit error rate(BER) with the use of TPC especially under moderate turbulence. While this code gain is more if BCH based TPC is used, it becomes less if hamming based TPC is used. With low code rate and TPC which is constructed with BCH codecomponent, BER of system can decreaseto even in 0dB signal to noise ratio(SNR).

Keywords

Turbo product code, free space optic, bit error rate, atmospheric turbulence

References

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