On Error Rate Approximations for FSO Systems With Weak Turbulence and Pointing Errors

Carmen Álvarez Roa; Yunus Can Gültekin; Kaiquan Wu; Cornelis Willem Korevaar; Alex Alvarado

doi:10.1109/JSTQE.2025.3590410

On Error Rate Approximations for FSO Systems With Weak Turbulence and Pointing Errors

Carmen Álvarez Roa (Corresponding author)
, Yunus Can Gültekin
, Kaiquan Wu
, Cornelis Willem Korevaar
, Alex Alvarado

Research output: Contribution to journal › Article › Academic › peer-review

1 Citation (Scopus)

Abstract

Atmospheric attenuation, atmospheric turbulence, geometric spread, and pointing errors, degrade the performance of free-space optical transmission. In the weak turbulence regime, the probability density function describing the distribution of the channel fading coefficient that models these four effects is known in the literature. This function is an integral equation, which makes it difficult to find simple analytical expressions of important performance metrics such as the bit error rate (BER) and symbol error rate (SER). In this paper, we present simple and accurate approximations of the average BER and SER for pulse-amplitude modulation (PAM) in the weak turbulence regime for an intensity modulation and direct detection system. Our numerical results show that the proposed expressions exhibit excellent accuracy when compared against Monte Carlo simulations. To demonstrate the usefulness of the developed approximations, we perform two asymptotic analyses. First, we investigate the additional transmit power required to maintain the same SER when the spectral efficiency increases by 1 b/symbol. Second, we study the asymptotic behavior of our SER approximation for dense PAM constellations and high transmit power.

Original language	English
Article number	3800115
Number of pages	15
Journal	IEEE Journal of Selected Topics in Quantum Electronics
Volume	32
Issue number	1
DOIs	https://doi.org/10.1109/JSTQE.2025.3590410
Publication status	Published - Feb 2026

Bibliographical note

Publisher Copyright:
© 2025 IEEE.

Funding

Received 30 April 2025; revised 14 July 2025; accepted 15 July 2025. Date of publication 17 July 2025; date of current version 8 September 2025. This work was supported by Dutch Research Council (NWO). An earlier version of this paper was presented in part at the ICTON, Bari, Italy, June 2024 [DOI: 10.1109/ICTON62926.2024.10647275]. (Corresponding author: Carmen Ál-varez Roa.) The authors are with the Information and Communication Theory Lab, Signal Processing Systems Group, Department of Electrical Engineering, Eindhoven University of Technology, 5600MB Eindhoven, The Netherlands (e-mail: [email protected]; [email protected]; [email protected]; [email protected]; [email protected]). This work was supported by Dutch Research Council (NWO). An earlier version of this paper was presented in part at the ICTON, Bari, Italy, June 2024 [DOI: 10.1109/ICTON62926.2024.10647275].

Keywords

atmospheric turbulence
bit error rate
channel modeling
Free-space optical communications
pointing errors
symbol error rate

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10.1109/JSTQE.2025.3590410

Cite this

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title = "On Error Rate Approximations for FSO Systems With Weak Turbulence and Pointing Errors",

abstract = "Atmospheric attenuation, atmospheric turbulence, geometric spread, and pointing errors, degrade the performance of free-space optical transmission. In the weak turbulence regime, the probability density function describing the distribution of the channel fading coefficient that models these four effects is known in the literature. This function is an integral equation, which makes it difficult to find simple analytical expressions of important performance metrics such as the bit error rate (BER) and symbol error rate (SER). In this paper, we present simple and accurate approximations of the average BER and SER for pulse-amplitude modulation (PAM) in the weak turbulence regime for an intensity modulation and direct detection system. Our numerical results show that the proposed expressions exhibit excellent accuracy when compared against Monte Carlo simulations. To demonstrate the usefulness of the developed approximations, we perform two asymptotic analyses. First, we investigate the additional transmit power required to maintain the same SER when the spectral efficiency increases by 1 b/symbol. Second, we study the asymptotic behavior of our SER approximation for dense PAM constellations and high transmit power.",

keywords = "atmospheric turbulence, bit error rate, channel modeling, Free-space optical communications, pointing errors, symbol error rate",

author = "\{{\'A}lvarez Roa\}, Carmen and G{\"u}ltekin, \{Yunus Can\} and Kaiquan Wu and Korevaar, \{Cornelis Willem\} and Alex Alvarado",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.",

year = "2026",

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doi = "10.1109/JSTQE.2025.3590410",

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AU - Gültekin, Yunus Can

AU - Wu, Kaiquan

AU - Korevaar, Cornelis Willem

AU - Alvarado, Alex

PY - 2026/2

Y1 - 2026/2

N2 - Atmospheric attenuation, atmospheric turbulence, geometric spread, and pointing errors, degrade the performance of free-space optical transmission. In the weak turbulence regime, the probability density function describing the distribution of the channel fading coefficient that models these four effects is known in the literature. This function is an integral equation, which makes it difficult to find simple analytical expressions of important performance metrics such as the bit error rate (BER) and symbol error rate (SER). In this paper, we present simple and accurate approximations of the average BER and SER for pulse-amplitude modulation (PAM) in the weak turbulence regime for an intensity modulation and direct detection system. Our numerical results show that the proposed expressions exhibit excellent accuracy when compared against Monte Carlo simulations. To demonstrate the usefulness of the developed approximations, we perform two asymptotic analyses. First, we investigate the additional transmit power required to maintain the same SER when the spectral efficiency increases by 1 b/symbol. Second, we study the asymptotic behavior of our SER approximation for dense PAM constellations and high transmit power.

AB - Atmospheric attenuation, atmospheric turbulence, geometric spread, and pointing errors, degrade the performance of free-space optical transmission. In the weak turbulence regime, the probability density function describing the distribution of the channel fading coefficient that models these four effects is known in the literature. This function is an integral equation, which makes it difficult to find simple analytical expressions of important performance metrics such as the bit error rate (BER) and symbol error rate (SER). In this paper, we present simple and accurate approximations of the average BER and SER for pulse-amplitude modulation (PAM) in the weak turbulence regime for an intensity modulation and direct detection system. Our numerical results show that the proposed expressions exhibit excellent accuracy when compared against Monte Carlo simulations. To demonstrate the usefulness of the developed approximations, we perform two asymptotic analyses. First, we investigate the additional transmit power required to maintain the same SER when the spectral efficiency increases by 1 b/symbol. Second, we study the asymptotic behavior of our SER approximation for dense PAM constellations and high transmit power.

KW - atmospheric turbulence

KW - bit error rate

KW - channel modeling

KW - Free-space optical communications

KW - pointing errors

KW - symbol error rate

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JO - IEEE Journal of Selected Topics in Quantum Electronics

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ER -

On Error Rate Approximations for FSO Systems With Weak Turbulence and Pointing Errors

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BIT-FREE: Hybrid coded modulation for reliable and power-efficient coherent free-space optics

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On Error Rate Approximations for FSO Systems With Weak Turbulence and Pointing Errors

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BIT-FREE: Hybrid coded modulation for reliable and power-efficient coherent free-space optics

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