Abstract
In this paper, the design analysis and construction of the Optical Wireless Communication (OWC) system are presented based on a new spreading code sequence. This new code is called Double Length Modified Prime Code (DL-MPC), which is designed to enhance the system security and achieves better Bit Error Rate (BER) performance. Additionally, the Binary Phase Shift Keying (BPSK) coherent homodyne Optical Code Division Multiple Access (OCDMA) transceiver is utilized based on the proposed code to improve the system performance. In the coherent homodyne system, the Mach–Zehnder Interferometer (MZI) is used as a phase modulator/demodulator. As well in this study, the proposed code construction and correlation characteristics have been investigated. Moreover, the OWC channel model is illustrated and further analyzed. The analysis and evaluation of overall system BER performance and throughput have been presented considering the effect of the Multi-User Interference (MUI) as a source of noise. Finally, the results indicated that the coherent homodyne OCDMA transceiver based on the DL-MPC outperforms the same system based on the popular codes concerning the system BER performance and system throughput.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Al-Kinani, A., Wang, C.-X., Zhou, L., & Zhang, W. (2018). Optical wireless communication channel measurements and models. IEEE Communications Surveys & Tutorials,20(3), 1939–1962.
Malik, M. T., Hossain, M. J., Cheng, J., & Alouini, M. S. (2015). Performance of BICM-Based QAM-SIM OWC over gamma-gamma turbulence channels. IEEE Communications Letters,19(5), 731–734.
Zhang, Y.-Y., Hong-Yi, Y., Zhang, J.-K., & Zhu, Y.-J. (2016). optimal design of linear space code for MIMO optical wireless communications. IEEE Photonics Journal,8(2), 7902612.
Kishore, V., & Mani, V. V. (2019). An LED modelled GFDM for optical wireless communications. AEU-International Journal of Electronics and Communications,101, 54–61.
Vappangi, S., & Vakamulla, V. M. (2018). Channel estimation in ACO-OFDM employing different transforms for VLC. AEU-International Journal of Electronics and Communications,84, 111–122.
Vellakudiyan, J., Muthuchidambaranathan, P., Bui, F. M., & Palliyembil, V. (2015). Performance of a subcarrier intensity modulated differential phase-shift keying over generalized turbulence channel. AEU-International Journal of Electronics and Communications,69(11), 1569–1573.
Barroso, A. R. F., & Johnson, J. (2017). Optical wireless communications omnidirectional receivers for vehicular communications. AEU-International Journal of Electronics and Communications,79, 102–109.
Prabu, K., Gupta, S., & Jaiswal, S. (2018). Impact of pointing errors and turbulence effects on POLSK and coherent OWC-based FSO system over generalized turbulence channel model. Photonic Network Communications,36, 96.
Cheng-Gang, W.-X., Xiao-ming, S., & Tie-ying, Z. (2007). New modulation scheme for optical wireless communication systems. IET Conference on Wireless, Mobile and Sensor Networks,2007(CCWMSN07), 489–492.
Patnaik, B., & Sahu, P. K. (2012). Inter-satellite optical wireless communication system design and simulation. IET Communications,6(16), 2561–2567.
Green, R. J., & Leeson, M. S. (2008). Editorial: Optical wireless communications. IET Communications,2(1), 1–2.
Morsy, M. A., & Alsayyari, A. (2019). Multi-rate OCDMA system BER performance evaluations for different ML-code sequences. Optical and Quantum Electronics,51, 198.
Morsy, M. A. (2018). Analysis and design of weighted MPC in incoherent synchronous OCDMA network. Optical and Quantum Electronics,50, 387.
Morsy, M. A., & Abdulaziz S. Alsayyari. (2019). Performance control of incoherent synchronous PPM-OCDMA networks. In 2019 2nd IEEE Middle East and North Africa COMMunications Conference (MENACOMM), pp. 1–4. IEEE.
Ismail, M. A. M., Alsayyari, A., & Galal, O. H. (2019). Performance analysis of optical code division multiple access networks for multimedia applications using multilength weighted modified prime codes. Optical Engineering,58(3), 035101.
Morsy, M. A., Hassan, K. M., Morshed, A. H., & Elhennawy, A. (2006). Analysis of optical code division multiple access passive networks for different encoder delay elements. In 2006 International Conference on Computer Engineering and Systems, Cairo, 2006, pp. 294–299.
Morsy, M. A., Rajab, H. S. A., & Al-Obaidan, H. M. (2013). Performance of passive OCDMA networks for different encoder/decoder delay lines. International Journal of Optics and Applications,3(3), 19–26.
Khandelwal, V., Kaushik, R., & Jain, R. C. (2017). A simple closed form approximation of average channel capacity for weakly turbulent optical wireless links. Wireless Personal Communications.,201(95), 2665.
Zeng, Z., Fu, S., Zhang, H., Dong, Y., & Cheng, J. (2016). A survey of underwater optical wireless communications. IEEE Communications Surveys and Tutorials,19(1), 204–238.
Arnon, S. (2010). Underwater optical wireless communication network. Optical Engineering,49(1), 015001.
Otero, C. E., Haber, R., Peter, A. M., Alsayyari, A., & Kostanic, I. (2015). A wireless sensor networks' analytics system for predicting performance in on-demand deployments. IEEE Systems Journal,9(4), 1344–1353.
Alsayyari, A., Kostanic, I., Otero, C. E, Aldosary, A. (2017). An empirical path loss model for wireless sensor network deployment in a dense tree environment. In IEEE Sensors Applications Symposium (SAS), pp. 1–6.
Xu, J., Kong, M., Lin, A., Song, Y., Yu, X., Qu, F., et al. (2016). OFDM-based broadband underwater wireless optical communication system using a compact blue LED. Optics Communications,369, 100–105.
Cossu, G., Sturniolo, A., Messa, A., Scaradozzi, D., & Ciaramella, E. (2018). Full-fledged 10Base-T ethernet underwater optical wireless communication system. IEEE Journal on Selected Areas in Communications,36(1), 194–202.
Nakamura, K., Mizukoshi, I., & Hanawa, M. (2015). Optical wireless transmission of 405 nm, 1.45 Gbit/s optical IM/DD-OFDM signals through a 4.8 m underwater channel. Optics Express,23(2), 1558–1566.
Kaushal, H., & Kaddoum, G. (2016). Underwater optical wireless communication. IEEE Access,4, 1518–1547.
Alomari, M. M., Wafa, M., Rehab, A., Babhair, G. G., & Hemalatha, M. (2017). Vision and challenges of underwater optical wireless communication: A survey. International Journal of Computers and Applications,167(8), 8–10.
Saeed, N., Celik, A., Al-Naffouri, T. Y., & Alouini, M.-S. (2018) Underwater optical sensor networks localization with limited connectivity. In submitted to IEEE International of Conferences on Acoustics, Speech and Signal Processing (ICASSP), pp. 1–5
Karbassian, M. M., & Ghafouri-Shiraz, H. (2007). Performance analysis of Heterodyne detected coherent optical CDMA using a novel prime code family. Journal of Lightwave Technology,25, 3028–3034.
Dressler, F., Mutschlechner, M., Li, B., Kapitza, R., Ripperger, S., Eibel, C., et al. (2016). Monitoring bats in the wild: On using erasure codes for energy-efficient wireless sensor networks. ACM Transactions on Sensor Networks (TOSN),12(1), 1–29.
AlQuwaiee, H., Ansari, I. S., & Alouini, M. S. (2015). On the performance of free-space optical communication systems over double generalized gamma channel. IEEE Journal on Selected Areas in Communications,33(9), 1829–1840.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Morsy, M.A., Alsayyari, A.S. Performance analysis of coherent BPSK-OCDMA wireless communication system. Wireless Netw 26, 4491–4505 (2020). https://doi.org/10.1007/s11276-020-02355-7
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11276-020-02355-7