[1. Pleros, N., Vyrsokinos, K., Tsagkaris, K., Tselikas, N. (2009). A 60 GHz Radio-Over-Fiber Network Architecture for Seamless Communication with High Mobility. Journal of Light Wave Technology, 27(12), 1957-1967.10.1109/JLT.2009.2022505]Search in Google Scholar
[2. Ng’oma, A. (2009). Radio-over-Fiber Systems for Multi-Gbps Wireless Communication. In A. Ng’oma, M. Sauer (Eds.), Communications and Photonics Conference and Exhibition (ACP), vol. 7632 (pp. 1-10).10.1364/ACP.2009.FF1]Search in Google Scholar
[3. Il'chenko, M.E., Sunduchkov, K.S., Volkov, S.E. et al. (2008). Interactive heterogeneous telecommunication system 4G with wireless access in the millimeter range for the multi media services provisioning to mobile subscribers. Communication, 7-8, 28-32. (In Russian)]Search in Google Scholar
[4. Kim, H. B., Emmelmann, M., Rathke, B., Wolisz, A. (2005). Radio over Fiber Network Architecture for Road Vehicle Communication Systems. In Proceedings of IEEE Vehicular Technology Conference VTC 2005-Spring, 2005 IEEE 61st, Vol. 5 (pp. 2920-2924).]Search in Google Scholar
[5. Lannoo, B., Colle, D., Pickavet, M., Demeester, P. (2003). Radio over Fiber Technique for Multimedia Train Environment. NOC, pp. 99-106.]Search in Google Scholar
[6. Sunduchkov, K. S., Tykhonenko, I. I., Iashchuk, O. S. (2012). Formation of services set and parameters of OFDM-symbols in the distributed mobile communication network. Communication, 2 (98), 22-26. (In Russian)]Search in Google Scholar
[7. Iashchuk, O. S., Sunduchkov, K. S. (2012). Mathematical model of selective conversion in the vehicle mobile terminal receiver. Radio Electronic and Computer Systems, 1(53), 125-131. (In Russian)]Search in Google Scholar