Profile
International Journal of Computer & Software Engineering Volume 4 (2019), Article ID 4:IJCSE-143, 7 pages
https://doi.org/10.15344/2456-4451/2019/143
Research Article
Special Issue: Wireless and Mobile Networks and Their Applications
Transmission Performance Improvement by Non-Linear Distortion Noise Power Control in Multi-Band Systems

Shigeru Tomisato*, Jumpei Onji and Kazuhiro Uehara

Graduate School of Natural Science and Technology, Okayama University, Japan
Prof. Shigeru Tomisato, Graduate School of Natural Science and Technology, Okayama University, 3-1-1, Tsushima-Naka, Okayama, 700-8530 Japan; E-mail: tomisato@okayama-u.ac.jp
30 December 2018; 04 March 2019; 06 March 2019
Tomisato S, Onji J, Uehara K (2019) Transmission Performance Improvement by Non-Linear Distortion Noise Power Control in Multi-Band Systems. Int J Comput Softw Eng 4: 143. doi: https://doi.org/10.15344/2456-4451/2019/143

References

  1. Mitola J (1999) Cognitive radio for flexible mobile multimedia communications. IEEE International Workshop on Mobile Multimedia Communications. View
  2. Haykin S (2005) Cognitive radio: brain-empowered wireless communications. IEEE J Select Area Commun 23: 201-220. View
  3. Harada H, Murakami H, Ishizu K, Filin S, Saito Y, et al. (2007) A software defined cognitive radio system: cognitive wireless cloud. IEEE Global Telecommunications Conference. View
  4. Fujii H, Yoshino H (2009) Spectrum sharing by adaptive transmit power control for low priority systems and achievable capacity. IEICE Trans. Commun 92: 2568-2576. View
  5. Bassam S, Helaoui M, Ghannouchi F (2011) 2-D Digital Predistortion (2-D-DPD) architecture for concurrent dual-band transmitters. IEEE Trans Microw Theory Tech 59: 2547-2553. View
  6. Fukuda A, Furuta T, Okazaki H, Narahashi S, Nojima T, et al. (2012) Low-loss matching network design for band-switchable multi-band power amplifier. IEICE Trans Electron 95: 1172-1181. View
  7. Bassam S, Chen W, Helaoui M, Channouchi F (2013) Transmitter architecture for CA: Carrier aggregation in LTE-advanced systems. IEEE Microwave Mag 14: 78-86. View
  8. Li X, Cimini LJ (1998) Effects of clipping and filtering on the performance of OFDM. IEEE Commun Lett 2: 131-133. View
  9. Armstrong J (2002) Peak-to-Average power reduction for OFDM by repeated clipping and frequency domain filtering. Electron Lett 38: 246-247. View
  10. Rao KD, Murthy TSN (2007) Analysis of effects of clipping and filtering on the performance of MB-OFDM UWB signals. International Conference on Digital Signal Processing. View
  11. Tomisato S, Hata M (2004) PAPR reduction method using adaptive peak reduction signal control for OFDM transmission system. Proc of WPMC. View
  12. Rapp C (1991) Effects of HPA-nonlinearity on a 4DPSK/OFDM signal for a digital sound broadcasting system. Second European Conference on Satellite Communications. View