350 rub
Journal Nonlinear World №3 for 2016 г.
Article in number:
Improving quality reception of radio signal with adaptive linearization characteristics of the nonlinear power amplifier
Authors:
A.Yu. Sizyakova - Ph.D. (Eng.), Associate Professor, Radio Systems Department, MPEI (Moscow). E-mail: anna_u_s@mail.ru Luu Hai Nam - Post-graduate Student, Radio Systems Department, MPEI (Moscow). E-mail: namlh234@mail.ru
Abstract:
Modern requirements for satellite communication systems for interference immunity and information transmission rate makes it ne-cessary apply signals with complex modulation types and high spectral efficiency. As a rule, used digital signals described changeable amplitude, such as when rounding the envelope low frequency modulating of oscillation by Nyquist. For wideband transmission channels are increased requirements to ensuring the path linearity with a high peak factor signal at the amplifier input, in particular for wideband transmitters and wideband power amplifiers. For realization linearization the characteristics of nonlinear power amplifier the most simple and effective technique is predistortion input. The problems linearization characteristics of nonlinear inertial power amplifier microwave frequency of radio signal by using digital predistortion linearizer (DPD). An algorithm for calculating the parameters of the model adaptive DPD based on Volterra series to the schemes with indirect learning architecture based on the least mean square method (LMS), normalized LMS (NLMS), recursive least square (RLS), RLS with exponential forgetting (RLS-Lamda) and Kalman (Kalman). Calculation coefficients of DPD are performed in real time. The characteristics of the signals at the output of the nonlinear amplifier with a linearizer and bit error rate (BER) at the receiver radio when linearization characteristics of power amplifier. Method of research is analytical calculation and simulation.
Pages: 71-78
References

 

  1. Sizjakova A.JU., Lyu KHajj Nam. Vlijanie nelinejjnogo usilitelja moshhnosti na kachestvo raboty sistemy svjazi // Tez. dokl. 19-jj Mezhdunar. nauchno-tekhnich. konf. studentov i aspirantov «Radioehlektronika, ehlektrotekhnika i ehnergetika». T. 1. M.: Izdelskijj dom MEHI. 2013. S. 147.
  2. Zhu A., Brazil T.J. An overview of Volterra series based behavioral modeling of RF/microwave power amplifiers // Proc. Wireless Microwave Technol. Conf. 2006. P. 101-107.
  3. Pedro J.C., Maas S.A. Comparative overview of microwave and wireless power-amplifier behavioral modeling approaches // IEEE Trans. on Microwave Theory and Techniques. 2005. V. 53. № 4. P. 1150-1163.
  4. Dennis R., Morgan A. Generalized memory polynomial model for digital predistortion of RF power amplifiers // IEEE Transactions on signal processing. October 2006. V. 54. № 10. P. 3852-3860.
  5. Sizjakova A.JU., Lyu KHajj Nam. Cifrovojj predyskazhajushhijj linearizator na osnove rjadov Volterra dlja nelinejjnogo usilitelja moshhnosti // Vestnik MEHI. 2016. №3 (v pechati).
  6. Sizjakova A.JU, Lyu KHajj Nam. Model cifrovogo predyskazhajushhego linearizatora na osnove rjadov Volterra dlja nelinejjnogo SVCH usilitelja moshhnosti. Rez. Int. dejatelnosti. (na registracii). 2016.
  7. Baudoin G., Jardin P., Marsalek R. Power amplifier linearization using pre-distortion with memory // IEEE Trans. Signal Process. 2007. V. 58. № 14. P. 1822-1828.
  8. SHutov V.D. Linearizacija SVCH-usilitelejj moshhnosti metodom cifrovykh predyskazhenijj: Avtoref. dis. - kand. fiz.-mat. nauk. Voronezh. 2015. S. 146.
  9. Cheong M.Y., Werner S., Bruno M., Figueroa J., Cousseau J., Wichman R. Adaptive piecewise linear predistorters for nonlinear power amplifiers with memory // IEEE Transactions on Circuit and Systems-I: Regular papers. 2012. V. 59. № 7. P. 1-14.
  10. Yang W.Y., Cao W., Chung TS., Morris J.Applied numerical methods using MATLAB. John Wiley & Sons. 2005. P. 71-79.
  11. Sergienko A.B. Cifrovaja obrabotka signalov: Uchebnik dlja vuzov. Izd. 2-e. SPb.: Piter. 2007. S. 751.
  12. Sergienko A.B. Algoritmy adaptivnojj filtracii: osobennosti realizacii v MATLAB // ExponentaPro. Matematika v prilozhenijakh. 2003. № 1. S. 18-28.
  13. Belov L.A., Rozhkov V.M., CHelnokov O.A., Filinykh D.A. Analiz nelinejjnykh iskazhenijj signalov v usiliteljakh moshhnosti na lampakh begushhejj volny // Vestnik MEHI. 2009. № 1. S. 43-48.
  14. Saleh A.A.M. Frequency-independent and frequency-dependent nonlinear models of TWT amplifiers // IEEE Transactions on Communications. 1981. V. COM-29. № 11. P. 1715-1720.
  15. Skljar B. Cifrovaja svjaz. Teoreticheskie osnovy i prakticheskoe primenenie. Izd. 2-e, ispr.: Per. s angl. M.: Izdatelskijj dom «Viljams». 2003. S. 1104.