احمد کشاورز

‎During past few years‎, ‎OFDM has gained lots of attention as a multicarrier modulation technique and it has been very well known in high data rate transmission due to its various potentials‎, ‎like as its ability to combat multipath fading and intersymbol interference‎, ‎high bandwidth efficiency and finally its simplicity of implementation‎. ‎Also it has been accepted as a convenient modulation method based on many standards‎, ‎for examples DAB‎, ‎DVB(DVB-T‎, ‎DVB-T2) and WLAN(802.11x‎, ‎HyperLAN2)‎. ‎Even though these systems show lots of advantages‎, ‎one of their main disadvantages is high PAPR that could result in the OFDM from HPA which will affect the amplitude of the transmitted signals‎. ‎That also will lead to increase bit error rate and spectral spreading‎, ‎finally it will cause the malfunction of the whole system performance‎. ‎Up to now there have been several suggested methods to decrease PAPR in OFDM systems‎. ‎In this thesis‎, ‎there have been several reported new methods to decrease PAPR in SISO and MIMO systems based on the fast Reed--Solomon codes over $\mbox{GF}(257)$ and $\mbox{GF}(65537)$‎. ‎In these methods some different candidates blocks with the same information compare to the main block have been produced‎. ‎Among those‎, ‎one or some blocks with the smaller PAPR have been selected‎. ‎The length of the code's blocks on the mentioned prime fields are similar to the power of two of those of OFDM blocks‎, ‎hence in order to implement its coding and decoding‎, ‎it is possible to use the fast fourier transnsform algorithms‎. ‎On the other hand‎, ‎addition and multiplication operations can be done modular on these fields hence have less complications‎. ‎Any small changes in the symbol's data of these codes will result in the new codes that will be suitable to produce independent block's candidate‎. ‎Knowing the fact that these codes have capability of error correction and are MDS‎, ‎they can be used for both error correction and decreasing PA