We investigate the average Level Crossing Rate (LCR) and Average Fading Duration (AFD) of multiuser single relay co- operation wireless uplinks over independent and non-identically distributed (i.ni.d) Ray- leig...We investigate the average Level Crossing Rate (LCR) and Average Fading Duration (AFD) of multiuser single relay co- operation wireless uplinks over independent and non-identically distributed (i.ni.d) Ray- leigh fading channels. We first present the statistical analyses of the first-hop equivalent envelope. Then, we investigate the LCR and AFD of an equivalent end-to-end envelope, and present the closed-form solutions to LCR and AFD, which are given with integral forms. Finally, we derive the Laplace approximations of LCR and AFD as well as the upper and lower bounds. The numerical results of LCR show that the upper bound is tight. For multi user systems with different number of mobile users, the analyses indicate that the LCRs are approximately the same at the low level of the envelope. envelope However, there are at the high level of the reasonable differences among the curves of LCRs. Due to that fact that AFD is the inverse function of LCR, the results for AFD are the opposite.展开更多
基金supported by the Natural Science Foundation of China under Grant No.61261015the 973 Project under Grant No.2013CB329104+4 种基金the National Natural Science Foundation of China under Grants No. 61071090,No. 61171093the Key Projects under GrantsNo. 2011ZX03005-004-003, No. BK2011027the China Postdoctoral Science Foundation under Grant No. 2012M521105Research Fund for the Doctoral Program of Higher Educationof China under Grant No. 20113223110001the project 11KJA510001 and PAPD
文摘We investigate the average Level Crossing Rate (LCR) and Average Fading Duration (AFD) of multiuser single relay co- operation wireless uplinks over independent and non-identically distributed (i.ni.d) Ray- leigh fading channels. We first present the statistical analyses of the first-hop equivalent envelope. Then, we investigate the LCR and AFD of an equivalent end-to-end envelope, and present the closed-form solutions to LCR and AFD, which are given with integral forms. Finally, we derive the Laplace approximations of LCR and AFD as well as the upper and lower bounds. The numerical results of LCR show that the upper bound is tight. For multi user systems with different number of mobile users, the analyses indicate that the LCRs are approximately the same at the low level of the envelope. envelope However, there are at the high level of the reasonable differences among the curves of LCRs. Due to that fact that AFD is the inverse function of LCR, the results for AFD are the opposite.
