The wireless revolution
暂无分享,去创建一个
[1] A. Maloberti. Radio transmission interface of the digital panEuropean mobile system , 1989, IEEE 39th Vehicular Technology Conference.
[2] T. Rappaport. Characterization of UHF multipath radio channels in factory buildings , 1989 .
[3] Robert J. C. Bultitude,et al. Propagation characteristics on microcellular urban mobile radio channels at 910 MHz , 1989, IEEE J. Sel. Areas Commun..
[4] D.J. Goodman,et al. Trends in cellular and cordless communications , 1991, IEEE Communications Magazine.
[5] Davood Molkdar,et al. Review on radio propagation into and within buildings , 1991 .
[6] D. Devasirvatham,et al. Multipath time delay spread in the digital portable radio environment , 1987, IEEE Communications Magazine.
[7] P. Estabrook,et al. A 20/30 GHz personal access satellite system design , 1989, IEEE International Conference on Communications, World Prosperity Through Communications,.
[8] K. Pahlavan,et al. Statistics of short time variations of indoor radio propagation , 1991, ICC 91 International Conference on Communications Conference Record.
[9] Theodore S. Rappaport,et al. Statistical channel impulse response models for factory and open plan building radio communicate system design , 1991, IEEE Trans. Commun..
[10] Donald C. Cox,et al. A radio system proposal for widespread low-power tetherless communications , 1991, IEEE Trans. Commun..
[11] George R. Cooper,et al. A spread-spectrum technique for high-capacity mobile communications , 1978 .
[12] J.I. Smith,et al. A computer generated multipath fading simulation for mobile radio , 1975, IEEE Transactions on Vehicular Technology.
[13] Theodore S. Rappaport,et al. Radio frequency noise measurements and models for indoor wireless communications at 918 MHz, 2.44 GHz, and 4.0 GHz , 1991, ICC 91 International Conference on Communications Conference Record.
[14] R.W. Lorenz. Impact of frequency-selective fading on digital land mobile radio communication at transmission rates of several hundred kbit/s , 1987, IEEE Transactions on Vehicular Technology.
[15] Theodore S. Rappaport,et al. 900 MHz path loss measurements and prediction techniques for in-building communication system design , 1991, [1991 Proceedings] 41st IEEE Vehicular Technology Conference.
[16] D. A. Hawbaker,et al. Indoor wideband radiowave propagation measurements at 1.3 GHz and 4.0 GHz , 1990 .
[17] L. B. Milstein,et al. Spread spectrum for mobile communications , 1991 .
[18] H. Hashemi. Simulation of the urban radio propagation channel , 1979, IEEE Transactions on Vehicular Technology.
[19] Laurence B. Milstein,et al. Effects of path loss and fringe user distribution on CDMA cellular frequency reuse efficiency , 1990, [Proceedings] GLOBECOM '90: IEEE Global Telecommunications Conference and Exhibition.
[20] K. Raith,et al. Capacity of digital cellular TDMA systems , 1991 .
[21] Theodore S. Rappaport,et al. Path loss, scattering and multipath delay statistics in four European cities for digital cellular and microcellular radiotelephone , 1991 .
[22] D. Cox. Time‐ and Frequency‐Domain Characterizations of Multipath Propagation at 910 MHz in a Suburban Mobile‐Radio Environment , 1972 .
[23] V. Fung,et al. Bit-error simulation of pi /4 DQPSK in flat and frequency-selective fading mobile radio channels with real time applications , 1991, ICC 91 International Conference on Communications Conference Record.
[24] T.S. Rappaport,et al. Indoor radio communications for factories of the future , 1989, IEEE Communications Magazine.
[25] Theodore S. Rappaport,et al. UHF fading in factories , 1989, IEEE J. Sel. Areas Commun..
[26] S. Yoshida,et al. Theoretical prediction of mean field strength for urban mobile radio , 1991 .
[27] H. Ochsner,et al. DECT-digital European cordless telecommunications , 1989, IEEE 39th Vehicular Technology Conference.
[28] S. Seidel,et al. 900-MHz multipath propagation measurements for US digital cellular radiotelephone , 1990 .