History of Communications/Radio Wave Propagation from Marconi to MIMO

Radio waves from a few kilohertz to millimeter-wave frequencies play a key role in modern wireless communications. The development over the last 120 years is traced with an emphasis on communication aspects and physical phenomena rather than theory. The early years were characterized by experiments with no theory and lack of knowledge of ionospheric propagation. High frequency (HF) propagation via the ionosphere at HF frequencies meant global communications for thousands of kilometers. Another natural medium is the atmosphere near the Earth’s surface, the troposphere, leading sometimes to anomalous phenomena, but it is also important for satellite signals near the horizon. Propagation over man-made structures like in an urban environment is covered by the simple Hata equations for first generation cellular systems. Higher generations must include delay information to accurately describe propagation, and the Hatalike equations may be extended into the millimeter frequency range. Indoor propagation may also be covered by a diffuse impulse response. Finally, the promise of increased spectral efficiency is given by multiple-input multiple-output (MIMO), if certain conditions of uncorrelated antenna signals are fulfilled.

[1]  Jack H. Winters,et al.  On the Capacity of Radio Communication Systems with Diversity in a Rayleigh Fading Environment , 1987, IEEE J. Sel. Areas Commun..

[2]  David R. Cox,et al.  Correlation Bandwidth and Delay Spread Multipath Propagation Statistics for 910-MHz Urban Mobile Radio Channels , 1975, IEEE Trans. Commun..

[3]  G Falciasecca Marconi's Early Experiments in Wireless Telegraphy, 1895 , 2010, IEEE Antennas and Propagation Magazine.

[4]  Michael Cheffena,et al.  Propagation Channel Characteristics of Industrial Wireless Sensor Networks [Wireless Corner] , 2016, IEEE Antennas and Propagation Magazine.

[5]  J. Chisholm Progress of tropospheric propagation research related to communications beyond the horizon , 1956 .

[6]  Desmond P. Taylor,et al.  A Statistical Model for Indoor Multipath Propagation , 2007 .

[7]  J. Wait The ancient and modern history of EM ground-wave propagation , 1998 .

[8]  D. C. Cox A measured delay-Doppler scattering function for multipath propagation at 910 MHz in an urban mobile radio environment , 1973 .

[9]  Larry J. Greenstein,et al.  An empirical indoor path loss model for ultra-wideband channels , 2003, Journal of Communications and Networks.

[10]  Ergin Dinc,et al.  More Than the Eye Can See: Coherence Time and Coherence Bandwidth of Troposcatter Links for Mobile Receivers , 2015, IEEE Vehicular Technology Magazine.

[11]  Theodore S. Rappaport,et al.  Investigation of Prediction Accuracy, Sensitivity, and Parameter Stability of Large-Scale Propagation Path Loss Models for 5G Wireless Communications , 2016, IEEE Transactions on Vehicular Technology.