T
Theodore S. Rappaport
Researcher at New York University
Publications - 503
Citations - 76147
Theodore S. Rappaport is an academic researcher from New York University. The author has contributed to research in topics: Path loss & Multipath propagation. The author has an hindex of 112, co-authored 490 publications receiving 68853 citations. Previous affiliations of Theodore S. Rappaport include University of Waterloo & University of Texas at Austin.
Papers
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Journal ArticleDOI
Millimeter-Wave Enhanced Local Area Systems: A High-Data-Rate Approach for Future Wireless Networks
Amitava Ghosh,Timothy A. Thomas,Mark C. Cudak,Rapeepat Ratasuk,Prakash Moorut,Frederick W. Vook,Theodore S. Rappaport,George R. MacCartney,Shu Sun,Shuai Nie +9 more
TL;DR: A case is made for using mmWave for a fifth generation (5G) wireless system for ultradense networks by presenting an overview of enhanced local area (eLA) technology at mmWave with emphasis on 5G requirements, spectrum considerations, propagation and channel modeling, air-interface and multiantenna design, and network architecture solutions.
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Position location using wireless communications on highways of the future
TL;DR: The fundamental technical challenges and business motivations behind wireless position location systems are described, and promising techniques for solving the practical position location problem are treated.
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Spatial and temporal characteristics of 60-GHz indoor channels
TL;DR: The measurement results confirm that the majority of the multipath components can be determined from image based ray tracing techniques for line-of-sight (LOS) applications and can be used as empirical values for broadband wireless system design for 60-GHz short-range channels.
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Mimo for millimeter-wave wireless communications: beamforming, spatial multiplexing, or both?
TL;DR: This tutorial explores the fundamental issues involved in selecting the best communications approaches for mmWave frequencies, and provides insights, challenges, and appropriate uses of each MIMO technique based on early knowledge of the mmWave propagation environment.
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Site-specific propagation prediction for wireless in-building personal communication system design
TL;DR: Time delay comparison shows that the amplitudes of many significant multipath components are accurately predicted by this model, and the effective building material properties are derived for two dissimilar buildings based upon comparison of measured and predicted power delay profiles.