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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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Book ChapterDOI
Spatial channel modeling for wireless communications
TL;DR: This chapter presents a novel theoretical framework for relating the small-scale fading characteristics of a wireless channel to multipath angle-of-arrival, and three shape factors that have simple, intuitive geometrical interpretations are shown to describe the statistics of received signal fluctuations in a fading multipath channel.
Patent
Networking method with broadband relay
TL;DR: In this paper, an ultrawideband radio transceiver/repeater provides a low cost infrastructure solution that merges wireless and wired network devices while providing connection to the plant, flexible repeater capabilities, network security, traffic monitoring and provisioning, and traffic flow control for wired and wireless connectivity of devices or networks.
Proceedings ArticleDOI
Distributed real time signal processing for cellular and paging traffic analysis, fraud detection, and intelligent wireless network control
TL;DR: This arrangement of remote receivers can be configured to measure and respond to real-time multiple-channel traffic on cellular and paging channels for market studies, adaptive RF coverage and control, fraud detection and abatement, and law enforcement applications.
Posted Content
Real-time Millimeter Wave Omnidirectional Channel Sounder Using Phased Array Antennas
Aditya Chopra,Andrew Thornburg,Ojas Kanhere,Abbas Termos,Saeed S. Ghassemzadeh,Theodore S. Rappaport +5 more
TL;DR: A channel sounder design capable of covering 360 degrees in azimuth and 60 degrees in elevation with 200 individual beam directions by using four phased arrays simultaneously is presented, allowing channel sounding to be conducted while either the transmitter, or the receiver, or both are moving.