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ORCIDTheodore S. Rappaport
Theodore Ted S. Rappaport
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Books and Theses
- 1996
[b1]Theodore S. Rappaport:
Wireless communications - principles and practice. Prentice Hall 1996, ISBN 978-0-13-375536-7, pp. I-XVI, 1-641
Journal Articles
- 2024
- [j93]Hitesh Poddar
, Shihao Ju, Dipankar Shakya, Theodore S. Rappaport:
A Tutorial on NYUSIM: Sub-Terahertz and Millimeter-Wave Channel Simulator for 5G, 6G, and Beyond. IEEE Commun. Surv. Tutorials 26(2): 824-857 (2024) - [j92]Theodore S. Rappaport, Mingjun Ying, Nicola Piovesan, Antonio De Domenico, Dipankar Shakya:
Waste Factor and Waste Figure: A Unified Theory for Modeling and Analyzing Wasted Power in Radio Access Networks for Improved Sustainability. IEEE Open J. Commun. Soc. 5: 4839-4867 (2024) - [j91]Dipankar Shakya, Mingjun Ying, Theodore S. Rappaport, Hitesh Poddar, Peijie Ma, Yanbo Wang, Idris Al-Wazani:
Comprehensive FR1(C) and FR3 Lower and Upper Mid-Band Propagation and Material Penetration Loss Measurements and Channel Models in Indoor Environment for 5G and 6G. IEEE Open J. Commun. Soc. 5: 5192-5218 (2024) - [j90]Shihao Ju, Dipankar Shakya, Hitesh Poddar, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
142 GHz Sub-Terahertz Radio Propagation Measurements and Channel Characterization in Factory Buildings. IEEE Trans. Wirel. Commun. 23(7): 7127-7143 (2024) - 2023
- [j89]Theodore S. Rappaport:
Crucible Of Communications: How Amateur Radio Launched The Information Age And Brought High Tech To Life Part 2: Hams Bring Real-Time Communications To The World Invited Article. IEEE Commun. Mag. 61(11): 10-23 (2023) - 2022
- [j88]Theodore S. Rappaport:
Crucible of Communications: How Amateur Radio Launched the Information Age and Brought High Tech to Life: Part 1: The Birth and Breadth of the Ham Radio Hobby Invited Article. IEEE Commun. Mag. 60(10): 6-10 (2022) - [j87]Ojas Kanhere, Hitesh Poddar, Yunchou Xing, Dipankar Shakya, Shihao Ju, Theodore S. Rappaport:
A Power Efficiency Metric for Comparing Energy Consumption in Future Wireless Networks in the Millimeter-Wave and Terahertz Bands. IEEE Wirel. Commun. 29(6): 56-63 (2022) - 2021
- [j86]Najath Akram, Arjuna Madanayake, Sravan Kumar Pulipati, Viduneth Ariyarathna, Satheesh Bojja Venkatakrishnan, Dimitra Psychogiou, John L. Volakis, Theodore S. Rappaport, Thomas L. Marzetta:
Frequency-Multiplexed Array Digitization for MIMO Receivers: 4-Antennas/ADC at 28 GHz on Xilinx ZCU-1285 RF SoC. IEEE Access 9: 142743-142753 (2021) - [j85]Ojas Kanhere, Theodore S. Rappaport:
Position Location for Futuristic Cellular Communications: 5G and Beyond. IEEE Commun. Mag. 59(1): 70-75 (2021) - [j84]Yu Wang, Ticao Zhang, Shiwen Mao, Theodore Ted S. Rappaport:
Directional neighbor discovery in mmWave wireless networks. Digit. Commun. Networks 7(1): 1-15 (2021) - [j83]Yunchou Xing, Theodore S. Rappaport, Amitava Ghosh:
Millimeter Wave and Sub-THz Indoor Radio Propagation Channel Measurements, Models, and Comparisons in an Office Environment. IEEE Commun. Lett. 25(10): 3151-3155 (2021) - [j82]Yunchou Xing, Theodore S. Rappaport:
Terahertz Wireless Communications: Co-Sharing for Terrestrial and Satellite Systems Above 100 GHz. IEEE Commun. Lett. 25(10): 3156-3160 (2021) - [j81]Yunchou Xing, Theodore S. Rappaport:
Millimeter Wave and Terahertz Urban Microcell Propagation Measurements and Models. IEEE Commun. Lett. 25(12): 3755-3759 (2021) - [j80]Shihao Ju, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
Millimeter Wave and Sub-Terahertz Spatial Statistical Channel Model for an Indoor Office Building. IEEE J. Sel. Areas Commun. 39(6): 1561-1575 (2021) - [j79]Najath Akram, Viduneth Ariyarathna, Soumyajit Mandal, Leonid Belostotski, Theodore S. Rappaport, Arjuna Madanayake:
Spacetime Frequency-Multiplexed Digital-RF Array Receivers With Reduced ADC Count. IEEE Trans. Circuits Syst. II Express Briefs 68(8): 2840-2844 (2021) - [j78]Dipankar Shakya, Ting Wu, Michael E. Knox, Theodore S. Rappaport:
A Wideband Sliding Correlation Channel Sounder in 65 nm CMOS: Evaluation Board Performance. IEEE Trans. Circuits Syst. II Express Briefs 68(9): 3043-3047 (2021) - 2020
- [j77]Arjuna Madanayake, Renato J. Cintra, Najath Akram, Viduneth Ariyarathna, Soumyajit Mandal, Vítor de A. Coutinho, Fábio M. Bayer, Diego F. G. Coelho, Theodore S. Rappaport:
Fast Radix-32 Approximate DFTs for 1024-Beam Digital RF Beamforming. IEEE Access 8: 96613-96627 (2020) - 2019
- [j76]James F. Harvey, Michael B. Steer, Theodore S. Rappaport:
Exploiting High Millimeter Wave Bands for Military Communications, Applications, and Design. IEEE Access 7: 52350-52359 (2019) - [j75]Theodore S. Rappaport, Yunchou Xing, Ojas Kanhere, Shihao Ju, Arjuna Madanayake, Soumyajit Mandal, Ahmed Alkhateeb, Georgios C. Trichopoulos:
Wireless Communications and Applications Above 100 GHz: Opportunities and Challenges for 6G and Beyond. IEEE Access 7: 78729-78757 (2019) - [j74]Dacheng Xu, Theodore S. Rappaport:
Construction on teaching evaluation index system of track and field general course for physical education major in light of wireless network technology. J. Intell. Fuzzy Syst. 37(3): 3435-3443 (2019) - [j73]George R. MacCartney, Theodore S. Rappaport:
Millimeter-Wave Base Station Diversity for 5G Coordinated Multipoint (CoMP) Applications. IEEE Trans. Wirel. Commun. 18(7): 3395-3410 (2019) - 2018
- [j72]Marco Mezzavilla, Michele Polese, Andrea Zanella, Aditya Dhananjay, Sundeep Rangan, Coitt Kessler, Theodore S. Rappaport, Michele Zorzi:
Public Safety Communications above 6 GHz: Challenges and Opportunities. IEEE Access 6: 316-329 (2018) - [j71]Mansoor Shafi, Jianhua Zhang, Harsh Tataria, Andreas F. Molisch, Shu Sun, Theodore S. Rappaport, Fredrik Tufvesson, Shangbin Wu, Koshiro Kitao:
Microwave vs. Millimeter-Wave Propagation Channels: Key Differences and Impact on 5G Cellular Systems. IEEE Commun. Mag. 56(12): 14-20 (2018) - [j70]Bolei Wang, Feifei Gao, Shi Jin, Hai Lin, Geoffrey Ye Li, Shu Sun, Theodore S. Rappaport:
Spatial-Wideband Effect in Massive MIMO with Application in mmWave Systems. IEEE Commun. Mag. 56(12): 134-141 (2018) - [j69]Viduneth Ariyarathna, Arjuna Madanayake, Xinyao Tang, Diego F. G. Coelho, Renato J. Cintra, Leonid Belostotski, Soumyajit Mandal, Theodore S. Rappaport:
Analog Approximate-FFT 8/16-Beam Algorithms, Architectures and CMOS Circuits for 5G Beamforming MIMO Transceivers. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(3): 466-479 (2018) - [j68]Sirani M. Perera, Viduneth Ariyarathna, Nilan Udayanga, Arjuna Madanayake, Ge Wu, Leonid Belostotski, Yingying Wang, Soumyajit Mandal, Renato J. Cintra, Theodore S. Rappaport:
Wideband N-Beam Arrays Using Low-Complexity Algorithms and Mixed-Signal Integrated Circuits. IEEE J. Sel. Top. Signal Process. 12(2): 368-382 (2018) - [j67]Shu Sun, Theodore S. Rappaport, Mansoor Shafi, Pan Tang, Jianhua Zhang, Peter J. Smith:
Propagation Models and Performance Evaluation for 5G Millimeter-Wave Bands. IEEE Trans. Veh. Technol. 67(9): 8422-8439 (2018) - [j66]Shu Sun, Theodore S. Rappaport, Mansoor Shafi, Harsh Tataria:
Analytical Framework of Hybrid Beamforming in Multi-Cell Millimeter-Wave Systems. IEEE Trans. Wirel. Commun. 17(11): 7528-7543 (2018) - 2017
- [j65]George R. MacCartney, Theodore S. Rappaport:
A Flexible Millimeter-Wave Channel Sounder With Absolute Timing. IEEE J. Sel. Areas Commun. 35(6): 1402-1418 (2017) - [j64]George R. MacCartney, Theodore S. Rappaport:
Rural Macrocell Path Loss Models for Millimeter Wave Wireless Communications. IEEE J. Sel. Areas Commun. 35(7): 1663-1677 (2017) - [j63]Jaswinder Lota, Shu Sun, Theodore S. Rappaport, Andreas Demosthenous:
5G Uniform Linear Arrays With Beamforming and Spatial Multiplexing at 28, 37, 64, and 71 GHz for Outdoor Urban Communication: A Two-Level Approach. IEEE Trans. Veh. Technol. 66(11): 9972-9985 (2017) - [j62]Parisa A. Eliasi, Sundeep Rangan, Theodore S. Rappaport:
Low-Rank Spatial Channel Estimation for Millimeter Wave Cellular Systems. IEEE Trans. Wirel. Commun. 16(5): 2748-2759 (2017) - 2016
- [j61]Sooyoung Hur, Sangkyu Baek, Byungchul Kim, Youngbin Chang, Andreas F. Molisch, Theodore S. Rappaport, Katsuyuki Haneda, Jeongho Park:
Proposal on Millimeter-Wave Channel Modeling for 5G Cellular System. IEEE J. Sel. Top. Signal Process. 10(3): 454-469 (2016) - [j60]Shu Sun, Theodore S. Rappaport, Timothy A. Thomas, Amitava Ghosh, Huan Cong Nguyen, István Z. Kovács, Ignacio Rodriguez, Ozge H. Koymen, Andrzej Partyka:
Investigation of Prediction Accuracy, Sensitivity, and Parameter Stability of Large-Scale Propagation Path Loss Models for 5G Wireless Communications. IEEE Trans. Veh. Technol. 65(5): 2843-2860 (2016) - [j59]Ahmed Iyanda Sulyman, Abdulmalik Alwarafy, George R. MacCartney, Theodore S. Rappaport, Abdulhameed Alsanie:
Directional Radio Propagation Path Loss Models for Millimeter-Wave Wireless Networks in the 28-, 60-, and 73-GHz Bands. IEEE Trans. Wirel. Commun. 15(10): 6939-6947 (2016) - 2015
- [j58]Zhifeng He, Shiwen Mao, Theodore Ted S. Rappaport:
On Link Scheduling Under Blockage and Interference in 60-GHz Ad Hoc Networks. IEEE Access 3: 1437-1449 (2015) - [j57]George R. MacCartney, Theodore S. Rappaport, Mathew K. Samimi, Shu Sun:
Millimeter-Wave Omnidirectional Path Loss Data for Small Cell 5G Channel Modeling. IEEE Access 3: 1573-1580 (2015) - [j56]George R. MacCartney, Theodore S. Rappaport, Shu Sun, Sijia Deng:
Indoor Office Wideband Millimeter-Wave Propagation Measurements and Channel Models at 28 and 73 GHz for Ultra-Dense 5G Wireless Networks. IEEE Access 3: 2388-2424 (2015) - [j55]In Keun Son, Shiwen Mao, Yihan Li, Min Chen, Michelle X. Gong, Theodore Ted S. Rappaport:
Frame-Based Medium Access Control for 5G Wireless Networks. Mob. Networks Appl. 20(6): 763-772 (2015) - [j54]Theodore S. Rappaport, George R. MacCartney, Mathew K. Samimi, Shu Sun:
Wideband Millimeter-Wave Propagation Measurements and Channel Models for Future Wireless Communication System Design. IEEE Trans. Commun. 63(9): 3029-3056 (2015) - [j53]C. Nicolas Barati, S. Amir Hosseini, Sundeep Rangan, Pei Liu, Thanasis Korakis, Shivendra S. Panwar, Theodore S. Rappaport:
Directional Cell Discovery in Millimeter Wave Cellular Networks. IEEE Trans. Wirel. Commun. 14(12): 6664-6678 (2015) - [j52]Mathew K. Samimi, Theodore S. Rappaport, George R. MacCartney:
Probabilistic Omnidirectional Path Loss Models for Millimeter-Wave Outdoor Communications. IEEE Wirel. Commun. Lett. 4(4): 357-360 (2015) - 2014
- [j51]Ahmed Iyanda Sulyman, Almuthanna Turki Nassar, Mathew K. Samimi, George R. MacCartney, Theodore S. Rappaport, Abdulhameed Alsanie:
Radio propagation path loss models for 5G cellular networks in the 28 GHZ and 38 GHZ millimeter-wave bands. IEEE Commun. Mag. 52(9): 78-86 (2014) - [j50]Shu Sun, Theodore S. Rappaport, Robert W. Heath Jr., Andrew R. Nix, Sundeep Rangan:
Mimo for millimeter-wave wireless communications: beamforming, spatial multiplexing, or both? IEEE Commun. Mag. 52(12): 110-121 (2014) - [j49]James Murdock, Theodore S. Rappaport:
Consumption Factor and Power-Efficiency Factor: A Theory for Evaluating the Energy Efficiency of Cascaded Communication Systems. IEEE J. Sel. Areas Commun. 32(2): 221-236 (2014) - [j48]Amitava Ghosh, Timothy A. Thomas, Mark Cudak, Rapeepat Ratasuk, Prakash Moorut, Frederick W. Vook, Theodore S. Rappaport, George R. MacCartney, Shu Sun, Shuai Nie:
Millimeter-Wave Enhanced Local Area Systems: A High-Data-Rate Approach for Future Wireless Networks. IEEE J. Sel. Areas Commun. 32(6): 1152-1163 (2014) - [j47]Mustafa Riza Akdeniz, Yuanpeng Liu, Mathew K. Samimi, Shu Sun, Sundeep Rangan, Theodore S. Rappaport, Elza Erkip:
Millimeter Wave Channel Modeling and Cellular Capacity Evaluation. IEEE J. Sel. Areas Commun. 32(6): 1164-1179 (2014) - [j46]Ansuman Adhikary, Ebrahim Al Safadi, Mathew K. Samimi, Rui Wang, Giuseppe Caire, Theodore S. Rappaport, Andreas F. Molisch:
Joint Spatial Division and Multiplexing for mm-Wave Channels. IEEE J. Sel. Areas Commun. 32(6): 1239-1255 (2014) - [j45]Sundeep Rangan, Theodore S. Rappaport, Elza Erkip:
Millimeter-Wave Cellular Wireless Networks: Potentials and Challenges. Proc. IEEE 102(3): 366-385 (2014) - 2013
- [j44]Theodore S. Rappaport, Shu Sun, Rimma Mayzus, Hang Zhao, Yaniv Azar, Kevin Wang, George N. Wong, Jocelyn K. Schulz, Mathew Samimi, Felix Gutierrez Jr.:
Millimeter Wave Mobile Communications for 5G Cellular: It Will Work! IEEE Access 1: 335-349 (2013) - 2011
- [j43]Theodore S. Rappaport, James Murdock, Felix Gutierrez Jr.:
State of the Art in 60-GHz Integrated Circuits and Systems for Wireless Communications. Proc. IEEE 99(8): 1390-1436 (2011) - [j42]Theodore S. Rappaport, Stefano DiPierro, Riza Akturan:
Analysis and Simulation of Interference to Vehicle-Equipped Digital Receivers From Cellular Mobile Terminals Operating in Adjacent Frequencies. IEEE Trans. Veh. Technol. 60(4): 1664-1676 (2011) - [j41]Theodore S. Rappaport, James Murdock, David G. Michelson, R. Shapiro:
An Open-Source Archiving System. IEEE Veh. Technol. Mag. 6(2): 24-32 (2011) - 2009
- [j40]Jeffrey R. Foerster, Jim Lansford, Joy Laskar, Theodore S. Rappaport, Shuzo Kato:
Realizing Gbps wireless personal area networks - guest editorial. IEEE J. Sel. Areas Commun. 27(8): 1313-1317 (2009) - [j39]Felix Gutierrez Jr., Shatam Agarwal, Kristen Parrish, Theodore S. Rappaport:
On-chip integrated antenna structures in CMOS for 60 GHz WPAN systems. IEEE J. Sel. Areas Commun. 27(8): 1367-1378 (2009) - [j38]Jeremy K. Chen, Gustavo de Veciana, Theodore S. Rappaport:
Site-Specific Knowledge and Interference Measurement for Improving Frequency Allocations in Wireless Networks. IEEE Trans. Veh. Technol. 58(5): 2366-2377 (2009) - [j37]Cheol-Hee Park, Robert W. Heath Jr., Theodore S. Rappaport:
Frequency-Domain Channel Estimation and Equalization for Continuous-Phase Modulations With Superimposed Pilot Sequences. IEEE Trans. Veh. Technol. 58(9): 4903-4908 (2009) - 2007
- [j36]Cheol-Hee Park, Theodore S. Rappaport:
Short-Range Wireless Communications for Next-Generation Networks: UWB, 60 GHz Millimeter-Wave WPAN, And ZigBee. IEEE Wirel. Commun. 14(4): 70-78 (2007) - 2006
- [j35]Chen Na, Jeremy K. Chen, Theodore S. Rappaport:
Measured Traffic Statistics and Throughput of IEEE 802.11b Public WLAN Hotspots with Three Different Applications. IEEE Trans. Wirel. Commun. 5(11): 3296-3305 (2006) - 2004
- [j34]Roger R. Skidmore, Alex Verstak, Naren Ramakrishnan, Theodore S. Rappaport, Layne T. Watson, Jian He, Srinidhi Varadarajan, Clifford A. Shaffer, Jeremy K.-P. Chen, Kyung Kyoon Bae, Jing Jiang, William H. Tranter:
Towards integrated PSEs for wireless communications: experiences with the S4W and SitePlanner® projects. ACM SIGMOBILE Mob. Comput. Commun. Rev. 8(2): 20-34 (2004) - [j33]Christopher Robert Anderson, Theodore S. Rappaport:
In-building wideband partition loss measurements at 2.5 and 60 GHz. IEEE Trans. Wirel. Commun. 3(3): 922-928 (2004) - [j32]Jian He, Alex Verstak, Layne T. Watson, C. A. Stinson, Naren Ramakrishnan, Clifford A. Shaffer, Theodore S. Rappaport, Christopher Robert Anderson, Kyung Kyoon Bae, Jing Jiang, William H. Tranter:
Globally optimal transmitter placement for indoor wireless communication systems. IEEE Trans. Wirel. Commun. 3(6): 1906-1911 (2004) - 2003
- [j31]Sanjay Shakkottai, Theodore S. Rappaport, Peter C. Karlsson:
Cross-layer design for wireless networks. IEEE Commun. Mag. 41(10): 74-80 (2003) - [j30]Alex Verstak, Naren Ramakrishnan, Layne T. Watson, Jian He, Clifford A. Shaffer, Kyung Kyoon Bae, Jing Jiang, William H. Tranter, Theodore S. Rappaport:
BSML: A binding schema markup language for data interchange in problem solving environments. Sci. Program. 11(3): 199-224 (2003) - 2002
- [j29]Theodore S. Rappaport, Annamalai Annamalai, R. Michael Buehrer, William H. Tranter:
Wireless communications: past events and a future perspective. IEEE Commun. Mag. 40(5): 148-161 (2002) - [j28]Hao Xu, Vikas Kukshya, Theodore S. Rappaport:
Spatial and temporal characteristics of 60-GHz indoor channels. IEEE J. Sel. Areas Commun. 20(3): 620-630 (2002) - [j27]Paul Petrus, Jeffrey H. Reed, Theodore S. Rappaport:
Geometrical-based statistical macrocell channel model for mobile environments. IEEE Trans. Commun. 50(3): 495-502 (2002) - [j26]Gregory D. Durgin, Theodore S. Rappaport, David A. de Wolf:
New analytical models and probability density functions for fading in wireless communications. IEEE Trans. Commun. 50(6): 1005-1015 (2002) - 2001
- [j25]Paulo Cardieri, Theodore S. Rappaport:
Application of narrow-beam antennas and fractional loading factor in cellular communication systems. IEEE Trans. Veh. Technol. 50(2): 430-440 (2001) - [j24]Paulo Cardieri, Theodore S. Rappaport:
Statistical analysis of co-channel interference in wireless communications systems. Wirel. Commun. Mob. Comput. 1(1): 111-121 (2001) - 2000
- [j23]Hao Xu, Theodore S. Rappaport, Robert J. Boyle, James H. Schaffner:
38-GHz wide-band point-to-multipoint measurements under different weather conditions. IEEE Commun. Lett. 4(1): 7-8 (2000) - [j22]Hao Xu, Theodore S. Rappaport, Robert J. Boyle, James H. Schaffner:
Measurements and models for 38-GHz point-to-multipoint radiowave propagation. IEEE J. Sel. Areas Commun. 18(3): 310-321 (2000) - 1998
- [j21]Jeffrey H. Reed, Kevin J. Krizman, Brian D. Woerner, Theodore S. Rappaport:
An overview of the challenges and progress in meeting the E-911 requirement for location service. IEEE Commun. Mag. 36(4): 30-37 (1998) - [j20]Gregory D. Durgin, Theodore S. Rappaport, Hao Xu:
5.85-GHz radio path loss and penetration loss measurements in and around homes and trees. IEEE Commun. Lett. 2(3): 70-72 (1998) - [j19]Gregory D. Durgin, Theodore S. Rappaport, Hao Xu:
Measurements and models for radio path loss and penetration loss in and around homes and trees at 5.85 GHz. IEEE Trans. Commun. 46(11): 1484-1496 (1998) - [j18]Richard Brian Ertel, Paulo Cardieri, Kevin W. Sowerby, Theodore S. Rappaport, Jeffrey H. Reed:
Overview of spatial channel models for antenna array communication systems. IEEE Wirel. Commun. 5(1): 10-22 (1998) - 1997
- [j17]Paul Petrus, Jeffrey H. Reed, Theodore S. Rappaport:
Effects of directional antennas at the base station on the Doppler spectrum. IEEE Commun. Lett. 1(2): 40-42 (1997) - [j16]Zhigang Rong, Paul Petrus, Theodore S. Rappaport, Jeffrey H. Reed:
Despread-respread multi-target constant modulus array for CDMA systems. IEEE Commun. Lett. 1(4): 114-116 (1997) - [j15]Theodore S. Rappaport, Robert A. Brickhouse:
A simulation study of urban in-building cellular frequency reuse. IEEE Wirel. Commun. 4(1): 19-23 (1997) - 1996
- [j14]Theodore S. Rappaport, Jeffrey H. Reed, Brian D. Woerner:
Position location using wireless communications on highways of the future. IEEE Commun. Mag. 34(10): 33-41 (1996) - [j13]Manish A. Panjwani, A. Lynn Abbott, Theodore S. Rappaport:
Interactive Computation of Coverage Regions for Wireless Communication in Multifloored Indoor Environments. IEEE J. Sel. Areas Commun. 14(3): 420-430 (1996) - [j12]Hanif D. Sherali, Chandra Mohan Pendyala, Theodore S. Rappaport:
Optimal location of transmitters for micro-cellular radio communication system design. IEEE J. Sel. Areas Commun. 14(4): 662-673 (1996) - 1995
- [j11]Jørgen Bach Andersen, Theodore S. Rappaport, Susumu Yoshida:
Propagation measurements and models for wireless communications channels. IEEE Commun. Mag. 33(1): 42-49 (1995) - 1994
- [j10]Brian D. Woerner, Jeffrey H. Reed, Theodore S. Rappaport:
Simulation issues for future wireless modems. IEEE Commun. Mag. 32(7): 42-53 (1994) - [j9]C. M. Peter Ho, Theodore S. Rappaport, M. Prabhakar Koushik:
Antenna effects on indoor obstructed wireless channels and a deterministic image-based wide-band propagation model for in-building personal communication systems. Int. J. Wirel. Inf. Networks 1(1): 61-76 (1994) - 1993
- [j8]Victor Fung, Theodore S. Rappaport, Berthold Thoma:
Bit Error Simulation for pi/4 DQPSK Mobile Radio Communications using Two-Ray and Measurement-Based Impulse Response Models. IEEE J. Sel. Areas Commun. 11(3): 393-405 (1993) - [j7]Kenneth L. Blackard, Theodore S. Rappaport, Charles W. Bostian:
Measurements and Models of Radio Frequency Impulsive Noise for Indoor Wireless Communications. IEEE J. Sel. Areas Commun. 11(7): 991-1001 (1993) - 1992
- [j6]Laurence B. Milstein, Theodore S. Rappaport, Rashad Barghouti:
Performance Evaluation for Cellular CDMA. IEEE J. Sel. Areas Commun. 10(4): 680-689 (1992) - [j5]Theodore S. Rappaport, Dwayne A. Hawbaker:
Wide-band microwave propagation parameters using circular and linear polarized antennas for indoor wireless channels. IEEE Trans. Commun. 40(2): 240-245 (1992) - 1991
- [j4]Theodore S. Rappaport:
The wireless revolution. IEEE Commun. Mag. 29(11): 52 (1991) - [j3]Theodore S. Rappaport, Scott Y. Seidel, Koichiro Takamizawa:
Statistical channel impulse response models for factory and open plan building radio communicate system design. IEEE Trans. Commun. 39(5): 794-807 (1991) - 1989
- [j2]Theodore S. Rappaport:
Indoor radio communications for factories of the future. IEEE Commun. Mag. 27(5): 15-24 (1989) - [j1]Theodore S. Rappaport, Clare D. McGillem:
UHF fading in factories. IEEE J. Sel. Areas Commun. 7(1): 40-48 (1989)
Conference and Workshop Papers
- 2024
- [c99]Hitesh Poddar, Akhileswar Chowdary, Theodore S. Rappaport, Marwa Chafii:
Full-Stack End-To-End Sub-THz Simulations at 140 GHz using NYUSIM Channel Model in ns-3. WCNC 2024: 1-6 - 2023
- [c98]Dipankar Shakya, Hitesh Poddar, Theodore S. Rappaport:
A Sub-Terahertz Sliding Correlator Channel Sounder with Absolute Timing using Precision Time Protocol over Wi-Fi. GLOBECOM 2023: 5793-5798 - [c97]Mingjun Ying, Dipankar Shakya, Hitesh Poddar, Theodore S. Rappaport:
Waste Factor: A New Metric for Evaluating Power Efficiency in any Cascade. GLOBECOM 2023: 6735-6740 - [c96]Hitesh Poddar, Tomoki Yoshimura, Matteo Pagin, Theodore S. Rappaport, Art Ishii, Michele Zorzi:
Full-Stack End-to-End mmWave Simulations Using 3GPP and NYUSIM Channel Model in ns-3. ICC 2023: 1048-1053 - [c95]Shihao Ju, Theodore S. Rappaport:
142 GHz Multipath Propagation Measurements and Path Loss Channel Modeling in Factory Buildings. ICC 2023: 5048-5053 - [c94]Ojas Kanhere, Theodore S. Rappaport:
Calibration of NYURay, a 3D mmWave and Sub-THz Ray Tracer Using Indoor, Outdoor, and Factory Channel Measurements. ICC 2023: 5054-5059 - [c93]Hitesh Poddar, Tomoki Yoshimura, Matteo Pagin, Theodore S. Rappaport, Art Ishii, Michele Zorzi:
ns-3 Implementation of Sub-Terahertz and Millimeter Wave Drop-based NYU Channel Model (NYUSIM). WNS3 2023: 19-27 - 2022
- [c92]Dipankar Shakya, Dmitry Chizhik, Jinfeng Du, Reinaldo A. Valenzuela, Theodore S. Rappaport:
Dense Urban Outdoor-Indoor Coverage from 3.5 to 28 GHz. ICC 2022: 932-937 - [c91]Shihao Ju, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
Sub-Terahertz Channel Measurements and Characterization in a Factory Building. ICC 2022: 2882-2887 - [c90]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport:
Sub-Terahertz Wireless Coverage Analysis at 142 GHz in Urban Microcell. ICC 2022: 3942-3947 - [c89]Aditya Chopra, Andrew Thornburg, Ojas Kanhere, Saeed S. Ghassemzadeh, Milap Majmundar, Theodore S. Rappaport:
A Real-Time Millimeter Wave V2V Channel Sounder. WCNC 2022: 2607-2612 - 2021
- [c88]Shihao Ju, Theodore S. Rappaport:
Sub-Terahertz Spatial Statistical MIMO Channel Model for Urban Microcells at 142 GHz. GLOBECOM 2021: 1-6 - [c87]Shihao Ju, Theodore S. Rappaport:
140 GHz Urban Microcell Propagation Measurements for Spatial Consistency Modeling. ICC 2021: 1-6 - [c86]Ojas Kanhere, Theodore S. Rappaport:
Outdoor sub-THz Position Location and Tracking using Field Measurements at 142 GHz. ICC 2021: 1-6 - [c85]Yunchou Xing, Theodore S. Rappaport:
Propagation Measurements and Path Loss Models for sub-THz in Urban Microcells. ICC 2021: 1-6 - [c84]Ojas Kanhere, Aditya Chopra, Andrew Thornburg, Theodore S. Rappaport, Saeed S. Ghassemzadeh:
Performance Impact Analysis of Beam Switching in Millimeter Wave Vehicular Communications. VTC Spring 2021: 1-7 - [c83]Ojas Kanhere, Sanjay Goyal, Mihaela C. Beluri, Theodore S. Rappaport:
Target Localization using Bistatic and Multistatic Radar with 5G NR Waveform. VTC Spring 2021: 1-7 - [c82]Yunchou Xing, Frank Hsieh, Amitava Ghosh, Theodore S. Rappaport:
High Altitude Platform Stations (HAPS): Architecture and System Performance. VTC Spring 2021: 1-6 - 2020
- [c81]Aditya Chopra, Andrew Thornburg, Ojas Kanhere, Abbas Termos, Saeed S. Ghassemzadeh, Theodore S. Rappaport:
Real-time Millimeter Wave Omnidirectional Channel Sounder Using Phased Array Antennas. GLOBECOM 2020: 1-7 - [c80]Shihao Ju, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
3-D Statistical Indoor Channel Model for Millimeter-Wave and Sub-Terahertz Bands. GLOBECOM 2020: 1-7 - [c79]Ojas Kanhere, Theodore S. Rappaport:
Millimeter Wave Position Location using Multipath Differentiation for 3GPP using Field Measurements. GLOBECOM 2020: 1-7 - [c78]Dipankar Shakya, Ting Wu, Theodore S. Rappaport:
A Wideband Sliding Correlator based Channel Sounder in 65 nm CMOS: An Evaluation Board Design. GLOBECOM 2020: 1-6 - 2019
- [c77]Shihao Ju, Ojas Kanhere, Yunchou Xing, Theodore S. Rappaport:
A Millimeter-Wave Channel Simulator NYUSIM with Spatial Consistency and Human Blockage. GLOBECOM 2019: 1-6 - [c76]Ojas Kanhere, Shihao Ju, Yunchou Xing, Theodore S. Rappaport:
Map-Assisted Millimeter Wave Localization for Accurate Position Location. GLOBECOM 2019: 1-6 - [c75]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport:
Indoor Wireless Channel Properties at Millimeter Wave and Sub-Terahertz Frequencies. GLOBECOM 2019: 1-6 - [c74]Shihao Ju, Syed Hashim Ali Shah, Muhammad Affan Javed, Jun Li, Girish Palteru, Jyotish Robin, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
Scattering Mechanisms and Modeling for Terahertz Wireless Communications. ICC 2019: 1-7 - [c73]Ting Wu, Theodore S. Rappaport, Michael E. Knox, Davood Shahrjerdi:
A Wideband Sliding Correlator-Based Channel Sounder with Synchronization in 65 nm CMOS. ISCAS 2019: 1-5 - 2018
- [c72]Shihao Ju, Theodore S. Rappaport:
Millimeter-Wave Extended NYUSIM Channel Model for Spatial Consistency. GLOBECOM 2018: 1-6 - [c71]Yunchou Xing, Theodore S. Rappaport:
Propagation Measurement System and Approach at 140 GHz-Moving to 6G and Above 100 GHz. GLOBECOM 2018: 1-6 - [c70]Ojas Kanhere, Theodore S. Rappaport:
Position Locationing for Millimeter Wave Systems. GLOBECOM 2018: 206-212 - [c69]Shu Sun, Theodore S. Rappaport, Mansoor Shafi:
Hybrid beamforming for 5G millimeter-wave multi-cell networks. INFOCOM Workshops 2018: 589-596 - [c68]Shihao Ju, Theodore S. Rappaport:
Simulating Motion - Incorporating Spatial Consistency into NYUSIM Channel Model. VTC Fall 2018: 1-6 - [c67]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport, George R. MacCartney:
Verification and Calibration of Antenna Cross-Polarization Discrimination and Penetration Loss for Millimeter Wave Communications. VTC Fall 2018: 1-6 - 2017
- [c66]George R. MacCartney, Theodore S. Rappaport, Amitava Ghosh:
Base Station Diversity Propagation Measurements at 73 GHz Millimeter-Wave for 5G Coordinated Multipoint (CoMP) Analysis. GLOBECOM Workshops 2017: 1-7 - [c65]George R. MacCartney, Theodore S. Rappaport, Sundeep Rangan:
Rapid Fading Due to Human Blockage in Pedestrian Crowds at 5G Millimeter-Wave Frequencies. GLOBECOM 2017: 1-7 - [c64]George R. MacCartney, Theodore S. Rappaport:
Study on 3GPP rural macrocell path loss models for millimeter wave wireless communications. ICC 2017: 1-7 - [c63]George R. MacCartney, Hangsong Yan, Shu Sun, Theodore S. Rappaport:
A flexible wideband millimeter-wave channel sounder with local area and NLOS to LOS transition measurements. ICC 2017: 1-7 - [c62]Shu Sun, George R. MacCartney, Theodore S. Rappaport:
A novel millimeter-wave channel simulator and applications for 5G wireless communications. ICC 2017: 1-7 - [c61]Shu Sun, Hangsong Yan, George R. MacCartney, Theodore S. Rappaport:
Millimeter wave small-scale spatial statistics in an urban microcell scenario. ICC 2017: 1-7 - [c60]Shu Sun, Theodore S. Rappaport:
Millimeter Wave MIMO channel estimation based on adaptive compressed sensing. ICC Workshops 2017: 47-53 - [c59]Jacqueline Ryan, George R. MacCartney, Theodore S. Rappaport:
Indoor office wideband penetration loss measurements at 73 GHz. ICC Workshops 2017: 228-233 - [c58]Yu Wang, Shiwen Mao, Theodore S. Rappaport:
On Directional Neighbor Discovery in mmWave Networks. ICDCS 2017: 1704-1713 - [c57]Theodore S. Rappaport, Shu Sun, Mansoor Shafi:
Investigation and Comparison of 3GPP and NYUSIM Channel Models for 5G Wireless Communications. VTC Fall 2017: 1-5 - 2016
- [c56]Sijia Deng, George R. MacCartney, Theodore S. Rappaport:
Indoor and Outdoor 5G Diffraction Measurements and Models at 10, 20, and 26 GHz. GLOBECOM 2016: 1-7 - [c55]Katsuyuki Haneda, Lei Tian, Henrik Asplund, Jian Li, Yi Wang, David Steer, Clara Li, Tommaso Balercia, Sunguk Lee, YoungSuk Kim, Amitava Ghosh, Timothy A. Thomas, Takehiro Nakamura, Yuichi Kakishima, Tetsuro Imai, Haralabos C. Papadopoulos, Theodore S. Rappaport, George R. MacCartney, Mathew K. Samimi, Shu Sun, Ozge H. Koymen, Sooyoung Hur, Jeongho Park, Jianzhong Zhang, Evangelos Mellios, Andreas F. Molisch, Saeed S. Ghassamzadeh, Arun Ghosh:
Indoor 5G 3GPP-like channel models for office and shopping mall environments. ICC Workshops 2016: 694-699 - [c54]George R. MacCartney Jr., Shu Sun, Theodore S. Rappaport, Yunchou Xing, Hangsong Yan, Jeton Koka, Ruichen Wang, Dian Yu:
Millimeter wave wireless communications: new results for rural connectivity. ATC@MobiCom 2016: 31-36 - [c53]Katsuyuki Haneda, Lei Tan, Yi Zheng, Henrik Asplund, Jian Li, Yi Wang, David Steer, Clara Li, Tommaso Balercia, Sunguk Lee, YoungSuk Kim, Amitava Ghosh, Timothy A. Thomas, Takehiro Nakamura, Yuichi Kakishima, Tetsuro Imai, Haralabos C. Papadopoulos, Theodore S. Rappaport, George R. MacCartney, Mathew K. Samimi, Shu Sun, Ozge H. Koymen, Sooyoung Hur, Jeongho Park, Jianzhong Charlie Zhang, Evangelos Mellios, Andreas F. Molisch, Saeed S. Ghassamzadeh, Arun Ghosh:
5G 3GPP-Like Channel Models for Outdoor Urban Microcellular and Macrocellular Environments. VTC Spring 2016: 1-7 - [c52]George R. MacCartney, Sijia Deng, Theodore S. Rappaport:
Indoor Office Plan Environment and Layout-Based mmWave Path Loss Models for 28 GHz and 73 GHz. VTC Spring 2016: 1-6 - [c51]George R. MacCartney, Sijia Deng, Shu Sun, Theodore S. Rappaport:
Millimeter-Wave Human Blockage at 73 GHz with a Simple Double Knife-Edge Diffraction Model and Extension for Directional Antennas. VTC Fall 2016: 1-6 - [c50]Mathew K. Samimi, George R. MacCartney, Shu Sun, Theodore S. Rappaport:
28 GHz Millimeter-Wave Ultrawideband Small-Scale Fading Models in Wireless Channels. VTC Spring 2016: 1-6 - [c49]Shu Sun, Theodore S. Rappaport, Sundeep Rangan, Timothy A. Thomas, Amitava Ghosh, István Z. Kovács, Ignacio Rodriguez, Ozge H. Koymen, Andrzej Partyka, Jan Jarvelainen:
Propagation Path Loss Models for 5G Urban Micro- and Macro-Cellular Scenarios. VTC Spring 2016: 1-6 - [c48]Timothy A. Thomas, Marcin Rybakowski, Shu Sun, Theodore S. Rappaport, Huan Nguyen, István Z. Kovács, Ignacio Rodriguez:
A Prediction Study of Path Loss Models from 2-73.5 GHz in an Urban-Macro Environment. VTC Spring 2016: 1-5 - 2015
- [c47]Mathew K. Samimi, Theodore S. Rappaport:
Statistical Channel Model with Multi-Frequency and Arbitrary Antenna Beamwidth for Millimeter-Wave Outdoor Communications. GLOBECOM Workshops 2015: 1-7 - [c46]Shu Sun, George R. MacCartney, Mathew K. Samimi, Theodore S. Rappaport:
Synthesizing Omnidirectional Antenna Patterns, Received Power and Path Loss from Directional Antennas for 5G Millimeter-Wave Communications. GLOBECOM 2015: 1-7 - [c45]Shu Sun, Timothy A. Thomas, Theodore S. Rappaport, Huan Nguyen, István Z. Kovács, Ignacio Rodriguez:
Path Loss, Shadow Fading, and Line-of-Sight Probability Models for 5G Urban Macro-Cellular Scenarios. GLOBECOM Workshops 2015: 1-7 - [c44]Theodore S. Rappaport, Sijia Deng:
73 GHz wideband millimeter-wave foliage and ground reflection measurements and models. ICC Workshops 2015: 1238-1243 - [c43]Sijia Deng, Mathew K. Samimi, Theodore S. Rappaport:
28 GHz and 73 GHz millimeter-wave indoor propagation measurements and path loss models. ICC Workshops 2015: 1244-1250 - [c42]George R. MacCartney, Mathew K. Samimi, Theodore S. Rappaport:
Exploiting directionality for millimeter-wave wireless system improvement. ICC 2015: 2416-2422 - [c41]Ting Wu, Theodore S. Rappaport, Christopher M. Collins:
The human body and millimeter-wave wireless communication systems: Interactions and implications. ICC 2015: 2423-2429 - [c40]Mathew K. Samimi, Theodore S. Rappaport:
3-D statistical channel model for millimeter-wave outdoor mobile broadband communications. ICC 2015: 2430-2436 - [c39]Shu Sun, Theodore S. Rappaport, Timothy A. Thomas, Amitava Ghosh:
A preliminary 3D mm wave indoor office channel model. ICNC 2015: 26-31 - [c38]Qian (Clara) Li, Hooman Shirani-Mehr, Tommaso Balercia, Apostolos Papathanassiou, Geng Wu, Shu Sun, Mathew K. Samimi, Theodore S. Rappaport:
Validation of a Geometry-Based Statistical mmWave Channel Model Using Ray-Tracing Simulation. VTC Spring 2015: 1-5 - [c37]Zhifeng He, Shiwen Mao, Theodore Ted S. Rappaport:
Minimum time length link scheduling under blockage and interference in 60GHz networks. WCNC 2015: 837-842 - 2014
- [c36]Qian (Clara) Li, Geng Wu, Theodore S. Rappaport:
Channel model for millimeter-wave communications based on geometry statistics. GLOBECOM Workshops 2014: 427-432 - [c35]Mathew K. Samimi, Theodore S. Rappaport:
Ultra-wideband statistical channel model for non line of sight millimeter-wave urban channels. GLOBECOM 2014: 3483-3489 - [c34]Shuai Nie, George R. MacCartney, Shu Sun, Theodore S. Rappaport:
28 GHz and 73 GHz signal outage study for millimeter wave cellular and backhaul communications. ICC 2014: 4856-4861 - [c33]George R. MacCartney, Theodore S. Rappaport:
73 GHz millimeter wave propagation measurements for outdoor urban mobile and backhaul communications in New York City. ICC 2014: 4862-4867 - [c32]Shu Sun, George R. MacCartney, Mathew K. Samimi, Shuai Nie, Theodore S. Rappaport:
Millimeter wave multi-beam antenna combining for 5G cellular link improvement in New York City. ICC 2014: 5468-5473 - [c31]George R. MacCartney, Mathew K. Samimi, Theodore S. Rappaport:
Omnidirectional path loss models in New York City at 28 GHz and 73 GHz. PIMRC 2014: 227-231 - [c30]Huan Cong Nguyen, George R. MacCartney, Timothy A. Thomas, Theodore S. Rappaport, Benny Vejlgaard, Preben E. Mogensen:
Evaluation of Empirical Ray-Tracing Model for an Urban Outdoor Scenario at 73 GHz E-Band. VTC Fall 2014: 1-6 - [c29]Timothy A. Thomas, Huan Cong Nguyen, George R. MacCartney, Theodore S. Rappaport:
3D mmWave Channel Model Proposal. VTC Fall 2014: 1-6 - 2013
- [c28]Shu Sun, Theodore S. Rappaport:
Multi-beam antenna combining for 28 GHz cellular link improvement in urban environments. GLOBECOM 2013: 3754-3759 - [c27]George R. MacCartney, Junhong Zhang, Shuai Nie, Theodore S. Rappaport:
Path loss models for 5G millimeter wave propagation channels in urban microcells. GLOBECOM 2013: 3948-3953 - [c26]Yaniv Azar, George N. Wong, Kevin Wang, Rimma Mayzus, Jocelyn K. Schulz, Hang Zhao, Felix Gutierrez Jr., DuckDong Hwang, Theodore S. Rappaport:
28 GHz propagation measurements for outdoor cellular communications using steerable beam antennas in New York city. ICC 2013: 5143-5147 - [c25]Hang Zhao, Rimma Mayzus, Shu Sun, Mathew Samimi, Jocelyn K. Schulz, Yaniv Azar, Kevin Wang, George N. Wong, Felix Gutierrez Jr., Theodore S. Rappaport:
28 GHz millimeter wave cellular communication measurements for reflection and penetration loss in and around buildings in New York city. ICC 2013: 5163-5167 - [c24]Shuai Nie, George R. MacCartney, Shu Sun, Theodore S. Rappaport:
72 GHz millimeter wave indoor measurements for wireless and backhaul communications. PIMRC 2013: 2429-2433 - [c23]Mathew Samimi, Kevin Wang, Yaniv Azar, George N. Wong, Rimma Mayzus, Hang Zhao, Jocelyn K. Schulz, Shu Sun, Felix Gutierrez Jr., Theodore S. Rappaport:
28 GHz Angle of Arrival and Angle of Departure Analysis for Outdoor Cellular Communications Using Steerable Beam Antennas in New York City. VTC Spring 2013: 1-6 - 2012
- [c22]Theodore S. Rappaport, James Murdock:
Power efficiency and consumption factor analysis for broadband millimeter-wave cellular networks. GLOBECOM 2012: 4518-4523 - [c21]Jonathan I. Tamir, Theodore S. Rappaport, Yonina C. Eldar, Ahsan Aziz:
Analog compressed sensing for RF propagation channel sounding. ICASSP 2012: 5317-5320 - [c20]Theodore S. Rappaport, Eshar Ben-Dor, James Murdock, Yijun Qiao:
38 GHz and 60 GHz angle-dependent propagation for cellular & peer-to-peer wireless communications. ICC 2012: 4568-4573 - [c19]Theodore S. Rappaport, Yijun Qiao, Jonathan I. Tamir, James Murdock, Eshar Ben-Dor:
Cellular broadband millimeter wave propagation and angle of arrival for adaptive beam steering systems (invited paper). RWS 2012: 151-154 - [c18]James Murdock, Eshar Ben-Dor, Yijun Qiao, Jonathan I. Tamir, Theodore S. Rappaport:
A 38 GHz cellular outage study for an urban outdoor campus environment. WCNC 2012: 3085-3090 - 2011
- [c17]Eshar Ben-Dor, Theodore S. Rappaport, Yijun Qiao, Samuel J. Lauffenburger:
Millimeter-Wave 60 GHz Outdoor and Vehicle AOA Propagation Measurements Using a Broadband Channel Sounder. GLOBECOM 2011: 1-6 - [c16]James Murdock, Theodore S. Rappaport:
Consumption factor: A figure of merit for power consumption and energy efficiency in broadband wireless communications. GLOBECOM Workshops 2011: 1393-1398 - [c15]Vinodh K. Rajendran, James Murdock, Adrian Duran, Theodore S. Rappaport:
Concepts and Implementation of a Semantic Web Archiving and Simulation System for RF Propagation Measurements. VTC Fall 2011: 1-5 - 2010
- [c14]Khursheed Hassan, Theodore S. Rappaport, Jeffrey G. Andrews:
Analog Equalization for Low Power 60 GHz Receivers in Realistic Multipath Channels. GLOBECOM 2010: 1-5 - [c13]Felix Gutierrez Jr., Theodore S. Rappaport, James Murdock:
Millimeter-Wave CMOS Antennas and RFIC Parameter Extraction for Vehicular Applications. VTC Fall 2010: 1-6 - [c12]Theodore S. Rappaport, Stefano DiPierro, Riza Akturan:
Analysis and Simulation of Adjacent Service Interference to Vehicle-Equipped Digital Wireless Receivers from Cellular Mobile Terminals. VTC Fall 2010: 1-5 - 2009
- [c11]Felix Gutierrez Jr., Kristen Parrish, Theodore S. Rappaport:
On-Chip Integrated Antenna Structures in CMOS for 60 GHz WPAN Systems. GLOBECOM 2009: 1-7 - 2007
- [c10]Jeremy K. Chen, Gustavo de Veciana, Theodore S. Rappaport:
Improved Measurement-Based Frequency Allocation Algorithms for Wireless Networks. GLOBECOM 2007: 4790-4795 - [c9]Jeremy K.-P. Chen, Theodore S. Rappaport, Gustavo de Veciana:
Site Specific Knowledge for Improving Frequency Allocations in Wireless LAN and Cellular Networks. VTC Fall 2007: 1431-1435 - [c8]Lawrence H. Ragan, Arjang Hassibi, Theodore S. Rappaport, Craig L. Christianson:
Novel On-Chip Antenna Structures and Frequency Selective Surface (FSS) Approaches for Millimeter Wave Devices. VTC Fall 2007: 2051-2055 - 2006
- [c7]Jeremy K.-P. Chen, Theodore S. Rappaport, Gustavo de Veciana:
Iterative Water-filling for Load-balancing in Wireless LAN or Microcellular Networks. VTC Spring 2006: 117-121 - 2004
- [c6]Ajay Mahimkar, Theodore S. Rappaport:
SecureDAV: a secure data aggregation and verification protocol for sensor networks. GLOBECOM 2004: 2175-2179 - [c5]Chen Na, Jeremy K. Chen, Theodore S. Rappaport:
Hotspot traffic statistics and throughput models for several applications. GLOBECOM 2004: 3257-3263 - [c4]Taeyoon Kim, Jaeweon Kim, Jeffrey G. Andrews, Theodore S. Rappaport:
Multi-code multicarrier CDMA: performance analysis. ICC 2004: 973-977 - 2002
- [c3]Alex Verstak, Jian He, Layne T. Watson, Naren Ramakrishnan, Clifford A. Shaffer, Theodore S. Rappaport, Christopher Robert Anderson, Kyung Kyoon Bae, Jing Jiang, William H. Tranter:
S4W: Globally Optimized Design of Wireless Communications Systems. IPDPS 2002 - 2001
- [c2]Paulo Cardieri, Theodore S. Rappaport:
Channel allocation in SDMA cellular systems. VTC Fall 2001: 399-403 - 1988
- [c1]Clare D. McGillem, Theodore S. Rappaport:
Infra-red location system for navigation of autonomous vehicles. ICRA 1988: 1236-1238
Informal and Other Publications
- 2024
- [i79]Mingjun Ying, Dipankar Shakya, Theodore S. Rappaport:
Using Waste Factor to Optimize Energy Efficiency in Multiple-Input Single-Output (MISO) and Multiple-Input Multiple-Output (MIMO) Systems. CoRR abs/2405.01352 (2024) - [i78]Theodore S. Rappaport, Mingjun Ying, Nicola Piovesan, Antonio De Domenico, Dipankar Shakya:
Waste Factor and Waste Figure: A Unified Theory for Modeling and Analyzing Wasted Power in Radio Access Networks for Improved Sustainability. CoRR abs/2405.07710 (2024) - [i77]Josep Miquel Jornet, Vitaly Petrov, Hua Wang, Zoya Popovic, Dipankar Shakya, Jose V. Siles, Theodore S. Rappaport:
The Evolution of Applications, Hardware Design, and Channel Modeling for Terahertz (THz) Band Communications and Sensing: Ready for 6G? CoRR abs/2406.06105 (2024) - [i76]Dipankar Shakya, Mingjun Ying, Theodore S. Rappaport:
Angular Spread Statistics for 6.75 GHz FR1(C) and 16.95 GHz FR3 Mid-Band Frequencies in an Indoor Hotspot Environment. CoRR abs/2409.03013 (2024) - 2023
- [i75]Shihao Ju, Theodore S. Rappaport:
142 GHz Multipath Propagation Measurements and Path Loss Channel Modeling in Factory Buildings. CoRR abs/2302.12142 (2023) - [i74]Ojas Kanhere, Theodore S. Rappaport:
Calibration of NYURay, a 3D mmWave and sub-THz Ray Tracer using Indoor, Outdoor, and Factory Channel Measurements. CoRR abs/2302.12380 (2023) - [i73]Hitesh Poddar, Tomoki Yoshimura, Matteo Pagin, Theodore S. Rappaport, Art Ishii, Michele Zorzi:
Full-Stack End-To-End mmWave Simulations Using 3GPP and NYUSIM Channel Model in ns-3. CoRR abs/2302.12385 (2023) - [i72]Hitesh Poddar, Tomoki Yoshimura, Matteo Pagin, Theodore S. Rappaport, Art Ishii, Michele Zorzi:
ns-3 Implementation of Sub-Terahertz and Millimeter Wave Drop-based NYU Channel Model (NYUSIM). CoRR abs/2305.01828 (2023) - [i71]Hitesh Poddar, Akhileswar Chowdary, Theodore S. Rappaport, Marwa Chafii:
Full-Stack End-to-End Sub-THz Simulations at 140 GHz using NYUSIM Channel Model in ns-3. CoRR abs/2312.15987 (2023) - 2022
- [i70]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport:
Sub-Terahertz Wireless Coverage Analysis at 142 GHz in Urban Microcell. CoRR abs/2203.09029 (2022) - [i69]Aditya Chopra, Andrew Thornburg, Ojas Kanhere, Saeed S. Ghassemzadeh, Milap Majmundar, Theodore S. Rappaport:
A Real-Time Millimeter Wave V2V Channel Sounder. CoRR abs/2203.09057 (2022) - [i68]Arjuna Madanayake, Renato J. Cintra, Najath Akram, Viduneth Ariyarathna, Soumyajit Mandal, Vítor de A. Coutinho, Fábio M. Bayer, Diego F. G. Coelho, Theodore S. Rappaport:
Fast Radix-32 Approximate DFTs for 1024-Beam Digital RF Beamforming. CoRR abs/2207.05866 (2022) - [i67]Arjuna Madanayake, Viduneth Ariyarathna, Suresh Madishetty, Sravan Kumar Pulipati, Renato J. Cintra, Diego F. G. Coelho, Raíza Oliveira, Fábio M. Bayer, Leonid Belostotski, Soumyajit Mandal, Theodore S. Rappaport:
Towards a Low-SWaP 1024-beam Digital Array: A 32-beam Sub-system at 5.8 GHz. CoRR abs/2207.09054 (2022) - [i66]Ojas Kanhere, Hitesh Poddar, Yunchou Xing, Dipankar Shakya, Shihao Ju, Theodore S. Rappaport:
A Power Efficiency Metric for Comparing Energy Consumption in Future Wireless Networks in the Millimeter Wave and Terahertz bands. CoRR abs/2209.04627 (2022) - 2021
- [i65]Ojas Kanhere, Theodore S. Rappaport:
Position Location for Futuristic Cellular Communications - 5G and Beyond. CoRR abs/2102.12074 (2021) - [i64]Yunchou Xing, Theodore S. Rappaport, Amitava Ghosh:
Millimeter Wave and sub-THz Indoor Radio Propagation Channel Measurements, Models, and Comparisons in an Office Environment. CoRR abs/2103.00385 (2021) - [i63]Yunchou Xing, Theodore S. Rappaport:
Terahertz Wireless Communications: Research Issues and Challenges for Active and Passive Systems in Space and on the Ground above 100 GHz. CoRR abs/2103.00604 (2021) - [i62]Yunchou Xing, Theodore S. Rappaport:
Propagation Measurements and Path Loss Models for sub-THz in Urban Microcells. CoRR abs/2103.01151 (2021) - [i61]Ojas Kanhere, Sanjay Goyal, Mihaela C. Beluri, Theodore S. Rappaport:
Target Localization using Bistatic and Multistatic Radar with 5G NR Waveform. CoRR abs/2103.03426 (2021) - [i60]Yunchou Xing, Frank Hsieh, Amitava Ghosh, Theodore S. Rappaport:
High Altitude Platform Stations (HAPS): Architecture and System Performance. CoRR abs/2103.03431 (2021) - [i59]Ojas Kanhere, Aditya Chopra, Andrew Thornburg, Theodore S. Rappaport, Saeed S. Ghassemzadeh:
Performance Impact Analysis of Beam Switching in Millimeter Wave Vehicular Communications. CoRR abs/2103.03434 (2021) - [i58]Ojas Kanhere, Theodore S. Rappaport:
Outdoor sub-THz Position Location and Tracking using Field Measurements at 142 GHz. CoRR abs/2103.05219 (2021) - [i57]Shihao Ju, Theodore S. Rappaport:
140 GHz Urban Microcell Propagation Measurements for Spatial Consistency Modeling. CoRR abs/2103.05496 (2021) - [i56]Shihao Ju, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
Millimeter Wave and Sub-Terahertz Spatial Statistical Channel Model for an Indoor Office Building. CoRR abs/2103.17127 (2021) - [i55]Dipankar Shakya, Ting Wu, Michael E. Knox, Theodore S. Rappaport:
A Wideband Sliding Correlation Channel Sounder in 65 nm CMOS: Evaluation Board Performance. CoRR abs/2106.06855 (2021) - [i54]Yunchou Xing, Theodore S. Rappaport:
Millimeter Wave and Terahertz Urban Microcell Propagation Measurements and Models. CoRR abs/2109.13404 (2021) - [i53]Shihao Ju, Theodore S. Rappaport:
Sub-Terahertz Spatial Statistical MIMO Channel Model for Urban Microcells at 142 GHz. CoRR abs/2110.06361 (2021) - 2020
- [i52]Ojas Kanhere, Theodore S. Rappaport:
Millimeter Wave Position Location using Multipath Differentiation for 3GPP using Field Measurements. CoRR abs/2009.10202 (2020) - [i51]Aditya Chopra, Andrew Thornburg, Ojas Kanhere, Abbas Termos, Saeed S. Ghassemzadeh, Theodore S. Rappaport:
Real-time Millimeter Wave Omnidirectional Channel Sounder Using Phased Array Antennas. CoRR abs/2009.11093 (2020) - [i50]Shihao Ju, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
3-D Statistical Indoor Channel Model for Millimeter-Wave and Sub-Terahertz Bands. CoRR abs/2009.12971 (2020) - 2019
- [i49]Shihao Ju, Syed Hashim Ali Shah, Muhammad Affan Javed, Jun Li, Girish Palteru, Jyotish Robin, Yunchou Xing, Ojas Kanhere, Theodore S. Rappaport:
Scattering Mechanisms and Modeling for Terahertz Wireless Communications. CoRR abs/1903.02657 (2019) - [i48]Shihao Ju, Ojas Kanhere, Yunchou Xing, Theodore S. Rappaport:
A Millimeter-Wave Channel Simulator NYUSIM with Spatial Consistency and Human Blockage. CoRR abs/1908.09762 (2019) - [i47]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport:
Indoor Wireless Channel Properties at Millimeter Wave and Sub-Terahertz Frequencies. CoRR abs/1908.09765 (2019) - [i46]Ojas Kanhere, Shihao Ju, Yunchou Xing, Theodore S. Rappaport:
Map-Assisted Millimeter Wave Localization for Accurate Position Location. CoRR abs/1908.09773 (2019) - 2018
- [i45]Shu Sun, Theodore S. Rappaport, Mansoor Shafi:
Hybrid Beamforming for 5G Millimeter-Wave Multi-Cell Networks. CoRR abs/1803.03986 (2018) - [i44]Yunchou Xing, Ojas Kanhere, Shihao Ju, Theodore S. Rappaport, George R. MacCartney Jr.:
Verification and Calibration of Antenna Cross-Polarization Discrimination and Penetration Loss for Millimeter Wave Communications. CoRR abs/1807.04384 (2018) - [i43]Shihao Ju, Theodore S. Rappaport:
Simulating Motion - Incorporating Spatial Consistency into the NYUSIM Channel Model. CoRR abs/1807.04392 (2018) - [i42]Ojas Kanhere, Theodore S. Rappaport:
Position Locationing for Millimeter Wave Systems. CoRR abs/1808.07094 (2018) - [i41]Shihao Ju, Theodore S. Rappaport:
Millimeter-wave Extended NYUSIM Channel Model for Spatial Consistency. CoRR abs/1808.07099 (2018) - [i40]Yunchou Xing, Theodore S. Rappaport:
Propagation Measurement System and Approach at 140 GHz-Moving to 6G and Above 100 GHz. CoRR abs/1808.07594 (2018) - 2017
- [i39]Christopher Robert Anderson, Theodore S. Rappaport:
In-Building Wideband Partition Loss Measurements at 2.5 GHz and 60 GHz. CoRR abs/1701.03415 (2017) - [i38]Jacqueline Ryan, George R. MacCartney Jr., Theodore S. Rappaport:
Indoor Office Wideband Penetration Loss Measurements at 73 GHz. CoRR abs/1703.08030 (2017) - [i37]George R. MacCartney Jr., Hangsong Yan, Shu Sun, Theodore S. Rappaport:
A Flexible Wideband Millimeter-Wave Channel Sounder with Local Area and NLOS to LOS Transition Measurements. CoRR abs/1703.08043 (2017) - [i36]Shu Sun, Theodore S. Rappaport:
Millimeter Wave MIMO Channel Estimation Based on Adaptive Compressed Sensing. CoRR abs/1703.08227 (2017) - [i35]Shu Sun, George R. MacCartney Jr., Theodore S. Rappaport:
A Novel Millimeter-Wave Channel Simulator and Applications for 5G Wireless Communications. CoRR abs/1703.08232 (2017) - [i34]Shu Sun, Hangsong Yan, George R. MacCartney Jr., Theodore S. Rappaport:
Millimeter Wave Small-Scale Spatial Statistics in an Urban Microcell Scenario. CoRR abs/1703.08239 (2017) - [i33]George R. MacCartney Jr., Theodore S. Rappaport:
Study on 3GPP Rural Macrocell Path Loss Models for Millimeter Wave Wireless Communications. CoRR abs/1703.10300 (2017) - [i32]Theodore S. Rappaport, Shu Sun, Mansoor Shafi:
Investigation and Comparison of 3GPP and NYUSIM Channel Models for 5G Wireless Communications. CoRR abs/1707.00291 (2017) - [i31]Theodore S. Rappaport, George R. MacCartney Jr., Shu Sun, Hangsong Yan, Sijia Deng:
Small-Scale, Local Area, and Transitional Millimeter Wave Propagation for 5G Communications. CoRR abs/1707.07816 (2017) - [i30]Theodore S. Rappaport, Yunchou Xing, George R. MacCartney Jr., Andreas F. Molisch, Evangelos Mellios, Jianhua Zhang:
Overview of Millimeter Wave Communications for Fifth-Generation (5G) Wireless Networks-with a focus on Propagation Models. CoRR abs/1708.02557 (2017) - [i29]George R. MacCartney Jr., Theodore S. Rappaport, Sundeep Rangan:
Rapid Fading Due to Human Blockage in Pedestrian Crowds at 5G Millimeter-Wave Frequencies. CoRR abs/1709.05883 (2017) - [i28]George R. MacCartney Jr., Theodore S. Rappaport, Amitava Ghosh:
Base Station Diversity Propagation Measurements at 73 GHz Millimeter-Wave for 5G Coordinated Multipoint (CoMP) Analysis. CoRR abs/1710.03626 (2017) - 2016
- [i27]Katsuyuki Haneda, Lei Tian, Yi Zheng, Henrik Asplund, Jian Li, Yi Wang, David Steer, Clara Li, Tommaso Balercia, Sunguk Lee, YoungSuk Kim, Amitava Ghosh, Timothy A. Thomas, Takehiro Nakamura, Yuichi Kakishima, Tetsuro Imai, Haralabos C. Papadopoulos, Theodore S. Rappaport, George R. MacCartney Jr., Mathew K. Samimi, Shu Sun, Ozge H. Koymen, Sooyoung Hur, Jeongho Park, Jianzhong Charlie Zhang, Evangelos Mellios, Andreas F. Molisch, Saeed S. Ghassamzadah, Arun Ghosh:
5G 3GPP-like Channel Models for Outdoor Urban Microcellular and Macrocellular Environments. CoRR abs/1602.07533 (2016) - [i26]Katsuyuki Haneda, Lei Tian, Henrik Asplund, Jian Li, Yi Wang, David Steer, Clara Li, Tommaso Balercia, Sunguk Lee, YoungSuk Kim, Amitava Ghosh, Timothy A. Thomas, Takehiro Nakamura, Yuichi Kakishima, Tetsuro Imai, Haralabos C. Papadopoulos, Theodore S. Rappaport, George R. MacCartney Jr., Mathew K. Samimi, Shu Sun, Ozge H. Koymen, Sooyoung Hur, Jeongho Park, Jianzhong Charlie Zhang, Evangelos Mellios, Andreas F. Molisch, Saeed S. Ghassamzadah, Arun Ghosh:
Indoor 5G 3GPP-like Channel Models for Office and Shopping Mall Environments. CoRR abs/1603.04079 (2016) - [i25]Shu Sun, Theodore S. Rappaport, Timothy A. Thomas, Amitava Ghosh, Huan Nguyen, István Z. Kovács, Ignacio Rodriguez, Ozge H. Koymen, Andrzej Partyka:
Investigation of Prediction Accuracy, Sensitivity, and Parameter Stability of Large-Scale Propagation Path Loss Models for 5G Wireless Communications. CoRR abs/1603.04404 (2016) - [i24]George R. MacCartney Jr., Sijia Deng, Shu Sun, Theodore S. Rappaport:
Millimeter-Wave Human Blockage at 73 GHz with a Simple Double Knife-Edge Diffraction Model and Extension for Directional Antennas. CoRR abs/1607.00226 (2016) - [i23]George R. MacCartney Jr., Shu Sun, Theodore S. Rappaport, Yunchou Xing, Hangsong Yan, Jeton Koka, Ruichen Wang, Dian Yu:
Millimeter Wave Wireless Communications: New Results for Rural Connectivity. CoRR abs/1608.05384 (2016) - 2015
- [i22]George R. MacCartney, Mathew K. Samimi, Theodore S. Rappaport:
Exploiting Directionality for Millimeter-Wave Wireless System Improvement. CoRR abs/1503.05265 (2015) - [i21]Mathew K. Samimi, Theodore S. Rappaport:
3-D Statistical Channel Model for Millimeter-Wave Outdoor Mobile Broadband Communications. CoRR abs/1503.05619 (2015) - [i20]Ting Wu, Theodore S. Rappaport, Christopher M. Collins:
The Human Body and Millimeter-Wave Wireless Communication Systems: Interactions and Implications. CoRR abs/1503.05944 (2015) - [i19]Mathew K. Samimi, Theodore S. Rappaport, George R. MacCartney:
Probabilistic Omnidirectional Path Loss Models for Millimeter-Wave Outdoor Communications. CoRR abs/1503.07612 (2015) - [i18]Sijia Deng, Mathew K. Samimi, Theodore S. Rappaport:
28 GHz and 73 GHz Millimeter-Wave Indoor Propagation Measurements and Path Loss Models. CoRR abs/1509.00395 (2015) - [i17]Theodore S. Rappaport, Sijia Deng:
73 GHz Wideband Millimeter-Wave Foliage and Ground Reflection Measurements and Models. CoRR abs/1509.00436 (2015) - [i16]Mathew K. Samimi, Theodore S. Rappaport:
3-D Statistical Channel Model for Millimeter-Wave Outdoor Communications. CoRR abs/1510.03081 (2015) - [i15]Mathew K. Samimi, Theodore S. Rappaport:
28 GHz Millimeter-Wave Ultrawideband Small-Scale Fading Models in Wireless Channels. CoRR abs/1511.06938 (2015) - [i14]Mathew K. Samimi, Shu Sun, Theodore S. Rappaport:
MIMO Channel Modeling and Capacity Analysis for 5G Millimeter-Wave Wireless Systems. CoRR abs/1511.06940 (2015) - [i13]Mathew K. Samimi, Theodore S. Rappaport:
Local Multipath Model Parameters for Generating 5G Millimeter-Wave 3GPP-like Channel Impulse Response. CoRR abs/1511.06941 (2015) - [i12]Sijia Deng, George R. MacCartney Jr., Theodore S. Rappaport:
Indoor Office Plan Environment and Layout-Based MmWave Path Loss Models for 28 GHz and 73 GHz. CoRR abs/1511.07057 (2015) - [i11]Shu Sun, George R. MacCartney Jr., Mathew K. Samimi, Theodore S. Rappaport:
Synthesizing Omnidirectional Antenna Patterns, Received Power and Path Loss from Directional Antennas for 5G Millimeter-Wave Communications. CoRR abs/1511.07271 (2015) - [i10]Shu Sun, Theodore S. Rappaport, Sundeep Rangan, Timothy A. Thomas, Amitava Ghosh, István Z. Kovács, Ignacio Rodriguez, Ozge H. Koymen, Andrzej Partyka, Jan Jarvelainen:
Propagation Path Loss Models for 5G Urban Micro- and Macro-Cellular Scenarios. CoRR abs/1511.07311 (2015) - [i9]Shu Sun, George R. MacCartney Jr., Theodore S. Rappaport:
Millimeter-Wave Distance-Dependent Large-Scale Propagation Measurements and Path Loss Models for Outdoor and Indoor 5G Systems. CoRR abs/1511.07345 (2015) - [i8]Shu Sun, Timothy A. Thomas, Theodore S. Rappaport, Huan Nguyen, István Z. Kovács, Ignacio Rodriguez:
Path Loss, Shadow Fading, and Line-Of-Sight Probability Models for 5G Urban Macro-Cellular Scenarios. CoRR abs/1511.07374 (2015) - [i7]Timothy A. Thomas, Marcin Rybakowski, Shu Sun, Theodore S. Rappaport, Huan Nguyen, István Z. Kovács, Ignacio Rodriguez:
A Prediction Study of Path Loss Models from 2-73.5 GHz in an Urban-Macro Environment. CoRR abs/1512.01585 (2015) - 2014
- [i6]Sundeep Rangan, Theodore S. Rappaport, Elza Erkip:
Millimeter Wave Cellular Wireless Networks: Potentials and Challenges. CoRR abs/1401.2560 (2014) - [i5]Parisa A. Eliasi, Sundeep Rangan, Theodore S. Rappaport:
Low-Rank Spatial Channel Estimation for Millimeter Wave Cellular Systems. CoRR abs/1410.4831 (2014) - 2013
- [i4]Ansuman Adhikary, Ebrahim Al Safadi, Mathew Samimi, Rui Wang, Giuseppe Caire, Theodore S. Rappaport, Andreas F. Molisch:
Joint Spatial Division and Multiplexing for mm-Wave Channels. CoRR abs/1312.2045 (2013) - [i3]Mustafa Riza Akdeniz, Yuanpeng Liu, Shu Sun, Sundeep Rangan, Theodore S. Rappaport, Elza Erkip:
Millimeter Wave Channel Modeling and Cellular Capacity Evaluation. CoRR abs/1312.4921 (2013) - 2002
- [i2]Alex Verstak, Naren Ramakrishnan, Layne T. Watson, Jian He, Clifford A. Shaffer, Kyung Kyoon Bae, Jing Jiang, William H. Tranter, Theodore S. Rappaport:
BSML: A Binding Schema Markup Language for Data Interchange in Problem Solving Environments (PSEs). CoRR cs.CE/0202027 (2002) - [i1]Alex Verstak, Naren Ramakrishnan, Kyung Kyoon Bae, William H. Tranter, Layne T. Watson, Jian He, Clifford A. Shaffer, Theodore S. Rappaport:
Using Hierarchical Data Mining to Characterize Performance of Wireless System Configurations. CoRR cs.CE/0208040 (2002)
Coauthor Index
George R. MacCartney
aka: George R. MacCartney Jr.
aka: George R. MacCartney Jr.
[j73] [j65] [j64] [j59] [j57] [j56] [j54] [j52] [j51] [j48] [c67] [c66] [c65] [c64] [c63] [c62] [c61] [c59] [c56] [c55] [c54] [c53] [c52] [c51] [c50] [c46] [c42] [c34] [c33] [c32] [c31] [c30] [c29] [c27] [c24] [i44] [i38] [i37] [i35] [i34] [i33] [i31] [i30] [i29] [i28] [i27] [i26] [i24] [i23] [i22] [i19] [i12] [i11] [i9]
Mathew Samimi
aka: Mathew K. Samimi
aka: Mathew K. Samimi
[j71] [j70] [j67] [j66] [j63] [j60] [j57] [j56] [j54] [j50] [j48] [j47] [j44] [c69] [c63] [c62] [c61] [c60] [c57] [c55] [c54] [c53] [c51] [c50] [c49] [c48] [c46] [c45] [c39] [c38] [c34] [c32] [c28] [c25] [c24] [c23] [i45] [i37] [i36] [i35] [i34] [i32] [i31] [i27] [i26] [i25] [i24] [i23] [i14] [i11] [i10] [i9] [i8] [i7] [i3]
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