UWB Bibliography

UWB Channel and Receiver

Ali, M.H., A.S. Parker, and K. Pahlavan, “Frequency domain model for standard simulation of wideband radio propagation for personal communications,” Electronics Letters, Volume: 30, Issue: 25 (December 1994), 2103–2104.
Alvarez, A., G. Valera, M. Lobeira, R. Torres, and J.L. Garcia, “Ultra Wideband Channel Model for Indoor Environments,” Journal of Communications and Networks, Volume: 5, Issue: 4 (December 2003), 309–318.
Batra, A., J. Balakrishnan, A. Dabak, R. Gharpurey, J. Lin, P. Fontaine, J.-M. Ho, S. Lee, M. Frechette, S. March, M. Yamaguchi, and Texas Instruments et al., Multi-band OFDM Physical Layer Proposal for IEEE 802.15 Task Group 3a, Available at www.multibandofdm.org/papers/15-03-0268-01-003a-Multi-band-CFP-Document.pdf (September 2003).
Bi, C., and J.Y. Hui, “Multiple Access Capacity for Ultra-Wide Band Radio with Multi-Antenna Receivers,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 151–155.
Baccarelli, E., and M. Biagi, “A Novel self-Pilot based Transmit-Receiving Architecture for Multipath-Impaired UWB systems,” in press in IEEE Transactions on Communications (June 2004).
Biagi, M., and E. Baccarelli, “A Simple Multiple-Antenna UWB Transceiver Scheme for 4th generation WLAN,” IEEE Vehicular Technology Conference Proceedings (October 2003), 1903–1907.
Bregni, S., Synchronization of Digital Telecommunications Networks, Chichester, UK: J. Wiley and Sons (2002).
Buehrer, R.M., W.A. Davis, A. Safaai-Jazi, and D. Sweeney, “Characterization of the Ultra-wideband Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 26–31.
Carbonelli, C., U. Mengali, and U. Mitra, “Synchronization and channel estimation for UWB signals,” IEEE Global Telecommunications Conference (December 2003), 764–768.
Cartwright, P.M., and K.W. Sowerby, “Uplink and downlink analysis of a three-dimensional wireless indoor communication system,” Electronics Letters, Volume: 31, Issue: 7 (March 1995), 538–539.
Cassioli, D., M.Z. Win, F. Vatalaro, and A.F. Molisch, “Performance of Low-Complexity Rake Reception in a Realistic UWB Channel,” IEEE International Conference on Communications, Volume: 2 (April 2002a), 763–767.
Cassioli, D., M.Z. Win, and A.F. Molisch, “The Ultra-Wide Bandwidth Indoor Channel: From Statistical Model to Simulations,” IEEE Journal on Selected Areas in Communications, Volume: 20 , Issue: 6 (August 2002b), 1247–1257.
Chao, Y.L., and R.A. Scholtz, “Optimal and Suboptimal Receivers for Ultra-wideband Transmitted Reference Systems,” IEEE Global Telecommunications Conference (December 2003), 759–763.
Cherniakov, M., and L. Donskoi, “Frequency Band Selection of Radars for Buried Object Detection,” IEEE Transaction on Geoscience and Remote Sensing, Volume: 37, Issue: 2 (March 1999), 838–845.
Choi, J.D., and W.E. Stark, “Performance of Ultra-Wideband Communications With Suboptimal Receivers in Multipath Channels,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1754–1766.
Chui, C.-C., and R.A. Scholtz, “Optimizing Tracking Loops for UWB Monocycles,” IEEE Global Telecommunications Conference (December 2003), 425–430.
Corazza, G.E., and A. Polydoros, “Code Acquisition in CDMA Cellular Mobile Networks. Part I: Theory,” Proceedings of the IEEE 5th International Symposium on Spread Spectrum Techniques and Applications, Volume: 2 (September 1998), 454–458.
Cramer, R.J-M., R.A. Scholtz, and M.Z. Win, “Evaluation of an Ultra-Wide-Band Propagation Channel,” IEEE Transactions on Antennas and Propagation, Volume: 50, Issue: 5 (May 2002a), 561–570.
Cramer, R.J-M., R.A. Scholtz, and M.Z. Win, Evaluation of an Indoor Ultra-Wideband Propagation Channel, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02286r0P802-15_SG3a-Evaluation-of-an-Indoor-Ultra-Wideband-Propagation-Channel.doc (June 2002b).
Dabin, J.A., N. Ni, A.M. Haimovich, E. Niver, and H. Grebel, “The Effects of Antenna Directivity on Path Loss and Multipath Propagation in UWB Indoor Wireless Channels,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 305–309.
de Rivaz, S., B. Denis, J. Keignart, M. Pezzin, N. Daniele, and D. Morche, “Performances Analysis of a UWB Receiver using Complex Processing,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 229–233.
Denis, B., and J. Keignart, “Post-Processing Framework for Enhanced UWB Channel Modeling from Band-limited Measurements,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 260–264.
Di Benedetto, M.-G., L. De Nardis, M. Junk, and G. Giancola, “(UWB)²: Uncoordinated, Wireless, Baseborn medium access for UWB communication networks,” in press in Mobile Networks and Applications special issue on WLAN Optimization at the MAC and Networks Levels, (2004).
Durisi, G., and G. Romano, “Simulation Analysis and Performance Evaluation of an UWB system in indoor multipath channel,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 255–258.
Ezaki, T., and T. Ohtsuki, “Diversity Gain in Ultra Wideband Impulse Radio (UWB-IR),” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 56–60.
Feng, L., and W. Namgoong, “Joint Estimation and Detection of UWB Signals with Timing Offset Error and Unknown Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 152–156.
Feuerstein, M.J., and T.S. Rappaport, Wireless Personal Communications, Boston, MA: Kluwer Academic Publishers (1993), 225–249.
Foerster, J., and Q. Li, UWB Channel Modeling Contribution from Intel, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02279r0P802-15_SG3a-Channel-Model-Cont-Intel.doc (June 2002).
Franz, S., and U. Mitra, “On Optimal Data Detection for UWB Transmitted Reference Systems,” IEEE Global Telecommunications Conference (December 2003), 744–748.
Funk, E.E., and C.H. Lee, “Free-Space Power Combining and Beam Steering of Ultra-Wideband Radiation Using an Array of Laser-Triggered Antennas,” IEEE Transactions on Microwave Theory and Techniques, Volume: 44, Issue: 11 (November 1996), 2039–2044.
Ganesh, R., and K. Pahlavan, “Statistical modeling and computer simulation of indoor radio channel,” IEE Proceeding-I, Volume: 138, Issue: 3 (June 1991), 153–161.
Ghassemzadeh, S.S., L.J. Greenstein, A. Kavcic, T. Sveinsson, and V. Tarokh, “An Empirical Indoor Path Loss Model for Ultra-Wideband Channels”, Journal of Communications and Networks, Volume: 5, Issue: 4 (December 2003), 303–308.
Ghassemzadeh, S.S., L.J. Greenstein, and V. Tarokh, The Ultra-Wideband Indoor Multipath Model, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02282r1P802-15_SG3a-802-15-UWB-Multipath-Model.doc (July 2002).
Ghassemzadeh, S.S., and V. Tarokh, The Ultra-wideband Indoor Path Loss model, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02277r1P802-15_SG3a-802.15-UWB-Propagation-Path%20Loss-Model.doc (July 2002).
Ghassemzadeh, S.S., and V. Tarokh, “UWB Path Loss Characterization In Residential Environments,” IEEE Radio Frequency Integrated Circuits Symposium (June 2003), 501–504.
Haneda, K., and J. Takada, “An Application of SAGE Algorithm for UWB Propagation Channel Estimation,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 483–487.
Hanzo, L., M. Münster, B.J. Choi, and T. Keller, OFDM and MC-CDMA for Broadband Multi-User Communications, WLANs and Broadcasting, Chichester, West Sussex, England: John Wiley and Sons, Inc. (2003).
Hashemi, H., “Simulation of the Urban Radio Propagation Channel,” IEEE Transactions on Vehicular Technology, Volume: 28, Issue: 3 (August 1979), 213–225.
Hashemi, H., “The Indoor Radio Propagation Channel,” Proceedings of the IEEE, Volume: 81, Issue: 7 (July 1993a), 943–968.
Hashemi, H., “Impulse Response Modeling of Indoor Radio Propagation Channels,” IEEE Journal on Selected Areas in Communications, Volume: 11, Issue: 7 (September 1993b), 967–978.
Hashemi, H., and D. Tholl, “Statistical Modeling and Simulation of the RMS Delay Spread of Indoor Radio Propagation Channels,” IEEE Transactions on Vehicular Technology, Volume: 43, Issue: 1 (February 1994), 110–119.
Hashemi, H., M. McGuire, T. Vlasschaert, and T. Tholl, “Measurements and Modeling of Temporal Variations of the Indoor Radio Propagation Channel,” IEEE Transactions on Vehicular Technology, Volume: 43, Issue: 3 (August 1994), 733–737.
Hendrickson, C., G. Gerace, C. Yerkes, and J. Forgy, “Wideband Wireless Peer to Peer Propagation Measurements,” Conference Record of the Thirty-Third Asilomar Conference on Signals, Systems, and Computers, Volume: 1 (October 1999), 183–189.
Hingorani, G.D., and J.C. Hancock, “A Transmitted Reference System for Communication in Random of Unknown Channels,” IEEE Transactions on Communication Technology, Volume: 13, Issue: 3 (September 1965), 293–301.
Hong, Y.W., and A. Scaglione, “Time synchronization and reach-back communications with pulse-coupled oscillators for UWB wireless ad hoc networks,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 190–194.
Hovinen, V., M. Hamalainen, R. Tesi, L. Hentila, N. Laine, D. Porcino, and G. Shor, A proposal for a selection of indoor UWB path loss model, Available at grouper.ieee.org/groups/802/15/pub/2002/Mar02/02119r0P802-15_SG3a-Response-to-CFA-ULTRAWAVES.ppt (June 2002a).
Hovinen, V., M. Hamalainen, and T. Pätsi, “Ultra Wideband Indoor Radio Channel Models: Preliminary Results,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002b), 75–79.
Howard, S.J., and K. Pahlavan, “Doppler Spread Measurements of Indoor Radio Channel,” Electronics Letters, Volume: 26, Issue: 2 (January 1990), 107–108.
Howard, S.J., and K. Pahlavan, “Autoregressive Modeling of Wide-Band Indoor Radio Propagation,” IEEE Transactions on Communications, Volume: 40, Issue: 9 (September 1992), 1540–1552.
Hoyos, S., B.M. Sadler, and G.R. Arce, “Dithering and SD Modulation in Mono-bit Digital Receivers for Ultra-Wideband Communications,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 71–75.
Huang, D., and K.B. Letaief, “A Reduced Complexity Coded OFDM System with MIMO Antennas for Broadband Wireless Communications,” IEEE Global Telecommunications Conference, Volume:1 (November 2002), 661–665.
IEEE 802.15.SG3a, “Channel modeling Sub-committee Report Final,” IEEE P802.15-02/490r1-SG3a (February 2003).
Jaureguy, M., and P. Borderies, “Modelling and Processing of Ultra Wide Band Scattering of Buried Targets,” IEE Conference Publication No.431, “Detection of abandoned land mines” (October 1996), 119–123.
Junk, M.D., Synchronization Issues in Ultra Wideband Communication Networks, M.S. Thesis, Fachgebiet Nachrichtentechnische Systeme der Universitat Duisburg-Essen Standort Duisburg (2003).
Kaiser, T., “On UWB Beamforming,” Proceedings of Kleinheubacher Tagung (October 2003).
Keignart, J., and N. Daniele, “Subnanosecond UWB Channel Sounding in Frequency and Temporal Domain,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 25–30.
Kolenchery, S.S., J.K. Townsend, and J.A. Freebersyer, “A novel impulse radio network for tactical military wireless communications,” IEEE Military Communications Conference, Volume: 1 (October 1998), 59–65.
Kunisch, J., and J. Pamp, “Measurement results and Modeling Aspects for the UWB Radio Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002a), 19–23.
Kunisch, J., and J. Pamp, Radio Channel Model for Indoor UWB WPAN Environments, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02281r0P802-15_SG3a-IMST-Response-Call-Contributions-UWB-Channel-Models.pdf (June 2002b), 290–294.
Kunisch, J., and J. Pamp, “An Ultra-Wideband Space-Variant Multipath Indoor Radio Channel Model,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003).
Lawton, M.C., and J.P. McGeehan, “The Application of a Deterministic Ray Launching Algorithm for the Prediction of Radio Channel Characteristics in Small-Cell Environments,” IEEE Transactions on Vehicular Technology, Volume: 43, Issue: 4 (November 1994), 955–969.
Lee, E.A., and D.G. Messerschmitt, Digital Communication, 2nd Edition, Boston, Massachusetts: Kluwer Academic Publishers (1994).
Lee, H., B. Han, Y. Shin, and S. Im, “Multipath Characteristics of Impulse Radio Channels,” IEEE Vehicular Technology Conference Proceedings, Volume: 3 (May 2000), 2487–2491.
Lee, H.J., D.S. Ha, and H.S. Lee, “A Frequency-Domain Approach for all-digital CMOS Ultra Wideband Receivers,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 86–90.
Li, Q., and L.A. Rusch, “Multiuser Detection for DS-CDMA UWB in the Home Environment,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1701–1711.
Licul, S., W.A. Davis, and W.L. Stutzman, “Ultra-Wideband (UWB) Communication Link Modeling and Characterization,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 310–314.
Liu, P., Z. Xu, and J. Tang, “Subspace Multiuser Receivers for UWB Communication Systems,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 116–120.
Lottici, V., A. D’Andrea, and U. Mengali, “Channel Estimation for Ultra-Wideband Communications,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1638–1645.
Lovelace, W.M., and J.K. Townsend, “The Effects of Timing Jitter and Tracking on the Performance of Impulse Radio,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1646–1651.
Ma, Y., F. Chin, B. Kannan, and S. Pasupathy, “Acquisition Performance of an Ultra Wide-band Communications System Over a Multiple-Access Fading Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 99–103.
McEwan, T.E., Ultra-Wideband Receiver, United States Patent number 5345471 (September 1994).
McEwan, T.E., Ultra-Wideband Receiver, United States Patent number 5523760 (June 1996).
Mengali, U., and A. D’Andrea, Synchronization Techniques for Digital Receivers, 1st Edition, New York : Plenum Press/Kluwer Academic Publishers (1997).
Middleton, D., An introduction to Statistical Communication Theory, New York: McGraw-Hill Book Company (1960).
Molisch, A.F., M.Z. Win, and D. Cassioli, The Ultra-Wide Bandwidth Indoor Channel: from Statistical Model to Simulations. Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02284r0P802-15_SG3a-The-Ultra-Wide-Bandwidth-Indoor-Channel-from-Statistical-Model-to-Simulations.pdf (June 2002).
Molkdar, D., “Review on radio propagation into and within buildings,” IEE Proceedings-H, Volume: 138, Issue: 1 (February 1991), 61–73.
Muqaibel, A., B. Woerner, and S. Riad, “Application of Multi-User Detection Techniques to Impulse Radio Time Hopping Multiple Access Systems,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 169-173.
Muqaibel, A.H., A. Safaai-Jazi, A.M. Attiya, A. Bayram, and S. Riad, “Measurement and Characterization of Indoor Ultra-Wideband Propagation,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 295–299.
Namgoong, W., “A Channalized Digital Ultrawideband Receiver,” IEEE Transactions on Wireless Communications, Volume: 2, Issue: 3 (May 2003), 502–510.
Narayanan, R.M., and M. Dawood, “Doppler Estimation Using a Coherent Ultrawide-Band Random Noise Radar,” IEEE Transactions on Atennas and Propagation, Volume: 48, Issue: 6 (June 2000), 868–878.
Pajusco, P., and P. Pagani, “Extension of SIMO Wideband Channel Sounder for UWB Propagation Experiment,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 250–254.
Pelissier, M., B. Denis, and D. Morche, “A methodology to investigate UWB digital receiver sensitivity to clock jitter,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 126–130.
Pendergrass, M., and W.C. Beeler, Empirically Based Statistical Ultra-Wideband (UWB) Channel Model, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02294r1p802-15_SG3a-Empirically_Based_UWB_Channel_Model.ppt (July 2002).
Polydoros, A., and S. Glisic, “Code synchronization a review of principles and techniques,” IEEE Third International Symposium on Spread Spectrum Techniques and Applications, Volume: 1 (July 1994), 115-137.
Prettie, C., D. Cheung, L. Rusch, and M. Ho, “Spatial Correlation of UWB Signals in a Home Environment,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 65–69.
Price, R., and P.E. Green Jr., “A communication technique for multipath channels,” Proc. IRE, Volume: 46 (March 1958), 555–570.
Proakis, J.G., Digital Communications, 3rd Edition, New York: McGraw-Hill International Editions (1995).
Qiu, R.C., “A Study of the Ultra-Wideband Wireless Propagation Channel and Optimum UWB Receiver Design,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1628–1637.
Rajeswaran, A., V.S. Somayazulu, and J.R. Foerster, “Rake Performance for a Pulse Based UWB System in a Realistic UWB Indoor Channel,” IEEE Conference on Communications, Volume: 4 (2003), 2879–2883.
Ramirez-Mireles, F., “Signal Design for Ultra-Wide-Band Communications in Dense Multipath,” IEEE Transactions on Vehicular Technology, Volume: 51, Issue: 6 (November 2002), 1517–1521.
Ramirez-Mireles, F., M.W. Win, and R.A. Scholtz, “Performance of Ultra-Wideband Time-Shift-Modulated Signals in the Indoor Wireless Impulse Radio Channel,” Conference Record of the Thirty-First Asilomar Conference on Signals, Systems, and Computers, Volume: 1 (November 1997), 192–196.
Rappaport, T.S., S.Y. Seidel, and R. Singh, “900-MHz Multipath Propagation Measurements for U.S. Digital Cellular Radiotelephone,” IEEE Transactions on Vehicular Technology, Volume: 39, Issue: 2 (May 1990), 132–139.
Rappaport, T.S., S.Y. Seidel, K. Takamizawa, “Statistical Channel Impulse Response Models for Factory and Open Plan Building Radio Communication System Design,” IEEE Transactions on Communications, Volume: 39, Issue: 5 (May 1991), 794–807.
Reggiani, L., and G.M. Maggio, “A Reduced-Complexity Acquisition Algorithm for UWB Impulse Radio,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 131–135.
Rice, L.P., “Radio transmission into buildings at 35 and 150 mc,” Bell Syst. Tech. J., Volume: 38, Issue: 1 (January 1959), 197–210.
Robbins, K.W., Short Base-Band Pulse Receiver, United States Patent number 3662316 (May 1972).
Roberts, R., XtremeSpectrum CFP Document, Available at grouper.ieee.org/groups/802/15/pub/2003/Jul03/03154r3P802-15_TG3a-XtremeSpectrum-CFP-Documentation.pdf (July 2003).
Romme, J., and B. Kull, “On the Relation Between Bandwidth and robustness of indoor UWB Coomunication,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 255–259.
Rushforth, C.K., “Transmitted-reference Techniques for Random or Unknown Channels,” IEEE Transactions on Information Theory, Volume: 10, Issue: 1 (January 1964), 39–42.
Saleh, A.A.M., and R.A. Valenzuela, “A Statistical Model for Indoor Multipath Propagation,” IEEE Journal on Selected Areas in Communications, Volume: 5, Issue: 2 (February 1987), 128–137.
Scholtz, R.A., R.J.-M. Cramer, and M.Z. Win, “Evaluation of the Propagation Characteristics of Ultra-Wideband Communication Channels,” IEEE Transactions on Antennas and Propagation, Volume: 50 (February 1998), 626–630.
Seidel, S.Y., and T.S. Rappaport, “Site-Specific Propagation Prediction for Wireless In-Building Personal Communication System Design,” IEEE Transactions on Vehicular Technology, Volume: 43, Issue: 4 (November 1994), 879–891.
Sexton, T.A., and K. Pahlavan, “Channel Modeling and Adaptive Equalization of Indoor Radio Channels,” IEEE Journal on Selected Areas in Communications, Volume: 7, Issue 1 (January 1989), 114–120.
Sheng, H., A.M. Haimovich, A.F. Molisch, and J. Zhang, “Optimum Combining for Time Hopping Impulse Radio UWB Rake Receivers,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 224–228.
Siwiak, K., and A. Petroff, “A Path Link Model for Ultra Wide Band Pulse Transmissions,” IEEE Conference on Vehicular Technology, Volume: 2 (May 2001), 1173–1175.
Siwiak, K., Propagation notes to P802.15 SG3a from IEEE Tutorial, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02328r0P802-15_SG3a-Propagation-notes-to-SG3a-from-IEEE-Tutorial.ppt (July 2002a).
Siwiak, K., UWB Propagation phenomena, Available at grouper.ieee.org/groups/802/15/pub/2002/Jul02/02301r3P802-15_SG3a-UWB-Propagation-Phenomena.ppt (July 2002b).
Suzuki, Y., and T. Kobayashi, “Ultra Wideband Signal Propagation in Desktop Environments,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 493–497.
Tan, S.S., B. Kannan, and A. Nallanathan, “Performance of UWB Multiple Access Impulse Radio Systems In Multipath Environment with Antenna Array,” IEEE Global Telecommunications Conference (December 2003), 2182–2186.
Tian, Z., and G.B. Giannakis, “Data-aided ML timing acquisition in ultra-wideband radios,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003a), 142–146.
Tian, Z., and G.B. Giannakis, “BER Sensitivity to Mis-Timing in Correlation based UWB Receivers,” IEEE Global Telecommunications Conference (December 2003b), 441–445.
Turin, G.L., “Communication through Noisy, Random-Multipath Channels,” IRE Convention (1956), 154–166.
Turin, G.L., F.D. Clapp, T.L. Johnston, S.B. Fine, and D. Lavry, “A Statistical Model of Urban Multipath Propagation,” IEEE Transactions Vehicular Technology, Volume: 21 (February 1972), 1–9.
Turin, W., R. Jana, S.S. Ghassemzadeh, C.W. Rice, and V. Tarokh, “Autoregressive Modeling of an Indoor UWB Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 71–74.
Uguen, B., E. Plouhinec, Y. Lostanlen, and G. Chassay, “A Deterministic Ultra Wideband Channel Modeling,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 1–5.
Weeks, G.D., J.K. Townsend, and J.A. Freebersyser, “Performance of Hard Decision Detection for Impulse Radio,” IEEE Military Communications Conference (October 1999), 1201–1206.
Weisenhorn, M., and W. Hirt, “Performance of Binary Antipodal Signaling over the Indoor UWB MIMO Channel,” IEEE International Conference on Communications, Volume: 4 (May 2003), 2872–2878.
Win, M.Z., “Spectral Density of Random UWB Signals,” IEEE Communications Letters, Volume: 6, Issue: 12 (December 2002), 526–528.
Win, M.Z., F. Ramirez-Mireles, R.A. Scholtz, and M.A. Barnes, “Ultra-Wide Bandwidth (UWB) Signal Propagation for Outdoor Wireless Communications,” IEEE Conference on Vehicular Technology, Volume: 1 (May 1997), 251–255.
Win, M.Z., and R.A. Scholtz, “On the Robustness of Ultra-Wide Bandwidth Signals in Dense Multipath Environments,” IEEE Communications Letters, Volume: 2, Issue: 2 (February 1998a), 51–53.
Win, M.Z., and R.A. Scholtz, “On the Energy Capture of Ultrawide Bandwidth Signals in Dense Multipath Environments”, IEEE Communications Letters, Volume: 2, Issue: 9 (September 1998b), 245–247.
Win, M.Z., and R.A. Scholtz, “Characterization of Ultra-Wide Bandwidth Wireless Indoor Channels: A Communication-Theoretic View,” IEEE Journal on Selected Areas in Communications, Volume: 20, Issue: 9 (December 2002), 1613–1627.
Yang, G., K. Pahlavan, and T. Holt, “Effects Antenna Sectorisation on Data Rate Limitations of Indoor Radio Modems,” Electronics Letters, Volume: 28, Issue: 13 (June 1992), 1182–1183.
Yang, L., and G.B. Giannakis, “Low-Complexity Training for Rapid Timing Acquisition in Ultra Wideband Communications,” IEEE Global Telecommunications Conference (December 2003), 769–773.
Yao, R., G. Gao, Z. Chen, and W. Zhu, “UWB Multipath Channel Model Based on Time-Domain UTD Technique,” IEEE Global Telecommunications Conference (December 2003), 1205–1210.
Zhang, H., T. Udagawa, T. Arita, and M. Nakagawa, “A Statistical Model for the Small-Scale Multipath Fading Characteristics of Ultra Wideband Indoor Channel,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 81–85.
Zhang, H., and D.L. Goeckel, “Generalized Transmitted-Reference UWB Systems,” IEEE Conference on Ultra Wideband Systems and Technologies (November 2003), 147–151.
Zhu, F., Z. Wu, and C.R. Nassar, “Generalized Fading Channel Model with Application to UWB,” IEEE Conference on Ultra Wideband Systems and Technologies (May 2002), 13–17.