Final report on link level and system level channel models - Winner

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WINNER D5.4 v. 1.4 8. References [3GPP SCM] 3GPP TR 25.996, “3rd Generation Partnership Project; technical specification group radio access network; spatial channel model for MIMO simulations (release 6)”, V6.1.0. [802.11n] IEEE 802.11-03/940r2, “IEEE P802.11 Wireless LANs, TGn Channel Models, Jan. 9, 2004. [AlPM02] [Bal02] [BBK+02] [BBK+04] A. Algans, K. I. Pedersen, and P. E. Mogensen, “Experimental analysis of the joint statistical properties of azimuth spread, delay spread, and shadow fading,” IEEE J. Select. Areas Commun., vol. 20, no. 3, pp. 523-531, Apr. 2002. Baltitude, R.J.C., “A Comparison of Multipath-Dispersion-Related Micro-Cellular Mobile Radio Channel Characteristics at 1.9 GHz and 5.8 GHz”, in Proc. ANTEM’02, Montreal, Jul. 31 – Aug. 2, 2002, pp. 623-626. M. D. Batariere, T. K. Blankenship, J. F. Kepler, T. P. Krauss, I. Lisica, S. Mukthvaram, J. W. Porter, T. A. Thomas, F. W. Vook, “Wideband MIMO mobile impulse response measurements at 3.7 GHz”, IEEE 55 th VTC, pp. 26-30, 2002. M. D. Batariere, T. K. Blankenshiop, J. F. Kepler, T. P. Krauss, ”Seasonal variations in path-loss in the 3.7 GHz band”, IEEE RAWCON, pp. 399-402, 2004. [BGS+05] D. S. Baum, G. Del Galdo, J. Salo, P. Kyösti, T. Rautiainen, M. Milojevic, and J. Hansen, “An Interim Channel Model for Beyond-3G Systems,” in Proc. IEEE VTC’S05, May 2005. [Bul03] [Cor01] R. J. C. Bultitude, ”Microcellular mobile radio channel transmission loss and temporal dispersion characteristics at 1.9 GHz and 5.9 GHz”, COST273 TD(03)015, Barcelona, Spain, 15-17 Jan, 2003. L. M. Correia, Wireless Flexible Personalised Communications: COST 259, European Co-operation in Mobile Radio Research, John Wiley & Sons Ltd, 2001. [Cost231] “Digital Mobile radio towards future generations”, Cost-231. final <strong>report</strong>. http://www.lx.it.pt/cost231/ [D5.1] [D5.2] WINNER WP5, “A set of channel and propagation models for early link and system level simulations,” WP5 Deliverable D5.1, March. 2004. WINNER WP5, “Determination of Propagation Scenarios,” WINNER WP5, Deliverable. 30.6.2004. [D5.3] WINNER WP5, “Interim Channel Models”, WINNER project deliverable D5.3, ver 2.4, April 2005. [D7.2] [DC99] [DGM+03] [DRX98] [Dug99] J. Nyström et. al., “System Assessment Criteria Specification”. WINNER WP7, D7.2. June 2004. (Currently, 4.5.04, a draft version.) E. Damosso and L. Correia, eds., COST Action 231, Digital Mobile Radio Towards Future Generation Systems, <strong>Final</strong> Report. No. EUR 18957, European Commission, 1999. A. Domazetovic, L. J. Greenstein, N. B. Mandayam, and I. Seskar. “Estimating the Doppler Spectrum of a Short-Range Fixed Wireless Channel”, IEEE Comm. Lett., 7(5):227-229, May 2003. G. Durkin, T. S. Rappaport, H. Xu, ”Measurements and models for radio path-loss and penetration in and around homes and trees at 5.85 GHz, IEEE Trans. Comm., Vol. 46, pp.1484-1496, 1998. A. Dugas, “5 GHz MILTON Propagation Study”, slide-set downloadable from http://www.crc.ca/en/html/milton/home/documents. [EBITAR] EBIT “Analysis Report of EBIT”, WINNER Internal Report, 2005, https://bscw.eurescom.de/bscw/bscw.cgi/0/124779 [EGT+99] V. Erceg, L. J. Greenstein, S. Y. Tjandra, S. R. Parkoff, A. Gupta, B. Kulic, A. A. Julius, and R. Bianchi, “An empirically based path-loss model for wireless channels in suburban environments”, IEEE J. Selected Areas Comm., Vol. 17, No. 7, pp. 1205-1211, 1999. [Erc01] V. Erceg et al., “Channel Models for Fixed Applications”, Technical <strong>report</strong>, IEEE 802.16 Broadband Wireless Working Group, Jul. 2001. Page 148 (167)
WINNER D5.4 v. 1.4 [FBR+94] [FDS+94] [Fle00] [Gald04] [GEYC] [Gud91] [Hat80] [HOHB02] [JXP01] [KHK+01] [KKM02] [KRB00] [KSL+02] [KVV05] [LUI99] [Maw92] [MBX93] [MBX94] [Medav] [MEJ91] Feuerstein, M.J.; Blackard, K.L.; Rappaport, T.S.; Seidel, S.Y.; Xia, H.H., “Path-loss, delay spread, and outage models as functions of antenna height for microcellular system design”, in Proc. IEEE VTC’94, Vol. 43, Iss. 3, Aug. 1994, pp. 487 – 498. Foster, H.M.; Dehghan, S.F.; Steele, R.; Stefanov, J.J.; Strelouhov, H.K., “Microcellular measurements and their prediction”, IEE Colloquium on “Role of Site Shielding in Prediction Models for Urban Radiowave Propagation” (Digest No. 1994/231), Nov. 1994, pp. 2/1 - 2/6. B. H. Fleury, “First- and second-order characterization of direction dispersion and space selectivity in the radio channel”, IEEE Trans. Inform. Theory, Sep. 2000, vol. IT-46, no. 6, pp. 2027-2044. G. Del Galdo, “The SCM bandwidth extension,” WINNER WP5.5, Tech. Rep., Sep. 2004. L. J. Greenstein, V. Erceg, Y. S. Yeh, and M. V. Clark, “A new path-gain/delay-spread propagation model for digital cellular channels,” IEEE Trans. Vehicular Technology, vol. 46, p. 477, 1997. M. Gudmundson, “Correlation Model For Shadow Fading in Mobile Radio Systems,” Electron. Lett., Vol. 27, No. 23, Nov. 1991. M. Hata, “Empirical Formula for Propagation Loss in Land Mobile Radio Services,” IEEE Trans. Vehicular Technology, Vol. VT-29, Aug. 1980. M. Herdin, H. Ozcelik, H. Hofstetter, and E. Bonek, „Variation of measured indoor MIMO capacity with receive direction and position at 5.2 GHz,“ Electronic Letters, vol. 38, no. 21m pp. 1283-1285, Oct. 2002. J. Kivinen, X. Zhao, and P. Vainikainen, “Empirical characterization of wideband indoor radio channel at 5.3 GHz,” IEEE Trans. Antennas Propagt., vol. 49, no. 8, pp. 1192-1203, Aug. 2001. K. Kalliola, H. Laitinen, K. Sulonen, L. Vuokko, and P. Vainikainen, ‘’Directional Radio Channel Measurements at Mobile Station in Different Radio Environments at 2.15 GHz’’, Feb. 2001. J. F. Kepler, T. P. Krauss, S. Mukthvaram, ”Delay spread measurements on a wideband MIMO channel at 3.7 GHz”, IEEE 56 th VTC, pp. 2498-2502, 2002. A. Kuchar, J-P. Rossi, and E. Bonek, ”Directional macro-cell channel characterization from urban measurements”, IEEE Trans. Antennas and Propagation, Vol. 48, pp.137-145, 2000. K. Kalliola, K. Sulonen, H. Laitinen, O. Kivekäs, J. Krogerus, and P. Vainikainen, ”Angle power distribution and mean effective gain of mobile antenna in different propagation environments”, IEEE Trans. Veh. Techn., Vol. 51, pp. 823-838, 2002. A. Kainulainen, L. Vuokko, and P. Vainikainen, “Polarization Behavior in Different Urban Radio Environments at 5.3 GHz,” COST273 TD(05)18, Bologna, Jan. 19-21. L. M. Correia, `COST 259: Wireless Flexible Personalized Communications` Mawira, A., “Models for the spatial correlation functions of the (log)-normal component of the variability of VHF/UHF field strength in urban environment,” PIMRC 1992, pp. 436-440. L. R. Maciel, H. L. Bertoni, and H. H. Xia, “Unified Approach to prediction of Propagation Over Building for all Ranges of Base Station Antenna Height,” IEEE Trans. Vehicular Technology, Vol. 42, No. 1, Feb. 1993. L. R. Maciel, H. L. Bertoni, and H. H. Xia, “Unified Approach to prediction of Propagation Over Building for all Ranges of Base Station Antenna Height,” IEEE Trans. Vehicular Technology, Vol. 42, No. 1, Feb. 1993. http://www.channelsounder.de P. E. Mogensen, P. Eggers, and C. Jensen, ”Urban area radio propagation measurements for GSM/DCS 1800 macro and micro cells”, ICAP 91, pp. 500-503, 1991. [MET99] IST-1999-11729 METRA, D2, MIMO channel characterisation, February 2001. Page 149 (167)
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WINNER D5.4 v. 1.4 IST-2003-507581
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WINNER D5.4 v. 1.4 Authors Partner
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WINNER D5.4 v. 1.4 Partner Name Pho
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WINNER D5.4 v. 1.4 4.3.2 Sum-of-Sin
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WINNER D5.4 v. 1.4 List of Acronyms
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WINNER D5.4 v. 1.4 PART I The deliv
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WINNER D5.4 v. 1.4 the models defin
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WINNER D5.4 v. 1.4 Figure 2.1: Layo
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WINNER D5.4 v. 1.4 2.1.7 Scenario D
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WINNER D5.4 v. 1.4 (dB) XPR H (dB)
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WINNER D5.4 v. 1.4 3.1.6.1 Scenario
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WINNER D5.4 v. 1.4 3.2.3.2 NLOS ZDS
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h WINNER D5.4 v. 1.4 the properties
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WINNER D5.4 v. 1.4 { } ( τφθϕϑ
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WINNER D5.4 v. 1.4 pdf as the doubl
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WINNER D5.4 v. 1.4 Depending on the
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WINNER D5.4 v. 1.4 A measurement ca
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WINNER D5.4 v. 1.4 Heigh_Gain dB =
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WINNER D5.4 v. 1.4 RX 1 RX module 1
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WINNER D5.4 v. 1.4 5.2.4 Scenario C
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WINNER D5.4 v. 1.4 Cumulative Proba
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WINNER D5.4 v. 1.4 (a) LOS (b) NLOS
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WINNER D5.4 v. 1.4 a Figure 5.49: P
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WINNER D5.4 v. 1.4 0.35 PDF 0.3 0.2
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