Wireless Network Design: Optimization Models and Solution ...

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3 Channel Models for Wireless Communication Systems 61 3.5.2.6 Indoor Models Based on Measurement Data The clustering model is applied to the indoor environment and validated with measurements [37, 41]. The channel response is given by h(t) = ∞ ∞ ∑ ∑ k=0 l=0 αkl δ(t − τkl − Tk) (3.27) where k denotes the cluster, l denotes the ray within a cluster, and αkl is a Rayleigh distributed random variable. An extension to this model was proposed in [37]. Here, h(t, θ) = h(t)h(θ) with the assumption that temporal and angular impulse responses are independent. The angular impulse response is given by h(θ) = ∞ ∞ ∑ ∑ k=0 l=0 αkl δ(t − ωkl −Θk) (3.28) with ωkl is the ray angle and Θk is the mean angle of the kth cluster. The probability density function of ωkl is given by f (ω) = (1/2 √ σ exp(−| √ 2ω/σ|)) The Time- Angle FIR filter model [20] defines the channel impulse response as h(t,τ,θ) = Q ∑ q=1 αqδ(t − τq)δ(θ − θq) (3.29) where the FIR structure has Q taps. This is a simple extension of the temporal FIR model presented before. 3.6 Conclusion The wireless channel models presented in previous sections are used for designing highly efficient communication systems which can provide huge data rates. The statistical nature of these models provides a means to cover most of the possible scenarios in the real-world through an exhaustive numerical simulation study. The choice of models is varied and an appropriate choice of the model can be made based on the specifications of the wireless system to be designed. This chapter provides a brief introduction to this topic of wireless channel models which have been used to design the present digital wireless communication systems. References 1. Digital Land Mobile Radio Communications - COST 207”, Commission of the European Communities, Final Report. Commission of the European Communities, Final Report, 14
62 K. V. S. Hari March, 1984–13 September, 1988, Office for Official Publications of the European Communities, Luxembourg (1989) 2. EURO-COST-231 Revision 2, Urban transmission loss models for mobile radio in the 900 and 1800 MHz bands. Commission of the European Communities, Office for Official Publications of the European Communities, Luxembourg (1991) 3. Adachi, F., Feeney, M., Parsons, J., Williamson, A.: Crosscorrelation between the envelopes of 900 MHz signals received at a mobile radio base station site. In: IEE Proceedings F Communications, Radar and Signal Processing, vol. 133, pp. 506–512 (1986) 4. Asztély, D.: On antenna arrays in mobile communication systems: Fast fading and GSM base station receiver algorithms. Ph.D Thesis, Royal Institute of Technology, Stockholm, Sweden, IR-S3-SB-9611 (1996) 5. Bajwa, A., Parsons, J.: Large area characterization of urban UHF multipath propagation and its relevance to the performance bounds of mobile radio systems. IEE Proceedings on Communications, Radar and Signal Processing 132(2 Part F), 99–106 (1985) 6. Blanz, J., Klein, A., Mohr, W.: Measurement-based parameter adaptation of wideband spatial mobileradio channel models. In: IEEE 4th International Symposium on Spread Spectrum Techniques and Applications Proceedings, 1996., vol. 1 (1996) 7. Clarke, R.: A statistical theory of mobile-radio reception. Bell Syst. Tech. J 47(6), 957–1000 (1968) 8. Cox, D., Leck, R.: Distributions of multipath delay spread and average excess delay for 910- MHz urban mobile radio paths. IEEE Transactions on Antennas and Propagation 23(2), 206– 213 (1975) 9. Devasirvatham, D.: A comparison of time delay spread and signal level measurements within two dissimilar office buildings. IEEE Transactions on Antennas and Propagation 35(3), 319– 324 (1987) 10. Durgin, G.: Space-Time Wireless Channels. Prentice Hall PTR, NJ, USA (2003) 11. Erceg, V., Hari, K. V. S., Smith, M., Baum, D., Sheikh, K., Tappenden, C., Costa, J., Bushue, C., Sarajedini, A., Schwartz, R., Branlund, D., Kaitz, T., D., T.: Channel Models for Fixed Wireless Applications. IEEE 802.16 Standards (2001) 12. Ertel, R.: Vector channel model evaluation. SW Bell Tech. Res., Tech. Rep (1997) 13. Ertel, R., Cardieri, P., Sowerby, K., Rappoport, T., Reed, J.: Overview of Spatial Channel Models for Antenna Array Communication Systems. IEEE Personal Communications magazine pp. 10–22 (1998) 14. Feuerstein, M., Blackard, K., Rappaport, T., Seidel, S., Xia, H.: Path loss, delay spread, and outage models as functions of antennaheight for microcellular system design. IEEE Transactions on Vehicular Technology 43(3 Part 1), 487–498 (1994) 15. Fuhl, J., Rossi, J., Bonek, E.: High-resolution 3-D direction-of-arrival determination for urbanmobile radio. IEEE Transactions on Antennas and Propagation 45(4), 672–682 (1997) 16. Gans, M.: A power-spectral theory of propagation in the mobile-radio environment. IEEE Transactions on Vehicular Technology 21(1), 27–38 (1972) 17. Greenstein, L., Erceg, V., Yeh, Y., Clark, M.: A new path-gain/delay-spread propagation model for digital cellularchannels. IEEE Transactions on Vehicular Technology 46(2), 477–485 (1997) 18. Hari, K. V. S., Ottersten, B.: Parameter Estimation using a Sensor Array in a Ricean Fading channe. Sadhana, Journal of Indian Academy of Sciences 23(1), 5–15 (1998) 19. Hata, M.: Empirical formula for propagation loss in land mobile radio services. IEEE Transactions on Vehicular Technology 29(3), 317–325 20. Klein, A., Mohr, W.: A statistical wideband mobile radio channel model including the directions-of-arrival. In: IEEE 4th International Symposium on Spread Spectrum Techniques and Applications, pp. 102–06 (1996) 21. Kozono, S., Taguchi, A.: Mobile propagation loss and delay spread characteristics with a lowbase station antenna on an urban road. IEEE Transactions on vehicular technology 42(1), 103–109 (1993) 22. Lee, W.: Mobile communications engineering. McGraw-Hill, Inc. New York, NY, USA (1982)
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International Series in Operations
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Editors Jeff Kennington Eli Olinick
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vi Preface assistance. The work of
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viii Contents 3.4.1 Experiments to
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x Contents 8.3.2 The Solution Proce
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xii Contents References . . . . . .
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List of Contributors Khaldoun Al Ag
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List of Contributors xvii Nitin Sal
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Chapter 1 Introduction to Optimizat
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1 Introduction to Optimization in W
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1 Introduction to Optimization in W
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Part I Background
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112 Eli Olinick Using bk to denote
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114 Eli Olinick 5.3.5 Additional De
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116 Eli Olinick capacity, provide n
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118 Eli Olinick ficult optimization
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120 Eli Olinick and-bound so that t
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122 Eli Olinick solution times. Cai
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124 Eli Olinick 27. Glover, F.: Tab
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Chapter 6 Optimization Based WLAN M
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6 Optimization Based WLAN Modeling
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Chapter 7 Spectrum Auctions Karla H
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7 Spectrum Auctions 149 full value.
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7 Spectrum Auctions 151 also decide
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7 Spectrum Auctions 153 disclosed t
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7 Spectrum Auctions 171 bidder on a
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7 Spectrum Auctions 173 some discus
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7 Spectrum Auctions 175 21. Dunford
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Chapter 8 The Design of Partially S
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8 The Design of Partially Survivabl
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200 Khaldoun Al Agha and Steven Mar
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Chapter 10 Compact Integer Programm
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10 Integer Programming Models for P
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11 Improving Network Connectivity i
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296 Hang Jin and Li Guo formance in
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300 Hang Jin and Li Guo ARQ (HARQ)
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302 Hang Jin and Li Guo 13.3 Radio
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304 Hang Jin and Li Guo Table 13.2
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306 Hang Jin and Li Guo is transmit
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308 Hang Jin and Li Guo uplink powe
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310 Hang Jin and Li Guo The link ad
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314 Hang Jin and Li Guo 13.4.4.3 Ex
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318 Hang Jin and Li Guo 1. Guarante
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14 Cross Layer Scheduling in Wirele
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15 Major Trends in Cellular Network
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