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Optimisation of radio coverage in urban microcells using a UTD based ray-tracing model

Optimisation of radio coverage in urban microcells using a UTD based ray-tracing model

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In cellular communications, requirements for increased system capacity, improved coverage, better quality and reduced transmitter power, along with the need to rationalise cellular system planning, have prompted a considerable interest in the development of valid and efficient radiowave propagation models. This work utilises recent advances that improve the accuracy and efficiency of ray-tracing models, using a three-dimensional representation of the terrain and urban topographies, in conjunction with adaptive and selective ray-tracing. These improvements allow utilisation of the field computation algorithms in the network design and radio coverage planning processes. They include optimum automated selection of base station locations and phased array excitation. A reliable ray-tracing scheme can be utilised directly in the optimum and, potentially, adaptive beamforming of base station antenna systems by interfacing field computations with design aims. The paper addresses a cellular planning process, which involves determination of the antenna array position and beam shape or, equivalently, the array excitation coefficients, for a desired power distribution over the defined cell area.

Inspec keywords: antenna phased arrays; geometrical theory of diffraction; ray tracing; microcellular radio; optimisation; radiowave propagation

Other keywords: terrain three-dimensional representation; antenna array position; radio coverage optimisation; ray-tracing model; cellular communications; array excitation coefficients; optimum automated selection; phased array excitation; uniform geometrical theory of diffraction; base station locations; radiowave propagation models; UTD; urban microcells; cellular system planning; field computation algorithms

Subjects: Antenna arrays; Optimisation techniques; Radiowave propagation; Mobile radio systems

References

    1. 1)
      • Norbury, J.R., Craig, K.H.: `The development of cellular radio access for broadband services (CRABS)', Conf. on Fixed wireless access, October 1997, London Visions in Business.
    2. 2)
    3. 3)
      • Al-Nuaimi, M.O., Richter, J., Ivrissimtzis, L.: `Optimisation of urban radio coverage using adaptive antenna excitation linked to radio site topography', europ. Conf. on fixed radio systems and networks, ECRR 2000, September 2000, Dresden, Germany.
    4. 4)
      • G.V. Tsoulos , G.E. Athanasiadou . On the application of adaptive antennas to microcellular environments: radio channel characteristics and system performance. IEEE Trans on Veh. Techol. , 1
    5. 5)
      • F. Ikegami , T. Takeuchi , S. Yoshida . Theoretical prediction of mean field strength for urban mobile radio. IEEE Trans. Antennas Propag. , 3 , 229 - 302
    6. 6)
    7. 7)
      • P.R. Rousseau , P.H. Pathak . Time-domain uniform geometrical theory of diffraction for a curved wedge. IEEE Trans. Antennas Propag. , 12 , 1375 - 1382
    8. 8)
      • Richter, J., Al-Nuaimi, M.O., Ivrissimtzis, L.: `Improved efficiency of urban microcells by topography dependent control of base station antenna radiation characteristics', Int. Conf. on Mobile propagation, EPMCC 2001, February 2001, Vienna, Austria.
    9. 9)
    10. 10)
    11. 11)
      • G.V. Tsoulos , G.E. Athanasiadou , R.J. Piechocki . Low-complexity smart antenna methods for third generation W-CDMA systems. IEEE Trans. on Veh. Technol. , 6 , 2382 - 2396
    12. 12)
      • Kouyoumjian, R.G., Pathak, P.H.: `A uniform geometrical theory of diffraction for an edge in perfectly conducting surface', Proc. IEEE, 1974, p. 1448–1461.
    13. 13)
    14. 14)
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