Enhancing wireless communication system performance through modified indoor environments

This thesis reports the methods, the deployment strategies and the resulting system performance improvement of in-building environmental modification. With the increasing use of mobile computing devices such as PDAs, laptops, and the expansion of wireless local area networks (WLANs), there is growing interest in increasing productivity and efficiency through enhancing received signal power. This thesis proposes the deployment of waveguides consisting of frequency selective surfaces (FSSs) in indoor wireless environments and investigates their effect on radio wave propagation. The received power of the obstructed (OBS) path is attenuated significantly as compared with that of the line of sight (LOS) path, thereby requiring an additional link budget margin as well as increased battery power drain. In this thesis, the use of an innovative model is also presented to selectively enhance radio propagation in indoor areas under OBS conditions by reflecting the channel radio signals into areas of interest in order to avoid significant propagation loss. An FSS is a surface which exhibits reflection and/or transmission properties as a function of frequency. An FSS with a pass band frequency response was applied to an ordinary or modified wall as a wallpaper to transform the wall into a frequency selective (FS) wall (FS-WALL) or frequency selective modified wall (FS-MWALL). Measurements have shown that the innovative model prototype can enhance 2.4GHz (IEEE 802.11b/g/n) transmissions in addition to the unmodified wall, whereas other radio services, such as cellular telephony at 1.8GHz, have other routes to penetrate or escape. The FSS performance has been examined intensely by both equivalent circuit modelling, simulation, and practical measurements. Factors that influence FSS performance such as the FSS element dimensions, element conductivities, dielectric substrates adjacent to the FSS, and signal incident angles, were investigated. By keeping the elements small and densely packed, a largely angle-insensitive FSS was developed as a promising prototype for FSS wallpaper. Accordingly, the resultant can be modelled by cascading the effects of the FSS wallpaper and the ordinary wall (FSWALL) or modified wall (FS-MWALL). Good agreement between the modelled, simulated, and the measured results was observed. Finally, a small-scale indoor environment has been constructed and measured in a half-wave chamber and free space measurements in order to practically verify this approach and through the usage of the deterministic ray tracing technique. An initial investigation showing that the use of an innovative model can increase capacity in MIMO systems. This can be explained by the presence of strong multipath components which give rise to a low correlated Rayleigh Channel. This research work has linked the fields of antenna design, communication systems, and building architecture.

[1]  J. Tarng,et al.  Three-dimensional modeling of 900-MHz and 2.44-GHz radio propagation in corridors , 1997 .

[2]  Indoor signal focusing by means of Fresnel zone plate lens attached to building wall , 2004, IEEE Transactions on Antennas and Propagation.

[3]  Nidal Qasem,et al.  Indoor band pass frequency selective wall paper Equivalent Circuit & ways to enhance wireless signal , 2011, 2011 Loughborough Antennas & Propagation Conference.

[4]  M. Norton Microwave System Engineering Using Large Passive Reflectors , 1962 .

[5]  Davood Molkdar,et al.  Review on radio propagation into and within buildings , 1991 .

[6]  D.C. Cox,et al.  UHF propagation in indoor hallways , 2003, IEEE International Conference on Communications, 2003. ICC '03..

[7]  S. Loredo,et al.  Accuracy analysis of GO/UTD radio-channel modeling in indoor scenarios at 1.8 and 2.5 GHz , 2001 .

[8]  Yuji Maeda,et al.  Experimental investigation of controlling coverage of wireless LAN by using partitions with absorbing board , 1999, 1999 International Symposium on Electromagnetic Compatibility (IEEE Cat. No.99EX147).

[9]  Henry L. Bertoni,et al.  Radio Propagation for Modern Wireless Systems , 1999 .

[10]  Jonas Medbo,et al.  Spatio-temporal channel characteristics at 5 GHz in a typical office environment , 2001, IEEE 54th Vehicular Technology Conference. VTC Fall 2001. Proceedings (Cat. No.01CH37211).

[11]  H. Bertoni,et al.  Transmission and reflection characteristics at concrete block walls in the UHF bands proposed for future PCS , 1994 .

[12]  M. Philippakis,et al.  Application of FSS Structures to Selectively Control the Propagation of signals into and out of buildings Annex 3: Enhancing propagation Into buildings , 2004 .

[13]  Edward A. Parker,et al.  Fields in an FSS screened enclosure , 2004 .

[14]  A. Kajiwara,et al.  Millimeter-wave indoor radio channel with artificial reflector , 1997 .

[15]  A. Newbold Designing buildings for the wireless age , 2004 .

[16]  Jonas Medbo,et al.  A simple approach to site sensitive modeling of indoor radio propagation , 2002, Vehicular Technology Conference. IEEE 55th Vehicular Technology Conference. VTC Spring 2002 (Cat. No.02CH37367).

[17]  Akihiro Kajiwara Circular polarization diversity with passive reflectors in indoor radio channels , 2000, IEEE Trans. Veh. Technol..

[18]  Iñigo Cuiñas,et al.  Wide-band measurements of nondeterministic effects on the BRAN indoor radio channel , 2004, IEEE Transactions on Vehicular Technology.

[19]  Christodoulou Antennas and Propagation for Wireless Communication , 2006 .

[20]  Henry L. Bertoni,et al.  Mechanisms governing UHF propagation on single floors in modern office buildings , 1992 .

[21]  Björn Widenberg,et al.  Design of Energy Saving Windows with High Transmission at 900 MHz and 1800 MHz , 2002 .

[22]  R.L. Hamilton,et al.  Ray tracing as a design tool for radio networks , 1991, IEEE Network.

[23]  C. Banerjee,et al.  Four-frequency radiowave propagation measurements of the indoor environment in a large metropolitan commercial building , 1991, IEEE Global Telecommunications Conference GLOBECOM '91: Countdown to the New Millennium. Conference Record.

[24]  Rolf Jakoby,et al.  Single-cell coverage prediction of LMDS including passive reflectors , 2001 .

[25]  Y. Serizawa,et al.  Multipath propagation effects on digital radio equipped with a plane reflector repeater , 1992 .

[26]  Yanwei Wang,et al.  The importance of the multipoint-to-multipoint indoor radio channel in ad hoc networks , 2002, 2002 IEEE Wireless Communications and Networking Conference Record. WCNC 2002 (Cat. No.02TH8609).

[27]  D.C. Kemp,et al.  Enhancing radio coverage inside buildings , 2005, 2005 IEEE Antennas and Propagation Society International Symposium.

[28]  YAS Dama,et al.  MIMO indoor propagation prediction using 3D shoot-and-bounce ray (SBR) tracing technique for 2.4 GHz and 5 GHz , 2011, Proceedings of the 5th European Conference on Antennas and Propagation (EUCAP).

[29]  Hyun Kyu Chung,et al.  Indoor propagation characteristics at 5.2GHz in home and office environments , 2002, Journal of Communications and Networks.

[30]  Iñigo Cuiñas,et al.  Measuring, modeling, and characterizing of indoor radio channel at 5.8 GHz , 2001, IEEE Trans. Veh. Technol..

[31]  T. Manabe,et al.  Measurements of reflection and transmission characteristics of interior structures of office building in the 60-GHz band , 1997 .

[32]  Theodore S. Rappaport,et al.  Site-specific propagation prediction for wireless in-building personal communication system design , 1994 .