Title :
Simulation of the achievable indoor MIMO capacity by using an adaptive phased-array
Author :
Elnaggar, Michel S. ; Safavi-Naeini, Safieddin ; Chaudhuri, Sujeet K.
Author_Institution :
Dept. of Electr. & Comput. Eng., Waterloo Univ., Ont., Canada
Abstract :
For a scenario-specific (4,4) multiple-input-multiple-output (MIMO) system in a corridor, we predict the channel matrix between the transmit and receive ports through image ray tracing (IRT) simulations. The physical arrays at the transmit/receive ends are 4 linear equally spaced λ/2-dipoles (vertically polarized, horizontally arranged and λ/2 separated) connected to the transmit/receive ports either directly (separate λ/2-dipole patterns) or through a static/adaptive beamforming network (collocated patterns). For collocated radiation, we use either static patterns (Butler beamformer) or adaptive patterns (collocated phased-array). Accordingly, we show the capacity improvement through adaptive patterns assuming a narrow-band frequency-flat channel (2.4 GHz operating frequency) for each scenario.
Keywords :
MIMO systems; UHF antennas; adaptive antenna arrays; antenna feeds; antenna phased arrays; antenna radiation patterns; array signal processing; channel capacity; dipole antenna arrays; electromagnetic wave polarisation; indoor radio; multipath channels; ray tracing; receiving antennas; transmitting antennas; 2.4 GHz; Butler beamformer; adaptive beamforming network; adaptive patterns; adaptive phased-array; channel matrix; collocated patterns; collocated phased-array; dipole arrays; image ray tracing; indoor MIMO channel capacity; multipath channels; multiple-input-multiple-output system; narrow-band frequency-flat channel; static beamforming network; static patterns; Adaptive arrays; Computational modeling; Electromagnetic propagation; Frequency; MIMO; Phased arrays; Polarization; Ray tracing; Reflection; Solid modeling;
Conference_Titel :
Radio and Wireless Conference, 2004 IEEE
Print_ISBN :
0-7803-8451-2
DOI :
10.1109/RAWCON.2004.1389096
