Title :
2D-RAKE MMSE receiver for burst communications through multiple-access shallow-water channels
Author :
Tsimenidis, C.C. ; Hinton, O.R. ; Sharif, B.S. ; Adams, A.E.
Author_Institution :
Underwater Acoust. Group, Newcastle upon Tyne Univ., UK
Abstract :
This paper suggests a spread-spectrum based receiver architecture that employs both spatial diversity and RAKE reception, in order to achieve reliable communications through multiple-access shallow-water acoustic channels. The key idea is to improve system performance by exploiting the multipath profile and combining, rather than canceling, the energy arriving at the receiver via bottom and surface reflections. The optimization of the receiver parameters is achieved by employing the minimum mean-square error (MMSE) criterion. Results indicate that the suggested receiver algorithm can dramatically reduce the number of receive elements required without any significant loss in performance. However, this is achieved at the cost of increased computational complexity
Keywords :
acoustic arrays; acoustic receivers; acoustic wave reflection; code division multiple access; diversity reception; least mean squares methods; multipath channels; multiuser channels; spread spectrum communication; underwater acoustic communication; underwater acoustic propagation; 2D-RAKE MMSE receiver; DS-CDMA; MMSE; RAKE reception; adaptive-array receiver structure; bottom reflections; computational complexity; minimum mean-square error; multipath profile; multiple-access shallow-water acoustic channels; multiple-access shallow-water channels; protocols; receiver algorithm; receiver parameters optimization; spatial diversity; spatial diversity combining; spread-spectrum based receiver architecture; surface reflections; system performance; Acoustic propagation; Attenuation; Bandwidth; Delay; Fading; Frequency; Multiaccess communication; RAKE receivers; Spread spectrum communication; Underwater acoustics;
Conference_Titel :
OCEANS, 2001. MTS/IEEE Conference and Exhibition
Conference_Location :
Honolulu, HI
Print_ISBN :
0-933957-28-9
DOI :
10.1109/OCEANS.2001.968336
