Blind PARAFAC receivers for DS-CDMA systems

Author

Sidiropoulos, Nicholas D. ; Giannakis, Georgios B. ; Bro, Rasmus

Volume

48

Issue

3

fYear

2000

fDate

3/1/2000 12:00:00 AM

Firstpage

810

Lastpage

823

Abstract

This paper links the direct-sequence code-division multiple access (DS-CDMA) multiuser separation-equalization-detection problem to the parallel factor (PARAFAC) model, which is an analysis tool rooted in psychometrics and chemometrics. Exploiting this link, it derives a deterministic blind PARAFAC DS-CDMA receiver with performance close to non-blind minimum mean-squared error (MMSE). The proposed PARAFAC receiver capitalizes on code, spatial, and temporal diversity-combining, thereby supporting small sample sizes, more users than sensors, and/or less spreading than users. Interestingly, PARAFAC does not require knowledge of spreading codes, the specifics of multipath (interchip interference), DOA-calibration information, finite alphabet/constant modulus, or statistical independence/whiteness to recover the information-bearing signals. Instead, PARAFAC relies on a fundamental result regarding the uniqueness of low-rank three-way array decomposition due to Kruskal (1977, 1988) (and generalized herein to the complex-valued case) that guarantees identifiability of all relevant signals and propagation parameters. These and other issues are also demonstrated in pertinent simulation experiments

Keywords

array signal processing; blind equalisers; code division multiple access; digital simulation; direction-of-arrival estimation; least mean squares methods; multiuser channels; radio receivers; signal detection; signal sampling; spread spectrum communication; DOA estimation; DS-CDMA systems; MMSE; antenna array; blind signal separation; chemometrics; code diversity-combining; deterministic blind PARAFAC receivers; direct-sequence code-division multiple access; low-rank three-way array decomposition; multiuser separation-equalization-detection; nonblind minimum mean-squared error; parallel factor model; performance; propagation parameters; psychometrics; sensors; simulation experiments; small sample sizes; spatial diversity-combining; temporal diversity-combining; Antenna arrays; Antennas and propagation; Calibration; Direct-sequence code-division multiple access; Frequency estimation; Interference; Multiaccess communication; Psychometric testing; Sensor arrays; Signal processing;

fLanguage

English

Journal_Title

Signal Processing, IEEE Transactions on

Publisher

ieee

ISSN

1053-587X

Type

jour

DOI

10.1109/78.824675

Filename

824675