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Joint transmit/receive one-tap minimum mean square error frequency-domain equalisation for broadband multicode direct-sequence code division multiple access

Joint transmit/receive one-tap minimum mean square error frequency-domain equalisation for broadband multicode direct-sequence code division multiple access

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© The Institution of Engineering and Technology
Published

Multicode direct-sequence code division multiple access (DS-CDMA) can flexibly support multimedia services with various data rates simply by changing the code multiplexing order. The use of simple one-tap frequency-domain equalisation (FDE) at a receiver is known to improve the bit error rate (BER) performance of multicode DS-CDMA in a severe frequency-selective fading environment. However, the BER performance improvement is limited due to the presence of the residual inter-chip interference (ICI). The authors propose a joint transmit/receive minimum mean square error (MMSE) FDE, which carries out one-tap transmit FDE and one-tap receive FDE jointly based on the MMSE criterion. The authors theoretically derive a suboptimal set of transmit and receive FDE weights and investigate the BER performance improvement by computer simulation in a freqeuncy-selective Rayleigh fading channel. The proposed scheme improves the received signal-to-interference plus noise ratio after despreading, and consequently, the BER performance can be significantly improved compared to the conventioal receive MMSE-FDE by (a) making the variations in the equivalent channel gain shallower to reduce the residual ICI for large code multiplexing order U and (b) allocating the transmit power to the frequencies having good condition to improve the received signal-to-noise ratio for a small U. This is conformed by the computer simualtion.

Inspec keywords: digital simulation; interference (signal); code division multiple access; multimedia communication; broadband networks; Rayleigh channels; code division multiplexing

Other keywords: bit error rate; signal-to-interference plus noise ratio; multimedia services; joint transmit-receive minimum mean square error; multicode DS-CDMA; receive one-tap minimum mean square error frequency-domain equalisation; BER performance; computer simulation; freqeuncy-selective Rayleigh fading channel; inter-chip interference; large code multiplexing order; broadband multicode direct-sequence code division multiple access; frequency-selective fading environment

Subjects: Multimedia communications; Multiple access communication; Radio links and equipment; Electromagnetic compatibility and interference

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