Abstract
The implementation of efficient baseband receivers characterized by affordable computational load is a crucial point in the development of transmission systems exploiting diversity in different domains. This would be a crucial point in the future development of 4G systems, where space, time, and frequency diversity will be combined together in order to increase system throughput. In this framework, a linear multiuser detector for MC-CDMA systems with Alamouti's Space-Time Block Coding (STBC), which is inspired by the concept of Minimum Conditional Bit Error Rate (MCBER), is proposed. The MCBER combiner has been implemented in adaptive way by using Least-Mean-Square (LMS) optimization. The estimation of Channel State Information (CSI), necessary to make practically feasible the MCBER detection, is aided by a Genetic Algorithm (GA). The obtained receiver scheme is near-optimal, as both LMS-based MCBER and GA-assisted channel estimation perform closely to optimum in fulfilling their respective tasks. Simulation results evidenced that the proposed receiver always outperforms state-of-the-art receiver schemes based on EGC and MMSE criterion exploiting the same degree of channel knowledge.
Highlights
Future mobile communications standards will be required to provide high performance in terms of data rate, capacity, and quality of service
The performances of the proposed Space-Time Block Coding (STBC) Multicarrier CDMA (MC-CDMA) receiver are evaluated by means of intensive simulation trials in a Rayleigh fading channel fixing the following parameters: number of subcarriers N = 8, transmission data rate rb = 1024 Kb/s, coherence bandwidth of the channel 2.1 MHz, and Doppler spread of the channel 100 Hz
We considered two test cases: the most theoretical case related to the Minimum Conditional Bit Error Rate (MCBER) detector exploiting the ideal Channel State Information (CSI) knowledge and the more realistic case related to the MCBER detector supported by the Genetic Algorithm (GA)-assisted channel estimation
Summary
Future mobile communications standards will be required to provide high performance in terms of data rate, capacity, and quality of service. For this reason, the efficient exploitation of diversity in different domains (time, space, frequency) will be an issue. Multicarrier modulations [1] and Multiple-Input Multiple-Output (MIMO) space-time coding [2] are among the enabling technologies of future diversity-based highcapacity wireless communications. OFDM and OFDMA apparently dominate the panorama of multicarrier modulations in wireless standards. In these last years, the spread-spectrum extension of OFDM, namely, Multicarrier CDMA (MC-CDMA), is raising a renewed interest. The adoption of lowcomplexity multiuser detection makes MC-CDMA a valuable competitor with OFDMA with some clear advantages in terms of anti-multipath resilience, in particular in mobile
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