Coherent Receiver Antenna Diversity Research Articles

A Generalized View on Multicarrier CDMA Mobile Radio Systems with Joint Detection (Part II)

This communication presents a generalized view on multicarrier code division multiple access (MC-CDMA) concepts for mobile radio applications. A comprehensive introduction to CDMA and the arising multiple access interference (MAI) will be presented. It will be explained why joint detection (JD) is a mandatory prerequisite for hybrid frequency and time divided code division multiple access (F/T/CDMA) which is a viable basis for third generation mobile radio systems. The benefits of MC-CDMA over other CDMA concepts will be discussed in an illustrative manner and a flexible MC-CDMA concept will be introduced and explained in detail. The signal generation in MC-CDMA will be described in continuous-time and discrete-time form revealing the close relationship between the presented flexible MC-CDMA and the well known joint detection CDMA (JD-CDMA) concept. The discrete-time transmission model which results from the continuous-time representation will be introduced to facilitate digital signal processing. This transmission model takes coherent receiver antenna diversity (CRAD) explicitly into account. Four viable JD techniques suitable for the discussed flexible MC-CDMA concept will be presented. Their structure and mode of operation will be explained in detail and their uplink performance will be studied in a variety of transmission conditions.

On Multicarrier Detection and Coherent CDMA Mobile Receiver Radio Systems with Joint Antenna Diversity

The combination of code division multiple access(CDMA) and multicarrier (MC) transmission techniques,termed MC-CDMA, is considered a promising alternative toconventional DS (direct sequence)-CDMA. For this reason, recent research activities haveconcentrated on the application of MC-CDMA to mobileradio systems. In this paper an MC-CDMA concept which iswell suited for mobile radio applications is described. The described MC-CDMA concept overcomesdisadvantages of previously proposed concepts. InMC-CDMA mobile radio systems, signal reception isimpaired by time-varying multipath propagation. Theimpairments can be reduced by applying diversitytechniques. Coherent receiver antenna diversity (CRAD)is especially attractive because only the signalprocessing at the receivers must be modified. In thiscommunication, the application of CRAD in combination withjoint detection (JD) techniques to the more criticaluplink of MC-CDMA mobile radio systems is investigated.It is explained that the deployment of JD techniques for CRAD is an effective countermeasure againstthe influence of the mobile radio channel on the systemperformance. Four JD techniques for CRAD which areapplicable to MC-CDMA are presented. Their performances are studied in bad urban, typical urban, andtypical macrocellular environments. It is shown thatMC-CDMA allows a favorable performance compared to otherCDMA concepts.

Results on turbo-codes for speech transmission in a joint detection CDMA mobile radio system with coherent receiver antenna diversity

Turbo-codes which are applicable to speech transmission in digital mobile radio systems are treated. Three turbo-codes of different complexity are presented. The proposed turbo-codes are suitable for the application to speech transmission in the joint detection code-division multiple access (JD-CDMA) mobile radio system with coherent receiver antenna diversity (CRAD) which are described concisely. The performance of the designed turbo-codes in terms of bit and frame error rates are shown in the case of additive white Gaussian noise (AWGN) channels, flat Rayleigh fading channels, and in the uplink of the aforementioned JD-CDMA mobile radio system.

Joint detection with coherent receiver antenna diversity in CDMA mobile radio systems

In code division multiple access (CDMA) mobile radio systems, both intersymbol interference and multiple access interference arise which can be combated by using either elaborate optimum or favorable suboptimum joint detection (JD) techniques. Furthermore, the time variation of the radio channels leads to degradations of the receiver performance. These degradations can be reduced by applying diversity techniques. Using coherent receiver antenna diversity (CRAD) is especially attractive because only the signal processing at the receiver must be modified. In the present paper, the application of CRAD to the more critical uplink of CDMA mobile radio systems with suboptimum JD techniques is investigated for maximal-ratio combining. The authors study six different suboptimum JD techniques based on decorrelating matched filtering, Gauss-Markov estimation, and minimum mean square error estimation with and without decision feedback. These six suboptimum JD techniques which are well-known for single antenna receivers are extended for the application to CRAD. A main concern of the paper is the determining of the SNR performance of the presented JD techniques for CRAD and the achievable average uncoded bit error probabilities for the transmission over rural area, typical urban and bad urban mobile radio channels are determined.

Performance evaluation of a novel M-detector for coherent receiver antenna diversity in a GSM-type mobile radio system

Powerful adaptive detectors such as the maximum-likelihood (ML) detector based on the Viterbi algorithm (VA) are required at the receivers for GSM type mobile radio systems in order to combat the effect of frequency-selective fading radio channels. The use of diversity techniques like receiver antenna diversity leads to a further improvement of the receiver performance. Hence, ML detectors for coherent receiver antenna diversity (CRAD) have attracted the attention of many authors. However, the complexity of the defector for CRAD can be considerably decreased when the VA is replaced with the M-algorithm, which is a suboptimum tree search algorithm. In the course of this paper, the M-detector is extended to CRAD in the case of maximal-ratio combining (MRC), equal-gain combining (EGC), and selection combining (SC), and its performance in GSM type mobile radio systems is studied by simulations using the radio channel models rural area (RA), typical urban (TU), and bad urban (BU) specified by COST 207. It is demonstrated that this novel M-detector for CRAD can perform similarly to the ML detector for CRAD thus being a favorable alternative. >

Performance of a cellular hybrid C/TDMA mobile radio system applying joint detection and coherent receiver antenna diversity

For future mobile radio systems, an appropriately chosen multiple access technique is a critical issue. Multiple access techniques presently under discussion are code division multiple access (CDMA), time division multiple access (TDMA), and hybrids of both. In the paper, a hybrid C/TDMA system using joint detection (JD-C/TDMA) with coherent receiver antenna diversity (CRAD) at the base station (BS) receiver is proposed. Some attractive features of the JD-C/TDMA system are the possibility to flexibly offer voice and data services with different bit rates, soft capacity, inherent frequency and interferer diversity, and high system capacity due to JD. Furthermore, due to JD, a cluster size equal to 1 can be realized without needing soft handover. The single cell E/sub b//N/sub 0/ performance and the interference situation in a cellular environment of the uplink of a JD-C/TDMA mobile radio system with CRAD is investigated in detail. It is shown that the cellular spectrum efficiency is remarkably high, taking values up to 0.2 bit/s/Hz/BS in the uplink, depending on the actual transmission conditions. >

Simulation of the uplink of JD-CDMA mobile radio systems with coherent receiver antenna diversity

Due to time variant multipath propagation, both intersymbol interference and multiple access interference occur at CDMA receivers. These degrading effects can be combatted by joint detection (JD) techniques. In order to reduce the performance impairments resulting from time variance, coherent receiver antenna diversity (CRAD) can be used. In the present paper, a system model of CDMA mobile radio systems using various JD techniques in combination with CRAD shall be considered. This system model is an evolution of the pan-European GSM and takes important real world aspects such as imperfect channel estimation, nonlinear amplification and D/A and A/D conversion into account. The viability of JD with CRAD shall be demonstrated by bit error rate simulations of this system model. It is shown that by using JD with two receiver antennas in bad urban areas,Eb/N0 < 8 dB per antenna is sufficient for a bit error rate of 10−2, andEb/N0 < 11 dB per antenna is required for a bit error rate of 10−3.

Maximum-Likelihood Detector for Coherent Receiver Antenna Diversity

Maximum-Likelihood Detector for Coherent Receiver Antenna Diversity