In this dissertation, selection diversity in both transmitter and users for multiuser MIMO (MU-MIMO) systems is considered. In the transmitter, transmit antenna selection for linearly precoded MU-MIMO systems is investigated. In some precoded single-user MIMO systems, using all transmit antennas does not always lead to the best performance due to ill-conditioned channel matrix. This motivates us to investigate whether similar result can be obtained in MU-MIMO systems. From the derived analytical results, it was found that for a given number of transmit antennas, decreasing the number of active transmit antennas (number of RF units) always degrades system performance in the linearly precoded MU-MIMO systems. The performance loss due to transmit antenna selection is further analyzed. These analytical results provide good design references for using transmit antenna selection in practical systems. Moreover, based on the analytical results, several simple transmit antenna selection algorithms for linearly precoded MU-MIMO systems are proposed. Complexity analysis and simulation results show that the computational complexity of the proposed algorithms can be significantly reduced while the performance is still comparable to the optimal selection scheme. As a result, the analyzed results enable us to better understand how transmit antenna selection affects the MU-MIMO systems; also, the proposed algorithms make transmit antenna selection more feasible to be used in practical systems. In the user terminals, user selection for zero-forcing precoded MU-MIMO systems is considered in both full and partial CSI (channel state information) environments. A greedy-based user selection algorithm using a sum throughput criterion is proposed to avoid exhaustive search. By analyzing the performance of the proposed algorithm, an equivalent design criterion is derived and a fast algorithm without degrading the performance is proposed for further reducing the computational complexity. Moreover, in the partial CSI environments, it is found that maximizing the received signal power for each user plays an important role in maximizing the sum throughput. Then, it is shown that the received signal power can be maximized if the codebooks as well as the precoders are designed using groups of unitary matrices. From the results, it is suggested that how to construct the codebooks for practical systems. Furthermore, a fair user scheduling algorithm is proposed based on the proposed user selection algorithms and codebook designs for achieving good trade-off between fairness and system performance. Simulation results show that the proposed user selection algorithms, codebook designs and user scheduling outperform conventional schemes in both full and partial CSI environments.