The multiple-input multiple output (MIMO) technology promises significant capacity increase over conventional single-input single-output systems. Most investigations on MIMO signal detection, however, assume perfect channel state information (CSI), which is difficult, if not impossible, to realize in practice. Earlier studies have shown that that the performance of MIMO detection schemes will suffer from severe degradation in the presence of channel estimation errors. In this thesis, the effects of imperfect CSI on two MIMO signal detectors, namely, the Particle-Swarm-Driven Cross-Entropy (PSD-CE) based detector and the QRD-$M$ detector, are studied, and new detector structures that take into account the CSI error are proposed. The PSD-CE detector tries to estimate and refine the `a posteriori probability distribution' of the transmitted signal location given the received vector. The distribution is estimated by sampling over the neighborhood of the received vector and is iteratively updated to the one which has the minimum cross entropy with respect to the current distribution. It is further modified by applying the concept of Particle Swarm Optimization to render a mixture of probability distribution. QRD-M, on the other hand, is an efficient tree-search based detector. It prunes the earch tree to reduce the number of surviving paths with minimum performance loss. Since the minimum Euclidean distance criterion is no longer suitable for both detectors in the presence of channel estimation errors, the proposed MIMO detectors take into account the imperfect CSI effect by averaging the estimation errors to obtain a new decoding metric. Numerical examples are given to demonstrate the performance improvement which is attained with insignificant complexity increase.