Recently, spatial modulation (SM) has been developed to improve the performance of multi-antenna systems. Several SM techniques, for example, space shift keying, generalized spatial modulation, and spatially modulated-MIMO (SM-MIMO), have been proposed. In this thesis, we consider low-complexity receiver designs in SM-MIMO systems. As well-known, the optimum receiver is the maximum likelihood (ML) receiver. However, also well-known, the computational complexity of the ML receiver can be prohibitively high. In this thesis, we propose two new algorithms, referred to as Gaussian approximation and QR-projection, to solve this problem. The main idea is to split the detection into two-stage, antenna index and symbol, and apply some dimension reduction techniques. There two methods are also extended to conduct soft-demapping in coded SM-MIMO systems. Simulations show that the performance of the proposed methods is similar to that of the ML receiver, while the computational complexity can be reduced by 90%, facilitating the real-world applications of the SM-MIMO systems.