In wireless communication, many researchers and engineers chase low detection complexity solutions. However, many such solutions trade performance for possible complexity reduction. In this dissertation, high DMT performance and low detection complexity transmission designs in both single user and multi-user, multiple-input-multiple-output (MIMO) communications are proposed. Firstly, in single-user MIMO system, linear receivers are often of more practical interest than maximum likelihood (ML) receivers, but at a cost of much worse diversity gain performance. Such statement on performance loss is due to the assumption of using an independent and identically distributed (i.i.d.) complex Gaussian vector as channel input. By removing this assumption, we find that the diversity performance of MIMO linear receivers can be significantly improved. In an extreme case, the maximum diversity gain can be the same as that of ML receivers. Specifically, in this dissertation we investigate the diversity multiplexing tradeoff (DMT) performance of MIMO linear receivers with colored and possibly degenerate Gaussian channel inputs. By varying the rank of the covariance matrix of the channel input vector and by allowing temporal coding across multiple channel uses, we show that the MIMO linear receiver can achieve a much better DMT performance than the currently known. Explicit optimal code constructions are also provided, along with simulation results to justify the above findings. For the case of (2 x 2) and (3 x 3) MIMO linear receivers, simulation results show that the newly proposed lattice space-time codes provide significant gains of 26.5 dB and 29.6 dB in E_b/N_0 at bit error rate 10^{-6}, compared to the conventional schemes, respectively. Secondly, in MIMO-multiple-access channel (MAC), the base station has less number of receive antennas than the total number of transmit antennas of all users, sphere (lattice) decoding for the existing MIMO-MAC codes requires an exhaustive search of exponentially large size before it can process the root node in sphere-decoding tree. In this dissertation, two coding schemes are proposed and are shown to have a constant sphere-decoding complexity, independent of the number of users as well as the number of transmit antennas. The schemes require a channel feedback, but at an extremely low rate. The first scheme is based on user selection, and the second scheme selects jointly the users and transmit antennas, using a fast antenna selection algorithm proposed by Jiang and Varanasi. It also requires an additional design of rate-assignments that maximizes the overall DMT performance. It is shown that both schemes yield DMT performances far superior to the optimal MIMO-MAC DMT without channel feedback. In the case of ten-user MIMO MAC, each with single antenna and two antennas at base station, simulation result confirms that the first proposed scheme and the second proposed scheme can provide an astonishing SNR gain of 2.8 dB and 14.5 dB at outage probability 10^{-6} compared to the optimal coding schemes without feedback, respectively.