Abstract By using multiple antennas at both the transmit and receive sides, one obtains multiple eigenmodes (eigenchannels) on the same carrier through beamforming (precoding). With each eigenchannel represents an equivalent SISO channel, array gain is obtained by using only the strongest eigenmode but the capacity is maximized by allocate the transmit power across subchannels according to the water-filling result. The orthogonal frequency division multiplexing (OFDM) scheme divide a wideband channel into parallel narrowband subchannels so that signals propagate through each subchannel suffer from frequency nonselective fading. The OFDM-based multiple access (OFDMA) scheme has been shown to be capable of achieving the maximum spectral efficiency with extremely high probability. A key ingredient of an OFDMA system is that it can exploit the diversity offered by the time-varying and user(location)-dependent nature of the subchannels via proper scheduling and power/subchannel allocation. Hence a MIMO-OFDMA system is expected to offer high capacity through an efficient use of the spectral, spatial and user domain resources. The main design issue we try to solve in this thesis is the following. Given the users’ rate requirements of a MIMO-OFDMA system, how to apportion the transmission resources in space, frequency, and user domains so that the total transmit power and each user’s average bit error rate are minimized. We first consider two orthogonal precoding schemes based on singular value decomposition (SVD). In the first design we construct orthogonal eigenchannels by performing linear operations on the channel matrix’s singular vectors under the channel rank constraint. To improve spectral efficiency, we then remove the rank constraint on the number of users allowed on a subcarrier. Although the resulting co-channel interference may cause performance degradation, it is more than compensated for by the increased capacity through a proper RA plan that ensure the associated signal-to-interference ratios are within the tolerable limits. The proposed RA algorithms for both precoding scenarios are designed to minimize the total transmit power while satisfying the users’ QoS constraints. Finally, we examine the resource allocation (RA) issue for MIMO systems with limited feedback. More specifically, we consider the codebook based precoding scheme and suggest subcarrier assignment scheme based on the Lagrange multiplier method. For a given subcarrier assignment, we then present a power allocation method which minimizes the average bit error rate performance.