The contradiction between the limited spectrum resource and ever-increasing user requirement lays the foundation of most researches in wireless communications. The exploration in the use of multiple antennas and orthogonal subcarriers for the last two decades have extended the spectrum efficiency to a great extent. Besides the pursuit for higher spectrum efficiency, it is sometimes more critical to leverage the limited resource flexibly and dynamically to properly match the constantly changing user requirements. For future mobile networks, some trends and their accompanied requirements can be foreseen, including: a) the use of massive antennas and the requirement for dynamic tradeoff between diversity and multiplexing gain; b) the emergence of massive user terminals, and the requirement for flexible scheduling of them; and c) the deployment of dense small cells, and the requirement for managing interference among them due to full frequency reuse. The limitation in spectrum resource gives rise to the exploitation in many other domains, such as subcarriers, users, and base stations (i.e. cells), and the coordination technologies in these domains are the focus of this dissertation. The dissertation includes three parts: • Multi-carrier coordination for diversity-multiplexing-tradeoff (DMT); • Multi-user coordination for virtual MIMO uplink; and • Multi-cell coordination for RAN enhancement. In the first part, we propose a new hybrid cyclic delay diversity (HCDD) scheme for multiple input multiple output (MIMO) orthogonal frequency division multiplexing (OFDM) systems. Unlike the existing double space time transmit diversity (DSTTD) and stacked cyclic delay diversity (SCDD) schemes suitable for integer multiplexing rates, the proposed HCDD scheme can achieve arbitrary non-integer multiplexing rates. Our results demonstrate that the HCDD scheme can provide flexibility in selecting the required number of transmitting antennas and in adjusting diversity and multiplexing gains to match various users requirements. The advantages of the proposed HCDD, including the flexible rate assignment and less complex receivers, are presented in applications of scalable video broadcasting (SVB). In the second part, we point out that although MIMO antenna systems can provide the spatial multiplexing gain to enhance spectrum efficiency, but they are hampered by the fact that the number of antennas in a hand-held mobile device is smaller than that of a base station. To overcome this issue, the virtual MIMO techniques coordinate a group of single-antenna mobile users to become a virtual multiple-antenna entity. However, existing virtual MIMO techniques are either applicable only to a small group or computationally too complex. In this part, we propose a low-complexity user scheduling for a virtual MIMO with a flexible group size. In comparison with existing approaches, our results show that the proposed user scheduling for virtual MIMO can reduce the floating operations by 96% in the case of a 6 × 6 virtual MIMO while maintaining the same throughput and fairness performance. In the third part, we first provide two cases of multi-cell coordination: adaptive handover initiation for data-oriented networks and macrodiversity antenna combining techniques. The adaptive handover initiation technique is suitable for data-oriented networks and can improve data rates in handover operation. Besides, we propose macrodiversity antenna combining techniques, and use simulation results to show that space-frequency-block-coded macrodiversity antenna combing has the highest spectrum efficiency. Although multi-cell coordination technologies play an important role in addressing the inter-cell interference in communication systems with full frequency reuse, the efficiency in information exchange among cells, however, is the main limiting factor. By combining cloud computing technologies, centralized radio access network (C-RAN) can achieve higher coordination processing gain with lower CAPEX and OPEX than its predecessor and regarded as the potential 5G RAN architecture. The key coordination technologies, such as handover, user-cell association, scheduling and precoding, are comprehensively surveyed in this dissertation. Multidimensional optimization is desired but usually with impractical complexity, and low complexity heuristics with moderate performance loss become the key to the success of C-RAN. To cope with challenges brought by heterogeneous fronthaul, denser deployment, and scaled up antenna numbers, new technologies need to be developed such as fronthaul traffic reduction, flexible function allocation, and RAN sharing. In summary, in this dissertation, we investigate coordination technologies in the subcarrier, user, and space (base station) domains to improve the performances of current mobile networks, including: • increased flexibility in multiple-antenna diversity-multiplexing-tradeoff and multiple-user capacity-fairness-tradeoff; • improved scalability in the number of antenna, users, as well as base stations; and • low-complexity algorithms with negligible performance degradation.