The OFDM-based multiple access (OFDMA) scheme has been shown to be capable of achieving very high spectral efficiency. A key advantage of an OFDMA system is that it can exploit the diversities offered by the time-varying and user(location)-dependent nature of the subchannels via proper scheduling and power/subchannel allocation. In this thesis, we first present a new single-symbol based initial ranging code structure. We also address issues related to the associated signal detection, timing synchronization methods and novel ranging sequences. These sequences are generated by a prototype sequence with proper linear phase rotations in frequency domain. The proposed detection method is capable of detecting single and multiple ranging codes, estimating the corresponding timing offsets and power strengths. Our approach offers improved performance and enhanced robustness against multi-user interference and multipath fading. Computer simulations are provided to assess the effectiveness of the proposed method and its advantages over existing alternatives. We proceed to present a novel ranging sequence design method in the second of the thesis. When designing ranging sequences, reducing the probability of collision is one of top priorities. Our ranging sequences design is based on the well known Bose, Chaudhuri, and Hocquengham (BCH) codes. The design generate more ranging sequences to increase the ranging opportunities. Peak to Average Power ration (PAPR) is taken into our design consideration as well. Our sequences have the desired properties of rendering low peak to average power ratio (PAPR) and cross-correlation values, which enable a receiver to effectively detect multiple ranging codes and estimate the corresponding time offsets. It therefore gives improved performance and enhanced robustness against multi-user interference and multi-path fading. Numerical results verify the effectiveness of the proposed method and its advantages over that based on pseudo-random binary sequences (PRBS). The last part of this thesis considers a two-tier pico/femtocell network comprising a conventional cellular network plus embedded pico/femtocell stations. Such network architecture offers an economically viable solution to achieving high cellular capacity and improved coverage. For an OFDMA network using universal frequency reuse and timedivision duplex (TDD), however, the resulting cross-tier interference causes unacceptable high outage probability and ranging signal detection error. The problem becomes more critical when performing a ranging process. A two-step uplink synchronization method is provided for uplink synchronization between a mobile station (MS) and a pico/femto base station (BS) that overlays upon a macro/micro cellular network. By using the proposed uplink synchronization method, a unified synchronous ranging channel may be used for ranging and UL access in pico/femrocells with reduced interference.