In this thesis, an improved discrete Fourier transforms (DFT)-based channel estimation technique is proposed for time domain synchronous orthogonal frequency division multiplexing (TDS-OFDM) communication systems. The conventional DFT-based channel estimation techniques for cyclic prefix (CP)-OFDM systems employ pilots to estimate the channel frequency response and suppress the noise effect in the DFT by using the zero insertion. Recently, the DFT-based channel estimation called significant channel tap detector (SCTD) has been developed for CP-OFDM systems. It could improve the system performance by deciding significant channel taps adaptively without requiring any channel statistical information. However, the original SCTD scheme is not suitable to apply for the TDS-OFDM systems in large delay spread channel environment. The main contribution of this thesis is that the proposed channel estimation technique based on the concept of SCTD scheme could effectively improve the system performance of TDS-OFDM systems. The frame structure with dual pseudo noise sequence padding is considered in order to avoid inter-symbol interference. The correlation of two successive preambles is employed to estimate the average noise power as the threshold for obtaining the SCTD threshold estimation error and loss path information resulting in performance degradation in large delay spread channel environment. The proposed estimation scheme could also roughly predict the noise power in order to choose the significant channel taps to estimate the channel impulse response. Some comparative simulations are given to show that the proposed channel estimation technique has potentials to improve the bit error rate performance compared with the conventional least-squares channel estimation.