Energy efficiency is a critical demand in the design of next generation wireless communication systems such as Long Term Evolution (LTE). In this thesis, we study the problem of training overhead reduction for LTE uplink transmission, in which the Single-Carrier Frequency Division Multiple Access (SC-FDMA) modulation is adopted. Motivated by the fact that samples of real-world wireless channels are typically correlated in time, we propose to exploit such temporal correlation to develop a new channel prediction scheme for training overhead reduction. More specifically, assuming that the receiver has acquired a set of channel estimates, based on the linear minimum mean square error (LMMSE) rule, during a few training phases, we develop a LMMSE based channel prediction scheme which explicitly takes account of the effect of channel estimation errors. A closed-form formula for the optimal channel predictor is derived, and the achievable MSE performance is the analytically characterized. The achievable post-detection SNR performance when the predicted channels are employed in the LMMSE equalizer design is also studied. Computer simulations are used to illustrate the performances of the proposed scheme.