Continue capacity demand in cellular communications has stimulated new air interface concepts and technologies such as vertical sectorization, three-dimensional (3D) beamforming coordinated multi-point and large-scale MIMO. It is the main driving force for the consideration of millimeter wave (mmWave) bands and the advances in the associated circuits and devices technologies. In order to properly develop and evaluate the system performance in mmWave bands, a realistic channel model is urgently needed. In the first part of this thesis, we develop a 3GPP standard compatible 3D channel simulation platform that encompasses two most known mmWave channel models, namely those specified by the 3GPP-LTE-A standard and suggested by Rappaport of NYU. Given the simulation model and reported measurement results, we then consider the channel estimation issue in a single-cell time division duplexing (TDD) massive MIMO system with a base station (BS) equipped with a large uniform linear array serving many single-antenna mobile users. We first treat the narrowband multi-cluster channel case where the incoming waveform arrives at different mean angles of arrival (AoA) with non-identical angle spread (AS). Finally, we propose a model-based approach to solve the wideband channel estimation problem. Various simulated examples are given to validate the proposed solutions.