This dissertation addresses the fundamental issues of beamforming designs in massive multi-input-multi-output (MIMO) systems, especially for these systems operated under the frequency-division duplexing (FDD) mode. Massive MIMO is regarded as a crucial technology in enabling the next generation mobile communications due to its capability of enhancing system capacity and improving energy efficiency. Acquiring accurate downlink (DL) channel state information (CSI) at the transmitter for performing DL beamforming is regarded as a key of realizing the advantages of massive MIMO. The majority of studies concerning massive MIMO adopted the time-division duplexing (TDD) mode because it enables the base station (BS) to acquire DL CSI efficiently due to channel reciprocity. FDD massive MIMO is also considered because FDD is more suitable for providing low-latency services, and that is why it is widely deployed in nowadays cellular networks. Nevertheless, channel reciprocity no longer holds in FDD systems. Therefore, DL training and uplink (UL) feedback prior to DL data transmission are usually required for CSI acquisition at the BS. Compressing the overhead of DL training and UL feedback is considered utterly critical to the validation of FDD massive MIMO. In the literature, many channel estimation and beamforming schemes aimed at improving the efficiency of DL training and UL feedback have been proposed. However, these schemes all result in more round-trips between the BS and UEs than what TDD massive MIMO possesses. This implies longer latency of DL transmission. In this dissertation, beamforming schemes that need neither DL training nor UL feedback are proposed. Therefore, the proposed schemes are more suitable for extremely low-latency applications, which play an important role in the next generation wireless communication systems. The proposed schemes take advantage of the angular reciprocal property of FDD systems, which was suggested by a number of channel measurement studies. This property is called angle reciprocity in the literature. The simulation results provided in this dissertation indicate that the proposed schemes possess comparable performance to previous schemes that need DL training and UL feedback. Furthermore, a two-stage beamforming scheme with significantly reduced overhead of training and feedback is proposed by utilizing angle reciprocity. It is demonstrated that the proposed two-stage beamforming scheme outperforms some other schemes in achievable spectral efficiency. An optimization method for multicarrier new transmission waveform design is also proposed in this dissertation. Keywords: Massive MIMO, robust beamforming, beam-time block coding, no CSI feedback, two-stage beamforming, new waveform.