Due to the high cost and low energy efficiency of dedicated radio frequency (RF) chains, in practice, the number of RF chains is usually limited in millimeter wave (mmWave) massive multiple input multiple output (MIMO) systems. Hybrid beamforming (HB), combining digital baseband precoding and analog beamforming, was proposed as viable solution for this kind of systems. Spatial modulation (SM) is another low cost and power efficient technique that can exploit spatial diversity of MIMO systems. In this thesis, we will combine hybrid beamforming with SM to improve the efficiency of massive MIMO without additional cost. Compared with the traditional SM system that uses less modulation order and has relatively better performance, the hybrid beamforming with spatial modulation (HBSM) system is not exactly like this. Considering the multi-user scenario, we propose an antenna unit allocation design that can reduce the possibility of conflicts between users, thereby improving performance. The performance comparison of the HB-SM system and the antenna element allocation of hybrid beamforming with spatial modulation (AEA-HB-SM) system is analyzed off-line through mathematical formulae to help the system choose between AEA-HB-SM and HB-SM transmission modes under different parameters.