As the demand of high data rate transmission in wireless communication rises persistently, the Vertical Bell Laboratories Layered Space-Time (VBLAST) systems provide a solution which attains very high spectral e±ciency. In this work, the Symbol Error Rate (SER) of the VBLAST system with M-PSK and M-QAM using zero-forcing successive interference cancellation (ZF-SIC) under Rayleigh fading are analyzed. With the optimal power allocation pattern derived from the analysis, the power of the transmit antennas can be adjusted judiciously to acquire the lowest SER. The numerical results corroborate the accuracy of the analysis and reveal that the power diversity scheme can improve the system SER performance by 3.5 to 4 dB in the fast fading environment and 8.5 to 10 dB in slow fading environment. With the methodology developed in the analysis of the SER of the VBLAST system, we further analyze the bit error rate (BER) of the system of convolutional code concatenated with VBLAST architecture using ZF-SIC detection. The union bounds of BER of the convolutional coded ZF-SIC VBLAST system using BPSK and M-QAM modulation schemes are derived. To analyze the BER of the system, we first derive the probability distribution of the bit error number in a VBLAST symbol for BPSK and M-QAM, where the VBLAST symbol stands for the modulation symbols transmitted by the transmit antennas in one VBLAST transmission. The distribution of bit error number in a convolutional codeword is calculated with the bit error number in a VBLAST symbol, and then the pairwise probability of the convolutional code is derived. In the BPSK case, the union bound of BER approximates the simulation results as the SNR is higher than 6 dB, and in the 16QAM cases, the union bounds of BER approximates the simulation results as the SNR is higher than 15 dB. Since the union bounds are tight when the simulation BER is lower than 10^(-3), the analysis in this work provides a precise evaluation of the system performance in the appropriate operating region. The optimal power allocation is also applied to minimize the BER of the convolutional coded VBLAST system, and the numerical results reveal that allocating equal power to transmit antennas is closely optimal.