As the demand of broadband wireless communication grows continually and better quality of network service has been required, the 60-GHz band that has 7-GHz unlicensed spectrum is a promising choice to offer multi-Gb/s data rate in wireless transmission. To overcome the high air loss of 60GHz wireless signals, radio-over-fiber (R-o-F) system have been proposed to extent the coverage due to low loss and almost unlimited bandwidth of optical fiber. Recently, orthogonal frequency-division multiplexing (OFDM) modulation has been widely utilized in both wireless and optical communication. Compared with double-sideband single-carrier (DSB-SC) modulation, OFDM signals have high peak-to-average-power ratio (PAPR) which will induce nonlinearly effect to degrade signal performance. In this paper, we propose SSB-SC modulation which utilizes two orthogonal dimensions to carry in-phase and quadrature-phase signals. Orthogonal SSB-SC modulation not only has higher spectral efficiency than conventional DSB-SC modulation but also has less PAPR than OFDM modulation. However, SSB-SC signals suffered from self-inter-symbol interferences. Record 42-Gb/s wireless signal transmission is experimentally demonstrated using a Radio-over-Fiber system employing the SSB-SC and 64-QAM, representing a spectral efficiency of 6-b/s/Hz. Decision feedback equalizer and Maximum likelihood sequence estimation were utilized to compensate for the signal distortion caused by fiber dispersion and self-inter-symbol interference. And we analysis that different match filter versus effects of SSB-SC signal transmission. After transmission over 25-km single mode fiber and 3 m wireless distance, the power penalty was less than 1dB.