This paper presents the fundamental technique of phase generated carrier (PGC) and its realization on compact reconfigurable input and output (RIO) which adopts real-time and field programmable grate array (FPGA) techniques. Improvement of the PGC technique is also introduced by using peak-to-peak value detection method to reduce the influence of variation of the light intensity. A four-element fibre Bragg gratings (FBG) laser sensor system is conducted in the experiment and the demodulated results demonstrate correlation coefficient as high as 0.995 with the reference signal and the dynamic range to be 120dB@63Hz. This paper presents the fundamental technique of phase generated carrier (PGC) and its realization on compact reconfigurable input and output (RIO) which employs real-time and field programmable grate array (FPGA) techniques. Improvement of the PGC technique is also introduced by using peak-to-peak value detection method to reduce the influence of variation of the light intensity. A four-element fiber Bragg gratings (FBG) laser sensor system is conducted in the experiment and the demodulated results demonstrate correlation coefficient as high as 0.995 with the reference signal and the dynamic range to be 120dB @ 63Hz.