In this study both the underwater acoustic instruments and the fiber optic sensors were used to explore the characteristics of the air bubbles entrained by breaking waves near a submerged breakwater. The hydrophone was utilized to detect the noise radiated from the air bubbles. The time-series data of the underwater sound were transformed into the time-frequency domain for capturing the information of the bubbles, such as the bubble size and numbers. The probability density function of the bubbles was also determined. Array of fiber optic probe was deployed in the surf zone to monitor the optic signals. The time fraction ratio of signals affected by air bubbles was then obtained. A calibration experiment was carried out in a cylindrical tank to establish the rating curve between the time fraction ratio and the void fraction. The rating curve enables the transfer of the time fraction ratio into the void fraction. The results of this study reveal that the radius of the bubbles entrained by the breaking waves near a submerged breakwater ranges between 0.1 mm and 7.6 mm. The probability density function of the bubble shows a different slope with a Hinze scale of 0.7 mm. The number of air bubble increases along with the incident wave height and the width of submerged breakwater. Furthermore, the entrained air bubbles appear mainly near the free surface and distribute uniformly at the lee side of the breakwater.