Beam commissioning of the SuperKEKB collider began in 2016. The Beam Ex-orcism for A STable experiment II (BEAST II) project is particularly designed to measure the beam backgrounds around the interaction point of the SuperKEKB collider for the Belle II experiment. We developed a system using undoped bismuth germanium oxide (BGO) crystals with optical fiber connections to a multianode photomultiplier tube and one field-programmable gate array embedded DAQ (data acquisition) board for real-time beam radiation background monitoring. The radia-tion sensitivity of the BGO system is calibrated as 2.2E−12 ± 11.75% Gy/ADU (analog-to-digital unit) at the 700-V operation voltage with the nominal 10-m-long fibers for transmission. Our γ-ray irradiation study of the BGO system shows that the BGO crystals suffered from radiation damage. The light yields of the BGO crystals dropped by ∼40% after receiving 4.5 krad dose in 2.5 h, which agrees with the results of the radiation hardness study we have reported. The irradiation study also proves that the BGO system is very reliable, being able to function at fairly high radiation conditions without serious saturation or other problems. Besides, the running of the BGO system in BEAST II was very successful. It has provided much useful data for the beam background study. The data that the BGO system provided will facilitate the development of the entire BEAST II project. My study contains the design of the firmware and software, the calibration of the device, the analysis of the results of the irradiation study, and the integration of the data obtained during the running in BEAST II. In this thesis, I make a comprehensive portrait of the BGO system, including the design, calibration, tests, and the results of the beam background study in BEAST II.