A　brachytherapy, one of the radiation therapy fields, is a treatment that kills lesion cells by inserting a radioisotope that keeps naturally releasing radiation into the body. A high-dose-rate radiotherapy is being conducted in general. Compared to an external irradiation, however, that can restrict irradiation and control dose, the brachytherapy, performs immediate therapy after checking dose of radioisotope only or checking dose distribution through Film/Screen system. When checking the dose distribution using film/screen system, it is hard to observe a correspondency between treatment plan and dose distribution as shades due to scattered rays appear. In this research, we produced a semiconductor detecting sensor as a basic research in order to develop a system that checks a presence of dose distribution corresponding to the treatment plan during brachytherapy. We also appraised applicability of it in an actual brachytherapy environment by irradiating γ-ray of a radiation source of Ir-192. We used HgI2 as the semiconductor detecting material since it has a high atomic number and a function work is relatively less compared with other materials. We used ITO glass as lower electrode potential for signal collection, and formed masks to that in an area of 1.5 cm × 1.5 cm, and the thickness of it increased gradually from 600 μm to 1.6mm by forming separate masks. HgI2 was produced by Particles In Binder(PIB) method and then went though screen printing. We carried out vacuum metalization of gold in an area of 1 cm × 1 cm onto un upper part of the detecting material in order to form the upper electrode. We compared sensitivity of each completed sensor with different thickness onto the radiation source of Ir-192. We, then, selected the optimal thickness. We also assessed reproducibility about an identical irradiation condition and signal collection amount by increasing distance between the radiation source and irradiator. We granted voltages onto the upper electrode through electrometer. The collected signals from the inside of sensor were received as waveform through Oscilloscope and were analyzed by ACQ program. As a result of the experiment, we confirmed a stable signal collection amount where the thickness was 1.1 mm. An error range of the sensitivity was within 2% as a result of the reproducibility experiment. We found that there is difference in the sensitivity when distance between radiation source and detecting sensor being increased. Hence, we concluded that the sensor produced in this experiment can be used for the dose distribution checking system of brachytherapy.