Modern warfare is characterized by precise strikes, prompt reaction and high efficiency, for which militarily advanced countries around the world have begun to develop better equipment and weapon systems for the individual soldier. The main problem is that the more advanced the equipment and intelligent systems are, the heavier the weight of the load is, consequently decreasing the degree of mobility of the person carrying them. Thus, how to reduce the soldiers’ load while still maintaining equipment functions has become one of the major topics of interest in related research. In this context, we investigate the use of lightweight copper indium gallium selenide (CIGS) solar batteries as a power supply for electrical communication and computer systems in the field, to reduce the workload of the individual soldier by decreasing the weight they have to carry. Given considerations of portability and mobility, to reduce the dependence on petroleum fuels, it is important that every item of the soldier’s equipment have the characteristics of being lightweight and flexible. This would be advantageous for the development of better weapon systems and power supplies for future combat operations. The high-energy lithium battery and CIGS solar energy module can significantly solve the individual soldier’s operational problems in the field, effectively reducing the long-term load, hence maintaining highly efficient combat capability. Therefore, the purpose of this study is to reduce the soldier’s load and improve his/her mobility on the battlefield by improving the efficiency of the CIGS solar cell. Looking at the results of the analysis of EMG, blood oxygen concentration tests, T-shaped test and a subjective questionnaire were administered to individual soldiers to evaluate the degree of fatigue and their functional status under different loads. They were tested by comparison with basic quantitative indexes. It can be found that during the whole load exercise test, the blood oxygen concentration test results show can analyze that the transient intense load movement has a slight decrease on the human blood oxygen level, but does not cause human hypoxia. However, when the weight-bearing rate was 15% BW and 12.5%, the muscle activity of the trapezius and erector spinae was significantly higher than the load. Therefore, it can be stated that if the CIGS solar module can replacinge the traditional lithium battery used on the battlefield with CIGS molar modules, it will effectively reduce the fatigue of the future fighters' equipment load.