Regarding the question of “how large is the space photovoltaic market”, Junda Co., Ltd. said in an online conference call with the agency on December 22 that currently, the deployment of the global low-orbit satellite constellation and the space computing power industry have entered a cycle of explosive growth, and the space economy has become one of the core tracks for reshaping the global technological competition pattern. According to the International Telecommunication Union declaration data, the total number of planned low orbit satellites in the world has exceeded 100,000, marking that the industry has officially entered a new stage of intensive networking and large-scale development. At the same time, the functions of low-orbit satellites continue to be upgraded, from remote sensing and communication to high-computing power tasks such as in-orbit AI training and time-delay edge computing, and the demand for “light weight and high efficiency” of space-borne energy continues to upgrade. On the other hand, with the rapid expansion of AI computing clusters, terrestrial computing power is facing double bottlenecks in energy supply and heat dissipation efficiency. Demand for electricity and cooling will far exceed the carrying capacity of existing ground facilities. Space computing power has become a key breakthrough direction, and the prospects for an explosion are clear.

Regarding the question of “how large is the space photovoltaic market”, Junda Co., Ltd. said in an online conference call with the agency on December 22 that currently, the deployment of the global low-orbit satellite constellation and the space computing power industry have entered a cycle of explosive growth, and the space economy has become one of the core tracks for reshaping the global technological competition pattern. According to the International Telecommunication Union declaration data, the total number of planned low orbit satellites in the world has exceeded 100,000, marking that the industry has officially entered a new stage of intensive networking and large-scale development. At the same time, the functions of low-orbit satellites continue to be upgraded, from remote sensing and communication to high-computing power tasks such as in-orbit AI training and time-delay edge computing, and the demand for “light weight and high efficiency” of space-borne energy continues to upgrade. On the other hand, with the rapid expansion of AI computing clusters, terrestrial computing power is facing double bottlenecks in energy supply and heat dissipation efficiency. Demand for electricity and cooling will far exceed the carrying capacity of existing ground facilities. Space computing power has become a key breakthrough direction, and the prospects for an explosion are clear.