When AI robots need to perform complex calculations and flexible actions simultaneously, a single rigid board or flexible board cannot meet the requirements. However, the R-FPC, with its composite structure of "rigid area carrying core chip+flexible area adapting active parts", becomes the optimal solution for connecting the robot's "brain" and "limbs".

In the control system of AI robots, the rigid part of the soft hard combination board can stably carry core computing chips such as CPU and GPU, as well as surface mount components such as capacitors and resistors, to ensure the heat dissipation and stability of the chips during high-speed computing; The flexible part can be extended to the moving parts of the robot, such as the robotic arm and tracks, to accurately transmit computational instructions to the execution unit. This "one board dual-use" design not only reduces the number of connectors used between boards, reducing the probability of contact failures by more than 30%, but also increases the integration of robot control systems by 40%, reserving more installation space for AI modules.

Industrial inspection AI robots are a typical application scenario for soft hard integrated boards. This type of robot needs to move in a factory with dense equipment. The control box contains a combination of soft and hard boards, and the rigid area is equipped with AI image recognition chips and data storage modules. The flexible area is connected to the walking motor at the bottom of the robot and the infrared sensor at the top, achieving efficient operation throughout the entire process of "real-time image acquisition AI fault analysis autonomous path adjustment". In addition, in the field of medical AI robots, the combination of soft and hard boards also needs to meet biocompatibility requirements. The substrate treated with special coatings can avoid the production of harmful substances when in contact with the human body, providing safety guarantees for the precise operation of surgical robots.