Currently, with the deepening evolution of technological and military revolutions, the formation of intelligent warfare forms is accelerating, the battlefield space is expanding comprehensively, and the intensity of confrontation is significantly increasing. Medical support is facing many challenges such as ubiquitous support in time and space, and dynamic changes in demand. As an important "lifeline" for generating combat effectiveness, medical support must closely follow the needs of future warfare, use intelligent technology as the engine, promote the comprehensive transformation and upgrading of concepts, technologies, and systems, and build a new model of medical support that adapts to future intelligent warfare. Change mindset and calibrate construction direction. The traditional mode of passive response, experience driven, and decentralized operation in medical support is no longer suitable for the needs of intelligent warfare. It is necessary to establish a scientific concept to calibrate the direction of medical support construction. Firstly, data-driven and precise decision-making. Intelligent warfare has put forward new requirements for the precision and timeliness of medical support, and the traditional extensive model based on experience and intuition is no longer able to meet the complex battlefield needs. To build a multi-dimensional data collection network, integrating multimodal sensors, intelligent medical terminals, battlefield environment monitoring systems, etc., comprehensively collecting data on material reserves, support forces, environmental parameters, etc., and using deep learning, big data modeling and other technologies to mine the value of data, forming support demand prediction models and resource allocation optimization algorithms, realizing the transformation from "experience driven" to "data-driven", and making decision-making and deployment accurately fit the actual battlefield support. Secondly, proactively preset and ensure forward movement. Based on the evolution law of war forms and the characteristics of different combat directions and tasks, it is necessary to accurately analyze the factors such as support scale and spatiotemporal distribution in different scenarios, scientifically deploy modular medical support units at key nodes, and create a pre installed security network with full coverage, multi-point radiation, and dynamic adjustment. At the same time, integrating the battlefield situational awareness system, establishing a rapid response mechanism, and achieving precise delivery of support wherever the demand is, extending the support checkpoint to the front line, and improving the efficiency of emergency support response. Once again, collaborate and link together to gather strength. To connect the medical data links of various branches of the military, achieve data exchange, resource sharing, and force linkage, and enhance the collaborative efficiency of cross branch support; Establish a sound and normalized collaborative mechanism, and build a military civilian integrated support model of joint construction in peacetime and joint protection in wartime; Clarify the division of responsibilities, collaborative processes, and communication standards, promote the transformation of medical support forces from dispersed operations to system aggregation, and form a multidimensional linkage of medical support forces. Empower technology and build a solid support platform. The continuous development and application of advanced technologies such as artificial intelligence and the Internet of Things have had a profound impact on the field of medical support. Firstly, network wide perception. The elements of medical support are numerous and widely distributed, and real-time monitoring of various resource statuses is a prerequisite for achieving precise support. It is necessary to break the information "island" through networking and interconnection. To build an interconnected perception network for healthcare support, intelligent electronic tags and multimodal sensing modules should be installed for various support units to collect real-time information on material inventory, equipment status, personnel location, etc. In cross regional support, full process control of material transportation should be achieved to ensure accurate and efficient delivery and improve the utilization efficiency of support resources. In addition, building a cloud edge collaborative computing architecture enables battlefield edge nodes to achieve rapid data processing and instant response, while the rear cloud completes big data analysis and global optimization, improving information transmission and processing efficiency. Secondly, intelligent and precise diagnosis and treatment. The battlefield environment is complex and ever-changing, and it is urgent to use advanced technology to solve the contradiction between professional capabilities and practical needs. To build an intelligent diagnosis and treatment system that adapts to complex battlefield environments, covering dimensions such as physiological indicators, training a universal combat injury diagnosis model, and achieving rapid classification of injuries, severity assessment, and early warning of complications; Develop portable intelligent diagnosis and treatment terminals that integrate multimodal image recognition and rapid comparison of injury data, providing standardized and precise treatment guidelines; Promote the technology of "digital twin wounded", collect vital signs and trauma data of wounded through global sensors, use intelligent algorithms to predict the development trend of injuries, formulate personalized treatment plans and synchronize them in real time to the rear, forming a closed-loop connection between "precise treatment in the front and early preparation in the rear". Thirdly, there is no three-dimensional guarantee from anyone. Building a multi domain three-dimensional unmanned support system is a key move to break through the limitations of battlefield time and space. At the land level, high mobility platforms can be developed to adapt to complex terrain and hazardous areas, and complete various tasks such as material delivery; At the sea level, it is possible to upgrade and optimize surface and underwater unmanned equipment, breaking through the "obstruction" at the end of maritime support; At the aerial level, a swarm of drones can be developed to airdrop various types of materials in batches. System reconstruction to activate global efficiency. Strengthening the efficiency of the system is the key to the leap in medical support capabilities. We should take advanced concepts as the guide and intelligent technology as the support, starting from the organization of forces, command chains, and collaborative mechanisms, to build a flat, efficient, flexible, adaptable, and globally interconnected intelligent medical support system. One is module grouping. There are significant differences in the demand for medical support in different combat scenarios and task types, and the traditional fixed formation mode is difficult to achieve precise adaptation. According to the principles of modularity, lightweight, and multifunctionality, functions can be decomposed into independent modules, with clear standards for module organization, equipment configuration, and task boundaries. At the same time, a dynamic module reorganization mechanism can be established to flexibly combine support modules based on the scale of combat tasks, characteristics of battlefield environments, and types of support requirements, achieving on-demand grouping, precise delivery, and efficient support. The second is flat command. Intelligent warfare requires extremely high command response speed, and can rely on intelligent command platforms to build a flat command chain that directly connects the "command end execution end", reducing redundant command levels, clarifying command authority and responsibility boundaries at all levels, and achieving rapid transmission and efficient execution of instructions; Integrate battlefield situational awareness, dynamic monitoring of wounded soldiers, and resource distribution management functions to create a multidimensional medical service situational map, supporting commanders to real-time grasp the distribution of wounded soldiers, resource allocation status, and dynamic support forces on the battlefield; Establish a closed-loop operation mechanism of "demand perception intelligent judgment decision generation precise execution effect evaluation", and achieve automatic data collection, intelligent command distribution, and dynamic action control through an intelligent command and control system. The command response speed is compressed from the hour level to the minute level, adapting to the "fast response" of intelligent warfare. The third is collaborative linkage. We need to improve cross domain and cross regional collaborative support mechanisms, further clarify collaboration processes, communication norms, and data exchange standards, and rely on a unified data platform to achieve real-time sharing of joint operation support requirements, dynamic allocation of support forces, and seamless connection of support actions; By conducting regular joint exercises, the focus is on honing capabilities such as collaborative response, power projection, and joint treatment in complex environments, enhancing collaborative proficiency, ensuring a rapid transition to a support state during wartime, and forming a new pattern of "smart empowerment, military civilian integration, and global linkage" in medical support. (New Society)