Core Viewpoint - The "fast-slow dual system" design in robotics is gaining attention as it allows robots to balance rapid responses to environmental changes with thoughtful, complex decision-making, inspired by human cognitive processes [1][3][4]. Group 1: Fast-Slow Dual System Concept - The fast system (System 1) operates instinctively and automatically, while the slow system (System 2) engages in deliberate and conscious thought, enabling efficient decision-making [1][4]. - This decoupling of fast and slow systems allows for independent upgrades of AI algorithms without altering the stable control framework, reducing development complexity [1][4]. Group 2: Application in Robotics - The fast-slow dual system can address the challenge of balancing generality and practicality in robotics, enabling quick visual motion strategies and end-to-end training for rapid communication and interaction [3][4]. - For example, in a task like "grabbing a red block," the slow system handles perception and planning, while the fast system calculates the necessary torque for smooth movement, allowing for immediate responses to disturbances [3][4]. Group 3: Company Implementations - Various companies are adopting the fast-slow dual system, each with unique implementations but sharing the core inspiration from human cognitive dual-process theory [4][5]. - Companies like Figure AI, PI, and智平方 are developing models that emphasize the separation of planning and execution, allowing for asynchronous parallel processing and improved task execution in complex environments [6][9][12][13]. Group 4: Data Strategies and Training Methods - Companies such as 魔法原子 and 微亿智造 focus on collecting vast amounts of real-world data to minimize the gap between simulation and reality, while others like PI utilize synthetic data for efficient model training [5][28]. - The approaches vary from general models seeking ultimate generalization to specialized models targeting specific scenarios for reliability and efficiency [5][28]. Group 5: Specific Company Models - Figure AI's Helix model integrates a dual system architecture for high-frequency control of the robot's upper body, achieving end-to-end visual-language-action capabilities [6][7]. - PI's Hi Robot system combines high-level semantic planning with low-level action execution, enabling complex task management in home environments [9][10]. - 智平方's GOVLA model enhances task understanding and execution through a three-part architecture, achieving coordination in open environments [12][13]. - 星海图's G0 model focuses on real-time control and task planning in complex scenarios, supported by a high-quality dataset [15][16]. - 擎朗's KOM2.0 model emphasizes service industry applications, utilizing a dual system for environment perception and action generation [18][19]. - 星动纪元's ERA-42 model integrates high-level planning with low-level control, enhancing execution capabilities in dynamic environments [21][22]. - 节卡's JAKA EVO platform employs a dual system for task parsing and execution, facilitating rapid adaptation to new industrial scenarios [25][26]. - 微亿智造's architecture leverages a cloud-edge-end model to ensure scalable applications in complex industrial settings [28][30]. - 魔法原子’s model simulates human cognitive processes to enhance real-time response and long-term task planning [30][31]. - 灵初智能's Psi-R1 model combines planning and execution through a layered architecture, achieving high-level task management and precise control [33][34].