波动几何

Problem Handling Protocol Model Response - Author: Wang Jiao Cheng#

Okay, the protocol has been loaded. Based on the cognitive model system you provided, we will systematically address the issues. Below is a structured analytical response that integrates this system:

Target of Handling: (Since your input did not specify a particular issue, this response will demonstrate how the system integrates and is used to analyze problems in general. Please provide a specific issue later.)

I. Ultimate Understanding: The Fundamental Context of the Problem (Starting Point)#

• Temporal Evolution: How has this problem developed in its historical context? Is its trend continuous, exacerbating, or diminishing? (If there is no specific problem, consider the evolution needs of "the problem handling framework" itself.)
• Spatial System: To which larger system (society, organization, industry chain, ecosystem) does this problem belong? How do the key elements and energy/information flows within that system affect this problem? (If there is no specific problem, view the "cognitive model system" as a cognitive system.)
• Essential Relationship: What is the core contradiction of this problem? What are the deepest driving or constraining forces? (If there is no specific problem, the essence is the pursuit of "efficient cognition and decision-making methodology.")

II. Macro Understanding: A Bird's Eye View (Three Models Collaboration - 1)#

• Applying Four Layers of Thinking:
  • Ultimate Layer: What is the fundamental purpose of addressing this problem? (Pursuing efficiency? Resolving specific contradictions? Optimizing decisions?)
  • System Layer: Identify the core system and its boundaries related to the problem. What key subsystems are included? What are the interaction patterns between subsystems? What properties emerge from the whole?
  • Structural Layer: Deconstruct the key elements and static relationships (organizational structure, physical structure, knowledge structure) involved in the problem. Where are the leverage points?
  • Logical Layer: Clarify the core logical chain of the problem. Are the causal, conditional, and temporal relationships between elements clear? Are there logical fallacies or gaps?
• Applying Five Pairs of Relationships (Identifying Information/Knowledge Organization Methods):
  • Analyze whether the existing information is in a parallel comparison, hierarchical progression, causal loop, general-specific induction, or matrix/Venn intersection relationship? This determines the choice of cognitive tools for subsequent processing.

III. Macro Intervention: Planning the Breakthrough Path (Three Models Collaboration - 2)#

• Constructing Intervention Paths:
  • Clarifying Current Situation and Goals: (Fill in when specific problems are provided)
    • Current Situation: (Need specific description)
    • Goals: Set clear objectives using the SMART principle (Specific, Measurable, Achievable, Relevant, Time-bound).
  • Designing Methods (6W2H):
    • Why: What is the core value and necessity of achieving the goal? (Echoing the ultimate layer).
    • What: What specific work needs to be completed or what key points need to be resolved?
    • Where: At which system level or physical/logical position should the intervention take place? (Structural layer)
    • When: What are the time window, rhythm, and priorities for the intervention? (Temporal evolution)
    • Who: Who is responsible for execution, coordination, and decision-making? Which stakeholders are involved?
    • Which: Among many possible solutions, which path or constraints should be chosen?
    • How: What are the specific implementation plans, steps, required technologies, and tools?
    • How Much/Many: What are the required resource budgets (cost, manpower, time) and expected output measurement standards?
  • Planning Process (PDCA): Incorporate the intervention path into the PDCA cycle framework:
    • P (Plan): Develop a detailed plan based on the above.
    • D (Do): Execute the plan.
    • C (Check): Monitor progress, measure results, and evaluate against goals.
    • A (Act): Analyze deviations, optimize and adjust the plan (Adapt), or standardize successful experiences (Standardize).

IV. Micro Deconstruction: Deeply Constructing Solutions (Three Models Collaboration - 3)#

• Iron Rules of Execution:
  • Macro Intervention: Ensure that all micro actions consistently serve the established macro intervention goals and paths, avoiding "seeing the trees but not the forest."
  • Micro Construction: Rigorously design and implement the specific modules, elements, and interaction details of the solution (returning to the structural layer and logical layer). Use engineering thinking to decouple, refine, and test.
  • Analyzing Old Models: Deeply examine the existing cognitive patterns, processes, structures, or solutions (if targeting a specific problem). Identify their advantages, defects, and root causes (logical fallacies? Structural defects?).
  • Constructing New Models: Based on the above analysis, ultimate understanding, and macro intervention paths, create new cognitive frameworks, workflows, algorithms, or physical structures at the micro level to replace old patterns. This process requires repeated verification of the logic and system fit.

V. Collaborative Cycle and Iteration#

The above steps (macro understanding -> macro intervention -> micro deconstruction) are not linear but rather a highly collaborative and iterative process:

1. New information discovered in micro deconstruction may require adjusting macro understanding (e.g., discovering new elements or relationships).
2. The results of the intervention path (Check/Act in PDCA) will feedback into the macro intervention goals and plans for dynamic adjustments.
3. The in-depth analysis of the old model during the constructing new model process (iron rules of execution) is a key bridge connecting the micro and macro, ensuring that the new solution addresses the problem effectively.

Diagnosis and Key Emphasis Points (Combined with Your System Requirements)#

1. Advantages and Internal Logic of the System:

   • Emphasize Integration: Ultimate understanding, four layers of thinking, and five pairs of relationships constitute the depth, breadth, and organization of cognition.
   • Focus on Closed Loops: The intervention path (goal-method-process) and iron rules of execution (macro-micro, breaking old-creating new) provide a clear action paradigm and constraints.
   • Dynamic Collaboration: The three models collaboration is not a rigid process but emphasizes iterative feedback and validation between different perspectives, aligning with the resolution patterns of complex problems.
   • Emphasize "Meta-Thinking": The "analyzing old models/constructing new models" in the iron rules of execution is a reflection and innovation on cognitive patterns themselves, which is the core of continuous optimization.

2. Potential Difficulties and Considerations:

   • Abstraction: The system is highly abstract and needs to be combined with specific problems and a lot of practical applications to internalize. Otherwise, it may lead to conceptual piling.
   • Risk of Information Overload: Using all models simultaneously may create cognitive burdens. Emphasizing the selection of the most relevant models/layers/relationships at different stages is crucial. Use flexibly, rather than rigidly applying.
   • Time Cost: Deep application of this system to think about complex problems initially requires considerable time. It is necessary to improve proficiency through practice to optimize efficiency.
   • Execution Balance: "Macro intervention" and "micro construction" need dynamic balance. Prevent excessive focus on the macro while neglecting the details, or getting lost in the micro without direction. "Analyzing old models" should avoid getting stuck in minutiae, and "constructing new models" should prevent unrealistic fantasies.
   • Ambiguity of System Boundaries: The definition of system boundaries in ultimate understanding and macro understanding requires experience and judgment; otherwise, it affects the effectiveness of subsequent analysis and intervention.

3. Optimization Suggestions:

   • Strengthen Toolkits: Provide more specific instantiated tools or templates (e.g., logic trees, causal loop diagrams, SWOT/PESTEL analysis frameworks) for four layers of thinking, five pairs of relationships, 6W2H, PDCA, etc., to facilitate implementation.
   • Visual Guidance: Design mind maps or flowcharts to intuitively present the structure and collaborative relationships of the entire system.
   • Emphasize Priorities: When addressing practical problems, explicitly state which models or layers are the highest priority at the current stage.
   • Practice Scenario-Based: Set different typical scenarios (business decisions, product design, conflict resolution, etc.) to simulate and deduce using this system to deepen understanding.

Conclusion#

The cognitive model system you constructed has strong systematic, integrative, and action-oriented characteristics, covering a complete closed loop from understanding the essence of the cognitive world to micro execution, and emphasizing the iterative innovation of cognitive patterns. Its core value lies in providing structured thinking paths and toolkits for complex problems.

Key Success Factors:

• Truly apply the system to specific problems.
• Maintain flexibility in practice to avoid rigidity.
• Continuously "analyze old models/construct new models", optimizing the system itself and application methods.
• Reduce application thresholds and improve efficiency through visualization, toolization, and scenario-based approaches.

Next Steps:

• Please provide a specific problem or scenario. We will immediately apply this system for structured analysis and solution path planning, demonstrating its practical application effects.
• Continuously provide feedback on the experience and challenges of using the system itself to iteratively optimize this "operating system of thought."

The cognitive model handling protocol is on standby. Please provide the target problem or instructions!