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From skills-for-humanity
Routes to the right cognitive science tool based on your situation. Use when you need to understand attention, mental models, metacognition, or cognitive load.
npx claudepluginhub human-avatar/skills-for-humanityHow this skill is triggered — by the user, by Claude, or both
Slash command
/skills-for-humanity:cognitionThe summary Claude sees in its skill listing — used to decide when to auto-load this skill
Applies cognitive science to understand and improve how thinking itself works — attention, mental models, metacognition, and cognitive load. Diagnoses what kind of cognitive work is needed and routes to the right tool.
Applies metacognitive framework to monitor comprehension, calibrate confidence, assess reasoning quality. Useful for complex problem solving or when you doubt your understanding.
Challenges assumptions, applies mental models like SWOT, first principles, and inversion, and structures reasoning to sharpen decisions and solve complex problems.
Conducts meta-cognitive meditation to clear context noise, observe reasoning patterns, and build single-pointed task focus. Use when switching tasks, reasoning feels scattered, or pre-deep work.
Share bugs, ideas, or general feedback.
Applies cognitive science to understand and improve how thinking itself works — attention, mental models, metacognition, and cognitive load. Diagnoses what kind of cognitive work is needed and routes to the right tool.
| You need to... | Tool |
|---|---|
| Understand what is capturing or depleting attention — and how to protect it | cognition-attention |
| Surface and audit the mental models driving perception and decisions | cognition-mental-models |
| Apply thinking-about-thinking to monitor comprehension and calibrate confidence | cognition-metacognition |
| Manage the limits of working memory — chunking, offloading, reducing complexity | cognition-cognitive-load |
Framing check: Confirm the specific cognitive situation before routing. State what you've identified — the thinker or system in question, the cognitive challenge, and what the user wants to improve or understand — in one sentence, then use AskUserQuestion:
Question: "I'm reading this as: [your one-sentence framing of the specific cognitive challenge and what you want to understand or change]. Is that right?"
Header: "Framing"
Options:
"I can't focus" / "attention keeps getting pulled away" / "how do I protect deep work time" → cognition-attention (map the attention economy, identify threats and defences)
"I keep seeing this the same way" / "what assumptions are built into how I see this" / "what mental model am I using" → cognition-mental-models (surface the implicit representations driving perception)
"I don't know what I don't know" / "how confident should I be" / "am I actually understanding this" → cognition-metacognition (apply thinking-about-thinking to calibrate and monitor)
"This is too much to hold at once" / "complexity is overwhelming" / "how do I simplify this" → cognition-cognitive-load (apply Sweller's cognitive load theory to manage working memory limits)
Unclear → cognition-metacognition; most cognitive difficulties trace back to not knowing what you do and don't understand
After diagnosing which tool fits, use the AskUserQuestion tool to confirm direction. Construct the question dynamically to include your diagnosis:
Proceed based on their selection.
Maps the attention economy of a mind or situation — what captures it, what depletes it, and how to protect it.
Attention is finite and directional. What occupies it is not random — it follows predictable rules: salience, novelty, emotional charge, and personal relevance all compete for the cognitive resource that enables everything else. This skill maps the full attention landscape of a specific person or context: what is actively competing for focus, what legitimate demands exist, what noise can be eliminated, and what structural conditions protect or destroy sustained attention. The output is a prioritised defence plan for cognitive bandwidth.
Output: Attention threat map, current depletion sources, structural protection measures, and a priority list for reclaiming focus.
Surfaces and audits the internal representations that drive perception and decision-making.
Every perception and decision runs through a mental model — a simplified internal representation of how part of the world works. The danger is that models become invisible: they shape what we notice, how we interpret evidence, and what options we can imagine, all without our awareness. This skill, rooted in Philip Johnson-Laird's model theory, makes the implicit explicit. It identifies which models are active in a situation, tests them for accuracy and completeness, and surfaces the gaps and distortions that are shaping judgment without being seen.
Output: Active models identified, accuracy audit (what each model gets right and wrong), gaps and blind spots, and a recommended model update or replacement.
Applies thinking-about-thinking as a practical tool — monitoring comprehension, calibrating confidence, and knowing what you do not know.
Metacognition — understanding and regulating your own cognitive processes — is the highest-leverage cognitive skill because it governs all the others. Developed as a formal discipline by John Flavell in the 1970s, it encompasses: knowing what you know and don't know (metacognitive knowledge), monitoring whether you're actually understanding something (metacognitive monitoring), and adjusting your approach when you're not (metacognitive control). This skill applies these three dimensions to a concrete situation where the quality of thinking matters.
Output: Metacognitive status across knowledge, monitoring, and control dimensions — with specific gaps, overconfidence alerts, and recommended adjustments.
Manages the limits of working memory — chunking, offloading, and reducing unnecessary complexity to free capacity for what matters.
George Miller established in 1956 that working memory holds approximately seven items (plus or minus two). John Sweller's Cognitive Load Theory refined this: not all load is equal. Intrinsic load is inherent to the material; extraneous load comes from poor design; germane load builds schemas. The goal is to minimise extraneous load, manage intrinsic load through chunking, and use offloading strategies to extend effective working memory beyond its biological limits.
Output: Load type breakdown (intrinsic / extraneous / germane), chunking recommendations, offloading strategy, and redesigned information structure where applicable.