| name | think-fermi-estimation |
| description | Produces a Fermi decomposition worksheet that estimates an unknown numeric quantity by factoring it into a chain of order-of-magnitude sub-estimates, guessing each to within a band, then multiplying back to a point estimate plus a compounded low/high range, with an independence check and a dominant-uncertainty flag. Use when you need a number and no lookup-able data or genuine reference class exists, so the magnitude has to be built from factors (for example sizing a market, a load, a cost, or a conversion you cannot look up). Not for forecasting from real base rates (use reference-class-forecasting) or decomposing a question for coverage with no number (use issue-tree). |
| license | Apache-2.0 |
| metadata | {"id":"thinking-framework-skills.fermi-estimation","family":"decision-and-option-evaluation","evidence-tier":"M/P","version":"0.1.0","standard":"0.8"} |
Fermi Estimation
Sometimes you need a number and there is nothing to look up: no dataset, no genuine reference class, no precedent to borrow. A single all-at-once guess at the whole magnitude is badly anchored and hides its own uncertainty. The Fermi move is to factor the unknown into a short chain of sub-quantities - each one small and familiar enough to guess to within a factor - then multiply the chain back into an estimate and compound the per-factor bands into a low/high range. The reason it can beat one wild guess is partial error cancellation: if the per-factor errors are roughly independent and centered, over-guessing one factor and under-guessing another tend to offset in the product. The output is a Fermi decomposition worksheet, not a lone number. The honest constraint: the cancellation only works when the factors are independent, and the benefit is real mainly for large, unfamiliar quantities - not ordinary ones you could estimate directly.
When to Use
- You need a numeric magnitude and no lookup-able data and no genuine reference class exists, so the number has to be built from factors.
- The quantity is large and unfamiliar (market size, total load, total cost, a conversion count you cannot look up) - the regime where decomposition actually helps.
- An order-of-magnitude answer with an honest band is useful for sizing, sanity-checking, or triage; the number does not have to be exact.
- You want the estimate inspectable: each factor, its basis, and its band exposed so a reader can challenge one number, not an opaque total.
When NOT to Use
- A genuine reference class with real base-rate data exists. Then anchor on that data, not on invented factors - use
think-reference-class-forecasting. Fermi is precisely the build-from-factors method for when no such class exists; if you have real base rates, reference-class forecasting is strictly better.
- The task only needs the question decomposed for coverage, not a number. If you want a mutually-exclusive, collectively-exhaustive breakdown of a question and explicitly no estimate, use
think-issue-tree, which produces a tree and produces no number. Fermi exists to produce a number; do not use it when a number is not wanted.
- The quantity is ordinary and familiar. Decomposing something you could estimate directly adds noise; the decomposition benefit was absent or negative in that regime (see
evidence/dossier.md).
- The factors share a driver (correlated). Multiplicative error-cancellation fails when factors move together; the chain can be worse than one careful guess. Flag it and restructure to independent factors, or stop.
- Never emit a point estimate with no low/high band. A Fermi number without its range hides the uncertainty the method exists to expose.
Instructions
When asked to estimate a magnitude with no data to look up, follow these steps:
- State the target quantity precisely, with its unit. Confirm there is no real base-rate data or reference class to use instead (if there is, route to
think-reference-class-forecasting). Confirm a number is actually wanted (if not, route to think-issue-tree).
- Build the multiplicative factor chain. Write the unknown as a product of sub-quantities, each one small and familiar enough to guess to within roughly a factor. Keep the chain short; prefer factors you can anchor.
- Give each factor a band and a basis. For every factor, state a low / best / high guess, and where the number came from (a known datum, an analogy, a plausible range). A factor with no stated basis is just a guess in disguise.
- Run the independence check. Ask whether any two factors share a driver (move together). If they do, the error-cancellation premise breaks - flag the correlated factors and either restructure to independent factors or note that the range is unreliable.
- Combine. Multiply the best-guesses for the point estimate. Multiply the lows for the range floor and the highs for the range ceiling to get the compounded low/high range. Report the estimate as the point value and the range, never the point alone.
- Flag the dominant uncertainty. Name the one factor whose band most widens the combined range - that is where tightening one guess would most improve the answer.
- Emit the Fermi decomposition worksheet per
references/TEMPLATE.md.
Output Format
Use the template in references/TEMPLATE.md. The deliverable is the worksheet: the factor chain, per-factor low/best/high with bases, the point estimate, the compounded low/high range, the independence check, and the dominant-uncertainty flag - not a single number and not prose.
Quality Checklist
Before finalizing, verify:
Evidence
Tier M/P, transferred-evidence. The mechanism - judgmental multiplicative decomposition - has some controlled support: MacGregor & Armstrong (2007, Decision Sciences, "Judgmental Decomposition: When Does It Work?") and MacGregor (2001, in Armstrong ed., Principles of Forecasting) report that breaking an estimate into parts and recombining can reduce error - that earns the M half. Three facts cap it below a clean M and demand honesty: (1) the benefit is conditional, present for extreme/uncertain (large, unfamiliar) quantities and absent or negative for ordinary ones; (2) the multiplicative cancellation premise is sensitive to correlated component errors, which erode the benefit; (3) the base is essentially a single multi-problem study line plus field lore (the "within an order of magnitude" track record) plus a statistical argument (log-normal / geometric-mean cancellation), not replicated or meta-analytic. This skill therefore cites no effect-size figure; widely-repeated numbers could not be verified to a primary source and would overstate the grade. The evidence is human-subject, not AI-agent-validated. Full grading, sources, and the deliberately-omitted statistics: evidence/dossier.md.
Examples
See references/EXAMPLE.md for a completed Fermi decomposition worksheet on the shared Northwind scenario.