Calculus I · 2B · exploration
Sensitivity, Elasticity, and Condition Numbers
Explore sensitivity, elasticity, and condition numbers in an optional advanced note connecting Calculus I to later analysis and mathematical theory.
Section overview
Optional advanced explorationsWhat this section is building
Explore sensitivity, elasticity, and condition numbers in an optional advanced note connecting Calculus I to later analysis and mathematical theory.
Advanced results connect derivative evidence to error amplification, convergence speed, or global optimality under explicit hypotheses.
State the hypotheses before the conclusion and test the result on a concrete numerical or graphical example.
Quoting elasticity, quadratic convergence, or convexity without checking units, root simplicity, or the relevant domain.
How Input Error Becomes Output Error
The approximation
measures absolute sensitivity. Dividing by and rewriting gives
The factor
is called elasticity in economics and a relative condition number in numerical analysis, up to absolute value.
For , . A relative input error produces approximately an relative output error. This explains why volume is three times as sensitive, in relative terms, as radius.
Read this graph as text
Elasticity measures how relative input error is amplified. Absolute sensitivity uses f'(x) . Relative sensitivity uses the dimensionless factor E(x)=x f'(x)/f(x) , which predicts the approximate percentage output change caused by a one-percent input change. The first box measures error as a fraction of the input rather than in raw units. Elasticity multiplies that fraction. The result is a fractional output error, so the comparison works across quantities with different units and scales. Large |E(x)| warns that small relative input errors may be strongly amplified.
Every relationship in elasticity measures how relative input error is amplified is identified with written labels plus distinct solid, dashed, dotted, double, marker, or pattern cues; color is never the only carrier of meaning.
Why it matters: This visual distinguishes absolute derivative sensitivity from relative conditioning. It should help students understand why a derivative of 1000 is not automatically "large" and why percentage comparisons often provide the meaningful scale.
Absolute sensitivity uses f'(x). Relative sensitivity uses the dimensionless factor E(x)=x f'(x)/f(x), which predicts the approximate percentage output change caused by a one-percent input change.
A badly conditioned subtraction
When two nearly equal measured numbers are subtracted, the result may be tiny compared with either input. Small absolute measurement errors can then become enormous relative errors in the difference. Derivatives and condition numbers help identify such unstable calculations before they are trusted.
Source & rights
Original instruction with traceable references.
BetterGrades-original composition declared by source handoff; owner provenance review required before public release
Reference textbooks remain rights-separated and are not published as application assets. Any direct adaptation requires separate identification and attribution.