Calculus I · 2A · lesson
Chain Rule with Exponentials and Logarithms
Learn chain rule with exponentials and logarithms with clear exposition, guided derivations, worked examples, visuals, checks, and interpretation.
Section overview
The chain rule and compositionsWhat this section is building
Learn chain rule with exponentials and logarithms with clear exposition, guided derivations, worked examples, visuals, checks, and interpretation.
A small input change passes through a sequence of machines; the total response multiplies the response at each stage.
List the layers, differentiate one layer at a time, and stop only when every input-dependent layer contributes.
Differentiating the outside and leaving the inside unchanged without its derivative factor.
Learning objectives
Differentiate , , and .
Exponential and Logarithmic Compositions
Exponential and logarithmic layers preserve their inner expressions
For , the outer derivative remains , then the chain rule contributes . For , the outer derivative is the reciprocal of the inner expression, then multiplication by completes the rate conversion.
Parentheses are essential. Writing makes the whole inner function the denominator, which is exactly what the logarithmic derivative requires.
Before the formulas
In Chain Rule with Exponentials and Logarithms, the phrase "outside to inside" is useful only when paired with structure. Keep the inner expression unchanged while differentiating the outer layer, then multiply by the derivative of that inner expression. If the inner expression is itself composite, continue inward.
A missing inner derivative is the signature chain-rule error. Check units or scaling to catch it. If an inner quantity changes three times as fast, the final output rate should reflect that factor of three. The chain rule is a rate-conversion law, not punctuation attached to parentheses.
Exponential and logarithmic compositions appear whenever a model transforms a changing quantity multiplicatively or by scale. Their derivatives follow compact patterns, but each pattern is still the chain rule:
For logarithms, the sign and domain of require attention. In many derivative problems works on intervals where , but the underlying interval must not cross a zero of .
An exponential of a quadratic
Differentiate
Worked solution
Write a real attempt before opening the supplied answer.
A logarithm that simplifies the chain rule
Differentiate
Worked solution
Write a real attempt before opening the supplied answer.
A general exponential composition
For ,
The derivative is . The simple rule applies only when the logarithm's input is exactly .
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