Calculus I · 2A · lesson
Chain Rule with Trigonometric Functions
Learn chain rule with trigonometric functions 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 trigonometric functions 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 trigonometric functions with nontrivial inputs.
Trigonometric Compositions
Before the formulas
Composition is the hidden architecture of Chain Rule with Trigonometric Functions. An expression may look like one formula while actually containing several function machines. Draw or list the stages before differentiating. This is especially important when product, quotient, and chain rules appear together, because the outer algebraic connection and the inner compositions must both be respected.
Do not simplify away useful structure too early. A factored derivative often shows each chain factor more clearly and is easier to verify. Simplify after the calculus unless rewriting first genuinely reduces the number of rules required.
Trig functions often hide a changing angle
The derivative of is , but is not receiving the input directly. Its angle changes at rate , so the final derivative must include that factor.
Read "sine of something" as an outer sine function attached to an inner angle function. This language makes the chain rule visible before any symbols are manipulated.
A trigonometric formula such as describes an oscillation whose phase changes four times as fast as . The chain-rule factor records that increased frequency. Without it, the derivative would describe the wrong physical speed.
The same idea applies to shifted and nonlinear phases. In , the angle itself accelerates because changes at rate . The derivative combines the local slope of cosine with that changing phase rate.
The basic patterns are
with analogous rules for the remaining trig functions.
A sine of a quadratic
Differentiate
Worked solution
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A squared trig function
For ,
The expression is a composition: square the value of sine.
Tangent with a reciprocal input
so
chain-trig-01Differentiate .
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Show hint
Differentiate sine first, then multiply by the derivative of 3x^2.
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A pendulum's angular speed
For a small oscillation, suppose
radians. Then
radians per second. The factor is the phase rate. Omitting it would understate every angular speed by a factor of three.
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