Implicit Differentiation

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Presentation transcript:

Implicit Differentiation 3.7 Implicit Differentiation

Quick Review

Quick Review

Quick Review

Quick Review Solutions

Quick Review Solutions

Quick Review Solutions

What you’ll learn about Implicitly Defined Functions Lenses, Tangents, and Normal Lines Derivatives of Higher Order Rational Powers of Differentiable Functions … and why Implicit differentiation allows us to find derivatives of functions that are not defined or written explicitly as a function of a single variable.

Implicitly Defined Functions

Implicitly Defined Functions

Example Implicitly Defined Functions

Implicit Differentiation Process

Lenses, Tangents and Normal Lines In the law that describes how light changes direction as it enters a lens, the important angles are the angles the light makes with the line perpendicular to the surface of the lens at the point of entry (angles A and B in Figure 3.50). This line is called the normal to the surface at the point of entry. In a profile view of a lens, the normal is a line perpendicular to the tangent to the profile curve at the point of entry. Implicit differentiation is often used to find the tangents and normals of lenses described as quadratic curves.

Lenses, Tangents and Normal Lines

Example Lenses, Tangents and Normal Lines

Example Lenses, Tangents and Normal Lines

Example Derivatives of a Higher Order

Rule 9 Power Rule For Rational Powers of x