3.8 Implicit Differentiation | Calculus Volume 1 (2024)

We have already studied how to find equations of tangent lines to functions and the rate of change of a function at a specific point. In all these cases we had the explicit equation for the function and differentiated these functions explicitly. Suppose instead that we want to determine the equation of a tangent line to an arbitrary curve or the rate of change of an arbitrary curve at a point. In this section, we solve these problems by finding the derivatives of functions that define [latex]y[/latex] implicitly in terms of [latex]x[/latex].

In most discussions of math, if the dependent variable [latex]y[/latex] is a function of the independent variable [latex]x[/latex], we express [latex]y[/latex] in terms of [latex]x[/latex]. If this is the case, we say that [latex]y[/latex] is an explicit function of [latex]x[/latex]. For example, when we write the equation [latex]y=x^2+1[/latex], we are defining [latex]y[/latex] explicitly in terms of [latex]x[/latex]. On the other hand, if the relationship between the function [latex]y[/latex] and the variable [latex]x[/latex] is expressed by an equation where [latex]y[/latex] is not expressed entirely in terms of [latex]x[/latex], we say that the equation defines [latex]y[/latex] implicitly in terms of [latex]x[/latex]. For example, the equation [latex]y-x^2=1[/latex] defines the function [latex]y=x^2+1[/latex] implicitly.

Implicit differentiation allows us to find slopes of tangents to curves that are clearly not functions (they fail the vertical line test). We are using the idea that portions of [latex]y[/latex] are functions that satisfy the given equation, but that [latex]y[/latex] is not actually a function of [latex]x[/latex].

In general, an equation defines a function implicitly if the function satisfies that equation. An equation may define many different functions implicitly. For example, the functions

[latex]y=\sqrt{25-x^2}[/latex], [latex]y = -\sqrt{25-x^2}[/latex], and [latex]y=\begin{cases} \sqrt{25-x^2} & \text{if} \, -5 \le x < 0 \\ -\sqrt{25-x^2} & \text{if} \, 0 \le x \le 5 \end{cases}[/latex], which are illustrated in (Figure), are just three of the many functions defined implicitly by the equation [latex]x^2+y^2=25[/latex].

3.8 Implicit Differentiation | Calculus Volume 1 (1)

Figure 1. The equation [latex]{x}^{2}+{y}^{2}=25[/latex] defines many functions implicitly.

If we want to find the slope of the line tangent to the graph of [latex]x^2+y^2=25[/latex] at the point [latex](3,4)[/latex], we could evaluate the derivative of the function [latex]y=\sqrt{25-x^2}[/latex] at [latex]x=3[/latex]. On the other hand, if we want the slope of the tangent line at the point [latex](3,-4)[/latex], we could use the derivative of [latex]y=−\sqrt{25-x^2}[/latex]. However, it is not always easy to solve for a function defined implicitly by an equation. Fortunately, the technique of implicit differentiation allows us to find the derivative of an implicitly defined function without ever solving for the function explicitly. The process of finding [latex]\frac{dy}{dx}[/latex] using implicit differentiation is described in the following problem-solving strategy.

Problem-Solving Strategy: Implicit Differentiation

To perform implicit differentiation on an equation that defines a function [latex]y[/latex] implicitly in terms of a variable [latex]x[/latex], use the following steps:

  1. Take the derivative of both sides of the equation. Keep in mind that [latex]y[/latex] is a function of [latex]x[/latex]. Consequently, whereas [latex]\frac{d}{dx}(\sin x)= \cos x, \, \frac{d}{dx}(\sin y)= \cos y\frac{dy}{dx}[/latex] because we must use the Chain Rule to differentiate [latex]\sin y[/latex] with respect to [latex]x[/latex].
  2. Rewrite the equation so that all terms containing [latex]\frac{dy}{dx}[/latex] are on the left and all terms that do not contain [latex]\frac{dy}{dx}[/latex] are on the right.
  3. Factor out [latex]\frac{dy}{dx}[/latex] on the left.
  4. Solve for [latex]\frac{dy}{dx}[/latex] by dividing both sides of the equation by an appropriate algebraic expression.

Using Implicit Differentiation

Assuming that [latex]y[/latex] is defined implicitly by the equation [latex]x^2+y^2=25[/latex], find [latex]\frac{dy}{dx}[/latex].

Show Solution

Analysis

Note that the resulting expression for [latex]\frac{dy}{dx}[/latex] is in terms of both the independent variable [latex]x[/latex] and the dependent variable [latex]y[/latex]. Although in some cases it may be possible to express [latex]\frac{dy}{dx}[/latex] in terms of [latex]x[/latex] only, it is generally not possible to do so.

Using Implicit Differentiation and the Product Rule

Assuming that [latex]y[/latex] is defined implicitly by the equation [latex]x^3 \sin y+y=4x+3[/latex], find [latex]\frac{dy}{dx}[/latex].

Show Solution

Using Implicit Differentiation to Find a Second Derivative

Find [latex]\frac{d^2 y}{dx^2}[/latex] if [latex]x^2+y^2=25[/latex].

Show Solution

Find [latex]\frac{dy}{dx}[/latex] for [latex]y[/latex] defined implicitly by the equation [latex]4x^5+ \tan y=y^2+5x[/latex].

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Hint

Follow the problem solving strategy, remembering to apply the chain rule to differentiate [latex]\tan y[/latex] and [latex]y^2[/latex].

For the following exercises, use implicit differentiation to find [latex]\frac{dy}{dx}[/latex].

1.[latex]x^2-y^2=4[/latex]

2.[latex]6x^2+3y^2=12[/latex]

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3.[latex]x^2 y=y-7[/latex]

4.[latex]3x^3+9xy^2=5x^3[/latex]

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5.[latex]xy- \cos (xy)=1[/latex]

6.[latex]y\sqrt{x+4}=xy+8[/latex]

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7.[latex]−xy-2=\frac{x}{7}[/latex]

8.[latex]y \sin(xy)=y^2+2[/latex]

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9.[latex](xy)^2+3x=y^2[/latex]

10.[latex]x^3 y+xy^3=-8[/latex]

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For the following exercises, find the equation of the tangent line to the graph of the given equation at the indicated point. Use a calculator or computer software to graph the function and the tangent line.

11. [T][latex]x^4 y-xy^3=-2, \, (-1,-1)[/latex]

12. [T][latex]x^2 y^2+5xy=14, \, (2,1)[/latex]

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13. [T][latex]\tan (xy)=y, \, (\frac{\pi}{4},1)[/latex]

14. [T][latex]xy^2 + \sin(\pi y)-2x^2=10, \, (2,-3)[/latex]

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15. [T][latex]\frac{x}{y}+5x-7=-\frac{3}{4}y, \, (1,2)[/latex]

16. [T][latex]xy+ \sin (x)=1, \, (\frac{\pi}{2},0)[/latex]

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17. [T] The graph of a folium of Descartes with equation [latex]2x^3+2y^3-9xy=0[/latex] is given in the following graph.

3.8 Implicit Differentiation | Calculus Volume 1 (2)

  1. Find the equation of the tangent line at the point [latex](2,1)[/latex]. Graph the tangent line along with the folium.
  2. Find the equation of the normal line to the tangent line in a. at the point [latex](2,1)[/latex].

18.For the equation [latex]x^2+2xy-3y^2=0[/latex],

  1. Find the equation of the normal to the tangent line at the point [latex](1,1)[/latex].
  2. At what other point does the normal line in a. intersect the graph of the equation?

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19.Find all points on the graph of [latex]y^3-27y=x^2-90[/latex] at which the tangent line is vertical.

20.For the equation [latex]x^2+xy+y^2=7[/latex],

  1. Find the [latex]x[/latex]-intercept(s).
  2. Find the slope of the tangent line(s) at the [latex]x[/latex]-intercept(s).
  3. What does the value(s) in b. indicate about the tangent line(s)?

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21.Find the equation of the tangent line to the graph of the equation [latex]\sin^{-1} x+\sin^{-1} y=\frac{\pi}{6}[/latex] at the point [latex](0,\frac{1}{2})[/latex].

22.Find the equation of the tangent line to the graph of the equation [latex]\tan^{-1}(x+y)=x^2+\frac{\pi}{4}[/latex] at the point [latex](0,1)[/latex].

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23.Find [latex]y^{\prime}[/latex] and [latex]y''[/latex] for [latex]x^2+6xy-2y^2=3[/latex].

24. [T] The number of cell phones produced when [latex]x[/latex] dollars is spent on labor and [latex]y[/latex] dollars is spent on capital invested by a manufacturer can be modeled by the equation [latex]60x^{3/4}y^{1/4}=3240[/latex].

  1. Find [latex]\frac{dy}{dx}[/latex] and evaluate at the point [latex](81,16)[/latex].
  2. Interpret the result of a.

Show Solution

25. [T] The number of cars produced when [latex]x[/latex] dollars is spent on labor and [latex]y[/latex] dollars is spent on capital invested by a manufacturer can be modeled by the equation [latex]30x^{1/3}y^{2/3}=360[/latex].

(Both [latex]x[/latex] and [latex]y[/latex] are measured in thousands of dollars.)

  1. Find [latex]\frac{dy}{dx}[/latex] and evaluate at the point [latex](27,8)[/latex].
  2. Interpret the result of a.

26.The volume of a right circular cone of radius [latex]x[/latex] and height [latex]y[/latex] is given by [latex]V=\frac{1}{3}\pi x^2 y[/latex]. Suppose that the volume of the cone is [latex]85\pi \, \text{cm}^3[/latex]. Find [latex]\frac{dy}{dx}[/latex] when [latex]x=4[/latex] and [latex]y=16[/latex].

Show Solution

For the following exercises, consider a closed rectangular box with a square base with side [latex]x[/latex] and height [latex]y[/latex].

27.Find an equation for the surface area of the rectangular box, [latex]S(x,y)[/latex].

28.If the surface area of the rectangular box is 78 square feet, find [latex]\frac{dy}{dx}[/latex] when [latex]x=3[/latex] feet and [latex]y=5[/latex] feet.

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For the following exercises, use implicit differentiation to determine [latex]y^{\prime}[/latex]. Does the answer agree with the formulas we have previously determined?

29.[latex]x= \sin y[/latex]

30.[latex]x= \cos y[/latex]

Show Solution

31.[latex]x= \tan y[/latex]

3.8 Implicit Differentiation | Calculus Volume 1 (2024)

FAQs

How do I get better at implicit differentiation? ›

The trick to using implicit differentiation is remembering that every time you take a derivative of y, you must multiply by dy/dx. Furthermore, you'll often find this method is much easier than having to rearrange an equation into explicit form if it's even possible.

What is an example of an implicit function? ›

The function y = x2 + 2x + 1 that we found by solving for y is called the implicit function of the relation y − 1 = x2 + 2x. In general, any function we get by taking the relation f(x, y) = g(x, y) and solving for y is called an implicit function for that relation.

What is implicit differentiation used for? ›

Implicit differentiation is useful for, among other things, finding tangent and normal lines to a curve that cannot be expressed in the form y=f(x) y = f ( x ) .

How to use implicit differentiation to find the slope of a tangent line? ›

Take the derivative of the given function. Evaluate the derivative at the given point to find the slope of the tangent line. Plug the slope of the tangent line and the given point into the point-slope formula for the equation of a line, ( y − y 1 ) = m ( x − x 1 ) (y-y_1)=m(x-x_1) (y−y1​)=m(x−x1​), then simplify.

What is the chain rule for implicit differentiation? ›

Implicit differentiation helps us find ​dy/dx even for relationships like that. This is done using the chain ​rule, and viewing y as an implicit function of x. For example, according to the chain rule, the derivative of y² would be 2y⋅(dy/dx).

How to solve implicit functions? ›

First differentiate the entire expression f(x, y) = 0, with reference to one independent variable x. As a second step, find the dy/dx of the expression by algebraically moving the variables. The final answer of the differentiation of implicit function would have both variables.

What are two example of implicit? ›

Examples of implicit in a Sentence

There is a sense of moral duty implicit in her writings. I have implicit trust in her honesty. These examples are programmatically compiled from various online sources to illustrate current usage of the word 'implicit.

How to tell if a function is implicit or explicit? ›

An implicit function is one that has several variables, one of which is a function of the other set of variables. An explicit function is one in which the dependent variable can be written explicitly in terms of the independent variable. f(x, y) = 0 is the general form of an implicit function.

What is implicit differentiation better explained? ›

Implicit differentiation is the procedure of differentiating an implicit equation with respect to the desired variable x while treating the other variables as unspecified functions of x.

How is implicit differentiation used in real life? ›

Example 1: Engineering

In engineering, implicit differentiation can be used to determine how varying one physical property (such as pressure) might impact another (such as volume) when they are related through an equation that does not explicitly define one as a function of the other.

How to find y-intercept implicit differentiation? ›

Through implicit differentiation, the derivative is d y d x = − x y . So the y-intercept formula is y y i = y − x ( − x y ) = x 2 + y 2 y = r 2 y , and x-intercept formula is y x i = x − y ( − y x ) = x 2 + y 2 x = r 2 x .

What is the derivative of 2xy? ›

Therefore differentiating 2xy would become 2y + 2x(dy/dx) (Differentiating any term involving any other variable other than x with respect to x would require implicit differentiation).

How to logarithmic differentiation? ›

Logarithmic Differentiation
  1. Step 1 Take the natural logarithm of both sides.
  2. Step 2 Expand using properties of logarithms.
  3. Step 3 Differentiate both sites. Use the product rule on the right.
  4. Step 4 Multiply by Y on both sides. Step 5 Substitute y equals 2x^4 + 1, all raised to the exponent tangent x.

How do you gain differentiation advantage? ›

These are:
  1. become the low-cost supplier.
  2. develop differentiated, innovative products and services.
  3. target a niche—geography, industry, product/service.
  4. employ differentiated business methods and approaches.
Jun 24, 2024

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