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Chapter 2: Q19E (page 75)

Each DE in Problemsis a Bernoulli equation. In Problemssolve the given differential equation by using an appropriate substitution.

Short Answer

Expert verified

Answer:

The solution of the given differential equation is.

Step by step solution

01

Define substitution method for differentiation.

Often, the first step in solving a differential equation is to use a substitution to change it into another differential equation. In the differential equation , if can be any real number, it is called a Bernoulli’s equation. If and , Bernoulli’s equation is linear. If and , the substitution reduces Bernoulli’s equation to a linear equation.

02

Find the derivative of the function using chain rule.

Divide the equation on both sides by .

… (1)

Let, and take the derivative ofwith respect to.

Define the derivative of the function using the chain rule as shown below.

Substitute the values of and in equation (1).

03

Separate the variables and integrate the function.

Let the integrating factor be,

Integrate on both sides.

Substituteforinto the above equation.

Thus, the solution of the given differential equation is.

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Most popular questions from this chapter

In Problems, 1–4 reproduces the given computer-generated direction field. Then sketch, by hand, an approximate solution curve that passes through each of the indicated points. Use different colored pencils for each solution curve.

dydx=x2-y2a)y-2=1b)y3=0c)y0=2d)y0=0

FIGURE 2.1.12 Direction field for Problem 1

Consider the autonomous first-order differential equationand the initial condition. By hand, sketch the graph of a typical solution y(x) when y0has the given values.

(a) (b)

(c) (d)

Each DE in Problems 1 - 14is homogeneous. In Problems 1 - 10solve the given differential equation by using an appropriate substitution.

ydx = 2(x + y)dy

In Problems 37 and 38 solve the given initial-value problem by finding, as in Example 4, an appropriate integrating factor.

37.xdx+(x2y+4y)dy=0,y(4)=0

In Problems 1–22, solve the given differential equation by separation of variables.

dydx= x1 -y5
See all solutions

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