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Chapter 8: Problem 26

Determine whether the following equations are separable. If so, solve the initial value problem. $$y^{\prime}(t)=\cos ^{2} y, y(1)=\frac{\pi}{4}$$

Short Answer

Expert verified
Question: Solve the initial value problem for the given differential equation and initial condition. Differential Equation: $$ y'(t) = \cos^2{y} $$ Initial Condition: $$ y(1) = \frac{\pi}{4} $$ Answer: The solution to the initial value problem is $$ y(t) = \arctan{t} $$ with the initial condition $$ y(1) = \frac{\pi}{4} $$.

Step by step solution

01

Determine if the equation is separable

The equation is given as: $$ y'(t) = \cos^2{y} $$ Compare it to the form \(y'(t) = f(t)g(y)\). We can rewrite the right-hand side as: $$ y'(t) = (1)(\cos^2{y}) $$ Clearly, \(f(t) = 1\) and \(g(y) = \cos^2{y}\). The equation is separable.
02

Apply separation of variables

Now that we have confirmed that the equation is separable, we will separate the variables and rewrite the equation in the form: $$ \frac{dy}{\cos^2{y}} = dt $$
03

Integrate both sides

Integrate both sides of the equation: $$ \int \frac{dy}{\cos^2{y}} = \int dt $$ The left side can be integrated using the substitution technique with \(u = \tan{y}\) and \(du = \sec^2{y}dy\), giving: $$ \int du = \int dt $$
04

Solve for y(t)

Integrate both sides: $$ u = t + C $$ Substitute back for \(y\): $$ \tan{y} = t + C $$ So, we have $$ y(t) = \arctan{(t + C)} $$
05

Apply the initial condition

Now, we'll use the initial condition \(y(1) = \frac{\pi}{4}\) to find the constant \(C\). $$ y(1) = \arctan{(1 + C)} = \frac{\pi}{4} $$ We can find the value of \(C\) by taking the tangent of both sides: $$ \tan{y(1)} = 1 + C \Rightarrow \tan{\frac{\pi}{4}} = 1 + C $$ Since \(\tan{\frac{\pi}{4}} = 1\), we have: $$ 1 = 1 + C \Rightarrow C = 0 $$
06

Write the final solution

Now, substitute the value of \(C\) back into the equation for \(y(t)\): $$ y(t) = \arctan{(t + 0)} = \arctan{t} $$ This is the solution to the initial value problem: $$ y(t) = \arctan{t}, y(1) = \frac{\pi}{4} $$

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Initial Value Problem
An initial value problem is a type of differential equation along with a specified condition called the initial condition. This initial condition usually involves the value of the unknown function at a certain point. In simple terms, it tells us where the solution to the differential equation should begin.

To capture this, an initial value problem is often framed as follows:
  • A differential equation in terms of the function and its derivatives.
  • An initial condition that specifies the value of the function at a particular point.
In the exercise above, the differential equation is given by:\[ y'(t) = \cos^2{y} \]and the initial condition is:\[ y(1) = \frac{\pi}{4} \]This means we are looking for a function \( y(t) \) that satisfies both the equation and the condition at \( t = 1 \). The initial condition helps to find a unique solution from the family of possible solutions, ensuring that the solution fits the problem context.
Integration Techniques
To solve separable differential equations, integration techniques are essential. Once we have separated the variables, each side of the equation is integrated separately to help find the solution.

For instance, in the given problem, after separating variables, we arrived at:\[ \int \frac{dy}{\cos^2{y}} = \int dt \]The left side of the equation often requires specific integration techniques, such as substitution, while the right side is typically straightforward to integrate, usually resulting in just the variable, \( t \), plus a constant.

Understanding which integration technique to apply depends on the form of the functions involved:
  • Direct Integration: Used when simple antiderivatives are involved.
  • Substitution: Helpful for transforming a difficult integral into a simpler one, often used when a function's derivative is present in the equation.
By properly applying these techniques, we can evaluate integrals and proceed to solve the equation.
Substitution Method
The substitution method is a powerful tool in integration, often used for simplifying the problem or when part of the integral matches a derivative of a function. This method involves substituting part of the original integral with a new variable, making it easier to integrate.

In the problem given, we used substitution to integrate \( \frac{dy}{\cos^2{y}} \). By letting \( u = \tan{y} \), the derivative \( du = \sec^2{y}dy \) was used. Since \( \frac{dy}{\cos^2{y}} = \tan{y} \), this substitution simplified the equation to:\[ \int du = \int dt \]
  • First, identify a substitution that simplifies the integral.
  • Make the substitution, replacing the original variable with the new one.
  • Solve the resulting simpler integral.
Finally, it is important to remember to substitute back the original variable once the integration is complete, resulting in a solution in terms of the original variables used in the problem.

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Most popular questions from this chapter

Determine whether the following equations are separable. If so, solve the initial value problem. $$\frac{d y}{d t}=t y+2, y(1)=2$$

For each of the following stirred tank reactions, carry out the following analysis. a. Write an initial value problem for the mass of the substance. b. Solve the initial value problem and graph the solution to be sure that \(m(0)\) and \(\lim _{t \rightarrow \infty} m(t)\) are correct. A \(1500-L\) tank is initially filled with a solution that contains \(3000 \mathrm{g}\) of salt. A salt solution with a concentration of \(20 \mathrm{g} / \mathrm{L}\) flows into the tank at a rate of \(3 \mathrm{L} / \mathrm{min.}\) The thoroughly mixed solution is drained from the tank at a rate of \(3 \mathrm{L} / \mathrm{min}\)

Solution of the logistic equation Use separation of variables to show that the solution of the initial value problem $$P^{\prime}(t)=r P\left(1-\frac{P}{K}\right), \quad P(0)=P_{0}$$ $$\text { is } P(t)=\frac{K}{\left(\frac{K}{P_{0}}-1\right) e^{-n}+1}$$

U.S. population projections According to the U.S. Census Bureau, the nation's population (to the nearest million) was 281 million in 2000 and 310 million in \(2010 .\) The Bureau also projects a 2050 population of 439 million. To construct a logistic model, both the growth rate and the carrying capacity must be estimated. There are several ways to estimate these parameters. Here is one approach: a. Assume that \(t=0\) corresponds to 2000 and that the population growth is exponential for the first ten years; that is, between 2000 and \(2010,\) the population is given by \(P(t)=P(0) e^{n}\) Estimate the growth rate \(r\) using this assumption. b. Write the solution of the logistic equation with the value of \(r\) found in part (a). Use the projected value \(P(50)=439 \mathrm{mil}\) lion to find a value of the carrying capacity \(K\) c. According to the logistic model determined in parts (a) and (b), when will the U.S. population reach \(95 \%\) of its carrying capacity? d. Estimations of this kind must be made and interpreted carefully. Suppose the projected population for 2050 is 450 million rather than 439 million. What is the value of the carrying capacity in this case? e. Repeat part (d) assuming the projected population for 2050 is 430 million rather than 439 million. What is the value of the carrying capacity in this case? f. Comment on the sensitivity of the carrying capacity to the 40-year population projection.

Let \(y(t)\) be the population of a species that is being harvested, for \(t \geq 0 .\) Consider the harvesting model \(y^{\prime}(t)=0.008 y-h, y(0)=y_{0},\) where \(h\) is the annual harvesting rate, \(y_{0}\) is the initial population of the species, and \(t\) is measured in years. a. If \(y_{0}=2000,\) what harvesting rate should be used to maintain a constant population of \(y=2000,\) for \(t \geq 0 ?\) b. If the harvesting rate is \(h=200 /\) year, what initial population ensures a constant population?
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