Chapter 8: Problem 26
Solve the following initial value problems. $$y^{\prime}(x)=4 \sec ^{2} 2 x, y(0)=8$$
Short Answer
Expert verified
Answer: The solution to the given initial value problem is \(y(x) = 2\tan{2x} + 8\).
Step by step solution
01
Integrate the ODE
To find the general solution, we integrate both sides of the equation with respect to x:
$$\int y'(x) dx = \int 4\sec^2{2x} dx.$$
Recall that the integral of \(\sec^2{x}\) is equal to \(\tan{x}\). We then apply the integration by substitution method, and let \(u = 2x\). Therefore, \(\frac{1}{2}du = dx\). Now, our integral becomes:
$$\int y'(x) dx = \int 4\sec^2{u} \left(\frac{1}{2}du\right).$$
Integrate with respect to \(u\):
$$y(x) = 2\int\sec^2{u} du = 2\tan{u} + C = 2\tan{2x} + C.$$
02
Apply the initial condition
We are given the initial condition: \(y(0) = 8\). Using this condition, we can find the constant \(C\):
$$8 = 2\tan{2(\textscale{.87}{0})} + C = 2\tan{0} + C = 0 + C.$$
Thus, \(C = 8\).
03
Write the final solution
We now substitute the value of \(C\) back into the general solution to find the specific solution:
$$y(x) = 2\tan{2x} + 8.$$
So, the solution to the given initial value problem is:
$$y(x) = 2\tan{2x} + 8.$$
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Key Concepts
These are the key concepts you need to understand to accurately answer the question.
Initial Value Problems
Initial value problems (IVPs) involve solving differential equations with an added condition, called the initial condition. These conditions specify the value of the unknown function at a particular point, such as in the equation \(y'(x) = 4 \sec^2{2x},\) with the condition \(y(0) = 8\).
These problems typically necessitate finding a particular solution that satisfies both the differential equation and the initial condition.
Often, the process involves the following steps:
These problems typically necessitate finding a particular solution that satisfies both the differential equation and the initial condition.
Often, the process involves the following steps:
- Solving the differential equation to find the general solution.
- Applying the initial condition to the general solution to solve for any constants.
- Substituting back to find the particular solution that satisfies the IVP.
Integration by Substitution
Integration by substitution is a powerful technique that simplifies the process of integrating complex functions. It is akin to the chain rule in differentiation, helping to manage integral expressions by changing variables.
In our example, the integral \(\int 4\sec^2{2x}\ dx\) was transformed using substitution by letting \(u = 2x\). Consequently, \(dx\) became \(\frac{1}{2}du\).
This makes the integral of \(4\sec^2{u}\cdot\frac{1}{2}du\). This substitution transforms a seemingly difficult integral into a form which is more straightforward to evaluate.
The advantage is that you can use known integration results, such as \(\int \sec^2{u} = \tan{u}\), to solve the integral easily.
In our example, the integral \(\int 4\sec^2{2x}\ dx\) was transformed using substitution by letting \(u = 2x\). Consequently, \(dx\) became \(\frac{1}{2}du\).
This makes the integral of \(4\sec^2{u}\cdot\frac{1}{2}du\). This substitution transforms a seemingly difficult integral into a form which is more straightforward to evaluate.
The advantage is that you can use known integration results, such as \(\int \sec^2{u} = \tan{u}\), to solve the integral easily.
General Solution
The general solution of a differential equation includes all possible solutions generated by varying an arbitrary constant. This constant is crucial as it enables the solution to represent a family of curves rather than a single curve.
In the given ODE, the general solution after integration was \(y(x) = 2\tan{2x} + C\). This expression represents a continuum of solutions depending on the value of \(C\).
The general solution is like a template, flexible and adaptable to different conditions, until it is further refined by specific data, like initial conditions.
In the given ODE, the general solution after integration was \(y(x) = 2\tan{2x} + C\). This expression represents a continuum of solutions depending on the value of \(C\).
The general solution is like a template, flexible and adaptable to different conditions, until it is further refined by specific data, like initial conditions.
Particular Solution
The particular solution is the version of the general solution that specifically satisfies the initial condition provided in the problem.
By using the initial condition \(y(0) = 8\), we solved for the arbitrary constant \(C\). This resulted in the final solution \(y(x) = 2\tan{2x} + 8\).
This solution is a single curve that crosses a particular point, meeting both the requirements of the differential equation and the initial conditions.
It is critical in real-world applications because it provides an exact answer tailored to the unique constraints and data of the scenario at hand.
By using the initial condition \(y(0) = 8\), we solved for the arbitrary constant \(C\). This resulted in the final solution \(y(x) = 2\tan{2x} + 8\).
This solution is a single curve that crosses a particular point, meeting both the requirements of the differential equation and the initial conditions.
It is critical in real-world applications because it provides an exact answer tailored to the unique constraints and data of the scenario at hand.