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Chapter 11: Problem 37

Decide whether the statement is true or false. Assume that \(y=f(x)\) is a solution to the equation \(d y / d x=2 x-y .\) Justify your answer. $$f^{\prime}(x)=2 x-f(x)$$

Short Answer

Expert verified
True, based on matching the differential equation.

Step by step solution

01

Understanding the Given Equation

We are given that the function \( y = f(x) \) is a solution to the differential equation \( \frac{dy}{dx} = 2x - y \). This initially implies that the derivative of \( y \) with respect to \( x \), denoted \( f'(x) \), equals \( 2x - f(x) \), as this directly translates the expression given.
02

Restating the Equation

Restate the given differential equation in terms of the function notation: \( f'(x) = 2x - f(x) \). This is exactly the statement we are asked to verify: "\( f'(x) = 2x - f(x) \)."
03

Analyzing the Statement

Since the problem statement asks if \( f'(x) = 2x - f(x) \) is true given \( y = f(x) \) solves \( \frac{dy}{dx} = 2x - y \), we compare both. The equation \( \frac{dy}{dx} = 2x - y \) directly translates to \( f'(x) = 2x - f(x) \), confirming the given statement.
04

Conclusion

Since the translated expression \( f'(x) = 2x - f(x) \) matches the problem's differential equation, we conclude that the statement "\( f'(x) = 2x - f(x) \)" is true.

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Key Concepts

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

Solution Verification
Solution verification is a crucial part of solving differential equations. It helps confirm whether our proposed solution indeed satisfies the initial equation. In this exercise, we are tasked with verifying the statement \( f'(x) = 2x - f(x) \). This statement serves as the derivative of the function \( y = f(x) \), which is claimed to satisfy the differential equation \( \frac{dy}{dx} = 2x - y \). To verify a solution, follow these steps:
  • Substitute the proposed solution into the differential equation.
  • Check if both sides of the equation are equal after simplification.
By substituting \( f'(x) \) with \( 2x - f(x) \) and comparing each side in this exercise, we find they match perfectly. This confirms that the given function indeed solves the equation.
First-Order Differential Equations
A first-order differential equation involves derivatives of the first degree and no higher derivatives. A general form is written as \( \frac{dy}{dx} = g(x, y) \), where \( g(x, y) \) is some function of \( x \) and \( y \). In our case, the differential equation \( \frac{dy}{dx} = 2x - y \) is a classic example of a linear first-order differential equation. Key Characteristics of First-Order Differential Equations:
  • They only involve first derivatives, meaning only \( \frac{dy}{dx} \), and not involvement of any \( \frac{d^2y}{dx^2} \) or higher derivatives.
  • The equation describes the rate at which \( y \) changes concerning \( x \).
  • Such equations are pivotal in modeling several real-world systems, including population growth and decay processes.
For the equation \( \frac{dy}{dx} = 2x - y \), finding solutions typically involves techniques like separation of variables or integrating factors, though sometimes direct substitution verifies a proposed solution more efficiently.
Function Notation
Function notation is an essential tool that describes the rules used for transforming inputs (independent variables) into outputs (dependent variables). In calculus and differential equations, function notation simplifies expressions and helps communicate mathematical ideas clearly. Key Points:
  • Function notation is represented as \( y = f(x) \), where \( y \) is the output and \( x \) is the input.
  • It provides a concise way to compare equations, like the translation of a differential equation into \( f'(x) = 2x - f(x) \).
Here, \( f'(x) \) represents the derivative of \( f \), describing how \( y = f(x) \) changes. By using function notation, we directly relate the function's behavior through its derivatives, crucial in verifying solutions for differential equations.

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Most popular questions from this chapter

Decide whether the statement is true or false. Assume that \(y=f(x)\) is a solution to the equation \(d y / d x=2 x-y .\) Justify your answer. If \(f(a)=b,\) the slope of the graph of \(f\) at \((a, b)\) is \(2 a-b\)

Decide whether the statement is true or false. Assume that \(y=f(x)\) is a solution to the equation \(d y / d x=2 x-y .\) Justify your answer. All the inflection points of \(f\) lie on the line \(y=2 x-2\)

An object of mass \(m\) is thrown vertically upward from the surface of the earth with initial velocity \(v_{0} .\) We will calculate the value of \(v_{0},\) called the escape velocity, with which the object can escape the pull of the gravity and never return to earth. since the object is moving far from the surface of the earth, we must take into account the variation of gravity with altitude. If the acceleration due to gravity at sea level is \(g,\) and \(R\) is the radius of the earth, the gravitational force, \(F\), on the object of mass \(m\) at an altitude \(h\) above the surface of the earth is given by $$F=\frac{m g R^{2}}{(R+h)^{2}}$$. (a) The velocity of the object (measured upward) is \(v\) at time \(t .\) Use Newton's Second Law of Motion to show that $$\frac{d v}{d t}=-\frac{g R^{2}}{(R+h)^{2}}$$. (b) Rewrite this equation with \(h\) instead of \(t\) as the independent variable using the chain rule \(\frac{d v}{d t}=\frac{d v}{d h} \cdot \frac{d h}{d t}\) Hence, show that $$v \frac{d v}{d h}=-\frac{g R^{2}}{(R+h)^{2}}$$. (c) Solve the differential equation in part (b). (d) Find the escape velocity, the smallest value of \(v_{0}\) such that \(v\) is never zero.

According to an article in The New York Times,' ' pigweed has acquired resistance to the weedkiller Roundup. Let \(N\) be the number of acres, in millions, where Roundup-resistant pigweed is found. Suppose the relative growth rate, \((1 / N) d N / d t,\) was \(15 \%\) when \(N=5\) and \(14.5 \%\) when \(N=10 .\) Assuming the relative growth rate is a linear function of \(N,\) write a differential equation to model \(N\) as a function of time, and predict how many acres will eventually be afflicted before the spread of Roundup-resistant pigweed halts.

The total number of people infected with a virus often grows like a logistic curve. Suppose that time, \(t,\) is in weeks and that 10 people originally have the virus. In the early stages, the number of people infected is increasing exponentially with \(k=1.78 .\) In the long run, 5000 people are infected. (a) Find a logistic function to model the number of people infected. (b) Sketch a graph of your answer to part (a). (c) Use your graph to estimate the length of time until the rate at which people are becoming infected starts to decrease. What is the vertical coordinate at this point?
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