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Chapter 11: Problem 15

Show that \(y=A+C e^{k t}\) is a solution to the equation $$\frac{d y}{d t}=k(y-A).$$

Short Answer

Expert verified
The function is a solution as it satisfies the differential equation.

Step by step solution

01

Differentiate the Given Solution

To determine if the given function is a solution, we need to differentiate it with respect to time \(t\). The function is defined as \(y = A + C e^{k t}\). Differentiating term-by-term gives: \(\frac{dy}{dt} = 0 + C k e^{k t}\).
02

Substitute into the Differential Equation

Now we substitute \(y = A + C e^{k t}\) and \(\frac{dy}{dt} = Ck e^{kt}\) into the differential equation \(\frac{dy}{dt} = k(y - A)\). Substituting \(y - A\) gives \(C e^{k t}\), so the equation becomes \(C k e^{k t} = k(C e^{k t})\).
03

Simplify and Verify

Both sides of the equation \(C k e^{k t} = k(C e^{k t})\) are identical, indicating the equality holds for all \(t\). Therefore, the original function \(y = A + C e^{k t}\) is indeed a solution to the differential equation \(\frac{d y}{d t} = k(y - A)\).

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Key Concepts

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

Exponential Functions
Exponential functions are mathematical expressions in which a constant base is raised to a variable exponent. In the context of our differential equation exercise, the exponential term is written as \( e^{kt} \). Here, \( e \) is the base of natural logarithms, approximately equal to 2.718, and \( kt \) is the exponent. This form is characteristic of exponential functions, which are widely used in modeling growth or decay processes.

In an exponential function, the rate of change is proportional to its current value. For example, in finance, population biology, and physics, exponential growth or decay describes processes in which the quantity doubles or halves over regular intervals. The key point in this exercise is the exponential term \( C e^{kt} \) determining how the solution \( y \) evolves over time based on changing \( t \).
  • Key Properties: Constant proportional growth or decay
  • Rapid escalation over time if \( k > 0 \) (growth)
  • Rapid reduction over time if \( k < 0 \) (decay)
Understanding these characteristics helps in analyzing how the solution behaves under the influence of the exponential term.
Solution Verification
Solution verification involves confirming a proposed solution satisfies a given differential equation. In our exercise, we check if \( y = A + C e^{kt} \) actually solves \( \frac{d y}{d t} = k(y - A) \). This requires substituting both \( y \) and its derivative \( \frac{dy}{dt} \) back into the differential equation.

The verification steps can be simplified as:
  • Differentiate the proposed solution: Identify \( \frac{dy}{dt} \)
  • Substitute \( y \) and \( \frac{dy}{dt} \) into the equation
  • Check the equality to ensure both sides match
For our given equation, upon substitution, we reach \( C k e^{k t} = k(C e^{kt}) \). Simplifying shows both sides equal, confirming the original proposed function as a valid solution.

This method of solution verification is fundamental in ensuring our understanding of differential equations, offering insight into whether our algebraic manipulations and theoretical solutions hold under real conditions.
First-order Differential Equation
A first-order differential equation involves functions and their first derivatives. The primary characteristic is that it contains no terms with derivatives higher than the first degree. The general form for a first-order differential equation is \( \frac{dy}{dt} = f(t,y) \). In our specific problem, the equation \( \frac{dy}{dt} = k(y - A) \) illustrates the standard format, comprising only the first derivative.

First-order differential equations are used to model dynamic systems where the rate of change of a variable is directly related to the variable itself, as observed in population growth, chemical reactions, and heat transfer. These equations can frequently be solved by separation of variables or integrating factors, though in our case, the solution was given, and we've verified it.
  • Model simple dynamic systems
  • Analytical solutions by integration methods
  • Common in real-world applications
Recognizing the fundamental nature of these equations allows us to tackle more complex systems by building on the foundational principles they represent.

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Most popular questions from this chapter

Give an example of: A differential equation that has a slope field with all the slopes above the \(x\) -axis positive and all the slopes below the \(x\) -axis negative.

The systems of differential equations model the interaction of two populations \(x\) and \(y .\) In each case, answer the following two questions: (a) What kinds of interaction (symbiosis, \(^{30}\) competition, predator-prey) do the equations describe? (b) What happens in the long run? (For one of the systems, your answer will depend on the initial populations.) Use a calculator or computer to draw slope fields. $$\begin{aligned} &\frac{1}{x} \frac{d x}{d t}=1-\frac{x}{2}-\frac{y}{2}\\\ &\frac{1}{y} \frac{d y}{d t}=1-x-y \end{aligned}$$

(a) Sketch the slope field for \(y^{\prime}=-y / x\) (b) Sketch several solution curves. (c) Solve the differential equation analytically.

An item is initially sold at a price of \(p\text{dollars}\) per unit. Over time, market forces push the price toward the equilibrium price, \(p \text{dollars}^{*},\) at which supply balances demand. The Evans Price Adjustment model says that the rate of change in the market price, \(p\text{dollars},\) is proportional to the difference between the market price and the equilibrium price. (a) Write a differential equation for \(p\) as a function of \(t\) (b) Solve for \(p\) (c) Sketch solutions for various different initial prices, both above and below the equilibrium price. (d) What happens to \(p\) as \(t \rightarrow \infty ?\)

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.
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