4.1 Basics of differential equations (Page 5/14)

Calculus volume 2 Page 5 / 14

Suppose a rock falls from rest from a height of $100$ meters and the only force acting on it is gravity. Find an equation for the velocity $v (t)$ as a function of time, measured in meters per second.

$v (t) = −9.8 t$

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A natural question to ask after solving this type of problem is how high the object will be above Earth’s surface at a given point in time. Let $s (t)$ denote the height above Earth’s surface of the object, measured in meters. Because velocity is the derivative of position (in this case height), this assumption gives the equation $s^{'} (t) = v (t) .$ An initial value is necessary; in this case the initial height of the object works well. Let the initial height be given by the equation $s (0) = s_{0} .$ Together these assumptions give the initial-value problem

s^{'} (t) = v (t), s (0) = s_{0} .

If the velocity function is known, then it is possible to solve for the position function as well.

Height of a moving baseball

A baseball is thrown upward from a height of $3$ meters above Earth’s surface with an initial velocity of $10 m/s,$ and the only force acting on it is gravity. The ball has a mass of $0.15$ kilogram at Earth’s surface.

Find the position $s (t)$ of the baseball at time $t .$
What is its height after $2$ seconds?

We already know the velocity function for this problem is $v (t) = −9.8 t + 10 .$ The initial height of the baseball is $3$ meters, so $s_{0} = 3 .$ Therefore the initial-value problem for this example is
To solve the initial-value problem, we first find the antiderivatives:

$\begin{matrix} \int s^{'} (t) d t & = & \int −9.8 t + 10 d t \\ s (t) & = & −4.9 t^{2} + 10 t + C . \end{matrix}$

Next we substitute $t = 0$ and solve for $C :$

$\begin{matrix} s (t) & = & −4.9 t^{2} + 10 t + C \\ s (0) & = & −4.9 {(0)}^{2} + 10 (0) + C \\ 3 & = & C . \end{matrix}$

Therefore the position function is $s (t) = −4.9 t^{2} + 10 t + 3 .$
The height of the baseball after $2 s$ is given by $s (2) :$

$\begin{matrix} s (2) & = −4.9 {(2)}^{2} + 10 (2) + 3 \\ = −4.9 (4) + 23 \\ = 3.4. \end{matrix}$

Therefore the baseball is $3.4$ meters above Earth’s surface after $2$ seconds. It is worth noting that the mass of the ball cancelled out completely in the process of solving the problem.

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Key concepts

A differential equation is an equation involving a function $y = f (x)$ and one or more of its derivatives. A solution is a function $y = f (x)$ that satisfies the differential equation when $f$ and its derivatives are substituted into the equation.
The order of a differential equation is the highest order of any derivative of the unknown function that appears in the equation.
A differential equation coupled with an initial value is called an initial-value problem. To solve an initial-value problem, first find the general solution to the differential equation, then determine the value of the constant. Initial-value problems have many applications in science and engineering.

Determine the order of the following differential equations.

$y^{'} + y = 3 y^{2}$

$1$

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${(y^{'})}^{2} = y^{'} + 2 y$

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$y ‴ + y ″ y^{'} = 3 x^{2}$

$3$

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$y^{'} = y ″ + 3 t^{2}$

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$\frac{d y}{d t} = t$

$1$

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$\frac{d y}{d x} + \frac{d^{2} y}{d x^{2}} = 3 x^{4}$

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${(\frac{d y}{d t})}^{2} + 8 \frac{d y}{d t} + 3 y = 4 t$

$1$

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Verify that the following functions are solutions to the given differential equation.

$y = \frac{x^{3}}{3}$ solves $y^{'} = x^{2}$

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$y = 2 e^{− x} + x - 1$ solves $y^{'} = x - y$

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$y = e^{3 x} - \frac{e^{x}}{2}$ solves $y^{'} = 3 y + e^{x}$

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$y = \frac{1}{1 - x}$ solves $y^{'} = y^{2}$

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$y = e^{x^{2} / 2}$ solves $y^{'} = x y$

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$y = 4 + ln x$ solves $x y^{'} = 1$

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$y = 3 - x + x ln x$ solves $y^{'} = ln x$

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$y = 2 e^{x} - x - 1$ solves $y^{'} = y + x$

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$y = e^{x} + \frac{sin x}{2} - \frac{cos x}{2}$ solves $y^{'} = cos x + y$

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$y = π e^{− cos x}$ solves $y^{'} = y sin x$

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Verify the following general solutions and find the particular solution.

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Source: OpenStax, Calculus volume 2. OpenStax CNX. Feb 05, 2016 Download for free at http://cnx.org/content/col11965/1.2

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