4.5 First-order linear equations (Page 3/10)

Calculus volume 2 Page 3 / 10

Here $C_{2}$ can be an arbitrary (positive or negative) constant. This leads to a general method for solving a first-order linear differential equation. We first multiply both sides of [link] by the integrating factor $μ (x) .$ This gives

μ (x) y^{'} + μ (x) p (x) y = μ (x) q (x) .

The left-hand side of [link] can be rewritten as $\frac{d}{d x} (μ (x) y) .$

\frac{d}{d x} (μ (x) y) = μ (x) q (x) .

Next integrate both sides of [link] with respect to $x .$

\begin{matrix} \int \frac{d}{d x} (μ (x) y) d x & = & \int μ (x) q (x) d x \\ μ (x) y & = & \int μ (x) q (x) d x . \end{matrix}

Divide both sides of [link] by $μ (x) :$

y = \frac{1}{μ (x)} [\int μ (x) q (x) d x + C] .

Since $μ (x)$ was previously calculated, we are now finished. An important note about the integrating constant $C :$ It may seem that we are inconsistent in the usage of the integrating constant. However, the integral involving $p (x)$ is necessary in order to find an integrating factor for [link] . Only one integrating factor is needed in order to solve the equation; therefore, it is safe to assign a value for $C$ for this integral. We chose $C = 0 .$ When calculating the integral inside the brackets in [link] , it is necessary to keep our options open for the value of the integrating constant, because our goal is to find a general family of solutions to [link] . This integrating factor guarantees just that.

Problem-solving strategy: solving a first-order linear differential equation

Put the equation into standard form and identify $p (x)$ and $q (x) .$
Calculate the integrating factor $μ (x) = e^{\int p (x) d x} .$
Multiply both sides of the differential equation by $μ (x) .$
Integrate both sides of the equation obtained in step $3,$ and divide both sides by $μ (x) .$
If there is an initial condition, determine the value of $C .$

Solving a first-order linear equation

Find a general solution for the differential equation $x y' + 3 y = 4 x^{2} - 3 x .$ Assume $x > 0 .$

To put this differential equation into standard form, divide both sides by $x :$

$y' + \frac{3}{x} y = 4 x - 3 .$

Therefore $p (x) = \frac{3}{x}$ and $q (x) = 4 x - 3 .$
The integrating factor is $μ (x) = e^{\int (3 / x) d x} = e^{3 ln x} = x^{3} .$
Multiplying both sides of the differential equation by $μ (x)$ gives us

$\begin{matrix} x^{3} y^{'} + x^{3} (\frac{3}{x}) y & = & x^{3} (4 x - 3) \\ x^{3} y^{'} + 3 x^{2} y & = & 4 x^{4} - 3 x^{3} \\ \frac{d}{d x} (x^{3} y) & = & 4 x^{4} - 3 x^{3} . \end{matrix}$
Integrate both sides of the equation.

$\begin{matrix} \int \frac{d}{d x} (x^{3} y) d x & = & \int 4 x^{4} - 3 x^{3} d x \\ x^{3} y & = & \frac{4 x^{5}}{5} - \frac{3 x^{4}}{4} + C \\ y & = & \frac{4 x^{2}}{5} - \frac{3 x}{4} + C x^{−3} . \end{matrix}$
There is no initial value, so the problem is complete.

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Find the general solution to the differential equation $(x - 2) y' + y = 3 x^{2} + 2 x .$ Assume $x > 2 .$

$y = \frac{x^{3} + x^{2} + C}{x - 2}$

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Now we use the same strategy to find the solution to an initial-value problem.

A first-order linear initial-value problem

Solve the initial-value problem

y^{'} + 3 y = 2 x - 1, y (0) = 3 .

This differential equation is already in standard form with $p (x) = 3$ and $q (x) = 2 x - 1 .$
The integrating factor is $μ (x) = e^{\int 3 d x} = e^{3 x} .$
Multiplying both sides of the differential equation by $μ (x)$ gives

$\begin{matrix} e^{3 x} y^{'} + 3 e^{3 x} y & = & (2 x - 1) e^{3 x} \\ \frac{d}{d x} [y e^{3 x}] & = & (2 x - 1) e^{3 x} . \end{matrix}$

Integrate both sides of the equation:

$\begin{matrix} \int \frac{d}{d x} [y e^{3 x}] d x & = & \int (2 x - 1) e^{3 x} d x \\ y e^{3 x} & = & \frac{e^{3 x}}{3} (2 x - 1) - \int \frac{2}{3} e^{3 x} d x \\ y e^{3 x} & = & \frac{e^{3 x} (2 x - 1)}{3} - \frac{2 e^{3 x}}{9} + C \\ y & = & \frac{2 x - 1}{3} - \frac{2}{9} + C e^{−3 x} \\ y & = & \frac{2 x}{3} - \frac{5}{9} + C e^{−3 x} . \end{matrix}$
Now substitute $x = 0$ and $y = 3$ into the general solution and solve for $C :$

$\begin{matrix} y & = & \frac{2}{3} x - \frac{5}{9} + C e^{−3 x} \\ 3 & = & \frac{2}{3} (0) - \frac{5}{9} + C e^{−3 (0)} \\ 3 & = & - \frac{5}{9} + C \\ C & = & \frac{32}{9} . \end{matrix}$

Therefore the solution to the initial-value problem is

$y = \frac{2}{3} x - \frac{5}{9} + \frac{32}{9} e^{−3 x} .$

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Solve the initial-value problem $y' - 2 y = 4 x + 3 y (0) = −2 .$

$y = −2 x - 4 + 2 e^{2 x}$

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Applications of first-order linear differential equations

We look at two different applications of first-order linear differential equations. The first involves air resistance as it relates to objects that are rising or falling; the second involves an electrical circuit. Other applications are numerous, but most are solved in a similar fashion.

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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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