4.5 First-order linear equations (Page 2/10)

Calculus volume 2 Page 2 / 10

Examples of first-order nonlinear differential equations include

\begin{matrix} {(y')}^{4} - {(y')}^{3} & = & (3 x - 2) (y + 4) \\ 4 y' + 3 y^{3} & = & 4 x - 5 \\ {(y')}^{2} & = & sin y + cos x . \end{matrix}

These equations are nonlinear because of terms like ${(y^{'})}^{4}, y^{3},$ etc. Due to these terms, it is impossible to put these equations into the same form as [link] .

Standard form

Consider the differential equation

(3 x^{2} - 4) y^{'} + (x - 3) y = sin x .

Our main goal in this section is to derive a solution method for equations of this form. It is useful to have the coefficient of $y^{'}$ be equal to $1 .$ To make this happen, we divide both sides by $3 x^{2} - 4 .$

y^{'} + (\frac{x - 3}{3 x^{2} - 4}) y = \frac{sin x}{3 x^{2} - 4}

This is called the standard form of the differential equation. We will use it later when finding the solution to a general first-order linear differential equation. Returning to [link] , we can divide both sides of the equation by $a (x) .$ This leads to the equation

y^{'} + \frac{b (x)}{a (x)} y = \frac{c (x)}{a (x)} .

Now define $p (x) = \frac{b (x)}{a (x)}$ and $q (x) = \frac{c (x)}{a (x)} .$ Then [link] becomes

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

We can write any first-order linear differential equation in this form, and this is referred to as the standard form for a first-order linear differential equation.

Writing first-order linear equations in standard form

Put each of the following first-order linear differential equations into standard form. Identify $p (x)$ and $q (x)$ for each equation.

$y' = 3 x - 4 y$
$\frac{3 x y'}{4 y - 3} = 2$ (here $x > 0)$
$y = 3 y' - 4 x^{2} + 5$

Add $4 y$ to both sides:

$y' + 4 y = 3 x .$

In this equation, $p (x) = 4$ and $q (x) = 3 x .$
Multiply both sides by $4 y - 3,$ then subtract $8 y$ from each side:

$\begin{matrix} \frac{3 x y'}{4 y - 3} & = & 2 \\ 3 x y' & = & 2 (4 y - 3) \\ 3 x y' & = & 8 y - 6 \\ 3 x y' - 8 y & = & −6 . \end{matrix}$

Finally, divide both sides by $3 x$ to make the coefficient of $y'$ equal to $1 :$

$y' - \frac{8}{3 x} y = - \frac{2}{3 x} .$
This is allowable because in the original statement of this problem we assumed that $x > 0 .$ (If $x = 0$ then the original equation becomes $0 = 2,$ which is clearly a false statement.)
In this equation, $p (x) = - \frac{8}{3 x}$ and $q (x) = - \frac{2}{3 x} .$
Subtract $y$ from each side and add $4 x^{2} - 5 :$

$3 y' - y = 4 x^{2} - 5 .$

Next divide both sides by $3 :$

$y' - \frac{1}{3} y = \frac{4}{3} x^{2} - \frac{5}{3} .$

In this equation, $p (x) = - \frac{1}{3}$ and $q (x) = \frac{4}{3} x^{2} - \frac{5}{3} .$

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Put the equation $\frac{(x + 3) y'}{2 x - 3 y - 4} = 5$ into standard form and identify $p (x)$ and $q (x) .$

$y' + \frac{15}{x + 3} y = \frac{10 x - 20}{x + 3}; p (x) = \frac{15}{x + 3}$ and $q (x) = \frac{10 x - 20}{x + 3}$

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Integrating factors

We now develop a solution technique for any first-order linear differential equation. We start with the standard form of a first-order linear differential equation:

y' + p (x) y = q (x) .

The first term on the left-hand side of [link] is the derivative of the unknown function, and the second term is the product of a known function with the unknown function. This is somewhat reminiscent of the power rule from the Differentiation Rules section. If we multiply [link] by a yet-to-be-determined function $μ (x),$ then the equation becomes

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

The left-hand side [link] can be matched perfectly to the product rule:

\frac{d}{d x} [f (x) g (x)] = f^{'} (x) g (x) + f (x) g^{'} (x) .

Matching term by term gives $y = f (x), g (x) = μ (x),$ and $g^{'} (x) = μ (x) p (x) .$ Taking the derivative of $g (x) = μ (x)$ and setting it equal to the right-hand side of $g^{'} (x) = μ (x) p (x)$ leads to

μ^{'} (x) = μ (x) p (x) .

This is a first-order, separable differential equation for $μ (x) .$ We know $p (x)$ because it appears in the differential equation we are solving. Separating variables and integrating yields

\begin{matrix} \frac{μ^{'} (x)}{μ (x)} & = & p (x) \\ \int \frac{μ^{'} (x)}{μ (x)} d x & = & \int p (x) d x \\ ln | μ (x) | & = & \int p (x) d x + C \\ e^{ln | μ (x) |} & = & e^{\int p (x) d x + C} \\ | μ (x) | & = & C_{1} e^{\int p (x) d x} \\ μ (x) & = & C_{2} e^{\int p (x) d x} . \end{matrix}

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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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