Difference between revisions of "Integrating Factor"

Revision as of 14:02, 16 November 2021

The Method of Integrating Factors

Let $p$ and $g$ be functions of $t$ and consider the following first order differential equation:

{\begin{aligned}\quad {\frac {dy}{dt}}+p(t)y=g(t)\end{aligned}}

If we multiply the both sides of the equation above by the function $\mu (t)$ we get that:

{\begin{aligned}\quad \mu (t){\frac {dy}{dt}}+\mu (t)p(t)y=\mu (t)g(t)\end{aligned}}

If we can guarantee that $\mu '(t)=\mu (t)p(t)$ , then notice that by applying the product rule for differentiation that we get: ${\frac {d}{dt}}\left(\mu (t)y\right)=\mu (t){\frac {dy}{dt}}+\mu '(t)y$ and substituting $\mu '(t)=\mu (t)y$ and we get that ${\frac {d}{dt}}\left(\mu (t)y\right)=\mu (t){\frac {dy}{dt}}+\mu (t)p(t)y$ which is exactly the lefthand side of the equation above. Thus we get that:

{\begin{aligned}{\frac {d}{dt}}\left(\mu (t)y\right)=\mu (t)g(t)\\\end{aligned}}

The above differential equation can be solved by integrating both sides of the equation with respect to $t$ and isolating $y$ . The question now arises on how we can find such a function $\mu (t)$ .

Definition: If

{\frac {dy}{dt}}+p(t)y=g(t)

is a first order differential equation, then

\mu (t)

is called an Integrating Factor if for

\mu (t){\frac {dy}{dt}}+\mu (t)p(t)y=\mu (t)g(t)

we have that

\mu '(t)=\mu (t)p(t)

.

The following proposition will give us a formula for obtaining the integrating factor for differential equations in the form ${\frac {dy}{dt}}+p(t)y=g(t)$ .

Proposition 1: If

{\frac {dy}{dt}}+p(t)y=g(t)

is a differential equation, then an integrating factor

\mu (t)

of this equation is given by the formula

Failed to parse (syntax error): {\displaystyle \mu (t) = e^{\int p(t) \: dt}}

.

Proof: We want to find $\mu (t)$ such that $\mu '(t)=\mu (t)p(t)$ . We can rewrite this equation as as ${\frac {\mu '(t)}{\mu (t)}}=p(t)$ and then:

Failed to parse (unknown function "\begin{align}"): {\displaystyle \begin{align} \quad \frac{ \mu '(t)}{ \mu (t)} = p(t) \\ \quad \frac{d}{dt} \ln \mid \mu (t) \mid = p(t) \\ \quad \int \frac{d}{dt} \ln \mid \mu (t) \mid \: dt = \int p(t) \: dt \\ \quad \ln \mid \mu (t) \mid = \int p(t) \: dt \\ \quad \mu (t) = \pm e^{\int p(t) \: dt} \end{align}}

Since we only need one integrating factor to solve differential equations in the form ${\frac {dy}{dt}}+p(t)y=g(t)$ , we can more generally note that $Failed to parse (syntax error): {\displaystyle \mu (t) = e^{\int p(t) \: dt}}$ is an integrating factor of this differential equation. $\blacksquare$

Notice that from proposition 1 that integrating factors $\mu (t)$ are not unique. In fact, there are infinitely many integrating factors. This can be see when evaluating the indefinite integral in $Failed to parse (syntax error): {\displaystyle \mu (t) = e^{\int p(t) \: dt}}$ which will result in getting $\mu (t)=e^{P(t)+C}$ where $P$ is any antiderivative if $p$ and where $C$ is a constant. We will always use the simplest integrating factor in solving differential equations of this type.

Let's now look at some examples of applying the method of integrating factors.

Example 1

Find all solutions to the differential equation ${\frac {dy}{dt}}+{\frac {2y}{t}}={\frac {\sin t}{t^{2}}}$ .

We first notice that our differential equation is in the appropriate form ${\frac {dy}{dt}}+p(t)y=g(t)$ where $p(t)={\frac {2}{t}}$ and $g(t)={\frac {\sin t}{t^{2}}}$ . We compute our integrating factor as:

Failed to parse (MathML with SVG or PNG fallback (recommended for modern browsers and accessibility tools): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \begin{align} \quad \mu (t) = e^{\int p(t) \: dt} = e^{\int \frac{2}{t} \: dt} = e^{2 \ln (t)} = e^{\ln (t^2)} = t^2 \end{align}}

Thus we have that for $C$ as a constant:

Failed to parse (unknown function "\begin{align}"): {\displaystyle \begin{align} \quad \mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t) \\ \quad t^2 \frac{dy}{dt} + 2t y = \sin t \\ \quad \frac{d}{dt} \left ( t^2 y \right ) = \sin t \\ \quad \int \frac{d}{dt} \left ( t^2 y \right ) \: dt = \int \sin t \: dt \\ \quad t^2 y = -\cos t + C \\ \quad y = \frac{-\cos t}{t^2} + \frac{C}{t^2} \end{align}}

Example 2

Find all solutions to the differential equation ${\frac {dy}{dt}}-{\frac {y}{t}}+te^{-t}=0$ .

We first rewrite our differential equation as ${\frac {dy}{dt}}-{\frac {y}{t}}=-te^{-t}$ . We note that in this form we have $p(t)=-{\frac {1}{t}}$ and $g(t)=-te^{-t}$ . We now find an integrating factor:

Failed to parse (unknown function "\begin{align}"): {\displaystyle \begin{align} \quad \mu (t) = e^{\int p(t) \: dt} = e^{\int -\frac{1}{t} \: dt} = e^{-\ln t} = e^{\ln \left ( \frac{1}{t} \right)} = \frac{1}{t} \end{align}}

Thus we have that for $C$ as a constant:

Failed to parse (unknown function "\begin{align}"): {\displaystyle \begin{align} \quad \mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t) \\ \quad \frac{1}{t} \frac{dy}{dt} - \frac{1}{t^2} y = -e^{-t} \\ \quad \frac{d}{dt} \left ( \frac{y}{t} \right ) = -e^{-t} \\ \quad \int \frac{d}{dt} \left ( \frac{y}{t} \right ) \: dt = -\int e^{-t} \: dt \\ \quad \frac{y}{t} = e^{-t} + C \\ \quad y = te^{-t} + tC \end{align}}

@@ Line 1: / Line 1: @@
-When solving first order linear differential equations of the form <math> y' + p(x)y = g(x) </math>, we can utilize the "integrating factor" <math> \mu (x) = e^{\int p(x)dx}</math>.
+==The Method of Integrating Factors==
+<p>Let <span class="math-inline"><math>p</math></span> and <span class="math-inline"><math>g</math></span> be functions of <span class="math-inline"><math>t</math></span> and consider the following first order differential equation:</p>
-Steps to solving an equation of the form <math> \frac{dy}{dx} + p(x)y = g(x) </math>:
+<div style="text-align: center;"><math>\begin{align} \quad \frac{dy}{dt} + p(t) y = g(t) \end{align}</math></div>
-# Find the integrating factor <math> \mu (x) = e^{\int p(x)dx} </math>, and note that <math> \mu '(x) = p(x)e^{\int p(x)dx} = p(x)\mu (x)</math>,
+<p>If we multiply the both sides of the equation above by the function <span class="math-inline"><math>\mu (t)</math></span> we get that:</p>
-# Multiply both sides of the equation by the integrating factor.
+<div style="text-align: center;"><math>\begin{align} \quad \mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t) \end{align}</math></div>
-# The left side of the equation, <math> y'\mu (x) + p(x)\mu (x)y </math>, can now be rewritten as <math> (\mu (x)y)' </math> since <math> y'\mu (x) + p(x)\mu (x)y = y'\mu (x) + \mu '(x)y </math>. Verify by taking the derivative of <math> \mu (x)y </math> with respect to x with the product rule.
+<p>If we can guarantee that <span class="math-inline"><math>\mu ' (t) = \mu (t) p(t)</math></span>, then notice that by applying the product rule for differentiation that we get: <span class="math-inline"><math>\frac{d}{dt} \left ( \mu (t) y \right ) = \mu (t) \frac{dy}{dt} + \mu ' (t) y</math></span> and substituting <span class="math-inline"><math>\mu ' (t) = \mu (t) y</math></span> and we get that <span class="math-inline"><math>\frac{d}{dt} \left ( \mu (t) y \right ) = \mu (t) \frac{dy}{dt} + \mu (t) p(t) y</math></span> which is exactly the lefthand side of the equation above. Thus we get that:</p>
-# Now, integrate <math> (\mu (x)y)' = g(x)\mu (x)</math> to get <math> \mu (x)y = \int g(x)\mu (x)dx </math>.
+<div style="text-align: center;"><math>\begin{align} \frac{d}{dt} \left ( \mu (t) y \right ) = \mu (t) g(t) \\ \end{align}</math></div>
-# Solve for y.
+<p>The above differential equation can be solved by integrating both sides of the equation with respect to <span class="math-inline"><math>t</math></span> and isolating <span class="math-inline"><math>y</math></span>. The question now arises on how we can find such a function <span class="math-inline"><math>\mu (t)</math></span>.</p>
+<table class="wiki-content-table">
-Example problem: <math> y' + \frac{2}{t}y = t - 1 + \frac{1}{t} </math>
+<tr>
-# <math> \mu (x) = e^{\int \frac{2}{t}dt}  = e^{2\ln{|t|}} = e^{\ln{|t|^2}} = t^2 </math>
+<td><strong>Definition:</strong> If <span class="math-inline"><math>\frac{dy}{dt} + p(t) y = g(t)</math></span> is a first order differential equation, then <span class="math-inline"><math>\mu (t)</math></span> is called an <strong>Integrating Factor</strong> if for <span class="math-inline"><math>\mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t)</math></span> we have that <span class="math-inline"><math>\mu ' (t) = \mu (t) p(t)</math></span>.</td>
-# <math> t^2y' + 2ty = t^3 - t^2 + t </math>
+</tr>
-# <math> (t^2y)' = t^3 - t^2 + t </math>
+</table>
-# <math> t^2y = \int (t^3 - t^2 + t)dt  = \frac{1}{4}t^4 - \frac{1}{3}t^3 + \frac{1}{2}t^2 + C </math>
+<p>The following proposition will give us a formula for obtaining the integrating factor for differential equations in the form <span class="math-inline"><math>\frac{dy}{dt} + p(t) y = g(t)</math></span>.</p>
-# <math> y = \frac{1}{4}t^2 - \frac{1}{3}t + \frac{1}{2} + \frac{C}{t^2} </math>
+<table class="wiki-content-table">
+<tr>
-==Resources==
+<td><strong>Proposition 1:</strong> If <span class="math-inline"><math>\frac{dy}{dt} + p(t) y = g(t)</math></span> is a differential equation, then an integrating factor <span class="math-inline"><math>\mu (t)</math></span> of this equation is given by the formula <span class="math-inline"><math>\mu (t) = e^{\int p(t) \: dt}</math></span>.</td>
-* [https://tutorial.math.lamar.edu/classes/de/linear.aspx Solving Linear Equations], Paul's Online Notes
+</tr>
+</table>
+<ul>
+<li><strong>Proof:</strong> We want to find <span class="math-inline"><math>\mu (t)</math></span> such that <span class="math-inline"><math>\mu ' (t) = \mu (t) p(t)</math></span>. We can rewrite this equation as as <span class="math-inline"><math>\frac{\mu '(t)}{\mu (t)} = p(t)</math></span> and then:</li>
+</ul>
+<div style="text-align: center;"><math>\begin{align} \quad \frac{ \mu '(t)}{ \mu (t)} = p(t) \\ \quad \frac{d}{dt} \ln \mid \mu (t) \mid = p(t) \\ \quad \int \frac{d}{dt} \ln \mid \mu (t) \mid \: dt = \int p(t) \: dt \\ \quad \ln \mid \mu (t) \mid = \int p(t) \: dt \\ \quad \mu (t) = \pm e^{\int p(t) \: dt} \end{align}</math></div>
+<ul>
+<li>Since we only need one integrating factor to solve differential equations in the form <span class="math-inline"><math>\frac{dy}{dt} + p(t) y = g(t)</math></span>, we can more generally note that <span class="math-inline"><math>\mu (t) = e^{\int p(t) \: dt}</math></span> is an integrating factor of this differential equation. <span class="math-inline"><math>\blacksquare</math></span></li>
+</ul>
+<p><em>Notice that from proposition 1 that integrating factors <span class="math-inline"><math>\mu (t)</math></span> are not unique. In fact, there are infinitely many integrating factors. This can be see when evaluating the indefinite integral in <span class="math-inline"><math>\mu (t) = e^{\int p(t) \: dt}</math></span> which will result in getting <span class="math-inline"><math>\mu (t) = e^{P(t) + C}</math></span> where <span class="math-inline"><math>P</math></span> is any antiderivative if <span class="math-inline"><math>p</math></span> and where <span class="math-inline"><math>C</math></span> is a constant. We will always use the simplest integrating factor in solving differential equations of this type.</em></p>
+<p>Let's now look at some examples of applying the method of integrating factors.</p>
+===Example 1===
+<p><strong>Find all solutions to the differential equation <span class="math-inline"><math>\frac{dy}{dt} + \frac{2y}{t} = \frac{\sin t}{t^2}</math></span>.</strong></p>
+<p>We first notice that our differential equation is in the appropriate form <span class="math-inline"><math>\frac{dy}{dt} + p(t) y = g(t)</math></span> where <span class="math-inline"><math>p(t) = \frac{2}{t}</math></span> and <span class="math-inline"><math>g(t) = \frac{\sin t}{t^2}</math></span>. We compute our integrating factor as:</p>
+<div style="text-align: center;"><math>\begin{align} \quad \mu (t) = e^{\int p(t) \: dt} = e^{\int \frac{2}{t} \: dt} = e^{2 \ln (t)} = e^{\ln (t^2)} = t^2 \end{align}</math></div>
+<p>Thus we have that for <span class="math-inline"><math>C</math></span> as a constant:</p>
+<div style="text-align: center;"><math>\begin{align} \quad \mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t) \\ \quad t^2 \frac{dy}{dt} + 2t y = \sin t \\ \quad \frac{d}{dt} \left ( t^2 y \right ) = \sin t \\ \quad \int \frac{d}{dt} \left ( t^2 y \right ) \: dt = \int \sin t \: dt \\ \quad t^2 y = -\cos t + C \\ \quad y = \frac{-\cos t}{t^2} + \frac{C}{t^2} \end{align}</math></div>
+===Example 2===
+<p><strong>Find all solutions to the differential equation <span class="math-inline"><math>\frac{dy}{dt} - \frac{y}{t} + te^{-t} = 0</math></span>.</strong></p>
+<p>We first rewrite our differential equation as <span class="math-inline"><math>\frac{dy}{dt} - \frac{y}{t} = - te^{-t}</math></span>. We note that in this form we have <span class="math-inline"><math>p(t) = - \frac{1}{t}</math></span> and <span class="math-inline"><math>g(t) = -t e^{-t}</math></span>. We now find an integrating factor:</p>
+<div style="text-align: center;"><math>\begin{align} \quad \mu (t) = e^{\int p(t) \: dt} = e^{\int -\frac{1}{t} \: dt} = e^{-\ln t} = e^{\ln \left ( \frac{1}{t} \right)} = \frac{1}{t} \end{align}</math></div>
+<p>Thus we have that for <span class="math-inline"><math>C</math></span> as a constant:</p>
+<div style="text-align: center;"><math>\begin{align} \quad \mu (t) \frac{dy}{dt} + \mu (t) p(t) y = \mu (t) g(t) \\ \quad \frac{1}{t} \frac{dy}{dt} - \frac{1}{t^2} y = -e^{-t} \\ \quad \frac{d}{dt} \left ( \frac{y}{t} \right ) = -e^{-t} \\ \quad \int \frac{d}{dt} \left ( \frac{y}{t} \right ) \: dt = -\int e^{-t} \: dt \\ \quad \frac{y}{t} = e^{-t} + C \\ \quad y = te^{-t} + tC \end{align}</math></div>

Difference between revisions of "Integrating Factor"

Revision as of 14:02, 16 November 2021

The Method of Integrating Factors

Example 1

Example 2

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