Mathematics for Applied Sciences (Osnabrück 2023-2024)/Part I/Lecture 20/latex

\setcounter{section}{20}

We discuss now the main rules to find a primitive function, and to compute definite integrals. They rest on rules for derivation.






\subtitle {Integration by parts}




\inputfactproof
{Integration by parts/Fact}
{Theorem}
{}
{

\factsituation {Let
\mathdisp {f,g \colon [a,b] \longrightarrow \R} { }
denote continuously differentiable functions.}
\factconclusion {Then
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f(t)g'(t) \, d t }
{ =} { fg | _{ a } ^{ b } - \int_{ a }^{ b } f'(t)g(t) \, d t }
{ } { }
{ } { }
{ } { }
} {}{}{.}}
\factextra {}
}
{

Due to the product rule, the function $fg$ is a primitive function for \mathl{fg'+f'g}{.} Therefore,
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f(t) g'(t) \, d t + \int_{ a }^{ b } f'(t) g(t) \, d t }
{ =} { \int_{ a }^{ b } { \left( fg'+f'g \right) } (t) \, d t }
{ =} { fg | _{ a } ^{ b } }
{ } { }
{ } { }
} {}{}{.}

}


In using integration by parts, two things are to be considered. Firstly, the function to be integrated is usually not in the form \mathl{fg'}{,} but just as a product $uv$ \extrabracket {if there is no product, then this rule will probably not help, however, sometimes the trivial product $1 u$ might help} {} {.} Then for one factor, we have to find a primitive function, and we have to differentiate the other factor. If $V$ is a primitive function of $v$, then the formula reads
\mathrelationchaindisplay
{\relationchain
{ \int uv }
{ =} { uV- \int u' V }
{ } { }
{ } { }
{ } { }
} {}{}{.} Secondly, integration by parts only helps when the integral on the right, i.e. \mathl{\int_{ a }^{ b } f'(t)g(t) \, d t}{,} can be integrated.




\inputexample{}
{

We determine a primitive function for the natural logarithm \mathl{\ln x}{,} with integration by parts. We write
\mathrelationchain
{\relationchain
{ \ln x }
{ = }{ 1 \cdot \ln x }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} and we integrate the constant function $1$, and we differentiate the logarithm. Then
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } \ln x \, d x }
{ =} { (x \cdot \ln x) | _{ a } ^{ b } - \int_{ a }^{ b } x \cdot { \frac{ 1 }{ x } } \, d x }
{ =} { (x \cdot \ln x) | _{ a } ^{ b } - \int_{ a }^{ b } 1 \, d x }
{ =} { (x \cdot \ln x) | _{ a } ^{ b } - x | _{ a } ^{ b } }
{ } { }
} {}{}{.} So a primitive function is \mathl{x \cdot \ln x - x}{.}

}




\inputexample{}
{

A primitive function for the sine function \mathl{\sin x}{} is \mathl{- \cos x}{.} In order to find a primitive function for \mathl{\sin^{ n } x}{,} we use integration by parts to get a recursive relation to a power with a smaller exponent. To make this more precise, we work over an interval, the primitive function shall start at $0$ and have the value $0$ there. For
\mathrelationchain
{\relationchain
{n }
{ \geq }{2 }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} with integration by parts, we get
\mathrelationchainalign
{\relationchainalign
{ \int_{ 0 }^{ x } \sin^{ n } t \, d t }
{ =} { \int_{ 0 }^{ x } \sin^{ n-2 } t \cdot \sin^{ 2 } t \, d t }
{ =} { \int_{ 0 }^{ x } \sin^{ n-2 } t \cdot { \left( 1- \cos^{ 2 } t \right) } \, d t }
{ =} { \int_{ 0 }^{ x } \sin^{ n-2 } t \, d t - \int_{ 0 }^{ x } { \left( \sin^{ n-2 } t \cos t \right) } \cos t \, d t }
{ =} { \int_{ 0 }^{ x } \sin^{ n-2 } t \, d t - \frac{ \sin^{ n-1 } t }{ n-1} \cos t | _{ 0 } ^{ x } - \frac{1}{n-1} { \left(\int_{ 0 }^{ x } \sin^{ n } t \, d t\right) } }
} {} {}{.} Multiplication with \mathl{n-1}{} and rearranging yields
\mathrelationchaindisplay
{\relationchain
{ n \int_{ 0 }^{ x } \sin^{ n } t \, d t }
{ =} {(n-1) \int_{ 0 }^{ x } \sin^{ n-2 } t \, d t - \sin^{ n-1 } x \cos x }
{ } { }
{ } { }
{ } { }
} {}{}{.} In particular, for
\mathrelationchain
{\relationchain
{n }
{ = }{2 }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} we have
\mathrelationchaindisplay
{\relationchain
{ \int_{ 0 }^{ x } \sin^{ 2 } t \, d t }
{ =} { \frac{1}{2} { \left(x- \sin x \cos x\right) } }
{ } { }
{ } { }
{ } { }
} {}{}{.}

}






\subtitle {Integration of inverse function}




\inputfactproof
{Primitive function/Inverse function/Fact}
{Theorem}
{}
{

\factsituation {Let $f \colon [a,b] \rightarrow [c,d]$ denote a bijective differentiable function, and let $F$ denote a primitive function for $f$.}
\factconclusion {Then
\mathrelationchaindisplay
{\relationchain
{ G(y) }
{ \defeq} { y f^{-1} (y) - F { \left( f^{-1}(y) \right) } }
{ } { }
{ } { }
{ } { }
} {}{}{} is a primitive function for the inverse function \mathl{f^{-1}}{.}}
\factextra {}
}
{

Differentiating, using Lemma 14.7 and Theorem 14.8 , yields
\mathrelationchainalign
{\relationchainalign
{ { \left( y f^{-1}(y) - F { \left( f^{-1} (y) \right) } \right) }' }
{ =} { f^{-1}(y) + y { \frac{ 1 }{ f'(f^{-1}(y)) } } - f { \left( f^{-1}(y) \right) } { \frac{ 1 }{ f' { \left( f^{-1}(y) \right) } } } }
{ =} { f^{-1}(y) }
{ } { }
{ } { }
} {} {}{.}

}







\image{ \begin{center}
\includegraphics[width=5.5cm]{\imageinclude {FunktionUmkehrIntegralOhne.svg} }
\end{center}
\imagetext {The graph with its inverse function, and the areas relevant for the computation of the integral of the inverse function.} }

\imagelicense { FunktionUmkehrIntegralOhne.svg } {} {Jonathan.Steinbuch} {Commons} {CC-BY-SA-3.0} {}


For this statement, there exists also an easy geometric explanation. When $f \colon [a,b] \rightarrow \R_+$ is a strictly increasing continuous function \extrabracket {and therefore induces a bijection between \mathcor {} {[a,b]} {and} {[f(a),f(b)]} {}} {} {,} then the following relation between the areas holds:
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f(s) \, d s + \int_{ f(a) }^{ f(b) } f^{-1}(t) \, d t }
{ =} { bf(b)-a f(a) }
{ } { }
{ } { }
{ } { }
} {}{}{,} or, equivalently,
\mathrelationchaindisplay
{\relationchain
{ \int_{ f(a) }^{ f(b) } f^{-1}(t) \, d t }
{ =} { bf(b)-a f(a) - \int_{ a }^{ b } f(s) \, d s }
{ } { }
{ } { }
{ } { }
} {}{}{.} For the primitive function $G$ of \mathl{f^{-1}}{} with starting point \mathl{f(a)}{,} we have, if $F$ denotes a primitive function for $f$, the relation
\mathrelationchainalign
{\relationchainalign
{ G(y) }
{ =} { \int_{ f(a) }^{ y } f^{-1}(t) \, d t }
{ =} { \int_{ f(a) }^{ f(f^{-1}(y)) } f^{-1}(t) \, d t }
{ =} { f^{-1}(y) f( f^{-1}(y))-a f(a) - \int_{ a }^{ f^{-1}(y) } f(s) \, d s }
{ =} { y f^{-1}(y) - a f(a) - F(f^{-1}(y)) + F(a) }
} {
\relationchainextensionalign
{ =} { y f^{-1}(y) - F(f^{-1}(y)) - a f(a) + F(a) }
{ } { }
{ } {}
{ } {}
} {}{,} where \mathl{- a f(a) + F(a)}{} is a constant of integration.




\inputexample{}
{

We compute a primitive function for \mathl{\arctan x}{,} using Theorem 20.4 . A primitive function of tangent is
\mathrelationchaindisplay
{\relationchain
{ \int_{ }^{ } \tan t \, d t }
{ =} { - \ln (\cos x) }
{ } { }
{ } { }
{ } { }
} {}{}{.} Hence,
\mathdisp {x \cdot \arctan x + \ln (\cos (\arctan x))} { }
is a primitive function for \mathl{\arctan x}{.}

}






\subtitle {Substitution}




\inputfactproof
{Integration/Substitution/Fact}
{Theorem}
{}
{

\factsituation {Suppose that $I$ denotes a real interval, and let
\mathdisp {f \colon I \longrightarrow \R} { }
denote a continuous function. Let
\mathdisp {g \colon [a,b] \longrightarrow I} { }
be a continuously differentiable function.}
\factconclusion {Then
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f(g(t)) g'(t) \, d t }
{ =} { \int_{ g(a) }^{ g(b) } f ( s) \, d s }
{ } { }
{ } { }
{ } { }
} {}{}{} holds.}
\factextra {}
}
{

Since $f$ is continuous and $g$ is continuously differentiable, both integrals exist. Let $F$ denote a primitive function for $f$, which exists, due to Theorem 18.17 . Because of the chain rule, the composite function
\mathrelationchaindisplay
{\relationchain
{ t \mapsto F(g(t)) }
{ =} { (F \circ g)(t) }
{ } { }
{ } { }
{ } { }
} {}{}{} has the derivative
\mathrelationchain
{\relationchain
{ F'(g(t)) g'(t) }
{ = }{ f(g(t))g'(t) }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} Therefore,
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f(g(t)) g'(t) \, d t }
{ =} { (F \circ g) | _{ a } ^{ b } }
{ =} { F(g(b)) - F(g(a)) }
{ =} { F | _{ g(a) } ^{ g(b) } }
{ =} { \int_{ g(a) }^{ g(b) } f(s) \, d s }
} {}{}{.}

}





\inputexample{}
{

Typical examples, where one sees immediately that one can apply substitution, are
\mathdisp {\int g^n g'} { , }
with the primitive function
\mathdisp {{ \frac{ 1 }{ n+1 } } g^{n+1}} { }
or
\mathdisp {\int { \frac{ g' }{ g } }} { , }
with the primitive function
\mathdisp {\ln g} { . }

}

Often, the indefinite integral is not in a form where one can apply the preceding rule directly. Then the following variant is more appropriate.




\inputfactproof
{Integration/Substitution/dx version/Fact}
{Corollary}
{}
{

\factsituation {Suppose that
\mathdisp {f \colon [a,b] \longrightarrow \R} { }
is a continuous function, and let
\mathdisp {\varphi \colon [c,d] \longrightarrow [a,b] , s \longmapsto \varphi(s)} { , }
denote a bijective continuously differentiable function.}
\factconclusion {Then
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } f ( t) \, d t }
{ =} { \int_{ \varphi^{-1}(a) }^{ \varphi^{-1}(b) } f( \varphi(s)) \cdot \varphi'(s) \, d s }
{ } { }
{ } { }
{ } { }
} {}{}{} holds.}
\factextra {}
}
{

Because of Theorem 20.6 , we have
\mathrelationchaindisplay
{\relationchain
{ \int_{ \varphi^{-1}(a) }^{ \varphi^{-1}(b) } f( \varphi(s)) \varphi'(s) \, d s }
{ =} { \int_{ \varphi { \left( \varphi^{-1}(a) \right) } }^{ \varphi { \left( \varphi^{-1}(b) \right) } } f( t) \, d t }
{ =} { \int_{ a }^{ b } f(t) \, d t }
{ } { }
{ } { }
} {}{}{.}

}





\inputremark {}
{

The substitution is applied in the following way: suppose that the integral
\mathdisp {\int_{ a }^{ b } f ( t) \, d t} { }
has to be computed. Then one needs an idea that the integral gets simpler by the substitution
\mathrelationchaindisplay
{\relationchain
{ t }
{ =} { \varphi(s) }
{ } { }
{ } { }
{ } { }
} {}{}{} \extrabracket {taking into account the derivative \mathl{\varphi'(s)}{} and that the inverse function \mathl{\varphi^{-1}}{} has to be determined} {} {.} Setting \mathcor {} {c= \varphi^{-1}(a)} {and} {d= \varphi^{-1}(b)} {,} we have the situation
\mathdisp {[c,d] \stackrel{\varphi}{\longrightarrow} [a,b] \stackrel{f}{\longrightarrow} \R} { . }
In certain cases, some standard substitutions help.

In order to make a substitution, three operations have to be done. \enumerationthree {Replace \mathl{f(t)}{} by \mathl{f(\varphi(s))}{.} } {Replace \mathl{dt}{} by \mathl{\varphi'(s)ds}{.} } {Replace the integration bounds \mathcor {} {a} {and} {b} {} by \mathcor {} {\varphi^{-1}(a)} {and} {\varphi^{-1}(b)} {.} }

To remember the second step, think of
\mathrelationchaindisplay
{\relationchain
{ dt }
{ =} { d \varphi(s) }
{ =} { \varphi'(s)ds }
{ } { }
{ } { }
} {}{}{,} which in the framework \quotationshort{differential forms}{,} has a meaning.

}




\inputexample{}
{

The upper curve of the unit circle is the set
\mathdisp {{ \left\{ (x,y) \mid x^2+y^2 = 1 , \, -1 \leq x \leq 1 , \, y \geq 0 \right\} }} { . }
For a given
\mathcond {x} {}
{-1 \leq x \leq 1} {}
{} {} {} {,} there exists exactly one $y$ fulfilling this condition, namely
\mathrelationchain
{\relationchain
{ y }
{ = }{ \sqrt{1-x^2} }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} Hence, the area of the upper half of the unit circle is the area beneath the graph of the function \mathl{x \mapsto \sqrt{1-x^2}}{,} above the interval \mathl{[-1,1]}{,} that is
\mathdisp {\int_{ -1 }^{ 1 } \sqrt{1-x^2} \, d x} { . }
Applying substitution with
\mathdisp {x = \cos t \text{ and } t = \arccos x} { }
\extrabracket {where \mathl{\cos :[0, \pi] \rightarrow [-1,1]}{} is bijective, due to Corollary 16.14 } {} {,} we obtain, using Example 20.3 , the identities
\mathrelationchainalign
{\relationchainalign
{ \int_{ a }^{ b } \sqrt{1-x^2} \, d x }
{ =} { \int_{ \arccos a }^{ \arccos b } \sqrt{1- \cos^{ 2 } t } (- \sin t ) \, d t }
{ =} { - \int_{ \arccos a }^{ \arccos b } \sin^{ 2 } t \, d t }
{ =} { \frac{1}{2} ( \sin t \cos t -t ) | _{ \arccos a } ^{ \arccos b } }
{ } { }
} {} {}{.} In particular, we get that
\mathrelationchaindisplay
{\relationchain
{ { \frac{ 1 }{ 2 } } { \left( x \cdot \sin { \left( \arccos x \right) }- \arccos x \right) } }
{ =} { { \frac{ 1 }{ 2 } } { \left( x \cdot \sqrt{1-x^2} - \arccos x \right) } }
{ } { }
{ } { }
{ } { }
} {}{}{} is a primitive function for \mathl{\sqrt{1-x^2}}{.} Therefore,
\mathrelationchainalign
{\relationchainalign
{ \int_{ -1 }^{ 1 } \sqrt{1-x^2} \, d x }
{ =} { { \frac{ 1 }{ 2 } } { \left( x \cdot \sqrt{1-x^2} - \arccos x \right) } | _{ -1 } ^{ 1 } }
{ =} { { \frac{ 1 }{ 2 } } ( - \arccos 1 + \arccos (-1) ) }
{ =} { \pi/2 }
{ } {}
} {} {}{.}

}




\inputexample{}
{

We determine a primitive function for \mathl{\sqrt{x^2-1}}{,} using the hyperbolic functions \mathcor {} {\sinh t} {and} {\cosh t} {,} for which the relation
\mathrelationchain
{\relationchain
{ \cosh^{ 2 } t - \sinh^{ 2 } t }
{ = }{ 1 }
{ }{ }
{ }{ }
{ }{ }
} {}{}{} holds. The substitution
\mathdisp {x= \cosh t \text{ with } dx = \sinh t dt} { }
yields\extrafootnote {The inverse function of the hyperbolic cosine is called \keyword {area hyperbolic cosine} {,} and is denoted by $\, \operatorname{arcosh} \, x \,$} {.} {}
\mathrelationchaindisplay
{\relationchain
{ \int_{ a }^{ b } \sqrt{x^2-1} \, d x }
{ =} { \int_{ \, \operatorname{arcosh} \, a \, }^{ \, \operatorname{arcosh} \, b \, } \sqrt{ \cosh^{ 2 } t-1 } \cdot \sinh t \, d t }
{ =} { \int_{ \, \operatorname{arcosh} \, a \, }^{ \, \operatorname{arcosh} \, b \, } \sinh^{ 2 } t \, d t }
{ } { }
{ } { }
} {}{}{.} A primitive function of the hyperbolic sine squared follows from
\mathrelationchaindisplay
{\relationchain
{ \sinh^{ 2 } t }
{ =} { { \left(\frac{1}{2} { \left( e^t - e^{-t} \right) } \right) }^2 }
{ =} { { \frac{ 1 }{ 4 } } { \left( e^{2t} + e^{-2t} -2 \right) } }
{ } { }
{ } { }
} {}{}{.} Therefore,
\mathrelationchaindisplay
{\relationchain
{ \int_{ }^{ } \sinh^{ 2 } u \, d t }
{ =} { { \frac{ 1 }{ 4 } } { \left( { \frac{ 1 }{ 2 } } e^{2u} - { \frac{ 1 }{ 2 } } e^{-2u} - 2u\right) } }
{ =} { { \frac{ 1 }{ 4 } } \sinh 2 u - { \frac{ 1 }{ 2 } } u }
{ } { }
{ } { }
} {}{}{,} and hence
\mathrelationchaindisplay
{\relationchain
{ \int_{ }^{ } \sqrt{x^2-1} \, d x }
{ =} { { \frac{ 1 }{ 4 } } \sinh (2 \, \operatorname{arcosh} \, x \,) - { \frac{ 1 }{ 2 } } \, \operatorname{arcosh} \, x \, }
{ } { }
{ } { }
{ } { }
} {}{}{.} Due to the addition theorem for hyperbolic sine, we have
\mathrelationchain
{\relationchain
{ \sinh 2u }
{ = }{ 2 \sinh u \cosh u }
{ }{ }
{ }{ }
{ }{ }
} {}{}{,} and therefore this primitive function can also be written as
\mathrelationchainalign
{\relationchainalign
{ { \frac{ 1 }{ 2 } } { \left( \sinh { \left( \, \operatorname{arcosh} \, x \, \right) } \cosh { \left( \, \operatorname{arcosh} \, x \, \right) } - \, \operatorname{arcosh} \, x \, \right) } }
{ =} { { \frac{ 1 }{ 2 } } { \left( \sqrt{ \cosh { \left( \, \operatorname{arcosh} \, x \, \right) }^2 -1 } \cdot x - \, \operatorname{arcosh} \, x \, \right) } }
{ =} { { \frac{ 1 }{ 2 } } { \left( \sqrt{ x^2 -1 } \cdot x - \, \operatorname{arcosh} \, x \, \right) } }
{ } { }
{ } { }
} {} {}{.}

}




\inputexample{}
{

We want to find a primitive function for the function
\mathrelationchaindisplay
{\relationchain
{f(x) }
{ =} { { \frac{ x^2 }{ (x \cos x - \sin x )^2 } } }
{ } { }
{ } { }
{ } { }
} {}{}{.} We first determine the derivative of
\mathdisp {{ \frac{ 1 }{ x \cos x - \sin x } }} { . }
This is
\mathrelationchaindisplay
{\relationchain
{ - { \frac{ \cos x -x \sin x - \cos x }{ (x \cos x - \sin x )^2 } } }
{ =} { { \frac{ x \sin x }{ (x \cos x - \sin x )^2 } } }
{ } { }
{ } { }
{ } { }
} {}{}{.} Therefore, we write $f$ as a product
\mathrelationchain
{\relationchain
{f(x) }
{ = }{ { \frac{ x \sin x }{ (x \cos x - \sin x )^2 } } \cdot { \frac{ x }{ \sin x } } }
{ }{ }
{ }{ }
{ }{ }
} {}{}{.} We apply integration by parts, where we integrate the first factor and differentiate the second factor. The derivative of the second factor is
\mathrelationchaindisplay
{\relationchain
{ { \left({ \frac{ x }{ \sin x } }\right) }' }
{ =} { { \frac{ \sin x - x \cos x }{ \sin^{ 2 } x } } }
{ } { }
{ } { }
{ } { }
} {}{}{.} Hence, we have
\mathrelationchainalign
{\relationchainalign
{ \int_{ }^{ } f ( x) \, d x }
{ =} { { \frac{ 1 }{ x \cos x - \sin x } } \cdot { \frac{ x }{ \sin x } } - \int_{ }^{ } { \frac{ 1 }{ x \cos x - \sin x } } \cdot { \frac{ \sin x - x \cos x }{ \sin^{ 2 } x } } \, d x }
{ =} { { \frac{ 1 }{ x \cos x - \sin x } } \cdot { \frac{ x }{ \sin x } } + \int_{ }^{ } { \frac{ 1 }{ \sin^{ 2 } x } } \, d x }
{ =} { { \frac{ 1 }{ x \cos x - \sin x } } \cdot { \frac{ x }{ \sin x } } - \cot x }
{ } {}
} {} {}{.}

}