Rename glossary to reference.
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@ -15,13 +15,15 @@
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\tableofcontents
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\begingroup
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\renewcommand\thechapter{G}
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\renewcommand\thechapter{R}
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\setcounter{chapter}{0}
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\addtocounter{chapter}{-1}
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\chapter{Glossary}%
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\label{chap:glossary}
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\chapter{Reference}%
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\label{chap:reference}
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\section{\defined{Characteristic Function}}%
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\label{def:characteristic-function}
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\label{ref:characteristic-function}
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Let $S$ be a set of points on the real line.
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The \textbf{characteristic function} of $S$ is the function $\mathcal{X}_S$ such
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@ -35,7 +37,7 @@ The \textbf{characteristic function} of $S$ is the function $\mathcal{X}_S$ such
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\end{definition}
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\section{\defined{Infimum}}%
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\label{def:infimum}
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\label{ref:infimum}
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A number $B$ is called an \textbf{infimum} of a nonempty set $S$ if $B$ has
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the following two properties:
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@ -52,36 +54,36 @@ Such a number $B$ is also known as the \textbf{greatest lower bound}.
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\end{definition}
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\section{\partial{Integrable}}%
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\label{def:integrable}
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\label{ref:integrable}
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Let $f$ be a function defined and bounded on $[a, b]$.
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$f$ is said to be \textbf{integrable} if there exists one and only one number
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$I$ such that \eqref{def:integral-bounded-function-eq2} holds.
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$I$ such that \eqref{ref:integral-bounded-function-eq2} holds.
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If $f$ is integrable on $[a, b]$, we say that the integral
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$\int_a^b f(x) \mathop{dx}$ \textbf{exists}.
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\section{\partial{Integral of a Bounded Function}}%
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\label{def:integral-bounded-function}
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\label{ref:integral-bounded-function}
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Let $f$ be a function defined and bounded on $[a, b]$.
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Let $s$ and $t$ denote arbitrary step functions defined on $[a, b]$ such that
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\begin{equation}
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\label{def:integral-bounded-function-eq1}
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\label{ref:integral-bounded-function-eq1}
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s(x) \leq f(x) \leq t(x)
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\end{equation}
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for every $x$ in $[a, b]$.
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If there is one and only one number $I$ such that
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\begin{equation}
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\label{def:integral-bounded-function-eq2}
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\label{ref:integral-bounded-function-eq2}
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\int_a^b s(x) \mathop{dx} \leq I \leq \int_a^b t(x) \mathop{dx}
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\end{equation}
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for every pair of step functions $s$ and $t$ satisfying
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\eqref{def:integral-bounded-function-eq1}, then this number $I$ is called
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\eqref{ref:integral-bounded-function-eq1}, then this number $I$ is called
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the \textbf{integral of $f$ from $a$ to $b$}, and is denoted by the symbol
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$\int_a^b f(x) \mathop{dx}$ or by $\int_a^b f$.
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If $a < b$, we define $\int_b^a f(x) \mathop{dx} = -\int_a^b f(x) \mathop{dx}$,
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provided $f$ is \nameref{def:integrable} on $[a, b]$.
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provided $f$ is \nameref{ref:integrable} on $[a, b]$.
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We also define $\int_a^a f(x) \mathop{dx} = 0$.
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The function $f$ is called the \textbf{integrand}, the numbers $a$ and $b$ are
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@ -89,10 +91,10 @@ The function $f$ is called the \textbf{integrand}, the numbers $a$ and $b$ are
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\textbf{interval of integration}.
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\section{\partial{Integral of a Step Function}}%
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\label{def:integral-step-function}
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\label{ref:integral-step-function}
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Let $s$ be a \nameref{def:step-function} defined on $[a, b]$, and let
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$P = \{x_0, x_1, \ldots, x_n\}$ be a \nameref{def:partition} of $[a, b]$
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Let $s$ be a \nameref{ref:step-function} defined on $[a, b]$, and let
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$P = \{x_0, x_1, \ldots, x_n\}$ be a \nameref{ref:partition} of $[a, b]$
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such that $s$ is constant on the open subintervals of $P$.
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Denote by $s_k$ the constant value that $s$ takes in the $k$th open subinterval
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of $P$, so that
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@ -105,17 +107,17 @@ If $a < b$, we define $\int_b^a s(x) \mathop{dx} = -\int_a^b s(x) \mathop{dx}$.
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We also define $\int_a^a s(x) \mathop{dx} = 0$.
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\section{\partial{Lower Integral}}%
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\label{def:lower-integral}
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\label{ref:lower-integral}
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Let $f$ be a function bounded on $[a, b]$ and $S$ denote the set of numbers
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$\int_a^b s(x) \mathop{dx}$ obtained as $s$ runs through all
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\nameref{def:step-function}s below $f$.
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\nameref{ref:step-function}s below $f$.
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That is, let $$S = \left\{ \int_a^b s(x) \mathop{dx} : s \leq f \right\}.$$
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The number $\sup{S}$ is called the \textbf{lower integral of $f$}.
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It is denoted as $\ubar{I}(f)$.
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\section{\partial{Monotonic}}%
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\label{def:monotonic}
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\label{ref:monotonic}
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A function $f$ is called \textbf{monotonic} on set $S$ if it is increasing on
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$S$ or if it is decreasing on $S$.
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@ -125,11 +127,11 @@ $f$ is said to be \textbf{strictly monotonic} if it is strictly increasing on
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A function $f$ is said to be \textbf{piecewise monotonic} on an interval if its
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graph consists of a finite number of monotonic pieces.
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In other words, $f$ is piecewise monotonic on $[a, b]$ if there is a
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\nameref{def:partition} of $[a, b]$ such that $f$ is monotonic on each of
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\nameref{ref:partition} of $[a, b]$ such that $f$ is monotonic on each of
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the open subintervals of $P$.
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\section{\defined{Partition}}%
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\label{def:partition}
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\label{ref:partition}
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Let $[a, b]$ be a closed interval decomposed into $n$ subintervals by inserting
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$n - 1$ points of subdivision, say $x_1$, $x_2$, $\ldots$, $x_{n-1}$, subject
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@ -151,9 +153,9 @@ A collection of points satisfying \eqref{sec:partition-eq1} is called a
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\end{definition}
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\section{\partial{Refinement}}%
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\label{def:refinement}
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\label{ref:refinement}
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Let $P$ be a \nameref{def:partition} of closed interval $[a, b]$.
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Let $P$ be a \nameref{ref:partition} of closed interval $[a, b]$.
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A \textbf{refinement} $P'$ of $P$ is a partition formed by adjoining more
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subdivision points to those already in $P$.
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@ -161,10 +163,10 @@ $P'$ is said to be \textbf{finer than} $P$. The union of two partitions $P_1$
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and $P_2$ is called the \textbf{common refinement} of $P_1$ and $P_2$.
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\section{\defined{Step Function}}%
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\label{def:step-function}
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\label{ref:step-function}
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A function $s$, whose domain is a closed interval $[a, b]$, is called a
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\textbf{step function} if there is a \nameref{def:partition}
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\textbf{step function} if there is a \nameref{ref:partition}
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$P = \{x_0, x_1, \ldots, x_n\}$ of $[a, b]$ such that $s$ is constant on each
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open subinterval of $P$.
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That is to say, for each $k = 1, 2, \ldots, n$, there is a real number $s_k$
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@ -183,7 +185,7 @@ That is to say, for each $k = 1, 2, \ldots, n$, there is a real number $s_k$
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\end{definition}
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\section{\defined{Supremum}}%
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\label{def:supremum}
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\label{ref:supremum}
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A number $B$ is called a \textbf{supremum} of a nonempty set $S$ if $B$ has
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the following two properties:
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@ -200,11 +202,11 @@ Such a number $B$ is also known as the \textbf{least upper bound}.
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\end{definition}
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\section{\partial{Upper Integral}}%
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\label{def:upper-integral}
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\label{ref:upper-integral}
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Let $f$ be a function bounded on $[a, b]$ and $T$ denote the set of numbers
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$\int_a^b t(x) \mathop{dx}$ obtained as $t$ runs through all
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\nameref{def:step-function}s above $f$.
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\nameref{ref:step-function}s above $f$.
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That is, let $$T = \left\{ \int_a^b t(x) \mathop{dx} : f \leq t \right\}.$$
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The number $\inf{T}$ is called the \textbf{upper integral of $f$}.
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It is denoted as $\bar{I}(f)$.
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@ -241,7 +243,7 @@ Every nonempty set $S$ of real numbers which is bounded above has a supremum;
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{Apostol.Chapter\_I\_03.is\_lub\_neg\_set\_iff\_is\_glb\_set\_neg}
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Suppose $L = \sup{S}$ and fix $x \in S$.
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By definition of the \nameref{def:supremum}, $x \leq L$ and $L$ is the
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By definition of the \nameref{ref:supremum}, $x \leq L$ and $L$ is the
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smallest value satisfying this inequality.
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Negating both sides of the inequality yields $-x \geq -L$.
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Furthermore, $-L$ must be the largest value satisfying this inequality.
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@ -268,7 +270,7 @@ Every nonempty set $S$ of real numbers which is bounded above has a supremum;
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Let $S$ be a nonempty set bounded below by $x$.
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Then $-S$ is nonempty and bounded above by $x$.
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By the \nameref{sec:completeness-axiom}, there exists a
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\nameref{def:supremum} $L$ of $-S$.
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\nameref{ref:supremum} $L$ of $-S$.
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By \nameref{sec:lemma-1}, $L$ is a supremum of $-S$ if and only if $-L$ is an
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infimum of $S$.
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@ -433,7 +435,7 @@ Let $h$ be a given positive number and let $S$ be a set of real numbers.
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\lean{Bookshelf/Apostol/Chapter\_I\_03}
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{Apostol.Chapter\_I\_03.sup\_imp\_exists\_gt\_sup\_sub\_delta}
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By definition of a \nameref{def:supremum}, $\sup{S}$ is the least upper
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By definition of a \nameref{ref:supremum}, $\sup{S}$ is the least upper
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bound of $S$.
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For the sake of contradiction, suppose for all $x \in S$,
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$x \leq \sup{S} - h$.
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@ -459,7 +461,7 @@ Let $h$ be a given positive number and let $S$ be a set of real numbers.
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\lean{Bookshelf/Apostol/Chapter\_I\_03}
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{Apostol.Chapter\_I\_03.inf\_imp\_exists\_lt\_inf\_add\_delta}
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By definition of an \nameref{def:infimum}, $\inf{S}$ is the greatest lower
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By definition of an \nameref{ref:infimum}, $\inf{S}$ is the greatest lower
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bound of $S$.
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For the sake of contradiction, suppose for all $x \in S$,
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$x \geq \inf{S} + h$.
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@ -504,7 +506,7 @@ Given nonempty subsets $A$ and $B$ of $\mathbb{R}$, let $C$ denote the set
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Let $x \in C$.
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By definition of $C$, there exist elements $a' \in A$ and $b' \in B$ such
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that $x = a' + b'$.
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By definition of a \nameref{def:supremum}, $a' \leq \sup{A}$.
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By definition of a \nameref{ref:supremum}, $a' \leq \sup{A}$.
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Likewise, $b' \leq \sup{B}$.
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Therefore $a' + b' \leq \sup{A} + \sup{B}$.
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Since $x = a' + b'$ was arbitrarily chosen, it follows $\sup{A} + \sup{B}$
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@ -575,7 +577,7 @@ Given nonempty subsets $A$ and $B$ of $\mathbb{R}$, let $C$ denote the set
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Let $x \in C$.
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By definition of $C$, there exist elements $a' \in A$ and $b' \in B$ such
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that $x = a' + b'$.
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By definition of an \nameref{def:infimum}, $a' \geq \inf{A}$.
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By definition of an \nameref{ref:infimum}, $a' \geq \inf{A}$.
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Likewise, $b' \geq \inf{B}$.
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Therefore $a' + b' \geq \inf{A} + \inf{B}$.
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Since $x = a' + b'$ was arbitrarily chosen, it follows $\inf{A} + \inf{B}$
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@ -1740,8 +1742,8 @@ Now apply Exercises 4(a) and (b) to the bracket on the right.
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\label{sub:exercise-1.11.8}
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Let $S$ be a set of points on the real line.
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Let $\mathcal{X}_S$ denote the \nameref{def:characteristic-function} of $S$.
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Let $f$ be a \nameref{def:step-function} which takes the constant value
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Let $\mathcal{X}_S$ denote the \nameref{ref:characteristic-function} of $S$.
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Let $f$ be a \nameref{ref:step-function} which takes the constant value
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$c_k$ on the $k$th open subinterval $I_k$ of some partition of an interval
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$[a, b]$.
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Prove that for each $x$ in the union $I_1 \cup I_2 \cup \cdots \cup I_n$ we have
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@ -1754,7 +1756,7 @@ This property is described by saying that every step function is a linear
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Let $x \in I_1 \cup I_2 \cup \cdots \cup I_n$ and $N = \{1, \ldots, n\}$.
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Let $k \in N$ such that $x \in I_k$.
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Consider an arbitrary $j \in N - \{k\}$.
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By definition of a nameref{def:partition}, $I_j \cap I_k = \emptyset$.
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By definition of a nameref{ref:partition}, $I_j \cap I_k = \emptyset$.
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That is, $I_j$ and $I_k$ are disjoint for all $j \in N - \{k\}$.
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Therefore, by definition of the characteristic function,
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$\mathcal{X}_{I_k}(x) = 1$ and $\mathcal{X}_{I_j}(x) = 0$ for all
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\begin{theorem}[1.2]
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Let $s$ and $t$ be \nameref{def:step-function}s on closed interval
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Let $s$ and $t$ be \nameref{ref:step-function}s on closed interval
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$[a, b]$.
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Then
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$$\int_a^b \left[ s(x) + t(x) \right] \mathop{dx} =
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\begin{proof}
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Let $s$ and $t$ be step functions on closed interval $[a, b]$.
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By definition of a step function, there exists a \nameref{def:partition}
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By definition of a step function, there exists a \nameref{ref:partition}
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$P_s$ such that $s$ is constant on each open subinterval of $P_s$.
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Likewise, there exists a partition $P_t$ such that $t$ is constant on each
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open subinterval of $P_t$.
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@ -1804,7 +1806,7 @@ This property is described by saying that every step function is a linear
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$P$.
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Let $t_k$ denote the constant value of $t$ on the $k$th open subinterval of
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$P$.
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By definition of the \nameref{def:integral-step-function},
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By definition of the \nameref{ref:integral-step-function},
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\begin{align*}
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\int_a^b \left[ s(x) + t(x) \right] \mathop{dx}
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& = \sum_{k=1}^n (s_k + t_k) \cdot (x_k - x_{k-1}) \\
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\begin{theorem}[1.3]
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Let $s$ be a \nameref{def:step-function} on closed interval $[a, b]$.
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Let $s$ be a \nameref{ref:step-function} on closed interval $[a, b]$.
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For every real number $c$, we have
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$$\int_a^b c \cdot s(x) \mathop{dx} = c\int_a^b s(x) \mathop{dx}.$$
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\begin{proof}
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Let $s$ be a step function on closed interval $[a, b]$.
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By definition of a step function, there exists a \nameref{def:partition}
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By definition of a step function, there exists a \nameref{ref:partition}
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$P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is constant on each open
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subinterval of $P$.
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Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
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$P$.
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Then $c \cdot s$ is a step function with step partition $P$.
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By definition of the \nameref{def:integral-step-function},
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By definition of the \nameref{ref:integral-step-function},
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\begin{align*}
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\int_a^b c \cdot s(x) \mathop{dx}
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& = \sum_{k=1}^n c \cdot s_k \cdot (x_k - x_{k-1}) \\
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\begin{theorem}[1.4]
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Let $s$ and $t$ be \nameref{def:step-function}s on closed interval
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Let $s$ and $t$ be \nameref{ref:step-function}s on closed interval
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$[a, b]$.
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For every real $c_1$ and $c_2$, we have
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$$\int_a^b \left[ c_1s(x) + c_2t(x) \right] \mathop{dx} =
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\begin{theorem}[1.5]
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Let $s$ and $t$ be \nameref{def:step-function}s on closed interval
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Let $s$ and $t$ be \nameref{ref:step-function}s on closed interval
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$[a, b]$.
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If $s(x) < t(x)$ for every $x$ in $[a, b]$, then
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$$\int_a^b s(x) \mathop{dx} < \int_a^b t(x) \mathop{dx}.$$
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\begin{proof}
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Let $s$ and $t$ be step functions on closed interval $[a, b]$.
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By definition of a step function, there exists a \nameref{def:partition}
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By definition of a step function, there exists a \nameref{ref:partition}
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$P_s$ such that $s$ is constant on each open subinterval of $P_s$.
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Likewise, there exists a partition $P_t$ such that $t$ is constant on each
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open subinterval of $P_t$.
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@ -1907,7 +1909,7 @@ This property is described by saying that every step function is a linear
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$P$.
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Let $t_k$ denote the constant value of $t$ on the $k$th open subinterval of
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$P$.
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By definition of the \nameref{def:integral-step-function},
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By definition of the \nameref{ref:integral-step-function},
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\begin{align*}
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\int_a^b s(x) \mathop{dx}
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& = \sum_{k=1}^n s_k \cdot (x_k - x_{k-1}) \\
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\begin{theorem}[1.6]
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Let $a, b, c \in \mathbb{R}$ and $s$ a \nameref{def:step-function} on the
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Let $a, b, c \in \mathbb{R}$ and $s$ a \nameref{ref:step-function} on the
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smallest closed interval containing them.
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Then
|
||||
$$\int_a^c s(x) \mathop{dx} + \int_c^b s(x) \mathop{dx} +
|
||||
|
@ -1935,7 +1937,7 @@ This property is described by saying that every step function is a linear
|
|||
|
||||
WLOG, suppose $a < c < b$ and $s$ be a step function on closed interval
|
||||
$[a, b]$.
|
||||
By definition of a step function, there exists a \nameref{def:partition}
|
||||
By definition of a step function, there exists a \nameref{ref:partition}
|
||||
$P$ such that $s$ is constant on each open subinterval of $P$.
|
||||
|
||||
Let $Q = \{x_0, x_1, \ldots, x_n\}$ be a refinement of $P$ that includes $c$
|
||||
|
@ -1944,7 +1946,7 @@ This property is described by saying that every step function is a linear
|
|||
that $x_i = c$.
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
$Q$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b s(x) \mathop{dx}
|
||||
& = \sum_{k=1}^n s_k \cdot (x_k - x_{k - 1}) \\
|
||||
|
@ -1979,7 +1981,7 @@ This property is described by saying that every step function is a linear
|
|||
\begin{proof}
|
||||
|
||||
Let $s$ be a step function on closed interval $[a, b]$.
|
||||
By definition of a step function, there exists a \nameref{def:partition}
|
||||
By definition of a step function, there exists a \nameref{ref:partition}
|
||||
$P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is constant on each open
|
||||
subinterval of $P$.
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
|
@ -1992,7 +1994,7 @@ This property is described by saying that every step function is a linear
|
|||
Let $t_k$ denote the value of $t$ on the $k$th open subinterval of $Q$.
|
||||
By construction, $t_k = s_k$.
|
||||
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_{a+c}^{b+c} s(x - c) \mathop{dx}
|
||||
& = \int_{a+c}^{b+c} t(x) \mathop{dx} \\
|
||||
|
@ -2020,7 +2022,7 @@ This property is described by saying that every step function is a linear
|
|||
\begin{proof}
|
||||
|
||||
Let $s$ be a step function on closed interval $[a, b]$.
|
||||
By definition of a step function, there exists a \nameref{def:partition}
|
||||
By definition of a step function, there exists a \nameref{ref:partition}
|
||||
$P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is constant on each open
|
||||
subinterval of $P$.
|
||||
Let $s_i$ denote the value of $s$ on the $i$th open subinterval of $P$.
|
||||
|
@ -2034,7 +2036,7 @@ This property is described by saying that every step function is a linear
|
|||
Then $t(x) = s(x / k)$ is a step function on closed interval $[ka, kb]$
|
||||
with partition $Q = \{kx_0, kx_1, \ldots, kx_n\}$.
|
||||
Furthermore $t_i = s_i$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_{ka}^{kb} s(x / k) \mathop{dx}
|
||||
& = \int_{ka}^{kb} t(x) \mathop{dx} \\
|
||||
|
@ -2050,7 +2052,7 @@ This property is described by saying that every step function is a linear
|
|||
Then $t(x) = s(x / k)$ is a step function on closed interval $[kb, ka]$
|
||||
with partition $Q = \{kx_n, kx_{n-1}, \ldots, kx_0\}$.
|
||||
Furthermore $t_i = s_i$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_{ka}^{kb} s(x / k) \mathop{dx}
|
||||
& = -\int_{kb}^{ka} s(x / k) \mathop{dx} \\
|
||||
|
@ -2102,7 +2104,7 @@ $\int_{-1}^3 \floor{x} \mathop{dx}$.
|
|||
$P = \{-1, 0, 1, 2, 3\} = \{x_0, x_1, x_2, x_3, x_4\}$.
|
||||
Let $s_k$ denote the constant value $s$ takes on the $k$th open subinterval of
|
||||
$P$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_{-1}^3 \floor{x} \mathop{dx}
|
||||
& = \sum_{k=1}^4 s_k \cdot (x_k - x_{k-1}) \\
|
||||
|
@ -2129,7 +2131,7 @@ $\int_{-1}^3 \left(\floor{x} + \floor{x + \frac{1}{2}}\right) \mathop{dx}$.
|
|||
\end{align*}
|
||||
Let $s_k$ denote the constant value $s$ takes on the $k$th open subinterval of
|
||||
$P$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_{-1}^3 \floor{x} + \floor{x + \frac{1}{2}}
|
||||
& = \sum_{k=1}^8 s_k \cdot (x_k - x_{k-1}) \\
|
||||
|
@ -2166,13 +2168,13 @@ Show that
|
|||
Let $s(x) = \floor{x}$ and $t(x) = \floor{-x}$, both with domain $[a, b]$.
|
||||
Let $x_1$, $\ldots$, $x_{n-1}$ denote the integers found in interval $(a, b)$.
|
||||
Then $P = \{x_0, x_1, \ldots, x_n\}$, $x_0 = a$ and $x_n = b$, is a step
|
||||
\nameref{def:partition} of both $s$ and $t$.
|
||||
\nameref{ref:partition} of both $s$ and $t$.
|
||||
Let $s_k$ and $t_k$ denote the constant values $s$ and $t$ take on the $k$th
|
||||
open subinterval of $P$ respectively.
|
||||
By \nameref{ssub:exercise-1.11.4b}, $\floor{-x} = -\floor{x} - 1$ for all $x$
|
||||
in every open subinterval of $P$.
|
||||
That is, $s_k = -t_k - 1$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b \floor{x} \mathop{dx} + \int_a^b \floor{-x} \mathop{dx}
|
||||
& = \sum_{k=1}^n s_k (x_k - x_{k-1}) +
|
||||
|
@ -2197,11 +2199,11 @@ Prove that $\int_0^2 \floor{t^2} \mathop{dt} = 5 - \sqrt{2} - \sqrt{3}$.
|
|||
\begin{proof}
|
||||
|
||||
Let $s(t) = \floor{t^2}$ with domain $[0, 2]$.
|
||||
Then $s$ is a \nameref{def:step-function} with partition
|
||||
Then $s$ is a \nameref{ref:step-function} with partition
|
||||
$P = \{0, 1, \sqrt{2}, \sqrt{3}, 2\} = \{x_0, x_1, \ldots, x_4\}$.
|
||||
Let $s_k$ denote the constant value that $s$ takes in the $k$th open
|
||||
subinterval of $P$.
|
||||
By the \nameref{def:integral-step-function},
|
||||
By the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_0^2 \floor{t^2} \mathop{dt}
|
||||
& = \sum_{k=1}^4 s_k \cdot (x_k - x_{k-1}) \\
|
||||
|
@ -2220,7 +2222,7 @@ Compute $\int_{-3}^3 \floor{t^2} \mathop{dt}$.
|
|||
\begin{proof}
|
||||
|
||||
Let $s(t) = \floor{t^2}$ with domain $[0, 3]$.
|
||||
Then $s$ is a \nameref{def:step-function} with \nameref{def:partition}
|
||||
Then $s$ is a \nameref{ref:step-function} with \nameref{ref:partition}
|
||||
\begin{align*}
|
||||
P
|
||||
& = \{\sqrt{0}, \sqrt{1}, \sqrt{2}, \sqrt{3}, \sqrt{4}, \sqrt{5},
|
||||
|
@ -2229,7 +2231,7 @@ Compute $\int_{-3}^3 \floor{t^2} \mathop{dt}$.
|
|||
\end{align*}
|
||||
Let $s_k$ denote the constant value that $s$ takes in the $k$th open
|
||||
subinterval of $P$.
|
||||
By the \nameref{def:integral-step-function},
|
||||
By the \nameref{ref:integral-step-function},
|
||||
\begin{align}
|
||||
\int_0^3 \floor{t^2} \mathop{dt}
|
||||
& = \sum_{k=1}^9 s_k \cdot (x_k - x_{k-1})
|
||||
|
@ -2267,11 +2269,11 @@ Compute $\int_0^9 \floor{\sqrt{t}} \mathop{dt}$.
|
|||
\begin{proof}
|
||||
|
||||
Let $s(t) = \floor{\sqrt{t}}$ with domain $[0, 9]$.
|
||||
Then $s$ is a \nameref{def:step-function} with \nameref{def:partition}
|
||||
Then $s$ is a \nameref{ref:step-function} with \nameref{ref:partition}
|
||||
$P = \{0, 1, 4, 9\} = \{x_0, x_1, x_2, x_3\}$.
|
||||
Let $s_k$ denote the constant value that $s$ takes in the $k$th open
|
||||
subinterval of $P$.
|
||||
By the \nameref{def:integral-step-function},
|
||||
By the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_0^9 \floor{\sqrt{t}} \mathop{dt}
|
||||
& = \sum_{k=1}^3 s_k \cdot (x_k - x_{k-1}) \\
|
||||
|
@ -2300,11 +2302,11 @@ If $n$ is a positive integer, prove that
|
|||
|
||||
Let $n = 1$.
|
||||
Define $s(t) = \floor{\sqrt{t}}$ with domain $[0, 1]$.
|
||||
Then $s$ is a \nameref{def:step-function} with \nameref{def:partition}
|
||||
Then $s$ is a \nameref{ref:step-function} with \nameref{ref:partition}
|
||||
$P = \{0, 1\} = \{x_0, x_1\}$.
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
$P$.
|
||||
By definition of the \nameref{def:integral-step-function}, the left-hand
|
||||
By definition of the \nameref{ref:integral-step-function}, the left-hand
|
||||
side of \eqref{sub:exercise-1.15.7b-eq1} evaluates to
|
||||
\begin{align*}
|
||||
\int_0^{n^2} \floor{\sqrt{t}} \mathop{dt}
|
||||
|
@ -2320,7 +2322,7 @@ If $n$ is a positive integer, prove that
|
|||
|
||||
Let $n > 0$ be a positive integer and suppose $P(n)$ is true.
|
||||
Define $s(t) = \floor{\sqrt{t}}$ with domain $[0, (n + 1)^2]$.
|
||||
Then $s$ is a \nameref{def:step-function} with \nameref{def:partition}
|
||||
Then $s$ is a \nameref{ref:step-function} with \nameref{ref:partition}
|
||||
\begin{align*}
|
||||
P
|
||||
& = \{0, 1, 4, \ldots, n^2, (n + 1)^2\} \\
|
||||
|
@ -2328,7 +2330,7 @@ If $n$ is a positive integer, prove that
|
|||
\end{align*}
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
$P$.
|
||||
By definition of the \nameref{def:integral-step-function}, it follows
|
||||
By definition of the \nameref{ref:integral-step-function}, it follows
|
||||
that
|
||||
\begin{align*}
|
||||
& \int_0^{(n + 1)^2} s(x) \mathop{dx} \\
|
||||
|
@ -2405,8 +2407,8 @@ $\int_a^b s + \int_b^c s = \int_a^c s$.
|
|||
|
||||
WLOG, suppose $a < b < c$.
|
||||
Let $s$ be a step function defined on closed interval $[a, c]$.
|
||||
By definition of a \nameref{def:step-function}, there exists a
|
||||
\nameref{def:partition} such that $s$ is constant on each open
|
||||
By definition of a \nameref{ref:step-function}, there exists a
|
||||
\nameref{ref:partition} such that $s$ is constant on each open
|
||||
subinterval of $P$.
|
||||
Let $Q = \{x_0, x_1, \ldots, x_n\}$ be a refinement of $P$ that includes $b$
|
||||
as a subdivision point.
|
||||
|
@ -2439,7 +2441,7 @@ $\int_a^b (s + t) = \int_a^b s + \int_a^b t$.
|
|||
\vspace{6pt}
|
||||
|
||||
Let $s$ and $t$ be step functions on closed interval $[a, b]$.
|
||||
By definition of a step function, there exists a \nameref{def:partition}
|
||||
By definition of a step function, there exists a \nameref{ref:partition}
|
||||
$P_s$ such that $s$ is constant on each open subinterval of $P_s$.
|
||||
Likewise, there exists a partition $P_t$ such that $t$ is constant on each
|
||||
open subinterval of $P_t$.
|
||||
|
@ -2486,7 +2488,7 @@ $\int_a^b c \cdot s = c \int_a^b s$.
|
|||
\vspace{6pt}
|
||||
|
||||
Let $s$ be a step function on closed interval $[a, b]$.
|
||||
By definition of a step function, there exists a \nameref{def:partition}
|
||||
By definition of a step function, there exists a \nameref{ref:partition}
|
||||
$P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is constant on each open
|
||||
subinterval of $P$.
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
|
@ -2518,8 +2520,8 @@ $\int_{a+c}^{b+c} s(x) \mathop{dx} = \int_a^b s(x + c) \mathop{dx}$.
|
|||
\vspace{6pt}
|
||||
|
||||
Let $s$ be a step function on closed interval $[a + c, b + c]$.
|
||||
By definition of a \nameref{def:step-function}, there exists a
|
||||
\nameref{def:partition} $P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is
|
||||
By definition of a \nameref{ref:step-function}, there exists a
|
||||
\nameref{ref:partition} $P = \{x_0, x_1, \ldots, x_n\}$ such that $s$ is
|
||||
constant on each open subinterval of $P$.
|
||||
Let $s_k$ denote the constant value of $s$ on the $k$th open subinterval of
|
||||
$P$.
|
||||
|
@ -2556,8 +2558,8 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
\vspace{6pt}
|
||||
|
||||
Let $s$ and $t$ be step functions on closed interval $[a, b]$.
|
||||
By definition of a \nameref{def:step-function}, there exists a
|
||||
\nameref{def:partition} $P_s$ such that $s$ is constant on each open
|
||||
By definition of a \nameref{ref:step-function}, there exists a
|
||||
\nameref{ref:partition} $P_s$ such that $s$ is constant on each open
|
||||
subinterval of $P_s$.
|
||||
Likewise, there exists a partition $P_t$ such that $t$ is constant on each
|
||||
open subinterval of $P_t$.
|
||||
|
@ -2596,8 +2598,8 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
\int_a^b s(x) \mathop{dx} \leq \ubar{I}(f) \leq
|
||||
\bar{I}(f) \leq \int_a^b t(x) \mathop{dx}
|
||||
\end{equation}
|
||||
for all \nameref{def:step-function}s $s$ and $t$ with $s \leq f \leq t$.
|
||||
The function $f$ is \nameref{def:integrable} on $[a, b]$ if and only if
|
||||
for all \nameref{ref:step-function}s $s$ and $t$ with $s \leq f \leq t$.
|
||||
The function $f$ is \nameref{ref:integrable} on $[a, b]$ if and only if
|
||||
its upper and lower integrals are equal, in which case we have
|
||||
$$\int_a^b f(x) \mathop{dx} = \ubar{I}(f) = \bar{I}(f).$$
|
||||
|
||||
|
@ -2627,10 +2629,10 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
|
||||
By construction, $s \leq t$ for every $s$ in $S$ and $t$ in $T$.
|
||||
Therefore \nameref{sec:theorem-i.34} tells us $S$ has a
|
||||
\nameref{def:supremum}, $T$ has an \nameref{def:infimum}, and
|
||||
\nameref{ref:supremum}, $T$ has an \nameref{ref:infimum}, and
|
||||
$\sup{S} \leq \inf{T}$.
|
||||
By definition of the \nameref{def:lower-integral}, $\ubar{I}(f) = \sup{S}$.
|
||||
By definition of the \nameref{def:upper-integral}, $\bar{I}(f) = \inf{S}$.
|
||||
By definition of the \nameref{ref:lower-integral}, $\ubar{I}(f) = \sup{S}$.
|
||||
By definition of the \nameref{ref:upper-integral}, $\bar{I}(f) = \inf{S}$.
|
||||
Thus \eqref{sub:theorem-1.9-eq1} holds.
|
||||
|
||||
\paragraph{(ii)}%
|
||||
|
@ -2639,7 +2641,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
there exists one and only one number $I$ such that
|
||||
$$\int_a^b s(x) \mathop{dx} \leq I \leq \int_a^b t(x) \mathop{dx}$$
|
||||
for every pair of step functions $s$ and $t$ satisfying
|
||||
\eqref{def:integral-bounded-function-eq1}.
|
||||
\eqref{ref:integral-bounded-function-eq1}.
|
||||
By \eqref{sub:theorem-1.9-eq1} and the definition of the supremum/infimum,
|
||||
this holds if and only if $\ubar{I}(f) = \bar{I}(f)$, concluding the
|
||||
proof.
|
||||
|
@ -2654,7 +2656,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
|
||||
\begin{theorem}[1.10]
|
||||
|
||||
Let $f$ be a nonnegative function, \nameref{def:integrable} on an interval
|
||||
Let $f$ be a nonnegative function, \nameref{ref:integrable} on an interval
|
||||
$[a, b]$, and let $Q$ denote the ordinate set of $f$ over $[a, b]$.
|
||||
Then $Q$ is measurable and its area is equal to the integral
|
||||
$\int_a^b f(x) \mathop{dx}$.
|
||||
|
@ -2663,11 +2665,11 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
|
||||
\begin{proof}
|
||||
|
||||
Let $f$ be a nonnegative function, \nameref{def:integrable} on $[a, b]$.
|
||||
Let $f$ be a nonnegative function, \nameref{ref:integrable} on $[a, b]$.
|
||||
By definition of integrability, there exists one and only one number $I$ such
|
||||
that $$\int_a^b s(x) \mathop{dx} \leq I \leq \int_a^b t(x) \mathop{dx}$$ for
|
||||
every pair of step functions $s$ and $t$ satisfying
|
||||
\eqref{def:integral-bounded-function-eq1}.
|
||||
\eqref{ref:integral-bounded-function-eq1}.
|
||||
In other words, $I$ is the one and only number that satisfies
|
||||
$$a(S) \leq I \leq a(T)$$ for every pair of step regions
|
||||
$S \subseteq Q \subseteq T$.
|
||||
|
@ -2706,7 +2708,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
such that
|
||||
$$\int_a^b s(x) \mathop{dx} \leq I \leq \int_a^b t(x) \mathop{dx}$$
|
||||
for every pair of step functions $s$ and $t$ satisfying
|
||||
\eqref{def:integral-bounded-function-eq1}.
|
||||
\eqref{ref:integral-bounded-function-eq1}.
|
||||
In other words, $I$ is the one and only number that satisfies
|
||||
$$a(S) \leq I \leq a(T)$$ for every pair of step regions
|
||||
$S \subseteq Q' \subseteq T$.
|
||||
|
@ -2738,8 +2740,8 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
|
||||
\begin{theorem}[1.12]
|
||||
|
||||
If $f$ is \nameref{def:monotonic} on a closed interval $[a, b]$, then $f$
|
||||
is \nameref{def:integrable} on $[a, b]$.
|
||||
If $f$ is \nameref{ref:monotonic} on a closed interval $[a, b]$, then $f$
|
||||
is \nameref{ref:integrable} on $[a, b]$.
|
||||
|
||||
\end{theorem}
|
||||
|
||||
|
@ -2749,8 +2751,8 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
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|||
That is to say, either $f$ is increasing on $[a, b]$ or $f$ is decreasing on
|
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$[a, b]$.
|
||||
Because $f$ is on a closed interval, it is bounded.
|
||||
By \nameref{sub:theorem-1.9}, $f$ has a \nameref{def:lower-integral}
|
||||
$\ubar{I}(f)$, $f$ has an \nameref{def:upper-integral} $\bar{I}(f)$,
|
||||
By \nameref{sub:theorem-1.9}, $f$ has a \nameref{ref:lower-integral}
|
||||
$\ubar{I}(f)$, $f$ has an \nameref{ref:upper-integral} $\bar{I}(f)$,
|
||||
and $f$ is integrable if and only if $\ubar{I}(f) = \bar{I}(f)$.
|
||||
|
||||
Consider a partition $P = \{x_0, x_1, \ldots, x_n\}$ of $[a, b]$ in which
|
||||
|
@ -2770,7 +2772,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
\int_a^b s(x) \mathop{dx} \leq \ubar{I}(f)
|
||||
\leq \bar{I}(f) \leq \int_a^b t(x) \mathop{dx}.
|
||||
\end{equation}
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b s(x) \mathop{dx}
|
||||
& = \sum_{k=1}^n f(x_{k-1})\left[\frac{b - a}{n}\right] \\
|
||||
|
@ -2809,7 +2811,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
\int_a^b s(x) \mathop{dx} \leq \ubar{I}(f)
|
||||
\leq \bar{I}(f) \leq \int_a^b t(x) \mathop{dx}.
|
||||
\end{equation}
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b s(x) \mathop{dx}
|
||||
& = \sum_{k=1}^n f(x_k)\left[\frac{b - a}{n}\right] \\
|
||||
|
@ -2863,7 +2865,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
on every $k$th open subinterval of $P$.
|
||||
Let $t$ be the step function above $f$ with constant value $f(x_k)$
|
||||
on every $k$th open subinterval of $P$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b s(x) \mathop{dx}
|
||||
& = \sum_{k=1}^n f(x_{k-1})\left[\frac{b - a}{n}\right] \\
|
||||
|
@ -2935,7 +2937,7 @@ If $s(x) < t(x)$ for each $x$ in $[a, b]$, then $\int_a^b s < \int_a^b t$.
|
|||
on every $k$th open subinterval of $P$.
|
||||
Let $t$ be the step function above $f$ with constant value $f(x_{k-1})$
|
||||
on every $k$th open subinterval of $P$.
|
||||
By definition of the \nameref{def:integral-step-function},
|
||||
By definition of the \nameref{ref:integral-step-function},
|
||||
\begin{align*}
|
||||
\int_a^b s(x) \mathop{dx}
|
||||
& = \sum_{k=1}^n f(x_k) \left[\frac{b - a}{n}\right] \\
|
||||
|
|
|
@ -10,10 +10,10 @@
|
|||
\tableofcontents
|
||||
|
||||
\begingroup
|
||||
\renewcommand\thechapter{G}
|
||||
\renewcommand\thechapter{R}
|
||||
|
||||
\chapter{Glossary}%
|
||||
\label{chap:glossary}
|
||||
\chapter{Reference}%
|
||||
\label{chap:reference}
|
||||
|
||||
\endgroup
|
||||
|
||||
|
|
Loading…
Reference in New Issue