From: Michael Orlitzky <michael@orlitzky.com>
Date: Mon, 4 Nov 2019 14:26:24 +0000 (-0500)
Subject: mjo-set: adopt basic set operations from mjo-common.
X-Git-Url: http://gitweb.michael.orlitzky.com/?p=mjotex.git;a=commitdiff_plain;h=4febc3ad82bc8ac73e660c484e105835feb1ed84

mjo-set: adopt basic set operations from mjo-common.
---

diff --git a/examples.tex b/examples.tex
index e11815e..f922d65 100644
--- a/examples.tex
+++ b/examples.tex
@@ -100,39 +100,21 @@
     %
     The factorial of the number $10$ is $\factorial{10}$.
 
-    The Cartesian product of two sets $A$ and $B$ is
-    $\cartprod{A}{B}$; if we take the product with $C$ as well, then
-    we obtain $\cartprodthree{A}{B}{C}$. The direct sum of $V$ and $W$
-    is $\directsum{V}{W}$. Or three things,
-    $\directsumthree{U}{V}{W}$. How about more things? Like
-    $\directsummany{k=1}{\infty}{V_{k}} \ne
-    \cartprodmany{k=1}{\infty}{V_{k}}$. Those direct sums and
-    cartesian products adapt nicely to display equations:
+    The direct sum of $V$ and $W$ is $\directsum{V}{W}$. Or three
+    things, $\directsumthree{U}{V}{W}$. How about more things? Like
+    $\directsummany{k=1}{\infty}{V_{k}}$. Those direct sums
+    adapt nicely to display equations:
     %
     \begin{equation*}
-      \directsummany{k=1}{\infty}{V_{k}} \ne \cartprodmany{k=1}{\infty}{V_{k}}.
+      \directsummany{k=1}{\infty}{V_{k}} \ne \emptyset.
     \end{equation*}
     %
     Here are a few common tuple spaces that should not have a
     superscript when that superscript would be one: $\Nn[1]$,
     $\Zn[1]$, $\Qn[1]$, $\Rn[1]$, $\Cn[1]$. However, if the
     superscript is (say) two, then it appears: $\Nn[2]$, $\Zn[2]$,
-    $\Qn[2]$, $\Rn[2]$, $\Cn[2]$.
-
-    We also have a few basic set operations, for example the union of
-    two or three sets: $\union{A}{B}$, $\unionthree{A}{B}{C}$. And of
-    course with union comes intersection: $\intersect{A}{B}$,
-    $\intersectthree{A}{B}{C}$. We can also take an arbitrary
-    (indexed) union and intersections of things, like
-    $\unionmany{k=1}{\infty}{A_{k}}$ or
-    $\intersectmany{k=1}{\infty}{B_{k}}$. The best part about those
-    is that they do the right thing in a display equation:
-    %
-    \begin{equation*}
-      \unionmany{k=1}{\infty}{A_{k}} = \intersectmany{k=1}{\infty}{B_{k}}
-    \end{equation*}
-    %
-    Finally, we have the four standard types of intervals in $\Rn[1]$,
+    $\Qn[2]$, $\Rn[2]$, $\Cn[2]$. Finally, we have the four standard
+    types of intervals in $\Rn[1]$,
     %
     \begin{align*}
       \intervaloo{a}{b} &= \setc{ x \in \Rn[1]}{ a < x < b },\\
@@ -310,6 +292,29 @@
   \begin{section}{Set theory}
     The cardinality of the set $X \coloneqq \set{1,2,3}$ is $\card{X}
     = 3$, and its powerset is $\powerset{X}$.
+
+    We also have a few basic set operations, for example the union of
+    two or three sets: $\union{A}{B}$, $\unionthree{A}{B}{C}$. And of
+    course with union comes intersection: $\intersect{A}{B}$,
+    $\intersectthree{A}{B}{C}$. The Cartesian product of two sets $A$
+    and $B$ is there too: $\cartprod{A}{B}$. If we take the product
+    with $C$ as well, then we obtain $\cartprodthree{A}{B}{C}$.
+
+    We can also take an arbitrary (indexed) union, intersection, or
+    Cartesian product of things, like
+    $\unionmany{k=1}{\infty}{A_{k}}$,
+    $\intersectmany{k=1}{\infty}{B_{k}}$, or
+    $\cartprodmany{k=1}{\infty}{C_{k}}$. The best part about those is
+    that they do the right thing in a display equation:
+    %
+    \begin{equation*}
+      \unionmany{k=1}{\infty}{A_{k}}
+      \ne
+      \intersectmany{k=1}{\infty}{B_{k}}
+      \ne
+      \cartprodmany{k=1}{\infty}{C_{k}}.
+    \end{equation*}
+    %
   \end{section}
 
   \begin{section}{Theorems}
diff --git a/mjo-common.tex b/mjo-common.tex
index 2785d73..0fcc2aa 100644
--- a/mjo-common.tex
+++ b/mjo-common.tex
@@ -8,10 +8,6 @@
   \usepackage{amsfonts}
 \fi
 
-\ifx\bigtimes\undefined
-  \usepackage{mathtools}
-\fi
-
 % Place the argument in matching left/right parentheses.
 \newcommand*{\of}[1]{ \left({#1}\right) }
 
@@ -48,12 +44,6 @@
 % A seven-tuple of things.
 \newcommand*{\septuple}[7]{ \left({#1},{#2},{#3},{#4},{#5},{#6},{#7}\right) }
 
-% The Cartesian product of two things.
-\newcommand*{\cartprod}[2]{ {#1}\times{#2} }
-
-% The Cartesian product of three things.
-\newcommand*{\cartprodthree}[3]{ \cartprod{{#1}}{\cartprod{{#2}}{{#3}}} }
-
 % The direct sum of two things.
 \newcommand*{\directsum}[2]{ {#1}\oplus{#2} }
 
@@ -139,22 +129,6 @@
 \fi
 
 
-%
-% Basic set operations
-%
-
-% The union of its two arguments.
-\newcommand*{\union}[2]{ {#1}\cup{#2} }
-
-% A three-argument union.
-\newcommand*{\unionthree}[3]{ \union{\union{#1}{#2}}{#3} }
-
-% The intersection of its two arguments.
-\newcommand*{\intersect}[2]{ {#1}\cap{#2} }
-
-% A three-argument intersection.
-\newcommand*{\intersectthree}[3]{ \intersect{\intersect{#1}{#2}}{#3} }
-
 % An indexed arbitrary binary operation such as the union or
 % intersection of an infinite number of sets. The first argument is
 % the operator symbol to use, such as \cup for a union. The second
@@ -168,10 +142,9 @@
              { {#1}_{#2}^{#3}{#4} }
 }
 
-\newcommand*{\intersectmany}[3]{ \binopmany{\bigcap}{#1}{#2}{#3} }
-\newcommand*{\cartprodmany}[3]{ \binopmany{\bigtimes}{#1}{#2}{#3} }
+
 \newcommand*{\directsummany}[3]{ \binopmany{\bigoplus}{#1}{#2}{#3} }
-\newcommand*{\unionmany}[3]{ \binopmany{\bigcup}{#1}{#2}{#3} }
+
 
 % The four standard (UNLESS YOU'RE FRENCH) types of intervals along
 % the real line.
diff --git a/mjo-set.tex b/mjo-set.tex
index 23ea691..2134e64 100644
--- a/mjo-set.tex
+++ b/mjo-set.tex
@@ -4,18 +4,25 @@
 \ifx\havemjoset\undefined
 \def\havemjoset{1}
 
+\input{mjo-common} % binopmany
 \input{mjo-font} % amsfonts and \mathpzc
 
 \ifx\operatorname\undefined
   \usepackage{amsopn}
 \fi
 
+\ifx\bigtimes\undefined
+  \usepackage{mathtools}
+\fi
+
+
 % The cardinality of a set. The |X| notation conflicts with the
 % absolute value, and the meaning of card(X) is clear at once, so we
 % prefer the latter.
 \newcommand*{\card}[1]{ \operatorname{card}\of{{#1}} }
 
 
+% The powerset of (that is, the set of all subsets of) its argument.
 \newcommand*{\powerset}[1]{\mathpzc{P}\of{{#1}}}
 \ifdefined\newglossaryentry
   \newglossaryentry{powerset}{
@@ -26,4 +33,36 @@
 \fi
 
 
+%
+% Basic set operations
+%
+
+% The union of its two arguments.
+\newcommand*{\union}[2]{ {#1}\cup{#2} }
+
+% A three-argument union.
+\newcommand*{\unionthree}[3]{ \union{\union{#1}{#2}}{#3} }
+
+% The indexed union of many things.
+\newcommand*{\unionmany}[3]{ \binopmany{\bigcup}{#1}{#2}{#3} }
+
+% The intersection of its two arguments.
+\newcommand*{\intersect}[2]{ {#1}\cap{#2} }
+
+% A three-argument intersection.
+\newcommand*{\intersectthree}[3]{ \intersect{\intersect{#1}{#2}}{#3} }
+
+% The indexed intersection of many things.
+\newcommand*{\intersectmany}[3]{ \binopmany{\bigcap}{#1}{#2}{#3} }
+
+% The Cartesian product of two things.
+\newcommand*{\cartprod}[2]{ {#1}\times{#2} }
+
+% The Cartesian product of three things.
+\newcommand*{\cartprodthree}[3]{ \cartprod{{#1}}{\cartprod{{#2}}{{#3}}} }
+
+% The indexed Cartesian product of many things.
+\newcommand*{\cartprodmany}[3]{ \binopmany{\bigtimes}{#1}{#2}{#3} }
+
+
 \fi