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@@ -87,41 +87,79 @@
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Let $(E, \le)$ be a vector lattice and $x, y \in E$, then $x$ and $y$ are \textbf{disjoint}, denoted $x \perp y$, if $|x| \wedge |y| = 0$.
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\end{definition}
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\begin{lemma}
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\label{lemma:lattice-gymnastics}
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Let $E$ be a vector lattice and $a, b, c, d \in E$, then
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\begin{enumerate}
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\item $a + b = a \vee b + a \wedge b$.
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\item $b \le a + |b - a|$.
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\item If $c \ge 0$, then $(a + c) \vee b \le a \vee b + c$.
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\item $|a \vee c - b \vee c| \le |a - b|$.
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\item $|a \vee c - b \vee d| \le |a - b| \vee |c- d|$
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\end{enumerate}
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\end{lemma}
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\begin{proof}
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(1): By translation invariance,
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\begin{align*}
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x \vee y + x \wedge y - x - y &= 0 \vee (y - x) + (x - y) \wedge 0 \\
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&= 0 \vee (y - x) - 0 \vee (x - y) = 0
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\end{align*}
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\begin{proposition}[{{\cite[V.1.1]{SchaeferWolff}}}]
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(2): $b = a + b - a \le a + |b - a|$.
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(3): Since $c \ge 0$,
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\[
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(a + c) \vee b = (a + c) \vee (b - c + c) = a \vee (b - c) + c \le a \vee b + c
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\]
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(4): By (2) and then (3),
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\begin{align*}
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a \vee c - b \vee c &\le (b + |a - b|) \vee c - b \vee c \\
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&\le b \vee c + |a - b| - b \vee c \le |a - b|
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\end{align*}
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Similarly, $b \vee c - a \vee c \le |b - a| = |a - b|$.
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(5): Finally,
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\begin{align*}
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a \vee c - b \vee d &\le (b + |a - b|) \vee (d + |c- d|) - b \vee d \\
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&\le (b + |a - b| \vee |c- d|) \vee (d + |a - b| \vee |c- d|) - b \vee d \\
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&= b \vee d + |a - b| \vee |c- d| - b \vee d \\
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&\le |a - b| \vee |c- d|
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\end{align*}
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Similarly,
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\[
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b \vee d - a \vee c \le |b - a| \vee |d - c| = |a - b| \vee |c- d|
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\]
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\end{proof}
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\begin{proposition}
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\label{proposition:lattice-properties}
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Let $(E, \le)$ be a vector lattice, then:
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\begin{enumerate}
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\item For any $x, y \in E$,
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\[
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x + y = x \vee y + x \wedge y
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\]
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\item Let $x \in E$, $x^+ = x \vee 0 \ge 0$, and $x^- = -(x \wedge 0) \ge 0$, then $x = x^+ - x^-$ and $|x| = x^+ + x^-$. Moreover, $(x^+, x^-)$ are the unique disjoint non-negative elements of $E$ such that $x = x^+ - x^-$.
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\end{enumerate}
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For any $x, y \in E$ and $\lambda \in \real$,
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\begin{enumerate}
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\item[(3)] $|\lambda x| = |\lambda| \cdot |x|$
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\item[(4)] $|x + y| \le |x| + |y|$.
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\begin{enumerate}[start=1]
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\item $|\lambda x| = |\lambda| \cdot |x|$
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\item $|x + y| \le |x| + |y|$.
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\end{enumerate}
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Finally, for any $x, y \in E$ with $x, y \ge 0$,
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\begin{enumerate}
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\item[(5)] $[0, x] + [0, y] = [0, x + y]$.
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\begin{enumerate}[start=3]
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\item $[0, x] + [0, y] = [0, x + y]$.
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\end{enumerate}
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\end{proposition}
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\begin{proof}
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(1): By \autoref{proposition:ordered-vector-space-properties},
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\begin{align*}
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x \vee y + x \wedge y - x - y &= 0 \vee (y - x) + (x - y) \wedge 0 \\
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&= 0 \vee (y - x) - 0 \vee (y - x) = 0
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\end{align*}
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(2): By (1),
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\begin{proof}[Proof, {{\cite[V.1.1]{SchaeferWolff}}}. ]
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(1): By \autoref{lemma:lattice-gymnastics},
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\[
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x = x + 0 = x \vee 0 + x \wedge 0 = x^+ - x^-
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\]
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@@ -150,12 +188,12 @@
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and $x^- \le z$. If $y \perp z$, then $y - x^+ \perp z - x^-$. Since $y - x^+ = z - x^-$, $y - x^+ = z - x^- = 0$, so $y = x^+$ and $z = x^-$.
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(3): For any $\lambda > 0$, by (LO2),
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(2): For any $\lambda > 0$, by (LO2),
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\[
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|\lambda x| = (\lambda x) \vee (-\lambda x) = \lambda (x \vee -x) = \lambda |x|
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\]
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(4): For any $x, y \in E$, by \autoref{proposition:ordered-vector-space-properties},
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(3): For any $x, y \in E$, by \autoref{proposition:ordered-vector-space-properties},
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\begin{align*}
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x^+ + y^+ &= (x \vee 0) + (y \vee 0) = x \vee y \vee (x + y) \vee 0 \\
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&\ge (x + y) \vee 0 = (x + y)^+
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@@ -166,7 +204,7 @@
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|x+y| = (x+y)^+ + (x + y)^- \le x^+ + y^+ + x^- + y^- = |x| + |y|
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\]
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(5): Let $x, y \in E$ with $x, y \ge 0$, then $[0, x] + [0, y] \subset [0, x + y]$. For any $z \in [0, x + y]$, let $u = z \wedge x$ and $v = z - u$, then
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(4): Let $x, y \in E$ with $x, y \ge 0$, then $[0, x] + [0, y] \subset [0, x + y]$. For any $z \in [0, x + y]$, let $u = z \wedge x$ and $v = z - u$, then
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\[
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v = z - z \wedge x = z + (-z \vee -x) = (0 \vee z - x) \le z - x \le y
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\]
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