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This question is inspired by a discussion in chat with wj32. We allow for equality in the definition of increasing and decreasing and call a function monotonic if it is increasing or decreasing. If $f:\mathbb R\to \mathbb R$ is not monotonic, are there three points $x such that $f(y) or $f(y)>f(x),f(z)$? For convenience, call these the $\vee$ and $\wedge$ formations respectively.

2 Answers 2

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It's a purely combinatorial matter. The main task is to reduce the number of cases to be considered as much as possible.

It suffices to consider a surjective function $f:\ \{1,2,3,4\}\to\{1',\ldots,n'\}$ with the property that there exists a pair $x with $f(x) and a pair $u with $f(u)>f(v)$. Here $n\in\{2,3,4\}$.

I shall only deal with the case $n=4$.

If at least one of $2$ and $3$ is mapped onto $1'$ or $4'$ we are done.

If $f(2)=2$ and $f(3)=3$ then $f(1)=4'$, and we have a $\vee$ over $\{1,2,3\}$.

If $f(2)=3'$ and $f(3)=2'$ then $f(1)=1'$, and we have a $\wedge$ over $\{1,2,3\}$.

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If $f$ is not monotonic, it is not decreasing or increasing. Hence there are points $a with $f(a) and points $c with $f(c)>f(d)$.

If $a=c$, use $adb$ to form $\vee$ or $abd$ to form $\wedge$.

If $a=d$, use $cdb$ to form $\vee$.

If $b=c$, use $abd$ to form $\wedge$.

If $b=d$, use $acd$ to form $\wedge$ or $cab$ to form $\vee$.

Now we are left with the case when $a,b,c,d$ are pairwise distinct.

If $a, use $abd$ to form $\wedge$ or $acd$ to form $\wedge$.

If $a, use $abd$ to from $\wedge$ or $acd$ to form $\wedge$.

If $a, use $acd$ to form $\wedge$ or $cdb$ to form $\vee$.

If $c, use $cdb$ to form $\vee$ or $cab$ to form $\vee$.

If $c, use $cdb$ to form $\vee$ or $dab$ to form $\vee$.