2.1 Graphs

1. 1. In$(v;G):= \{x\in V\colon (x,v)\in G\}$, ${\rm indeg}(v;G):= |{\rm In}(v;G)|$,

2. 2. Out$(v;G) := \{x\in V\colon (v,x)\in G\}$, ${\rm outdeg}(v;G):= |{\rm Out}(v;G)|$,

3. 3. deg$(v;G) := {\rm indeg}(v;G) + {\rm outdeg}(v;G)$,

4. 4. In$(G) :=\{v\in V\colon {\rm indeg}(v;G)=0\}$, ${\rm Out}(G):=\{v\in V\colon {\rm outdeg}(v;G) = 0\}$,

5. 5. maxindeg$(G) := \max_{v\in V}{\rm indeg}(v;G)$, ${\rm maxoutdeg}(G):= \max_{v\in V}{\rm outdeg}(v;G)$,

${\rm maxdeg}(G) := \max_{v\in V}\deg(v;G)$,

$\max_{n\in \mathbb N}\ {\rm{maxdeg}}(G_n)< \infty$, $\max_{n\in \mathbb N}\ {\rm{maxindeg}}(G_n)< \infty$, or $\max_{n\in \mathbb N}\ {\rm{maxoutdeg}}(G_n)< \infty$.

2.2 Probability

Proof.

1. a. Follows directly from the definitions.

2. b. See e.g. [3, Section 2.3]

   

The main point of the following proposition is contained in its second item. Informally, it allows us to say the following: if f and g are $\mathbb N$-valued random variables with laws ${\alpha}$ and ${\beta}$, respectively, and $(x,y)\in \mathbb N^2$ is chosen according to the law ${\alpha}\times {\beta}$, then either it is roughly as probable that $x>y$ as it is that $y>x$, or the entropy of $f\sqcup g$ is substantially larger than the average of the entropies of f and g.

1. 1. We have $2H(f\sqcup g) - H(f) - H(g) \ge 0$.

2. 2. We have

   (1) \begin{equation} {\alpha}\times {\beta}\left(\{(x,y)\in \mathbb N^2\colon x> y\}\right) \le \frac{1}{2} + 2\sqrt{2H(f\sqcup g)- H(f)-H(g)}.\end{equation}

Proof. By the previous lemma, we have that the law of $f\sqcup g$ is ${\gamma}:= \frac{{\alpha}+{\beta}}{2}$. As such the first item follows from Jensen’s inequality.

The second item is a simple corollary of Pinsker’s inequality (see e.g. [6, Theorem 2.16] for the statement and proof of Pinsker’s inequality). To derive it, we start by stating the following two special cases of Pinsker’s inequality:

\begin{align*} \|{\alpha}-{\gamma}\|_1^2 \le 2D({\alpha} \|{\gamma})\end{align*}

and

\begin{align*} \|{\beta}-{\gamma}\|_1^2 \le 2D({\beta} \|{\gamma}),\end{align*}

where

\begin{align*} D( {\alpha} \| {\gamma}) := \sum_{i\in \mathbb N} {\alpha}(i)\log\left(\frac{{\alpha}(i)}{{\gamma}(i)}\right),\end{align*}

and similarly for $D({\beta}\|{\gamma})$. By convention, we set $0\log(0) = 0\log(\frac{0}{0}) =0$ in the definitions of $D({\alpha}\|{\gamma})$ and $D({\beta}\|{\gamma})$.

Noting that $\|{\alpha} -{\gamma}\|_1 = \|{\beta} - {\gamma}\|_1$, summing the two inequalities above gives

\begin{align*} 2\|{\beta} -{\gamma}\|^2_1 = 2\|{\alpha}-{\gamma}\|^2_1 \le 2D({\alpha} \|{\gamma}) + 2D({\beta} \|{\gamma}).\end{align*}

A direct computation shows that $D({\alpha} \|{\gamma}) + D({\beta} \|{\gamma}) = 2H({\gamma}) -H({\alpha}) - H({\beta})$, so together with the triangle inequality we deduce that

(2) \begin{equation}\|{\alpha} -{\beta}\|_1 \le 2\sqrt{2H({\gamma}) - H({\alpha})-H({\beta})}.\end{equation}

On the other hand, the left-hand side of (1) is equal to

\begin{align*}\sum_{i,j\in \mathbb N\colon i<j} {\alpha}(i){\beta}(j) &\le \sum_{i,j\in \mathbb N\colon i<j} {\alpha}(i)({\alpha}(j)+ \|{\alpha}-{\beta}\|_1)\\& \le {\alpha}\times {\alpha} \left(\{(x,y)\in \mathbb N^2\colon x>y\}\right)+ \|{\alpha}-{\beta}\|_1\\\le \frac{1}{2} + \|{\alpha}-{\beta}\|_1\end{align*}

which together with (2) finishes the proof.

3.1 Depth functions

Given a graph G and $S\subset V(G)$, we can associate to it a function which ‘measures the maximal distance to $S\cup {\rm Out}(G)$’. More precisely, we define ${\delta}_S\colon V(G) \to \mathbb N$ by setting ${\delta}_S(x)=0$ when $x\in S\cup{\rm Out}(G)$, and for $x\notin S\cup{\rm Out}(G)$ we let ${\delta}_S(x)$ to be the maximal $l\in \mathbb N$ for which there exists a directed simple path $x_0,\ldots, x_l$ with $x_0=x$, $x_l\in S\cup {\rm Out}(G)$, and $x_i\notin S$ when $0\le i<l$. Let us start by abstracting some properties of ${\delta}_S$ into the notion of a depth function as follows.

Example 14. It is straightforward to verify that if $S\subset V(G)$ then ${\delta}_S$ is a

\begin{align*} \left(\frac{|S\setminus {\rm Out}(G)|}{|V(G)|},\,\, {\rm{codepth}}(S;G)+1\right)\end{align*}

-depth function.

Proof. Let $(x_0,x_1,\ldots, x_k)$ be a simple path disjoint from $f^{-1}(0)\setminus {\rm Out}(G)$. We have $f(x_0) \le \rho$ and $f(x_{i+1})< f(x_i)$ for all $i<k$, by 1(a) in Definition 13. The only vertex, in any simple path, which can be in ${\rm Out}(G)$ is the last vertex, so we deduce that $x_{k-1} \notin f^{-1}(0)$, i.e. $f(x_{k-1}) >0$. This shows that $k-1<\rho$, and thus $k\le \rho$. This shows that any simple path disjoint from $f^{-1}(0)\setminus {\rm Out}(G)$ has length at most $\rho$, which proves the lemma.

This lemma allows us to characterise extender graphs as follows.

1. a. If G is an $({\varepsilon},\rho)$-extender, then there are no $({\varepsilon},\rho)$-depth functions for G.

2. b. If there are no $({\varepsilon},\rho+1)$-depth functions for G, then G is an $({\varepsilon},\rho)$-extender.

Proof.

1. a. Let ${\varepsilon}'>0$ and suppose that f is a $({\varepsilon}',\rho)$-depth function for G. By the previous lemma, we have ${\rm{codepth}}(f^{-1}(0)\setminus {\rm Out}(G);G) \le \rho$. Therefore, since we assume that G is an $({\varepsilon},\rho)$-extender, we have $|f^{-1}(0)\setminus {\rm Out}(G)| > {\varepsilon} |V(G)|$. By the definition of being a $({\varepsilon}',\rho)$-depth function, we have $|f^{-1}(0)\setminus {\rm Out}(G)| \le {\varepsilon}' |V(G)|$, which shows ${\varepsilon}'>{\varepsilon}$.

2. b. Let $S\subset V(G)$ be a set with $|S|\le {\varepsilon} |V(G)|$. Then by Example 14, we have that ${\delta}_S$ is a $({\varepsilon}, {\rm{codepth}}(S; G)+1)$-depth function. Since we assume that there are no $({\varepsilon},\rho+1)$-depth functions, we deduce ${\rm{codepth}}(S;G)+1> \rho+1$, and hence ${\rm{codepth}}(S;G) >\rho$. This shows that G is an $({\varepsilon},\rho)$-extender and finishes the proof.

   

It will be useful to restate the above corollary for the case of graph sequences.

1. a. The sequence $(G_n)$ is a $(\rho_n)$-extender sequence

2. b. There exists $C>0$, ${\varepsilon}>0$ such that for all $n\in\mathbb N$ we have that $G_n$ does not admit a $({\varepsilon},C\cdot \rho_{|V(G_n)|})$-depth function.

One of the steps in the proof of Theorem 5, Proposition 22, requires bounding the number of depth functions on a graph. We finish this subsection with a lemma which is used to count depth functions in the proof of Proposition 22. First, we need the following definition.

In other words, ${\delta}'_D$ is the ‘standard’ depth function for the graph (V(G),D). While it is not true that for every $D\subset E(G)$, we have that ${\delta}'_D$ is a depth function for the graph G, the following lemma shows in particular that for every depth function f we can find D such that $f={\delta}'_D$.

Proof. By Condition 1b) of Definition 13, there exists a function $n\colon V(G)\setminus f^{-1}(0) \to V(G)$ such that for every $v\in V(G)\setminus f^{-1}(0)$ we have $f(n(v)) = f(v)-1$. We let $D:=\{(v,n(v))\colon v\in V(G)\setminus f^{-1}(0)\}$. It is straightforward to check that D has the desired properties.

3.2 Definition and basic properties of the random graphs $\mathbf G_n^d$

In this article, a random graph is a pair $(V, \mathbf E)$ where V is a non-empty finite set and $\mathbf E$ is a random variable with values in ${\rm Pow}(V\times V)$ such that $\mathbf E$ is disjoint from the diagonal in $V\times V$ almost surely.

For $n\in \mathbb N$ let $\mathbb Z_n:= \mathbb Z/n\mathbb Z$. For $a,b\in \mathbb Z_n$, we write $a>b$ if $a = \overline a + n\mathbb Z$, $b = \overline b + n\mathbb Z$, where $\overline a, \overline b\in \{0,1,\ldots, n-1\}$ and $\overline a >\overline b$. We also let $R(n):=\lfloor\log(n)\rfloor$.

We start by defining a random variable $J_n$ with values in $\mathbb Z_n\times \mathbb Z_n$, as follows. We first choose $v\in \mathbb Z_n$ uniformly at random, then we choose $r\in R(n)$ uniformly at random, and we choose (x,y) uniformly at random in

\begin{align*}\{v,v+1,\ldots, v+2^r-1\} \times \{v+2^r, v+2^r+1,\ldots, v+2^{r+1}-1\}\subset \mathbb Z_n\times \mathbb Z_n.\end{align*}

The law of $J_n$ will be denoted with $\iota_n$.

Now for $d, n\in \mathbb N$, we define a random graph $\mathbf G_n^d$ as follows: we let $V(\mathbf G_n^d) := \mathbb Z_n$, and the random variable $\mathbf E_n^d$ with values in ${\rm Pow}(\mathbb Z_n\times \mathbb Z_n)$ is defined by choosing dn elements of $\mathbb Z_n\times \mathbb Z_n$ independently at random according to the law $\iota_n$. This finishes the definition of $\mathbf G_n^d$.

Let us note that $\mathbf G_n^d$ is typically neither a dag nor of bounded degree, but the following lemma implies that with high probability $\mathbf G_n^d$ becomes a bounded degree dag after removing a small amount of vertices.

(3) \begin{equation}{\mathbb P}_{\mathbf E} (|\{v\in \mathbb Z_n \colon \deg(v; (\mathbb Z_n,\mathbf E)) \ge 2{\Delta} \}| \ge {\varepsilon} \cdot n ) \le \frac{2d^{\Delta}}{{\Delta}!\cdot {\varepsilon}}\end{equation}

and

(4) \begin{equation} {\mathbb P}_{\mathbf E}( |\{(x,y)\in \mathbf E \colon x>y \}| \ge {\varepsilon}\cdot d n) \le \frac{2d}{{\varepsilon}\cdot R(n)}\end{equation}

Proof. Note that we have the following $(\mathbb Z_n\times \mathbb Z_n)$-valued random variable $J'_n$ whose law is the same as the law of $J_n$, that is, it is equal to $\iota_n$. We choose $(v,r)\in \mathbb Z_n \times R(n)$ uniformly at random, then we choose $(a,b)\in 2^r\times 2^r$ uniformly at random and we choose the edge $(v,v+2^r+b-a)$.

Therefore, if we fix $v\in \mathbb Z_n$, then

\begin{align*} {\mathbb P}_{\mathbf E}({\rm outdeg}(v; (\mathbb Z_n, \mathbf E))\ge {\Delta}) \le {nd \choose {\Delta}} \frac{1}{n^{\Delta}} \le \frac{d^{\Delta}}{{\Delta}!},\end{align*}

where the last inequality is obtained by writing

\begin{align*}{nd \choose {\Delta}} \frac{1}{n^{\Delta}} = \frac{nd\cdot\ldots\cdot (nd-{\Delta}+1)}{{\Delta}!} \frac{1}{n^{\Delta}} \le\frac{(nd)^{\Delta}}{{\Delta}!} \frac{1}{n^{\Delta}} = \frac{d^{\Delta}}{{\Delta}!}.\end{align*}

Similarly, for a fixed $v\in \mathbb Z_n$, we have

\begin{align*} {\mathbb P}_{\mathbf E}({\rm indeg}(v; (\mathbb Z_n, \mathbf E))\ge {\Delta}) \le \frac{d^{\Delta}}{{\Delta}!},\end{align*}

and hence

\begin{align*} {\mathbb P}_{\mathbf E}(\deg(v; (\mathbb Z_n, \mathbf E))\ge 2{\Delta}) \le \frac{2d^{\Delta}}{{\Delta}!}.\end{align*}

Now by linearity of expectation, we have

\begin{align*}{{\mathbb E}}_{\mathbf E} (|\{v\in \mathbb Z_n \colon \deg(v; (\mathbb Z_n,\mathbf E))\ge 2{\Delta} \}|) = \sum_{v\in \mathbb Z_n} {\mathbb P}_{\mathbf E}(\deg(v; (\mathbb Z_n, \mathbf E))\ge 2{\Delta}),\end{align*}

and the right-hand side is bounded from above by $\frac{2nd^{\Delta}}{{\Delta}!}$. Thus, by Markov’s inequality we have

\begin{align*}{\mathbb P}_{\mathbf E} (|\{v\in \mathbb Z_n \colon \deg(v; (\mathbb Z_n,\mathbf E))\ge 2{\Delta} \}| \ge {\varepsilon} \cdot n ) <\frac{2nd^{\Delta}}{{\Delta}! {\varepsilon} n} = \frac{2d^{\Delta}}{{\Delta}!{\varepsilon}},\end{align*}

which finishes the proof of (3).

In order to prove (4), we start by bounding $\iota_n(\{(x,y)\in {\mathbb Z}_n\times {\mathbb Z}_n\colon x>y\})$ from above. By the definition of $J_n'$, the only way in which $J_n'$ might take a value (x,y) with $x>y$ is when we start by choosing $(v,r)\in \mathbb Z_n \times R(n)$ such that $v>n-2^{r+1}$. As such we have

\begin{align*} \iota_n(\{(x,y)\in {\mathbb Z}_n\times {\mathbb Z}_n\colon x>y\}) \le \frac{1}{R(n)}\sum_{r < R(n)} \frac{1}{n}|\{a\in \mathbb Z_n\colon a>n-2^{r+1}\}|,\end{align*}

which is bounded from above by

\begin{align*}\frac{1}{nR(n)} \sum_{r<R(n)} 2^{r+1} < \frac{1}{nR(n)} 2^{R(n)+1} \le \frac{2n}{nR(n)} = \frac{2}{R(n)}\end{align*}

Therefore, we have

\begin{align*}{{\mathbb E}}_{\mathbf E}( |\{(a,b)\in \mathbf E \colon a>b \}|) < \frac{2nd}{R(n)}\end{align*}

and Markov’s inequality again gives us the desired bound.

3.3 Construction of an $n^{\delta}$-extender sequence from $\mathbf G_n^d$

The key lemma which we need is the following.

Lemma 21. Let $d,n\in \mathbb N$, let ${\varepsilon}>0$, let $k:=\lfloor n^{{\varepsilon}^3}\rfloor$, and let $l\colon {\mathbb Z}_n \to k$. We have

(5) \begin{equation}\iota_n(\{(a,b)\in \mathbb Z_n\times \mathbb Z_n\colon l(a)>l(b)\}) < \frac{1}{2} + 4{\varepsilon}\end{equation}

Let us discuss the intuition behind the proof of Lemma 21. First, let us discuss the meaning of the left-hand side of (5). We first choose $(v,r)\in \mathbb Z_n\times R(n)$ uniformly at random, then we look at the distribution of l(v), $l(v+1)$, …, $l(v+2^r-1)$ on the one side and the distribution of $l(v+2^r)$, $l(v+2^r+1)$, …, $l(v+2^{r+1}-1)$ on the other side. We sample an element of $\{0,\ldots, k-1\}$ from the first distribution and an element of $\{0,\ldots, k-1\}$ from the second distribution. Then the left-hand side of (5) is the probability that the first element is larger than the second element.

If the distribution of l(v), $l(v+1)$, …, $l(v+2^r-1)$ is very close to the distribution of $l(v+2^r)$, $l(v+2^r+1)$, …, $l(v+2^{r+1}-1)$, then for a random edge between the two vertex sets, l increases or decreases with approximately the same probability. But if the two distributions are not very close, then the entropy of the distribution of the union l(v), $l(v+1)$, …, $l(v+2^{r+1}-1)$ is larger than the average of the two entropies (this statement is formalised by Proposition 12).

As the entropy of the distribution of $l(v),\ldots, l(v+2^{R(n)})$ is bounded from above by $\log(k)$ (by Lemma 11(b)), it should be clear that when we choose k sufficiently small, then for a fixed $v\in \mathbb Z_n$ there will be only a small amount of r’s for which the distribution of l(v), $l(v+1)$, …, $l(v+2^r-1)$ and $l(v+2^r)$, $l(v+2^r+1)$, …, $l(2^{r+1}-1)$ is very different.

Proof of Lemma 21. For $v\in \mathbb Z_n$, $r<R(n)$, let $X_{v,r}$ denote the restriction of l to $[v,v+2^r-1]\subset {\mathbb Z}_n$, and let $Y_{v,r}$ denote the restriction of l to $[v+2^r,v+2^{r+1}-1]$. We consider $X_{v,r}$ and $Y_{v,r}$ as k-valued random variables.

Note that $X_{v,r+1} = X_{v,r} \sqcup Y_{v,r}$. As such, by the first item of Proposition 12, for all v,r we have

\begin{align*}2 \cdot H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r}) \ge 0.\end{align*}

On the other hand, we have ${{\mathbb E}}_{v,r} (H(X_{v,r})) = {{\mathbb E}}_{v,r} ( H(Y_{v,r}))$, where (v,r) is chosen uniformly at random from $\mathbb Z_n\times R(n)$. Hence,

\begin{align*}{{\mathbb E}}_{v,r} (2 \cdot H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r})) = 2{{\mathbb E}}_{v,r}(H(X_{v,r+1})) - 2{{\mathbb E}}_{v,r}(H(X_{v,r})),\end{align*}

and so

\begin{align*}{{\mathbb E}}_{v,r} (2 \cdot H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r}))&= \frac{2}{R(n)} {{\mathbb E}}_v(\sum_{r<R(n)} H(X_{v,r+1}) - H(X_{v,r}))\\&= \frac{2}{R(n)} {{\mathbb E}}_v ( H(X_{v,R(n)})-H(X_{v,0}))\\&\le \frac{2\log(k)}{R(n)}.\end{align*}

Now Markov’s inequality shows that

\begin{align*}{\mathbb P}_{v,r} (2 \cdot H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r}) \ge {\varepsilon}^2) \le \frac{2\log(k)}{{\varepsilon}^2 \cdot R(n)} \le 2{\varepsilon}.\end{align*}

By the second item of Proposition 12, if for some $r,v,{\varepsilon}$ we have $H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r}) < {\varepsilon}^2$, then ${\mathbb P}_{x,y}(X_{v,r}(x) > Y_{v,r}(y)) \le \frac{1}{2} +2{\varepsilon}$. Thus by the definition of $\iota_n$, we have

\begin{align*}\iota_n(\{(a,b)&\in \mathbb Z_n\times \mathbb Z_n\colon l(a)>l(b)\}) <\\& < \frac{1}{2} + 2{\varepsilon} + {\mathbb P}_{v,r} (2 \cdot H(X_{v,r+1}) - H(X_{v,r}) -H(Y_{v,r}) \ge {\varepsilon}^2)\\&\le \frac{1}{2}+4{\varepsilon},\end{align*}

which finishes the proof.

Proposition 22. Let $d,n\in \mathbb N$, $d\ge 3$, let $\mathbf E:= \mathbf E_n^d$, let ${\varepsilon}\in(0,1)$, and let $k:=\lfloor n^{{\varepsilon}^3}\rfloor$,

(6) \begin{equation} {\mathbb P}_\mathbf E(\text{$(\mathbb Z_n,\mathbf E)$ admits a $({\varepsilon},k)$-depth function}) < 2^{H(\frac{1}{d})dn} (\frac{1}{2} + 4{\varepsilon})^{(d-1)n},\end{equation}

where for $x\in (0,1)$ we set $H(x) = -x\log(x) - (1-x)\log(1-x)$.

Proof. Clearly it is enough to show that

(7) \begin{equation} {{\mathbb E}}_\mathbf E(\text{number of $({\varepsilon},k)$-depth functions for $(\mathbb Z_n,\mathbf E)$}) < 2^{H\left(\frac{1}{d}\right)dn} \left(\frac{1}{2} + 4{\varepsilon}\right)^{(d-1)n}.\end{equation}

By Lemma 19, the left-hand side of (7) is bounded above by

(8) \begin{align} {{\mathbb E}}_\mathbf E\Big(\big| &\big\{D\subset \mathbf E\colon\end{align}

\begin{align}&\text{ $|D|\le n$ and ${\delta}'_D$ is an $({\varepsilon},k)$-depth function for $(\mathbb Z_n,\mathbf E)$}\big\}\big|\Big).\nonumber\end{align}

Given $I\subset dn$, let ${\rm Set}_I\colon (\mathbb Z_n\times \mathbb Z_n)^{dn} \to {\rm Pow}(\mathbb Z_n\times \mathbb Z_n)$ be defined by

\begin{align*} {\rm Set}_I(x_0,\ldots, x_{dn-1}) := \{x_i\colon i\in I\},\end{align*}

and let ${\rm Set}:= {\rm Set}_{dn}$. Furthermore, if G is a graph and $D\subset E(G)$ is such that ${\delta}'_D$ is a $({\varepsilon},k)$-depth function, then let us say that D is an $({\varepsilon},k)$-depth set for G.

Recall that the law of $\mathbf E$ is the push-forward of $\iota^{dn}_n$ through the map Set. As such, we deduce that (8) is bounded above by:

(9) \begin{align} \sum_{I\subset dn\colon |I|\le n} \iota_n^{dn}\Big(&\big\{(e_i)_{i\in dn} \in (\mathbb Z_n\times \mathbb Z_n)^{dn}\colon\end{align}

\begin{align}&\text{${\rm Set}_I((e_i)_{i\in dn})$ is a $({\varepsilon},k)$-depth set for $(\mathbb Z_n, {\rm Set}((e_i)_{i\in dn})$}\big\}\Big)\nonumber \end{align}

Let us first estimate the number of summands in (9). Recall that for $0<{\alpha}\le\frac{1}{2}$ and $m\in \mathbb N$ we have $\sum_{i\le {\alpha} m} {m \choose i} \le 2^{H({\alpha}) m}$ (see e.g. [3, Theorem 3.1]). Since ${\varepsilon}<1$ and $d\ge 3$, we see that the number of summands in (9) is therefore at most $2^{H(\frac{1}{d})dn}$.

To estimate each summand, let us fix $I\subset dn$, and let us fix $(e_i)_{i\in I}\in (\mathbb Z_n\times \mathbb Z_n)^I$. Let $D:= \{e_i\colon i \in I\}$ and let l be the depth function ${\delta}'_D$ on the graph $(\mathbb Z_n,D)$. The probability that l will still be a depth function after we add $nd-|I|$ remaining edges is, by Lemma 21, at most

\begin{align*}\left(\frac{1}{2} + 4{\varepsilon}\right)^{dn-|I|} \le \left(\frac{1}{2} + 4{\varepsilon}\right)^{(d-1)n}.\end{align*}

As such, we have that (9) is bounded above by

\begin{align*}2^{H(\frac{1}{d})dn} \left(\frac{1}{2} + 4{\varepsilon}\right)^{(d-1)n},\end{align*}

and hence (7) and (6) hold true. This finishes the proof.

We are now ready to prove Theorem 5. Clearly, it follows from the following theorem.

Proof. Let ${\delta}>0$ be such that $p:= \frac{1}{2} + 4({\varepsilon} +2{\delta}) <1$. Let d be such that

(10) \begin{equation}2^{H\left(\frac{1}{d}\right)} \cdot \left(\frac{1}{2} + 4({\varepsilon}+2{\delta})\right)^{\frac{d-1}{d}} < 1.\end{equation}

It is possible to choose such d since $H(x)\to 0$ as $x\to 0$. Let ${\Delta}\in \mathbb N$ be such that $\frac{2d^{\Delta}}{{\Delta}!\cdot {\delta}}<{\delta}$, and let $n_0$ be such that for $n>n_0$ we have $\frac{2d^2}{{\delta} R(n)} <{\delta}$ and

\begin{align*} 2^{H\left(\frac{1}{d}\right)dn} \left(\frac{1}{2} + 4({\varepsilon}+2{\delta})\right)^{(d-1)n}<1-2{\delta},\end{align*}

which is possible by (10).

Therefore, by Proposition 22, we have for $n>n_0$ that

\begin{align*} {\mathbb P}_\mathbf E(\text{$(\mathbb Z_n,\mathbf E)$ admits a $({\varepsilon}+2{\delta},n^{({\varepsilon}+2{\delta})^3})$-depth function}) < 1-2{\delta}.\end{align*}

Furthermore, by Lemma 20, we have

\begin{align*} {\mathbb P}_{\mathbf E} (|\{v\in \mathbb Z_n \colon \deg(v; (\mathbb Z_n,\mathbf E))\ge 2{\Delta} \}| \ge {\delta} \cdot n ) \le \frac{2d^{\Delta}}{{\Delta}!\cdot {\delta}}<{\delta}\end{align*}

and

\begin{align*} {\mathbb P}_{\mathbf E}( |\{(a,b)\in \mathbf E \colon a>b \}| \ge\frac{{\delta}}d\cdot dn={\delta} n) \le \frac{2d}{\frac{{\delta}}{d} R(n)}<{\delta}.\end{align*}

As such, by the union bound, we get for each $n>n_0$ a graph $G_n$ with $V(G_n)=\mathbb Z_n$ such that $G_n$ does not admit a $({\varepsilon}+2{\delta},n^{({\varepsilon}+2{\delta})^3})$-depth function, and furthermore

\begin{align*} |\{v\in \mathbb Z_n \colon \deg(v; G_n)\ge 2{\Delta} \}| \le {\delta} \cdot n\end{align*}

and

\begin{align*} |\{(a,b)\in E(G_n) \colon a>b \}| \le{\delta}\cdot n.\end{align*}

Let $B\subset \mathbb Z_n$ be the union of

\begin{align*} \{v\in \mathbb Z_n\colon \deg(v;G_n)\ge 2{\Delta}\}\end{align*}

and

\begin{align*} \{a\in \mathbb Z_n\colon \exists b\in \mathbb Z_n \text{ such that } (a,b)\in E(G_n) \text{ and } a>b\}.\end{align*}

We let $H_n$ be the subgraph of $G_n$ induced by the set of vertices $\mathbb Z_n\setminus B$. Clearly, $H_n$ is a sequence of bounded degree dags, and since $|B|\le 2{\delta} n$, we see that $H_n$ does not admit a $({\varepsilon},n^{({\varepsilon}+2{\delta})^3})$-depth function, and hence it also does not admit a $({\varepsilon},n^{{\varepsilon}^3})$-depth function. By Corollary 17, this finishes the proof.