Proof. We partition X into subpaths $X^{\prime }_1,\dots ,X^{\prime }_{s},X^{\prime }_{s+1}$ such that, for each $1 \leq i \leq s$ , $X^{\prime }_i$ touches at least $\frac {m}{10k^2}$ and at most $\frac {m}{5k^2}$ chords and such that $X^{\prime }_{s+1}$ touches less than $\frac {m}{10k^2}$ chords. We do this as follows: Take $X^{\prime }_1$ to be the minimum initial segment of X which touches at least $\frac {m}{10k^2}$ chords. By minimality, the segment obtained by removing the last vertex x of $X^{\prime }_1$ touches less than $\frac {m}{10k^2}$ chords. Also, x itself touches at most $\frac {m}{10k^2}$ chords by the assumption of the lemma. So overall, $X^{\prime }_1$ touches at most $\frac {m}{5k^2}$ chords. We now remove $X^{\prime }_1$ and continue in this fashion. As long as the remaining subpath touches at least $\frac {m}{10k^2}$ chords, we can extract an initial segment of it which touches at least $\frac {m}{10k^2}$ and at most $\frac {m}{5k^2}$ chords. In the end, we are left with a, possibly empty, subpath touching less than $\frac {m}{10k^2}$ chords, and we take this subpath to be $X^{\prime }_{s+1}$ .

In the same way, partition Y into subpaths $Y^{\prime }_1,\dots ,Y^{\prime }_t,Y^{\prime }_{t+1}$ with each $Y^{\prime }_i$ , $1 \leq i \leq t$ , touching at least $\frac {m}{10k^2}$ and at most $\frac {m}{5k^2}$ chords and with $Y^{\prime }_{t+1}$ touching less than $\frac {m}{10k^2}$ chords. Clearly, $4k^2 \leq (m - \frac {m}{10k^2})/\frac {m}{5k^2} \leq s,t \leq 10k^2$ . Define an auxiliary bipartite graph G with sides $[s]$ and $[t+1]$ , in which $(i,j)$ is an edge if $e(X^{\prime }_i,Y^{\prime }_j) \geq \frac {m}{400k^4}$ . Let $I \subseteq [s]$ . We claim that $|N_G(I)| \geq |I|/4$ . To see this, note that

$$ \begin{align*} |I| \cdot \frac{m}{10k^2} &\leq \sum_{i \in I}{e(X^{\prime}_i,Y)} \leq \sum_{j \in N_G(I)}{e(X,Y^{\prime}_j)} + (t+1) \cdot |I| \cdot \frac{m}{400k^4} \\ &\leq |N_G(I)| \cdot \frac{m}{5k^2} + 2t \cdot |I| \cdot \frac{m}{400k^4} \leq |N_G(I)| \cdot \frac{m}{5k^2} + |I| \cdot \frac{m}{20k^2}. \end{align*} $$

Rearranging gives $|N_G(I)| \geq |I|/4$ . Now, by a well-known generalization of Hall’s theorem, there is a matching in G which saturates at least $s/4 \geq k^2$ of the elements of $[s]$ . By Lemma 3.1, such a matching contains either a parallel or an interlacing family of chords of size k. It is easy to see that such a family gives sets $X_1,\dots ,X_k,Y_1,\dots ,Y_k$ as in the statement of the lemma.

Proof. We will produce a partition $X_1,\ldots ,X_{t'}$ of X and a partition $Y_1,\ldots , Y_{t'}$ of Y such that $\sum _{i=1}^{t'} {e(X_i,Y_i)} \geq m/12,$ and each pair $X_i,Y_i$ satisfies the condition of one of the items 1 or 2. Evidently, for one of the items, the pairs satisfying it would contribute at least half of all chords. Keeping only the pairs satisfying this item, we will obtain the desired collection.

We now construct such partitions $X_1,\ldots ,X_{t'}$ and $Y_1,\ldots , Y_{t'}$ through the following process. We start with the trivial partition $\{X\}$ of X and $\{Y\}$ of Y. Note that we may assume that $m\ge 16$ or the trivial partition already satisfies the condition of item 1. Suppose that, at a given step of the process, there is a pair of sets $X_i,Y_i$ which violates the conditions of both items 1 and 2. Partition $X_i$ into two subsections $X',X"$ with $X'$ above $X"$ , such that $X'$ and $X"$ each touch at least $\left ( \frac {1}{2} - \frac {1}{6\log m} \right )e(X_i,Y_i)$ and at most $\left ( \frac {1}{2} + \frac {1}{6\log m} \right )e(X_i,Y_i)$ of the chords between $X_i$ and $Y_i$ . This is possible since every vertex of $X_i$ is incident to less than $\frac {e(X_i,Y_i)}{6\log m}$ of these chords (by the assumption that item 1 fails). Let x be the lowest vertex of $X'$ which is incident to a chord, and let y be the lowest vertex of $Y_i$ which is adjacent to x. Partition Y into subsections $Y',Y"$ such that $Y'$ is above $Y"$ and y is the lowest vertex of $Y'$ . Observe that if a chord $e \in E(X',Y") \cup E(X",Y')$ does not contain y, then e interlaces $(x,y)$ . So the number of such chords is less than $\frac {e(X_i,Y_i)}{6\log m}$ . Also, $e(X_i,y) < \frac {e(X_i,Y_i)}{6\log m}$ . (Here, we used the assumption that $X_i,Y_i$ violates both items 1 and 2). We conclude that $e(X',Y") + e(X",Y') < \frac {e(X_i,Y_i)}{3\log m}$ . It follows that $e(X',Y') = e(X',Y_i) - e(X',Y") \geq \left ( \frac {1}{2} - \frac {1}{2\log m} \right )e(X_i,Y_i)$ , and similarly $e(X",Y") \geq \left ( \frac {1}{2} - \frac {1}{2\log m} \right )e(X_i,Y_i)$ . Note that we also have the upper bound $e(X',Y'),e(X",Y") \leq \left ( \frac {1}{2} + \frac {1}{6\log m} \right )e(X_i,Y_i)$ . We now define new partitions by replacing $X_i$ with $X',X"$ and $Y_i$ with $Y',Y"$ . This way, we may continue the process until every pair $X_i,Y_i$ satisfies the condition of one of the items 1 or 2. Indeed, at each step, we replace some pair $X_i,Y_i$ with pairs having fewer edges than $X_i,Y_i$ . If the number of edges of some pair is at most $6$ , then this pair trivially satisfies item 1. Hence, the process must terminate.

To each pair $(X_i,Y_i)$ appearing in the course of the process, we assign a binary string as follows. Assign the initial pair $(X,Y)$ the empty string. If $(X',Y'),(X",Y")$ are obtained by splitting $(X_i,Y_i)$ as above and $(X_i,Y_i)$ is assigned the string $\sigma $ , then let $(X',Y')$ be assigned the string $\sigma ,0$ and $(X",Y")$ the string $\sigma ,1$ . Let $h(X_i,Y_i)$ be the length of the string assigned to a pair $X_i,Y_i$ . It is easy to show, by induction, that

(4.1) $$ \begin{align} \sum\left( \frac{1}{2} \right)^{h(X_i,Y_i)} = 1 \end{align} $$

is preserved throughout the process, where the sum ranges over all pairs $X_i,Y_i$ at a given moment. Moreover, by our upper and lower bounds on $e(X',Y'),e(X",Y")$ , we get by induction that

$$ \begin{align*}0<m \cdot \left( \frac{1}{2} - \frac{1}{2\log m} \right)^{h(X_i,Y_i)} \leq e(X_i,Y_i) \leq m \cdot \left( \frac{1}{2} + \frac{1}{6\log m} \right)^{h(X_i,Y_i)} \end{align*} $$

for every pair $(X_i,Y_i)$ appearing in the process. In particular, $h(X_i,Y_i) \le 2\log m$ for each such pair $(X_i,Y_i)$ . Hence,

$$ \begin{align*}e(X_i,Y_i) \geq m \cdot \left( \frac{1}{2} - \frac{1}{2\log m} \right)^{h(X_i,Y_i)} \geq m \cdot \left( 1 - \frac{1}{\log m} \right)^{2\log m} \left( \frac{1}{2} \right)^{h(X_i,Y_i)} \geq \frac{m}{12} \cdot \left( \frac{1}{2} \right)^{h(X_i,Y_i)}.\end{align*} $$

Consider the partitions $X_1,\dots ,X_{t'}$ and $Y_1,\dots ,Y_{t'}$ at the end of the process. By equation (4.1) and the above, we have $\sum _{i=1}^{t'}{e(X_i,Y_i)} \ge m/12$ . This completes the proof of the lemma.

Proof. We execute the following process. To start, set $E_1 = E(X,Y)$ . For each $i \geq 1$ , we do as follows. If every two chords in $E_i$ are interlacing, then stop. Otherwise, among all pairs of chords in $E_i$ which are parallel or share a vertex, choose one pair $e_i,e^{\prime }_i \in E_i$ , $e_i = (x_i,y_i)$ , $e^{\prime }_i = (x^{\prime }_i,y^{\prime }_i)$ , which maximizes $d_X(x_i,x^{\prime }_i)$ . Without loss of generality, let us assume that $x_i$ is above $x^{\prime }_i$ (note that $x_i,x^{\prime }_i$ are distinct by our assumption that every vertex in X is incident to at most one chord; $y_i,y^{\prime }_i$ may be equal). Since $e_i,e^{\prime }_i$ are parallel or share a vertex, it holds that either $y_i = y^{\prime }_i$ or $y_i$ is above $y^{\prime }_i$ . Let $X^*$ be the set of vertices of X between $x_i$ and $x^{\prime }_i$ (including $x_i,x^{\prime }_i$ ), and let $Y^*$ be the set of vertices of Y between $y_i$ and $y^{\prime }_i$ (including $y_i,y^{\prime }_i$ ). Observe that if $e = (x,y) \in E_i$ is a chord with $y \in Y^*$ , then x must be in $X^*$ . Indeed, if x is above $x_i$ , then $e,e^{\prime }_i$ are parallel or share a vertex and $d_X(x,x^{\prime }_i)> d_X(x_i,x^{\prime }_i)$ ; similarly, if x is below $x^{\prime }_i$ , then $e,e_i$ are parallel or share a vertex and $d_X(x,x_i)> d_X(x_i,x^{\prime }_i)$ . In both cases, we get a contradiction to the maximality of $e_i,e^{\prime }_i$ .

Let F be the set of chords $(x,y) \in E_i$ with $x \in X^*$ . Clearly, $|F| \geq 2$ because $e_i,e^{\prime }_i \in F$ . Set $E_{i+1} := E_i \setminus F$ . Note that $d_X(x_i,x^{\prime }_i) = |X^*| - 1 \geq |F| - 1 \geq |F|/2 = (|E_i| - |E_{i+1}|)/2$ , where the first inequality holds because every vertex of $X^*$ is incident to at most one chord. Above we have shown that F contains all chords $(x,y)$ with $y \in Y^*$ . It is now easy to see that each $e = (x,y) \in E_{i+1}$ interlaces both $e_i$ and $e^{\prime }_i$ . Indeed, let $e = (x,y) \in E_{i+1}$ . Then x is either above $x_i$ or below $x^{\prime }_i$ , and y is either above $y_i$ or below $y^{\prime }_i$ . If x is above $x_i$ and y is above $y_i$ , then $e,e^{\prime }_i$ are parallel with $d_X(x,x_i)> d(x_i,x^{\prime }_i)$ , contradicting the maximality of $e_i,e^{\prime }_i$ . Similarly, it is impossible that x is below $x^{\prime }_i$ and y is below $y^{\prime }_i$ . In the remaining two cases, e interlaces $e_i,e^{\prime }_i$ . This ensures that item 2 will be satisfied.

Suppose that the process continues for t steps. Then in $E_{t+1}$ , every two chords are interlacing. So if $|E_{t+1}| \geq m/2$ , then we are done. Suppose then that $|E_{t+1}| < m/2$ . Consider the pairs of chords $e_i = (x_i,y_i),e^{\prime }_i = (x^{\prime }_i,y^{\prime }_i)$ , $1 \leq i \leq t$ . We have already shown that items 1 and 2 hold. For item 3, we have

$$ \begin{align*}\sum_{i = 1}^t {d_X(x_i,x^{\prime}_i)} \geq \frac{1}{2}\sum_{i = 1}^t (|E_i| - |E_{i+1}|) = \frac{1}{2}(|E_1| - |E_{t+1}|) \geq m/4, \end{align*} $$

as required.

Proof. Let $(x_1,y_1),\dots ,(x_{3t},y_{3t}) \in E(X,Y)$ be the given family of interlacing chords, with $x_i$ above $x_j$ and $y_i$ below $y_j$ for each $1 \leq i < j \leq 3t$ . For $1 \leq i \leq 3t-1$ , put $d_i := d_Y(y_i,y_{i+1}) - d_X(x_i,x_{i+1})$ . Note that $d_i$ is precisely the difference between the lengths of $(x_i,y_i)$ and $(x_{i+1},y_{i+1})$ , so by our assumption, we have $|d_i|\le D-1.$ We prove the lemma by induction on t. In the base case $t=1$ , the desired path $P_1$ can be chosen as the trivial path of the chord $(x_1,y_1)$ .

For the induction step, we will first find two paths $Q_1,Q_2$ between $x_1$ and $x_3$ such that $1 \leq |Q_2| - |Q_1| \leq 2D$ and such that $Q_1,Q_2$ do not use any vertices of X below $x_3$ or any vertices of Y above $y_3$ . To find such $Q_1,Q_2$ , we proceed as follows. For $i = 1,2$ , put $a_i := d_X(x_i,x_{i+1})$ and $b_i := d_Y(y_i,y_{i+1})$ so that $d_i = b_i - a_i$ . Consider the following four paths between $x_1$ and $x_3$ .

• • $P^{\prime }_1 = X[x_1,x_3]$ , depicted in blue in Figure 4;

• • $P^{\prime }_2 = X[x_1,x_2],(x_2,y_2),Y[y_2,y_3],(y_3,x_3)$ , depicted in red in Figure 4;

• • $P^{\prime }_3 = (x_1,y_1),Y[y_1,y_2],(y_2,x_2),X[x_2,x_3]$ , depicted in green in Figure 4;

• • $P^{\prime }_4 = (x_1,y_1),Y[y_1,y_3],(y_3,x_3)$ , depicted in yellow in Figure 4.

Observe that $P^{\prime }_1,\dots ,P^{\prime }_4$ do not use any vertices of X below $x_3$ or any vertices of Y above $y_3$ . We have $|P^{\prime }_1| = a_1 + a_2$ , $|P^{\prime }_2| = a_1 + b_2 + 2$ , $|P^{\prime }_3| = a_2 + b_1 + 2$ , $|P^{\prime }_4| = b_1 + b_2 + 2$ . Hence, $|P^{\prime }_2| - |P^{\prime }_1| = d_2 + 2$ , $|P^{\prime }_3| - |P^{\prime }_1| = d_1 + 2$ , $|P^{\prime }_4| - |P^{\prime }_1| = d_1 + d_2 + 2$ , $|P^{\prime }_3| - |P^{\prime }_2| = d_1 - d_2$ , $|P^{\prime }_4| - |P^{\prime }_2| = d_1$ and $|P^{\prime }_4| - |P^{\prime }_3| = d_2$ . So we see that, for all $Q_1,Q_2 \in \{P^{\prime }_1,\dots ,P^{\prime }_4\}$ , it holds that $||Q_2| - |Q_1|| \leq |d_1| + |d_2| + 2 \leq 2D$ .

Observe that the four numbers $a_1 + a_2, a_1 + b_2 + 2, a_2 + b_1 + 2, b_1 + b_2 + 2$ cannot all be equal. Indeed, if the first three are equal, then $b_1 = a_1 - 2$ and $b_2 = a_2 - 2$ , which means that $b_1 + b_2 + 2 = a_1 + a_2 - 2 \neq a_1 + a_2$ . It follows that there are $Q_1,Q_2 \in \{P^{\prime }_1,\dots ,P^{\prime }_4\}$ with $|Q_1| \neq |Q_2|$ , say $|Q_1| < |Q_2|$ . We have already shown that $|Q_2| - |Q_1| \leq 2D$ . So $Q_1,Q_2$ satisfy all of our requirements.

We now complete the induction step using the paths $Q_1,Q_2$ found above. Let $t \geq 2$ , and apply the induction hypothesis with parameter $t - 1$ and with X and Y replaced by $X[x_4,x^{\text {b}}]$ and $Y[y^{\text {t}},y_4]$ , which still contain $3(t-1)$ of our interlacing chords. This way we obtain paths $R_1,\dots ,R_{t-1}$ between $x_4$ and $y^{\text {t}}$ such that $1 \leq |R_{i+1}| - |R_i| \leq 2D$ for every $1 \leq i \leq t - 2$ . For $1 \leq i \leq t-1$ , let $P_i$ be the concatenation of $X[x^{\text {t}},x_1]$ , $Q_1$ , $X[x_3,x_4]$ and $R_i$ . Let $P_{t}$ be the concatenation of $X[x^{\text {t}},x_1]$ , $Q_2$ , $X[x_3,x_4]$ and $R_{t-1}$ . See Figure 5 for an illustration of the resulting paths $P_i$ . For each $1 \leq i \leq t-2$ , we have $|P_{i+1}| - |P_i| = |R_{i+1}| - |R_i|$ , and hence $1 \leq |P_{i+1}| - |P_i| \leq 2D$ . Lastly, $|P_{t}| - |P_{t - 1}| = |Q_2| - |Q_1|$ , and hence $1 \leq |P_{t}| - |P_{t - 1}| \leq 2D$ as well. This completes the proof.

Proof. Without loss of generality, assume that $X_i$ is above $X_j$ for all $i<j$ (and consequently, the opposite is true for the $Y_i$ ’s). The proof is by induction on t. For the case $t = 1$ , simply take $P_1/P_2$ to be the concatenation of $X[x^{\text {t}},x^{\text {t}}_1]$ , $Q_1^B/Q_1^R$ and $Y[y^{\text {t}}_1,y^{\text {t}}]$ . Clearly, $|P_2| - |P_1| = |Q_1^R| - |Q_1^B|$ , which immediately implies that $|P_2| - |P_1| \geq d_1 \geq 1$ . On the other hand, since $Q_1^R,Q_1^B$ are both contained in $X_1 \cup Y_1$ , we have $|P_2| - |P_1| = |Q_1^R| - |Q_1^B| \leq |X_1| + |Y_1| \leq D$ , as required.

Suppose now that $t \geq 3$ . For each $c = R,B$ , define a path $Q^{\prime }_c$ from $x^{\text {t}}$ to $x_2^{\text {b}}$ as follows:

$$ \begin{align*}Q^{\prime}_c = X[x^{\text{t}},x_1^{\text{t}}], Q_1^c, Y[y_1^{\text{t}},y_2^{\text{b}}], Q_2^c.\end{align*} $$

See Figure 6 for an illustration. We have $|Q^{\prime }_R| - |Q^{\prime }_B| = \sum _{i = 1}^2(|Q_i^R| - |Q_i^B|) \geq d_1 + d_2$ . On the other hand, since $Q^R_i,Q^B_i \subseteq X_i \cup Y_i$ (for $i = 1,2$ ), we have that $|Q^R_i| - |Q^B_i| \leq D$ and hence $|Q^{\prime }_R| - |Q^{\prime }_B| \leq 2D$ . Note that $Q^{\prime }_B,Q^{\prime }_R$ do not use any vertices of X below $x_2^{\text {b}}$ or any vertices of Y above $y_2^{\text {t}}$ . Now apply the induction hypothesis with parameter $t-2$ and with X and Y replaced by $X[x_2^{\text {b}},x^{\text {b}}]$ and $Y[y^{\text {t}},y_3^{\text {b}}]$ . This gives paths $R_1,\dots ,R_{(t+1)/2}$ between $x_2^{\text {b}}$ and $y^{\text {t}}$ such that $|R_{(t+1)/2}| - |R_1| \geq \sum _{i = 3}^t{d_i}$ and such that $1 \leq |R_{i+1}| - |R_i| \leq 2D$ for every $1 \leq i \leq (t-1)/2$ . For $1 \leq i \leq (t+1)/2$ , let $P_i$ be the concatenation of $Q^{\prime }_B$ and $R_i$ . Let $P_{(t+3)/2}$ be the concatenation of $Q^{\prime }_R$ and $R_{(t+1)/2}$ . Then $|P_{(t+3)/2}| - |P_1| = |Q^{\prime }_R| - |Q^{\prime }_B| + |R_{(t+1)/2}| - |R_1| \geq \sum _{i = 1}^t{d_i}$ . Moreover, for every $1 \leq i \leq (t-1)/2$ we have $|P_{i+1}| - |P_i| = |R_{i+1}| - |R_i|$ and hence $1 \leq |P_{i+1}| - |P_i| \leq 2D$ . Finally, we have $|P_{(t+3)/2}| - |P_{(t+1)/2}| = |Q^{\prime }_R| - |Q^{\prime }_B|$ and hence $1 \leq |P_{(t+3)/2}| - |P_{(t+1)/2}| \leq 2D$ . This completes the proof.

Proof. Apply Lemma 4.3. If $E(X,Y)$ contains a family of $m/2$ pairwise-interlacing chords, then we are done by Lemma 4.4. Otherwise, let $e_i = (x_i,y_i)$ , $e^{\prime }_i = (x^{\prime }_i,y^{\prime }_i)$ , $1 \leq i \leq t$ , be as in Lemma 4.3. Without loss of generality we may assume, for each $1 \leq i \leq t$ , that $x_i$ is above $x^{\prime }_i$ , and hence either $y_i = y^{\prime }_i$ or $y_i$ is above $y^{\prime }_i$ . For $1 \leq i \leq t$ , let $X_i := X[x_i,x^{\prime }_i]$ , $Y_i := Y[y_i,y^{\prime }_i]$ ; so $x_i^{\text {t}} = x_i$ , $x_i^{\text {b}} = x^{\prime }_i$ , $y_i^{\text {t}} = y_i$ , and $y_i^{\text {b}} = y^{\prime }_i$ . Item 2 of Lemma 4.3 guarantees that, after possibly permuting the coordinates $1,\dots ,t$ , we have that $X_i$ is above $X_j$ and $Y_i$ is below $Y_j$ for every $1 \leq i < j \leq t$ . Set $d_i := d_X(x_i,x^{\prime }_i)$ . Observe that, for each $1 \leq i \leq t$ , $Q^B_i := (x_i,y_i)$ and $Q^R_i := X[x_i,x^{\prime }_i], (x^{\prime }_i,y^{\prime }_i), Y[y^{\prime }_i,y_i]$ are two paths between $x_i$ and $y_i$ , both contained in $X_i \cup Y_i$ such that $|Q^R_i| - |Q^B_i| = d_X(x_i,x^{\prime }_i) + d_Y(y_i,y^{\prime }_i) \geq d_i$ . Similarly, $Q^B_i := (x^{\prime }_i,y^{\prime }_i)$ and $Q^R_i := X[x^{\prime }_i,x_i], (x_i,y_i), Y[y_i,y^{\prime }_i]$ are two paths between $x^{\prime }_i$ and $y^{\prime }_i$ , both contained in $X_i \cup Y_i$ such that $|Q^R_i| - |Q^B_i| \geq d_i$ . Hence, we are in the setting of Lemma 4.5. By item 3 of Lemma 4.3, we have $\sum _{i=1}^t {d_i} \geq m/4$ . If t is even, then omit a pair $(X_i,Y_i)$ for which $d_i = \min \{d_1,\dots ,d_t\}$ ; this way we guarantee that t is odd (which is necessary for invoking Lemma 4.5), while making sure that the sum $\sum d_i$ over the remaining i is at least $m/8$ . To complete the proof, apply Lemma 4.5 and set $P := P_1$ and $P' := P_{(t+3)/2}$ .

Proof. We will assume that $|E| \gg |J|$ , as otherwise, the assertion is trivial. We only consider the chords in E (removing all others). Partition X into subsections $X_1,\dots ,X_s$ such that $X_1,\dots ,X_{s-1}$ have $|J|$ vertices each, and $X_s$ has less than $|J|$ vertices. (As usual, $X_i$ is below $X_j$ for $i < j$ .) Note that if $i \neq j$ have the same parity, then for all $x_1 \in X_i, x_2 \in X_j$ we have $d_X(x_1,x_2)> |J|$ . Without loss of generality, we shall assume that $\sum _{i \text { even}}{e(X_i)} \geq \sum _{i \text { odd}}{e(X_i)}$ , and hence $\sum _{i \text { even}}{e(X_i)} \geq |E|/2$ (the other case is symmetrical). For convenience, let us set $I_0 = \{i \in [s] : i \text { even}\}$ . For each $i \in I_0$ , let $Y_i$ be the minimal subpath of Y containing all neighbours of $X_i$ . Note that $\sum _{i \in I_0}{e(X_i,Y_i)} \geq |E|/2$ .

Observe that, for all $(x_1,y_1),(x_2,y_2) \in E(X_i,Y_i)$ , we have $d_Y(y_1,y_2) \leq d_X(x_1,x_2) + |J| < 2|J|$ , where the first inequality follows from the fact that the lengths of $(x_1,y_1)$ and $(x_2,y_2)$ both belong to J and hence differ by at most $|J|$ . So we see that $|Y_i| \leq 2|J|$ . Next, observe that, for every pair $i,j \in I_0$ with $i < j$ and for all $(x_1,y_1) \in E(X_i,Y_i)$ , $(x_2,y_2) \in E(X_j,Y_j)$ , it must be the case that $y_2$ is below $y_1$ . Indeed, if not, then $(x_1,y_1),(x_2,y_2)$ either are parallel or share a vertex, which means that the difference between the lengths of $(x_1,y_1)$ and $(x_2,y_2)$ is at least $d_X(x_1,x_2)> |J|$ , contradicting that both of these lengths are in J. So we see that $Y_j$ is below $Y_i$ . In other words, every chord in $E(X_i,Y_i)$ interlaces every chord in $E(X_j,Y_j)$ .

Let $I'$ (resp., $I"$ ) be the set of all $i \in I_0$ with $0 < e(X_i,Y_i) < 12$ (resp., $e(X_i,Y_i) \geq 12$ ). Suppose first that $\sum _{i \in I'}{e(X_i,Y_i)} \geq |E|/4$ . Then by picking one chord from $E(X_i,Y_i)$ for each $i \in I'$ , we obtain a family of pairwise-interlacing chords of size $\Omega (|E|)$ . Let $(x_1,y_1),\dots ,(x_{3t},y_{3t})$ be such a family with $t = \Omega (|E|)$ . By Lemma 4.4, there are paths $P_1,\dots ,P_{t}$ between $x^{\text {t}}$ and $y^{\text {t}}$ such that $1 \leq |P_{i+1}| - |P_i| \leq 2|J|$ for every $1 \leq i \leq t - 1$ . It is easy to see that, under these conditions, we can find indices $1 \leq i_1 < \dots < i_k$ with $k = \Omega (t/|J|) = \Omega (|E|/|J|)$ such that $|P_{i_{j+1}}| - |P_{i_j}| = \Theta (|J|)$ for every $1 \leq j \leq k-1$ . Thus, the assertion of the lemma holds in this case.

Suppose now that $\sum _{i \in I"}{e(X_i,Y_i)} \geq |E|/4$ . Write $I" = \{i_1,\dots ,i_t\}$ , where $i_1 < \dots < i_t$ . If t is even, then we only consider $i_1,\dots ,i_{t-1}$ , thus making sure that the number of indices in consideration is odd. Observe that $e(X_{i_t},Y_{i_t}) \leq |X_{i_t}| \leq |J|$ (since every vertex of X is incident to at most one chord), and hence $\sum _{j=1}^{t-1}{e(X_{i_j},Y_{i_j})} \geq |E|/4 - |J| \geq |E|/8$ . So with a slight abuse of notation, we will assume from now on that t is odd and $\sum _{j=1}^{t}{e(X_{i_j},Y_{i_j})} \geq |E|/8$ .

Fix any $1 \leq j \leq t$ . Applying Lemma 4.6 to $X_{i_j}$ and $Y_{i_j}$ gives paths $P,P' \subseteq X_{i_j} \cup Y_{i_j}$ between $x_{i_j}^{\text {t}}$ and $y_{i_j}^{\text {t}}$ with $|P'| \geq |P| + \Omega (e(X_{i_j},Y_{i_j}))$ , as well as paths $Q,Q' \subseteq X_{i_j} \cup Y_{i_j}$ between $x_{i_j}^{\text {b}}$ and $y_{i_j}^{\text {b}}$ with $|Q'| \geq |Q| + \Omega (e(X_{i_j},Y_{i_j}))$ . Hence, we are in the setting of Lemma 4.5 with $d_j = \Omega (e(X_{i_j},Y_{i_j}))$ . Moreover, $D := \max _{j = 1,\dots ,t}{(|X_{i_j}| + |Y_{i_j}|)} \leq 3|J|$ . By Lemma 4.5, there are paths $P_1,\dots ,P_{(t+3)/2}$ between $x^{\text {t}}$ and $y^{\text {t}}$ such that $|P_{(t+3)/2}| - |P_1| \geq \sum _{j = 1}^t{d_j} = \sum _{j = 1}^t{\Omega (e(X_{i_j},Y_{i_j}))} = \Omega (|E|)$ and such that $1 \leq |P_{i+1}| - |P_i| \leq 2D = O(|J|)$ for every $1 \leq i \leq (t+1)/2$ . Again, it is easy to see that under these conditions, we can find indices $1 \leq i_1 < \dots < i_k$ with $k = \Omega (|E|/|J|)$ such that $|P_{i_{j+1}}| - |P_{i_j}| = \Theta (|J|)$ for every $1 \leq j \leq k-1$ . So we have established the assertion of the lemma in this case as well. This completes the proof.

Proof. We may and will assume throughout that m is sufficiently large. Let us for convenience define $\varepsilon :=\sqrt {\frac {\log \log m}{\log m}}$ . Observe that $m^{\varepsilon }=2^{\sqrt {\log m \log \log m}}$ , so our goal is to find $\Omega (m^{1-4\varepsilon })$ different lengths of paths from $x^{\text {t}}$ to $y^{\text {t}}$ . Let us assume towards a contradiction that there are less than $\Omega (m^{1-4\varepsilon })$ different lengths of paths from $x^{\text {t}}$ to $y^{\text {t}}$ . Recall that $x_i^{\text {t}}$ / $x_i^{\text {b}}$ denote the top/bottom vertices of $X_i$ , and similarly $y_i^{\text {t}}$ / $y_i^{\text {b}}$ denote the top/bottom vertices of $Y_i$ . We will prove the following claim by induction on i.

Induction statement. For a large enough constant $C>0$ and for every $i \le 1/\varepsilon $ , there are below-paths from $x_i^{\text {t}}$ to $y_i^{\text {t}}$ of $\frac {m^{i\varepsilon }}{6(C\log m)^{2(i-1)}}$ different lengths, all of which belong to an interval of size $m^{i\varepsilon }$ .

Before turning to the proof of this statement, let us show that it indeed implies the lemma. By choosing $i= \left \lfloor 1/\varepsilon \right \rfloor $ , we have $m^{i\varepsilon } \ge m^{1-\varepsilon }$ and

(4.2) $$ \begin{align} (\log m)^{1/\varepsilon}=2^{\sqrt{\log m \log \log m}}=m^{\varepsilon}. \end{align} $$

So, using, e.g., that $C^2 \leq \log m$ , we get

$$ \begin{align*}\frac{m^{i\varepsilon}}{(C\log m)^{2(i-1)}} \geq \frac{m^{1-\varepsilon}}{(\log m)^{3i}} \geq \frac{m^{1-\varepsilon}}{(\log m)^{3/\varepsilon}} \geq m^{1-4\varepsilon}. \end{align*} $$

This implies we find at least $\Omega (m^{1-4\varepsilon })$ path lengths, as desired.

From now on, our goal is to prove the above induction statement. For the base case of $i=1$ , note that, since for any chord $(x,y)$ , the trivial path $X[x^{\text {t}},x],(x,y),Y[y,y^{\text {t}}]$ has length exactly the length of $(x,y)$ plus one, there can be at most $m^{1-4\varepsilon } \leq m^{1-\varepsilon }$ different chord lengths. Since there are m chords between $X_1$ and $Y_1$ , there must exist a length which appears at least $m^{\varepsilon }$ many times. Apply Lemma 4.4 with $t=\lfloor m^{\varepsilon }/3 \rfloor $ to the family of chords having this length, noting that chords of the same length must be interlacing and that for such chords the parameter D in Lemma 4.4 equals $1$ . Lemma 4.4 gives us a collection of $t \geq m^{\varepsilon }/6$ lengths of paths between $x_1^{\text {t}}$ and $y_1^{\text {t}}$ with all consecutive differences being either $1$ or $2$ apart so in total belonging into an interval of size at most $2t+1 \leq m^{\varepsilon }$ , as desired.

Let us now move on to the induction step. So assume that for some $1\le i \le 1/\varepsilon -1$ , there are below-paths going from $x_{i}^{\text {t}}$ to $y_{i}^{\text {t}}$ of $\frac {m^{i\varepsilon }}{6(C\log m)^{2(i-1)}}$ different lengths, all of which belong to an interval of size $m^{i\varepsilon }$ . Note that we can extend all of these paths to below-paths from $x_{i+1}^{\text {b}}$ to $y_{i+1}^{\text {b}}$ by using $X[x_{i}^{\text {t}},x_{i+1}^{\text {b}}]$ and $Y[y_{i}^{\text {t}},y_{i+1}^{\text {b}}]$ and still keep the same property concerning their lengths, as each length is increased by the same number.

Our goal now is to find in $X_{i+1},Y_{i+1}$ top-bottom path-pairs with many (roughly $m^{\varepsilon }/\text {poly}\log m$ ) different lengths, among which any two consecutive ones are $\Theta (m^{i\varepsilon })$ apart. We can use any such top-bottom path-pair to extend any of our below-paths from $x_{i+1}^{\text {b}}$ to $y_{i+1}^{\text {b}}$ into a below-path from $x_{i+1}^{\text {t}}$ to $y_{i+1}^{\text {t}}$ with the length being the sum of the lengths of our original path and that of the top-bottom path-pair we used. Lemma 3.3 will then allow us to ‘fill in the gaps’ of size $\Theta (m^{i\varepsilon })$ between the lengths of the top-bottom path-pairs we found, by using the path lengths given by the inductive assumption. This will complete the induction step. See Figure 7 for an illustration.

Let us apply Lemma 4.2 to the section pair $X_{i+1},Y_{i+1}$ to obtain a parallel collection of subsection pairs $X_1^{\prime }, Y_1^{\prime }; \ldots; X_{t'}^{\prime },Y_{t'}^{\prime }$ such that $\sum _{j=1}^{t'} e(X_j^{\prime },Y_j^{\prime }) \ge m/24$ and either for every j we have a vertex in $X_j^{\prime } \cup Y_j^{\prime }$ incident to ${e(X_j^{\prime },Y_j^{\prime })}/{(6\log m)}$ chords, or for every j there is a chord $(x_j,y_j)$ in $E(X_j^{\prime },Y_j^{\prime })$ interlacing at least ${e(X_j^{\prime },Y_j^{\prime })}/{(6\log m)}$ chords in $E(X_j^{\prime },Y_j^{\prime })$ . See Figures 8 and 9. In the former case, we get $\Omega (m/\log m)\ge \Omega (m^{1-4\varepsilon })$ chords, any two of which are either parallel or share a vertex, which means that all of these chords have different lengths. This in turn means that we have $\Omega (m^{1-4\varepsilon })$ different lengths of (trivial) paths from $x^{\text {t}}$ to $y^{\text {t}}$ , giving us a contradiction. So we may assume that we are in the latter case.

For each j, consider all chords in $E(X_j^{\prime },Y_j^{\prime })$ which interlace $(x_j,y_j)$ . Observe that they can be of two types: Either their X-vertex is above $x_j$ and their Y-vertex is below $y_j$ , or vice versa. Consider only the interlacing chords of the more frequent type, and define $X_j^{\prime \prime },Y_j^{\prime \prime }$ to be the smallest subsections of $X^{\prime }_j,Y^{\prime }_j$ which contain all these chords. In particular, $x_j \notin X_j^{\prime \prime }$ , $y_j \notin Y_j^{\prime \prime }$ , and $(X^{\prime \prime }_j,Y^{\prime \prime }_j)$ is interlaced by $(x_j,y_j)$ as a section pair. Moreover, we still have $\sum _{j=1}^{t'} e(X_j^{\prime \prime },Y_j^{\prime \prime }) \ge \Omega (m/\log m)$ chords altogether. Consider the intervals of the form $[k,2k]$ with k a power of $2$ and $k \leq m/2$ . Each $e(X_j^{\prime \prime },Y_j^{\prime \prime })$ belongs to such an interval, of which there are $O(\log m)$ . So by averaging, there exists $1 \le k \le m/2$ and a subset $S \subseteq [t']$ such that for any $j \in S$ we have $e(X_j^{\prime \prime },Y_j^{\prime \prime }) \in [k,2k]$ , and $\sum _{j \in S} e(X_j^{\prime \prime },Y_j^{\prime \prime }) \ge \Omega (m/\log ^2 m)$ . Furthermore, by deleting $e(X_j^{\prime \prime },Y_j^{\prime \prime }) - k \leq \frac {1}{2}e(X_j^{\prime \prime },Y_j^{\prime \prime })$ chords from each pair $X^{\prime \prime }_j,Y^{\prime \prime }_j$ with $j \in S$ (so in total at most a half of all such chords), we may assume for convenience that $e(X_j^{\prime \prime },Y_j^{\prime \prime })=k$ for all $j \in S$ . Observe in particular that

(4.3) $$ \begin{align} |S|k \ge \Omega(m/\log^2 m). \end{align} $$

We now construct a collection of top-bottom path-pairs for $X_j^{\prime },Y_j^{\prime }$ for each $j \in S$ . Depending on which of the two types above was more frequent, we have two essentially symmetric cases. In the first one, $X_j^{\prime \prime }$ is above $x_j$ and $Y_j^{\prime \prime }$ is below $y_j$ . Here, we will take our path pairs to all contain the path which goes along $X_j^{\prime }$ from the bottom to $x_j$ , uses the chord $(x_j,y_j)$ and then goes along $Y^{\prime }_j$ from $y_j$ to the top of $Y_j^{\prime }$ . The second path in each pair is going to follow $X_j^{\prime }$ from the top until the top of $X_j^{\prime \prime }$ , then follow a path inside $X_j^{\prime \prime } \cup Y_j^{\prime \prime }$ from the top of $X_j^{\prime \prime }$ to the bottom of $Y_j^{\prime \prime }$ , and then follow along $Y_j^{\prime }$ to its bottom. Symmetrically, in the second case, our path pairs will all use the path through $(x_j,y_j)$ from the top of $X_j^{\prime }$ to the bottom of $Y_j^{\prime }$ , with the other path (from the bottom of $X_j^{\prime }$ to the top of $Y_j^{\prime }$ ) passing through $X_j^{\prime \prime } \cup Y_j^{\prime \prime }$ . See Figure 10 for these two symmetric cases. Since the argument is analogous in both cases, from now on, let us assume we are in the first case.

Observe that if we find a collection of path lengths inside $X_j^{\prime \prime } \cup Y_j^{\prime \prime }$ going from the top of $X_j^{\prime \prime }$ to the bottom of $Y_j^{\prime \prime }$ , then we have the same collection of lengths of top-bottom path-pairs for $X_j^{\prime },Y_j^{\prime }$ up to a possible translation by a fixed constant. This is because the top-bottom path-pairs we consider only differ in which path they use between the top of $X_j^{\prime \prime }$ and the bottom of $Y_j^{\prime \prime }$ .

It will be convenient to consider the ‘flipped’ section pair $X_j^{\prime \prime},\bar {Y_j^{\prime \prime }}$ , which we obtain by reversing the path $Y_j^{\prime \prime }$ (and denote it as $\bar {Y_j^{\prime \prime }}$ ). In particular, the top of $\bar {Y_j^{\prime \prime }}$ is the bottom of $Y_j^{\prime \prime }$ and any top-to-top path in $X_j^{\prime \prime },\bar {Y_j^{\prime \prime }}$ is just a path between the top of $X_j^{\prime \prime }$ and the bottom of $Y_j^{\prime \prime }$ .

Let $S_1$ be the subset of S consisting of j for which case $1$ of the above claim occurred. Let us first assume this was the more common case, namely that $|S_1|\ge |S|/2$ .

Let us now use Claim 2 to complete the proof in the case that $|S_1| \geq |S|/2$ . Observe that we may combine our top-bottom path-pairs for $X_{i+1},Y_{i+1}$ (provided by Claim 2) with top-to-top below-paths from $x_i^{\text {t}}$ to $y_i^{\text {t}}$ , provided by the inductive assumption, to obtain below-paths from $x_{i+1}^{\text {t}}$ to $y_{i+1}^{\text {t}}$ , which can then be extended along $X,Y$ into top-to-top paths for $X,Y$ . Each such path length is of the form $\ell _1+\ell _2+C_0$ , where $\ell _1$ may be chosen among our $\Omega (m^{1-(i+1)\varepsilon }/\log ^2m)$ lengths of top-bottom path-pairs for $X_{i+1},Y_{i+1}$ , which are at least $m^{i\varepsilon }$ apart; $\ell _2$ may be chosen among $\Omega (m^{i\varepsilon }/(C\log m)^{(2i-2)})$ lengths which belong in an interval of size $m^{i\varepsilon }$ (as guaranteed by the induction hypothesis), and $C_0$ is independent of the choice of $\ell _1,\ell _2$ . Therefore, by Lemma 3.3 we get at least $\Omega (m^{1-\varepsilon }/(C\log m)^{2i}) \ge \Omega (m^{1-4\varepsilon })$ (see equation (4.2)) different lengths of top-to-top paths for $X,Y$ , contradicting our assumption that the number of such lengths is smaller than $\Omega (m^{1-4\varepsilon })$ . This completes the proof in the case $|S_1| \geq |S|/2$ .

So we must have the second case in Claim 1 occurring more often, namely that $S_2:=S \setminus S_1$ has size at least $|S|/2$ . By definition, for any $j \in S_2$ there is an interval $I_j$ of size $k^{i\varepsilon }$ such that at least $k^{(i+1)\varepsilon }/4$ chords in $E(X^{\prime \prime }_i,\bar {Y_{j}^{\prime \prime }})$ have their length with respect to the subsection pair $X_{j}^{\prime \prime }, \bar {Y_{j}^{\prime \prime }}$ belong in $I_j$ . Applying Lemma 4.7 (with $J = I_j$ ), we find $\Omega (k^{\varepsilon })$ top-to-top paths in $X_{j}^{\prime \prime }, \bar {Y_{j}^{\prime \prime }}$ whose lengths are $\Theta (k^{i\varepsilon })$ apart. As before, this gives us top-bottom path-pairs for $X_{j}^{\prime },Y_j^{\prime }$ of lengths which are $\Theta (k^{i\varepsilon })$ apart. Once again, we can choose one such length for each $X_j^{\prime },Y_j^{\prime }$ and combine the corresponding top-bottom path-pairs into a top-bottom path-pair for $X_{i+1},Y_{i+1}$ , with the resulting length being the sum of the lengths of the top-bottom path-pairs we chose plus a fixed number (which is independent of our choices). Lemma 3.2 then tells us that we can find top-bottom path-pairs for $X_{i+1},Y_{i+1}$ of $\Omega (|S_2|k^{\varepsilon })\ge \Omega (|S|k^{\varepsilon })$ lengths which are $\Theta (k^{i \varepsilon })$ apart, say between $c_1 k^{i \varepsilon }$ and $c_2 k^{i \varepsilon }$ . Once again, we only consider every $m^{i\varepsilon }/c_1k^{i\varepsilon }$ -th length, thus guaranteeing that every two such lengths are at least $m^{i\varepsilon }$ and at most $\frac {c_2}{c_1}m^{i\varepsilon } = O(m^{i\varepsilon })$ apart. The number of these lengths is at least $c_1k^{i\varepsilon }/m^{i\varepsilon }\cdot \Omega (|S|k^{\varepsilon })\ge \Omega (k^{(i+1)\varepsilon -1} m^{1-i\varepsilon }/\log ^2 m)\ge \Omega (m^{\varepsilon }/\log ^2 m)$ , with the first inequality using equation (4.3). Take the first $\Theta (m^{\varepsilon }/\log ^2 m)$ of them. Since these lengths are at most $O(m^{i\varepsilon })$ apart, they are all contained in an interval of size $O(m^{(i+1)\varepsilon })$ . Now similarly as in the previous case, we can combine any of these top-bottom path-pairs with our below paths from $x_i^{\text {t}}$ to $y_i^{\text {t}}$ , which are provided by the induction hypothesis. Lemma 3.3 ensures that, by doing so, we get at least $\Omega (m^{\varepsilon }/\log ^2 m) \cdot \frac {m^{i\varepsilon }}{6(C\log m)^{2(i-1)}} = \Omega \left (\frac {m^{(i+1)\varepsilon }}{C^{2i-2}(\log m)^{2i}}\right )$ lengths which all belong to an interval of size $O(m^{(i+1)\varepsilon })$ . By potentially losing a constant proportion of the lengths, we can guarantee they all lie in an interval of size at most $m^{(i+1)\varepsilon }$ , and by choosing C to be large enough, we will have at least $\frac {m^{(i+1)\varepsilon }}{(C\log m)^{2i}}$ of them, completing the induction step and hence the proof.

Proof. Let us fix a Hamilton cycle H in our graph and a direction for this cycle. We define the length of a chord $\{x,y\}$ to be the length of the shorter of the two paths along the cycle between x and y; in particular, the length is always at most $n/2$ . For every vertex v, we fix a single chord $c(v)$ incident to v. By the pigeonhole principle, there must exist an $\ell \le n/4$ such that at least $n/\log n$ vertices have the length of their chosen chord in $[\ell ,2\ell ]$ . Now let us partition H into consecutive sections $B_1,\ldots , B_s,R$ (appearing in this order along H), where $|B_s|=4\ell $ and $s= \left \lfloor \frac {n}{4\ell } \right \rfloor \ge 1$ , and the starting vertex for $B_1$ is chosen uniformly at random among the vertices of the cycle. We will talk of the first half of $B_j$ (which is just the set of the first $2\ell $ vertices of $B_j$ ), the first quarter of $B_j$ (the set of the first $\ell $ vertices), etc.

A vertex v is said to be good if $c(v)$ is contained in some $B_j$ and if the two endpoints of $c(v)$ belong to different halves of $B_j$ . We claim that the probability that a given v with $c(v) \in [\ell ,2\ell ]$ is good is at least $\frac {1}{8}$ . To see this, write $c(v) = \{v,w\}$ , and consider the shorter path (along the cycle) between v and w; recall that the length of $c(v)$ is defined as the length of this path. There are two cases: If when walking on this path from v to w, we walk in the direction of the cycle (which was fixed at the beginning), then v is guaranteed to be good if it belongs to the second quarter of some $B_j$ . Otherwise, i.e., if we walk against the direction of the cycle, then v is guaranteed to be good if it belongs to the third quarter of some $B_j$ . In any case, the probability that v is good is at least $\frac {1}{4} \cdot \frac {|B_1| + \ldots + |B_s|}{n}$ . Since $|B_1| + \ldots + |B_s| \geq n/2$ , this probability is at least $\frac {1}{8}$ , as claimed. By linearity of expectation, the expected number of good vertices is at least $\frac {n}{8 \log n}$ . Let us now fix an outcome $B_1,\ldots , B_s,R$ for which we have at least this many good vertices. Let I be the set of $i \in [s]$ such that $B_i$ contains at least $\frac {\ell }{4\log n}$ good vertices. Observe that the sections $B_i$ , $i \notin I$ , contribute in total at most $s\cdot \frac {\ell }{4\log n} \le \frac {n}{16\log n}$ to the overall number of good vertices. Therefore, at least $\frac {n}{16 \log n}$ good vertices belong to sections $B_i$ with $i \in I$ . In particular, $|I| \geq \frac {n}{64 \ell \log n}$ since each $B_i$ has $4\ell $ vertices.

For each $i \in I$ , we will later find inside $B_i$ paths of at least $1+ \Omega (\ell /2^{5\sqrt {\log n \log \log n}})$ different lengths joining the endpoints of $B_i$ . Let us first complete the proof using this. To do so, choose for each $i \in I$ , one of these paths joining the endpoints of $B_i$ , and combine these paths into a cycle using H. The length of the resulting cycle is equal to the sum of the lengths of the paths we chose plus a fixed number, independent of our choices (i.e., the total length of the pieces of H we used to join the paths). So by Lemma 3.2, these cycles take at least $\Omega \left (\frac {n}{ \ell \log n}\cdot {\ell }/{2^{5\sqrt {\log n \log \log n}}}\right ) \ge \Omega \left ({n}/{2^{6\sqrt {\log n \log \log n}}}\right )$ different lengths, as desired.

What remains to be proved is that, for $i \in I$ , $B_i$ contains paths of $1+ \Omega (\ell /2^{5\sqrt {\log n \log \log n}})$ different lengths joining its endpoints. By definition, $B_i$ has at least $\frac {\ell }{4\log n}$ good vertices. Since $B_i$ contains at least one chord, we know it has at least two path lengths (one coming from the length of $B_i$ itself and the other from the path only using a single chord). In particular, we may assume that $\ell \gg 2^{5\sqrt {\log n \log \log n}}$ or we are done. Let X denote the first half of $B_i$ and Y its second half. We think of $X,Y$ as a section pair (omitting the middle edge of $B_i$ ) and consider the endpoints of $B_i$ to be the top vertices of X and Y. By definition, every chord $c(v)$ which corresponds to a good vertex v has one endpoint in X and one in Y. Let us assume without loss of generality that X contains at least half (so at least $\frac {\ell }{8\log n}$ ) of all good vertices in $B_i$ . Delete any chord which was not chosen by one of the good vertices in X. This way, we make sure that every vertex in X is incident to at most one chord. Also, at least $\frac {\ell }{8\log n}$ chords remain.

Let us now apply Lemma 4.1 to this section pair $X,Y$ with parameter $m=\frac {\ell }{8\log n}$ and $k=\sqrt {\log n}$ and thus obtain either a vertex $v \in Y$ incident to at least $\Omega \left ({\ell }/{\log ^2 n}\right )$ chords or an interlacing or parallel collection of k subsection pairs $X_1,Y_1;\ldots; X_k,Y_k$ , each containing at least $\Omega \left ({\ell }/{\log ^3 n}\right )$ chords.

Suppose first that there is a vertex $v \in Y$ incident to at least $\Omega \left ({\ell }/{\log ^2 n}\right )$ chords $(v,x)$ , $x \in X$ . Observe that all these chords have different lengths. Now, for each such chord, consider the path between the endpoints of $B_i$ , which uses only this chord and no others. These are paths of $\Omega \left ({\ell }/{\log ^2 n}\right )$ different lengths between the endpoints of $B_i$ , as required.

Suppose now that we are in the second case, namely that there exists an interlacing or parallel collection $X_1,Y_1;\ldots; X_k,Y_k$ of subsection pairs with $e(X_i,Y_i) \geq \Omega \left ({\ell }/{\log ^3 n}\right )$ for each $i = 1,\dots ,k$ . If these subsection pairs are parallel, then we may immediately apply Lemma 4.8 with $t=k$ and $m=\Omega ({\ell }/{\log ^3 n})$ to get the desired number $\Omega \big ( \frac {\ell }{\log ^3n}/2^{4\sqrt {\log n \log \log n}} \big ) \geq \Omega (\ell /2^{5\sqrt {\log n \log \log n}})$ of different path lengths between the endpoints of $B_i$ . In the case that $X_1,Y_1;\ldots; X_k,Y_k$ are interlacing, we need an extra step, as follows. Suppose without loss of generality that $X_i$ is below $X_j$ (and hence $Y_i$ is above $Y_j$ ) for each $1 \leq i < j \leq k$ . Take $(x_1,y_1) \in E(X_1,Y_1)$ and $(x_2,y_2) \in E(X_2,Y_2)$ . Let us now ‘reroute’ $B_i$ along the interlacing chords $(x_1,y_1)$ , $(x_2,y_2)$ ; in other words, we consider a new path $B_i^{\prime }$ , obtained by following X from the top until $x_2$ , jumping along $(x_2,y_2)$ , following $B_i$ (now in the other direction) until $x_1$ , jumping along $(x_1,y_1)$ and finally following Y until its top. See Figure 11 for a picture. Note that $B_i^{\prime }$ splits into the section pair $X' := X[x^{\text {t}},x_2]$ , $Y' := B_i[y_2,x_1],(x_1,y_1),Y[y_1,y^{\text {t}}]$ , with $X'$ having the same top as X and $Y'$ the same top as Y. Observe that $X_k,\ldots , X_3$ still appear in this order along $X'$ , but, crucially, $Y_3,\dots ,Y_k$ now appear in the reverse order; see Figure 12. In other words, the subsection pairs $X_3,Y_3;\ldots; X_k,Y_k$ are parallel in $X',Y'$ . So we may now apply Lemma 4.8 with $t=k-2$ and $m=\Omega ({\ell }/{\log ^3 n})$ to get the desired number of different path lengths between the endpoints of $B_i$ . This completes the proof.

Figure 11 Rerouting through a path $B^{\prime }_i$ marked in red.

Figure 12 Rerouted path $B^{\prime }_i$ with new relative positions of the section pairs.