Claim 3.1. X has members of every colour.

Proof Fix A the set of colours which occur in X, and suppose this is not all the colours.

Fix a length n such that every colour in A occurs on a string $\tau \in X$ with $|\tau | \le n$ , and fix t sufficiently large such that X has converged on strings of length at most n by stage t, i.e., if $|\tau | \le n$ , then for all $s \ge t$ , $X_s(\tau ) = X(\tau )$ .

Since X is infinite, it contains some $\tau $ which enters $\text {dom}(U)$ at some stage $s> t$ . At stage s, $r_i \le n$ for every $i \in A$ , whereas $r_i> n$ for every colour $i \not \in A$ . So $\chi (\tau )$ will be a colour not in A, contrary to choice of A.

Proof Fix d such that for every $\sigma \in X$ , $K(\sigma )> |\sigma |-d$ . For every n, let $n^*_s$ be the natural stage s approximation to $n^*$ . This may be undefined for small s, but it will eventually converge to the true $n^*$ . Further, if $n^*_s\!\!\downarrow $ and $n^*_{s+1} \neq n^*_s$ , then $|n^*_{s+1}| < |n^*_s|$ .

Again fix $\epsilon $ as in Corollary 1.13. Fix k with $2^{-k} < \epsilon $ . For every n and s with $|n_s^*|> |n^*| + k+d$ (a c.e. event), we enumerate $(n, |n_s^*| - d)$ into A. Since for a fixed n there is at most one $n^*_s$ of any given length, the weight of our requests is bounded by

$$ \begin{align*} \sum_{n} \sum_{i> |n^*|+k+d} 2^{-(i-d)} = 2^{-k} \sum_n 2^{-|n^*|} < 2^{-k}. \end{align*} $$

Thus $\text {wt}(A) \le \epsilon $ , and so $K(n^*_s) \le |n^*_s| - d$ for every such $n^*_s$ .

It follows that if $n^*_s \in X$ , then since $K(n^*_s)> |n^*_s| - d$ by assumption, $|n^*_s| \le |n^*| + k+d$ , or $|n^*| \ge |n^*_s| - k - d$ . As in the proof of Theorem 1.8, this allows X to enumerate an infinite sequence from $N_U$ . Since every infinite c.e. set contains an infinite computable set, and this relativizes, we get that X computes an infinite $Y \subseteq N_U$ . As X is $\Delta ^0_2$ , Y is as well, so $Y \ge _T \emptyset '$ , and thus $X \ge _T \emptyset '$ .

Proof Let P be a bounded $\Pi ^0_1$ class of K-compression functionsFootnote ⁵ . Since we have an a priori upper bound of $K(n) \le ^+ 2\log (n)$ , we may take $P \subseteq 2^\omega $ . Let F be a “weakly-low for K” path. That is, there are infinitely many n with $F(n)=^+K(n)$ . This can be shown to exist using the “low for $\Omega $ ”-Basis TheoremFootnote ⁶ (Downey, Hirschfeldt, Miller, and Nies [Reference Downey, Hirschfeldt, Miller and Nies6], Reimann and Slaman [Reference Reimann and Slaman15]) and the fact that low for $\Omega $ is equivalent to “weakly low for K” (see Downey and Hirschfeldt [Reference Downey and Hirschfeldt5]).

Now fix the least c with $K(n) = F(n)+c$ for infinitely many n, and fix an m with $K(n) \ge F(n) + c$ for all $n \ge m$ . F can enumerate an infinite subset of $N_U$ : $\{ n_s^* : n \ge m \wedge |n_s^*| = F(n)+c\}$ . Thus F computes an infinite $X \subseteq N_U$ (again relativizing the fact that every infinite c.e. set has an infinite computable subset), Since F does not compute $\emptyset '$ (since it is weakly low for K), X also does not compute $\emptyset '$ .

Proof As one direction is immediate, it remains to show that

$$ \begin{align*} K^{\emptyset'}(\sigma) \le^+ \limsup_{n \in X} K(\sigma\mid n). \end{align*} $$

We will work with request sets.

For each $n \in \omega $ , define $A_n = \{ (\sigma , s) : s \ge K(\sigma \mid n)\}$ . We may think of $A_n$ as the request set generating $K(\cdot |n)$ . Observe that $\text {wt}(A_n) < 2$ for all n.

Note that for any finite set $D \subset 2^{<\omega } \times \omega $ and any $m \in \omega $ , the set $\{ n\ge m : \text {wt}(D \cup A_n)> 2\}$ is c.e. (it is even primitive recursive with appropriate assumptions on $K(\cdot |n)$ , but this is not necessary). Indeed this is uniform, so we may fix a total computable function e such that $W_{e(D, m)} = \{n \ge m : \text {wt}(D\cup A_n)> 2\}$ , where D is given by a canonical index.

We will build a $\emptyset '$ -enumerable request set B with $\text {wt}(B) \le 2$ and such that for all $\sigma $ , if $s = \limsup _{n \in X} K(\sigma \mid n)$ , then $(\sigma , s) \in B$ . By Corollary 1.12 relativized to $\emptyset '$ , this will suffice to prove the result.

Fix an effective listing $(\sigma _m, s_m)_{m \in \omega }$ of $2^{<\omega }\times \omega $ such that every pair is repeated infinitely many times on the list. We define B as follows:

• • $B_0 = \emptyset $ .

• • Given $B_m$ , fix $D = B_m \cup \{(\sigma _m, s_m)\}$ . If $X \cap W_{e(D,m)} = \emptyset $ , we let $B_{m+1} = D$ ; otherwise, we let $B_{m+1} = B_m$ .

As X is semi-low, $\emptyset '$ can run this construction, and so B is $\emptyset '$ -enumerable.

This completes the proof.

Proof By symmetry, and the fact that $N_V \subseteq M_V$ , it suffices to show

$$ \begin{align*} \limsup_{\tau \in M_U} K(\sigma\mid \tau) \le^+ \limsup_{\tau \in N_V} K(\sigma\mid \tau). \end{align*} $$

By standard arguments, there is a constant c such that if $\tau \in M_U$ , $\rho \in M_V$ , and $U(\tau ) = V(\rho )$ , then $| |\tau | - |\rho | | \le c$ .

For each $\tau \in 2^{<\omega }$ and $i \in \mathbb {Z}$ with $|i| \le c$ , let $ \rho (\tau ,i)$ be the first $\rho $ located with $|\rho | = |\tau |+i$ and $U(\tau )\!\!\downarrow = V(\rho )\!\!\downarrow $ , if such $\rho $ exists. We define

$$ \begin{align*} B_\tau = \{ (\sigma, s) : \exists i\, \rho(\tau,i)\!\!\downarrow \wedge s \ge K(\sigma\mid \rho(\tau,i))\}. \end{align*} $$

Then $\text {wt}(B_\tau ) \le \sum _{|i| \le c} \sum _{\sigma } 2\cdot 2^{-K(\sigma \mid \rho (\tau ,i))} \le (2c+1)\cdot 2$ , and thus these are uniformly given request sets.

It follows that $K(\sigma \mid \tau ) \le ^+ K(\sigma \mid \rho (\tau ,i))$ for all i with $\rho (\tau ,i)\!\!\downarrow $ . Note that if $\tau \in M_U$ , then there is an i with $\rho (\tau ,i)\!\!\downarrow \in N_V$ . The claim follows.

Proof Fix some universal prefix-free machine V. We define $U(0^{3}\widehat {\phantom {\alpha }}\tau ) = V(\tau )$ for all $\tau $ , which makes U universal while giving us the freedom to do as we like on other neighborhoods.

Let $(N_s)_{s \in \omega }$ be the natural approximation to $N_U$ . We will have semi-lowness requirements $R_e$ and infiniteness requirements $P_n$ . The strategy for each requirement will claim various strings in $N_s$ , and each strategy will have a directive at every stage: meet or avoid. A string may only be claimed by a single strategy at a time, and a strategy will retain its claim on a string until either the string leaves $N_s$ , or a higher priority strategy claims the string. In either case, the strategy will immediately relinquish its claim.

We will build a c.e. set $A \subseteq 2^{<\omega } \times \omega $ . As we will argue, the sum $\sum 2^{-|\sigma |}$ over all strings $\sigma $ which are ever claimed in the construction will be bounded by 1/2. The first time a string $\sigma $ is claimed by a strategy (i.e., it was unclaimed at all previous stages), we will immediately enumerate $(k, |\sigma |-1)$ into A, where k is larger than any value yet seen in the construction. As the previous sum is bounded by 1/2, $\text {wt}(A) \le 1$ . By the Machine Existence Theorem, we uniformly obtain the index of a corresponding prefix-free machine Q such that for every such pair $(k, |\sigma |-1) \in A$ , there is a $\tau $ with $|\tau | = |\sigma |-1$ and $Q(\tau ) = k$ .

We define $U(1\widehat {\phantom {\alpha }}\tau ) = Q(\tau )$ for all $\tau $ . Suppose $\sigma $ is first claimed at stage s, and so we enumerate $(k, |\sigma |-1)$ into A for some large k. Then for the appropriate $\tau $ , $|1\widehat {\phantom {\alpha }}\tau | = |\sigma |$ and $U(1\widehat {\phantom {\alpha }}\tau ) = k$ . By the largeness of k, $N_s$ contains no codes for k, so $\tau $ will belong to $N_U$ unless V enumerates a sufficiently shorter code at some subsequent stage. The idea is that whenever a potential element of $N_U$ is claimed, we ensure it is replaced with a new element of the same length or shorter.

This completes the description of U, apart from describing how strategies claim strings. We order our requirements $R_0, P_0, R_1, P_1, \dots $ . At stage s, we consider the first s requirements in order, implementing the following strategies.

Strategy for $P_n$ :

$P_n$ will always have the meet directive, and will claim at most one string at a time. At stage s, if it retains a claimed string from the previous stage (i.e., $s>0$ , $P_n$ had a claimed string at stage $s-1$ , that string remains in $N_s$ , and that string has not been claimed by a higher priority strategy earlier in stage s), then we take no further action. Otherwise, if there is a string in $N_s$ of length at least $2n+4$ and unclaimed by any higher priority strategy, $P_n$ claims the least one (in some effective ordering). If $P_n$ did not retain a claimed string, and there is no appropriate string to claim, we simply do nothing.

Strategy for $R_e$ : The behaviour of $R_e$ is a yo–yo: it continues to claim strings until the weight of the claimed strings surpasses $2^{-(2e+4)}$ , at which point it stops and lets those strings bleed away. Once it has lost all of its claims, the strategy begins claiming new strings again. The details follow.

At stage s, let C be the set of strings which $R_e$ retains the claim on from the previous stage: those strings which it claimed at stage $s-1$ , which remain in $N_s$ , and which were not claimed by a higher priority strategy earlier in stage s. If $R_e$ was not considered at stage $s-1$ (possibly because $s = 0$ ), then $C=\emptyset $ .

Let $w = \sum _{\sigma \in C} 2^{-|\sigma |}$ . Our directive for $R_e$ at stage s will depend on w and on $R_e$ ’s directive at stage $s-1$ :

• • If $w = 0$ (i.e., $C = \emptyset $ ), then $R_e$ has the directive avoid at stage s.

• • If $0 < w \le 2^{-(2e+4)}$ , then $R_e$ retains the same directive as it had at the previous stage ( $w> 0$ entails that $R_e$ was considered at the previous stage).

• • If $w> 2^{-(2e+4)}$ , then $R_e$ has the directive meet at stage s.

If our directive for $R_e$ at stage s is meet, we take no further action at this stage.

If our directive for $R_e$ at stage s is avoid, and there is a string in $N_s \cap W_{e,s}$ of length at least $2e+4$ and unclaimed by any higher priority strategy, then $R_e$ claims the least such string (in some effective ordering). Our action for $R_e$ at this stage is then complete. Note that we claim no more than one string for $R_e$ at each stage.

This completes the construction.

Definition of X:

Let $X_s$ be the set of strings $\sigma $ claimed by a strategy with the meet directive at stage s.

Observe that if $\sigma \in N_U$ is claimed by a strategy, then there are only two possibilities: that strategy may retain its claim on $\sigma $ forever, or the claim on $\sigma $ may pass to a higher priority strategy. As we will argue, each $R_e$ strategy changes its directive only finitely many times. It follows that $X = \lim _s X_s$ is defined.

Verification:

First we must keep our promises.

Proof If a string $\sigma $ is claimed during the construction, there are three possible fates for $\sigma $ : 1) there is some n such that $P_n$ claims $\sigma $ at almost every stage; 2) there is some e such that $R_e$ claims $\sigma $ at almost every stage; 3) $\sigma $ leaves $N_U$ . We consider each case in turn.

Fix n. By construction, there is at most one string which is ultimately claimed by $P_n$ , and such a string has length at least $2n+4$ . So the sum $\sum 2^{-|\sigma |}$ over all strings $\sigma $ ultimately claimed by $P_n$ is bounded by $2^{-(2n+4)}$ .

Fix e. Let $\hat {C}$ be the set of strings $\sigma $ such that $R_e$ claims $\sigma $ at almost every stage. Then each $\sigma \in \hat {C}$ contributes to almost every $w(e,s)$ , so $\sum _{\sigma \in \hat {C}}2^{-|\sigma |} \le \sup _s w(e,s) \le 2^{-(2e+3)}$ .

Finally, consider strings which leave $N_U$ . We will split this case into two subcases, based on whether the given string extends $000$ , and so was introduced by our copying of V, or it extends 1, and so was introduced by our other actions. Since the extensions of $000$ in the domain of U form an antichain, the sum $\sum 2^{-|\sigma |}$ over all strings in the first subcase is bounded by $1/8$ .

Consider now the second subcase. Note that strings never leave $N_U$ because of our action; instead, if $\sigma $ leaves $N_U$ , then there must be some $\tau \in N_V$ with $V(\tau ) = U(\sigma )$ and $|\tau | < |\sigma |-3$ . As we always choose our values large, if $\sigma _0$ and $\sigma _1$ are distinct strings from this subcase, $U(\sigma _0) \neq U(\sigma _1)$ , so the corresponding $\tau $ s are distinct. So summing over the $\sigma $ of this subcase, we have $\sum 2^{-|\sigma |} < \frac 18 \sum _{\tau \in N_V} 2^{-|\tau |} < \frac 18$ . Putting these all together, our desired sum is bounded by

$$ \begin{align*}6 \sum_{n \in \omega} 2^{-(2n+4)} + \sum_{e \in \omega} 2^{-(2e+3)} + \frac18 + \frac18 \le \frac12, \end{align*} $$

as desired.

Thus we may speak of an $R_j$ strategy’s ultimate directive.

Our promises being met, the construction of X is as described. Now we verify that X has the desired properties.

This completes the proof.

Proof As this is independent of choice of machine, let U and X be as in Proposition 5.2. Then

$$ \begin{align*} K^{\emptyset'}(\sigma) =^+ \limsup_{\tau \in X} K(\sigma\mid \tau) \le \limsup_{\tau \in N_U} K(\sigma\mid \tau) \le \limsup_{\tau \in M_U} K(\sigma\mid \tau) \le \limsup_{\tau \in 2^{<\omega}} K(\sigma\mid \tau) =^+ K^{\emptyset'}(\sigma), \end{align*} $$

where the first equality is by Proposition 4.2, the last is by Theorem 1.3, and the inequalities are by subset.

Proof For any m, define $\tau _m \in 2^{<\omega }$ to be the string of length $a_m$ such that $\tau _m(x) = 1$ iff $x = a_n$ for some $n < m$ . Note that $m \mapsto \tau _m$ is effective, so $K(\sigma \mid m) \le ^+ K(\sigma \mid \tau _m)$ . Also, $\sigma _m \prec \emptyset '$ iff $m \in E$ , so

$$ \begin{align*} \limsup_{m \in E} K(\sigma \mid m) &\le^+ \limsup_{m \in E} K(\sigma \mid \emptyset'\!\!\upharpoonright\! a_m)\\ &\le \limsup_n K(\sigma \mid \emptyset'\!\!\upharpoonright\! n)\\ &=^+ \limsup_n K^{\emptyset'}(\sigma\mid n). \end{align*} $$

Conversely, $\emptyset '$ can compute the increasing enumeration of E, $E = \{ b_0 < b_1 < \dots \}$ , so $K^{\emptyset '}(\sigma \mid n) \le ^+ K(\sigma \mid b_n)$ , giving

$$ \begin{align*} \limsup_{m \in E} K(\sigma \mid m) =^+ \limsup_n K^{\emptyset'}(\sigma\mid n). \end{align*} $$

By Theorem 1.3 relativized to $\emptyset '$ , this is (up to an additive constant) $K^{\emptyset ^{(2)}}(\sigma )$ .

Proof of Theorem 6.2

We will enumerate a c.e. set A. Fix an effective bijection $\tau = \langle D, k \rangle $ between $\tau \in 2^{<\omega }$ and pairs $\langle D, k \rangle $ with $D \subset 2^{<\omega }$ finite and $k \in \omega $ . For $\tau = \langle D, k \rangle $ , for every $\sigma \in 2^{<\omega } \setminus D$ , we enumerate $(\sigma , t-k, \tau )$ into A for every $t \ge K(\sigma )$ , provided doing so does not cause $\sum _{(\sigma , s, \tau ) \in A} 2^{-s}$ to exceed 1.

Fix the constant c such that $K(\sigma \mid \tau ) \le s+c$ for every $(\sigma ,s, \tau ) \in A$ . As $\sum _\sigma 2^{-K(\sigma )} < 1$ , there is some finite D such that $\sum _{\sigma \not \in D} 2^{-K(\sigma )} < 2^{-(e+c+1)}$ . Fix $\tau = \langle D, e+c \rangle $ . Then $\sum _{\sigma \not \in D} \sum _{t \ge K(\sigma } 2^{-(t - e - c)} < 1$ , so $(\sigma , t-e-c, \tau )$ is successfully enumerated into A for all such $\sigma $ and t. Thus $K(\sigma \mid \tau ) \le K(\sigma ) - e - c+c = K(\sigma )-e$ for all $\sigma \not \in D$ .

Question 6.4. What can be said about the set $C_e=\{\rho \mid \rho $ is e-compressing $\}$ ?

Question 6.5. Is there a definition of k-randomness purely involving C?