Higman's lemma

Not to be confused with Higman's theorem.

In mathematics, Higman's lemma states that the set ${\displaystyle \Sigma ^{*}}$ of finite sequences over a finite alphabet ${\displaystyle \Sigma }$, as partially ordered by the subsequence relation, is well-quasi-ordered. That is, if ${\displaystyle w_{1},w_{2},\ldots \in \Sigma ^{*}}$ is an infinite sequence of words over a finite alphabet ${\displaystyle \Sigma }$, then there exist indices ${\displaystyle i<j}$ such that ${\displaystyle w_{i}}$ can be obtained from ${\displaystyle w_{j}}$ by deleting some (possibly none) symbols. More generally this remains true when ${\displaystyle \Sigma }$ is not necessarily finite, but is itself well-quasi-ordered, and the subsequence relation is generalized into an "embedding" relation that allows the replacement of symbols by earlier symbols in the well-quasi-ordering of ${\displaystyle \Sigma }$. This is a special case of the later Kruskal's tree theorem. It is named after Graham Higman, who published it in 1952.

Proof

Let ${\displaystyle \Sigma }$  be a well-quasi-ordered alphabet of symbols (in particular, ${\displaystyle \Sigma }$  could be finite and ordered by the identity relation). Suppose for a contradiction that there exist infinite bad sequences, i.e. infinite sequences of words ${\displaystyle w_{1},w_{2},w_{3},\ldots \in \Sigma ^{*}}$  such that no ${\displaystyle w_{i}}$  embeds into a later ${\displaystyle w_{j}}$ . Then there exists an infinite bad sequence of words ${\displaystyle W=(w_{1},w_{2},w_{3},\ldots )}$  that is minimal in the following sense: ${\displaystyle w_{1}}$  is a word of minimum length from among all words that start infinite bad sequences; ${\displaystyle w_{2}}$  is a word of minimum length from among all infinite bad sequences that start with ${\displaystyle w_{1}}$ ; ${\displaystyle w_{3}}$  is a word of minimum length from among all infinite bad sequences that start with ${\displaystyle w_{1},w_{2}}$ ; and so on. In general, ${\displaystyle w_{i}}$  is a word of minimum length from among all infinite bad sequences that start with ${\displaystyle w_{1},\ldots ,w_{i-1}}$ .

Since no ${\displaystyle w_{i}}$  can be the empty word, we can write ${\displaystyle w_{i}=a_{i}z_{i}}$  for ${\displaystyle a_{i}\in \Sigma }$  and ${\displaystyle z_{i}\in \Sigma ^{*}}$ . Since ${\displaystyle \Sigma }$  is well-quasi-ordered, the sequence of leading symbols ${\displaystyle a_{1},a_{2},a_{3},\ldots }$  must contain an infinite increasing sequence ${\displaystyle a_{i_{1}}\leq a_{i_{2}}\leq a_{i_{3}}\leq \cdots }$  with ${\displaystyle i_{1}<i_{2}<i_{3}<\cdots }$ .

Now consider the sequence of words

$${\displaystyle w_{1},\ldots ,w_{{i_{1}}-1},z_{i_{1}},z_{i_{2}},z_{i_{3}},\ldots .}$$

 

Since this sequence is "more minimal" than ${\displaystyle W}$ , it must contain a word ${\displaystyle u}$  that embeds into a later word ${\displaystyle v}$ . But ${\displaystyle u}$  and ${\displaystyle v}$  cannot both be ${\displaystyle w_{j}}$ 's, because then the original sequence ${\displaystyle W}$  would not be bad. Similarly, it cannot be that ${\displaystyle u}$  is a ${\displaystyle w_{j}}$  and ${\displaystyle v}$  is a ${\displaystyle z_{i_{k}}}$ , because then ${\displaystyle w_{j}}$  would also embed into ${\displaystyle w_{i_{k}}=a_{i_{k}}z_{i_{k}}}$ . And similarly, it cannot be that ${\displaystyle u=z_{i_{j}}}$  and ${\displaystyle v=z_{i_{k}}}$ , ${\displaystyle j<k}$ , because then ${\displaystyle w_{i_{j}}=a_{i_{j}}z_{i_{j}}}$  would embed into ${\displaystyle w_{i_{k}}=a_{i_{k}}z_{i_{k}}}$ . In every case we arrive at a contradiction.

Ordinal type

The ordinal type of ${\displaystyle \Sigma ^{*}}$  is related to the ordinal type of ${\displaystyle \Sigma }$  as follows:^[1][2]

$${\displaystyle o(\Sigma ^{*})={\begin{cases}\omega ^{\omega ^{o(\Sigma )-1}},&o(\Sigma ){\text{ finite}};\\\omega ^{\omega ^{o(\Sigma )+1}},&o(\Sigma )=\varepsilon _{\alpha }+n{\text{ for some }}\alpha {\text{ and some finite }}n;\\\omega ^{\omega ^{o(\Sigma )}},&{\text{otherwise}}.\end{cases}}}$$

 

Reverse-mathematical calibration

Higman's lemma has been reverse mathematically calibrated (in terms of subsystems of second-order arithmetic) as equivalent to ${\displaystyle ACA_{0}}$  over the base theory ${\displaystyle RCA_{0}}$ .^[3]

References

• Higman, Graham (1952), "Ordering by divisibility in abstract algebras", Proceedings of the London Mathematical Society, (3), 2 (7): 326–336, doi:10.1112/plms/s3-2.1.326

Citations

1. de Jongh, Dick H. G.; Parikh, Rohit (1977). "Well-partial orderings and hierarchies". Indagationes Mathematicae (Proceedings). 80 (3): 195–207. doi:10.1016/1385-7258(77)90067-1.
2. Schmidt, Diana (1979). Well-partial orderings and their maximal order types (Habilitationsschrift). Heidelberg. Republished in: Schmidt, Diana (2020). "Well-partial orderings and their maximal order types". In Schuster, Peter M.; Seisenberger, Monika; Weiermann, Andreas (eds.). Well-Quasi Orders in Computation, Logic, Language and Reasoning. Trends in Logic. Vol. 53. Springer. pp. 351–391. doi:10.1007/978-3-030-30229-0_13.
3. J. van der Meeren, M. Rathjen, A. Weiermann, An order-theoretic characterization of the Howard-Bachmann-hierarchy (2015, p.41). Accessed 03 November 2022.