Linear-Inequality Affine Transformation Automata

Linear-Inequality Affine Transformation Automata (LIATA) are a model for computation based upon applying affine transformations to vectors based on cases defined by linear inequalities. They are a generalization of the rules for BMO1 and were proven to be Turing complete.

Example

An example of a LIATA are the rules for BMO1:

where ${\displaystyle f(n,n)}$ is undefined. BMO1 halts iff there exists k such that ${\displaystyle f^{k}(1,2)}$ is undefined (in other words ${\displaystyle f^{k-1}(1,2)=(n,n)}$ for some n).

This is a 2-dimension, 2-case LIATA. The 2 dimensions are the parameters a,b and the two cases are the ${\displaystyle a<b}$ and ${\displaystyle a>b}$ rows. For each case the parameters are transformed via an affine transformation.

Formal Definition

A n-dimension, k-case LIATA is a piecewise defined partial function ${\displaystyle f:\mathbb {Z} ^{n}\to \mathbb {Z} ^{n}}$:

Where each ${\displaystyle f_{i}:\mathbb {Z} ^{n}\to \mathbb {Z} ^{n}}$ is an affine function and each ${\displaystyle C_{i}:\mathbb {Z} ^{n}\to \{T,F\}}$ is a "linear inequality condition" (defined below) such that for all ${\displaystyle {\vec {x}}}$ at most one condition ${\displaystyle C_{i}({\vec {x}})}$ applies. If none of the conditions apply to ${\displaystyle {\vec {x}}}$, we say that it halts on that configuration.

Let a linear inequality term be any equation of the form ${\displaystyle g({\vec {x}})\sim c}$ where ${\displaystyle g:\mathbb {Z} ^{n}\to \mathbb {Z} }$ is a linear function and ~ is replaced by any (in)equality relation (=,<,≤,>,≥). Then let a linear inequality condition be any combination of linear inequality terms using logical AND, OR and NOT operations.

So, for example, the following are all linear inequality conditions:

• ${\displaystyle a<b}$ represented formally as ${\displaystyle a-b<0}$
• ${\displaystyle 3a\leq b<4a}$ represented formally as ${\displaystyle (b-3a\geq 0)\land (4a-b>0)}$
• ${\displaystyle a=2}$ (note that we allow equalities as well)

Given a LIATA f, we say that it halts in k steps starting from configuration ${\displaystyle {\vec {x}}}$ iff ${\displaystyle f^{k}({\vec {x}})}$ is undefined.

Turing Complete

LIATA are Turing complete. This has been proven by implementing Minsky machines as LIATA:

• @Bard's proved that 3-dim LIATA are Turing complete: Discord link
• @star's proved that 2-dim LIATA are Turing complete: Discord link
• In progress: Shawn Ligocki is working on a proof that 2-case LIATA are Turing complete: Discord link