Unique homomorphic extension theorem

The unique homomorphic extension theorem is a result in mathematical logic which formalizes the intuition that the truth or falsity of a statement can be deduced from the truth values of its parts.^[1]^[2]^[3]

The lemma

Let A be a non-empty set, X a subset of A, F a set of functions in A, and $X_{+}$ the inductive closure of X under F.

Let be B any non-empty set and let G be the set of functions on B, such that there is a function $d:F\to G$ in G that maps with each function f of arity n in F the following function $d(f):B^{n}\to B$ in G (G cannot be a bijection).

From this lemma we can now build the concept of unique homomorphic extension.

The theorem

If $X_{+}$ is a free set generated by X and F, for each function $h:X\to B$ there is a single function ${\hat {h}}:X_{+}\to B$ such that:

\forall x\in X,{\hat {h}}(x)=h(x);\qquad (1)

For each function f of arity n > 0, for each $x_{1},\ldots ,x_{n}\in X_{+}^{n},$

{\hat {h}}(f(x_{1},\ldots ,x_{n}))=g({\hat {h}}(x_{1}),\ldots ,{\hat {h}}(x_{n})),{\text{ where }}g=d(f)\qquad (2)

Consequence

The identities seen in (1) e (2) show that ${\hat {h}}$ is an homomorphism, specifically named the unique homomorphic extension of $h$ . To prove the theorem, two requirements must be met: to prove that the extension ( ${\hat {h}}$ ) exists and is unique (assuring the lack of bijections).

Proof of the theorem

We must define a sequence of functions $h_{i}:X_{i}\to B$ inductively, satisfying conditions (1) and (2) restricted to $X_{i}$ . For this, we define $h_{0}=h$ , and given $h_{i}$ then $h_{i+1}$ shall have the following graph:

{\{(f(x_{1},\ldots ,x_{n}),g(h_{i}(x_{1}),\ldots ,h_{i}(x_{n})))\mid (x_{1},\ldots ,x_{n})\in X_{i}^{n}-X_{i-1}^{n},f\in F\}}\cup {\operatorname {graph} (h_{i})}{\text{ with }}g=d(f)

First we must be certain the graph actually has functionality, since $X_{+}$ is a free set, from the lemma we have $f(x_{1},\ldots ,x_{n})\in X_{i+1}-X_{i}$ when $(x_{1},\ldots ,x_{n})\in X_{i}^{n}-X_{i-1}^{n},(i\geq 0)$ , so we only have to determine the functionality for the left side of the union. Knowing that the elements of G are functions(again, as defined by the lemma), the only instance where $(x,y)\in graph(h_{i})$ and $(x,z)\in graph(h_{i})$ for some $x\in X_{i+1}-X_{i}$ is possible is if we have $x=f(x_{1},\ldots ,x_{m})=f'(y_{1},\ldots ,y_{n})$ for some $(x_{1},\ldots ,x_{m})\in X_{i}^{m}-X_{i-1}^{m},(y_{1},\ldots ,y_{n})\in X_{i}^{n}-X_{i-1}^{n}$ and for some generators $f$ and ${f'}$ in $F$ .

Since $f(X_{+}^{m})$ and ${f'}(X_{+}^{n})$ are disjoint when $f\neq {f'},f(x_{1},\ldots ,x_{m})=f'(y_{1},\ldots ,Y_{n})$ this implies $f=f'$ and $m=n$ . Being all $f\in F$ in $X_{+}^{n}$ , we must have $x_{j}=y_{j},\forall j,1\leq j\leq n$ .

Then we have $y=z=g(x_{1},\ldots ,x_{n})$ with $g=d(f)$ , displaying functionality.

Before moving further we must make use of a new lemma that determines the rules for partial functions, it may be written as:

 (3)Be  $(f_{n})_{n\geq 0}$  a sequence of partial functions  $f_{n}:A\to B$  such that  $f_{n}\subseteq f_{n+1},\forall n\geq 0$ . Then,  $g=(A,\bigcup graph(f_{n}),B)$  is a partial function. [1]

Using (3), ${\hat {h}}=\bigcup _{i\geq 0}h_{i}$ is a partial function. Since $dom({\hat {h}})=\bigcup dom(h_{i})=\bigcup X_{i}=X_{+}$ then ${\hat {h}}$ is total in $X_{+}$ .

Furthermore, it is clear from the definition of $h_{i}$ that ${\hat {h}}$ satisfies (1) and (2). To prove the uniqueness of ${\hat {h}}$ , or any other function ${h'}$ that satisfies (1) and (2), it is enough to use a simple induction that shows ${\hat {h}}$ and ${h'}$ work for $X_{i},\forall i\geq 0$ , and such is proved the Theorem of the Unique Homomorphic Extension.[2]

Example of a particular case

We can use the theorem of unique homomorphic extension for calculating numeric expressions over whole numbers. First, we must define the following:

A=\Sigma ^{*}

where

\Sigma =\mathrm {Variables} \cup \{0,1,2,\ldots ,9\}\cup \{+,-,*\}\cup \{(,)\},{\text{ where }}|*=\mathrm {Variables} \cup \{{0,\ldots ,9}\}

Be $F=\{{f-,f+,f*}\}$

$f:\Sigma ^{*}\to \Sigma _{w\mapsto {-w}}^{*}$

$f:\Sigma ^{*}x\Sigma ^{*}\to \Sigma _{w_{1},w_{2}\mapsto {w_{1}+w_{2}}}^{*}$

$f:\Sigma ^{*}x\Sigma ^{*}\to \Sigma _{w_{1},w_{2}\mapsto {w_{1}*w_{2}}}^{*}$

Be $EXPR$ he inductive closure of $X$ under $F$ and be $B=\mathbb {Z} ,G={\{Soma(-.-),Mult(-,-),Menos(-)}\}$

Be $d:F\to G$

$d({f-})=menos$

$d({f+})=mais$

$d({f*})=mult$

Then ${\hat {h}}:X_{+}\to \{{0,1}\}$ will be a function that calculates recursively the truth-value of a proposition, and in a way, will be an extension of the function $h:X\to \{{0,1}\}$ that associates a truth-value to each atomic proposition, such that: