\section{Structures} \definition{} A \textit{universe} is a set of meaningless objects. Here are a few examples: \begin{itemize} \item $\{a, b, ..., z\}$ \item $\{0, 1\}$ \item $\mathbb{Z}$, $\mathbb{R}$, etc. \end{itemize} \definition{} A \textit{structure} consists of a universe $U$ and a set of symbols. \par A structure's symbols give meaning to the objects in its universe. \vspace{2mm} Symbols generally come in three types: \begin{itemize} \item Constant symbols, which let us specify specific elements of our universe. \par Examples: $0, 1, \frac{1}{2}, \pi$ \vspace{2mm} \item Function symbols, which let us navigate between elements of our universe. \par Examples: $+, \times, \sin{x}, \sqrt{x}$ \vspace{2mm} \item Relation symbols, which let us compare elements of our universe. \par Examples: $<, >, \leq, \geq$ \par \vspace{2mm} \end{itemize} The equality check $=$ is \textbf{not} a relation symbol. It is included in every structure by default. \vspace{3mm} \example{} The first structure we'll look at is the following: $$ \Bigl( \mathbb{Z} ~\big|~ \{0, 1, +, -, <\} \Bigr) $$ \vspace{2mm} This is a structure with the universe $\mathbb{Z}$ that contains the following symbols: \begin{itemize} \item Constants: \tab $\{0, 1\}$ \item Functions: \tab $\{+, -\}$ \item Relations: \tab $\{<\}$ \end{itemize} \vspace{2mm} If you look at our set of constant symbols, you'll see that the only integers we can directly refer to in this structure are 0 and 1. If we want any others, we must define them using the tools the structure offers. \vspace{1mm} Say we want the number 2. We could use the function $+$ to define it: $2 \coloneqq [x \text{ where } 1 + 1 = x]$ \par We would write this as $2 \coloneqq [x \text{ where } +(1, 1) = x]$ in proper \say{functional} notation. \problem{} Can we define $-1$ in $\Bigl( \mathbb{Z} ~\big|~ \{0, 1, +, -, <\} \Bigr)$? If so, how? \vfill \problem{} Can we define $-1$ in $\Bigl( \mathbb{Z} ~\big|~ \{0, +, -, <\} \Bigr)$? \par \hint{In this problem, $1$ has been removed from the set of constant symbols.} \vfill \pagebreak Let us formalize what we found in the previous two problems. \par \definition{} A \textit{formula} in a structure $S$ is a well-formed string of constants, functions, and relations. \par \vspace{2mm} You already know what a \say{well-formed} string is: $1 + 1$ is fine, $\sqrt{+}$ is nonsense. \par For the sake of time, I will not provide a formal definition. It isn't particularly interesting. \vspace{2mm} A formula can contain one or more \textit{free variables.} These are denoted $\varphi{(a, b, ...)}$. \par Formulas with free variables let us define \say{properties} that certain objects have. \par For example, $x$ is a free variable in the formula $\varphi(x) = x > 0$. \par $\varphi(3)$ is true and $\varphi(-3)$ is false. \definition{Definable Elements} Say $S$ is a structure with a universe $U$. \par We say an element $e \in U$ is \textit{definable in $S$} if we can write a formula that only $e$ satisfies. \problem{} Can we define 2 in the structure $\Bigl( \mathbb{Z^+} ~\big|~ \{4, \times \} \Bigr)$? \par \hint{$\mathbb{Z}^+ = \{1, 2, 3, ...\}$. Also, $2 \times 2 = 4$.} \begin{solution} $2$ is the only element in $\mathbb{Z}^+$ that satisfies $[x \text{ where } x \times x = 4]$. \end{solution} \vfill \problem{} Try to define 2 in the structure $\Bigl( \mathbb{Z} ~\big|~ \{4, \times \} \Bigr)$. \begin{solution} This isn't possible. We could try $[x \text{ where } x \times x = 4]$, but this is satisfied by both $2$ and $-2$. \\ We have no way to distinguish between negative and positive numbers. \begin{instructornote} Actually, it is. Bonus problem: how? \par Do this after understanding quantifiers. \end{instructornote} \end{solution} \vfill \problem{} What numbers are definable in the structure $\Bigl( \mathbb{R}^+_0 ~\big|~ \{1, 2, \div \} \Bigr)$? \begin{solution} We can define powers of two, positive and negative. If you're clever, you can define many more: $\sqrt{2}, \sqrt[3]{2}, ...$. \end{solution} \vfill \pagebreak