--- title: "Prenex Normal Form - Implication Exercise" date: 2023-02-17T11:05:35-05:00 draft: false tags: - Logic math: true medium_enabled: false --- I recently read through the Wikipedia article on [Prenex Normal Form](https://en.wikipedia.org/wiki/Prenex_normal_form). It first describes the two equivalences for conjunction/disjunction. $$ (\forall x \phi) \vee \psi \iff \forall x(\phi \vee \psi) \tag{1.1} $$ $$ (\exists x \phi) \vee \psi \iff \exists x (\phi \vee \psi) \tag{1.2} $$ They show these rules similarly for conjunction. In the next section, they describe the rules for negation: $$ \neg \exists x \phi \iff \forall x \neg \phi \tag{2.1} $$ $$ \neg \forall x \phi \iff \exists x \neg \phi \tag{2.2} $$ In the third section, they describe the rules related to implication. With it comes the following quote: > These rules can be derived by [rewriting](https://en.wikipedia.org/wiki/Rewriting#Logic) the implication $\phi \implies \psi$ as $\neg \phi \vee \psi$ and applying the rules for disjunction above. This sounds like "we leave this as an exercise to the reader", and a reader I am! Let's label the rule in the quote as $0.1$. **1.** Show that $(\forall x \phi) \implies \psi$ is equivalent to $\exists x (\phi \implies \psi)$ $$ \begin{align*} (\forall x \phi) \implies \psi &\iff \neg (\forall x \phi) \vee \psi \tag{0.1} \\\\ &\iff (\exists x \neg \phi) \vee \psi \tag{2.2}\\\\ &\iff \exists x (\neg \phi \vee \psi) \tag{1.2}\\\\ &\iff \exists x (\phi \implies \psi) \tag{0.1} \end{align*} $$ **2.** Show that $(\exists x \phi) \implies \psi$ is equivalent to $\forall x (\phi \implies \psi)$ $$ \begin{align*} (\exists x \phi) \implies \psi &\iff \neg(\exists x \phi) \vee \psi \tag{0.1}\\\\ &\iff \forall x (\neg \phi) \vee \psi \tag{2.1}\\\\ &\iff \forall x (\neg \phi \vee \psi) \tag{1.1}\\\\ &\iff \forall x (\phi \implies \psi) \tag{0.1} \end{align*} $$ **3.** Show that $\phi \implies (\exists x \psi)$ is equivalent to $\exists x (\phi \implies \psi)$ $$ \begin{align*} \phi \implies (\exists x \psi) &\iff \neg \phi \vee (\exists x \psi) \tag{0.1}\\\\ &\iff (\exists x \psi) \vee \neg \phi \tag{symmetry}\\\\ &\iff \exists x (\psi \vee \neg \phi) \tag{1.2}\\\\ &\iff \exists x (\neg \phi \vee \psi) \tag{symmetry}\\\\ &\iff \exists x (\phi \implies \psi) \tag{0.1} \end{align*} $$ **4.** Show that $\phi \implies (\forall x \psi)$ is equivalent to $\forall x (\phi \implies \psi)$ $$ \begin{align*} \phi \implies (\forall x \psi) &\iff \neg \phi \vee (\forall x \psi) \tag{0.1}\\\\ &\iff \forall x(\psi) \vee \neg \phi \tag{symmetry} \\\\ &\iff \forall x (\psi \vee \neg \phi) \tag{1.1}\\\\ &\iff \forall x (\neg \phi \vee \psi) \tag{symmetry} \\\\ &\iff \forall x (\phi \implies \psi) \tag{0.1} \end{align*} $$