I was trying to code into Coq logical connectives encoded in lambda calculus with type à la System F. Here is the bunch of code I wrote (standard things, I think)
Definition True := forall X: Prop, X -> X. Lemma I: True. Proof. unfold True. intros. apply H. Qed. Section s. Variables A B: Prop. (* conjunction *) Definition and := forall X: Prop, (A -> B -> X) -> X. Infix "/\" := and. Lemma and_intro: A -> B -> A/\B. Proof. intros HA HB. split. apply HA. apply HB. Qed. Lemma and_elim_l: A/\B -> A. Proof. intros H. destruct H as [HA HB]. apply HA. Qed. Lemma and_elim_r: A/\B -> B. Proof. intros H. destruct H as [HA HB]. apply HB. Qed. (* disjunction *) Definition or := forall X:Prop, (A -> X) -> (B -> X) -> X. Infix "\/" := or. Lemma or_intro_l: A -> A\/B. intros HA. left. apply HA. Qed. Lemma or_elim: forall C:Prop, A \/ B -> (A -> C) -> (B -> C) -> C. Proof. intros C HOR HAC HBC. destruct HOR. apply (HAC H). apply (HBC H). Qed. (* falsity *) Definition False := forall Y:Prop, Y. Lemma false_elim: False -> A. Proof. unfold False. intros. apply (H A). Qed. End s.
Basically, I wrote down the elimination and introduction laws for conjunction, disjunction, true and false. I am not sure of having done thing correctly, but I think that things should work that way. Now I would like to define the existential quantification, but I have no idea of how to proceed. Does anyone have a suggestion?