+theorem le_n_fn: \forall f:nat \to nat. (increasing f)
+\to \forall n:nat. n \le (f n).
+intros.elim n.
+apply le_O_n.
+apply (trans_le ? (S (f n1))).
+apply le_S_S.apply H1.
+simplify in H. unfold increasing in H.unfold lt in H.apply H.
+qed.
+
+theorem increasing_to_le: \forall f:nat \to nat. (increasing f)
+\to \forall m:nat. \exists i. m \le (f i).
+intros.elim m.
+apply (ex_intro ? ? O).apply le_O_n.
+elim H1.
+apply (ex_intro ? ? (S a)).
+apply (trans_le ? (S (f a))).
+apply le_S_S.assumption.
+simplify in H.unfold increasing in H.unfold lt in H.
+apply H.
+qed.
+
+theorem increasing_to_le2: \forall f:nat \to nat. (increasing f)
+\to \forall m:nat. (f O) \le m \to
+\exists i. (f i) \le m \land m <(f (S i)).
+intros.elim H1.
+apply (ex_intro ? ? O).
+split.apply le_n.apply H.
+elim H3.elim H4.
+cut ((S n1) < (f (S a)) \lor (S n1) = (f (S a))).
+elim Hcut.
+apply (ex_intro ? ? a).
+split.apply le_S. assumption.assumption.
+apply (ex_intro ? ? (S a)).
+split.rewrite < H7.apply le_n.
+rewrite > H7.
+apply H.
+apply le_to_or_lt_eq.apply H6.
+qed.