You can easily derive induction principles from the functions `div2`

and `mod2`

like so:

```
Functional Scheme div2_ind := Induction for div2 Sort Prop.
Functional Scheme mod2_ind := Induction for mod2 Sort Prop.
```

`div2_ind`

and `mod2_ind`

have more or less types:

```
forall P1,
P1 0 0 ->
P1 1 0 ->
(forall n1, P1 n1 (div2 n1) -> P1 (S (S n1)) (S (div2 n1))) ->
forall n1, P1 n1 (div2 n1)
forall P1,
P1 0 0 ->
P1 1 1 ->
(forall n1, P1 n1 (mod2 n1) -> P1 (S (S n1)) (mod2 n1)) ->
forall n1, P1 n1 (mod2 n1)
```

To apply these theorems you can conveniently write `functional induction (div2 n)`

or `functional induction (mod2 n)`

where you might usually write `induction n`

.

But a stronger induction principle is associated with these functions:

```
Lemma nat_ind_alt : forall P1 : nat -> Prop,
P1 0 ->
P1 1 ->
(forall n1, P1 n1 -> P1 (S (S n1))) ->
forall n1, P1 n1.
Proof.
intros P1 H1 H2 H3. induction n1 as [[| [| n1]] H4] using lt_wf_ind.
info_auto.
info_auto.
info_auto.
Qed.
```

In fact, the domain of any function is a clue to a useful induction principle. For example, the induction principle associated to the domain of the functions `plus : nat -> nat -> nat`

and `mult : nat -> nat -> nat`

is just structural induction. Which makes me wonder why `Functional Scheme`

doesn't just generate these more general principles instead.

In any case, the proofs of your theorems then become:

```
Lemma div2_eq : forall n, 2 * div2 n + mod2 n = n.
Proof.
induction n as [| | n1 H1] using nat_ind_alt.
simpl in *. omega.
simpl in *. omega.
simpl in *. omega.
Qed.
Lemma div2_le : forall n, div2 n <= n.
Proof.
induction n as [| | n1 H1] using nat_ind_alt.
simpl. omega.
simpl. omega.
simpl. omega.
Qed.
```

You should familiarize yourself with functional induction, but more importantly, you should really familiarize yourself with well-founded induction.