# Degree of polynomial smaller than a number

I am working on a lemma that shows that the degree of a sum of monomials is always less or equal to `n` if the exponent of each monomial is less or equal to `n`.

``````lemma degree_poly_smaller:
fixes a :: "('a::comm_ring_1 poly)" and n::nat
shows "degree (∑x∷nat | x ≤ n . monom (coeff a x) x) ≤ n"
sorry
``````

What I have to so far is the following (please mind that I am a beginner in Isabelle):

``````lemma degree_smaller:
fixes a :: "('a::comm_ring_1 poly)" and n::nat
shows "degree (∑x∷nat | x ≤ n . monom (coeff a x) x) ≤ n"
proof-

have th01: "⋀k. k ≤ n ⟹
degree (setsum (λ x . monom (coeff a x) k) {x∷nat. x ≤ n})  ≤ n"
by (metis degree_monom_le monom_setsum order_trans)

have min_lemma1: "k∈{x∷nat. x ≤ n} ⟹ k ≤ n" by simp

from this th01 have th02:
"⋀k. k∈{x∷nat. x ≤ n} ⟹
degree (setsum (λ x . monom (coeff a x) k) {x∷nat. x ≤ n})  ≤ n"
by (metis mem_Collect_eq)

have min_lemma2: "(SOME y . y ≤ n) ≤ n" by (metis (full_types) le0 some_eq_ex)

from this have th03:
"degree (∑x∷nat | x ≤ n . monom (coeff a x) (SOME y . y ≤ n)) ≤ n"
by (metis th01)

from min_lemma1 min_lemma2 have min_lemma3:
"(SOME y . y∈{x∷nat. x ≤ n}) ≤ n" by (metis (full_types) mem_Collect_eq some_eq_ex)

from this th01 th02 th03 have th04:
"degree (∑x∷nat | x ≤ n . monom (coeff a x) (SOME y . y∈{x∷nat. x ≤ n}) ) ≤ n"
by presburger
``````

Here is the problem, I don't understand why the following lemma is not sufficient to finish the proof. In particular, I would expect the last part (where the sorry is) to be simple enough for sledgehammer to find a proof:

`````` from this th01 th02 th03 th04  have th05:
"degree
(setsum (λ i . monom (coeff a i) (SOME y . y∈{x∷nat. x ≤ n})) {x∷nat. x ≤ n})
≤ n"
by linarith

(* how can I prove this last step ? *)
from this have
"degree (setsum (λ i . monom (coeff a i) i) {x∷nat. x ≤ n}) ≤ n" sorry

from this show ?thesis by auto
qed
``````

.
SOLUTION from Brian Huffman's excellent answer:
.

``````lemma degree_setsum_smaller:
"finite A ⟹ ∀x∈A. degree (f x) ≤ n ⟹ degree (∑x∈A. f x) ≤ n"
apply(induct rule: finite_induct)
apply(auto)

lemma finiteSetSmallerThanNumber:
"finite {x∷nat. x ≤ n}"
by (metis finite_Collect_le_nat)

lemma degree_smaller:
fixes a :: "('a::comm_ring_1 poly)" and n::nat
shows "degree (∑x∷nat | x ≤ n . monom (coeff a x) x) ≤ n"
apply (rule degree_setsum_smaller)
by (metis degree_0 degree_monom_eq le0 mem_Collect_eq monom_eq_0_iff) (* from sledgehammer *)
``````
-

The last step does not follow from your `th05`. The problem is that you seem to want to unify `(SOME y. y∈{x∷nat. x ≤ n})` with the bound variable `i`. However, in HOL `(SOME y. y∈{x∷nat. x ≤ n})` has a single value that depends only on `n` and not on `i`. Furthermore, you don't get to choose the value; a theorem using `SOME` is not the same as a theorem with a universally quantified variable.

My advice is to avoid using `SOME` altogether, and instead try to prove a generalization of your theorem first:

``````lemma degree_setsum_smaller:
"finite A ⟹ ∀x∈A. degree (f x) ≤ n ⟹ degree (∑x∈A. f x) ≤ n"
``````

You should be able to prove `degree_setsum_smaller` by induction over `A` (use `induct rule: finite_induct`), and then use it to prove `degree_poly_smaller`. Lemma `degree_add_le` from the polynomial library should be useful.

-
I see that the generalized version can be proofed easily; but I don't yet see how I can proof degree_poly_smaller from it. – mrsteve Sep 13 '13 at 3:43
Start the proof of degree_poly_smaller with `apply (rule degree_setsum_smaller)`, and then see if you can prove the remaining goals (maybe with the help of `auto` and/or `sledgehammer`). – Brian Huffman Sep 13 '13 at 18:33
Thank you very much for your answer. It saved me a lot of work hours as I now often apply the principle of first proving an abstract lemma. all the best! – mrsteve Sep 15 '13 at 22:43

It is generally considered bad style to use auto as anything other than the last method in an apply script, because such proofs tend to be quite fragile. I would eliminate the "finiteSetSmallerThanNumber" lemma completely, it is a needlessly specific special case of Collect_le_nat. Also, camel case names for theorems are usually not used in Isabelle.

At any rate, this is my suggestion of how to make the proofs nicer:

``````lemma degree_setsum_smaller:
"finite A ⟹ ∀x∈A. degree (f x) ≤ n ⟹ degree (∑x∈A. f x) ≤ n"

lemma degree_smaller:
fixes a :: "('a::comm_ring_1 poly)" and n::nat
shows "degree (∑x∷nat | x ≤ n . monom (coeff a x) x) ≤ n"
proof (rule degree_setsum_smaller)
show "finite {x. x ≤ n}" using finite_Collect_le_nat .
{
fix x assume "x ≤ n"
hence "degree (monom (coeff a x) x) ≤ n"
by (cases "coeff a x = 0", simp_all add: degree_monom_eq)
}
thus "∀x∈{x. x≤ n}. degree (monom (coeff a x) x) ≤ n" by simp
qed
``````
-