# Accessing first element of a matrix in Isabelle

Accessing the “first” element of a matrix

I want to write a proof about a trivial case of the determinant of a matrix, where the matrix consists of just a single element (i.e., the cardinality of `'n` is one).

Thus the determinant (or `det A`) is the single element in the matrix.

However, it is not clear to me how to reference the single element of the matrix. I tried `A \$ zero \$ zero`, which did not work.

My current way to demonstrate the problem is to write `∀a∈(UNIV :: 'n set). det A = A \$ a \$ a`. It assumes that the cardinality of the numeral type is one.

What is the correct way to write this trivial proof about determinants?

Here is my current code:

``````theory Notepad
imports
Main
"~~/src/HOL/Library/Polynomial"
"~~/src/HOL/Algebra/Ring"
"~~/src/HOL/Library/Numeral_Type"
"~~/src/HOL/Library/Permutations"
"~~/src/HOL/Multivariate_Analysis/Determinants"
"~~/src/HOL/Multivariate_Analysis/L2_Norm"
"~~/src/HOL/Library/Numeral_Type"
begin

lemma det_one_element_matrix:
fixes A :: "('a::comm_ring_1)^'n∷finite^'n∷finite"
assumes "card(UNIV :: 'n set) = 1"
shows "∀a∈(UNIV :: 'n set). det A = A \$ a \$ a"
proof-

(*sledgehammer proof of 1, 2 and ?thesis *)
have 1: "∀a∈(UNIV :: 'n set). UNIV = {a}"
by (metis (full_types) Set.set_insert UNIV_I assms card_1_exists ex_in_conv)

have 2:
"det A = (∏i∈UNIV. A \$ i \$ i)"
by (metis (mono_tags, lifting) "1" UNIV_I det_diagonal singletonD)

from 1 2 show ?thesis by (metis setprod_singleton)

qed
``````

UPDATE:

Unfortunately, this is part of a larger theorem which is already proven for the cardinality of `'n∷finite` > 1. In this theorem the type of matrix A is fixed as `A :: "('a::comm_ring_1)^'n∷finite^'n∷finite` and the definition of the determinant is used in this larger theorem.

Therefore, I don't think I can change the type of my matrix A to `('a::comm_ring_1)^1^1)` in oder to solve my larger theorem.

-

I feel that my previous answer is the better solution in general if it is possible to use, so I will leave it as-is. In your case where you are not able to use this approach, things get a little harder, unfortunately.

What you need to show is that:

• There can only be a single element in your type `'n`, and thus every element is equal;

• Additionally, the definition of `det` also references permutations, so we need to show that there only exists a single function of type `'n ⇒ 'n`, which happens to be equal to the function `id`.

With these in place, we can carry out the proof as follows:

``````lemma det_one_element_matrix:
fixes A :: "('a::comm_ring_1)^'n∷finite^'n∷finite"
assumes "card(UNIV :: 'n set) = 1"
shows "det A = A \$ x \$ x"
proof-
have 0: "⋀x y. (x :: 'n) = y"
by (metis (full_types) UNIV_I assms card_1_exists)

hence 1: "(UNIV :: 'n set) = {x}"
by auto

have 2: "(UNIV :: ('n ⇒ 'n) set) = {id}"
by (auto intro!: ext simp: 0)

thus ?thesis
by (auto simp: det_def permutes_def 0 1 2 sign_id)
qed
``````
-

Using `A \$ zero \$ zero` (or `A \$ 0 \$ 0`) wouldn't have worked, because the vectors are indexed from 1: `A \$ 0 \$ 0` is undefined, which makes it hard to prove anything about.

Playing a little myself, I came up with the following lemma:

``````lemma det_one_element_matrix:
"det (A :: ('a::comm_ring_1)^1^1) = A \$ 1 \$ 1"
by (clarsimp simp: det_def sign_def)
``````

Instead of using a type `'a :: finite` and assuming it has cardinality 1, I used the standard Isabelle `1` type which encodes both these facts into the type itself. (Similar types exist for all numerals, so you can write things like `'a ^ 23 ^ 72`)

Incidentally, after typing in the lemma above, `auto solve_direct` quickly informed me that something already exists in the library stating the same result, a lemma named `det_1`.

-
I added the following update to my question: Unfortunately, this is part of a larger theorem which is already proven for the cardinality of 'n∷finite > 1. In this theorem the type of matrix A is fixed as A :: "('a::comm_ring_1)^'n∷finite^'n∷finite and the definition of the determinant is used in this larger theorem. Therefore I don't think I can change type of my matrix A to ('a::comm_ring_1)^1^1) in oder to solve my larger theorem. – mrsteve Mar 24 '14 at 19:15