As I understand it, matrices in Isabelle are essentially functions and of abitrary dimension. In this setting, it is not easy to define a squared matrix (*n* x *n* matrix). Also, in a proof on paper the dimension "n" of a squared can be used in the proof. But how do I do that in Isabelle?

Leibniz Formula:

My proof on paper:

Here is a relevant excerpt of my Isabelle proof:

```
(* tested with Isabelle2013-2 (and also Isabelle2013-1) *)
theory Notepad
imports
Main
"~~/src/HOL/Library/Polynomial"
"~~/src/HOL/Multivariate_Analysis/Determinants"
begin
notepad
begin
fix C :: "('a::comm_ring_1 poly)^'n∷finite^'n∷finite"
(* Definition Determinant (from the HOL Library, shown for reference
see: "~~/src/HOL/Multivariate_Analysis/Determinants") *)
have "det C =
setsum (λp. of_int (sign p) *
setprod (λi. C$i$p i) (UNIV :: 'n set))
{p. p permutes (UNIV :: 'n set)}" unfolding det_def by simp
(* assumtions *)
have 1: "∀ i j. degree (C $ i $ j) ≤ 1" sorry (* from assumtions, not shown *)
have 2: "∀ i. degree (C $ i $ i) = 1" sorry (* from assumtions, not shown *)
(* don't have "n", that is the dimension of the squared matrix *)
have "∀p∈{p. p permutes (UNIV :: 'n set)}. degree (setprod (λi. C$i$p i) (UNIV :: 'n set)) ≤ n" sorry (* no n! *)
end
```

What can I do in this situation?

**UPDATE:**

Your type for C, a restricted version of ('a ^ 'n ^ 'n), appears to be a custom type of > yours, because I get an error when trying to use it, even after importing > Polynomial.thy. But maybe it's defined in some other HOL theory.

Unfortunately I did not write the includes in my code example, please see the updated example. But it is not a custom type, importing "Polynomial.thy" and "Determinants" should be sufficient. (I tested Isabelle version 2013-1 and 2013-2.)

If you're using a custom definition of a matrix, there's a good chance you're on your own, for the most part.

I don't belive I am using a custom definition of a matrix.
The library `Determinants`

(~~/src/HOL/Multivariate_Analysis/Determinants) has the following definition of a determinant:

`definition det:: "'a::comm_ring_1^'n^'n ⇒ 'a" where ...`

. So the library uses the notion of a matrix as a vector of vectors. If my ring is over polynomials it should not make a difference in my eyes.

Regardless, for a type such as ('a ^ 'n ^ 'n), it seems to me, you should be able to write a function to return a value for the size of the matrix. So if (p ^ n ^ n) is a matrix, where n is a set, then maybe the cardinality of n is the n you want in your question.

This brought me on the right way. My current guess is that the following definition is helpful:

```
definition card_diagonal :: "('a::zero poly)^'n^'n ⇒ nat" where "card_diagonal A = card { (A $ i $ i) | i . True }"
```

`card`

is definied in `Finite_Set`

.