You must study the Linear congruence theorem and the extended GCD algorithm, which belong to Number Theory, in order to understand the maths behind modulo arithmetic.

The inverse of matrix K for example is (1/det(K)) * adjoint(K), where det(K) <> 0.

I assume that you don't understand how to calculate the **1/det(K)** in modulo arithmetic and here is where linear congruences and GCD come to play.

Your K has det(K) = -121. Lets say that the modulo m is 26. We want **x***(-121) = 1 (mod 26).

**[ a = b (mod m) means that a-b = N*m]**

We can easily find that for **x=3** the above congruence is true because 26 divides (3*(-121) -1) exactly. Of course, the correct way is to use GCD in reverse to calculate the x, but I don't have time for explaining how do it. Check the extented GCD algorithm :)

Now, inv(K) = 3*([3 -8], [-17 5]) (mod 26) = ([9 -24], [-51 15]) (mod 26) = **([9 2], [1 15])**.

**Update:** check out Basics of Computational Number Theory to see how to calculate modular inverses with the Extended Euclidean algorithm. Note that `-121 mod 26 = 9`

, so for `gcd(9, 26) = 1`

we get `(-1, 3)`

.