First, we need to determine the identity elements of the
groups G and G'.
One of the four axioms of the group is the
identity.
A group must have an identity element, such
as:
x*e = e*x = x
We'll
determine the identity element for G:
x*e = xe - 2x - 2e +
6
But x*e = x => xe - 2x - 2e + 6 =
x
We'll move all elements that do not contain x, to the
right:
e(x-2) = 2x + x +
6
e(x-2) = 3x - 6
e(x-2) =
3(x-2)
e = 3
We'll determine
the identity element for G':
xoe' =
x
xe' - 3x - 3e' + 12 =
x
We'll move all elements that do not contain x, to the
right:
e'(x-3) = 4x -
12
e'(x-3) = 4(x-3)
e' =
4
If f is isomorphism of groups G and G', then f(3) =
4
f(3) = 3 + a => 3 + a = 4 => a =
1
The function f(x) is f(x) = x +
1.
We'll prove that f is morphism of
groups:
f(x*y) =
f(x)of(y)
f(x*y) = x*y + 1 = xy - 2x - 2y + 7
(1)
f(x)of(y) = (x+1)o(y+1) = (x+1)(y+1) - 3(x+1) - 3(y+1)
+ 12
f(x)of(y) = xy - 2x - 2y + 7
(2)
We notice that (1) = (2) => f(x*y) =
f(x)of(y)
Now, we have to prove that f is bijective, to
verify if f is isomorphism of G and G'.
We'll verify if
f(x) is one to one function:
f(x) = f(y) <=>
x + 1 = y + 1 => x = y => f(x) is one to one function
(3)
We'll verify if f(x) is on to
function:
For any y that belongs to G', there is an x that
belongs to G, such as f(x) = y.
x + 1 = y <=>
x = y - 1
But x>2 => y - 1 > 2
=> y > 3,true => f(x) is on to function
(4)
From (3) and (4) => f(x) is bijective
function.
Since f(x) = x + 1 is a morphism of
G and G' and it is also a bijective function, then f:(2,+inf.)->(3,+inf.) is an
isomorphism of groups G and G'.
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