vela said:It's not enough to say there are four elements in G to prove that there is a subgroup of order 4. (Plus since a2=b2=e, you've only shown there are three elements in G.) Think about what "subgroup of order 4" means. What do you need to show to say that a subset of G is a subgroup of G and that its order is 4?
snipez90 said:Again, you have to be careful here. If a^2 = e, what does this tell you about a^-1 (Hint: multiply both sides of the equation by a^-1)?
vela said:Suppose H is a subgroup that includes a and b. What other elements have to be in H?
Why not?188818881888 said:that means a= a inverse which is not true
vela said:Why not?
An Abelian group, also known as a commutative group, is a mathematical structure consisting of a set of elements and a binary operation that satisfies the commutative property, meaning that the order of the elements does not affect the outcome of the operation.
An Abelian group with 2 elements of order 2 is a special type of group that has only two elements, both of which have an order of 2 (meaning that when the element is multiplied by itself twice, the result is the identity element). This type of group is important in abstract algebra and can be used to prove various theorems and properties.
To prove that an Abelian group with 2 elements of order 2 has a subgroup of order 4, you can use the subgroup criterion, which states that for a subset of a group to be a subgroup, it must contain the identity element, be closed under the group operation, and contain the inverse of each of its elements. By constructing a subset with these properties, you can prove that it is a subgroup of the original group with an order of 4.
Yes, this proof can be applied to all Abelian groups. The subgroup criterion is a general method for proving the existence of subgroups in any group, and an Abelian group with 2 elements of order 2 is a specific type of group that can be used to demonstrate this method.
This theorem has applications in many fields, including cryptography, coding theory, and physics. In cryptography, it can be used to prove the security of certain encryption algorithms. In coding theory, it can be used to construct error-correcting codes. In physics, it can be used to study symmetries and conservation laws in systems with discrete elements.