Group theory
branch of mathematics that studies the algebraic properties of groups From Wikipedia, the free encyclopedia
branch of mathematics that studies the algebraic properties of groups From Wikipedia, the free encyclopedia
In mathematics and abstract algebra, group theory studies a type of algebraic structure called a group. Group theory is often used in mathematics as a starting point for the study of many algebraic structures, such as a set of numbers along with its addition and multiplication. Because group theory is also useful for studying symmetry in nature and abstract systems, it has many applications in physics and chemistry.
A group is a set (collection) G whose members are called elements. The elements can be numbers of some kind, or other abstract objects. The elements can even be material objects. There is also a binary operation which combines any two elements of G and results in another element of G. This new element may be different from either of the original two, but it does not have to be: it only has to be an element of G. To be a group, the following four conditions must be true of G and the operation defined over G:
e • a = a • e = a holds.
An important property about groups is whether the order of the elements matters when two elements are combined using the operation. Switching the order of two combined elements typically gives a different result. This means that we have many cases with a • b ≠ b • a. However, if the order of a and b actually does not matter (for any a and b, we always have a • b = b • a), then the group is called an abelian group (or commutative group).[2]
If a group contains finitely many elements, then it is called a finite group. If a subset of a group is also a group, then the subset is called a subgroup.[3]
A simple example of a group is the set of integers (called Z) with the addition operator +. This group is called G = (Z, +). Each of the required conditions is true of G, so G is a group. If we replace • with the + sign, then we can easily check that these conditions are true:
The addition operator is also commutative: the order of a and b does not matter. For any two integers a and b in G, a + b = b + a. For example, 7+3 is the same as 3+7. Thus, G is also an abelian group.
Commutative operators are common in our daily lives. For example, 7 · 3 is also the same as 3 · 7. However, not all operations are commutative. For example, 7÷3 is different from 3÷7 (and neither of these results is an integer), and 73 is different from 37. Therefore, not all combinations of number sets and mathematical operations can form an abelian group—or even a group at all.
Seamless Wikipedia browsing. On steroids.
Every time you click a link to Wikipedia, Wiktionary or Wikiquote in your browser's search results, it will show the modern Wikiwand interface.
Wikiwand extension is a five stars, simple, with minimum permission required to keep your browsing private, safe and transparent.