The fundamental group of an arcwise-connected set 
is the group formed by the sets of equivalence
classes of the set of all loops, i.e., paths with initial
and final points at a given basepoint 
, under the equivalence
relation of homotopy. The identity
element of this group is the set of all paths homotopic
to the degenerate path consisting of the point 
. The fundamental groups of homeomorphic
spaces are isomorphic. In fact, the fundamental group
only depends on the homotopy type of 
. The fundamental group of a topological
space was introduced by Poincaré (Munkres 1993, p. 1).
The following is a table of the fundamental group for some common spaces 
, where 
denotes the fundamental group, 
is the first integral
homology group, 
denotes the group direct product, 
denotes the free product,
denotes the ring of integers, and 
is the cyclic group of order
.
space ( ) | symbol |  |  |
| circle |  |  |  |
| complex projective space |  | 0 | 0 |
| figure eight |  |  | |
| Klein bottle |  |  | |
 -torus |  |  |  |
| real projective plane |  |  |  |
| sphere |  | 0 | 0 |
The group product 
of loop 
and loop 
is given by the path of 
followed by the path of 
. The identity element is represented by the constant path,
and the inverse of 
is given by traversing 
in the opposite direction. The fundamental group is independent
of the choice of basepoint because any loop through 
is homotopic to a loop through
any other point 
.
So it makes sense to say the "fundamental group of 
."
The diagram above shows that a loop followed by the opposite loop is homotopic to the constant loop, i.e., the identity. That is, it starts by traversing the path
,
and then turns around and goes the other way, 
. The composition is deformed, or homotoped, to the constant
path, along the original path 
.
A space with a trivial fundamental group (i.e., every loop is homotopic to the constant loop), is called simply connected. For instance,
any contractible space, like Euclidean
space, is simply connected. The sphere is simply
connected, but not contractible. By definition,
the universal cover 
is simply connected, and loops in 
lift to paths in 
. The lifted paths in the universal cover define the deck
transformations, which form a group isomorphic to the
fundamental group.
The underlying set of the fundamental group of 
is the set of based homotopy
classes from the circle to 
, denoted ![[S^1,X]](/images/equations/FundamentalGroup/Inline50.svg)
. For general spaces 
and 
, there is no natural group structure on ![[X,Y]](/images/equations/FundamentalGroup/Inline53.svg)
, but when there is, 
is called a co-H-space. Besides
the circle, every sphere 
is a co-H-space,
defining the homotopy groups. In general, the fundamental
group is non-Abelian. However, the higher homotopy
groups are Abelian. In some special cases, the fundamental group is Abelian.
For example, the animation above shows that 
in the torus. The red path
goes before the blue path. The animation is a homotopy between the loop that goes
around the inside first and the loop that goes around the outside first.
Since the first integral homology 
of 
is also represented by loops, which are the only one-dimensional
objects with no boundary, there is a group homomorphism
 |
which is surjective. In fact, the group kernel of 
is the commutator subgroup and 
is called Abelianization.
The fundamental group of 
can be computed using van
Kampen's theorem, when 
can be written as a union 
of spaces whose fundamental groups are known.
When 
is a continuous map, then the fundamental group pushes forward. That is, there is
a map 
defined by taking the image of loops from 
. The pushforward map is
natural, i.e., 
whenever the composition of two maps is defined.
