Homotopy of real projective space

Statement

This article describes the homotopy groups of the real projective space. This includes the set of path components $\pi _{0}$ , the fundamental group $\pi _{1}$ , and all the higher homotopy groups.

The case $n=0$

The space $\mathbb {P} ^{0}(\mathbb {R} )$ is a one-point space and all its homotopy groups are trivial groups, and the set of path components is a one-point space.

The case $n=1$ =

In the case $n=1$ we get $\mathbb {P} ^{1}(\mathbb {R} )$ is homeomorphic to the circle $S^{1}$ . We have $\pi _{0}(S^{1})$ is the one-point space (the trivial group), $\pi _{1}(S^{1})\cong \mathbb {Z}$ is the group of integers, and $\pi _{k}(S^{1})$ is the trivial group.

The case of higher $n$

For $n>1$ , $\mathbb {P} ^{n}(\mathbb {R} )$ has the $n$ -sphere $S^{n}$ as its double cover and universal cover. In particular, $\pi _{k}(\mathbb {P} ^{n}(\mathbb {R} ))\cong \pi _{k}(S^{n})$ for $k>1$ and $\pi _{1}(\mathbb {P} ^{n}(\mathbb {R} )\cong \mathbb {Z} /2\mathbb {Z} )$ . Hence:

$\pi _{0}(\mathbb {P} ^{n}(\mathbb {R} ))$ is the one-point space.
$\pi _{1}(\mathbb {P} ^{n}(R))$ is the cyclic group:Z2, i.e., $\mathbb {Z} /2\mathbb {Z}$ .
$\pi _{k}(\mathbb {P} ^{n}(\mathbb {R} ))$ is the trivial group for $1<k<n$ .
$\pi _{n}(\mathbb {P} ^{n}(\mathbb {R} ))$ is isomorphic to $\mathbb {Z}$ , the group of integers.
$\pi _{2n-1}(\mathbb {P} ^{n}(\mathbb {R} ))$ is isomorphic to $\mathbb {Z}$ , the group of integers.
$\pi _{k}(\mathbb {P} ^{n}(\mathbb {R} ))\cong \pi _{k}(S^{n})$ is a finite group for $k>n,k\neq 2n-1$ .

Statement

The case n = 0 {\displaystyle n=0}

The case n = 1 {\displaystyle n=1} =

The case of higher n {\displaystyle n}

The case $n=0$

The case $n=1$ =

The case of higher $n$