Given a closed manifold $M$ and an integer $k\geq 0$, let $G_k(M)$ denote the space of smooth functions $f:M\to\mathbb R$ with at most $k$ critical points.
To what extend has the topology of the spaces $G_k(M)$ been studied?
Obviously, a complete understanding of the topology of $G_k(M)$ in general seems hopeless, but that does not mean there aren't interesting things to be said.
Some things I know already:
- The smallest $k$ for which $G_k(M)$ is non-empty is called the Lusternik--Schnirelman category of $M$. Obviously, constructing functions with few critical points is important in topology, e.g. for proving the h-cobordism theorem.
- The space of functions on $N\times[0,1]$ which have no critical points and which are standard near the boundary is a main object of study in the theory of pseudo-isotopies. (This space isn't exactly of the form $G_k(M)$, but seems close enough to include on this list.)
- The spaces $G_{2n}(S^1)$ and $G_{2n+1}(S^1)$ are homotopy equivalent to $S^{2n-1}$ (proved using the heat equation, which is apparently useless once $\dim M\geq 2$).
- There is a natural map $S^n\to G_2(S^n)$ which associates to a given vector $\mathbf v$ the function $\mathbf w\mapsto\mathbf w\cdot\mathbf v$ on the unit sphere $S^n$ in $\mathbb R^{n+1}$. This element of $\pi_n(G_2(S^n))$ becomes trivial in $G_{2n+2}(S^n)$, and I would conjecture this is sharp (i.e. it is non-trivial in $G_{2n+1}(S^n)$). This conjecture is proven for $n\leq 3$ in [1], and I believe the methods used there can also be used to treat the case $n=4$.
