See A008949"Triangle of partial sums of binomial coefficients."
$T(n,k) = \sum_{i-0}^k {N\choose i}$ is the maximal number of regions into which $n$ hyperplanes of co-dimension $1$ divide $\mathbb R^k$ (the Cake-Without-Icing numbers)
$2 ~T(n-1,k-1)$ is the number of orthants intersecting a generic linear subspace of $\mathbb R^n$ of dimension $k$. This tells you the probability if you choose $a$ independent random points on the unit sphere in $\mathbb R^d$, the probability that the origin is contained in the convex hull is $T(a-1,a-d-1)/2^{a-1}$. Complementarily, no hemisphere contains all of the points. The null space of the map by linear combinations of the points $\mathbb R^a \to \mathbb R^d$ generically has a kernel of dimension $a-d$, and this intersects the positive orthant iff $0$ is a convex hull of the points. By symmetry, all orthants are equally likely.