I have $m$ points $D = \{x_1, \dots, x_m\}$ with $x_i \in \mathbb{R}^n$. After some preprocessing / building up data structures for those points, I get $T$ queries $y_i \in \mathbb{R}^n$ with $i=1, \dots, T$. Each query comes at a time and independently. The datastructures for the queries should not be modified by the past queries. After receiving an query $y_i$, the $k$ nearest neighbors
$$NN_k(y_i) \subset D \text{ with } |NN_k(y_i)| = k \text{ and }$$ $$\forall x_a \in NN_k(y_i) \forall x_b \in D \setminus NN_k(y_i) : \|x_a - y_j\|_2 \leq \|x_b - y_j\|_2$$
All points $x_i$ and all queries $y_j$ are on the unit hypersphere, so $\|x_i\|_2 = \|y_i\|_2 = 1$.
How do I process those queries fast?
Limits
To get a feeling for what matters, here are some orders of magnitude:
- $100 \leq n \leq 1000$: Dimension of points
- $m \geq 100\,000$: Candidates
- $T \geq 10\,000\,000$: Number of queries
- $3 \leq k \leq 20$: Expected number of returned points
- Reasonable memory consumption (e.g. less than 2GB for the data structure)
The query time for a single brute force approach is in $\mathcal{O}(m \cdot n)$ as it just compares every candidate point in $D$ with the query and stores the closest $k$ of them.
Misc
I've just implemented this with Python (see code).
k=5, n=128, m=100000, T=100: 0.56s per query.(Brute force approach)
That is actually much better than I expected. However, I guess this could be an order of magnitude faster with a good data structure / smarter algorithm. I wrote the Python script in a way which should make it easy to run your own experiments on your tests, if you like.
