Comparison Based Nearest Neighbor Search
This addresses a practical challenge for machine learning applications where exact distances are inaccessible, offering a competitive method with fewer comparisons than existing approaches.
The paper tackles the problem of nearest neighbor search when only relative distance comparisons are available, proving that under certain expansion conditions, a comparison tree algorithm achieves logarithmic height and efficient search with a bounded failure probability for returning the true nearest neighbor.
We consider machine learning in a comparison-based setting where we are given a set of points in a metric space, but we have no access to the actual distances between the points. Instead, we can only ask an oracle whether the distance between two points $i$ and $j$ is smaller than the distance between the points $i$ and $k$. We are concerned with data structures and algorithms to find nearest neighbors based on such comparisons. We focus on a simple yet effective algorithm that recursively splits the space by first selecting two random pivot points and then assigning all other points to the closer of the two (comparison tree). We prove that if the metric space satisfies certain expansion conditions, then with high probability the height of the comparison tree is logarithmic in the number of points, leading to efficient search performance. We also provide an upper bound for the failure probability to return the true nearest neighbor. Experiments show that the comparison tree is competitive with algorithms that have access to the actual distance values, and needs less triplet comparisons than other competitors.