Abstract
Granular-balls reduce the data volume and enhance the efficiency of fundamental algorithms such as clustering and classification. However, generating granular-balls is a time-consuming process, posing a significant bottleneck for the practical application of granular-balls. In this paper, we propose two innovative quantum granular-ball generation methods that capitalize on the inherent properties of quantum computing. The first method employs an iterative splitting technique, while the second utilizes a predetermined number of splits. The iterative splitting method significantly reduces time complexity compared to existing classical granular-ball generation methods. Notably, the method employing a fixed number of splits delivers a substantial quadratic acceleration over the iterative technique. Moreover, we also propose a quantum k-nearest neighbors algorithm based on granular-balls (QGBkNN) and empirically show the effectiveness of our approach.