Scalable Discrete Supervised Multimedia Hash Learning With Clustering

The hashing method maps similar data of various types to binary hashcodes with smaller hamming distance, and it has received broad attention due to its low-storage cost and fast retrieval speed. However, the existing limitations make the present algorithms difficult to deal with for large-scale data sets: 1) discrete constraints are involved in the learning of the hash function and 2) pairwise or triplet similarity is adopted to generate efficient hashcodes, resulting in both time and space complexity greater than O(n(2)). To address these issues, we propose a novel discrete supervised hash learning framework that can be scalable to large-scale data sets of various types. First, the discrete learning procedure is decomposed into a binary classifier learning scheme and binary codes learning scheme, which makes the learning procedure more efficient. Second, by adopting the asymmetric low-rank matrix factorization, we propose the fast clustering-based batch coordinate descent method, such that the time and space complexity are reduced to O (n). The proposed framework also provides a flexible paradigm to incorporate with arbitrary hash function, including deep neural networks and kernel methods, as well as any types of data to hash, including images and videos. Experiments on large-scale data sets demonstrate that the proposed method is superior or comparable with the state-of-the-art hashing algorithms.