Publication details
Metric index: an efficient and scalable solution for precise and approximate similarity search
| Authors | |
|---|---|
| Year of publication | 2011 |
| Type | Article in Periodical |
| Magazine / Source | Information Systems |
| MU Faculty or unit | |
| Citation | |
| Doi | http://dx.doi.org/10.1016/j.is.2010.10.002 |
| Field | Informatics |
| Keywords | Metric space; Similarity search; Data structure; Approximation; Scalability |
| Description | Metric space is a universal and versatile model of similarity that can be applied in various areas of information retrieval. However, a general, efficient, and scalable solution for metric data management is still a resisting research challenge. We introduce a novel indexing and searching mechanism called Metric Index (M-Index) that employs practically all known principles of metric space partitioning, pruning, and filtering, thus reaching high search performance while having constant building costs per object. The heart of the M-Index is a general mapping mechanism that enables to actually store the data in established structures such as the B+ - tree or even in a distributed storage. We implemented the M-Index with the B+ - tree and performed experiments on two datasets - the first is an artificial set of vectors and the other is a real-life dataset composed of a combination of five MPEG-7 visual descriptors extracted from a database of up to several million digital images. The experiments put several M-Index variants under test and compare them with established techniques for both precise and approximate similarity search. The trials show that the M-Index outperforms the others in terms of efficiency of search-space pruning, I/O costs, and response times for precise similarity queries. Further, the M-Index demonstrates excellent ability to keep similar data close in the index which makes its approximation algorithm very efficient - maintaining practically constant response times while preserving a very high recall as the dataset grows and even beating approaches designed purely for approximate search. |
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