Evolutionary Projection Selection for Radon Barcodes
This work addresses a domain-specific issue for medical image tagging by improving barcode generation, but it is incremental as it builds on existing Radon transformation methods.
The paper tackled the problem of selecting optimal projection directions for Radon barcodes in medical images to increase expressiveness, proposing an evolutionary approach that outperformed exhaustive search in finding the best projections, as demonstrated on a subset of the IRMA dataset with 10 classes and 5 images per class.
Recently, Radon transformation has been used to generate barcodes for tagging medical images. The under-sampled image is projected in certain directions, and each projection is binarized using a local threshold. The concatenation of the thresholded projections creates a barcode that can be used for tagging or annotating medical images. A small number of equidistant projections, e.g., 4 or 8, is generally used to generate short barcodes. However, due to the diverse nature of digital images, and since we are only working with a small number of projections (to keep the barcode short), taking equidistant projections may not be the best course of action. In this paper, we proposed to find $n$ optimal projections, whereas $n\!<\!180$, in order to increase the expressiveness of Radon barcodes. We show examples for the exhaustive search for the simple case when we attempt to find 4 best projections out of 16 equidistant projections and compare it with the evolutionary approach in order to establish the benefit of the latter when operating on a small population size as in the case of micro-DE. We randomly selected 10 different classes from IRMA dataset (14,400 x-ray images in 58 classes) and further randomly selected 5 images per class for our tests.