Search

Your search keyword '"Hernandez-Cabronero, Miguel"' showing total 12 results
Start Over Author "Hernandez-Cabronero, Miguel" Database Complementary Index
12 results on '"Hernandez-Cabronero, Miguel"'

1. Mosaic-Based Color-Transform Optimization for Lossy and Lossy-to-Lossless Compression of Pathology Whole-Slide Images.

Author

Hernandez-Cabronero, Miguel, Sanchez, Victor, Blanes, Ian, Auli-Llinas, Francesc, Marcellin, Michael W., and Serra-Sagrista, Joan

Subjects
ARTIFICIAL intelligence, DIGITAL image processing, MATHEMATICAL optimization, WAVELET transforms, INFORMATION technology
Abstract

The use of whole-slide images (WSIs) in pathology entails stringent storage and transmission requirements because of their huge dimensions. Therefore, image compression is an essential tool to enable efficient access to these data. In particular, color transforms are needed to exploit the very high degree of inter-component correlation and obtain competitive compression performance. Even though the state-of-the-art color transforms remove some redundancy, they disregard important details of the compression algorithm applied after the transform. Therefore, their coding performance is not optimal. We propose an optimization method called mosaic optimization for designing irreversible and reversible color transforms simultaneously optimized for any given WSI and the subsequent compression algorithm. Mosaic optimization is designed to attain reasonable computational complexity and enable continuous scanner operation. Exhaustive experimental results indicate that, for JPEG 2000 at identical compression ratios, the optimized transforms yield images more similar to the original than the other state-of-the-art transforms. Specifically, irreversible optimized transforms outperform the Karhunen–Loève Transform in terms of PSNR (up to 1.1 dB), the HDR-VDP-2 visual distortion metric (up to 3.8 dB), and the accuracy of computer-aided nuclei detection tasks (F1 score up to 0.04 higher). In addition, reversible optimized transforms achieve PSNR, HDR-VDP-2, and nuclei detection accuracy gains of up to 0.9 dB, 7.1 dB, and 0.025, respectively, when compared with the reversible color transform in lossy-to-lossless compression regimes. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

2. Graph-Based Rate Control in Pathology Imaging With Lossless Region of Interest Coding.

Author

Sanchez, Victor and Hernandez-Cabronero, Miguel

Subjects
SIGNAL processing, VIDEO coding, PATHOLOGY, LOSSLESS data compression, BIT rate
Abstract

The increasing availability of digital pathology images has motivated the design of tools to foster multidisciplinary collaboration among researchers, pathologists, and computer scientists. Telepathology plays an important role in the development of collaborative tools, as it facilitates the transmission and access to pathology images by multiple users. However, the huge file size associated with pathology images usually prevents full exploitation of the collaborative telepathology system potential. Within this context, rate control (RC) is an important tool that allows meeting storage and bandwidth requirements by controlling the bit rate of the coded image. In this paper, we propose a novel graph-based RC algorithm with lossless region of interest (RoI) coding for pathology images. The algorithm, which is designed for block-based predictive transform coding methods, compresses the non-RoI in a lossy manner according to a target bit rate and the RoI in a lossless manner. It employs a graph where each node represents a constituent block of the image to be coded. By incorporating information about the coding cost similarities of blocks into the graph, a graph kernel is used to distribute a target bit budget among the non-RoI blocks. In order to increase RC accuracy, the algorithm uses a rate-lambda (R- $\lambda $) model to approximate the slope of the rate-distortion curve of the non-RoI, and a graph-based approach to guarantee that the target bit rate is accurately attained. The algorithm is implemented in the High-Efficiency Video Coding standard and tested over a wide range of pathology images with multiple RoIs. Evaluation results show that it outperforms the other state-of-the-art methods designed for single images by very accurately attaining the target bit rate of the non-RoI. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

3. Dual Link Image Coding for Earth Observation Satellites.

Author

Auli-Llinas, Francesc, Marcellin, Michael W., Sanchez, Victor, Bartrina-Rapesta, Joan, and Hernandez-Cabronero, Miguel

Subjects
IMAGE compression, CODING theory, REMOTE-sensing images of Earth, JPEG (Image coding standard), LANDSAT satellites, ARTIFICIAL satellites
Abstract

The conventional strategy to download images captured by satellites is to compress the data on board and then transmit them via the downlink. It often happens that the capacity of the downlink is too small to accommodate all the acquired data, so the images are trimmed and/or transmitted through lossy regimes. This paper introduces a coding system that increases the amount and quality of the downloaded imaging data. The main insight of this paper is to use both the uplink and the downlink to code the images. The uplink is employed to send reference information to the satellite so that the onboard coding system can achieve higher efficiency. This reference information is computed on the ground, possibly employing extensive data and computational resources. The proposed system is called dual link image coding. As it is devised in this paper, it is suitable for Earth observation satellites with polar orbits. Experimental results obtained for data sets acquired by the Landsat 8 satellite indicate significant coding gains with respect to conventional methods. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

4. Lossless Compression of Color Filter Array Mosaic Images With Visualization via JPEG 2000.

Author

Hernandez-Cabronero, Miguel, Marcellin, Michael W., Blanes, Ian, and Serra-Sagrista, Joan

Abstract

Digital cameras have become ubiquitous for amateur and professional applications. The raw images captured by digital sensors typically take the form of color filter array (CFA) mosaic images which must be “developed” (via digital signal processing) before they can be viewed. Photographers and scientists often repeat the “development process” using different parameters to obtain images suitable for different purposes. Since the development process is generally not invertible it is commonly desirable to store the raw (or undeveloped) mosaic images indefinitely. Uncompressed mosaic image file sizes can be more than 30 times larger than those of developed images stored in JPEG format. Thus data compression is of interest. Several compression methods for mosaic images have been proposed in the literature. However they all require a custom decompressor followed by development-specific software to generate a displayable image. In this paper a novel compression pipeline that removes these requirements is proposed. Specifically mosaic images can be losslessly recovered from the resulting compressed files and more significantly images can be directly viewed (decompressed and developed) using only a JPEG 2000 compliant image viewer. Experiments reveal that the proposed pipeline attains excellent visual quality while providing compression performance competitive to that of state-of-the-art compression algorithms for mosaic images. [ABSTRACT FROM PUBLISHER]

Published
2018
Full Text
View/download PDF

5. The Current Role of Image Compression Standards in Medical Imaging.

Author

Feng Liu, Hernandez-Cabronero, Miguel, Sanchez, Victor, Marcellin, Michael W., and Bilgin, Ali

Subjects
DIAGNOSTIC imaging, BIG data
Abstract

With the increasing utilization of medical imaging in clinical practice and the growing dimensions of data volumes generated by various medical imaging modalities, the distribution, storage, and management of digital medical image data sets requires data compression. Over the past few decades, several image compression standards have been proposed by international standardization organizations. This paper discusses the current status of these image compression standards in medical imaging applications together with some of the legal and regulatory issues surrounding the use of compression in medical settings. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

10. Progressive Lossy-to-Lossless Compression of DNA Microarray Images.

Author

Hernandez-Cabronero, Miguel, Blanes, Ian, Pinho, Armando J., Marcellin, Michael W., and Serra-Sagrista, Joan

Subjects
LOSSY data compression, DATA compression, DNA microarrays, IMAGE reconstruction, SIGNAL quantization
Abstract

The analysis techniques applied to DNA microarray images are under active development. As new techniques become available, it will be useful to apply them to existing microarray images to obtain more accurate results. The compression of these images can be a useful tool to alleviate the costs associated to their storage and transmission. The recently proposed Relative Quantizer (RQ) coder provides the most competitive lossy compression ratios while introducing only acceptable changes in the images. However, images compressed with the RQ coder can only be reconstructed with a limited quality, determined before compression. In this work, a progressive lossy-to-lossless scheme is presented to solve this problem. First, the regular structure of the RQ intervals is exploited to define a lossy-to-lossless coding algorithm called the Progressive RQ (PRQ) coder. Second, an enhanced version that prioritizes a region of interest, called the PRQ-region of interest (ROI) coder, is described. Experiments indicate that the PRQ coder offers progressivity with lossless and lossy coding performance almost identical to the best techniques in the literature, none of which is progressive. In turn, the PRQ-ROI exhibits very similar lossless coding results with better rate-distortion performance than both the RQ and PRQ coders. [ABSTRACT FROM AUTHOR]

Published
2016
Full Text
View/download PDF

11. Analysis-Driven Lossy Compression of DNA Microarray Images.

Author

Hernandez-Cabronero, Miguel, Blanes, Ian, Pinho, Armando J., Marcellin, Michael W., and Serra-Sagrista, Joan

Subjects
DNA microarrays, LOSSY data compression, GENETIC research, DATA transmission systems, INFORMATION sharing
Abstract

DNA microarrays are one of the fastest-growing new technologies in the field of genetic research, and DNA microarray images continue to grow in number and size. Since analysis techniques are under active and ongoing development, storage, transmission and sharing of DNA microarray images need be addressed, with compression playing a significant role. However, existing lossless coding algorithms yield only limited compression performance (compression ratios below 2:1), whereas lossy coding methods may introduce unacceptable distortions in the analysis process. This work introduces a novel Relative Quantizer (RQ), which employs non-uniform quantization intervals designed for improved compression while bounding the impact on the DNA microarray analysis. This quantizer constrains the maximum relative error introduced into quantized imagery, devoting higher precision to pixels critical to the analysis process. For suitable parameter choices, the resulting variations in the DNA microarray analysis are less than half of those inherent to the experimental variability. Experimental results reveal that appropriate analysis can still be performed for average compression ratios exceeding 4.5:1. [ABSTRACT FROM PUBLISHER]

Published
2016
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results