CNES studies of on-board compression for multispectral and hyperspectral images

Thiebaut, Carole; Christophe, Emmanuel; Lebedeff, Dimitri; Latry, Christophe

doi:10.1117/12.734186

Cited by 11 publications

(13 citation statements)

References 9 publications

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“…To find the estimate W j of the details components W j based on the approximation components to the Exogenous model proposed for the PCA [56] or for the orthogonal optimal spectral transform (OST) [18], [19].…”

Section: Regression Modelmentioning

confidence: 99%

Regression Wavelet Analysis for Lossless Coding of Remote-Sensing Data

Amrani

Serra-Sagristà

Laparra

et al. 2016

IEEE Trans. Geosci. Remote Sensing

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A novel wavelet-based scheme to increase coefficient independence in hyperspectral images is introduced for lossless coding. The proposed Regression Wavelet Analysis (RWA) uses multivariate regression to exploit the relationships among wavelet-transformed components. It builds on our previous nonlinear schemes that estimate each coefficient from neighbor coefficients. Specifically, RWA performs a pyramidal estimation in the wavelet domain thus reducing the statistical relations in the residuals and the energy of the representation compared to existing wavelet-based schemes. We propose three regression models to address the issues concerning estimation accuracy, component scalability and computational complexity. Other suitable regression models could be devised for other goals. RWA is invertible, it allows a reversible integer implementation, and it does not expand the dynamic range. Experimental results over a wide range of sensors, such as AVIRIS, Hyperion and IASI, suggest that RWA outperforms not only Principal Component Analysis (PCA) and Wavelets, but also the best and most recent coding standard in remote sensing, CCSDS-123. Index TermsTransform coding via regression, wavelet-based transform coding, remote sensing data compression, redundancy in hyperspectral images.

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Section: Regression Modelmentioning

confidence: 99%

Regression Wavelet Analysis for Lossless Coding of Remote-Sensing Data

Amrani

Serra-Sagristà

Laparra

et al. 2016

IEEE Trans. Geosci. Remote Sensing

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“…However, the main drawback of the data-dependent KLT (or PCA) is its heavy computational cost (due to the calculation of a covariance matrix across the data), therefore low-complexity computations of the covariance matrix have been proposed to reduce the computational burden [4,7]. To reduce the complexity of KLT based codecs, another strategy has been successfully applied in [6] for on-board compression of multispectral images. This strategy is to calculate first the KLT on a set of images (called the learning basis) from one (and only one) spectrometer in order to obtain an efficient, although sub-optimal, spectral transform, called exogenous KLT, that is then applied to any image from the same sensor.…”

Section: Introductionmentioning

confidence: 99%

“…They used 1-D DWT for reducing spectral redundancies, however the result still holds with a linear transform. Moreover, when the spectral decorrelation is achieved via the Karhunen-Loève Transform (KLT) or a Principal Component Analysis (PCA), the performances are significantly improved at low, medium and high bit-rates [3,4], even when the DWT adapts to the encoded image [5,6]. However, the main drawback of the data-dependent KLT (or PCA) is its heavy computational cost (due to the calculation of a covariance matrix across the data), therefore low-complexity computations of the covariance matrix have been proposed to reduce the computational burden [4,7].…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, codecs based on these methods have generally a lower complexity than codecs using vectorial quantization before entropy coding. Thus, research activities on multicomponent image codecs based on transform and/or subband coding have been strengthened these last years [1][2][3][4][5][6][7][8][9][10][11]. The JPEG2000 (JP2K) Part 2 standard implements such a method with two variants for reducing spectral redundancies: by applying either a 1-D linear transform, or a 1-D discrete wavelet transform (DWT) between the components of the encoded image.…”

Section: Introductionmentioning

confidence: 99%

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Lossy and lossless compression of MERIS hyperspectral images with exogenous quasi-optimal spectral transforms

Barret¹

2010

J. Appl. Remote Sens

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International audienceOur research focuses on reducing complexity of hyperspectral image codecs based on transform and/or subband coding, so they can be on-board a satellite. It is well-known that the Karhunen Loeve transform (KLT) can be sub-optimal for non Gaussian data. However, it is generally recommended as the best calculable coding transform in practice. Now, for a compression scheme compatible with both the JPEG2000 Part2 standard and the CCSDS recommendations for onboard satellite image compression, the concept and computation of optimal spectral transforms (OST), at high bit-rates, were carried out, under low restrictive hypotheses. These linear transforms are optimal for reducing spectral redundancies of multi- or hyper-spectral images, when the spatial redundancies are reduced with a fixed 2-D discrete wavelet transform. The problem of OST is their heavy computational cost. In this paper we present the performances in coding of a quasi-optimal spectral transform, called exogenous OrthOST, obtained by learning an orthogonal OST on a sample of hyperspectral images from the spectrometer MERIS. Moreover, we compute an integer variant of OrthOST for lossless compression. The performances are compared to the ones of the KLT in both lossy and lossless compressions. We observe good performances of the exogenous OrthOST

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“…Image compression is achieved by exploiting correlations in the data to achieve a more efficient representation of the image information. The first known satellite to implement onboard image compression was SPOT-1, launched in 1986 [1]. Since then, many satellites have featured onboard compression capabilities [2].…”

mentioning

confidence: 99%

Adaptive multispectral GPU accelerated architecture for Earth Observation satellites

Davidson

Bridges

2016

2016 IEEE International Conference on Imaging Systems and Techniques (IST)

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Abstract-In recent years the growth in quantity, diversity and capability of Earth Observation (EO) satellites, has enabled increase's in the achievable payload data dimensionality and volume. However, the lack of equivalent advancement in downlink technology has resulted in the development of an onboard data bottleneck. This bottleneck must be alleviated in order for EO satellites to continue to efficiently provide high quality and increasing quantities of payload data.This research explores the selection and implementation of state-of-the-art multidimensional image compression algorithms and proposes a new onboard data processing architecture, to help alleviate the bottleneck and increase the data throughput of the platform. The proposed new system is based upon a backplane architecture to provide scalability with different satellite platform sizes and varying mission's objectives. The heterogeneous nature of the architecture allows benefits of both Field Programmable Gate Array (FPGA) and Graphical Processing Unit (GPU) hardware to be leveraged for maximised data processing throughput.

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CNES studies of on-board compression for multispectral and hyperspectral images

Cited by 11 publications

References 9 publications

Regression Wavelet Analysis for Lossless Coding of Remote-Sensing Data

Regression Wavelet Analysis for Lossless Coding of Remote-Sensing Data

Lossy and lossless compression of MERIS hyperspectral images with exogenous quasi-optimal spectral transforms

Adaptive multispectral GPU accelerated architecture for Earth Observation satellites

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