On-board Compressing of Hyperspectral Images using CCSDS 123

A satellite performing hyperspectral image processing requireshigh storage capacity and larger communication bandwidth. Compressionalgorithms, like the CCSDS 123, have been proposed tomitigate these requirements. Considering the constraints associatedto satellites, single-purpose processors have been developedto run these algorithms in Systems-on-Chip (SoC). In this work, weevaluate alternatives to integrate a CCSDS 123 compressor withan embedded processor based on RISC-V and ARM-based architectures.

Download Full-text

Systematic Review of Anomaly Detection in Hyperspectral Remote Sensing Applications

Applied Sciences ◽

10.3390/app11114878 ◽

2021 ◽

Vol 11 (11) ◽

pp. 4878

Author(s):

Ivan Racetin ◽

Andrija Krtalić

Keyword(s):

Remote Sensing ◽

Image Processing ◽

Anomaly Detection ◽

Target Detection ◽

Hyperspectral Image ◽

Hyperspectral Images ◽

Detection Methods ◽

Hyperspectral Image Processing ◽

Sensing Applications ◽

Remote Sensing Applications

Hyperspectral sensors are passive instruments that record reflected electromagnetic radiation in tens or hundreds of narrow and consecutive spectral bands. In the last two decades, the availability of hyperspectral data has sharply increased, propelling the development of a plethora of hyperspectral classification and target detection algorithms. Anomaly detection methods in hyperspectral images refer to a class of target detection methods that do not require any a-priori knowledge about a hyperspectral scene or target spectrum. They are unsupervised learning techniques that automatically discover rare features on hyperspectral images. This review paper is organized into two parts: part A provides a bibliographic analysis of hyperspectral image processing for anomaly detection in remote sensing applications. Development of the subject field is discussed, and key authors and journals are highlighted. In part B an overview of the topic is presented, starting from the mathematical framework for anomaly detection. The anomaly detection methods were generally categorized as techniques that implement structured or unstructured background models and then organized into appropriate sub-categories. Specific anomaly detection methods are presented with corresponding detection statistics, and their properties are discussed. This paper represents the first review regarding hyperspectral image processing for anomaly detection in remote sensing applications.

Download Full-text

The Quick Atmospheric Correction (QUAC) Algorithm for Hyperspectral Image Processing: Extending QUAC to a Coastal Scene

2015 International Conference on Digital Image Computing: Techniques and Applications (DICTA) ◽

10.1109/dicta.2015.7371314 ◽

2015 ◽

Cited By ~ 4

Author(s):

S. B. Carr ◽

L. S. Bernstein ◽

S. M. Adler-Golden

Keyword(s):

Image Processing ◽

Hyperspectral Image ◽

Atmospheric Correction ◽

Hyperspectral Image Processing

Download Full-text

A Distributed Parallel Algorithm Based on Low-Rank and Sparse Representation for Anomaly Detection in Hyperspectral Images

Sensors ◽

10.3390/s18113627 ◽

2018 ◽

Vol 18 (11) ◽

pp. 3627 ◽

Cited By ~ 1

Author(s):

Yi Zhang ◽

Zebin Wu ◽

Jin Sun ◽

Yan Zhang ◽

Yaoqin Zhu ◽

...

Keyword(s):

Anomaly Detection ◽

Sparse Representation ◽

Parallel Algorithm ◽

Hyperspectral Image ◽

Hyperspectral Images ◽

Low Rank ◽

Detection Methods ◽

Matrix Computations ◽

Hyperspectral Image Processing ◽

Mapreduce Model

Anomaly detection aims to separate anomalous pixels from the background, and has become an important application of remotely sensed hyperspectral image processing. Anomaly detection methods based on low-rank and sparse representation (LRASR) can accurately detect anomalous pixels. However, with the significant volume increase of hyperspectral image repositories, such techniques consume a significant amount of time (mainly due to the massive amount of matrix computations involved). In this paper, we propose a novel distributed parallel algorithm (DPA) by redesigning key operators of LRASR in terms of MapReduce model to accelerate LRASR on cloud computing architectures. Independent computation operators are explored and executed in parallel on Spark. Specifically, we reconstitute the hyperspectral images in an appropriate format for efficient DPA processing, design the optimized storage strategy, and develop a pre-merge mechanism to reduce data transmission. Besides, a repartitioning policy is also proposed to improve DPA’s efficiency. Our experimental results demonstrate that the newly developed DPA achieves very high speedups when accelerating LRASR, in addition to maintaining similar accuracies. Moreover, our proposed DPA is shown to be scalable with the number of computing nodes and capable of processing big hyperspectral images involving massive amounts of data.

Download Full-text