2008
DOI: 10.1016/j.parco.2007.12.005
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An experimental comparison of parallel algorithms for hyperspectral analysis using heterogeneous and homogeneous networks of workstations

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Cited by 38 publications
(17 citation statements)
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“…However, a recent trend in the design of HPC systems for data-intensive problems, such as those involved in hyperspectral image analysis, is to utilize highly heterogeneous computing resources [176]. In this regard, networks of heterogeneous workstations can realize a very high level of aggregate performance in hyperspectral imaging applications, and the pervasive availability of these resources resulted in the current notions of grid and, later, cloud computing, which are yet to be fully exploited in hyperspectral imaging problems [177].…”
Section: A Clusters and Distributed Platforms For Hyperspectral Procmentioning
confidence: 99%
“…However, a recent trend in the design of HPC systems for data-intensive problems, such as those involved in hyperspectral image analysis, is to utilize highly heterogeneous computing resources [176]. In this regard, networks of heterogeneous workstations can realize a very high level of aggregate performance in hyperspectral imaging applications, and the pervasive availability of these resources resulted in the current notions of grid and, later, cloud computing, which are yet to be fully exploited in hyperspectral imaging problems [177].…”
Section: A Clusters and Distributed Platforms For Hyperspectral Procmentioning
confidence: 99%
“…The main advantage of the spatial-domain decomposition approach in Figure 3 is that the cost of inter-processor communication is reduced, as shown in the previous work [10,18,24]. At this point, it is important to emphasize that spatial-domain partitioning should be used with extra care when parallelizing data processing techniques that include sample spectral correlation and/or covariance calculations, such as the principal component transform [28] or the RX detector developed by Reed and Yu [29], both of them widely used in hyperspectral image analysis.…”
Section: Hyperspectral Data Partitioningmentioning
confidence: 79%
“…c ij = c ji ). With the above assumptions in mind [24], processor p i should accomplish a share of i · W of the total workload, denoted by W , to be performed by a certain algorithm, with i ≥0 for 1≤i≤P and P i=1 i = 1, being P the total number of processors in the system.…”
Section: Optimization Problemmentioning
confidence: 99%
“…the latency for large message sizes (typical in hyperspectral imaging applications, since each pixel vector is made up of hundreds of spectral values) is extremely sensitive to the size of the message. Thus, decreasing the size of the messages could significantly reduce the latency and hence improve the scalability or parallel performance [5]. In this paper, we propose a new framework based on the utilization of lossy data compression techniques for improving the scalability of parallel hyperspectral imaging algorithms on both homogeneous and heterogeneous parallel computers.…”
Section: Introductionmentioning
confidence: 99%