Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/35729
Título: Porting a PCA-based hyperspectral image dimensionality reduction algorithm for brain cancer detection on a manycore architecture
Autores/as: Lazcano, R.
Madroñal, D.
Salvador, R.
Desnos, K.
Pelcat, M.
Guerra, R. 
Fabelo, H. 
Ortega, S. 
Lopez, S. 
Callico, G. M. 
Juarez, E.
Sanz, C.
Clasificación UNESCO: 330790 Microelectrónica
220921 Espectroscopia
Palabras clave: Dimensionality reduction
Hyperspectral imaging
Massively parallel processing
Real-time processing
Fecha de publicación: 2017
Publicación seriada: Journal of Systems Architecture 
Resumen: This paper presents a study of the parallelism of a Principal Component Analysis (PCA) algorithm and its adaptation to a manycore MPPA (Massively Parallel Processor Array) architecture, which gathers 256 cores distributed among 16 clusters. This study focuses on porting hyperspectral image processing into many core platforms by optimizing their processing to fulfill real-time constraints, fixed by the image capture rate of the hyperspectral sensor. Real-time is a challenging objective for hyperspectral image processing, as hyperspectral images consist of extremely large volumes of data and this problem is often solved by reducing image size before starting the processing itself. To tackle the challenge, this paper proposes an analysis of the intrinsic parallelism of the different stages of the PCA algorithm with the objective of exploiting the parallelization possibilities offered by an MPPA manycore architecture. Furthermore, the impact on internal communication when increasing the level of parallelism, is also analyzed. Experimenting with medical images obtained from two different surgical use cases, an average speedup of 20 is achieved. Internal communications are shown to rapidly become the bottleneck that reduces the achievable speedup offered by the PCA parallelization. As a result of this study, PCA processing time is reduced to less than 6 s, a time compatible with the targeted brain surgery application requiring 1 frame-per-minute.
URI: http://hdl.handle.net/10553/35729
ISSN: 1383-7621
DOI: 10.1016/j.sysarc.2017.05.001
Fuente: Journal of Systems Architecture[ISSN 1383-7621],v. 77, p. 101-111
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