This paper introduces a compressive sampling (CS) scheme for pulse stream images. We adopt a particular sparse sampling matrix, that we call Radon-like CS matrix. Whilst the Radon transform evaluates projections of a given image along different directions, the Radon-like CS matrix evaluates randomly weighted projections of the image along a few directions. We demonstrate that the such CS measurements are invertible and assess the reconstruction accuracy of CS with the Radonlike sampling matrix by numerical trials. The Radon-like CS performs almost as well as state of the art techniques, with a reduced number of operations. As an application example, we show that, when implemented in a resource limited framework such as a Smart Sensors Grid, the sampling matrix significantly reduces inter-node signaling and then the associated energy consumption. © 2012 IEEE.
Computationally-efficient compressive sampling of pulse stream images using Radon-like measurements / Colonnese, Stefania; Cusani, Roberto; Rinauro, Stefano; Scarano, Gaetano. - STAMPA. - (2012), pp. 1-4. (Intervento presentato al convegno 5th International Symposium on Communications Control and Signal Processing, ISCCSP 2012 tenutosi a Rome; Italy nel 2 May 2012 through 4 May 2012) [10.1109/isccsp.2012.6217819].
Computationally-efficient compressive sampling of pulse stream images using Radon-like measurements
COLONNESE, Stefania;CUSANI, Roberto;RINAURO, STEFANO;SCARANO, Gaetano
2012
Abstract
This paper introduces a compressive sampling (CS) scheme for pulse stream images. We adopt a particular sparse sampling matrix, that we call Radon-like CS matrix. Whilst the Radon transform evaluates projections of a given image along different directions, the Radon-like CS matrix evaluates randomly weighted projections of the image along a few directions. We demonstrate that the such CS measurements are invertible and assess the reconstruction accuracy of CS with the Radonlike sampling matrix by numerical trials. The Radon-like CS performs almost as well as state of the art techniques, with a reduced number of operations. As an application example, we show that, when implemented in a resource limited framework such as a Smart Sensors Grid, the sampling matrix significantly reduces inter-node signaling and then the associated energy consumption. © 2012 IEEE.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
