Lucio Bianchi scite author profile

Soundfield imaging is a special analysis methodology aimed at capturing the directional components of the acoustic field and mapping them onto a domain called "ray space", where rele-vant acoustic objects become linear patterns, i.e., sets of collinear points. This allows us to overcome resolution issues while easing far-field assumptions. In this paper, we generalize this concept by introducing the ray space transform for acoustic field repre-sentation. The transform is based on a short space-time Fourier transform of the signals captured by a microphone array, using discrete Gabor frames. The resulting transform coefficients are parameterized in the same ray space used for soundfield imaging. The resulting transform enables the definition of analysis and syn-thesis operators, which exhibit perfect reconstruction capabilities. We show examples of applications of the ray space transform to source localization and spot spatial filtering.

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Compress-then-Analyze versus Analyze-then-Compress: What Is Best in Visual Sensor Networks?

Redondi

Baroffio

Bianchi

et al. 2016

IEEE Trans. on Mobile Comput.

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Visual Sensor Networks (VSNs) have attracted the interest of researchers worldwide in the last few years, and are expected to play a major role in the evolution of the Internet-of-Things (IoT). When used to perform visual analysis tasks, VSNs may be operated according to two different paradigms. In the traditional compress-then-analyze paradigm, images are acquired, compressed and transmitted for further analysis. Conversely, in the analyze-then-compress paradigm, image features are extracted by visual sensor nodes, encoded and then delivered to a remote destination where analysis is performed. The question this paper aims to answer is What is the best visual analysis paradigm in VSNs? To do this, first we empirically characterize the rate-energy-accuracy performance of the two aforementioned paradigms. Then, we leverage such models to formulate a resource allocation problem for VSNs. The problem optimally allocates the specific paradigm used by each camera node in the network and the related transmission source rate, with the objective of optimizing the accuracy of the visual analysis task and the VSN coverage. Experimental results over several VSNs instances demonstrate that there is no "winning" paradigm, but the best performance are obtained by allowing the coexistence of the two and by properly optimizing their utilization.

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Loudspeaker virtualization–Part II: The inverse transducer model and the Direct-Inverse-Direct Chain

Bernardini

Bianchi²,

Sarti

2023

Signal Processing

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Loudspeaker virtualization–Part I: Digital modeling and implementation of the nonlinear transducer equivalent circuit

Bernardini

Bianchi²,

Sarti

2023

Signal Processing

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Model-based acoustic rendering based on plane wave decomposition

et al. 2016

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Lucio Bianchi

The Ray Space Transform: A New Framework for Wave Field Processing

Compress-then-Analyze versus Analyze-then-Compress: What Is Best in Visual Sensor Networks?

Loudspeaker virtualization–Part II: The inverse transducer model and the Direct-Inverse-Direct Chain

Loudspeaker virtualization–Part I: Digital modeling and implementation of the nonlinear transducer equivalent circuit

Model-based acoustic rendering based on plane wave decomposition

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