High frame rate (HFR) imaging methods are increasingly popular but impose severe requirements to ultrasound scanners. Real-time HFR imaging is such a challenging task that, conventional scanners merely elaborate the echo-data in post-processing. Real-time acquisition and data post-processing are usually well separated: the former needs to be guided by a standard B-Mode display that is interrupted when the raw data are transferred to, e.g., a GPU board for off-line processing. In this paper we describe a different approach, called “virtual real-time” mode, implemented on the ULA-OP 256 scanner, in which the two phases are tightly interleaved: raw data that are continuously stored in RAM during a real-time elaboration can be immediately re-processed at a different rate. This enables not only to display in slow-motion possible fast recorded events, but also to facilitate the achievement of optimal conditions for US acquisition and the extraction of additional information from the echo data.
Virtual real-time: a new US operating modality / Claudio Giangrossi , Valentino Meacci, Enrico Boni, Alessandro Dallai, Francesco Guidi, Stefano Ricci, Alfred Yu, Piero Tortoli. - ELETTRONICO. - (2019), pp. 1493-14960. (Intervento presentato al convegno 2019 IEEE Ultrasonics Symposium (IUS) tenutosi a Glasgow (UK) nel 6-9 ottobre 2019) [10.1109/ULTSYM.2019.8926259].
Virtual real-time: a new US operating modality
GIANGROSSI, CLAUDIO
Membro del Collaboration Group
;Valentino MeacciMembro del Collaboration Group
;Enrico BoniMembro del Collaboration Group
;Alessandro DallaiMembro del Collaboration Group
;Francesco GuidiMembro del Collaboration Group
;Stefano RicciMembro del Collaboration Group
;Piero TortoliSupervision
2019
Abstract
High frame rate (HFR) imaging methods are increasingly popular but impose severe requirements to ultrasound scanners. Real-time HFR imaging is such a challenging task that, conventional scanners merely elaborate the echo-data in post-processing. Real-time acquisition and data post-processing are usually well separated: the former needs to be guided by a standard B-Mode display that is interrupted when the raw data are transferred to, e.g., a GPU board for off-line processing. In this paper we describe a different approach, called “virtual real-time” mode, implemented on the ULA-OP 256 scanner, in which the two phases are tightly interleaved: raw data that are continuously stored in RAM during a real-time elaboration can be immediately re-processed at a different rate. This enables not only to display in slow-motion possible fast recorded events, but also to facilitate the achievement of optimal conditions for US acquisition and the extraction of additional information from the echo data.
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