High-frame-rate (HFR) color flow mapping (CFM) improves the temporal resolution and sensitivity of Doppler imaging but remains limited by aliasing when Doppler shifts exceed the Nyquist limit. This work presents a real-time implementation of staggered pulse repetition frequency Doppler imaging to overcome these limitations in HFR-CFM. The method was deployed on a heterogeneous ultrasound research platform integrating FPGAs, DSPs, and an embedded GPU. Interleaved dual-PRF sequences were used to generate aliased velocity estimates with distinct wrapping patterns, which were processed on the GPU using dedicated parallel pipelines. In vitro experiments were performed using a flow phantom and a linear array probe. Results demonstrate that staggered HFR-CFM effectively suppresses aliasing artifacts and restores smooth velocity profiles in conditions where conventional methods fail, while maintaining high spatial and temporal resolution.
Real-Time High Frame Rate Color Doppler Imaging with Staggered Pulse Repetition Frequency / Bonciani, Giulio; Guidi, Francesco; Giangrossi, Claudio; Varray, François; Garcia, Damien; Boni, Enrico; Ramalli, Alessandro. - ELETTRONICO. - (2025), pp. 1-4. (Intervento presentato al convegno 2025 IEEE International Ultrasonics Symposium, IUS 2025 tenutosi a Utrecht nel 2025) [10.1109/ius62464.2025.11201738].
Real-Time High Frame Rate Color Doppler Imaging with Staggered Pulse Repetition Frequency
Bonciani, Giulio;Guidi, Francesco;Giangrossi, Claudio;Boni, Enrico;Ramalli, Alessandro
2025
Abstract
High-frame-rate (HFR) color flow mapping (CFM) improves the temporal resolution and sensitivity of Doppler imaging but remains limited by aliasing when Doppler shifts exceed the Nyquist limit. This work presents a real-time implementation of staggered pulse repetition frequency Doppler imaging to overcome these limitations in HFR-CFM. The method was deployed on a heterogeneous ultrasound research platform integrating FPGAs, DSPs, and an embedded GPU. Interleaved dual-PRF sequences were used to generate aliased velocity estimates with distinct wrapping patterns, which were processed on the GPU using dedicated parallel pipelines. In vitro experiments were performed using a flow phantom and a linear array probe. Results demonstrate that staggered HFR-CFM effectively suppresses aliasing artifacts and restores smooth velocity profiles in conditions where conventional methods fail, while maintaining high spatial and temporal resolution.
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