High-level accelerator design for plane-wave ultrasound beamforming in Fourier domain
Date
2025
Authors
Babajan Rahaghi, Mahdi
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Abstract
This thesis presents the design and implementation of a high-throughput receive beamforming system for Fourier-domain multi-angle plane-wave ultrasound image reconstruction using high-level synthesis (HLS) on a AMD Versal™ adaptive system-on-chip device. The proposed architecture implements a customized Temme–Mueller migration algorithm entirely within the programmable logic fabric, avoiding off-chip memory and relying solely on on-chip resources. The system operates in a stream-based multi-stage pipelined fashion, with each stage — including temporal and spatial Fast Fourier Transforms (FFTs), dynamic phase delay, spectral remapping, multi-angle coherent compounding, and inverse FFTs— realized as modular, latency-aware HLS blocks.
Unlike previous methods, the system performs remapping and interpolation without relying on large, precomputed lookup tables, instead computing all migration-related parameters on the fly. The architecture achieves a sustained processing throughput of over 500 frames per second (with five-angle compounding), enabled by four-lane parallelization and efficient pipelining across all stages. The system HLS specification is statically parameterized in terms of user-controlled FFT lengths, data frame sizes. and number of compounding angles. On the other hand, the key imaging parameters, such as speed of sound, sampling frequency, and probe geometry, are configurable at runtime. Extensive module-level simulation and architecture-level integration testing have validated the system’s correctness confirmed against a MATLAB-based reference model.