A 1.2-mW/Channel Pitch-Matched Transceiver ASIC Employing a Boxcar-Integration-Based RX Micro-Beamformer for High-Resolution 3-D Ultrasound Imaging
P. Guo (TU Delft - Electronic Instrumentation, TU Delft - Bio-Electronics)
F. Fool (TU Delft - ImPhys/Verweij group)
Z.Y. Chang (TU Delft - Electronic Instrumentation)
E. Noothout (TU Delft - ImPhys/Verweij group)
H.J. Vos (TU Delft - ImPhys/Verweij group, Erasmus MC)
J. G. Bosch (Erasmus MC)
N. de Jong (TU Delft - ImPhys/De Jong group, Erasmus MC)
M. Verweij (Erasmus MC, ImPhys/Medical Imaging, TU Delft - ImPhys/Verweij group)
M. Pertijs (TU Delft - Electronic Instrumentation)
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Abstract
This article presents a low-power and small-area transceiver application-specific integrated circuit (ASIC) for 3-D trans-fontanelle ultrasonography. A novel micro-beamforming receiver architecture that employs current-mode summation and boxcar integration is used to realize delay-and-sum on an N -element sub-array using N× fewer capacitive memory elements than conventional micro-beamforming implementations, thus reducing the hardware overhead associated with the memory elements. The boxcar integration also obviates the need for explicit anti-aliasing filtering in the analog front end, thus further reducing die area. These features facilitate the use of micro-beamforming in smaller pitch applications, as demonstrated by a prototype transceiver ASIC employing micro-beamforming on sub-arrays of N=4 elements, targeting a wearable ultrasound device that monitors brain perfusion in preterm infants via the fontanel. To meet its strict spatial resolution requirements, a 10-MHz 100- μ m-pitch piezoelectric transducer array is employed, leading to a per-element die area > 2 × smaller than prior designs employing micro-beamforming.