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Bibliographic Details
Main Authors: Laurijssen, Dennis, Baeyens, Rens, Daems, Walter, Steckel, Jan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.01372
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author Laurijssen, Dennis
Baeyens, Rens
Daems, Walter
Steckel, Jan
author_facet Laurijssen, Dennis
Baeyens, Rens
Daems, Walter
Steckel, Jan
contents This paper presents the ConamArray, a compact broadband ultrasound transducer array composed of 32 MEMS loudspeakers. Unlike conventional broadband transducers, which are typically large and require high driving voltages, the proposed array combines small form factor MEMS devices in a staggered two-row configuration to enable beam steering across a wide ultrasonic band. A dual-microcontroller back-end with synchronized multi-DAC outputs provides flexible waveform generation and runtime steering control. Both simulations and anechoic chamber measurements demonstrate that the ConamArray achieves stable beam steering, while also revealing the onset of grating lobes when steering to larger angles. These results confirm the feasibility of broadband beam steering using MEMS technology, opening new opportunities for applications in ultrasonic imaging, localization, and bio-inspired robotics.
format Preprint
id arxiv_https___arxiv_org_abs_2509_01372
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle ConamArray: A 32-Element Broadband MEMS Ultrasound Transducer Array
Laurijssen, Dennis
Baeyens, Rens
Daems, Walter
Steckel, Jan
Systems and Control
This paper presents the ConamArray, a compact broadband ultrasound transducer array composed of 32 MEMS loudspeakers. Unlike conventional broadband transducers, which are typically large and require high driving voltages, the proposed array combines small form factor MEMS devices in a staggered two-row configuration to enable beam steering across a wide ultrasonic band. A dual-microcontroller back-end with synchronized multi-DAC outputs provides flexible waveform generation and runtime steering control. Both simulations and anechoic chamber measurements demonstrate that the ConamArray achieves stable beam steering, while also revealing the onset of grating lobes when steering to larger angles. These results confirm the feasibility of broadband beam steering using MEMS technology, opening new opportunities for applications in ultrasonic imaging, localization, and bio-inspired robotics.
title ConamArray: A 32-Element Broadband MEMS Ultrasound Transducer Array
topic Systems and Control
url https://arxiv.org/abs/2509.01372