Laimer, M., Wolf, T., Kern, T. A., Schitter, G., & Csencsics, E. (2025). Real-time sensing of micrometer in-plane motion with a measurement rate of 25 kHz. In 2025 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM) (pp. 1–6). https://doi.org/10.1109/AIM64088.2025.11175625
This paper presents a laser speckle-based line sensor for real-time measurements of translational in-plane displacements along one degree of freedom (DOF) at measurement rates of several ten kHz. The sensor architecture includes a high-speed CMOS line camera combined with an field-programmable gate array (FPGA), facilitating efficient data acquisition and processing with low latency. Laser-induced speckle serve as temporal surface markers for in-plane displacement measurements on non-structured surfaces. With cross-correlation and sub-pixel interpolation algorithms being implemented on an FPGA, measurement of in-plane displacement with single micrometer resolution is achieved. Experimental results demonstrate that the developed speckle sensor can effectively measure in-plane displacements at a measurement rate of 25 kHz over a range of 100 μm, and a resolution of 3.5 μm. With a latency of 81 μs, the ability to efficiently process data in real-time is successfully demonstrated, which enables the speckle sensor to be used for high-bandwidth feedback control loops.
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Project (external):
Austrian Federal Ministry of Economy, Energy and Tourism National Foundation for Research, Technology and Development Christian Doppler Research Association Micro-Epsilon Atensor GmbH MICRO-EPSILON-MESSTECHNIK GmbH & Co.K.G
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Research Areas:
Modeling and Simulation: 30% Automation and Robotics: 40% Sensor Systems: 30%
