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| Main Authors: | , , |
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| Format: | Preprint |
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2026
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2602.20779 |
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| _version_ | 1866914347149688832 |
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| author | Lux, Florian Ditchendorf, Elijah Ataman, Çağlar |
| author_facet | Lux, Florian Ditchendorf, Elijah Ataman, Çağlar |
| contents | 3D nano-printing through two-photon polymerization enables monolithic manufacturing of mechanical and freeform micro-optical elements with high inherent alignment accuracy. However, viscoelasticity and temperature-dependent stiffness of the photopolymer lead to hysteresis and drift, which significantly degrade open-loop position accuracy and long-term stability in quasi-static operation. Therefore, closed-loop control with integrated displacement sensing is essential for 3D nano-printed optical microsystems in practical precision positioning applications. Here, we present a closed-loop control system for a such a lens actuator that uses a commercial 3-axis Hall sensor for position tracking. A NdFeB micromagnet encircling the integrated microlens provides both the actuation force and a position-dependent sensing signal. The Hall sensor, located between an anti-Helmholtz-like coil pair that drives the scanner bidirectionally, measures the combined field due to the micro-magnet and the coil pair. Calibration-based subtraction separates the coil field and sensor offset contributions to recover the magnet field and thus the axial magnet displacement. Closed-loop operation yields a mean absolute accuracy of 0.86 um and a precision of 0.49 um over a displacement range of 150 um while eliminating viscoelastic creep, suppressing hysteresis, and minimizing temperature-induced displacement drift under coil self-heating. This sensing approach requires no additional microfabrication steps and provides a practical path toward stable and repeatable positioning for monolithically 3D nano-printed optical microsystems. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2602_20779 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Closed-loop control of a monolithically 3D nano-printed electromagnetic lens scanner with an integrated Hall sensor Lux, Florian Ditchendorf, Elijah Ataman, Çağlar Optics 3D nano-printing through two-photon polymerization enables monolithic manufacturing of mechanical and freeform micro-optical elements with high inherent alignment accuracy. However, viscoelasticity and temperature-dependent stiffness of the photopolymer lead to hysteresis and drift, which significantly degrade open-loop position accuracy and long-term stability in quasi-static operation. Therefore, closed-loop control with integrated displacement sensing is essential for 3D nano-printed optical microsystems in practical precision positioning applications. Here, we present a closed-loop control system for a such a lens actuator that uses a commercial 3-axis Hall sensor for position tracking. A NdFeB micromagnet encircling the integrated microlens provides both the actuation force and a position-dependent sensing signal. The Hall sensor, located between an anti-Helmholtz-like coil pair that drives the scanner bidirectionally, measures the combined field due to the micro-magnet and the coil pair. Calibration-based subtraction separates the coil field and sensor offset contributions to recover the magnet field and thus the axial magnet displacement. Closed-loop operation yields a mean absolute accuracy of 0.86 um and a precision of 0.49 um over a displacement range of 150 um while eliminating viscoelastic creep, suppressing hysteresis, and minimizing temperature-induced displacement drift under coil self-heating. This sensing approach requires no additional microfabrication steps and provides a practical path toward stable and repeatable positioning for monolithically 3D nano-printed optical microsystems. |
| title | Closed-loop control of a monolithically 3D nano-printed electromagnetic lens scanner with an integrated Hall sensor |
| topic | Optics |
| url | https://arxiv.org/abs/2602.20779 |