Modified Phase-Offset-Driven Lissajous Scanning Endomicroscopy With a Polyimide-Film-Based Frequency Separator

Im, Jintaek; Chang, Yeonhee; Song, Chang-Woo

doi:10.1109/tmech.2022.3166453

Cited by 9 publications

(2 citation statements)

References 42 publications

(66 reference statements)

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“…This instrument could greatly increase the areas of the in vivo tissue scanning with the help of pCLE platform. [41][42][43] The proposed instrument is to address the problems associated with mechanical scanning over large tissue areas in confocal endomicroscopy, which can greatly improve the prospects for intraoperative in vivo digestive tract margin evaluation.…”

Section: Discussionmentioning

confidence: 99%

A Novel Flexible Endomicroscopic Scanning Instrument with Visual Servoing Control

Xu,

Zhang,

Zhang

et al. 2024

Advanced Intelligent Systems

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Optical biopsy using probe‐based confocal laser endomicroscopy (pCLE) and optical coherence tomography (OCT) technologies performs in vivo tissue scanning of organ surfaces and plays a crucial role in early cancer diagnosis. Herein, a flexible endomicroscopic scanning instrument based on a 3‐degree‐of‐freedom flexible hinge structure and visual servoing control is presented. The instrument integrates OCT and pCLE. OCT information compensates for the imaging distance of pCLE, which can combine the advantages of the two technologies. The mechanism allows for tissue surface scanning with a wire‐driven active bending part and dynamic adjustment of the probe‐tissue distance using a combination of wire and spring‐driven, which satisfy large‐area scanning while maintaining consistence tissue contacts. Local optimization‐based visual servoing control is proposed to optimize the tissue scanning. Through the scanning experiments, high‐quality mosaics of uneven surfaces are obtained with an effective area that is larger than 4 mm2. In vivo animal trial further verifies the feasibility and clinical potential of the instrument.

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Section: Discussionmentioning

confidence: 99%

A Novel Flexible Endomicroscopic Scanning Instrument with Visual Servoing Control

Xu,

Zhang,

Zhang

et al. 2024

Advanced Intelligent Systems

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“…Currently, the sinusoids-based non-raster scanning patterns, including the spiral scan, Lissajous scan, cycloid scan, rotational scan, and so on, have been investigated, and thus contribute to a significant increase in the scanning speed. Among these patterns, the Lissajous scan trajectories [8,9], a self-repeating pattern where both the X and Y-axis are driven by sinusoids with a suitable frequency ratio, can be regarded as a promising alternative to the raster scan trajectories with their extremely simple spectrum for both axes and easy implementation for sequential scanning. Although this scanning pattern can alleviate the existing problem of the traditional trajectory itself, the advanced control techniques are still a requisite to handle the residual tracking errors resulting from the hysteresis nonlinearity for ensuring tracking precision.…”

Section: Introductionmentioning

confidence: 99%

Research on Active Repetitive Control for Tracking Lissajous Scan Trajectories with Voice Coil Motors Actuated Fast Steering Mirror

Wang,

Liu,

Liang

et al. 2024

Fractal Fract

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The performance of laser beams in tracking Lissajous scan trajectories is severely limited by beam jitter. To enhance the performance of fast steering mirror (FSM) control in tracking Lissajous scan trajectories, this paper proposed a fractional order active disturbance rejection controller (FOADRC) and verified its effectiveness in improving system scanning tracking accuracy. A dynamic mathematical model of a fast steering mirror was studied, and the design of parameters for the control mode of the closed-loop system was determined. A reduced-order linear active disturbance rejection controller suitable for FSM systems was designed, and the corresponding fractional-order proportional differentiation (FOPD) controller was determined according to the mathematical model. The use of the designed controller enabled high-performance tracking of high-frequency Lissajous scanning curves (X-axis 500 Hz, Y-axis 350 Hz) and met the need for high-frequency repetitive scanning. The controller has the characteristics of simple implementation and low computational complexity and is suitable for closed-loop control applications in engineering.

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Optical fibre positioning and resonant frequency adjustment using intermittent optical feedback for pre-imaging calibration

Leong,

Bahari,

Mokhtar

et al. 2024

Sensors and Actuators A: Physical

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Modified Phase-Offset-Driven Lissajous Scanning Endomicroscopy With a Polyimide-Film-Based Frequency Separator

Cited by 9 publications

References 42 publications

A Novel Flexible Endomicroscopic Scanning Instrument with Visual Servoing Control

A Novel Flexible Endomicroscopic Scanning Instrument with Visual Servoing Control

Research on Active Repetitive Control for Tracking Lissajous Scan Trajectories with Voice Coil Motors Actuated Fast Steering Mirror

Optical fibre positioning and resonant frequency adjustment using intermittent optical feedback for pre-imaging calibration

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