Real-time in situ calibration of an optically trapped probing system

We present real-time in situ calibration of an optically trapped probing system. In the probing system, a micro/nanobead is stably trapped around the minimum of the field potential to serve as the measurement probe, whereas the random thermal force tends to destabilize it and causes Brownian motion...

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Bibliographic Details
Published in:Applied optics. Optical technology and biomedical optics 2009-09, Vol.48 (25), p.4832
Main Authors: Wan, Jingfang, Huang, Yanan, Jhiang, Sissy, Menq, Chia-Hsiang
Format: Article
Language:English
Subjects:
Algorithms
Calibration
Computer Systems
Molecular Probe Techniques - instrumentation
Molecular Probe Techniques - standards
Optical Tweezers - standards
United States
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Summary:We present real-time in situ calibration of an optically trapped probing system. In the probing system, a micro/nanobead is stably trapped around the minimum of the field potential to serve as the measurement probe, whereas the random thermal force tends to destabilize it and causes Brownian motion around the equilibrium. The weighted recursive least-squares algorithm is applied to recursively update the system's parameters, such as the state transition coefficient, and to estimate specific system response and the unknown variance of the Gaussian white noise in real time according to the probe's motion. The real-time recursive algorithm was first applied to real-time calibration of measurement sensitivity and trapping stiffness for the case that the local temperature and the damping coefficient of the probe are known. It was then applied to estimate the probe's local temperature in real time. Two experiments were designed to illustrate the applicability of the real-time calibration method. The experimental results show that the recursive algorithm is able to real-time calibrate the trapping stiffness of the probing system and the measurement sensitivity of the back-focal-plane interferometry employed for position measurement. The experimental results also show that the method can estimate the probe's local temperature in real time.
ISSN:2155-3165
DOI:10.1364/AO.48.004832