Super-sensitivity incoherent optical methods for full-field displacement measurements
Document Type
Article
Publication Date
2022
Department
Department of Mechanical Engineering-Engineering Mechanics
Abstract
The sensitivity of incoherent optical methods using video cameras (e.g., optical flow and digital image correlation) for full-field displacement measurements, defined by the minimum measurable displacements, is essentially limited by the finite bit depth of the digital camera due to the quantization with round-off error. Quantitatively, the theoretical sensitivity limit is determined by the bit depth B as δp = 1/(2B − 1) [pixel] which corresponds to a displacement causing an intensity change of one gray level. Fortunately, the random noise in the imaging system may be leveraged to perform a natural dithering to overcome the quantization, rendering the possibility of breaking the sensitivity limit. In this work we study such a theoretical sensitivity limit and present a spatiotemporal pixel-averaging method with dithering to achieve super-sensitivity. The numerical simulation results indicate that super-sensitivity can be achieved and is quantitatively determined by the total pixel number N for averaging and the noise level σn as δp∗ ∝ (σn/√N)δp.
Publication Title
Optics Letters
Recommended Citation
Li, S.,
&
Yang, Y.
(2022).
Super-sensitivity incoherent optical methods for full-field displacement measurements.
Optics Letters,
47(21), 5453-5456.
http://doi.org/10.1364/OL.471481
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/16589