Title :
Quantification of Thermal Lensing Using an Artificial Eye
Author :
Towle, E.L. ; Rickman, M. ; Dunn, A.K. ; Welch, A.J. ; Thomas, R.J.
Author_Institution :
Air Force Res. Lab., Fort Sam Houston, TX, USA
Abstract :
Recent experiments have concluded that it is possible to interrupt the vision of human subjects using infrared (IR) light through an effect known as thermal lensing. While these experiments successfully demonstrated the influence of thermal lensing on an Amsler grid target, little has been done to quantify the amount of visual disruption resulting from this phenomenon. Therefore, an artificial eye system was configured to better quantify the refractive power of the thermal lens generated within the human eye. The influence of 1319 nm energy with power levels from 220 to 630 mW and exposure durations between 0.25 and 1.00 s was evaluated based on changes induced within a visible probe beam (542 nm). Results showed up to a -2.0 D blur could be induced in human subjects using these energy levels. Results also established a relationship between the peak IR power and exposure durations used to determine the strength of the thermal lens.
Keywords :
artificial organs; bio-optics; eye; infrared imaging; thermal lensing; vision; Amsler grid target; artificial eye; blur; exposure durations; human eye; human subject vision; human subjects; infrared light; peak IR power; power 220 mW to 630 mW; refractive power; thermal lensing quantification; visible probe beam; visual disruption; wavelength 1319 nm; wavelength 542 nm; Biological tissues; Infrared detectors; Lasers; Nonlinear optics; Thermal analysis; Cain cell; laser-tissue interaction; nonlinear optics; thermal blooming;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2013.2260728
