The pupil response to light is usually used for inspection of a patient's activity. When medical personnel performs light reflection examinations, it depends on the experience of medical staff. Even for the same person, they may induce variant measurement results in different situations. This paper proposes an algorithm that can calculate pupil size based on Convolution Neural Network (CNN). The study aims to measure pupil size on a mobile device convenient for medical staff to measure real-time. Still, the shape of the pupil is not round, and 50% of pupils can be calculated using ellipses for the best fitting. Therefore, we use the major and minor axis of an ellipse to represent the size of pupils and use the two parameters as the output of the network. The compares the mean error with changing the depth of the network and the field of view (FOV) of the convolution filter. Finally, the mean error of the pupil length is 7.63%. The result shows that both deepening the network and widening the FOV of the convolution filter can reduce the mean error. In the operation speed, we use mobile device systems at 36 frames per second to use mobile device systems for pupil size prediction.
A set of high-efficiency optical coupler design methods that can be used to collect multiple light sources for compression and integrate them into one light source outlet is proposed. It adopts parabolic confocal principle and high reflectivity coating and completes the structural design with the formulation concept. In addition to direct sunlight collection, the optical coupler is also coupled to the exit source of the collection subsystem of a natural light illumination system (NLIS). The concept of NLIS is to collect sunlight and direct it into indoor lighting. Due to the numerous light sources and the nonparallel light exiting from the light collection subsystem, it is inconvenient for space utilization and back-end transmission. Therefore, the actual NLIS structure is considered as a coupler to improve the efficiency of this design. The optical software used in this study was Fred. Finally, coupling 900 light sources still maintains 50.28% coupler efficiency. The results show that this optical coupler can provide perfect use in the application, and also solve the export problem, and finally achieve high coupler efficiency.
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