Described embodiments provide a method, computer program product, and computer system for identifying, by a computing device, that an image is captured. A face in the image may be identified. An eye of the face in the image may be detected. A pupil of the eye included in the image may be detected, wherein the pupil may include objects reflected by the pupil. The objects reflected by the pupil may be augmented by augmenting the pupil in the image.

Described embodiments provide a method, computer program product, and computer system for identifying, by a computing device, that an image is captured. A face in the image may be identified. An eye of the face in the image may be detected. A pupil of the eye included in the image may be detected, wherein the pupil may include objects reflected by the pupil. The objects reflected by the pupil may be augmented by augmenting the pupil in the image.

A head mounted display (HMD) comprises an eye tracking system configured to enable eye-tracking using light. The eye tracking system comprises two or more illumination sources positioned relative to one another and an optical detector in order to capture. The optical detector is configured to capture images of the cornea based on one or more reflections. The eye tracking unit is configured to generate a model of the user's eye. The generated eye model is used to determine eye tracking information such as gaze direction as the user glances at different objects in the HMD.

A processing apparatus includes a corrector that, when the object is sequentially irradiated with light from three or more light sources with mutually different positions, corrects a light source condition to calculate surface normal information of an object on the basis of brightness of each of the light sources.

A processing apparatus includes a corrector that, when the object is sequentially irradiated with light from three or more light sources with mutually different positions, corrects a light source condition to calculate surface normal information of an object on the basis of brightness of each of the light sources.

A head mounted display (HMD) comprises an eye tracking system configured to perform a calibration process using an eye tracking system of the HMD that includes determining a pupillary axis and/or determining an angular offset between the pupillary axis and the eye's true line of sight. The eye tracking system obtains an eye model captures images of the user's pupil while the user is looking at a target or other content displayed on the HMD. In some embodiments, the calibration process is based on a single image of the user's eye and is performed only once. For example, the process can be performed the first time the user uses the HMD, which stores the calibration data for the user in a memory for future use.

Systems and methods of forming and analyzing a dissolvable article are provided herein. In an embodiment, a method of forming a dissolvable article with excellent dissolution performance includes heating a dissolvable composition that includes a water-soluble block copolymer at heating conditions that are sufficient to render the copolymer flowable and to form a hot melt composition. The water-soluble block copolymer is solid at ambient conditions. The method further includes solidifying the dissolvable composition to form the dissolvable article. A surface of the dissolvable article is analyzed for surface texture using a three-dimensional imaging device to produce a data set that is representative of the surface texture. If the data set fails to at least equal a predetermined threshold value, the method further includes reformulating the dissolvable composition to form a reformulated dissolvable composition.

A system and method for compensating for reflections caused by light-generating objects in the scene facing a display device includes capturing images of the scene. Reflection-inducting zones corresponding to the light generating objects are identified from the captured images. The reflection effect on the display device from the reflection-inducing zones are estimated. A target image to be displayed on the display device is adjusted based on the estimated reflection effect.

A system and method for compensating for reflections caused by light-generating objects in the scene facing a display device includes capturing images of the scene. Reflection-inducting zones corresponding to the light generating objects are identified from the captured images. The reflection effect on the display device from the reflection-inducing zones are estimated. A target image to be displayed on the display device is adjusted based on the estimated reflection effect.

A flying drone for inspecting surfaces able to reflect light has a lighting device formed of two light sources each having a shape that is elongate in a longitudinal direction of each of the light sources, two first image acquisition devices, and a second image acquisition device between the two first image acquisition devices. The two light sources are respectively between the second image acquisition device and each of the first image acquisition devices. The flying drone allows effective detection of dents in surfaces by analyzing specular reflections, by the lighting device and of the first image acquisition devices, and effective detection of superficial defects on surfaces by the second image acquisition device, with the lighting device switched off.