The present disclosure relates to a light exposure monitoring system that includes a central control server; a plurality of indoor light exposure zones and a positioning system configured to communicate with the central control server to determine: a position (P) of an individual within the plurality of indoor light exposure zones, and a distance between a head of the individual and a floor within the plurality of indoor light exposure zones.

The present disclosure relates to a light exposure monitoring system that includes a central control server; a plurality of indoor light exposure zones and a positioning system configured to communicate with the central control server to determine: a position (P) of an individual within the plurality of indoor light exposure zones, and a distance between a head of the individual and a floor within the plurality of indoor light exposure zones.

The present disclosure relates to a light exposure monitoring system that includes a central control server; a plurality of indoor light exposure zones and a positioning system configured to communicate with the central control server to determine: a position (P) of an individual within the plurality of indoor light exposure zones, and a distance between a head of the individual and a floor within the plurality of indoor light exposure zones.

A method is provided that includes discriminating an autofluorescence (AF) response of a lens tissue of an eye due to a current level of 2-(2-furoyl)-4(5)-furanyl-1H-imidazole (FFI) in the lens tissue by interrogating a lens tissue of an eye along a visual axis of the eye by activating an illuminator for a select time to produce interrogating irradiation having a peak wavelength of 425 nm to 460 nm, the illuminator comprising at least one light source and a focal lens positioned with respect to the light source. The method also includes obtaining at least one image of the autofluorescence response of the lens tissue from a detector, the detector including a digital camera unit, analyzing the at least one image to determine a total autofluorescence index of the lens tissue, and determining a current level of FFI in the lens tissue based, at least in part, on the total autofluorescence index.

A method is provided that includes discriminating an autofluorescence (AF) response of a lens tissue of an eye due to a current level of 2-(2-furoyl)-4(5)-furanyl-1H-imidazole (FFI) in the lens tissue by interrogating a lens tissue of an eye along a visual axis of the eye by activating an illuminator for a select time to produce interrogating irradiation having a peak wavelength of 425 nm to 460 nm, the illuminator comprising at least one light source and a focal lens positioned with respect to the light source. The method also includes obtaining at least one image of the autofluorescence response of the lens tissue from a detector, the detector including a digital camera unit, analyzing the at least one image to determine a total autofluorescence index of the lens tissue, and determining a current level of FFI in the lens tissue based, at least in part, on the total autofluorescence index.

An image following information detecting device capable of obtaining information for causing a central portion of an image to follow a line-of-sight of a user. The device includes: an image display system including an image light projecting unit, and a transmissive reflection member that reflects a part of the image light toward an eyeball and transmits other parts; and a line-of-sight detection system including at least one invisible light source, a diffractive optical element provided integrally with the transmissive reflection member and including a reflective diffraction portion that reflects and diffracts invisible light toward the eyeball, and a light receiving element that receives the invisible light reflected by the eyeball. A portion irradiated with a central portion of the image light of the transmissive reflection member and the reflective diffraction portion overlap each other when viewed from a thickness direction of the transmissive reflection member.

An image following information detecting device capable of obtaining information for causing a central portion of an image to follow a line-of-sight of a user. The device includes: an image display system including an image light projecting unit, and a transmissive reflection member that reflects a part of the image light toward an eyeball and transmits other parts; and a line-of-sight detection system including at least one invisible light source, a diffractive optical element provided integrally with the transmissive reflection member and including a reflective diffraction portion that reflects and diffracts invisible light toward the eyeball, and a light receiving element that receives the invisible light reflected by the eyeball. A portion irradiated with a central portion of the image light of the transmissive reflection member and the reflective diffraction portion overlap each other when viewed from a thickness direction of the transmissive reflection member.