A smart glasses include: a main frame having an eyeglass frame shape; a support frame coupled to a central portion of the main frame; a first display supported by the support frame and displaying a first image; a second display supported by the support frame and displaying a second image; a first mirror for reflecting the first image; a second mirror for reflecting the second image; a first main lens for providing a first main image from the central portion of the main frame to the inside thereof on the basis of the first image reflected by the first mirror; and a second main lens for providing a second main image from the central portion of the main frame to the inside thereof on the basis of the second image reflected by the second mirror.

An optical attachment for surgical loupe glasses is disclosed. The optical attachment for surgical loupe glasses includes a visor sized to cover at least a portion of a first carrier lens of the surgical loupe glasses. The optical attachment also includes at least one loupe orienting feature defined by the visor.

A user-wearable fluorescence based visualization system comprising a multi-light lamp assembly that provides for the selected output of light using multiple light emitting sources, wherein the outputted light may be tailored to generate response wavelength by the interaction of the emitted light and a tissue illuminated by the emitted light, through the process of fluorescence, and a viewing system that allows a practitioner view the fluorescent light generated by the tissue, and distinguish between healthy and diseased tissues.

An assembly with removable and replaceable wire arms is used to attach different nose pad configurations to eyeglass frames for enhanced versatility. A plate with front and back surfaces and opposing side edges mounts on the bridge portion of the eyeglass frames. Opposing right and left wire members extending downwardly from the side edges of the plate terminate in a coupling mechanism adapted to receive a nose pad. The wire members are manually bendable, enabling a user to independently adjust the distance between the nose pads and the distance of the nose pads from the eyeglass frames. The coupling mechanisms may include holes to receive nose pads with posts, and screws to hold the posts in position, or barbed fins to receive nose pads with slots that engage with the barbed fins. The coupling mechanisms may receive physically separate nose pads or nose pads interconnected through an upper nose rest.

A method is presented that includes providing a set of spectacle magnifiers, each magnifier in the set having a different corresponding diopter value, the magnifiers together providing a sequence of evenly incremented diopter values. The set further includes a magnifier having a lowest value (MAG.sub.0), a magnifier having a highest value (MAG.sub.N), and one or more magnifiers having values between those of MAG.sub.0 and MAG.sub.N. In one or more embodiments, the diopter value increment between any two successive magnifiers of the set is equal to K(0.1) log, where K is an integer>0 or a fraction whose denominator is an integer>0. In one or more embodiments, one or more elements of the set are packaged for sale. In some embodiments, a set of optical, telescopic, or electronic magnification devices may be provided, the set including one or more devices configured to provide non-rectilinear magnification.

A hands free integrated personal task lighting system for dental or surgical use providing remote control light activation and selective adjustable light intensity output. A fixed output value light source on a headset has an electronically activated variable transmission glass which changes transparency to degrees of translucentness by varied electrical activation. The light system provides both remote light activation and illumination value control by variable control sensors in a hands-free environment including temperature sensing activation control.

An eye shield has an attachment device configured to be coupled to an optical device. The attachment device includes a clamping ring that has an open position and a closed position. The eye shield further has a shield coupled to the clamping ring to pivot away and towards the clamping ring, the shield extends laterally from the attachment device and a locking element that is disposed on the clamping ring and configured to lock the clamping ring in the closed position. The locking element has a locked and an unlocked position, and when the locking element is in the locked position the clamping ring is in the closed position.

A lighting device comprising a plurality of lighting modules arranged concentrically about an optical axis is disclosed wherein the plurality of lighting modules emit light in at least one of a plurality of wavelength ranges (UV, visible (e.g., blue, green, yellow, orange, red, white, etc.), IR) and are arranged at a non-parallel angle to an optical axis of the lighting device, wherein the emitted light is directed towards a lens system that focuses the light onto a viewing point. A second lighting device is disclosed, wherein the lighting device comprises a plurality of lighting modules arranged concentrically about an inner circumference of the lighting device, wherein the plurality of lighting modules emit light in at least one of a plurality of wavelength ranges (UV, visible (e.g., blue, green, yellow, orange, red, white, etc.), IR) onto a lighting director device that redirects the emitted light toward a lens system that focuses the light onto a viewing point.

An electro-active lens provides simultaneous focusing at two different optical powers. It does this with a stack of electro-active lens elements aligned along the same optical axis that each focus light in different polarization states (e.g., horizontal and vertical polarization states). If a first and second electro-active lens elements have different optical powers, light in a first polarization state can be focused to one optical power and light in a second polarization state can be focused to a different optical power simultaneously. The electro-active lens can be switched between different single and multiple optical powers. People with presbyopia may use the electro-active lens mounted in eyewear in place of conventional bifocal glasses. The electro-active lens may also be used in a scope to improve target aiming.

A lighting device comprising a plurality of lighting modules arranged concentrically about an optical axis is disclosed wherein the plurality of lighting modules emit light in at least one of a plurality of wavelength ranges (UV, visible (e.g., blue, green, yellow, orange, red, white, etc.), IR) and are arranged at a non-parallel angle to an optical axis of the lighting device, wherein the emitted light is directed towards a lens system that focuses the light onto a viewing point. A second lighting device is disclosed, wherein the lighting device comprises a plurality of lighting modules arranged concentrically about an inner circumference of the lighting device, wherein the plurality of lighting modules emit light in at least one of a plurality of wavelength ranges (UV, visible (e.g., blue, green, yellow, orange, red, white, etc.), IR) onto a lighting director device that redirects the emitted light toward a lens system that focuses the light onto a viewing point.