A visual display assembly useful as an authentication or anti-counterfeiting element. The assembly includes a substrate and, on a surface of the substrate, an array of micro mirrors receiving ambient light. Each mirror includes a reflective surface to reflect the ambient light to display an image that appears to float in a plane, which is spaced a distance apart from the surface of the substrate. The image includes a plurality of pixels, and the array of micro mirrors includes for each of the pixels a set of the micro mirrors each having a reflective surface oriented to reflect the ambient light toward a point on the plane corresponding to one of the pixels. Each of the sets of the micro mirrors includes a plurality of the micro mirrors, and the reflected ambient light each set of micro mirrors intersects to illuminate or write a pixel of an image.

A lighting module is disclosed. The lighting module includes a light emitting diode (LED) light source, and a total internal reflection (TIR) optical assembly. The optical assembly includes a refractor configured to be located proximate to the LED light source, and a reflector configured to be attached to the refractor. The refractor is made from a material that is resistant to thermal damage when exposed to heat generated by the LED light source.

A head-mounted display (HMD) system includes an optical arrangement; a first image panel, wherein the optical arrangement directs image light from the first image panel along a first optical pathway; a second image panel, wherein the optical arrangement directs image light from the second image panel along a second optical pathway different from the first optical pathway; and a third image panel and a fourth image panel, wherein the third and fourth image panels are spaced apart from each other and the optical arrangement directs light from the third image panel and the fourth image panel along different optical pathways. The optical arrangement is configured such that light from the first image panel and the third image panel are emitted from the HMD system in a combined fashion in a first eye direction, and light from the second image panel and the fourth image panel are emitted from the HMD system in a combined fashion in a second eye direction different from the first eye direction.

An optical device includes a plurality of light sources each configured to emit light having a different wavelength, and a lens mirror array in which a plurality of optical elements is arrayed, each of the plurality of optical elements including an incident surface through which the light emitted from each light source enters the optical element, a first reflection surface from which the light incident on the incident surface is reflected, a second reflection surface from which the light reflected by the first reflection surface is further reflected, and an emission surface through which the light reflected by the second reflection surface exits the optical element. The plurality of light sources is arranged such that a light source that emits light having a shorter wavelength is disposed farther from the second reflection surface.

A focusing device (1) comprises a base unit (12) and a mirror unit (11) which is translatable relative to the base unit parallel to an optical axis (A) of the focusing device. The minor unit (11) is configured to receive incident light along the optical axis (A) in a first direction and to reflect the incident light parallel with the optical axis (A) in said first direction. The minor unit (11) comprises at least four minors (21-24), at least one of the mirrors being curved.

Methods, devices, and systems for elongating a beam path of a light beam, in particular of a laser beam, are provided. An example method includes coupling the light beam into an interspace between a plurality of first reflective surfaces and a plurality of second reflective surfaces facing the first reflective surfaces, multiply reflecting the light beam between the first reflective surfaces and the second reflective surfaces to elongate the beam path of the light beam, and coupling out the light beam from the interspace. The light beam undergoes the steps of coupling in, repeated reflecting and coupling out at least a first time with a first pass and a second time with a second pass, and the light beam traverses a different beam path in the interspace during the first pass in comparison with during the second pass.

In order to achieve a relatively small installation height of a multi-aperture imaging device having a one-line array of adjacently arranged optical channels, lenses of the optics of the optical channels are attached to a main side of a substrate by one or more lens holders and are mechanically connected via the substrate, the substrate being positioned such that the optical paths of the plurality of optical channels pass therethrough.

A display device includes an array of light emitting elements and a plurality of optical elements for receiving light from the array of light emitting elements where each optical element is configured to provide a collimated light beam.

A lens system includes a first lens array assembly including a first plurality of cells, each cell of the first plurality of cells configured to exhibit a pair of first Fourier transform lenses, and a second lens array assembly including a second plurality of cells, each cell of the second plurality of cells configured to exhibit a pair of second Fourier transform lenses. The first and second lens array assemblies are positioned relative to one another along an optical axis of the lens system such that light diverging from an object at a plane disposed at an object conjugate distance from the first lens array assembly reconverges at an image plane after passing through the first and second lens array assemblies. The image plane is disposed at an image conjugate distance from the second lens array assembly in accordance with the object conjugate distance.

A head-mounted display (HMD) system includes an optical arrangement; a first image panel, wherein the optical arrangement directs image light from the first image panel along a first optical pathway; a second image panel, wherein the optical arrangement directs image light from the second image panel along a second optical pathway different from the first optical pathway; and a third image panel and a fourth image panel, wherein the third and fourth image panels are spaced apart from each other and the optical arrangement directs light from the third image panel and the fourth image panel along different optical pathways. The optical arrangement is configured such that light from the first image panel and the third image panel are emitted from the HMD system in a combined fashion in a first eye direction, and light from the second image panel and the fourth image panel are emitted from the HMD system in a combined fashion in a second eye direction different from the first eye direction.