Provided is a multifunctional display device or a multifunctional electronic device. Provided is a display device or electronic device with high visibility. Provided is a display device or electronic device with low power consumption. The electronic device includes a housing, a display device, a system unit, a camera, a secondary battery, a reflective surface, and a wearing tool. The system unit and the secondary battery are each positioned inside the housing. The system unit includes a charging circuit unit. The charging circuit unit is configured to control charging of the secondary battery. The system unit is configured to perform first processing based on imaging data of the camera. The first processing includes at least one of gesture operation, head tracking, and eye tracking. The system unit is configured to generate image data based on the first processing. The display device is configured to display the image data.

A display driver includes interface circuitry, image processing circuitry, and drive circuitry. The interface circuitry is configured to receive a full frame image and a foveal image from a source external to the display driver. The image processing circuitry is configured to: upscale the full frame image; render a foveated image from the upscaled full frame image and the foveal image. The foveated image includes a foveal area based on the foveal image, a peripheral are based on the upscaled full frame image, and a border area based on the foveal image and the upscaled full frame image. The border area being located between the foveal area and the peripheral area. The drive circuitry is configured to drive a display panel using the foveated image.

A display assembly presented herein includes an inset display, a peripheral display, and a multiplexing optical assembly (MOA). The inset display has a first resolution and emits image light of a first polarization. The peripheral display has a second resolution and emits image light of a second polarization. The MOA receives the image light of the first polarization and the image light of the second polarization. The MOA then transforms the image light of the first polarization into a first portion of image light of a third polarization, and transforms the image light of the second polarization into a second portion of image light of the third polarization. The MOA directs the first portion of image light and the second portion of image light toward an eye-box. The display assembly can be implemented as a component of a head-mounted display of an artificial reality system.

A dynamic positioning control system having a transparent or semi-transparent substrate, an image processor, and one or more image-generating elements operatively connected to the image processor configured to simultaneously generate a plurality of images within an overall image-generating-capable field area of the substrate is provided. A dynamic positioning control system having a transparent or semi-transparent substrate, a dimming controller, and a plurality of electrodes operatively connected to the dimming controller configured to dim one or more areas on or within the substrate within an overall electrochromic dimming-capable field area is also provided. The image processor and the dimming controller may be separate elements or may be a single controller.

Aspects of the present disclosure relates to user interface systems and methods for use in head-worn computing systems.

A projection device for smart glasses. The projection device includes an image generating unit for generating at least one first light beam representing image information, and at least one deflecting element, which is configured to deflect the first light beam in the form of a second light beam representing first image information, and to deflect the first light beam in the form of a third light beam representing second image information, into a first field of vision and/or into a second field of vision of an eye; the second light beam and the third light beam differing with regard to a beam divergence; and the second field of vision and the first field of vision at least overlapping.

A head mounted display system to display an image, the head mounted display system comprising a display engine to generate light for a display, the system configured to color specific settings to one or more colors of the light. In one embodiment, the color specific settings comprises one or more of: colors having different resolutions, different focal distances, and different fields of view.

A display device includes a display panel having a first emission region and a second emission region that surrounds the first emission region. The display device includes a first plurality of light emitters arranged in the first emission region, a plurality of activation lines for the first emission region, a second plurality of light emitters arranged in the second emission region, and a plurality of activation lines for the second emission region. A single activation line of the plurality of activation lines for the first emission region is electrically coupled with a first number of light emitters in the first emission region and a single activation line of the plurality of activation lines for the second emission region is electrically coupled with a second number, distinct from the first number, of light emitters in the second emission region.

A display system comprising a foveal display having a monocular field of view of at least 1 degree is positioned within a scannable field of view of at least 20 degrees, the foveal display positioned for a user. In one embodiment, the foveal display is positioned for the user's fovea.

Embodiments include a head-worn display including a display panel sized and positioned to produce a field of view to present digital content to an eye of a user, and a processor adapted to present the digital content to the display panel such that the digital content is only presented in a portion of the field of view, the portion being in the middle of the field of view such that horizontally opposing edges of the field of view are blank areas. The processor is adapted to shift the digital content into one of the blank areas to adjust the convergence distance of the digital content and thereby change the perceived distance from the user to the digital content.