Abstract: According to certain embodiments, an image system comprises a display and a controller. A portion of the display is capable of a first visual fidelity level which is the highest visual fidelity capability of the display. The controller is configured to determine a first location of a point on the display where the center of gaze of a user intersects the display and determine a plurality of concentric regions on the display sharing a common center determined at least in part on the first location of the point. The controller is further configured to communicate a command to the display to reduce the angular and spatial resolution of selected regions below the first visual fidelity level, the reduction in visual fidelity of each region determined at least in part on a proximity of each region from the first location of the point, such that the regions farther from the point have greater levels of reduction in visual fidelity.

Abstract: In one embodiment, an electronic camera assembly includes a circuit board and a plurality of sensor facets. Each sensor facet is coupled to a respective one of a plurality of facet locations on one side of the circuit board. Each sensor facet includes a plurality of sensor pixels. Each sensor facet can capture light at a plurality of capture resolutions. Each sensor facet includes a selectable capture resolution from the plurality of capture resolutions. Each sensor facet is individually addressable such that the plurality of sensor facets are configurable to provide heterogeneous capture resolutions. Each particular facet location is configured to transmit signals from a particular sensor facet that is electrically coupled to the particular facet location to a display, thereby displaying light on the display that corresponds to light captured at a particular selected capture resolution by the particular sensor facet.

Abstract: In one embodiment, an electronic display assembly includes a circuit board, a microlens layer, a pixel array layer, and a logic unit layer. The microlens layer includes cells that are arranged in a grid pattern that includes a center cell and a plurality of surrounding cells around the center cell. The pixel array layer includes a plurality of display pixels. The logic unit layer includes logic configured to display, using some of the plurality of display pixels, a sub-image in each particular cell of the first plurality of cells and to access vision correction parameters of a user. The logic is further configured to perform linear transformations on a plurality of the sub-images of the surrounding cells according to the vision correction parameters of the user and to shift the plurality of sub-images of the surrounding cells according to the linear transformations, thereby providing digital vision correction for the user.

Abstract: In one embodiment, an electronic display assembly includes a microlens layer and a pixel array layer. The microlens layer includes a plurality of cells. The pixel array layer is adjacent to the microlens layer. The pixel array layer includes a plurality of pixels. Each cell of the plurality of cells includes a transparent lenslet and one or both of: a plurality of opaque walls configured to prevent light from bleeding into adjacent cells; and a filter layer on one end of each cell of the plurality of cells. The filter layer is configured to limit light passing through the filter layer to a specific incident angle.

Abstract: In one embodiment, an electronic display assembly includes a sensor array located on one side of a circuit board and an electronic display array located on an opposite side of the circuit board from the sensor array. The sensor array includes a plurality of sensor pixel units. Each sensor pixel unit includes a plurality of sensor pixels. The electronic display array includes a plurality of display pixel units. Each display pixel unit includes a plurality of display pixels. Each particular one of the plurality of sensor pixel units is mapped to a corresponding one of the plurality of display pixel units such that display pixels of each particular one of the plurality of display pixel units display light corresponding to light captured by sensor pixels of its mapped sensor pixel unit.

Abstract: In one embodiment, an electronic display assembly includes a circuit board and a plurality of display facets. Each display facet is coupled to one side of the circuit board. Each display facet includes a plurality of display pixels. Each display facet includes a selectable display resolution from a plurality of display resolutions. Each display facet is individually addressable such that the plurality of display facets are configurable to provide heterogeneous display resolutions. The circuit board includes a plurality of facet locations. Each particular facet location is configured to transmit signals to a particular display facet that is electrically coupled to the particular facet location, thereby displaying light on the particular display facet at a particular selected display resolution.

Abstract: In one embodiment, an electronic display assembly includes a sensor array located on one side of a circuit board, an electronic display array located on an opposite side of the circuit board from the sensor array, and a logic unit layer coupled to one side of the circuit board. The logic unit layer is configured to receive first signals from the sensor array, perform at least one operation on the received first signals to create second signals, and transmit the second signals to the electronic display array. The first signals are communicated using a particular signal protocol and correspond to light captured by sensor pixels of the sensor array. The second signals are communicated using the particular signal protocol of the first signals and are operable to instruct the electronic display array to display light corresponding to the light captured by the plurality of sensor pixels.

Abstract: In one embodiment, an electronic display assembly includes a circuit board, a first microlens layer on a first side of the circuit board, and a second microlens layer on an opposite side of the circuit board from the first microlens layer. The first microlens layer includes a first plurality of microlenses, and the second microlens layer includes a second plurality of microlenses. The electronic display assembly further includes an image sensor layer adjacent to the first microlens layer and a display layer adjacent to the second microlens array. The image sensor layer includes sensor pixels for detecting incoming light through the first microlenses, and the display layer includes display pixels for emitting light through the second microlenses. The electronic display assembly emulates transparency by emitting light from the second microlenses at angles that correspond to angles of the incoming light detected through the first microlenses.

Abstract: In one embodiment, a flexible circuit board includes a plurality of facet locations that each correspond to a particular one of a plurality of rigid sensor facets and a particular one of a plurality of rigid display facets. The flexible circuit board also includes a plurality of wire traces that serially connect the plurality of facet locations. The facet locations are arranged into a plurality of facet columns. When the flexible circuit board is flat, at least some of the facet locations are separated from one or more adjacent facet locations by a plurality of gaps. When the flexible circuit board is formed into a three-dimensional shape, the plurality of gaps are substantially eliminated, thereby permitting the plurality of rigid sensor facets to form a continuous sensing surface and the plurality of rigid display facets to form a continuous display surface.