Device localization (e.g., ultra-wideband device localization) may be used to provide coordinated outputs and/or receive coordinated inputs using multiple devices. Providing coordinated outputs may include providing partial outputs using multiple devices, modifying an output of a device based on its position and/or orientation relative to another device, and the like. In some cases, each device of a set of multiple devices may provide a partial output, which combines with partial outputs of the remaining devices to produce a coordinated output.

Fast wireless communicators are used to carry out functions in a stage lighting display environment. LED tiles can be equipped with fast Internet such as 5G, and each of a number of LED tiles in an array can define an address that represents a part of the array. The video processor can break up an image into different parts for each LED tile of the array and send those different parts to the array.

In a display control device, a first display control unit displays values of a plurality of molding conditions in a first display area, on the basis of layout information including a display size and a display position of the plurality of molding conditions. A data setting unit sets as molding data the values of the plurality of molding conditions that are displayed in the first display area. On the basis of the layout information, and in the same layout as that of the first display area, a second display control unit displays for inspection in a second display area the values of the plurality of molding conditions based on the molding data which are stored in a storage unit.

In one example, a method may include receiving a wireless signal from a device. The device may be within an environment. The method may also include identifying the device. The device may be identified based on at least one of data and metadata included in the wireless signal. In addition, the method may include determining a location of the device within the environment. The location of the device within the environment may be determined based on the data included the wireless signal. Further, the method may include displaying an augmented environment representative of the environment and a symbol representative of the device within the augmented environment. The symbol may be displayed in a location within the augmented environment corresponding to the location of the device within the environment.

A visualization system provides graphics for presentation on displays of multiple users who may be wearing head-mounted displays (HMDs). In an embodiment, the system determines that a first gaze direction of a first user is directed toward a first display. The system determines user inputs performed by the first user. The user inputs may be hands-free such as gestures of a hand or finger or voice commands. The system generates a graphical annotation using the user inputs. The system provides the graphical annotation to a first HMD for presentation to the first user. The system determines a second display paired to the first display. The system provides the graphical annotation to a second HMD for presentation to a second user looking at the second display. The displays may include a physical display or a virtual display, for example, in an augmented reality environment.

Methods, systems and devices for displaying video content on large, high resolution video walls, which may comprise a mesh network of an array of display tiles with redundant network switching, in which a virtual, unlimited pixel canvas is created in a video controller memory to facilitate packetizing and addressing of video content packets for delivery to the video wall through a packet-switched network. Embodiments disclosed are particularly well-suited for use with video walls employing LED tiles.

Systems and methods for generating multi-monitor recommendations. In some embodiments, an Information Handling System (IHS) may include: a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: collect window information during use of the IHS; and create a multi-monitor recommendation based, at least in part, upon the window information.

An embodiment for adjusting digital content in a flexible display device is provided. The embodiment may include receiving data relating to a position and orientation of a reference device relative to a user. The embodiment may also include identifying an orientation of a display surface of a mobile device and a relative position of the mobile device relative to a viewing direction of the user. The embodiment may further include identifying an optimal viewing angle of display content on the display surface of the mobile device. The embodiment may also include in response to determining the display content is not able to be displayed as a hologram, aligning the display content as text based on the optimal viewing angle. The embodiment may further include presenting the aligned display content as text to the user.

Methods and systems are disclosed for sharing a content item from a secondary computing device to a primary computing device based on a tilt position of the secondary computing device. A sensor on the secondary computing device determines that the secondary computing device has a first tilt position that is associated with a non-sharing mode. The sensor senses that the secondary computing device is tilting from the first tilt position towards a second tilt position that is associated with a full sharing mode. In response, the content item is begun to be shared with the primary computing device. An amount of the content item that is shared with the primary computing device is continued to be increased as long as the sensor continues to sense that the secondary computing device is tilting from the first tilt position towards the second tilt position. The sensor senses that the secondary computing device has reached the second tilt position and shares the entire content item with the primary computing device.

In embodiments, an electronic device includes: a foldable housing that includes a hinge, a first housing connected to the hinge, the first housing having a first surface facing a first direction and a second surface facing a second direction opposite the first direction, and a second housing connected to the hinge and configured to be foldable with the first housing around the hinge, the second housing having a third surface facing a third direction and a fourth surface facing a fourth direction opposite the third direction. The first surface faces the third surface in a folded state, and the third direction is equal to the first direction in an unfolded state. The electronic device further includes a first display extending from the first surface to the third surface to define the first and third surfaces, a second display viewable through at least a part of the second or fourth surface, at least one sensor, a processor disposed in the first or second housing structure, and a memory operatively connected to the processor. The memory stores instructions which, when executed, cause the processor to control the electronic device to display a plurality of applications on the first display in the unfolded state, to select at least one of the plurality of applications, based on an input or priorities of the plurality of applications, based on the at least one sensor detecting that the foldable housing is changed from the unfolded state to the folded state, and to display the selected application on the second display.