A system and method in which information relevant to a Photovoltaic (PV) solar-site specific activity environment is displayed on the display screen of an Augmented Reality (AR) device as part of the surrounding environment, instead of on a separate computing device or an installation manual. The activity environment includes PV solar site-specific survey and feasibility analysis, installation and commissioning, Operation and Maintenance (O&M), and site overhaul/removal activities. Thus, relevant information is available to an installer/technician at their fingertips so that the installer/technician can continue the task they are involved in without losing focus. The AR device may record relevant data during site survey and note important points, accelerate installation and commissioning, make O&M more efficient, and record the complete process for ongoing improvement/management of the site. Moreover, company-specific best practices may be loaded on the AR device as guidelines to make the process uniform across the entire fleet of installers.

In one embodiment, a first computing server receives a message from a client computing device. The message identifies an image to be displayed on the client computing device. The message is generated by a second computing server and received by the client computing device in response to a request sent by the client computing device to the second computing server for the identified image. The first computing server determines one or more adjustment parameters based on the display capabilities of the client computing device. The first computing server creates an adjusted version of the identified image based on the adjustment parameters, and sends the adjusted version of the identified image to the client computing device for display.

A mobile electronic device may have a flexible organic light emitting diode (OLED) multi-touch display with a pixel layer and an adaptive layer. The adaptive layer may include a resizable display area capable of being made semi-transparent by the controller.

A system and method in which information relevant to a Photovoltaic (PV) solar-site specific activity environment is displayed on the display screen of an Augmented Reality (AR) device as part of the surrounding environment, instead of on a separate computing device or an installation manual. The activity environment includes PV solar site-specific survey and feasibility analysis, installation and commissioning, Operation and Maintenance (O&M), and site overhaul/removal activities. Thus, relevant information is available to an installer/technician at their fingertips so that the installer/technician can continue the task they are involved in without losing focus. The AR device may record relevant data during site survey and note important points, accelerate installation and commissioning, make O&M more efficient, and record the complete process for ongoing improvement/management of the site. Moreover, company-specific best practices may be loaded on the AR device as guidelines to make the process uniform across the entire fleet of installers.

A pixel circuit includes a first organic light emitting diode (OLED), a second OLED, a storage unit coupled to a data line, the storage unit including a first capacitor configured to store at least one of a first data signal and a second data signal received via the data line, a first driver including a second capacitor configured to store the first data signal received via the storage unit, and a first transistor configured to control an amount of a current supplied to the first OLED in response to a voltage stored in the second capacitor, and a second driver including a third capacitor configured to store the second data signal received via the storage unit, and a second transistor configured to control an amount of a current supplied to the second OLED in response to a voltage stored in the third capacitor.

Particular embodiments described herein provide for a wearable electronic device, such as a bracelet, watch, wristband or armband. One particular example implementation of a wearable electronic device may include a first display screen, a second display screen, and logic. At least a portion of the logic is implemented in hardware. The logic is configured to receive a communication over a wireless network, and to display, in the first display screen, a communication alert. The communication alert can be a graphic design. The logic is also configured to receive input data indicative of a screen transition input to view information associated with the communication, and to display, in the second display screen, the information associated with the communication. In further embodiments, the graphic design includes a notification pattern indicating one or more attributes of the communication. In further embodiments, the first and second display screens form a single display screen.

A display device (100) includes: a display panel (1) capable of being in a transparent display state where a background scene is viewable through the display panel; a panel light source (3) that irradiates the display panel with colored light of a plurality of colors in a time division manner; a rear side light source (2) placed on a rear surface side of the display panel, the rear side light source being capable of emitting colored light of a plurality of colors in a time division manner; and a control circuit that controls emission timings of the colored light from the panel light source and from the rear side light source, wherein the panel light source and the rear side light source are synchronized by the control circuit such that colored light of different colors are not emitted at a same timing.

The present invention is a coin device having a module containing a display screen a power source and a system board providing circuitry to link all of the components of the present invention. The display screen and internal circuitry are protected by an outer shell, which forms a protective casing around the coin. The outer shell may be made of any material, including conventional metals and alloys used in minting. The circuitry may or may not be detachable from the protective casing.

Augmented reality extrapolation techniques are described. In one or more implementations, a frame of an augmented-reality display is rendered based at least in part on an optical basis that describes a current orientation or position of at least a part of a computing device. While the frame is rendered, an extrapolation based on a previous basis and a sensor basis generates an updated optical basis that describes a likely orientation or position of the part of the computing device, and the extrapolation is effective to account for a lag time duration between rendering the frame and displaying the frame of the augmented-reality display. The rendered frame of the augmented-reality display is updated before the rendered frame is displayed based at least in part on the updated optical basis that describes the likely orientation or position of the part of the computing device.

A stereoscopic image is displayed with an appropriate amount of parallax on the basis of auxiliary information recorded in a three-dimensional image file. A 2D image file is read (Step S31), and the size of a display which performs 2D display is acquired (Step S32). The maximum display size capable of appropriately performing 2D display of a viewpoint image is acquired from metadata of the read 2D image file (Step S33). The size acquired in Step S32 is compared with the maximum display size acquired in Step S33 (Step S34). When the maximum display size is smaller, parallax displacement or parallax compression is performed, (Step S35), and then 2D display is performed (Step S36). Therefore, display can be appropriately performed on the basis of the maximum display size.