In examples provided herein, upon receiving notification of a computational task requested by a package to provide an experience to a user, a remote node management engine identifies computing nodes for performing the computational task and determining available processing resources for each computing node, where a computing node resides at networked wearable devices associated with the user. The remote node management engine further selects one of the computing nodes as a primary controller to distribute portions of the computational task to one or more of the other computing nodes and receive results from performance of the portions of the computational task by the other computing nodes, and provides to the selected computing node information about available processing resources at each computing node.

In examples provided herein, upon receiving notification of a computational task requested by a package to provide an experience to a user, a remote node management engine identifies computing nodes for performing the computational task and determining available processing resources for each computing node, where a computing node resides at networked wearable devices associated with the user. The remote node management engine further selects one of the computing nodes as a primary controller to distribute portions of the computational task to one or more of the other computing nodes and receive results from performance of the portions of the computational task by the other computing nodes, and provides to the selected computing node information about available processing resources at each computing node.

Eyewear device that includes two SoCs that share processing workload. Instead of using a single SoC located either on the left or right side of the eyewear device, the two SoCs have different assigned responsibilities to operate different devices and perform different processes to balance workload. In one example, the eyewear device utilizes a first SoC to operate all peripheral components, and a second SoC performing computational tasks. This is a low-risk architecture since the second SoC is not required to operate any of the peripherals, and it has low standby power since the second SoC can be fully shutdown in a low-power mode. The second SoC does not have any direct access to camera data, so an interprocessor communication bus continuously transmits camera buffer data for most augmented reality (AR) compute tasks. This configuration provides organized logistics to efficiently operate various features, and balanced power consumption.

Eyewear devices that include two SoCs that share processing workload. Instead of using a single SoC located either on the left or right side of the eyewear devices, the two SoCs have similar assigned responsibilities to operate the same types of peripheral components and perform similar processes to balance workload. In one example, the eyewear device utilizes a first SoC to operate a first color camera, a first computer vision (CV) camera, and a first display, and perform three-dimensional graphics and compositing. A second SoC operates a second color camera, a second CV camera, and a second display. The SoCs are synchronized since peripheral components are operated by both SoCs. Each of the SoCs have an operating system (OS), CV algorithms, and visual odometry (VIO), e.g., for tracking hand gestures of the user, and providing depth from stereo images from the color cameras. This configuration provides simplified organized logistics to efficiently operate various features, and balanced power consumption.

A game controller has first and second controllers detachably coupled to a bridge or an information handling system housing to provide inputs to a gaming application executing on the information handling system, such as from a joystick input device integrated in each controller. Logic stored in non-transitory memory of the information handling system executes to track game controllers based upon unique identifiers retrieved from each controller to the information handling system, such as through a direct coupling of the controllers to the information handling system or indirect communication by the information handling system with a bridge directly coupled to the controllers. The information handling system sets priority for inputs from game controllers based upon controller unique identifiers and also tracks composite game controller assemblies that include controllers and a bridge.

A display film includes a transparent glass layer having a thickness of 250 micrometers or less, or in a range from 25 to 100 micrometers. A transparent energy dissipation layer is fixed to the transparent glass layer. The transparent energy dissipation layer has a glass transition temperature of 27 degrees Celsius or less and a Tan Delta peak value of 0.5 or greater, or from 1 to 2.

An electronic device may have a housing. The housing may be characterized by a vertical axis and may have housing structures such as cylindrical housing structures with a cylindrical surface. A speaker may be mounted in the housing to provide sound through openings in the housing structures. A visual output device may be mounted in the housing to provide light through openings in the housing structures. The visual output device may include an electrophoretic display, a light-emitting diode display, or other display with an array of pixels that display images or may include other components for emitting light. During operation, voice commands may be received by a microphone in the device and action taken based on the commands and other information. The action taken may include playing sound with the speaker and providing visual output with the visual output device.

An electronic device includes an enclosure formed of a plurality of layers cooperating to define an interior volume. The enclosure includes a first layer formed of a first material and defining a user input surface of the enclosure and a first portion of a side surface of the enclosure. The enclosure also includes a second layer, formed of a second material different from the first material, positioned below the first layer and defining a second portion of the side surface of the enclosure. The enclosure also includes a third layer, formed of a third material different from the first and second materials, positioned below the second layer and defining a bottom surface of the enclosure and a third portion of the side surface of the enclosure.

A system includes a sensor applicator, a sensor control device arranged within the sensor applicator and including an electronics housing and a sensor extending from a bottom of the electronics housing, and a cap coupled to one of the sensor applicator and the sensor control device, wherein the cap is removable prior to deploying the sensor control device from the sensor applicator.

An electronic device includes a first application. The electronic device detects a first operation. The electronic device displays, in a landscape orientation state, a first interface of the first application in a first area of a display screen of the electronic device in response to the first operation. The electronic device detects a second operation on the first interface, where the second operation enables the electronic device to open a second interface of the first application. The electronic device displays the second interface in a second area in response to the second operation. The display screen includes at least two areas, the at least two areas include the first area and the second area, and different areas of the display screen do not overlap.