Systems, methods, and non-transitory computer readable media configured for modifying the display of virtual objects docked to a movable input device are provided. In one implementation, the computer readable medium may be configured to receive image data from an image sensor, the image data representing an input device placed at a first location on a supporting surface. At least one processor may generate a presentation of at least one virtual object in proximity to the first location. Operations may include docking the at least one virtual object to the input device. The processor may determine that the input device is in a second location on the support surface. The virtual object presentation may be modified based on the second location. Operations may further include determining that the input device is in a third location removed from the support surface and modifying the virtual object presentation accordingly.

Systems, methods, and non-transitory computer readable media containing instructions for causing at least one processor to perform operations for changing display of virtual content based on temperature are provided. In one implementation, the processor is configured to perform operations comprising displaying virtual content via a wearable extended reality appliance, wherein during displaying of the virtual content, heat is generated by at least one component of the wearable extended reality appliance; receiving information indicative of a temperature associated with the wearable extended reality appliance; determining a need to change display settings of the virtual content based on the received information; and based on the determination, changing the display settings of the virtual content to achieve a target temperature.

An integrated computational interface device may include a portable housing having a key region and a non-key region; a keyboard associated with the key region of the housing; and a holder associated with the non-key region of the housing. The holder may be configured for selective engagement with and disengagement from the wearable extended reality appliance, such that when the wearable extended reality appliance is selectively engaged with the housing via the holder, the wearable extended reality appliance is transportable with the housing.

Systems, methods, and non-transitory computer readable media for coordinating virtual content display with mobility status are disclosed. A non-transitory computer readable medium contains instructions that cause a processor to: access rules associating user mobility statuses with display modes; receive first sensor data reflecting a mobility status of a user during a first time period; based on the first sensor data, determine that during the first time period the user is associated with a first mobility status; implement a first accessed rule to generate a first display of virtual content; receive second sensor data reflecting the mobility status of the user during a second time period; based on the second sensor data, determine that during the second time period the user is associated with a second mobility status; and implement a second accessed rule to generate a second display of the virtual content different from the first display.

A system and method for operating an extended reality environment with a virtual display screen and virtual objects are disclosed. The system may include a processor configured to dock virtual objects to a virtual display screen; receive an input indicative of an intent to change a location of the virtual display screen without an expression of an intent to move the at least one virtual object; change the location of the virtual display screen in response to the input; and change the location of the at least one virtual object to move with the virtual display screen as a result of the docking.

An integrated computational interface device includes a housing, at least one image sensor, and a foldable protective cover. The housing has a key region and a non-key region, and a keyboard associated with the key region. The foldable protective cover incorporates the at least one image sensor. The protective cover is configured to be manipulated into a plurality of folding configurations, including a first folding configuration, wherein the protective cover is configured to encase the key region and at least a portion of the non-key region, and a second folding configuration, wherein the protective cover is configured to stand in a manner that causes an optical axis of the at least one image sensor to generally face a user of the integrated computational interface device while the user types on the keyboard.

A luminous keyboard and an optical module thereof are provided. The optical module includes a light guide sheet, a reflective film on one side of the light guide sheet, and an optical film on another side of the light guide sheet opposite to the reflective film. The optical film has a mask pattern. The mask pattern defines a light-transparent region, a light-shielding region, and a light modulation region extending from the light-shielding region to the light-transparent region. The light-transparent region allows light to pass therethrough. The light-shielding region blocks light. The light modulation region partially allows light to pass therethrough and partially blocks light, so that an average light-transmitting rate per unit area of the light modulation region is smaller than that of the light-transparent region and larger than that of the light-shielding region.

A luminous keyboard includes a keyswitch module and an optical module disposed under the keyswitch module. The keyswitch module includes a plurality of keyswitches. The optical module includes a mask film and a light guide sheet. The mask film has a mask pattern. The mask pattern defines a plurality of light-transparent regions respectively corresponding to the plurality of keyswitches, and an outer light-transparent region of the plurality of light-transparent regions has a boundary. The light guide sheet has a light-exit edge. The vertical projection of the light-exit edge of the light guide sheet on the mask film at least partially falls within the outer light-transparent region and is not parallel to the boundary.

An electronic device includes an enclosure, a substrate within the enclosure, a keycap support mechanism, and a keycap supported by the keycap support mechanism and movable relative to the substrate. The keycap includes a body, a mask layer defining a glyph opening, and a semitransparent mirror layer positioned within the glyph opening. The electronic device also includes a light source configured to direct light through the semitransparent mirror layer.

Systems, methods, and non-transitory computer readable media containing instructions for causing at least one processor to perform operations for integrating a moveable input device with a virtual display projected via a wearable extended reality appliance. In one implementation, the processor is configured to perform operations comprising receiving motion signals associated with the moveable input device, the motion signals reflecting physical movement; outputting during a first time period, first display signals to the reality appliance, the first display signals being configured to cause the wearable extended reality appliance to virtually present content in a first orientation; outputting during a second time period, second display signals to the wearable extended reality appliance, the second display signals being configured to cause the wearable extended reality appliance to virtually present the content in a second orientation; and switching between the output of the first display signals and the output of the second display signals.