A smart watch is disclosed which may be controlled remotely using any of a variety of communications control links and control modules that are not part of the watch itself. The control links include RF, Bluetooth, Optical, Hardwired and Artificial Intelligence (Al) control links; operating in combination with tactile, audio and/or visual/motion sensing control mechanisms (modules). The disclosed smart watch optionally includes an expandable speaker extending from the wrist band of the watch to allow for the speaker to easily be placed next to the user's ear while in use. The Bluetooth speaker may be removable and may be used with other wireless devices. Methods, apparatus and systems incorporating the disclosed teachings are particularly well suited to support use of a smart watch by the disabled; and allows for both hands free and/or remote smart watch operation and control.

A transparent display device having an optical transmissive region and a circuit layout region is provided. A light transmittance of the optical transmissive region is greater than that of the circuit layout region. The transparent display device includes a plurality of display elements and a driving circuit. The display elements are disposed in the optical transmissive region or the circuit layout region. The driving circuit is disposed in the circuit layout region and is electrically connected with the display elements. The transparent display device satisfies: 0.1<light spot spreading degree <1.1+0.78exp (0.0072resolution), and 10%<aperture ratio <90%.

Examples of mixed reality computing devices that utilize remote sensors and local sensors as input devices are disclosed. In one example, a mixed reality computing device comprises an image sensor, a remote input device, a processor, and storage comprising stored instructions. The stored instructions are executable by the processor to perform object motion tracking and environmental tracking based on output from the image sensor, and in response to detecting that the remote input device is in use, adjust a parameter of the motion tracking while maintaining the environmental tracking.

A method and a device for the quick navigation of users through the user interface of a plant for manufacturing a product from thermoplastic, an extruder being operated for plastification of a thermoplastic, and a method and a plant for manufacturing a product from thermoplastic allow quick changing between user views of a machine or plant control. An input device for entering representative signals from a customized input library is used, which signals are linked to actions in a relational database, wherein the actions cause a rapid change between user views of a machine or plant control. The rapid change between user views makes the machine or plant control faster, and the customized input library makes the control more intuitive.

An input sensing unit may include the following elements: a first sensing electrode including first sensors and a first connector coupling the first sensors; a second sensing electrode including second sensors and a second connector coupling the second sensors; a first sensing line including first sensing line parts and a third connector coupling the first sensing line parts; a second sensing line; and an insulating layer including a first insulating side and a second insulating side opposite the first insulating side. The first sensing line parts may overlap the first sensors and may be disposed on the first insulating side. The second sensing line may overlap the second sensors and may be disposed on the first insulating side. The first sensors may be disposed on the second insulating side. The second sensors may be disposed on the second insulating side.

Methods, systems, and devices for testing a die using a segmented digital die ring are described. A segmented digital die ring may include multiple signal line segments, each coupled with a test segment circuit, and a control circuit. A test segment circuit may generate a digital feedback signal that indicates a condition of a respective signal line segment. The control circuit may generate a single output signal, indicative of the condition of the signal line segments. By utilizing digital testing circuitry and a single digital output signal, a layout area of the segmented digital die ring be minimized and a power consumption associated with the testing operation may be reduced.

This application relates to the field of display technologies, and provides a method and an apparatus for adjusting an orientation, and an electronic device. The method comprises: in response to a first rotation operation performed by a user on an electronic device, determining an orientation of content displayed on the screen of the electronic device; after the user performs the first rotation operation on the electronic device, determining whether an orientation of the screen is consistent with the orientation of the content; and in response to that after the user performs the first rotation operation on the electronic device, the orientation of the screen is consistent with the orientation of the content, maintaining the orientation of the content. By using the method, the apparatus, and the electronic device provided in embodiments of the present invention, content displayed on the electronic device can be adjusted to an orientation suitable for a user to view, and the user does not need to perform a specified gesture or enter an edit interface to perform a rotation operation, thereby simplifying a user operation and improving user experience.

A multi-display device is adapted to be dockable or otherwise associatable with an additional device. In accordance with one exemplary embodiment, the multi-display device is dockable with a smartpad. The exemplary smartpad can include a screen, a touch sensitive display, a configurable area, a gesture capture region(s) and a camera. The smartpad can also include a port adapted to receive the device. The exemplary smartpad is able to cooperate with the device such that information displayable on the device is also displayable on the smartpad. Furthermore, any one or more of the functions on the device are extendable to the smartpad, with the smartpad capable of acting as an input/output interface or extension of the smartpad. Therefore, for example, information from one or more of the displays on the multi-screen device is displayable on the smartpad.

An electronic device and a manufacturing method for the same are provided. The electronic device includes a light-permeable display screen and an optical sensor. The light-permeable display screen has a first surface and a second surface facing away from the first surface. The second surface includes a display area and a black matrix area surrounding the display area. The black matrix area includes a first window region. The optical sensor is disposed opposite to the second surface of the light-permeable display screen, and includes an emitter and a receiver. The emitter is configured to emit an infrared light through the first window region and the receiver is configured to receive the infrared light through the light-permeable display screen.

A touch substrate, a touch screen, and an electronic device are provided. The touch substrate includes a touch layer. The touch layer includes at least two electrode blocks having a first electrode group and a second electrode group. The first electrode group includes at least two first electrodes arranged in a first direction and/or a second direction, and the second electrode group includes at least two second electrodes arranged in the first direction and/or the second direction.