An estimated goal time display system includes at least one processor; and at least one memory. The at least one processor is configured to perform the following according to a program stored in the at least one memory: first deriving that derives a pace that a user runs a distance set in advance based on exercise data obtained when the user is running; second deriving that derives an estimated goal time that the user will reach a preset goal point, a faster-pace estimated goal time that the user will reach the goal point if the user makes the pace a predetermined amount of time faster, and a slower-pace estimated goal time that the user will reach the goal point if the user makes the pace a predetermined amount of time slower; and display controlling that displays on a display the estimated goal time, the faster-pace estimated goal time and the slower-pace estimated goal time.

A wearable device includes at least one memory, at least one sensor, a display, and at least one processor configured to receive, via the display, an input with respect to an item among a plurality of items respectively representing an exercise plan; in response to receiving the input, acquire, via the sensor, information for a first body temperature of a user wearing the wearable device; in response to identifying that the first body temperature is less than a first reference temperature, display a second screen guiding a warm-up exercise distinguishable from a first screen guiding the exercise plan indicated by the item corresponding to the input; acquire, via the sensor, a second body temperature of the user, while the second screen is displayed; and in response to identifying that the second body temperature reaches a second reference temperature, switch the second screen to the first screen.

A display and interaction method in a user interface and devices, computer program products and systems therefor are disclosed. An information object display area includes a plurality of information objects displayed on a track. The track extends along a path created between an outer and inner elliptical border in the interface. A plurality of elliptical frames are generated along the track, each in contact with the outer and inner elliptical borders, and first and second neighboring elliptical frames adjacent to it. Information objects are displayed based on the elliptical frames. In response to receiving user input associated with movement of a pointer, the center of the inner elliptical border is moved in the direction of pointer movement while resizing the inner border so that it remains within the outer border. The elliptical frames are resized and moved along the track so that all the elliptical frames remain in contact with the borders and their neighboring elliptical frames.

A wearable information terminal that can be worn by a user is provided with: a main body; a display that is incorporated in the main body and includes a screen; a controller that is incorporated in the main body and executes display processing onto the screen; and an operation detector that detects input operation executed by the user with respect to the controller.

This Application pertains to a charging control method including: setting a temperature range when a wearable electronic device is being charged according to a user demand; when the charging starts, turning on a wirelessly receiving coil of the wearable electronic device and using it to generate a charging current for charging the wearable electronic device; when it is monitored that a value of the charging current of the wearable electronic device rises to a preset constant-current charging current value, acquiring in real time a temperature value of the wearable electronic device; and judging whether the temperature value is within the temperature range; and if yes, maintaining the present value of the charging current of the wearable electronic device; and if not, changing the value of the charging current of the wearable electronic device, so that the temperature value of the wearable electronic device is within the temperature range.

A computing device includes a pixelated electronic display having a substrate and a plurality of pixels arranged thereon. The plurality of pixels includes, at least, a first portion of pixels and a second portion of pixels. The second portion of pixels has a gradually varying pixel aperture size. The computing device also includes at least one sensor positioned under the pixelated electronic display and adjacent to the second portion of pixels having the gradually varying pixel aperture size and at least one processor communicatively coupled to the at least one sensor for controlling the computing device.

In one aspect, a smart watch or other device may include at least one processor, a display accessible to the at least one processor, and storage accessible to the at least one processor. The storage may include instructions executable by the at least one processor to identify an orientation of a user’s head and identify an orientation of the smart watch with respect to the user’s head. The instructions may also be executable to, based on the orientation of the user’s head and the orientation of the smart watch, present content on the display in a content orientation that is maintained with respect to a reference for the content to appear upright on the display relative to the reference.

One embodiment provides a method, including: identifying, on an information handling device, a fixed user interface; presenting, on a display of the information handling device, a view of a portion of the fixed user interface; determining, using a processor, whether movement of the information handling device is detected; and updating, responsive to determining that movement of the information handling device is detected, the view on the display with another portion of the fixed user interface. Other aspects are described and claimed.

A method for executing a function of an electronic device is provided. The method includes the operations of displaying a virtual clock user interface (UI) indicating a virtual time, and an icon list UI including icons corresponding to a plurality of functions, respectively, acquiring first input data according to a user input for selecting one time by using the displayed virtual clock UI, and second input data according to a user input for selecting one icon from the icon list UI, performing control, on the basis of the first input data and the second input data, so that a function corresponding to the selected icon is executed at the selected one time, and highlighting the selected icon as the virtual time reaches the one time, and executing the function corresponding to the selected icon as the current time reaches the one time.

A wearable electronic device is provided. The wearable electronic device includes at least one first thermistor arranged in different heat generation positions in the wearable electronic device and configured to detect a temperature change of internal elements of the wearable electronic device, a temperature sensor configured to calculate a body temperature of a user based on the temperature change of the internal elements and a skin temperature trend of the user, and at least one processor configured to determine whether an internal temperature by the internal elements in the wearable electronic device is within a reference temperature range that does not have an influence on a calculation of the body temperature, based on a measured value of the at least one first thermistor, determine a user state index (UI) indicating whether the user is in a state in which the body temperature is measurable, when the internal temperature is determined to be within the reference temperature range, and measure the body temperature by adjusting a body temperature measurement period based on the UI.