An electronic timepiece includes a storage that stores specific-region DST application rule information and local time information that includes, in association with each other, DST application rules for each region and standard-wave transmitting station information indicating each station transmitting standard waves receivable in the region; a processor that controls clock time to be kept by a clock circuit and displays time to be displayed on a display; and a standard wave receiver that receives standard waves and obtains time information. The processor calibrates the clock time based on the time information indicated by the standard waves received by the standard wave receiver, and controls the display time based on whether the specific-region DST application rule information and the DST application rule information associated with the standard-wave transmitting station information indicating a station transmitting the received standard waves satisfy a predetermined condition.

A smartwatch comprises a CPU configured to acquire current location information, acquire map information based on the current location information, select any icon from a plurality of icons associated with predetermined information wherein the plurality of icons are different from each other, add the selected icon to a designated point designated on the map information in response to a user operation, and report predetermined information corresponding to the icon added to the designated point to the user when a predetermined condition for the selected icon is satisfied, and a display unit configured to display additional information added by the CPU and its corresponding designated point together with the map information.

Systems and methods to facilitate sleep are described. In on example, a cognitive alarm clock system for children learns sleep patterns and activities towards recommending sleep schedules and teaching independence. The system may detect the cognitive state of a child based on voice or cry pattern recognition, a time of day or night, scheduled activities, and social context, among other factors. The system may initiate actions to facilitate sleep in response to the cognitive factors. For example, the system may adjust lighting or push back a wakeup time. In another example, the system may use the cognitive analysis to teach children good sleeping habits by making recommendations to facilitate a good night's rest and encourage independence.

Systems and methods to facilitate sleep are described. In on example, a cognitive alarm clock system for children learns sleep patterns and activities towards recommending sleep schedules and teaching independence. The system may detect the cognitive state of a child based on voice or cry pattern recognition, a time of day or night, scheduled activities, and social context, among other factors. The system may initiate actions to facilitate sleep in response to the cognitive factors. For example, the system may adjust lighting or push back a wakeup time. In another example, the system may use the cognitive analysis to teach children good sleeping habits by making recommendations to facilitate a good night's rest and encourage independence.

A device is disclosed. The device includes a display, a memory configured to store an artificial intelligence model trained to obtain an output layout information of an additional information provided in the device, and a processor connected to the display and the memory. The processor is configured to control the device, and obtain, based on an output layout of the main information provided in the device being selected, an output layout information of the additional information by inputting information related to an output layout of a main information to the artificial intelligence model. The processor is also configured to control the display to output a user interface (UI) screen including time information and additional information based on an output layout of the main information and an output layout information of the additional information.

An apparatus, intended for use in indicating time interval durations of particular events in an augmented reality display, includes a computer system with a processing system having a hardware processor and a memory accessible to the processing system, a user interface controller under control of the processing system, a display controllable by the user interface controller to show a user interface, and logic, under control of the processing system. The logic has modules that control the user interface controller to cause the display to show a first clockface that indicates a time interval duration for at least a first event and an augmented reality background appearing behind the first clockface.

An electrical time measuring device, intended to conserve processor cycles and memory when used in indicating time interval durations, includes a computer system with a processing system having a hardware processor and a memory accessible to the processing system, a user interface controller under control of the processing system, and logic, under control of the processing system. The user interface presented thereby has various regions including an ante meridiem events region and a post meridiem events region that share a common center. Arciforms indicate the time duration of events. In various embodiments, an arciform has a first start point in one of the regions and connected to an initial arc of points that are equidistant from the common center, and a final arc of points that are equidistant from the common center connected to a first end point in a different one of the regions, with a transition indicator linking the initial arc with the final arc.

A smartwatch including a first screen cooperating with a first display management device of said smartwatch contributing to broadcasting information pertaining to functions provided by the smartwatch and a second screen that is separate from the first screen cooperating with a second display management device of the smartwatch contributing to broadcasting information concerning all or part of a visual message pertaining to a visual and/or audio animation occurring within an environment wherein the smartwatch is located, the information being transmitted from a display control server controlling the second display management device of the smartwatch.

The patent relates to the technical field of smart wearable device, and discloses a watch with the function of automobile key, including: watch case, which is hollow inside and open at both ends, the watch case is made of metal material, the watch case is provided with a rubber cover, one end of the rubber cover is provided with a holding groove, the holding groove is provided with a watch movement, the first power supply for providing electric energy to the watch is provided in the watch movement, and one end of the watch movement that is far away from the rubber cover is provided with a dial, dial is provided with hands, the rubber cover is provided with a automobile key module, the automobile key module is provided with a locking button for closing the door lock and a unlocking button for opening the door lock, and one end of the automobile key module is provided with a second power supply for providing power to the automobile key module. The watch is powered by the first power supply, the automobile key module is powered by the second power supply, and the door lock can be opened by unlocking button and the door lock can be closed by locking button, so as to realize the operation of dual independent batteries, so that the watch does not need to be recharged, can be used for a long time, and is convenient for energy saving.

Smart wearable sensor system and methods to lower risks of distracted walking, and the system includes at least a smart mobile device connected to both the wearables and a machine learning block. The wearables is used to sense users' environment and acquire featured data. The smart mobile device computes on the featured data with existing algorithms and models and makes judgement to alert users of objects and situations needing attention. In the machine learning block, servers are used to construct machine learning algorithms and models, and a computing block is used to train the algorithms and models. The servers update algorithms and models regularly. The servers are connected to the mobile device thru a wireless network, and the mobile device downloads updated algorithms and models from the servers. The system is intelligent as the algorithms and models are continuously optimized and improved. The intelligence helps the person to percept the surroundings and effectively lower the risk of accident as a result of dropped vision and hearing during distracted walking.