A wearable computing device generates a volumetric visualization at a first position that is located in a three-dimensional space. The wearable computing device includes a volumetric source configured to create the volumetric visualization. The wearable computing device includes one or more sensors configured to determine movement of the wearable computing device. A movement of the wearable computing device is identified by the wearable computing device. Based on the movement the wearable computing device adjusts the volumetric source.

A computerized watch is described that includes a cover that forms an outer surface of the computerized watch, a screen configured to output graphical information for display, a set of physical watch hands positioned between the cover and the screen and configured to present a time of day. One or more computer processors and a memory comprising instructions. The instructions, when executed, cause the one or more computer processors to responsive to determining that the computerized watch is operating in a time display mode, manipulate the set of physical watch hands such that the set of physical watch hands present the time of day by obscuring a portion of a display region of the screen, and responsive to determining that the computerized watch is not operating in the time display mode, manipulate the set of physical watch hands such that the set of physical hands do not obscure the screen.

The present disclosure discloses a multi-eye analog smart timekeeping apparatus, comprising: a dial, comprising a dial substrate comprising a plurality of view regions; an arm positioned above the dial; a display panel positioned below the dial and comprising a plurality of display regions, each of the display regions corresponding to one of at least two of the view regions;

and a shaft connected to the arm and being through the dial and the display panel. The present disclosure also discloses a method of making a display panel that may be used with the timekeeping apparatus, comprising: providing a first substrate comprising a first area; forming a display layer on the first substrate outside the first area; applying encapsulation material on the first area and around the display layer; sealing the display layer between the first substrate and a second substrate; and drilling a hole in the first area, wherein a size of the hole is smaller than a size of the first area.

A wrist-wearable electronic device comprising first and second light emitting elements, a sensor, and a processor. The processor is configured to transmit a first command to the first light emitting element in response to the wrist-wearable device reaching a forward position relative to a user based on data received from the sensor and transmit a second command to the second light emitting element in response to the wrist-wearable device reaching a rearward position relative to the user based on the data from the sensor.

A method of a wearable device displaying icons is provided. The method includes displaying a plurality of circular icons comprising a first circular icon located in a center area of a touch display in a first size and a second circular icon located outside of the center area of the touch display in a second size smaller than the first size, and based on a direction of a touch input received on the touch display, moving the plurality of circular icons such that the first circular icon is moved to a first position located outside of the center area of the touch display and the second circular icon is moved from a second position located outside the center area of the touch display to the center area of the touch display and enlarged in size from the second size to the first size.

A wearable terminal device capable of wirelessly communicating with a mobile terminal device having a display unit, the wearable terminal device comprising receiving status information of the mobile terminal device from the mobile terminal device when status of the mobile terminal device changes, determining whether or not to select display of the wearable terminal device based on the status information, and controlling the display of the wearable terminal device based on a determination result by the determining.

The present disclosure generally describe user interfaces related to time. In accordance with embodiments, user interfaces for displaying and enabling an adjustment of a displayed time zone are described. In accordance with embodiments, user interfaces for initiating a measurement of time are described. In accordance with embodiments, user interfaces for enabling and displaying a user interface using a character are described. In accordance with embodiments, user interfaces for enabling and displaying a user interface that includes an indication of a current time are described. In accordance with embodiments, user interfaces for enabling configuration of a background for a user interface are described. In accordance with embodiments, user interfaces for enabling configuration of displayed applications on a user interface are described.

An electronic timepiece device including an electronic processing unit determining first, geolocation parameters and second parameters concerning the current legal standard time, and establishing local horizontal coordinates of the Sun from predetermined calculation rules stored in a memory of the electronic processing unit. The device also has a dial equipped with a casing enclosing all or part of the electronic processing unit and equipped with a display system displaying at least one indicator hand having an orientation that varies over time such that the angle formed between the indicator hand and a first fixed reference axis of the dial is equal, at each instant, to the azimuth of the Sun established by the processing unit, and a time scale calculated by the electronic processing unit and displayed at the periphery of the dial in the form of a plurality of time points positioned, with respect to the first fixed reference axis, as a function of the azimuth of the Sun respectively at the times of which the time points are representative. Thus the indicator needle simultaneously indicates, at each instant, a representation of the relative directions of the Sun and of the cardinal point of the culmination of the Sun and the current legal time.

An electronic device, such as a smart watch, incorporating a fluid-based pressure-sensing device is disclosed. The fluid-based pressure-sensing device includes an enclosure, a pressure sensor, a diaphragm and a sensing medium. The enclosure includes an opening and the pressure sensor is disposed inside the enclosure. The diaphragm hermetically seals the opening, and the sensing medium transfers a pressure exerted on the diaphragm to the pressure sensor. The sensing medium can be liquid oil filling a space of the enclosure, and the diaphragm is a polymer material. The pressure-sensing device may sense an environmental pressure, which may be used by the electronic device to modify its operations, change information that is displayed, and so on.

A timepiece includes a clock circuit, a signal receiver configured to receive signals including time information, a processor configured to control a changing operation of changing a current time measured by the clock circuit based on the time information obtained from the signal receiver and controls a presenting operation of whether or not the changing operation is successful. The processor controls the changing operation based on a first flag indicating whether or not the signal receiver successfully receives the time information. The processor controls the presenting operation based on a second flag indicating whether or not the changing operation is successful within a predetermined period of time.