An electronically controlled mechanical watch includes a time indication device including a time indication wheel train configured to indicate a time using a transmitted torque of a mechanical energy source, a circuit board on which a crystal oscillator, an electronic control circuit configured to adjust a rotation speed of the time indication wheel train based on an oscillation frequency of the crystal oscillator, and a plurality of logical regulation setting patterns are disposed, and a rotary switch including a conduction portion, the rotary switch being configured to rotate with respect to the circuit board to select one of the plurality of logical regulation setting patterns, conducting to the conduction portion, wherein the electronic control circuit includes an oscillation circuit, a frequency divider circuit, and a logical regulation circuit configured to control the frequency divider circuit based on a conduction state of the conduction portion and the logical regulation setting pattern.

A watch includes a crystal oscillator, a controller including an oscillation circuit configured to cause the crystal oscillator to oscillate, wiring that couples the crystal oscillator with the controller, and the crystal oscillator, a storage container that stores the crystal oscillator, the wiring, and the controller, and an outer case that stores the storage container, in which the crystal oscillator and the controller are placed side by side inside the storage container in plan view.

An electronic device, such as a watch, has a crown assembly having a shaft and a user-rotatable crown. The user-rotatable crown may include a conductive cap that is mechanically and electrically coupled to the shaft and functions as an electrode. The conductive cap may be coupled to the shaft using solder or another conductive attachment mechanism. The shaft may electrically couple the conductive cap to a processing unit of the electronic device. One or more additional electrodes may be positioned on the exterior surface of the electronic device. The conductive cap is operable to be contacted by a finger of a user of the electronic device while another electrode is positioned against skin of the user. The processing unit of the electronic device is operable to determine a biological parameter, such as an electrocardiogram, of the user based on voltages at the electrodes.

A method and an electronic device implementing the method are disclosed. The electronic device may include sensors, a memory and a processor executing instructions stored in the memory to: select at least one sensor of the one or more sensors to detect movement of the electronic device and select a sampling frequency of the selected at least one sensor based on usage state information of the electronic device, detect the movement of the electronic device using the selected at least one sensor at the selected sampling frequency, and when the detected movement corresponds to at least one preset condition of the one or more preset conditions, execute a specific application of the one or more applications associated with the at least one preset condition.

A wrist apparatus as a portable electronic apparatus calculates an evaluation value based on data outputted from acceleration sensors, each of which serves as an inertia sensor, and assuming that when the evaluation value becomes greater than a first threshold, it is determined that a first state has been achieved, and when the evaluation value becomes smaller than a second threshold, it is determined that a second state has been achieved, performs a predetermined display when a result of the determination shows that the first state has transitioned to the second state.

An electronic device is disclosed. In some examples, a crown comprising a housing can be operatively coupled to a body of the electronic device, and configured to rotate in a first direction with respect to the body of the electronic device in response to a mechanical input provided by the user. A rotating member can be disposed at least partially inside the crown housing and configured to rotate in the first direction in response to the mechanical input. A first magnetic sensing cell can be attached to the rotating member at a first location of the rotating member and can be electrically connected to an electronic circuit. A magnet can be configured to remain stationary with respect to the body of the electronic device. The electronic circuit can be configured to generate a first signal corresponding to a rotational position of the crown with respect to the body of the electronic device.

The invention relates to an electronic device comprising a processor configured to implement a user interface for allowing a user to interact with the electronic device, a display and a touch panel in communication with the processor, wherein the display and the touch panel provide a touch-sensitive display configured to allow a user to interact with the electronic device using the user interface by touching the touch panel, and a bezel rotatably mounted on a housing of the electronic device wherein the bezel comprises a pointing element configured to activate the touch panel at a plurality of different locations of the touch panel and wherein the plurality of different locations of the touch panel define a plurality of different positions of the bezel relative to the housing allowing the user to interact with the electronic device by using the bezel.

A wearable device is disclosed. The wearable device may include a body. The wearable device may also include a band coupled with the body. The band may include a signal generator configured to generate a signal indicating a change of a shape of the band.

In some examples, the apparatus comprises a mechanical input mechanism comprising a rotatable shaft, an optical sensor configured to detect a rotation of the shaft and detect a movement of the shaft toward or away from the optical sensor, and an optical sensor configured to detect light incident on the optical sensor, the light having a position and an orientation, the orientation of the light based on at least a position of the rotatable shaft, detect a rotation of the shaft, and detect a movement of the shaft based on at least a change in the orientation of the light. In some examples, a mechanical input mechanism is coupled to a housing and configured to contact a force sensor coupled to the housing in response to a user input. In some examples, the force sensor is configured to detect a position of the shaft and detect an amount of force between the shaft and the force sensor.

An input mechanism for a portable electronic device includes a rotational manipulation mechanism, such as a cap or shaft. The input mechanism also includes a sensor having first capacitive elements coupled to the manipulation mechanism, second capacitive elements, and a dielectric positioned between the first and second capacitive elements. Movement of the manipulation mechanism alters the positions of the first and second capacitive elements with respect to each other and is determinable based on capacitance changes resulting therefrom. In some implementations, the second capacitive elements may be part of an inner ring or partial ring nested at least partially within an outer ring or partial ring.