A timepiece movement is provided, including a first regulating member and a first escapement associated therewith; a first train connecting the first escapement to a first energy source; a second regulating member and a second escapement associated therewith; a second train connecting the second escapement to a second energy source; a display of a current time; at least one differential gear including a first input wheel meshing with the first train and a second input wheel meshing with the second train, the at least one differential gear driving the display, where the second regulating member consumes less energy than the first regulating member.

A timepiece movement is provided, including a first regulating member and a first escapement associated therewith; a first train connecting the first escapement to a first energy source; a second regulating member and a second escapement associated therewith; a second train connecting the second escapement to a second energy source; a display of a current time; at least one differential gear including a first input wheel meshing with the first train and a second input wheel meshing with the second train, the at least one differential gear driving the display, where the second regulating member consumes less energy than the first regulating member.

A timepiece movement is provided, including a first regulating member and a first escapement connected by a first train to a first energy source, where the first train, the first escapement, the first regulating member, and the first energy source together define a first assembly; a second regulating member and a second escapement connected by a second train to a second energy source, where the second train, the second escapement, the second regulating member, and the second energy source together define a second assembly; at least one differential gear configured to ensure a kinematic connection between the first and the second assemblies; a display of the current time; and a mechanism for stopping and allowing operation of one of the regulating members, where the differential gear carries the display to display the current time regardless of which of the regulating members is operating.

A timepiece movement is provided, including a first regulating member and a first escapement connected by a first train to a first energy source, where the first train, the first escapement, the first regulating member, and the first energy source together define a first assembly; a second regulating member and a second escapement connected by a second train to a second energy source, where the second train, the second escapement, the second regulating member, and the second energy source together define a second assembly; at least one differential gear configured to ensure a kinematic connection between the first and the second assemblies; a display of the current time; and a mechanism for stopping and allowing operation of one of the regulating members, where the differential gear carries the display to display the current time regardless of which of the regulating members is operating.

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.

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.

Provided are a timepiece having a temperature compensator drivable by a low voltage with low current consumption, and a control method of a timepiece. The timepiece includes an arithmetic circuit, a first switch that controls connection of a temperature compensation table storage to a power supply circuit, and a second switch that controls connection of a device-difference compensation data storage to the power supply circuit. The arithmetic circuit calculates a compensation amount based on a temperature measured by a temperature detector, a temperature compensation data, a device-difference compensation data, and outputs to a frequency adjustment control circuit and a theoretical regulation circuit. The first switch is controlled to the connect state during a first power supply connection period including a temperature compensation data read period. The second switch is controlled to the connect state during a second power supply connection period including a device-difference compensation data read period.

Provided are a timepiece having a temperature compensator drivable by a low voltage with low current consumption, and a control method of a timepiece. The timepiece includes an arithmetic circuit, a first switch that controls connection of a temperature compensation table storage to a power supply circuit, and a second switch that controls connection of a device-difference compensation data storage to the power supply circuit. The arithmetic circuit calculates a compensation amount based on a temperature measured by a temperature detector, a temperature compensation data, a device-difference compensation data, and outputs to a frequency adjustment control circuit and a theoretical regulation circuit. The first switch is controlled to the connect state during a first power supply connection period including a temperature compensation data read period. The second switch is controlled to the connect state during a second power supply connection period including a device-difference compensation data read period.

A timepiece movement, including a mechanism including an inertial element arranged to oscillate or pivot about a first axis of pivoting relative to a structure of the movement, and arranged to cooperate directly or indirectly with an energy distribution wheel set that pivots relative to the structure about a second axis of pivoting parallel to or coincident with the first axis of pivoting and subjected to a torque exerted by an energy source, wherein the energy distribution wheel set meshes directly or indirectly with at least one inertia wheel set that pivots about a third axis of pivoting relative to the structure, each inertia wheel set is arranged to pivot in the opposite direction to the energy distribution wheel set, and the total inertia of the inertia wheel sets is comprised between 60% and 140% of the inertia of the energy distribution wheel set.