A wearable power supply includes a strap to be worn on a user's wrist, arm, waist, leg or head; a flexible secondary battery carried by the strap; and a connector slot disposed on the strap and electrically connected to the flexible secondary battery, wherein the flexible secondary battery is capable of supplying current to a mobile device via a connecting wire connected between the connector slot and the mobile device, and is recharged from an external power supply connected to the connector slot. When the wearable power supply takes the form of a wristband, it can be used as a carrier of a hand worn mobile device, such as a smart watch or a smart bracelet, to provide a longer operating range.

An electronic watch may include a housing, a display positioned at least partially within the housing, a transparent cover coupled to the housing and at least partially covering the display, a battery, and a coil coupled to the battery and configured to, during a battery charging operation, supply a first current to the battery and, during a haptic output operation, receive a second current from the battery to produce a haptic output. The electronic watch may further include a ferromagnetic element positioned at least partially within the housing and movable relative to the housing. The second current may cause the coil to produce a magnetic field, and the haptic output may be produced as a result of an interaction between the magnetic field and the ferromagnetic element that causes the ferromagnetic element to move relative to the housing.

A real-time clock module includes a switch circuit that is electrically coupled to a first node to which a first power supply voltage is applied and a second node to which a second power supply voltage is applied and switches between outputting the first power supply voltage and outputting the second power supply voltage, a power supply detection circuit that detects a voltage value of the first power supply voltage, a switch control circuit that controls the switching of the switch circuit based on an output of the power supply detection circuit, a constant voltage circuit that outputs a constant voltage signal based on the output of the switch circuit, and a current control circuit that controls a current supplied to the constant voltage circuit, in which, when where the switch control circuit switches the switch circuit, the current control circuit increases the current supplied to the constant voltage circuit.

A real-time clock module includes a switch circuit that is electrically coupled to a first node to which a first power supply voltage is applied and a second node to which a second power supply voltage is applied and switches between outputting the first power supply voltage and outputting the second power supply voltage, a power supply detection circuit that detects a voltage value of the first power supply voltage, a switch control circuit that controls the switching of the switch circuit based on an output of the power supply detection circuit, a constant voltage circuit that outputs a constant voltage signal based on the output of the switch circuit, and a current control circuit that controls a current supplied to the constant voltage circuit, in which, when where the switch control circuit switches the switch circuit, the current control circuit increases the current supplied to the constant voltage circuit.

A watch charging assembly 10 has a coil 22, a membrane 24 and a back plate 12. The coil 22 is configured to pass electric current received at a first or second contact pad 27, 28. The membrane 24 is affixed to the coil 22 forming a membrane and coil assembly 20. The back plate 12 has a pair of conductive inserts 30. Each conductive insert 30 is aligned with and contacts each contact pad 27, 28. The back plate 12 with the coil 22 and membrane 24 form the charging assembly 10. The charging assembly 10 is configured to form a bottom or underside or, alternatively, be attached to a bottom or underside of a rechargeable battery operated wristwatch 100 and when worn, the charging assembly 10 receives electric current from the wearer to charge a rechargeable battery of the wristwatch 100. The coil 22 can be a pancake coil.

A quick release and connect system that provides battery power for a wearable electronic device and a method for reducing battery charging down time of a wearable electronic device are disclosed. The quick release and connect system that provides battery power for a wearable electronic device and the method for reducing battery charging down time of a wearable electronic device reduces battery charging down time of a wearable electronic device by swapping of attachable-detachable auxiliary components with auxiliary batteries.

A quick release and connect system that provides battery power for a wearable electronic device and a method for reducing battery charging down time of a wearable electronic device are disclosed. The quick release and connect system that provides battery power for a wearable electronic device and the method for reducing battery charging down time of a wearable electronic device reduces battery charging down time of a wearable electronic device by swapping of attachable-detachable auxiliary components with auxiliary batteries.

Various systems and methods for providing a separatable wearable device are provided herein. A detachable portion of a wearable device includes a microcontroller; a memory coupled to the microcontroller; a battery assembly coupled to the microcontroller; and a display coupled to the microcontroller, wherein the microcontroller is to: operate in a first mode when the detachable portion is coupled to a holder portion of the wearable device; and operate in a second mode when the detachable portion is decoupled from the holder portion, and being recharged.

Various systems and methods for providing a separatable wearable device are provided herein. A detachable portion of a wearable device includes a microcontroller; a memory coupled to the microcontroller; a battery assembly coupled to the microcontroller; and a display coupled to the microcontroller, wherein the microcontroller is to: operate in a first mode when the detachable portion is coupled to a holder portion of the wearable device; and operate in a second mode when the detachable portion is decoupled from the holder portion, and being recharged.

A testability method (500) for testing the operation of a thermoelectric element (110) of a thermoelectric watch (100) including the thermoelectric element (110), a power circuit supplied by primary storage elements (101) and secondary storage elements (102) so as to move at least one moveable element (190) or display information on an electro-optical display device. The testability method (500) includes steps of applying a heat source (540) to the thermoelectric element (110) so as to make it possible to electrically charge (550) or recharge (550) the secondary storage elements (102) in order to move at least one moveable element (190) or display information on an electro-optical display device, and thus check the functionality of the thermoelectric element (110).