A system, recharge apparatus, and method includes transmit coils positioned in a pattern to allow at least one of the transmit coils to establish a wireless link with a receive coil positioned in proximity of the recharge apparatus. A power source is coupled to the transmit coils and configured to selectively energize ones of the transmit coils to transfer power to the receive coil. An energy efficiency detection circuit is configured to detect an electrical response of each one of the transmit coils when energized by the power source, the electrical response indicative of an energy efficiency between the one of the transmit coils and the receive coil. The power source selectively energizes ones of the transmit coils, selected according to a statistical analysis of an historical record and the electrical response indicative of the energy efficiency meeting a minimum efficiency criterion for energy transfer to the receive coil.

A heated boot cover is disclosed. The heated boot cover comprises a layered material formed into an upper which is attached to a sole. The heated boot cover contains a layer of woven material having an electrically conductive yarn threaded throughout. The heating layer is disposed between a layer of fabric in the internal space of the boot cover and a thermal insulating layer. The outermost layer of material is a water resistant material. The boot cover has a fastener, such as a zipper, which has electrical connections so that the heating element of the boot cover can only be activated when the fastener is secured. The boot cover may have a transceiver which allows the operations of the boot cover to be controlled by a smart phone or other computerized device.

A heated boot cover is disclosed. The heated boot cover comprises a layered material formed into an upper which is attached to a sole. The heated boot cover contains a layer of woven material having an electrically conductive yarn threaded throughout. The heating layer is disposed between a layer of fabric in the internal space of the boot cover and a thermal insulating layer. The outermost layer of material is a water resistant material. The boot cover has a fastener, such as a zipper, which has electrical connections so that the heating element of the boot cover can only be activated when the fastener is secured. The boot cover may have a transceiver which allows the operations of the boot cover to be controlled by a smart phone or other computerized device.

Presenting a new approach to architect footwear as a communication and energy-transporting platform for personalized smart living. This is done by integrating the most advanced technologies today, along with some known technologies still under development, to provide solutions to power on demand for all personal and wearable devices. The systems, methods, and apparatuses disclosed in this invention make our personal and wearable devices smarter, thereby providing higher practical functions and more efficiency to our everyday lives.

Presenting a new approach to architect footwear as a communication and energy-transporting platform for personalized smart living. This is done by integrating the most advanced technologies today, along with some known technologies still under development, to provide solutions to power on demand for all personal and wearable devices. The systems, methods, and apparatuses disclosed in this invention make our personal and wearable devices smarter, thereby providing higher practical functions and more efficiency to our everyday lives.

The invention relates to an insole for a footwear including a non-moldable base layer (310) having an arch supporting portion (312) adapted to support an arch of a foot; and a moldable layer (330) overlaying the non-moldable base layer (310), such that the moldable layer (330) is adapted to be molded to conform to the arch of the foot. The invention also relates to a footwear comprising the insole.

A system, recharge apparatus, and method includes transmit coils positioned in a pattern to allow at least one of the transmit coils to establish a wireless link with a receive coil positioned in proximity of the recharge apparatus. A power source is coupled to the transmit coils and configured to selectively energize ones of the transmit coils to transfer power to the receive coil. An energy efficiency detection circuit is configured to detect an electrical response of each one of the transmit coils when energized by the power source, the electrical response indicative of an energy efficiency between the one of the transmit coils and the receive coil. The power source selectively energizes ones of the transmit coils, selected according to a statistical analysis of an historical record and the electrical response indicative of the energy efficiency meeting a minimum efficiency criterion for energy transfer to the receive coil.

An intelligent temperature controller for shoes includes a master chip, a heating unit, a temperature detecting unit detecting a current temperature of the shoes, a power source and a charging circuit connected with the power source, wherein the master chip is respectively and electrically connected with the heating unit, the temperature detecting unit and the power source, wherein the master chip controls the power source to supply power to the heating unit, wherein the master chip is communicated with an electric device to control the temperature of the shoes and provides operating states feedback to the electric device.

A method for distinguishing a foot motion of a user by placing a pedometer at a foot of a user includes the steps of collecting an accelerating data from an accelerometer in a real time manner; filtering the accelerating data via a smoothing filter and a Kalman filter; generating a step data that represents number of steps taken by the user in response to the accelerating data through the smoothing filter; generating an activity data that represents a foot motion of the user in response to the accelerating data through the Kalman filter; and combining the step data and the activity data to form a resulted data that distinguishes the foot motion with step count of the user.

A shoe includes a sole including front and rear compartments; a warming device in the front compartment; a main battery and circuit board in the rear compartment and enclosed by a first insulation member; a switch on a heel cap of the shoe; a display member on the heel cap a light emitting member on the heel cap; and an auxiliary battery enclosed by a second enclosure in the heel cap. The main battery and circuit board is electrically connected to the warming device, the push-button switch, the light emitting member, and the auxiliary battery respectively.