Abstract: A plurality of individually addressable electrodes is supported by a housing. The individually addressable electrodes are for at least one of applying stimulation electrical signals to skin of a user and detecting biometric electrical signals from the skin of the user. At least one of a signal detector is provided for detecting the biometric electrical signals and a signal generator is provided for generating the stimulation electrical signals. An electrode multiplex circuit is provided for addressing the plurality of individually addressable electrodes by at least one of routing the biometric electrical signals from the skin of the user through more than one of the plurality of individually addressable electrodes to the signal detector and routing the stimulation electrical signals from the signal generator through more than one of the plurality of individually addressable electrode to the skin of the user.

Abstract: A wearable electronic fabric comprises a woven fabric formed from a plurality of interlaced threads. The plurality of interlaced threads comprise a plurality of warp threads interlaced with a plurality of weft threads. The woven fabric has a top face and a bottom face. A plurality of conductive threads is included among the plurality of interlaced threads at predetermined intervals and interlacing angles to provide a pattern of connection locations. The connection locations are located at regular intervals on at least one of the top face and the bottom face of the woven fabric.

Abstract: The Thermal Footwear System includes an energy storage section adapted to store electrical energy and an energy release section electrically coupled to the energy storage section, configured to receive electrical energy from the energy storage section and utilize the electrical energy for production of thermal energy without requiring the use of energy overhead elements which cause expenditure of energy for other than heat generation. The Thermal Footwear System also provides for an energy storage section and a self-regulating energy release section printed on a substrate that can be physically separate and still remain electrically coupled.

Abstract: The Thin Film Energy Fabric includes an energy storage section; an energy release section coupled to the energy storage section; and an energy recharge section. In the energy release section, a self-regulating heater regulates itself specifically to a temperature determined before manufacture. This means that the resistive heating element changes its resistance depending on the instantaneous temperature of the heater without the use of sensors and added circuitry. In addition, the Positive Temperature Coefficient resistive heater is powered by the DC voltage output by the energy storage layer without the need for voltage converters or complex control circuitry.

Abstract: The Thin Film Energy Fabric includes an energy storage section adapted to store electrical energy; an energy release section coupled to the energy storage section and configured to receive electrical energy from the energy storage section and to utilize the electrical energy; and an energy recharge section, coupled to the energy storage section, adapted to receive or collect energy and convert the received or collected energy to electrical energy either for storage by the energy storage section or for use by the energy release section or simultaneous storage in the energy storage section and immediate use by the energy release section. The energy release section can provide electrical energy transmission capability to charge devices which are placed in a position juxtaposed to a surface of the Thin Film Energy Fabric.

Abstract: The Thin Film Energy Fabric includes an energy storage section adapted to store electrical energy; an energy release section coupled to the energy storage section and configured to receive electrical energy from the energy storage section and to utilize the electrical energy; and an energy recharge section, coupled to the energy storage section, adapted to receive or collect energy and convert the received or collected energy to electrical energy either for storage by the energy storage section or for use by the energy release section or simultaneous storage in the energy storage section and immediate use by the energy release section. The energy release section can provide electrical energy transmission capability to charge devices which are placed in a position juxtaposed to a surface of the Thin Film Energy Fabric. An optional protection section is provided on at least one side of the material.

Abstract: The Self-Regulating Heated Wound Dressing includes an energy storage section adapted to store electrical energy; an energy release section coupled to the energy storage section and configured to receive electrical energy from the energy storage section and to utilize the electrical energy in the generation of a thermal energy used to self-regulate the temperature of a heated wound dressing; and an energy recharge section, coupled to the energy storage section, adapted to receive or collect energy and convert the received or collected energy to electrical energy either for storage by the energy storage section or for use by the energy release section or simultaneous storage in the energy storage section and immediate use by the energy release section.