A clothing-type fabric capable of heating itself and cooling itself for the bodily comfort of a wearer includes a fabric body, at least two first electrodes, a second electrode, and a processor. The fabric body includes an inner surface and an outer surface opposite to the inner surface. The at least two first electrodes are disposed above the inner surface and the outer surface. The first electrode disposed above the inner surface can sense a body temperature of a wearer (first temperature value). The first electrode disposed above the outer surface can sense temperature of ambient environment (second temperature value). The second electrode is disposed above the inner surface, and can release heat and absorb heat. The processor can receive the first and the second temperature values, and control the second electrode to release or absorb heat by reference to the first temperature value and the second temperature value.

An active deformable semi-rigid element is combined with a garment and power source to create a pumping action to create a cooling flow of air across a wearer's body.

An electrically heatable, above-the-calf, oversock is formed by interconnected fabric sections. The oversock defines a foot section and a leg section interconnected with one another. The foot section has a toe heating section secured thereto. The leg section is formed of interconnected pattern fabric panels secured together by thread seams. In one embodiment of the oversock, the pattern fabric panels include two elongated side fabric panels extending from a top end of the leg section to the foot section, a front panel and a rear panel. At least the lateral one of the two elongated side fabric panels is formed by two or more superimposed side panel pattern pieces interconnected to one another by stitch seams and defining there between a channel through which extends a power feed wire from a switch secured in a upper part of the channel and accessible from an outer surface of the lateral side panel. The feed wire extends to the toe heating section where it is secured to a toe heating wire. An oversock retainer is secured about a top end of the leg section for retention of the oversock above the calf of a wearer person's leg.

A wader suit system, including a personal flotation device (PFD), that helps to maintain body temperature of a wearer in extreme conditions is disclosed. The wader suit system includes a heated jacket system having an upper liner. The upper liner connects beneath the heated jacket system. The upper liner includes a first micro-wire. The heated jacket system includes a control panel. The wader suit system further includes a lower section having a chest portion and legs. The lower section encompasses a lower liner having a second micro-wire. The second micro-wire connects to the control panel. The heated jacket system connects over the lower section. Alternatively, the heated jacket system connects beneath the lower section. The control panel allows the wearer to control the temperature of said first micro-wire and said second micro-wire for maintaining body temperature of the wearer in the extreme conditions such as in water and freezing conditions.

A garment system comprises a garment substrate formed from one or more textile-based sheets, a distributed array of a plurality of resistive pressure sensors coupled to the garment substrate at a set of first specified locations. Each of the plurality of resistive sensors comprises a pair of first textile-based outer layers each having an electrical resistance of no more than 100 ohms and a textile-based inner layer sandwiched between the pair of first textile-based outer layers having an electrical resistance of at least 1 mega-ohm. The system also includes electronics configured to process signals from the distributed array of resistive pressure sensors to determine one or more physiological properties of a wearer of the garment substrate.

An integrated wearable energy generation and annunciation system is presented. The system includes a wearable item. The system also includes a plurality of solar panels integral with the wearable item and positionable on the wearable item. The system includes a plurality of light emitting diode (LED) panels integral with the wearable item and positionable on the wearable item. The system includes a plurality of batteries configured to receive power from the solar panels and to power LED panels and system components. The system also includes control circuitry arranged to interface the solar panels, the LED panels, system components, and the batteries. The system also includes a control platform structured to provide control functions for the system to generate power from the plurality of solar panels, to charge the batteries, to power and display data on the LED panels, and to coordinate functionality amongst system components.

A system for monitoring a user includes a garment configured to be placed on a foot of the user, a cover coupled to the garment, and a sensor arrangement between the garment and the cover, wherein the sensor arrangement comprises at least one temperature sensor to measure at least one temperature on the foot of the user. A method for making a system for monitoring a user includes forming a sensor arrangement including at least one sensor lead coupled to a temperature sensor, positioning at least a portion of the sensor arrangement on a garment configured to be placed on a foot of the user, and enclosing at least the portion of the sensor arrangement between the garment and a cover.

The present disclosure relates to a reception apparatus and method, a transmission apparatus and method, and a program, capable of obtaining desired communication quality. Under the control of a central control unit, a tactile signal generation unit generates a tactile signal of a necessary number. Under the control of the central control unit, a header generation unit generates header information including the presence or absence of the tactile signal (that is, information indicating whether or not the tactile signal is to be used for each of vibration units as information associated with the vibration unit that uses the tactile signal), the delay amount, and the magnitude. A signal coupling unit adds header information to each of the tactile signals from the tactile signal generation unit, and performs time-division multiplexing on each of the tactile signals to which the header information has been added. The present disclosure can be applied to a tactile presentation system that vibrates a wearable reception apparatus including the vibration unit, for example.

A lawn mower has an electrical port that receives current from an alternator powered by the lawn mower engine. The current and voltage sent the electrical port depend on a flywheel and stator arrangement operatively connected to the alternator. The stator may be replaceable or interchangeable to selectively determine the alternator current and voltage output. The port receives a plug from a garment worn by the lawn mower operator. The garment includes one or more thermo-electric elements that are powered from current extending through the port. The thermo-electric elements may be resistive heaters to warm the operator or TEC coolers to cool the operator. Furthermore, the garment may include a rechargeable battery that powers the thermo-electric elements when the plug is disconnected from the port.

A garment system comprises a garment substrate formed from one or more textile-based sheets, a distributed array of a plurality of resistive pressure sensors coupled to the garment substrate at a set of first specified locations. Each of the plurality of resistive sensors comprises a pair of first textile-based outer layers each having an electrical resistance of no more than 100 ohms and a textile-based inner layer sandwiched between the pair of first textile-based outer layers having an electrical resistance of at least 1 mega-ohm. The system also includes electronics configured to process signals from the distributed array of resistive pressure sensors to determine one or more physiological properties of a wearer of the garment substrate.