System includes a haptic garment comprising an integrated circuit (IC) controller coupled to the haptic garment. A sensing circuit configured to cause to transmit a motion signal sensed by a portion of the haptic garment surface to the IC controller is provided. The motion signal is based on one or more of a touch pattern, a gesture pattern, and a movement pattern associated with a user of the haptic garment. The IC controller is configured to transmit a first data associated with the motion signal to an external device. Conductive traces embedded in the haptic garment that electrically couple with the sensing circuit.

The various embodiments herein provide a multi-fabric apparel comprising a first fabric, a second fabric and a third fabric. The first fabric forms an upper surface of the apparel. The second fabric is stitched to the first fabric and forms a lower surface of the apparel. The third fabric is stitched between the first fabric and the second fabric forming an intermediate layer. The third fabric comprises a first layer and a second layer. The first layer is stitched between the first fabric and the second fabric, and the second layer is stitched to a second surface of the second fabric in a way that the second fabric is sandwiched between the first layer and the second layer.

The present disclosure discloses a human body simulation model, a fitting device, a fitting server, and a control method. The human body simulation model includes: a human body model; a photodeformable shaping garment; a plurality of excitation light sources; a plurality of elastic elements; and a first controller configured to control at least a part of the plurality of excitation light sources to emit light waves to the photodeformable shaping garment according to body shape parameters of a user received, so that the photodeformable shaping garment is deformed to simulate a body shape of the user.

The wearable article 100 comprises an inner fabric layer 101 and an outer fabric layer 11loverlapping the inner fabric layer 101 to form an overlapping region 121. An electronics component 200a, 200b is disposed at least partially between the inner and outer fabric layer 101, 111 in the overlapping region 121. The inner fabric layer 101 comprises an opening 143a, 143b to expose part of the electronics component 200a, 200b.

An illustrated view of an exemplary improved mask for allowing clearer voice communication is presented. The mask is useful for providing clearer voice communication when the mask is being worn. Also, the mask is useful preventing the spread of infectious diseases such as COVID. The mask further is light-weight, comfortable and cost efficient.

A tactical vest worn communication control hub has cables extending to transceivers, a headset, and PTT switches. The cables are operationally interconnected within the hub by a circuit board to enable the switches to control operation of the transceivers to receive and transmit and to convey audio signals to and from the headset. The hub is configured to be removably attached to the rear of the vest.

A system and method for social-physical haptic interaction that include receiving sensor data from a plurality of sensors that are disposed within a haptic vest. The system and method also include training a neural network with at least one haptic interaction profile based on the sensor data. The system and method additionally include analyzing at least one haptic interaction profile during execution of at least one haptic application. The system and method further include electronically controlling the haptic vest to provide haptic feedback during the execution of at least one haptic application that is based on at least one haptic interaction profile.

The present disclosure generally relates to intelligent garments that provide thermal regulation in a variety of environments. The garments may include different layers such as a hydrophobic layer in direct contact with a wearer's skin surface and saturated with an aqueous mixture, a spacer layer, a reflective layer, and an outer hydrophobic layer. The layers of the garment may work together to reduce the metabolic expenditure of the wearer in extreme environmental conditions or during demanding physical activity. A variety of sensors may be displaced throughout the garments so as to enable the collection of data associated with wearers as well as environmental conditions. Wearers may control the thermal balance and other properties of the garments as desired.

A sensor system includes a touch sensor having a plurality of conductive sensing elements integrated with a flexible substrate. A first subset of sensing elements is coupled to a first side of the flexible substrate and a second subset of sensing elements is coupled to a second side of the flexible substrate. The sensor system is configured to obtain touch data associated with a touch input to the touch sensor. The touch data is based at least in part on a respective response to the touch input by the plurality of conductive sensing elements. The sensor system is configured to determine whether the touch input is associated with the first subset of conductive sensing elements or the second subset of conductive sensing elements based at least in part on the respective response to the touch input by the sensing elements.

A system and method of detecting changes in an environment of an open circuit resonator configured to generate a signal when wirelessly powered by an external oscillating magnetic field, wherein the signal varies as a function of one or more environmental factors associated with the environment about the open circuit resonator. A monitoring device receives the signal from the open circuit resonator, captures data representative of the signal, compares the captured data to data previously received from the sensor to determine changes in the data, and estimates, based on the changes in the data, changes in one or more of the environmental factors.