A wearable may be provided with or configured to provide interactive skin. The interactive skin may be configured for accepting touch input from a user. The interactive skin may include one or more flexible layers and may include or be mounted under a transparent display cover layer such as a layer of clear glass or plastic. Interactive skin may include a touch-sensitive layer that allows a user to provide touch input to the wearable. Display pixels on interactive skin may be used to display visual information to the user. The interactive skin may be configured for detecting a condition of at least one wearable and generating an output function in response to the detected condition.

A method of manufacturing an illuminated athletic wear garment and an improved illuminated athletic wear garment. The method may include applying a first conductive trace to a surface of a first piece of fabric of the illuminated athletic wear garment and applying a second conductive trace to the surface of the first piece of fabric of the illuminated athletic wear garment. The method may further include affixing a plurality of lights to the illuminated athletic wear garment. The lights may each be connected to the first conductive trace and the second conductive trace. The first conductive trace and the second conductive trace may each be at least ¼ inch wide.

A multifunctional piece of athletic and/or work wear is presented. When worn as a compression sleeve to play rugby, American football and other ball-carrying sports (with oblong or round balls), or when worn to carry objects during physical labor, an object contact surface positioned on the inner forearm of the sleeve can grip the carried object with increased friction while an outside facing surface of the sleeve can be smooth to deflect defenders or objects that may impact the sleeve, can be padded to protect from impacts, can provide protection from contusions and lacerations, and/or can provide active cooling. The garment can further include static or dynamic readable symbols or images woven or knitted into the garment (rather than printed or fused onto the garment).

The present invention relates to a self-customized microLED wig. More specifically, one self-customized microLED wig comprises: a base plate (100) wrapped around the circumference of a wearer's head; hair parts (200) configured on the base plate; and a transparent microLED display skin (300) configured to cover the outer surfaces of the hair parts, wherein a master part (400) and a remote slave (500) are configured inside the base plate (100) so as to control the transparent microLED display skin (300), and a smart phone (600) is configured to enable the wearer to finally and selectively control the transparent microLED display skin (300), whereby the present invention is a useful invention which enables colors of the hair parts (200) to be variously changed according to the wearer's current situation.

A garment includes a fabric base layer and at least one side-emitting optical fiber retained to or integrated with the fabric base layer. The fabric base layer can stretch in the grain and cross grain direction of the fabric base layer. The at least one side-emitting optical fiber is located in at least one light-emitting zone to be located over a targeted body area of the person wearing the garment, and is configured to receive light from a light source and in the at least one light-emitting zone is configured to project light having a therapeutic wavelength toward the targeted body area.

The present invention relates to a self-customizable micro LED garment capable of changing colors and patterns like a TV screen and, more particularly, to a useful invention comprising: a garment (100) composed of upper and lower garments (110, 120) worn on a wearer's body; a transparent micro LED display skin (300) coated on the surface of the garment (100); a master unit (400) and a remote slave (500) inside the upper and lower garments (110, 120) of the garment (100); and a smartphone (600), wherein the transparent micro LED display skin (300) is selectively controlled by means of an application installed on the smartphone (600) by the wearer to express a variety of colors according to the current situation of the wearer.

There is disclosed apparel for providing protection and illumination. In an embodiment, a gaiter has a top portion and a bottom portion with a layer of material extending therebetween. The layer of material provides a protective covering to a lower limb of the user. At least one securement mechanism provides an adjustable attachment of the gaiter to the user. The selective mechanism allows attachment of the gaiter with a variety of footwear. A light housing is integrally disposed on an outward portion of the layer of material of the gaiter. The light housing provides illumination adjacent to the foot of a user. The combination of the gaiter and the light housing together provide a body-worn lighting device without attaching the light housing directly to any of the user, the footwear worn by the user, and clothing worn by the user. Other embodiments are disclosed.

A lighted decorative article includes an outer layer of material with a batting layer attached to the outer layer. The outer layer includes a number of light source apertures. A light source wiring harness includes a number of light sources operatively connected by electrical wire. The light sources are positioned within the light source apertures of the outer layer, and the electrical wire is secured to the batting layer. A liner is secured to the batting layer so as to cover the wire.

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.