Abstract: An elastic and conductive fiber includes a cladding with a channel and a conductor disposed therein. The cladding may be made of a thermoplastic elastomer. The conductive fiber includes an excess length of conductor disposed inside of the channel so that the conductive fiber can stretch without applying substantial strain to the conductor and without substantially changing the electrical resistance of the conductive fiber. The conductor inside of the channel may have a buckled shape or a helical shape.

Abstract: Exemplary embodiments use a single, physical embodiment that compiles independent machine-readable codes together with little to no space in between codes. This physical embodiment is in two primary forms—adhesive tape or fabric strips with hook and loop backing. A code reader device, with software compatible with the machine-readable codes, can rapidly or simultaneously aggregate independent codes together on the physical embodiment in order to assign them to one or more digital addresses.

Abstract: The acoustic fiber transducer has a piezoelectric domain with Young's modulus, Epiezo, and including a non-centrosymmetric crystalline-phase piezoelectric material and inorganic piezoelectric particles. At least one charge collector domain is in electrical connection with the piezoelectric domain and includes an electrically conductive material operative to collect electrical charge generated in the piezoelectric domain. At least one electrical conductor is in electrical contact with the at least one charge collector domain and includes an electrically conductive material operative to transport electrical charge from a charge collector domain to an end of the acoustic fiber transducer as an electrical signal indicative of input acoustic sound pressure on a matrix of textile fibers that includes the acoustic fiber transducer. Outer acoustic energy transmission material has a Young's modulus Etrans, of 0.3 Pa-500 MPa, for matching vibrational modes of the textile fiber matrix.

Abstract: Methods for generating porous scaffolds may include tuning a porogen/crystallite's particle size to a desired range and mixing the crystallite particles with a polymer solution. The mixture is then cast to form films. The films are rolled and consolidated around another inner material to create a preform, which is then thermally drawn. The inner material and the porogen can be selectively removed to obtain porous constructs/fibers. The structures can be fuse-printed to produce complex tissue scaffolds with dimensions up to several centimeters and beyond.

Abstract: Exemplary embodiments use a single, physical embodiment that compiles independent machine-readable codes together with little to no space in between codes. This physical embodiment is in two primary forms—adhesive tape or fabric strips with hook and loop backing. A code reader device, with software compatible with the machine-readable codes, can rapidly or simultaneously aggregate independent codes together on the physical embodiment in order to assign them to one or more digital addresses.

Abstract: Exemplary embodiments use a single, physical embodiment that compiles independent machine-readable codes together with little to no space in between codes. This physical embodiment is in two primary forms—adhesive tape or fabric strips with hook and loop backing. A code reader device, with software compatible with the machine-readable codes, can rapidly or simultaneously aggregate independent codes together on the physical embodiment in order to assign them to one or more digital addresses.

Abstract: Provided herein is a fiber having a fiber body including fiber body material with a longitudinal-axis fiber body length. A plurality of gel domains is disposed within the fiber body along at least a portion of the longitudinal-axis fiber body length. Each gel domain includes a porous host matrix material and a liquid gel component that is entrapped in the molecular structure of the host matrix material and that is disposed in interstices of the host material matrix. At least two of the gel domains within the fiber body are disposed directly adjacent to each other in direct physical contact with each other. This fiber can include polymeric fiber body material and gel domains including a porous polymer host matrix material and an ionically conducting liquid solvent that is entrapped in the molecular structure of the polymer host matrix material and disposed in interstices of the polymer host material matrix.

Abstract: Provided is a fabric including a plurality of fibers disposed in a fabric configuration. At least one of the fibers comprises a device fiber having a device fiber body including a device fiber body material, having a longitudinal axis along a device fiber body length. A plurality of discrete devices are disposed as a linear sequence within the device fiber body along at least a portion of the device fiber body length. Each discrete device includes at least one electrical contact pad. The device fiber body includes device fiber body material regions disposed between adjacent discrete devices in the linear sequence, separating adjacent discrete devices. At least one electrical conductor is disposed within the device fiber body along at least a portion of the device fiber body length. The electrical conductor is disposed in electrical connection with an electrical contact pad of discrete devices within the device fiber body.

Abstract: In a method for printing a three dimensional structure, a continuous length of fiber that includes, interior to a surface of the fiber, a plurality of different materials arranged as an in-fiber functional domain, with at least two electrical conductors disposed in the functional domain in electrical contact with at least one functional domain material, is dispensed through a single heated nozzle. After sections of the length of fiber are dispensed from the heated nozzle, the sections are fused together in an arrangement of a three dimensional structure. The structure can thereby include a continuous length of fiber of least three different materials arranged as an in-fiber functional device, with the continuous length of fiber disposed as a plurality of fiber sections that are each in a state of material fusion with another fiber section in a spatial arrangement of the structure.

Abstract: An article is a selected one of a set of articles. Each article of the set includes a fabric and is associated with a unique identification code. The selected article has a pattern distributed over at least 10% of an exposed surface of the selected article. The pattern encodes the identification code associated with the selected article, wherein the pattern is configured to be read and decoded by a mobile computing device in a manner wherein the selected article is contextually recognizable. A two-dimensional plaid pattern may be used to carry the identification code, which can be decoded according to described methods.

Abstract: Exemplary embodiments use a single, physical embodiment that compiles independent machine-readable codes together with little to no space in between codes. This physical embodiment is in two primary forms—adhesive tape or fabric strips with hook and loop backing. A code reader device, with software compatible with the machine-readable codes, can rapidly or simultaneously aggregate independent codes together on the physical embodiment in order to assign them to one or more digital addresses.

Abstract: A fiber computer has a fiber body including electrically insulating fiber body material along the length of the fiber body. Electrical conductors are disposed within the fiber body and are operative to transmit electrical power, electrical ground, clock signals, and data signals through the fiber body. Input units disposed within the fiber body accept external stimuli. Microcontroller microchips disposed within the fiber body process stimuli accepted by an input unit. Memory module microchips within the fiber body store data and communicate with microcontroller microchips. Output units produce an output directed out of the fiber body. A clock signal generator within the fiber body synchronizes operation of input units, microcontroller microchips, memory module microchips, and output units.

Abstract: A fabric or article has a pattern on an exposed surface that encodes a unique identification code, wherein the pattern is configured to be read and decoded by a mobile computing device in a manner wherein the selected article is contextually recognizable. A two-dimensional plaid pattern may be used to carry the identification code, which can be decoded according to described methods. The pattern may be a plaid code or may be incorporated into a representational aesthetic environment. Fabrics may include optical transmitters embedded therein and configured to transmit information that can be detected by a mobile computing device, directed to the wearable article, and executing a suitable application. Fabrics may include optical receives configured to receive information such as from a free-space optical communication system of certain embodiments.

Abstract: Methods for generating porous scaffolds may include tuning a porogen/crystallite's particle size to a desired range and mixing the crystallite particles with a polymer solution. The mixture is then cast to form films. The films are rolled and consolidated around another inner material to create a preform, which is then thermally drawn. The inner material and the porogen can be selectively removed to obtain porous constructs/fibers. The structures can be fuse-printed to produce complex tissue scaffolds with dimensions up to several centimeters and beyond.

Abstract: There is provided a fiber that includes a fiber material disposed along a longitudinal-axis fiber length. A porous domain has a porous domain length along at least a portion of the fiber length, within the fiber material. The porous domain includes solid-phase material regions and fluid-phase interstitial regions that are both along the porous domain length and across the porous domain, for multi-dimensional porosity of the porous domain.

Abstract: A color-changing flexible fiber that can be incorporated into fabrics and other woven materials. The color changing flexible fibers are hollow and include at least two wire electrodes integrated into the wall of the hollow fiber that provide an electrical potential across an electro-optic medium disposed inside the hollow fiber. The electro-optic medium includes a non-polar solvent and at least one set of charged particles.

Abstract: Exemplary embodiments use a single, physical embodiment that compiles independent machine-readable codes together with little to no space in between codes. This physical embodiment is in two primary forms—adhesive tape or fabric strips with hook and loop backing. A code reader device, with software compatible with the machine-readable codes, can rapidly or simultaneously aggregate independent codes together on the physical embodiment in order to assign them to one or more digital addresses.

Abstract: Provided is a fabric including a plurality of fibers disposed in a fabric configuration. At least one of the fibers comprises a device fiber having a device fiber body including a device fiber body material, having a longitudinal axis along a device fiber body length. A plurality of discrete devices are disposed as a linear sequence within the device fiber body along at least a portion of the device fiber body length. Each discrete device includes at least one electrical contact pad. The device fiber body includes device fiber body material regions disposed between adjacent discrete devices in the linear sequence, separating adjacent discrete devices. At least one electrical conductor is disposed within the device fiber body along at least a portion of the device fiber body length. The electrical conductor is disposed in electrical connection with an electrical contact pad of discrete devices within the device fiber body.

Abstract: A textile capable of detecting electromagnetic radiation includes interlaced fibers; a photodetector embedded, as a result of a fiber draw process, within a particular one of the fibers; and a first electrical conductor extending within the particular fiber and along a longitudinal axis thereof. The first electrical conductor is in electrical contact with the photodetector, and the photodetector position in the particular fiber corresponds to a lowest energy configuration relative to a pattern of flow along the longitudinal axis of the particular fiber throughout the fiber draw process. A method of manufacturing the textile and a system including the textile are also disclosed.

Abstract: Provided herein is a fiber having a fiber body including fiber body material with a longitudinal-axis fiber body length. A plurality of gel domains is disposed within the fiber body along at least a portion of the longitudinal-axis fiber body length. Each gel domain includes a porous host matrix material and a liquid gel component that is entrapped in the molecular structure of the host matrix material and that is disposed in interstices of the host material matrix. At least two of the gel domains within the fiber body are disposed directly adjacent to each other in direct physical contact with each other. This fiber can include polymeric fiber body material and gel domains including a porous polymer host matrix material and an ionically conducting liquid solvent that is entrapped in the molecular structure of the polymer host matrix material and disposed in interstices of the polymer host material matrix.