Abstract: An example wearable device that includes a conductive deformable fabric is described herein. The conductive deformable fabric has a conductive trace that has a non-extendable fixed length along a first axis, and the conductive trace is sewn into a fabric structure to produce a conductive deformable material. The fabric structure includes a stitch pattern that facilitates the conductive trace to unfold and fold in an oscillating fashion to allow the conductive trace to expand and contract, respectively, along the first axis without exceeding the fixed length of the conductive trace. The conductive deformable material is positioned within the wearable device such that when the wearable device is worn, the stitch pattern is over a joint of the user to allow the stitch pattern to expand or contract along with the movement of the joint.

Abstract: An example wearable device that includes a conductive deformable fabric is described herein. The conductive deformable fabric has a conductive trace that has a non-extendable fixed length along a first axis, and the conductive trace is sewn into a fabric structure to produce a conductive deformable material. The fabric structure includes a stitch pattern that facilitates the conductive trace to unfold and fold in an oscillating fashion to allow the conductive trace to expand and contract, respectively, along the first axis without exceeding the fixed length of the conductive trace. The conductive deformable material is positioned within the wearable device such that when the wearable device is worn, the stitch pattern is over a joint of the user to allow the stitch pattern to expand or contract along with the movement of the joint.

Abstract: Active fabrics can be created by combining active and passive materials. Active materials with shape memory or other actuation characteristics can generate compression or dynamic fit, and the level of compression and/or change in fit can be determined by setting a knit index, wire diameter, and garment ease, or fit in relation to the body. Maximum compression can be set not only by varying physical properties of the knit structure but by built-in circuit breaking technologies, or by segmentation and control of the garment by a controller. In some embodiments, additive manufacturing can be combined with traditional textile equipment (e.g., circular knitting machine). Uniquely functional or active textiles can be made from additively manufactured, heterogeneous filaments. Yarn-like filament with varying properties (such as elasticity, stiffness, conductivity, activation, or surface properties) can be additively manufactured.

Abstract: Compressive garments described herein include an inner layer, a middle layer coupled to the inner layer, the middle layer comprising a plurality of circuits, each circuit of the plurality of circuits comprising a superelastic cable and a circuit breaker, and a outer layer removably coupled to at least one of the inner layer and the middle layer.