Embroidered strain sensing elements

What is claimed is: 1. A deformation sensing fabric comprising: a fabric substrate comprising a first fabric layer; a first conductive element woven into the first fabric layer, and configured to: form a first strain gauge that outputs a first instrumented signal indicative of a measure of change in resistance of the first strain gauge in response to a strain applied to the fabric substrate along a length of the first strain gauge, and output the first instrumented signal, responsive to an applied stimulus signal; the first strain gauge comprises a meandering pattern of electrically conductive elastic yarn interwoven in the first fabric layer; the meandering interwoven pattern comprises one or more arcuate heads and a plurality of parallel elongate leads extending from ends of the one or more arcuate heads, the parallel leads formed along the length of the first strain gauge; the meandering interwoven pattern of electrically conductive elastic yarn forms a continuous electrically conductive path; the first strain-gauge has two distinct terminals, a first terminal and a second terminal, formed at two ends of the continuous electrically conductive yarn; and the first instrumented signal is measurable across the first and second terminals of the first strain-gauge. 2. A deformation sensing fabric comprising: a fabric substrate comprising a first fabric layer; and a first conductive element woven into the first fabric layer, and configured to output a first instrumented signal, responsive to an applied stimulus signal, indicative of a measure of change in an electrical property of the first conductive element in response to a strain applied to the fabric substrate along a long-axis of the first conductive element, and the first fabric layer comprises an electrically insulating fiber material; the first conductive element is configured to form a plurality of interdigitated coupled elements of a capacitor, including: a first coupled element comprising a first set of fingers interwoven into the first fabric layer along the long axis of the first conductive element, the first set of fingers physically and electrically connected by and extending along a first direction from a first base embroidered into the first fabric layer, and a second coupled element capacitively coupled to the first coupled element with a second set of fingers alternating with the first set of fingers and interwoven along the long axis of the first conductive element, the second set of fingers physically and electrically connected by and extending along a second direction from a second base embroidered into the first fabric layer, the second direction opposite and parallel to the first direction, the first set of fingers physically and electrically separated from the second set of fingers. 3. The deformation sensing fabric of claim 2 , wherein: the first instrumented signal represents an increase in capacitance between the interdigitated coupled elements in response to a strain applied to the fabric substrate along lengths of the first and second sets of fingers; and the first instrumented signal represents a decrease in capacitance between the interdigitated coupled elements in response to a strain applied to the fabric substrate perpendicular to the lengths of the first and second sets of fingers. 4. The deformation sensing fabric of claim 2 , wherein the first and second coupled elements are encapsulated by a first and a second electrically insulating elastic fiber material coating configured to be interwoven amidst threads of the electrically insulating fiber material and configured to deform corresponding to deformation of the first and second coupled elements. 5. A deformation sensing fabric comprising: a fabric substrate comprising a first fabric layer that comprises a first electrically insulating fiber material; a first conductive element woven into the first fabric layer, and configured to: form a first strain gauge, first strain gauge comprises a first electrically conductive elastic fiber material interwoven amidst threads of the first electrically insulating fiber material, and output the first instrumented signal, responsive to an applied stimulus signal, the first instrumented signal is indicative of a change in resistance of the first strain gauge in response to a strain applied to the fabric substrate along a length of the first strain gauge; the fabric substrate further comprises a second fabric layer comprising a second electrically insulating fiber material and an electrically insulating interstitial layer formed between the first and second fabric layers; the deformation sensing fabric further comprises a second conductive element interwoven into threads of the second fabric layer, the second conductive element configured to output a second instrumented signal in response to a strain applied in the same first direction; the second conductive element is configured to form a second strain gauge and the second instrumented signal is indicative of a change in resistance of the second strain gauge in response to a strain applied to the fabric substrate along a length of the second strain gauge; and the second strain gauge comprises a second electrically conductive elastic fiber material interwoven amidst threads of the second electrically insulating fiber material. 6. The deformation sensing fabric of claim 5 , wherein the first and second strain gauges are encapsulated by a first and a second electrically insulating elastic fiber material coating configured to be interwoven respectively into the first and second fabric layers and configured to deform corresponding to respective deformation of the first and second strain gauges. 7. The deformation sensing fabric of claim 5 , wherein: the first strain-gauge comprises a first continuous electrically conductive yarn with two distinct terminals, a first terminal and a second terminal, formed at two ends of the first continuous electrically conductive yarn; the first instrumented signal is a resistance measurement across the first and second terminals of the first strain-gauge; the second strain-gauge element comprises a second continuous electrically conductive yarn with two distinct terminals, a third terminal and a fourth terminal, formed at two ends of the second continuous electrically conductive yarn; and the second instrumented signal is a resistance measurement across the third and fourth terminals of the second strain-gauge. 8. A deformation sensing fabric comprising: a fabric substrate comprising a first fabric layer that comprises a first electrically insulating fiber material; a first conductive element woven into the first fabric layer, and configured to: form a first strain gauge that comprises a first electrically conductive elastic fiber material interwoven amidst threads of the first electrically insulating fiber material, and output a first instrumented signal, responsive to an applied stimulus signal, and the first instrumented signal is indicative of a change in resistance of the first strain gauge in response to a strain applied to the fabric substrate along a length of the first strain gauge; the fabric substrate further comprises a second fabric layer and an electrically insulating interstitial layer formed between the first and second fabric layers; the deformation sensing fabric material further comprises a second conductive element interwoven into threads of the second fabric layer, the second conductive element configured to output a second instrumented signal in response to a strain applied in a second direction, the second direction perpendicular to the first direction, the second direction along a long-axis of the second conductive element; and the second condu