Vision-guided stitching systems and logic for fabricating engineered textiles with interstitched superposed wires

What is claimed: 1. A method of constructing an engineered textile from a workpiece composed of superposed wires, the method comprising: receiving, via a system controller from an image capture device, image data indicative of a captured image of the workpiece; determining, via the system controller from the captured image of the workpiece, a plurality of joint locations for the superposed wires, the determining including locating multiple wire gaps each defined between a respective quadrangle of the superposed wires; commanding, via the system controller, a movable end effector to move a processing head attached to the movable end effector to thereby sequentially align the processing head with each of the joint locations, the processing head including a stitching head with a thread feeder and a sewing needle cooperatively configured to generate stitches; and commanding, via the system controller, the processing head to join the superposed wires at the joint locations to form the engineered textile, the joining including the stitching head inserting a succession of stitches within the wire gaps between the superposed wires. 2. The method of claim 1 , wherein the stitching head further includes a needle receiver, a bobbin case, and a shuttle hook, the method further comprising: commanding the needle receiver to reciprocally translate the sewing needle; commanding the bobbin case to feed a bobbin thread; and commanding the shuttle hook to create a lockstitch between the bobbin thread and a top thread fed from the thread feeder. 3. The method of claim 1 , wherein the image capture device is mounted to the movable end effector, the method further comprising capturing, via the image capture device, multiple images of the workpiece during movement of the movable end effector. 4. The method of claim 1 , further comprising: identifying, via the system controller within the captured image of the workpiece, respective sets of intersecting points of the superposed wires defining the quadrangles; and determining, within each of the respective sets, a center of a respective diagonal line segment connecting an opposing pair of the intersecting points, wherein locating the wire gaps includes designating the center of the diagonal line segment of each of the sets of intersecting points as one of the wire gaps. 5. The method of claim 1 , further comprising: identifying, via the system controller within the captured image of the workpiece, an estimated centerline for each of the superposed wires; and constructing the quadrangles of the superposed wires from the estimated centerlines, wherein locating the wire gaps includes designating a central region within each of the quadrangles between the estimated centerlines as one of the wire gaps. 6. The method of claim 1 , further comprising: identifying, via the system controller within the captured image of the workpiece, two intersecting points of the superposed wires defining two respective corners for each of the quadrangles; and determining, for each of the quadrangles, a central region at a calibrated angle from a line segment connecting the two respective corners and at a calibrated distance from one of the respective corners, wherein locating the wire gaps includes designating the central region of each of the quadrangles as one of the wire gaps. 7. The method of claim 1 , further comprising determining, via the system controller, path plan data for moving the processing head to join the superposed wires at the joint locations, the path plan data including an origin, a destination, and a joint route for traversing the processing head from the origin to the destination. 8. The method of claim 7 , further comprising: generating a trace of the joint route; determining a start position and an end position within the captured image of the workpiece; and superimposing the trace of the joint route onto the captured image of the workpiece with the origin overlapping the start position and the destination overlapping the end position. 9. The method of claim 8 , further comprising: determining a plurality of calibrated alignment points on the joint route; determining a respective displacement, if any, between each of the calibrated alignment points and a respective alignment location in the image of the workpiece; and determining a respective trace correction to offset each of the respective displacements. 10. The method of claim 1 , further comprising winding first and second layers of stretchable wire strands around a workpiece frame to define the superposed wires. 11. The method of claim 10 , wherein the workpiece frame includes a plurality of adjoining casing walls defining an inner frame space across which the first and second layers of stretchable wire strands are stretched, and a series of posts projecting from the casing walls and spaced from one another along the perimeter of the inner frame space, the wire strands being wound around the posts to retain the superposed wires in a tensioned, crisscrossed pattern. 12. The method of claim 1 , further comprising determining, via the system controller using sensor signals received from a position sensor, real-time positions of the processing head relative to a calibrated origin position. 13. The method of claim 12 , further comprising: receiving, via the system controller from the position sensor, the sensor signals indicative of the real-time positions of the processing head; determining, from the received sensor signals and the captured image of the workpiece, an estimated distance between each of the real-time positions of the processing head and a next adjacent one of the joint locations; and estimating a plurality of desired trajectories each based on the estimated distance between the real-time position of the processing head and the respective next adjacent one of the joint locations. 14. The method of claim 13 , further comprising determining, one-at-a-time in real-time via the system controller from the received sensor signals and the captured image of the workpiece, the respective next adjacent one of the joint locations closest to each of the real-time positions of the stitching head. 15. The method of claim 1 , wherein the movable end effector includes a support frame attached to a robot arm. 16. The method of claim 1 , characterized by a lack of weaving steps and a lack of knitting steps for constructing the engineered textile. 17. The method of claim 1 , further comprising stretching the superposed wires across a workpiece frame to form an intercrossed array of unwoven and unknitted wire windings. 18. The method of claim 1 , wherein the superposed wires include first and second wire strands each formed from an aliphatic or semi-aromatic polyamide material, an aromatic polyester material, an aramid material, a polypropylene material, and/or a polyethylene material. 19. A method of constructing an engineered textile from a workpiece composed of superposed wires, the method comprising: determining, via a system controller, a plurality of joint locations for the superposed wires; determining path plan data for moving a processing head attached to a movable end effector to join the superposed wires at the joint locations, the path plan data including an origin, a destination, and a joint route for traversing the processing head from the origin to the destination; generating a trace of the joint route; determining a start position and an end position within a captured image of the workpiece; superimposing the trac