Automated footwear lacing systems, devices, and techniques

The claimed invention includes: 1. A lacing engine for an automated footwear platform, the lacing engine comprising: a housing; a lace spool at least partially disposed within the housing, the lace spool adapted to collect a portion of a lace cable in response to rotation in a first direction during tightening of the footwear platform; and a detection mechanism to directly measure a characteristic of the lace cable while the lace cable is manipulated by the lacing engine, wherein the detection mechanism includes an electrode adapted to measure an electrical parameter, and wherein the electrode is adapted to contact a portion of the lace spool with the lace cable is in a first state. 2. The lacing engine of claim 1 , wherein the electrode completes an electrical circuit through the lace spool when the lace cable is in the first state. 3. The lacing engine of claim 2 , wherein the electrical circuit exhibits a low impedance measurement when the lace cable is in the first state. 4. The lacing engine of claim 3 , wherein the first state of the lace cable is a fully extended state wherein only a portion of the lace spool contacts any lace cable. 5. The lacing engine of any one of claims 1 and 2 - 4 , wherein the electrode is adapted to contact the lace cable when the lace cable is in a second state. 6. The lacing engine of claim 5 , further comprising a circuit including the electrode and the lace spool, the circuit exhibiting a high impedance measurement when the lace cable is in the second state. 7. The lacing engine of any one of claims 1 and 2 - 4 , wherein the electrode is spring-loaded to maintain contact against the lace spool with or without lace cable wrapped around the lace spool. 8. A lacing engine for an automated footwear platform, the lacing engine comprising: a housing; a lace spool at least partially disposed within the housing, the lace spool including a recess to collect a portion of a lace cable in response to rotation in a first direction during tightening of the footwear platform; and a detection mechanism including a circuit comprising an electrode biased against the lace cable within the recess of the lace spool to measure an impedance across the lace spool, wherein the measured impedance of the circuit provides a measure of an amount of lace cable present on the lace spool. 9. The lacing engine of claim 8 , wherein the electrode completes an electrical circuit through the lace spool when the lace cable is in the first state. 10. The lacing engine of claim 9 , wherein the electrical circuit exhibits a low impedance measurement when the lace cable is in the first state. 11. The lacing engine of claim 10 , wherein the first state of the lace cable is a fully extended state wherein only a portion of the lace spool contacts any lace cable. 12. The lacing engine of claim 8 , wherein the electrode is adapted to contact the lace cable when the lace cable is in a second state. 13. The lacing engine of claim 12 , further comprising a circuit including the electrode and the lace spool, the circuit exhibiting a high impedance measurement when the lace cable is in the second state. 14. A lacing engine for an automated footwear platform, the lacing engine comprising: a lace spool including a recess to collect a portion of a lace cable in response to rotation in a first direction during tightening of the footwear platform; a detection mechanism including a circuit configured to measure impedance across the recess of the lace spool; and a controller circuit to determine an amount of lace cable on the lace spool based on the impedance measurement, wherein the detection mechanism includes an electrode biased against the lace cable to measure the impedance across the lace spool. 15. The lacing engine of claim 14 , wherein the circuit exhibits a low impedance measurement when the lace cable is in the first state and the controller circuit estimates zero lace cable on the lace spool based on the low impedance measurement. 16. The lacing engine of claim 15 , wherein the first state of the lace cable is a fully extended state wherein only a portion of the lace spool contacts any lace cable. 17. The lacing engine of claim 14 , wherein an electrode within the circuit is adapted to contact the lace cable when the lace cable is in a second state. 18. The lacing engine of claim 17 , wherein the circuit exhibits a high impedance measurement when the lace cable is in the second state and the controller circuit estimates the amount of lace cable on the lace spool based on the high impedance measurement.