Methods and systems for sensing tension in a timing belt

What is claimed is: 1. A transmission device comprising: a timing belt transmission configured to cause rotation of an output hub, wherein the timing belt transmission includes a timing belt with conductive properties that wraps around an input hub and the output hub in a loop; a voltage source coupled to the timing belt to apply a voltage to the timing belt; a first detector positioned between the input hub and the output hub on a first side of the loop of the timing belt for detecting a given resistance of a portion of the timing belt as the timing belt is placed under a tension and stretches due to a load at the output hub; a second detector positioned between the input hub and the output hub on a second side of the loop of the timing belt for detecting a given resistance of a portion of the timing belt as the timing belt is placed under the tension and stretches due to the load at the output hub; and one or more processors for determining output torque of the timing belt transmission based on respective resistances of the timing belt output by the first detector and the second detector. 2. The transmission device of claim 1 , wherein the first detector contacts the timing belt across two contact points and detects the given resistance across the two contact points. 3. The transmission device of claim 1 , wherein the one or more processors determine the output torque of the timing belt transmission based on a change in at least one of the given resistance of the timing belt output by the first detector and the second detector as the timing belt is placed under the tension. 4. The transmission device of claim 1 , wherein the first detector detects a first resistance of the timing belt when no load is present at the output hub, and then detects a second resistance of the timing belt as the timing belt is placed under the tension, and wherein the one or more processors determine the output torque of the timing belt transmission based on a change between the first resistance and the second resistance. 5. The transmission device of claim 1 , wherein the timing belt comprises a conductive polymer material that changes resistance when a force or pressure is applied. 6. The transmission device of claim 1 , further comprising: a motor coupled to the input hub, and configured to cause rotation of the input hub, wherein the timing belt wraps around the input hub and the output hub in the loop, such that rotation of the input hub causes rotation of the output hub. 7. The transmission device of claim 6 , wherein the one or more processors determine the output torque of the timing belt transmission based on a difference between respective resistances of the timing belt output by the first detector and the second detector. 8. The transmission device of claim 1 , wherein the one or more processors determine a default resistance of the timing belt, and determine a difference between the default resistance and at least one of the given resistance of the timing belt output by the first detector and the second detector as the timing belt is placed under a tension and stretches due to the load at the output hub. 9. The transmission device of claim 8 , wherein the default resistance is determined based on absence of the load at the output hub. 10. The transmission device of claim 8 , wherein the one or more processors determine the output torque based on the difference between the default resistance and the at least one of the given resistance of the timing belt output by the first detector and the second detector as the timing belt is placed under a tension and stretches due to the load at the output hub. 11. A transmission device comprising: a timing belt transmission configured to cause rotation of an output hub, wherein the timing belt transmission includes a timing belt with conductive properties; a motor connected to a pulley of an input hub, and configured to cause rotation of the input hub, wherein the timing belt wraps around the input hub and the output hub in a loop, such that rotation of the input hub causes rotation of the output hub; a first detector positioned between the input hub and the output hub on a first side of the loop of the timing belt for detecting a given resistance of a portion of the timing belt as the timing belt is placed under a tension and stretches due to a load at the output hub; a second detector positioned between the input hub and the output hub on a second side of the loop of the timing belt for detecting a given resistance of a portion of the timing belt as the timing belt is placed under the tension and stretches due to the load at the output hub; and one or more processors for determining output torque of the timing belt transmission based on respective resistances of the timing belt output by the first detector and the second detector. 12. The transmission device of claim 11 , further comprising a voltage source coupled to the timing belt to apply a voltage to the timing belt. 13. The transmission device of claim 11 , wherein the first detector contacts the timing belt across two contact points and detects the given resistance across the two contact points. 14. The transmission device of claim 11 , wherein the one or more processors determine the output torque of the timing belt transmission based on a change in at least one of the given resistance of the timing belt output by the first detector and the second detector as the timing belt is placed under the tension. 15. The transmission device of claim 11 , wherein the timing belt comprises a conductive polymer material that changes resistance when a force or pressure is applied. 16. The transmission device of claim 11 , wherein the one or more processors determine a default resistance of the timing belt, and determine a difference between the default resistance and at least one of the given resistance of the timing belt output by the first detector and the second detector as the timing belt is placed under a tension and stretches due to the load at the output hub. 17. The transmission device of claim 16 , wherein the default resistance is determined based on absence of the load at the output hub. 18. A method comprising: rotating an output hub using a timing belt transmission, wherein the timing belt transmission includes a timing belt with conductive properties and a motor connected to a pulley of an input hub, wherein the timing belt wraps around the input hub and the output hub in a loop, such that rotation of the input hub causes rotation of the output hub; detecting, by a first detector positioned between the input hub and the output hub on a first side of the loop of the timing belt, a given resistance of a portion of the timing belt as the timing belt is placed under a tension and stretches due to a load at the output hub, wherein the resistance of the timing belt changes as the timing belt is placed under the tension; detecting, by a second detector positioned between the input hub and the output hub on a second side of the loop of the timing belt, a given resistance of a portion of the timing belt as the timing belt is placed under a tension and stretches due to a load at the output hub; and determining output torque of the timing belt transmission based on respective resistances of the timing belt output by the first detector and the second detector. 19. The method of claim 18 , further comprising determining the output torque of the timing belt transmission based on a change in at least one of the given resistance of the timing belt output by the