Torque monitoring system for a rotatable shaft

What is claimed is: 1. A torque monitoring system, comprising: a plurality of rotatable measurement interfaces ( 102 ) configured to be attached to a rotatable shaft ( 90 ) to rotate with the rotatable shaft ( 90 ), the measurement interfaces ( 102 ) including a strain gauge ( 120 ), a processor ( 126 ), a near field communication (NFC) transceiver coil ( 130 ), wherein the rotatable shaft ( 90 ) is a primary drive shaft ( 302 ); and a plurality of stationary data receivers ( 104 ) contained in a housing ( 210 ) and stationary with respect to the rotatable shaft ( 90 ), the stationary data receivers ( 104 ) including a processor ( 126 ) and a NFC transceiver coil ( 140 ); a transmission; a parallel drive shaft ( 304 ) mechanically coupled to the primary drive shaft ( 302 ) through the transmission, wherein each of the primary and parallel drive shafts ( 302 , 304 ) includes at least one of the rotatable measurement interfaces ( 102 ) wirelessly coupled to a corresponding stationary data receivers ( 104 ); wherein the rotatable measurement interfaces ( 102 ) receives operating power via its NFC transceiver coil ( 130 ) that is derived from a radio signal wirelessly transmitted by the NFC transceiver coil ( 140 ) in the stationary data receiver ( 104 ); wherein the processor ( 126 ) in the rotatable measurement interfaces ( 102 ) is configured to receive strain gauge ( 120 ) signals from the strain gauge ( 120 ) indicative of torque on the rotatable shaft ( 90 ) and wirelessly transmit digital data indicative of the strain gauge ( 120 ) signals through the NFC transceiver coils ( 130 , 140 ) to the processor ( 126 ) in the stationary data receiver ( 104 ); and wherein each stationary data receiver ( 104 ) is configured to communicate with an electronics control unit (ECU) ( 110 ), and said ECU ( 110 ) is configured to determine an efficiency value for the transmission based on digital data received from rotatable measurement interfaces ( 102 ) on the primary drive shaft ( 302 ) and rotatable measurement interfaces ( 102 ) on the parallel drive shaft ( 304 ). 2. The torque monitoring system of claim 1 wherein the rotatable measurement interfaces ( 102 ) also include a switched reactance element to encode the digital data during transmission to the processor ( 126 ) in the stationary data receivers ( 104 ). 3. The torque monitoring system of claim 2 wherein the switched reactance element includes at least one of a selectable capacitive divider network and multiple taps of the NFC transceiver coil ( 130 ) in the rotatable measurement interfaces ( 102 ). 4. The torque monitoring system of claim 1 wherein the (ECU) ( 110 ) is coupled to the stationary data receivers ( 104 ) and configured to control a speed and torque of the primary drive shaft ( 302 ), and wherein, based on the digital data, the stationary data receivers ( 104 ) are configured to determine that the primary drive shaft ( 302 ) is experiencing a mechanical event and to respond to the determined event by sending a signal to the (ECU) ( 110 ) to adjust at least one of speed and torque of the primary drive shaft ( 302 ). 5. The torque monitoring system of claim 4 wherein the event includes at least one of: a vibration event, a tension event, compression event, a bending event, a resonance event, and a torque event. 6. The torque monitoring system of claim 1 wherein the processor ( 126 ) in the rotatable measurement interfaces ( 102 ) determines whether the strain gauge ( 120 ) detects a force in excess of a threshold. 7. The torque monitoring system of claim 1 wherein the processor ( 126 ) in the stationary data receivers ( 104 ) process the digital data to determine whether the strain gauge ( 120 ) in the rotatable measurement interfaces ( 102 ) detect a force in excess of a threshold. 8. The torque monitoring system of claim 1 wherein the processor ( 126 ) in the rotatable measurement interfaces ( 102 ) is configured to wirelessly transmit the digital data through the NFC transceiver coils ( 130 ) to the processor ( 126 ) in the stationary data receivers ( 104 ) even if the primary drive shaft ( 302 ) is not rotating.