Fluid pressure pulse generating apparatus and method of using same

The invention claimed is: 1. A fluid pressure pulse generating apparatus comprising: (a) a pulser assembly comprising: a brushless motor; an inductive sensor for detecting output signals generated by rotation of the motor; a driveshaft rotationally coupled to the motor; processing and motor control equipment communicative with the motor and the sensor; and a mechanical stop sub-assembly comprising a collar fixedly coupled to the motor and at least one indexer protruding from a side of the driveshaft, the collar comprising an angular movement restrictor window with a central window segment which axially and rotatably receives the driveshaft, and an indexing window segment in communication with the central window segment and which receives the indexer, the indexing window segment having an angular span across which the indexer can be oscillated by the driveshaft; and (b) a fluid pressure pulse generator comprising a stator, and a rotor fixedly attached to the driveshaft such that the angular span of the indexing window segment defines the angular range of the rotor's angular movement relative to the stator. 2. The apparatus of claim 1 , wherein the inductive sensor comprises a Hall Effect sensor. 3. The apparatus of claim 1 , wherein the inductive sensor comprises multiple Hall Effect sensors. 4. The apparatus of claim 1 , wherein the pulser assembly further comprises a gearbox coupled with the motor and the driveshaft. 5. The apparatus of claim 1 , wherein the brushless motor comprises a motor rotor rotationally mounted in a fixed motor stator, the motor rotor comprising a first end having an output shaft and an opposed second end, whereby the output shaft is rotationally coupled to the driveshaft and the sensor is coupled with the second end. 6. The apparatus of claim 5 , wherein the processing and motor control equipment is electrically coupled with the motor and the sensor by at least one electrical interconnection extending therebetween. 7. The apparatus of claim 6 , wherein the pulser assembly comprises: a motor subassembly comprising a motor subassembly housing enclosing the motor, the sensor and the driveshaft; an electronics subassembly comprising an electronics subassembly housing enclosing the processing and motor control equipment; and a feed through connector located between the motor subassembly and the electronics subassembly, the feed through connector comprising a body with the at least one electrical interconnection extending axially through the body. 8. A method of calibrating a fluid pulse generating apparatus of claim 1 , comprising: (a) a pulser assembly comprising: a motor; a sensor for detecting rotation of the motor a driveshaft rotationally coupled to the motor: processing and motor control equipment communicative with the motor and the sensor; and a mechanical stop sub-assembly comprising a collar fixedly coupled to the motor and at least one indexer protruding from a side of the driveshaft, the collar comprising an angular movement restrictor window with a central window segment which axially and rotatably receives the driveshaft, and an indexing window segment in communication with the central window segment and which receives the indexer, the indexing window segment having an angular span across which the indexer ran be oscillated by the driveshaft: and (b) a fluid pressure pulse generator comprising a stator, and a rotor fixedly attached to the driveshaft such that the angular span of the indexing window segment defines the angular range of the rotor's angular movement relative to the stator, the method comprising: (c) rotating the motor to rotate the driveshaft and oscillate the indexer across the angular span of the indexing window segment; (d) measuring output signals generated by rotation of the motor and detected by the sensor as the indexer oscillates across the angular span, whereby a known number of output signals are generated per revolution of the motor; (e) determining the number of output signals detected per oscillation of the indexer across the angular span; (f) calculating the number of output signals that need to be generated by rotation of the motor to rotate the driveshaft from a first position where the indexer is at an edge of the indexing window segment to a calibration position within the angular span from the number of motor output signals detected per oscillation of the indexer across the angular span; (g) rotating the motor to rotate the driveshaft from the first position to the calibration position and counting output signals generated by rotation of the motor and detected by the sensor during rotation of the driveshaft from the first position to the calibration position; and (h) stopping rotation of the motor when the number of output signals counted equals the calculated number of output signals. 9. The method of claim 8 , wherein the calibration position is the central point of the angular span of the indexing window segment whereby the rotor is positioned relative to the stator to flow a drilling fluid in a full flow configuration to produce no pressure pulse. 10. The method of claim 8 , wherein the motor is a brushless motor and the output signals comprise an alternating magnetic field. 11. The method of claim 10 , wherein the sensor comprises at least one Hall Effect sensor that varies its output voltage in response to the alternating magnetic field to generate a sensor state, and the step of measuring output signals and the step of counting output signals comprising counting sensor states generated by rotation of the motor.