Encoderless motor with improved granularity and methods of use

The invention claimed is: 1. A DC electric motor comprising: a stator mounted to a substrate, the stator comprising a coil assembly having a core of magnetic material and electrical windings, the coil assembly having an outside diameter, a proximal extremity, and a distal extremity; a rotor mounted to the stator, the rotor comprising permanent magnets mounted to a cylindrical skirt and each extending to a distal edge, the rotor having an outside diameter, an inside diameter, wherein the distal edges of the permanent magnets extend beyond the coil assembly in a vertical direction when the rotor is oriented horizontally; and a plurality of sensors mounted to the substrate adjacent the distal edges of the permanent magnets along the vertical direction when the rotor is oriented horizontally, wherein a displacement of the motor is determinable from a signal from a sensor of the plurality of sensors; wherein a clearance between the extended distal edge of each of the permanent magnets and the plurality of sensors is defined such that during operation of the motor when the rotor is oriented horizontally, passage of the permanent magnets over the plurality of sensors produces a plurality of intersecting substantially sinusoidal signals of varying voltage; a processor module communicatively coupled with the plurality of sensors and configured to: receive the plurality of voltage signals from the plurality of sensors during rotation of the rotor, each signal having a linear portion corresponding to a straight line segment between crossing points; and determine a displacement of the motor from only the linear portion of the sinusoidal signal from a respective sensor of the plurality of sensors. 2. The motor of claim 1 , wherein the plurality of sensors mounted to the substrate are positioned relative the extended distal edges of the permanent magnets, with the clearance from the extended distal edges of the permanent magnets to the plurality of sensors sufficient to provide a voltage of from about 2 to about 5 volts DC. 3. The motor of claim 2 , wherein the extended edge of the permanent magnets extend beyond the distal extremity of the coil assembly by about 1 mm or more. 4. The motor of claim 1 , wherein the plurality of sensors are linear Hall-effect sensors, spaced apart by a common arc length along an arcuate path of the rotor. 5. The motor of claim 4 , comprising an even number of permanent magnets evenly spaced around the cylindrical skirt with adjacent magnets exhibiting opposite polarity at the distal edge of the skirt, and three Hall-effect sensors, each Hall-effect sensor producing a voltage varying in a substantially sinusoidal pattern, the three patterns phase-shifted by about 120 degrees when the motor is in operation. 6. The motor of claim 5 , comprising twelve magnets and three linear Hall-effect sensors spaced at increments of forty degrees of mechanical rotation. 7. The motor of claim 5 , wherein intersections of adjacent sinusoidal patterns define linear portions of the patterns. 8. The motor of claim 6 , wherein the substrate is a printed circuit board (PCB) comprising circuitry enabling analog-to-digital conversion (ADC) of voltage values in the defined linear portions of the patterns, and zero-crossing detection of the analog voltage patterns in the defined linear portions of the patterns, the processor module being configured to perform ADC of voltage values in the defined linear portions and zero-crossing detection of the analog voltage patterns. 9. The motor of claim 8 , wherein the circuitry employs an 11-bit analog to digital converter (ADC), producing 2048 equally-spaced digital values for each linear portion of the patterns that represent a resolution of the system. 10. The motor of claim 8 , wherein the circuitry is implemented in a programmable system on a chip (PSOC). 11. A method for encoding a DC electric motor, comprising: mounting a stator to a substrate, the stator comprising a coil assembly having a core of magnetic material and electrical windings, the coil assembly having an outside diameter, a proximal extremity, and a distal extremity; mounting a rotor to the stator, the rotor comprising permanent magnets mounted to a cylindrical skirt, each permanent magnet extending to a distal edge, the rotor having an outside diameter, an inside diameter, wherein the distal edges of the permanent magnets extend beyond the coil assembly in a vertical direction when the rotor is oriented horizontally; positioning a plurality of sensors on the substrate adjacent the distal edges of the permanent magnets along the vertical direction when the rotor is oriented to rotate along a horizontal plane, wherein a displacement of the motor is determinable from a signal from a sensor of the plurality of sensors; operating the DC electric motor by commutation, causing the permanent magnets to pass over the plurality of sensors when the rotor is oriented horizontally, producing a plurality of intersecting sinusoidal patterns of varying voltage each pattern having a linear portion corresponding to a straight line segment between crossing points; and determining positions of the rotor from only the linear portion of the sinusoidal pattern of a respective sensor of the plurality of sensors. 12. The method of claim 11 , wherein the plurality of sensors mounted to the substrate are positioned relative the extended edge of the permanent magnets of the rotor, with a clearance from the extended edge to the plurality of sensors sufficient to provide a voltage of from about 2 to about 5 volts DC. 13. The method of claim 12 , wherein the extended edge of the permanent magnets extend beyond the distal extremity of the coil assembly by about 1 mm or more. 14. The method of claim 11 , wherein the plurality of sensors are linear Hall-effect sensors, spaced apart by a common arc length along an arcuate path of the rotor. 15. The method of claim 14 , comprising an even number of permanent magnets evenly spaced around the cylindrical skirt with adjacent magnets exhibiting opposite polarity at the distal edge of the skirt, and three Hall-effect sensors, each Hall-effect sensor producing a voltage signal varying in a substantially sinusoidal pattern, the three patterns phase-shifted by about 120 degrees. 16. The method of claim 15 , comprising twelve magnets and three linear Hall-effect sensors spaced at increments of about twenty degrees of mechanical rotation. 17. The method of claim 15 , wherein intersections of adjacent sinusoidal patterns define linear portions of the patterns. 18. The method of claim 16 , wherein the substrate is a printed circuit board (PCB) comprising circuitry enabling analog-to-digital conversion (ADC) of voltage values in the defined linear portions of the patterns, and zero-crossing detection of the analog voltage patterns. 19. The method of claim 18 , wherein the circuitry employs an 11-bit analog to digital converter, producing 2048 equally-spaced digital values for each linear portion of the patterns. 20. The method of claim 18 , wherein the circuitry is implemented in a programmable system on a chip (PSOC). 21. A motor system comprising: a stator comprising a magnetic core; a rotor that is rotatably mounted relative to the stator, the rotor having a plurality of permanent magnets distributed radially about the rotor and each extending to a distal edge that extends beyond the magnetic core in a vertical direction when the rotor is oriented horizontally; a plurality of sensors at