Linear hall device based field oriented control motor drive system

What is claimed is: 1. A method for controlling an electric motor, the method comprising: producing a first signal indicative of a strength of a first magnetic field component produced by a set of rotor magnets included within a rotor of the electric motor using a first linear Hall device; simultaneously producing a second signal indicative of a strength of second magnetic field component produced by the rotor magnets that is approximately orthogonal to the first magnetic field component using a second linear Hall device; calculating an angular position and angular velocity of the rotor based on the first signal and the second signal; producing a plurality of phase signals based on the calculated angular position and angular velocity; and controlling current in a plurality of field windings of the motor using the plurality of phase signals; and normalizing the first signal and the second signal prior to calculating the angular position. 2. A method for controlling an electric motor, the method comprising: producing a first signal indicative of a strength of a first magnetic field component produced by a set of rotor magnets included within a rotor of the electric motor using a first linear Hall device; simultaneously producing a second signal indicative of a strength of second magnetic field component produced by the rotor magnets that is approximately orthogonal to the first magnetic field component using a second linear Hall device; calculating an angular position and angular velocity of the rotor based on the first signal and the second signal; producing a plurality of phase signals based on the calculated angular position and angular velocity; and controlling current in a plurality of field windings of the motor using the plurality of phase signals; and removing offset from the first signal and the second signal by providing bias compensation to the first linear Hall device and to the second linear Hall device. 3. A method for controlling an electric motor, the method comprising: producing a first signal indicative of a strength of a first magnetic field component produced by a set of rotor magnets included within a rotor of the electric motor using a first linear Hall device; simultaneously producing a second signal indicative of a strength of second magnetic field component produced by the rotor magnets that is approximately orthogonal to the first magnetic field component using a second linear Hall device; calculating an angular position and angular velocity of the rotor based on the first signal and the second signal; producing a plurality of phase signals based on the calculated angular position and angular velocity; and controlling current in a plurality of field windings of the motor using the plurality of phase signals; and in which the first Hall device and the second Hall device are formed in a same integrated circuit. 4. A method for controlling an electric motor, the method comprising: producing a first signal indicative of a strength of a first magnetic field component produced by a set of rotor magnets included within a rotor of the electric motor using a first linear Hall device; simultaneously producing a second signal indicative of a strength of second magnetic field component produced by the rotor magnets that is approximately orthogonal to the first magnetic field component using a second linear Hall device; calculating an angular position and angular velocity of the rotor based on the first signal and the second signal; producing a plurality of phase signals based on the calculated angular position and angular velocity; and controlling current in a plurality of field windings of the motor using the plurality of phase signals; and in which the first magnetic field component is a radial component and the second magnetic field component is a tangential or an axial field component. 5. A motor drive system comprising: a multidimensional array of at least a first linear Hall device and a second linear Hall device; angle-speed calculation logic coupled to receive signals indicative of magnetic field strength from each of the linear Hall devices; and motor controller and drive logic coupled to receive angular speed information from the angle-speed calculation logic, with a plurality of outputs for providing a plurality of phase signals to control a motor; wherein the multidimensional array of Hall devices, the angle-speed calculation logic and the motor controller and drive logic are all formed on a single integrated circuit, (IC); wherein the first linear Hall device is formed horizontally to a substrate of the IC, and in which the second linear Hall device is formed horizontally to the substrate and perpendicular to the first linear Hall device. 6. A motor drive system comprising: a multidimensional array of at least a first linear Hall device and a second linear Hall device; angle-speed calculation logic coupled to receive signals indicative of magnetic field strength from each of the linear Hall devices; and motor controller and drive logic coupled to receive angular speed information from the angle-speed calculation logic, with a plurality of outputs for providing a plurality of phase signals to control a motor; wherein the multidimensional array of Hall devices, the angle-speed calculation logic and the motor controller and drive logic are all formed on a single integrated circuit, (IC); wherein the first linear Hall device is formed horizontally to a substrate of the IC, and in which the second linear Hall device is formed vertically to the substrate. 7. A motor drive system comprising: a multidimensional array of at least a first linear Hall device and a second linear Hall device; angle-speed calculation logic coupled to receive signals indicative of magnetic field strength from each of the linear Hall devices; and motor controller and drive logic coupled to receive angular speed information from the angle-speed calculation logic, with a plurality of outputs for providing a plurality of phase signals to control a motor; wherein the multidimensional array of Hall devices, the angle-speed calculation logic and the motor controller and drive logic are all formed on a single integrated circuit, (IC); further including a motor having a rotor and a plurality of field windings, in which the plurality of phase signals are coupled to the field windings, and in which the rotor includes a plurality of rotor magnets. 8. The system of claim 7 , in which the IC is mounted adjacent to the rotor, such that the at least two linear Hall devices are operable to sense at least two orthogonal components of a varying magnetic field strength produced by the plurality of rotor magnets. 9. A permanent magnet synchronous motor (PMSM) comprising: stator having a plurality of field windings, in which the plurality of phase signals are coupled to the field windings; rotor configured to rotate with reference to the stator, the rotor having a plurality of rotor magnets; a motor drive system positioned so as to be within a magnetic field produced by the rotor magnets, in which the motor drive system includes a first linear Hall device and a second linear Hall device positioned perpendicular to each other; wherein the motor drive system further includes: angle-speed calculation logic coupled to receive signals indicative of magnetic field strength from each of the linear Hall devices; and motor controller and drive logic coupled to receive angular speed information from the angle-speed calculation logic, with a plurality of outputs for providing a plurality of phase coupled to the field windings of the stator; wherein the first linear Hall device, the second linear Hall device, the angle-s