Extended stroke position sensor

What is claimed is: 1. A position sensing system comprising: an extended stroke position sensor comprising: a waveguide having a given characteristic impedance; and a cylinder of magnetic material positioned in close proximity to the waveguide, the cylinder of magnetic material comprising soft or semi-soft magnetic material, wherein the waveguide comprises a copper core and a conductive wire wound along a longitudinal axis of the core in a spiral, the core and the spiral wound conductive wire being receivable within the cylinder of magnetic material; a signal generator communicatively coupled to the waveguide and a signal receiver, the signal generator configured to generate a first signal and communicate the first signal to the waveguide and the signal receiver; one or more impedance matching devices electrically coupled to the waveguide and configured such that the waveguide is impedance matched with the signal generator and the signal receiver; a magnet movable relative to the extended stroke position sensor, the magnet configured to generate a magnetic field sufficient to locally saturate the magnetic material, wherein the magnetic material is configured to cause an impedance discontinuity in the waveguide such that the first signal is reflected at the point of the impedance discontinuity and communicated to the signal receiver; and a position sensor circuit communicatively coupled to the signal receiver, the position sensor circuit configured to determine the position of the magnet relative to the extended stroke position sensor based in part on the first signal and the reflected signal as received by the signal receiver; wherein the cylinder of magnetic material encases the waveguide. 2. The system according to claim 1 , wherein the magnet comprises either a permanent magnet or an electro-magnet. 3. The system according to claim 1 , wherein the waveguide is one of a microstrip waveguide, a stripline waveguide, or a rectangular waveguide. 4. The system according to claim 1 , the extended stroke position sensor further comprising a first conductive layer disposed on the waveguide, the first conductive layer electrically coupled to the signal generator and the signal receiver. 5. The system according to claim 4 , the extended stroke position sensor further comprising a second conductive layer disposed between the waveguide and the magnetic material, the second conductive layer configured to shield the waveguide from electrical interference. 6. The system according to claim 5 , wherein the second conductive layer is grounded. 7. The system according to claim 1 , wherein a first end of the conductive wire is electrically coupled to the signal generator and a second end of the conductive wire is electrically coupled to the signal receiver. 8. The system according to claim 1 , wherein the signal generator is configured to repeatedly generate a series of pulses. 9. An extended stroke position sensor comprising: a waveguide having a given characteristic impedance, the waveguide configured to receive a first signal; and a cylinder of magnetic material positioned in close proximity to the waveguide, the cylinder of magnetic material comprising soft or semi-soft magnetic material, wherein the magnetic material is configured to cause an impedance discontinuity in the waveguide when the magnetic material is saturated by a local magnetic field, the impedance discontinuity configured such that the first signal is reflected at the point of the impedance discontinuity, wherein the waveguide comprises a copper core and a conductive wire wound along a longitudinal axis of the core in a spiral, the core and the spiral wound conductive wire being receivable within the cylinder of magnetic material; wherein the cylinder of magnetic material encases the waveguide. 10. The sensor according to claim 9 , wherein the waveguide is one of a microstrip waveguide, a stripline waveguide, or a rectangular waveguide. 11. The sensor according to claim 9 , further comprising a first conductive layer disposed on the waveguide, the first conductive layer electrically coupled to the signal generator and the signal receiver. 12. The sensor according to claim 11 , further comprising a second conductive layer disposed between the waveguide and the magnetic material, the second conductive layer configured to shield the waveguide from electrical interference. 13. The sensor according to claim 12 , wherein the second conductive layer is grounded. 14. A method of determining a position of a moveable object comprising: generating a first signal by a signal generator; communicating the first signal to a waveguide of an extended stroke position sensor, the extended stroke position sensor comprising the waveguide and a cylinder of magnetic material positioned in close proximity to the waveguide, the cylinder of magnetic material comprising soft or semi-soft magnetic material, wherein the waveguide comprises a copper core and a conductive wire wound along a longitudinal axis of the core in a spiral, the core and the spiral wound conductive wire being receivable within the cylinder of magnetic material; moving a magnet into close proximity to the extended stroke position sensor, the magnet configured to generate a magnetic field sufficient to locally saturate the magnetic material, wherein the magnetic material configures to cause an impedance discontinuity in the waveguide such that the first signal is reflected at the point of the impedance discontinuity; communicating the reflected signal to a signal receiver; and determining the position of the moveable object based on the received first signal and the received reflected signal; wherein the cylinder of magnetic material encases the waveguide. 15. The method according to claim 14 , wherein determining the position of the moveable object comprises: measuring the time delay between the generation of the first signal and the receipt of the reflected signal; and correlating the time delay with the position of the moveable object. 16. The method according to claim 14 , wherein determining the position of the moveable object comprises: measuring the phase difference between the first signal and the reflected signal; and correlating the phase difference with the position of the moveable object.