Aircraft wheel speed sensor

The invention claimed is: 1. A method of sensing aircraft wheel speed, the method comprising: receiving a carrier voltage signal at a stator winding via a pair of conductors coupled to the stator winding, the carrier voltage signal comprising a steady state alternating voltage signal, the stator winding disposed in a stator that defines an inner circumference about a rotor that moves within the stator upon rotation of an aircraft wheel, the stator comprising major stator teeth, minor stator teeth extending toward the rotor from the major stator teeth, and minor stator slots between adjacent pairs of the minor stator teeth, each minor stator tooth being narrower than its two neighboring minor stator slots, and the rotor comprising rotor teeth extending toward the minor stator teeth and rotor slots between adjacent pairs of the rotor teeth, each rotor tooth being narrower than its two neighboring rotor slots; rendering a modulated current signal on the pair of conductors in response to movement of the rotor, the modulated current signal comprising a variable-frequency-modulation to the carrier voltage signal and having a frequency that is dependent on a rotational speed of the aircraft wheel; detecting the modulated current signal; generating a square wave logic signal having the frequency of the modulated current signal; and providing the square wave logic signal to an aircraft control system. 2. The method of claim 1 , comprising isolating the modulated current signal from the carrier voltage signal. 3. The method of claim 1 , wherein the carrier voltage signal is a single-frequency voltage signal. 4. The method of claim 1 , wherein the frequency of the modulated current signal is temperature independent. 5. The method of claim 1 , comprising determining a speed of the aircraft wheel based on the detected modulated current signal. 6. The method of claim 1 , wherein the frequency of the carrier voltage signal is greater than the frequency of the modulated current signal. 7. The method of claim 1 , wherein the steady state alternating voltage signal has a constant amplitude. 8. An aircraft wheel speed sensor system comprising: a pair of conductors coupled between an electro-mechanical system and a control system; the control system configured to apply a carrier voltage signal comprising a steady state alternating voltage signal to the electro-mechanical system via the pair of conductors and to detect a modulated current signal from the electro-mechanical system on the pair of conductors, the modulated current signal comprising a variable-frequency-modulation to the carrier voltage signal; and the electro-mechanical system including: a rotor that moves within an inner circumference of a stator upon rotation of an aircraft wheel; and the stator that includes a winding disposed about the rotor, the winding configured to render the modulated current signal by modulating current on the pair of conductors in response to movement of the rotor, the modulated current signal having a frequency that is dependent on a rotational speed of the aircraft wheel; wherein the stator comprises major stator teeth, minor stator teeth extending toward the rotor from the major stator teeth, and minor stator slots between adjacent pairs of the minor stator teeth, each minor stator tooth being narrower than its two neighboring minor stator slots; and wherein the rotor comprises rotor teeth extending toward the minor stator teeth and rotor slots between adjacent pairs of the rotor teeth, each rotor tooth being narrower than its two neighboring rotor slots. 9. The aircraft wheel speed sensor system of claim 8 , the winding including a plurality of coils wound in series about the major stator teeth. 10. The aircraft wheel speed sensor system of claim 8 , wherein magnetic interactions between the minor stator teeth and the rotor teeth produce the modulated current signal on the winding. 11. The aircraft wheel speed sensor system of claim 8 , the rotor comprising a shaft that is mechanically coupled to the aircraft wheel. 12. The aircraft wheel speed sensor system of claim 8 , wherein the electro-mechanical system does not include permanent magnets. 13. The aircraft wheel speed sensor system of claim 8 , wherein electrical coupling between the electro-mechanical system and the control system is provided by only the pair of conductors. 14. The aircraft wheel speed system of claim 8 , wherein the frequency of the carrier voltage signal is greater than the frequency of the modulated current signal. 15. The aircraft wheel speed system of claim 8 , wherein the steady state alternating voltage signal has a constant amplitude. 16. A method of sensing aircraft wheel speed, the method comprising: receiving a carrier voltage signal at a stator winding disposed in a stator that defines an inner circumference about a rotor that moves within the stator upon rotation of an aircraft wheel, the carrier voltage signal being received from at most one pair of conductors external to the stator and comprising a steady state alternating voltage signal; rendering a modulated current signal on the at most one pair of conductors in response to movement of the rotor, the modulated current signal having a frequency that is dependent on a rotational speed of the aircraft wheel and comprising a variable-frequency-modulation to the carrier voltage signal; and isolating the modulated current signal from the carrier voltage signal. 17. The method of claim 16 , wherein the carrier voltage signal is a single-frequency voltage signal, the frequency of the carrier voltage signal being greater than the frequency of the modulated current signal. 18. The method of claim 16 , wherein the maximum voltage amplitude of the modulated current signal is constant for a range of aircraft wheel rotational speeds. 19. The method of claim 16 , wherein the frequency of the carrier voltage signal is greater than the frequency of the modulated current signal. 20. The method of claim 16 , wherein the steady state alternating voltage signal has a constant amplitude. 21. An aircraft wheel speed sensor system comprising: an electro-mechanical system electrically coupled to a control system by at most one pair of conductors, the electro-mechanical system including a stator without permanent magnets and a rotor without permanent magnets, the rotor being configured to rotate within an inner circumference of the stator, the stator configured to receive a carrier voltage signal from the control system via the at most one pair of conductors, the stator including a winding configured to render a modulated current signal on the at most one pair of conductors, wherein the modulated current signal comprises a variable-frequency-modulation to the carrier voltage signal, the modulated current signal having: a frequency that varies based on a rotational velocity of an aircraft wheel; a peak amplitude that remains constant as the rotational velocity approaches zero; and a constant maximum voltage amplitude for a range of aircraft wheel rotational speeds; and the control system configured to detect the signal on the at most one pair of conductors.