Charged air mass measurement for air data computation

The invention claimed is: 1. A method for air data computation using ionic charge sensing during flight of an aircraft, comprising: generating a first voltage difference between an emitter electrode and a first collector electrode coupled to an outer surface of the aircraft and exposed to ambient air, the first collector electrode being aft of the emitter electrode, wherein a voltage supplied to the emitter electrode is high enough to ionize air molecules in a region surrounding the emitter electrode and the first voltage difference is large enough and the first collector electrode is sufficiently close to the emitter electrode to cause a first current to be produced in the first collector electrode; generating a second voltage difference between the emitter electrode and a second collector electrode coupled to the outer surface of the aircraft and exposed to ambient air, the second collector electrode being aft of the emitter electrode, wherein the second voltage difference is large enough and the second collector electrode is sufficiently close to the emitter electrode to cause a second current to be produced in the second collector electrode; determining a first magnitude of the first current and a second magnitude of the second current; and computing an air data parameter value based on a static sensor parameter and a particular difference between the first magnitude and the second magnitude. 2. The method of claim 1 , further comprising computing a sideslip based on the first magnitude and the second magnitude. 3. The method of claim 1 , further comprising computing an estimated airspeed which is a function of a velocity of the aircraft and the particular difference. 4. The method of claim 1 , wherein the air data parameter value comprises an estimated pressure altitude, and wherein the static sensor parameter comprises a static pressure outside the aircraft. 5. The method of claim 1 , wherein the air data parameter value comprises an estimated total air temperature, and wherein the static sensor parameter comprises a static temperature outside the aircraft. 6. The method of claim 2 , further comprising annunciating an air data parameter value in a manner that is perceptible to an operator seated in a cockpit or on a flight deck of the aircraft, wherein the air data parameter value is based in part on the particular difference. 7. The method of claim 6 , wherein annunciating comprises displaying symbology representing the air data parameter value on a cockpit display unit. 8. The method of claim 1 , further comprising determining a particular ratio of the first magnitude and the second magnitude. 9. The method of claim 8 , further comprising computing an estimated angle of attack based on the particular ratio. 10. An aircraft comprising: an exterior skin; a power supply; an emitter electrode connected to the power supply and disposed at a first position coupled to the exterior skin and exposed to ambient air; a first collector electrode connected to ground and disposed at a second position coupled to the exterior skin and exposed to ambient air, the second position being aft of the first position; a second collector electrode connected to ground disposed at a third position coupled to the exterior skin and exposed to ambient air, the third position being aft of the first position; a first current sensor having an input connected to the first collector electrode and having an output, the first current sensor configured to determine a first magnitude of a first current; a second current sensor having an input connected to the second collector electrode and having an output, the second current sensor configured to determine a second magnitude of a second current; and a processor configured to compute an air data parameter value based on a static sensor parameter and a difference between the first magnitude and the second magnitude, wherein the emitter electrode, the first collector electrode, and the second collector electrode are configured and arranged so that respective currents are induced in the first and second collector electrodes by ionic wind flowing from the emitter electrode toward the first and second collector electrodes while power is being supplied to the emitter electrode during flight of the aircraft. 11. The aircraft of claim 10 , further comprising a non-transitory tangible computer-readable storage medium storing a calibration table which correlates relationships between respective magnitudes of first and second currents and air data parameter values recorded during testing. 12. The aircraft of claim 10 , further comprising a microcontroller configured to compute the difference between the first magnitude and the second magnitude. 13. The aircraft of claim 11 , wherein the processor is an air data processor of an air data and inertial reference unit (ADIRU). 14. The aircraft of claim 13 , wherein the ADIRU is configured to compute an estimated airspeed based on a velocity of the aircraft and the difference between the first magnitude and the second magnitude. 15. The aircraft of claim 13 , wherein the ADIRU is configured to compute an estimated pressure altitude which is a function of static pressure outside the aircraft and the difference between the first magnitude and the second magnitude. 16. The aircraft of claim 13 , wherein the ADIRU is configured to compute an estimated total air temperature which is a function of static air temperature outside the aircraft and the difference between the first magnitude and the second magnitude. 17. The aircraft of claim 10 , further comprising a microcontroller that is configured to compute a ratio of the first magnitude and the second magnitude. 18. The aircraft of claim 17 , wherein processor is further configured to compute an estimated angle of attack based on the ratio of the first magnitude and the second magnitude. 19. A method for air data computation using ionic charge sensing during flight of an aircraft, comprising: generating a first voltage difference between an emitter electrode and a first collector electrode coupled to an outer surface of the aircraft and exposed to ambient air, the first collector electrode being aft of the emitter electrode, wherein a voltage supplied to the emitter electrode is high enough to cause corona discharge in a region surrounding the emitter electrode and the first voltage difference is large enough and the first collector electrode is sufficiently close to the emitter electrode to cause a first current to be produced in the first collector electrode by the corona discharge; generating a second voltage difference between the emitter electrode and a second collector electrode coupled to the outer surface of the aircraft and exposed to ambient air, the second collector electrode being aft of the emitter electrode, wherein the second voltage difference is large enough and the second collector electrode is sufficiently close to the emitter electrode to cause a second current to be produced in the second collector electrode by the corona discharge; determining a first magnitude of the first current and a second magnitude of the second current; and computing an air data parameter value based on a static sensor parameter and a difference between the first magnitude and the second magnitude. 20. The method of claim 19 , wherein: the outer surface has an aerodynamic surface and first, second, and third cavities which are open to an ambient atmosphere, the first cavity being disposed at a position which is forwa