Acoustic airspeed sensors

What is claimed is: 1. An acoustic airspeed sensor system, comprising: at least one acoustic transmitter configured to provide an acoustic pulse; a plurality of acoustic receivers, including at least: a first acoustic receiver positioned at a first radial distance from the at least one acoustic transmitter, the first acoustic receiver configured to: receive the acoustic pulse at a first time; and output a first receiver signal; a second acoustic receiver positioned at a second radial distance from the at least one acoustic transmitter, the second acoustic receiver configured to: receive the acoustic pulse at a second time; and output a second receiver signal; and an air data module operatively connected to the first acoustic receiver and the second acoustic receiver, the air data module configured to: receive the first receiver signal and the second receiver signal; determine a first signal delay between receiving the first receiver signal and transmission of the acoustic pulse by the acoustic transmitter; determine a second signal delay between receiving the second receiver signal and transmission of the acoustic pulse by the acoustic transmitter; receive or determine a wind angle; determine true air speed (TAS) based upon the first signal delay, the second signal delay, and the wind angle; and output a TAS signal indicative of the TAS. 2. The airspeed sensor system of claim 1 , wherein the air data module includes one or more delay measurement modules operatively connected to a pulse control module and the first and/or second acoustic receiver, wherein the pulse control module is operatively connected to the transmitter and configured to cause the transmitter to send the acoustic pulse at a send time, wherein the one or more delay measurement modules are configured to compare the send time and the first time to determine the first signal delay and output first delay data indicative thereof, wherein the one or more delay measurement modules are configured to compare the send time to the second time to determine the second signal delay and output second delay data. 3. The airspeed sensor system of claim 2 , wherein the air data module includes a wind angle module operatively connected to the one or more delay measurement modules to receive the first delay data and the second delay data and configured to determine the wind angle based thereon, and to output wind angle data. 4. The airspeed sensor system of claim 3 , wherein air data module includes a curve fit module configured to curve fit the first delay data and the second delay data and to output curve fit data to the wind angle module. 5. The airspeed sensor system of claim 3 , wherein the air data module includes an airspeed module operatively connected to the wind angle module to receive wind angle data therefrom, wherein the airspeed module is operatively connected to the one or more delay measurement modules to receive the first delay data and the second delay data, wherein the airspeed module is configured to determine TAS based on the wind angle, the first delay data, and the second delay data, and to output the TAS signal. 6. The airspeed sensor system of claim 5 , wherein the air data module includes a speed of sound (SOS) module operatively connected to the airspeed module to receive the TAS signal, wherein the SOS module is operatively connected to the one or more delay measurement modules to receive the first delay data and the second delay data, wherein the SOS module is operatively connected to the one or more delay measurement modules to receive the first delay data and the second delay data, wherein the SOS module is operatively connected to the wind angle module to receive wind angle data, wherein the SOS module is configured to determine a SOS based on the TAS signal, the first and second delay data, and to output SOS data. 7. The airspeed sensor system of claim 6 , wherein the SOS module is configured to determine Mach number from the SOS and to output a Mach number signal. 8. The airspeed sensor system of claim 6 , wherein the air data module includes a static air temperature module operatively connected to the SOS module to receive the SOS data to determine a static air temperature (SAT) based on the SOS, and to output a SAT signal. 9. The airspeed sensor system of claim 2 , wherein the air data module includes a multiplexer (MUX) between the one or more delay measurement modules and at least one other module of the air data module, the MUX configured to receive the first delay data and the second delay data from the one or more delay measurement modules and to multiplex the data. 10. The airspeed sensor system of claim 1 , wherein the first radial distance and the second radial distance are the same. 11. The airspeed sensor system of claim 1 , wherein the first and second acoustic receivers comprise microelectro-mechanical systems (MEMS) microphones. 12. The airspeed sensor system of claim 1 , wherein the air data module is configured to determine if an acoustic receiver is shadowed by setting a maximum time for response, and to ignore any signals from the shadowed acoustic receivers. 13. A computer implemented method, comprising: emitting an acoustic pulse using at least one acoustic transmitter; receiving, at a first time, the acoustic pulse using a first acoustic receiver positioned at a radial distance from the at least one acoustic transmitter; providing a first receiver signal from the first acoustic receiver in response to receiving the acoustic pulse; receiving, at a second time, the acoustic pulse using a second acoustic receiver positioned at the radial distance from the at least one acoustic transmitter and aligned with an axis that extends through each of the at least one acoustic transmitter and the first acoustic receiver; determining a first signal delay between the first acoustic receiver and the acoustic transmitter; determining a second signal delay between the second acoustic receiver and the acoustic transmitter; determining a true airspeed (TAS) based upon the first signal delay, the second signal delay, and a wind angle; and outputting a TAS signal to an aircraft system. 14. The method of claim 13 , further comprising determining the wind angle based on the first signal delay and the second signal delay. 15. The method of claim 13 , further comprising determining a speed of sound (SOS) based on the wind angle, the TAS, the first signal delay, and the second signal delay. 16. The method of claim 15 , further comprising determining a Mach number based on the SOS and outputting the Mach number to an aircraft system. 17. The method of claim 15 , further comprising determining a static air temperature (SAT) based on the SOS and outputting the static air temperature to an aircraft system.