Pitot system for early ejection mode detection

What is claimed is: 1. An ejection seat, comprising: a seatback; a headrest located at an upper end of the seatback; a pitot tube rotatably coupled to the headrest; and a main parachute assembly located at an upper end of the seatback, wherein an axis of rotation of the pitot tube is located between an upper surface of the main parachute assembly and an upper end of the headrest and wherein in the stowed position, an air inlet of the pitot tube is located between the upper surface of the main parachute assembly and the upper end of the headrest. 2. The ejection seat of claim 1 , further comprising a pitot restraint assembly operably coupled to the pitot tube, the pitot restraint assembly being configured to translate between a restrained state and a released state, wherein the pitot tube is configured to rotate from a stowed position to a deployed position in response to the pitot restraint assembly translating to the released state. 3. The ejection seat of claim 2 , wherein the pitot restraint assembly includes a biased member configured to generate an interference with a rail located along a first side of the ejection seat, the interference between the rail and the biased member being configured to maintain the pitot restraint assembly in the restrained state, and wherein the pitot restraint assembly is configured to translate to the released state in response to removal of the interference between the rail and the biased member. 4. The ejection seat of claim 2 , further comprising a seat bucket configured to translate relative to the axis of rotation of the pitot tube. 5. The ejection seat of claim 1 , further comprising a high energy catapult configured to expel the ejection seat from an aircraft, the high energy catapult including: an outer tube coupled to the seatback; an inner tube located within the outer tube, wherein the outer tube is configured to telescope relative to the inner tube; a base coupled to the inner tube; a propellant located in the inner tube; and a rocket mortar configured to ignite in response to the outer tube translating a threshold distance from the base. 6. The ejection seat of claim 5 , wherein the pitot tube is configured to rotate to the deployed position prior ignition of the rocket mortar. 7. The ejection seat of claim 5 , wherein the pitot tube is coupled to the headrest such that an air inlet of the pitot tube will be located in an airstream outside a cockpit of the aircraft prior to a lower edge of the outer tube translating past upper edge of the inner tube. 8. An ejection seat, comprising a seatback; a headrest located at an upper end of the headrest; a pitot tube coupled to the headrest and configured to rotate between a stowed position and a deployed position; a high energy catapult assembly configured to expel the ejection seat from an aircraft, the high energy catapult assembly including: a base; an inner tube coupled to the base; an outer tube coupled to the seatback and configured to telescope relative to the inner tube; a propellant located in the inner tube; and a rocket mortar configured to ignite in response to the outer tube translating a threshold distance from the base; and a main parachute assembly located at an upper end of the seatback, wherein an axis of rotation of the pitot tube is located between an upper surface of the main parachute assembly and an upper end of the headrest and wherein in the stowed position, an air inlet of the pitot tube is located between the upper surface of the main parachute assembly and the upper end of the headrest. 9. The ejection seat of claim 8 , wherein the pitot tube is configured to rotate to the deployed position prior ignition of the rocket mortar. 10. The ejection seat of claim 8 , wherein the pitot tube is coupled to the headrest such that an air inlet of the pitot tube will be located in an airstream outside a cockpit of the aircraft prior to a lower edge of the outer tube translating past upper edge of the inner tube. 11. The ejection seat of claim 8 , further comprising a seat bucket, wherein a distance between a seat of the seat bucket and the axis of rotation of the pitot tube is configured to change in response to translation of the seat. 12. The ejection seat of claim 8 , further comprising a pitot restraint assembly operably coupled to the pitot tube, the pitot restraint assembly being configured to translate between a restrained state and a released state, wherein the pitot tube is configured to rotate from the stowed position to the deployed position in response to the pitot restraint assembly translating to the released state. 13. The ejection seat of claim 12 , wherein the pitot restraint assembly includes a biased member, the biased member being configured to contact a rail located along a first side of the ejection seat. 14. An ejection seat, comprising a seatback; a main parachute assembly located at an upper end of the seatback; a passive head and neck protection system including a headrest located at the upper end of the seatback and forward the main parachute assembly; and a pitot tube coupled to the headrest and configured to rotate between a stowed position and a deployed position, wherein an axis of rotation of the pitot tube is located between an upper surface of the main parachute assembly and an upper end of the headrest and wherein, in the stowed position, an air inlet of the pitot tube is located between the upper surface of the main parachute assembly and the upper end of the headrest. 15. The ejection seat of claim 14 , further comprising a pitot restraint assembly operably coupled to the pitot tube, the pitot restraint assembly being configured to translate between a restrained state and a released state, wherein the pitot tube is configured to rotate from the stowed position to the deployed position in response to the pitot restraint assembly translating to the released state.