Tri-rotor aircraft capable of vertical takeoff and landing and transitioning to forward flight

What is claimed is: 1. A tri-rotor vehicle, comprising: a wing having no rotors coupled thereto; a tail comprising two horizontal tail sections; a fuselage; two tail rotors coupled to the tail, wherein the two horizontal tail sections extend horizontally relative to the fuselage and from opposite sides of the fuselage, wherein each of the two tail rotors has a single corresponding respective horizontal tail section, and wherein each of the two tail rotors is coupled only to its own respective one of the two horizontal tail sections and is configured to tilt through a range of motion; and a front rotor coupled to the fuselage, wherein the front rotor is configured to tilt through a range of motion and the vehicle is configured to transition between a wing born flight phase and a VTOL flight phase by the front rotor tilting through the range of motion, and wherein during the wing born flight phase the front rotor is tilted up and is deactivated while the two tail rotors are activated and tilted forward. 2. The tri-rotor vehicle of claim 1 , wherein the front rotor is coupled to a front hinged portion of the fuselage controlled by an actuator to tilt through the range of motion. 3. The tri-rotor vehicle of claim 1 , wherein the two tail rotors are coupled to the tail such that rotor axes of each of the two tail rotors are configured to orient vertically relative to the fuselage during the VTOL flight phase. 4. The tri-rotor vehicle of claim 3 , wherein the front rotor and two tail rotors are not pitch controlled rotors. 5. The tri-rotor vehicle of claim 4 , wherein the two tail rotors are coupled to the tail at a canted angle. 6. The tri-rotor vehicle of claim 3 , wherein the tail is a v-tail. 7. The tri-rotor vehicle of claim 3 , wherein the wing is swept. 8. The tri-rotor vehicle of claim 3 , wherein the vehicle is an unmanned aerial vehicle. 9. The tri-rotor vehicle of claim 3 , further comprising retractable landing skids, wherein the tail is configured to act as a rear landing skid. 10. The tri-rotor vehicle of claim 1 , wherein the two tail rotors are Samara VTOL rotors. 11. The tri-rotor vehicle of claim 1 , wherein the front rotor and two tail rotors are cyclic and collective controlled rotors. 12. The tri-rotor vehicle of claim 11 , further comprising a front rotor motor configured to directly drive the front rotor and two tail rotor motors, each tail rotor motor configured to drive a respective one of the tail rotors, wherein the front rotor motor is a fuel burning engine and each of the two tail rotor motors is selected from the group consisting of a fuel burning engine and an electric motor. 13. The tri-rotor vehicle of claim 1 , wherein the two tail rotors are coupled to the tail such that the two tail rotors are configured to tilt forward, aft, starboard, and port. 14. A tri-rotor vehicle, comprising: a wing having no rotors coupled thereto; a tail comprising two horizontal tail sections; a fuselage; two tail rotors coupled to the tail, wherein the two horizontal tail sections extend horizontally relative to the fuselage and from opposite sides of the fuselage and wherein each of the two tail rotors is coupled to its own respective one of the two horizontal tail sections; and a front rotor coupled to the fuselage, wherein the front rotor is configured to tilt through a range of motion; and wherein the two tail rotors are configured to be stowed in pods on the tail during a wing born flight phase and are held in place by one or more magnets such that a long axis of each of the two tail rotors is aligned with airflow over the vehicle. 15. A tri-rotor vehicle, comprising: a wing having no rotors coupled thereto; a tail comprising two horizontal tail sections; a fuselage; two tail rotors coupled to the tail, wherein the two horizontal tail sections extend horizontally relative to the fuselage and from opposite sides of the fuselage, wherein each of the two tail rotors has a single corresponding respective horizontal tail section, and wherein each of the two tail rotors is coupled only to its own respective one of the two horizontal tail sections; and a front rotor coupled to a front hinged portion of the fuselage controlled by an actuator, wherein the front rotor is configured to tilt through a range of motion by control of the actuator and wherein the vehicle is configured to transition between a wing born flight phase and a VTOL flight phase by the front rotor tilting through the range of motion; and a front rotor motor configured to drive the front rotor and two tail rotor motors, each tail rotor motor configured to drive a respective one of the tail rotors, wherein the front rotor motor is selected from the group consisting of a fuel burning engine and an electric motor and each of the two tail rotor motors is selected from the group consisting of a fuel burning engine and an electric motor, wherein: the two tail rotors are coupled to the tail such that rotor axes of each of the two tail rotors are activated and configured to orient horizontally relative to the fuselage during the wing born flight phase; the front rotor is deactivated and configured to orient vertically relative to the fuselage during the wing born flight phase; and the front rotor and two tail rotors are cyclic and collective controlled rotors.