Lift offset management and control systems for coaxial rotorcraft

What is claimed is: 1. A lift offset management system, comprising: first and second rotors disposed to oppositely rotate about a same rotational axis; sensors disposed to generate hub moment, tip clearance and lift offset data of the first and second rotors; an input unit configured to generate a target lift offset reference command based on flight data, the hub moment data and the tip clearance data; and a feedback system configured to generate a correction command based on the lift offset data and comprising: a summation unit at which the target lift offset reference and correction commands are combined into an actual lift offset command; and a servo control unit disposed to control blade pitching of the first and second rotors based on the actual lift offset command. 2. The lift offset management system according to claim 1 , further comprising a storage unit on which the flight data is stored. 3. The lift offset management system according to claim 1 , wherein the first and second rotors are disposed at a top portion of a rotorcraft airframe comprising a tail portion with an auxiliary propulsor. 4. The lift offset management system according to claim 1 , wherein the flight data comprises data reflective of rotorcraft airspeed and altitude, air density of air surrounding the rotorcraft and a rotorcraft weight. 5. The lift offset management system according to claim 1 , wherein the sensors are disposed on at least one of each of the first and second rotors and a non-rotating frame. 6. The lift offset management system according to claim 1 , wherein the lift offset data comprises lateral lift offset data and longitudinal lift offset data. 7. The lift offset management system according to claim 1 , wherein the lift management system is incorporated into a rotorcraft, comprising: an airframe having an upper portion and a tail portion; main rotor and auxiliary propulsor assemblies respectively disposed at the upper and tail portions, the main rotor assembly including first and second rotors disposed to oppositely rotate relative to the airframe about a same rotational axis; and sensors disposed to generate hub moment, tip clearance and lift offset of the main rotor assembly. 8. A control system, comprising: first and second rotors disposed to oppositely rotate about a same rotational axis; sensors disposed to generate hub moment, tip clearance, pitch rate and attitude data of the first and second rotors from which hub moment command, tip clearance command and pitch rate and attitude command data are respectively derivable; a command unit receptive of pilot inputted commands and from which a pilot inputted command signal is accordingly output; and a mixer receptive of the tip clearance command data, the hub moment command data and elevator command data, which is reflective of the pitch rate and attitude command data and the pilot inputted command signal, the mixer being configured to exclusively couple the tip clearance command data, the hub moment command data and the elevator command data with a rotorcraft controlling tip clearance command, a hub moment command and an elevator command, respectively. 9. The control system according to claim 8 , wherein the command unit comprises an inverse plan model unit configured to cancel out errors associated with an inherent aircraft response. 10. The control system according to claim 8 , wherein the first and second rotors are disposed at a top portion of a rotorcraft airframe comprising a tail portion with an auxiliary propulsor. 11. The control system according to claim 8 , wherein the mixer is configured to decouple the tip clearance command data from the hub moment and elevator commands, the hub moment command data from the tip clearance and elevator commands and the elevator command data from the tip clearance and hub moment commands. 12. The control system according to claim 8 , wherein the sensors are disposed on at least one of each of the first and second rotors and a non-rotating frame. 13. The control system according to claim 8 , wherein the control system is incorporated into a rotorcraft, comprising: an airframe having an upper portion and a tail portion; main rotor and auxiliary propulsor assemblies respectively disposed at the upper and tail portions, the main rotor assembly including first and second rotors disposed to oppositely rotate relative to the airframe about a same rotational axis; and sensors disposed to generate hub moment, tip clearance and lift offset data of the main rotor assembly. 14. The lift offset management system according to claim 1 , wherein the lift management system is incorporated into a rotorcraft, comprising: an airframe having an upper portion and a tail portion; main rotor and auxiliary propulsor assemblies respectively disposed at the upper and tail portions, the main rotor assembly including first and second rotors disposed to oppositely rotate relative to the airframe about a same rotational axis; sensors disposed to generate hub moment, tip clearance, lift offset data and attitude data of the first and second rotors from which hub moment command, tip clearance command and pitch rate and attitude command data are respectively derivable; a command unit receptive of pilot inputted commands and from which a pilot inputted command signal is accordingly output; and a mixer receptive of the tip clearance command data, the hub moment command data and elevator command data, which is reflective of the pitch rate and attitude command data and the pilot inputted command signal, the mixer being configured to exclusively couple the tip clearance command data, the hub moment command data and the elevator command data with a rotorcraft controlling tip clearance command, a hub moment command and an elevator command, respectively. 15. The rotorcraft according to claim 14 , wherein the lift offset management system is operable during non-maneuvering flight regime portions and a control system comprising the command unit and the mixer is operable during maneuvering flight regime portions.