Power management between a propulsor and a coaxial rotor of a helicopter

What is claimed is: 1. A flight control system for a rotary wing aircraft comprising a main rotor system, a translational thrust system, and an engine control system, the flight control system comprising: a flight control computer configured to interface with the main rotor system, the translational thrust system, and the engine control system, the flight control computer comprising processing circuitry configured to execute control logic comprising: a primary flight control configured to produce flight control commands for the main rotor system and the translational thrust system; a main rotor engine anticipation logic configured to produce a rotor power demand associated with the main rotor system; and a propulsor loads engine anticipation logic configured to produce an auxiliary propulsor power demand associated with the translational thrust system, the auxiliary propulsor power demand anticipating a power demand for the engine control system in combination with the rotor power demand, wherein the propulsor loads engine anticipation logic further comprises: a shaped propeller power demand model configured to produce a propulsor power demand value based on aircraft state data, and the auxiliary propulsor power demand is based on the propulsor power demand value, wherein the translational thrust system comprises an auxiliary propulsor including a plurality of propeller blades, and wherein the aircraft state data comprises: a propeller pitch command for the propeller blades and a reference rotational rate of the auxiliary propulsor. 2. The flight control system according to claim 1 , wherein the propeller pitch command and the reference rotational rate of the auxiliary propulsor are modeled parameters, and the aircraft state data further comprises: an airspeed of the rotary wing aircraft and a density of air as sensor-based data. 3. The flight control system according to claim 1 , wherein the aircraft state data further comprises a propeller clutch engagement state of a propeller clutch and a propeller speed. 4. The flight control system according to claim 1 , wherein the propulsor loads engine anticipation logic further comprises: a filter configured to filter the propulsor power demand value to produce a filtered power demand value; and a drivetrain loss adjustment gain applied to the filtered power demand value to produce the auxiliary propulsor power demand. 5. The flight control system according to claim 1 , wherein the main rotor system further comprises dual contra-rotating main rotors, and the translational thrust system comprises an auxiliary propulsor configured as a pusher propeller or a puller propeller. 6. A method of providing engine anticipation for propulsor loads on a rotary wing aircraft comprising a main rotor system, a translational thrust system, and an engine control system, the method comprising: producing flight control commands, by a flight control computer of the rotary wing aircraft, for the main rotor system and the translational thrust system; producing a rotor power demand associated with applying the flight control commands to the main rotor system; producing an auxiliary propulsor power demand associated with applying the flight control commands to the translational thrust system; producing a propulsor power demand value using a shaped propeller power demand model based on aircraft state data, wherein the auxiliary propulsor power demand is based on the propulsor power demand value; and providing the engine control system with a total power demand anticipation signal based on a combination of the rotor power demand and the auxiliary propulsor power demand, wherein the translational thrust system comprises an auxiliary propulsor including a plurality of propeller blades, and wherein the aircraft state data comprises: a propeller pitch command for the propeller blades and a reference rotational rate of the auxiliary propulsor. 7. The method according to claim 6 , wherein the propeller pitch command and the reference rotational rate of the auxiliary propulsor are modeled parameters, and the aircraft state data comprises: an airspeed of the rotary wing aircraft and a density of air as sensor-based data. 8. The method according to claim 6 , further comprising: filtering the propulsor power demand value to produce a filtered power demand value; and applying a drivetrain loss adjustment gain to the filtered power demand value to produce the auxiliary propulsor power demand. 9. The method of claim 6 , wherein the main rotor system further comprises dual contra-rotating main rotors, and the translational thrust system comprises an auxiliary propulsor configured as a pusher propeller or a puller propeller.