Variable energy management methods and systems

What is claimed is: 1. A method of assisting operation of an aircraft en route to an airport, the method comprising: identifying a current altitude for the aircraft; identifying a current configuration of the aircraft; in response to a deviation between the current altitude for the aircraft and a target altitude according to a reference descent strategy: identifying a variable deceleration rate management strategy for determining a recommended flight path comprising a sequence of segments for recapturing the reference descent strategy and satisfying an upcoming constraint associated with the reference descent strategy from the current altitude based at least in part on the current configuration and the deviation; and incrementally generating the sequence of segments configured to recapture the reference descent strategy forward from a current location of the aircraft using the variable deceleration rate management strategy by: determining a maximum deceleration rate for a respective segment of the sequence of segments based at least in part on an aircraft drag configuration at the start of the respective segment and a respective deviation from the reference descent strategy at the start of the respective segment; and determining a respective combination of a vertical profile and a speed profile for the respective segment configured to reduce the respective deviation from the reference descent strategy and achieve the maximum deceleration rate, wherein: the respective combination of the vertical profile and the speed profile for the respective segment is configured to achieve the maximum deceleration rate for the respective segment; and the aircraft is autonomously operated in accordance with the respective combination of the vertical profile and the speed profile for the respective segment. 2. The method of claim 1 , wherein the vertical profile is configured to vary a flight path angle along the sequence of segments. 3. The method of claim 1 , wherein a slope of the speed profile varies along the sequence of segments. 4. The method of claim 1 , wherein the vertical profile and the speed profile are cooperatively configured to vary at least one of kinetic energy or potential energy of the aircraft along the recommended flight path en route to the upcoming constraint by varying at least one of a vertical speed of the aircraft, a deceleration rate of the aircraft, and a ratio of the potential energy to the kinetic energy of the aircraft along the recommended flight path. 5. The method of claim 1 , further comprising displaying a graphical representation of at least one of the vertical profile and the speed profile with respect to a graphical representation of the reference descent strategy. 6. The method of claim 1 , further comprising providing, by a flight management system (FMS), the vertical profile and the speed profile to a flight control system (FCS), wherein the FCS autonomously operates the aircraft in accordance with the vertical profile and the speed profile. 7. An aircraft system comprising: a navigation system to provide a current altitude of an aircraft; a data storage element to maintain one or more constraints defining a flight plan for the aircraft; and a flight management system coupled to the navigation system and the data storage element to determine a reference trajectory based at least in part on the one or more constraints, identify a variable deceleration rate energy management strategy for reducing a difference between the current altitude and a target altitude according to the reference trajectory based on the difference, generate a recommended flight path for recapturing the reference trajectory using the variable deceleration rate energy management strategy, and autonomously operate the aircraft in accordance with the recommended flight path, wherein: the recommended flight path comprises a sequence of segments for recapturing the reference trajectory and satisfying an upcoming constraint associated with the reference trajectory from the current altitude based at least in part on a current configuration of the aircraft and the difference; each segment of the sequence of segments has a respective vertical profile and a respective speed profile associated therewith configured to reduce a respective deviation from the reference trajectory and achieve a maximum deceleration rate determined for the respective segment of the sequence of segments based at least in part on an aircraft drag configuration at the start of the respective segment and the respective deviation from the reference trajectory at the start of the respective segment; and the aircraft is autonomously operated in accordance with the respective combination of the vertical profile and the speed profile for the respective segment. 8. The system of claim 7 , wherein the vertical profile is configured to vary a flight path angle along the sequence of segments. 9. The system of claim 7 , wherein a slope of the speed profile varies along the sequence of segments. 10. The system of claim 7 , wherein the vertical profile and the speed profile are cooperatively configured to vary at least one of kinetic energy or potential energy of the aircraft along the recommended flight path en route to the upcoming constraint by varying at least one of a vertical speed of the aircraft, a deceleration rate of the aircraft, and a ratio of the potential energy to the kinetic energy of the aircraft along the recommended flight path. 11. The system of claim 7 , wherein the flight management system is configured to display a graphical representation of at least one of the vertical profile and the speed profile with respect to a graphical representation of the reference descent strategy on a display device. 12. The system of claim 7 , wherein the flight management system is configured to provide the vertical profile and the speed profile to a flight control system (FCS), wherein the FCS autonomously operates the aircraft in accordance with the vertical profile and the speed profile. 13. A non-transitory computer-readable medium having computer-executable instructions stored thereon that, when executed by a processing system, are configurable to cause the processing system to: identify a current altitude for an aircraft; identify a current configuration of the aircraft; in response to a deviation between the current altitude for the aircraft and a target altitude according to a reference descent strategy: identify a variable deceleration rate management strategy for determining a recommended flight path comprising a sequence of segments for recapturing the reference descent strategy and satisfying an upcoming constraint associated with the reference descent strategy from the current altitude based at least in part on the current configuration and the deviation; and incrementally generating the sequence of segments configured to recapture the reference descent strategy forward from a current location of the aircraft using the variable deceleration rate management strategy by: determining a maximum deceleration rate for a respective segment of the sequence of segments based at least in part on an aircraft drag configuration at the start of the respective segment and a respective deviation from the reference descent strategy at the start of the respective segment; and determining a respective combination of a vertical profile and a speed profile for the respective segment configured to reduce the respective deviation from the reference descent strategy and achieve the maximum deceleration rate, wherein: the respective combination of the vertical profile and the speed profile for the resp