Acoustic noise suppressing ducted fan propulsor mounting arrangement and treatments

The invention claimed is: 1. An acoustic noise suppressing mounting arrangement for a ducted fan assembly comprising: an outer duct through which air is entrained on one end and ejected on the other; a central shaft assembly comprising: at least one rotating member, wherein the at least one rotating member comprises at least one of a fan, a propeller, an impeller, and a rotor; and a shaft power source configured to provide shaft power to the at least one rotating member, wherein the shaft power source comprises an external drive shaft, an electric engine, an internal combustion engine, or a turbine engine; and one or more bearing assemblies configured to rotatably secure the at least one rotating member within the outer duct and to transfer thrust loads between the outer duct and the central shaft assembly; and a plurality of structural spokes coupled to the central shaft assembly and configured to transfer loads between the outer duct and at least a portion of the central shaft assembly, wherein each structural spoke of the plurality of structural spokes is pretensioned and has a high aspect ratio, and wherein the plurality of structural spokes comprise aft-swept structural spokes and forward-swept structural spokes. 2. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising a plurality of fixtures, each fixture of the plurality of fixtures corresponding to one structural spoke of the plurality of structural spokes and configured to couple a first end of the corresponding structural spoke to the central shaft assembly. 3. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising a plurality of structural spoke mounting assemblies, each structural spoke mounting assembly of the plurality of structural spoke mounting assemblies corresponding to one structural spoke of the plurality of structural spokes and configured to couple a second end of the corresponding structural spoke to the outer duct, wherein each the plurality of structural spoke mounting assemblies is configured to tighten the corresponding structural spoke and to minimize transfer of axial spoke vibrations to a wall of the outer duct. 4. The acoustic noise suppressing mounting arrangement of claim 3 , wherein the plurality of structural spoke mounting assemblies comprise at least one of piezoelectric actuators, electroresistive actuators, and magnetostrictive actuators and are configured to actively minimize the transfer of the axial spoke vibrations to the wall of the outer duct. 5. The acoustic noise suppressing mounting arrangement of claim 4 , wherein the plurality of structural spoke mounting assemblies are configured to generate electricity by converting vibrational energy to electrical energy. 6. The acoustic noise suppressing mounting arrangement of claim 3 , wherein the plurality of structural spoke mounting assemblies are configured to passively minimize the transfer of the axial spoke vibrations to the wall of the outer duct. 7. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising at least one of a layer damping treatment applied to each structural spoke of the plurality of structural spokes, the outer duct, or both. 8. The acoustic noise suppressing mounting arrangement of claim 1 , wherein at least one structural spoke of the plurality of structural spokes comprises a secondary conduit configured to transfer at least one of electrical energy, signals, and fluids. 9. The acoustic noise suppressing mounting arrangement of claim 1 , wherein each structural spoke of the plurality of structural spokes has a tailored cambered shape configured to preswirl a flow entering the outer duct or swirl a flow exiting the outer duct. 10. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising acoustic vibration reduction treatments applied to at least one of an inside of the outer duct and a portion the central shaft assembly, wherein the acoustic vibration reduction treatment is configured to absorb acoustic energy. 11. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising rub strips mounted to an inner wall of the outer duct. 12. The acoustic noise suppressing mounting arrangement of claim 1 , further comprising one or more spoke cross-members configured to connect two or more structural spokes together, wherein the one or more spoke cross-members are configured to produce a tighter mesh between the two or more structural spokes and prevent a foreign object or body part from being ingested into the ducted fan assembly. 13. A method for mounting components of a ducted fan assembly, the method comprising: coupling at least one rotating member to a shaft power source to form a central shaft assembly, wherein the at least one rotating member comprises at least one of: a fan, a propeller, an impeller, and a rotor, and wherein the shaft power source comprises an external drive shaft, an electric engine, an internal combustion engine, or a turbine engine; coupling the central shaft assembly to an outer duct via one or more bearing assemblies, wherein the outer duct is configured to allow air to enter on a first end of the outer duct and eject the air from a second end of the outer duct, and wherein the one or more bearing assemblies are configured to rotatably secure the at least one rotating member within the outer duct and to transfer thrust loads between the outer duct and the central shaft assembly; coupling a plurality of structural spokes to the outer duct and the central shaft assembly, wherein the plurality of structural spokes are configured to transfer loads between the outer duct and at least a portion of the central shaft assembly, wherein each structural spoke of the plurality of structural spokes has a high aspect ratio, and wherein the plurality of structural spokes comprise aft-swept structural spokes and forward-swept structural spokes; and pretensioning each structural spoke of the plurality of structural spokes. 14. The method of claim 13 , wherein the coupling of the plurality of structural spokes to the central shaft assembly comprises coupling a plurality of fixtures to the central shaft assembly, wherein each fixture of the plurality of fixtures corresponds to one structural spoke of the plurality of structural spokes and is configured to couple a first end of the corresponding structural spoke to the central shaft assembly. 15. The method of claim 13 , wherein the coupling of the plurality of structural spokes to the outer duct comprises coupling a plurality of structural spoke mounting assemblies to the outer duct, wherein each structural spoke mounting assembly of the plurality of structural spoke mounting assemblies corresponds to one structural spoke of the plurality of structural spokes and is configured to couple a second end of the corresponding structural spoke to the outer duct, wherein each the plurality of structural spoke mounting assemblies is configured to tighten the corresponding structural spoke and to minimize transfer of axial spoke vibrations to a wall of the outer duct. 16. The method of claim 15 , wherein the plurality of structural spoke mounting assemblies comprise at least one of piezoelectric actuators, electroresistive actuators, and magnetostrictive actuators and are configured to actively minimize the transfer of the axial spoke vibrations to the wall of the outer duct. 17. The method of claim 16 , wherein the plurality of structural spoke mounting assemblies are configured to generate electricity by converting vibrational energy to elec