Systems and methods for estimating powder dosing in additive manufacturing processes

What is claimed is: 1. A method for forming a component, the method comprising: estimating a dosing plan for powder of a powder bed fusion (PBF) system needed to form the component, the dosing plan comprising powder dosing requirements needed per layer to form the component; providing the dosing plan to a controller of the PBF system; regulating, via the controller, the powder being supplied to a build chamber of the PBF system from a supply chamber of the PBF system based on the dosing plan; and additively manufacturing the component onto a build platform via the PBF system using the powder in the build chamber according to the dosing plan; wherein estimating the dosing plan for the powder of the PBF system needed to form the component further comprises: determining a volume of each layer of the component; determining a perimeter of each layer of the component; and estimating the powder dosing requirements of the dosing plan as a function of the volume and the perimeter. 2. The method of claim 1 , further comprising: determining at least one of a shrinkage factor or a compaction level for the powder based on a powder type; and estimating the powder dosing requirements of the dosing plan as a function of at least one of the shrinkage factor or the compaction level. 3. The method of claim 1 , wherein estimating the dosing plan for powder of the PBF system further comprises: dividing an exposure area of the component into one or more zones, the one or more zones being associated with one or more of a powder packing factor, a part orientation, a recoater contact, or build time productivity; determining, via an algorithm stored in the controller of the PBF system a variance of the exposure area across the one or more zones; and minimizing the variance of the exposure area across the one or more zones so as to equalize a power requirement across the build platform. 4. The method of claim 1 , wherein estimating the dosing plan for powder of the PBF system further comprises: receiving, via the controller, one or more inputs relating to slice files and a material type of the powder; calculating, via the controller, a shrinkage factor of the powder in a melted state; splitting, via the controller, the one or more slice files into a grid of pixels to determine which pixels require an amount of powder above a certain threshold; generating, via the controller, the dosing plan based on the shrink factor and the grid of pixels. 5. The method of claim 1 , wherein estimating the dosing plan for the powder of the PBF system needed to form the component further comprises: adding an additional powder margin to the powder dosing requirements of the dosing plan to account for an area between the build platform and at least one of the supply chamber or an overflow collector of the PBF system. 6. The method of claim 1 , wherein estimating the dosing plan for the powder of the PBF system needed to form the component further comprises: adding an additional powder margin to the powder dosing requirements of the dosing plan to account for melted powder having a lesser volume than powder particles. 7. The method of claim 1 , further comprising automating, via the controller of the PBF system, dosing level changes layer-by-layer. 8. The method of claim 1 , wherein the PBF system comprises a direct metal laser melting (DMLM) system. 9. The method of claim 1 , wherein the component is an aircraft component.