Integrated digital thread for additive manufacturing design optimization of lightweight structures

What is claimed is: 1. A part formed by an additive manufacturing process, the part consisting of three regions: regions of voids; regions of solid material; and regions of non-uniform lattice cells, each lattice cell comprising bars, wherein the regions are spatially distributed throughout the part as a function of load conditions such that the solid material is distributed in regions of first load paths and the non-uniform lattice cells are distributed in regions of second load paths lower in magnitude than the first load paths, wherein diameters of each bar of a non-uniform lattice cell are sized as a function of at least one of a resolution unit of the additive manufacturing process and part performance requirements, and wherein the diameters of each bar of the non-uniform lattice cells are classified into clusters, and wherein an average diameter size is assigned to each bar of the non-uniform lattice cells in a same cluster. 2. The part according to claim 1 , wherein the non-uniform lattice cells comprise 6-bar tetrahedral lattice cells, 16-bar hexahedral elements, and 24-bar hexahedral elements, wherein a type and a size of the non-uniform lattice cells are a function of the additive manufacturing process. 3. The part according to claim 2 , wherein diameters of each bar of the non-uniform lattice cells are not equal. 4. The part according to claim 1 further comprising one or more geometrical features as a function of the additive manufacturing process. 5. The part according to claim 4 , wherein the geometrical features include egress slots. 6. The part according to claim 5 , wherein the egress slots are configured to have un-sintered powder or uncured resin exit the part. 7. The part according to claim 1 , wherein a material of the part is selected from the group consisting of metals, ceramics, polymers, and composites. 8. A method of manufacturing a part using an additive manufacturing process, the method comprising: manufacturing regions of solid material; manufacturing regions of non-uniform lattice cells, each non-uniform lattice cell comprising bars; and leaving regions of voids with no material; wherein the regions are spatially distributed throughout the part as a function of load conditions such that the solid material is distributed in regions of first load paths and the non-uniform lattice cells are distributed in regions of second load paths lower in magnitude than the first load paths, wherein diameters of each bar of a non-uniform lattice cell are sized as a function of at least one of a resolution unit of the additive manufacturing process and part performance requirements, and wherein the diameters of each bar of the non-uniform lattice cells are classified into clusters, and wherein an average diameter size being assigned to each bar of the non-uniform lattice cells in a same cluster. 9. The method according to claim 8 , wherein the part is manufactured from different additive manufacturing processes. 10. The method according to claim 8 , wherein the additive manufacturing process is selected from the group consisting of selective laser sintering (SLS), stereolithography (SLA), fused deposition modeling (FDM), polyjet (PJ), direct metal laser sintering (DMLS), selective layer melting (SLM), continuous liquid interphase production (CLIP), and laminated object manufacturing (LOM). 11. The method according to claim 8 , wherein the non-uniform lattice cells comprise 6-bar tetrahedral lattice cells, 16-bar hexahedral elements, and 24-bar hexahedral elements, wherein a type and a size of the non-uniform lattice cells are a function of the additive manufacturing process. 12. The method according to claim 8 further comprising forming one or more geometrical features as a function of the additive manufacturing process. 13. The method according to claim 12 , wherein the additive manufacturing process is selective laser sintering (SLS) and the geometrical features include egress slots for un-sintered powder. 14. The method according to claim 12 , wherein the additive manufacturing process is stereolithography (SLA) and the geometrical features include egress slots for un-cured resin. 15. A part formed by an additive manufacturing process, the part consisting of: regions of voids; regions of solid material; regions of non-uniform lattice cells, each lattice cell comprising bars; and one or more geometrical features as a function of the additive manufacturing process, wherein the regions are spatially distributed throughout the part as a function of load conditions such that the solid material is distributed in regions of first load paths and the non-uniform lattice cells are distributed in regions of second load paths lower in magnitude than the first load paths, wherein diameters of each bar of a non-uniform lattice cell are sized as a function of at least one of a resolution unit of the additive manufacturing process and part performance requirements, wherein the diameters of each bar of the non-uniform lattice cells are classified into clusters, and wherein an average diameter size is assigned to each bar of the non-uniform lattice cells in a same cluster, and wherein a material of the part is selected from the group consisting of metals, ceramics, polymers, and composites. 16. The part according to claim 15 , wherein the geometrical features include egress slots. 17. The part according to claim 16 , wherein the egress slots are configured to have un-sintered powder or uncured resin exit the part. 18. The part according to claim 15 , wherein the non-uniform lattice cells comprise 6-bar tetrahedral lattice cells, 16-bar hexahedral elements, and 24-bar hexahedral elements, wherein a type and a size of the non-uniform lattice cells are a function of the additive manufacturing process. 19. The part according to claim 18 , wherein diameters of each bar of the non-uniform lattice cells are not equal. 20. The part according to claim 15 , wherein the diameters of each bar of the non-uniform lattice cells are adjusted as a function of at least one of a resolution unit of the additive manufacturing process and part performance requirements.