Model-based definition for machining aircraft parts

What is claimed is: 1. A method of manufacturing an aircraft part for an assembly, the method comprising: creating a three-dimensional geometry model for an aircraft part having surface features and holes represented thereby, the surface features and holes in the three-dimensional geometry model being sized to respectively a nominal surface feature dimension and a nominal hole diameter, and having respectively a surface-feature tolerance range and a hole-diameter tolerance range related thereto; generating a numerically-controlled machining program directly from the three-dimensional geometry model, the numerically-controlled machining program having instructions for a single numerically-controlled machining apparatus to machine the aircraft part including its surface features and holes, including instructions to machine the holes to the nominal hole diameter; and machining the aircraft part including its surface features and holes in a single machining setup on a single numerically-controlled machining apparatus utilizing the numerically-controlled machining program, wherein the numerically-controlled machining apparatus utilizes a hole-forming tool for machining the holes, the hole-forming tool being set at substantially the nominal hole diameter, instead of at a high side or a low side of the hole-diameter tolerance range to allow for tight geometric dimensioning and tolerancing requirements, whereby the holes are machined to substantially the nominal hole diameter, wherein the instructions of the numerically-controlled machining program include instructions to machine the surface features to the nominal surface feature dimension, wherein the numerically-controlled machining apparatus utilizes a surface machining tool for machining the surface features, the surface machining tool being set at substantially the nominal surface feature dimension, instead of at a high side or a low side of the surface-feature the surface features are machined to substantially the nominal surface feature dimension, and wherein the method further comprises comparing a weight of the machined aircraft part to a baseline weight for the aircraft part with nominal dimensions to confirm that the surface features are machined to substantially to the nominal surface feature dimension, and that the holes are machined to substantially to the nominal hole diameter. 2. The method of claim 1 further comprising disabling operator input to the numerically-controlled machining apparatus to set the hole-forming tool with an offset value for machining the holes away from the nominal hole diameter toward the high side or low side of the hole-diameter tolerance range to allow tight geometric dimensioning and tolerancing requirements. 3. The method of claim 1 further comprising disabling operator input to the numerically-controlled machining apparatus to set the surface machining tool with an offset value for machining the surface features away from the nominal surface feature dimension toward the high side or low side of the surface-feature tolerance range to allow for tight geometric dimensioning and tolerancing requirements. 4. The method of claim 1 , wherein the instructions of the numerically-controlled machining program include instructions for a multi-axis numerically-controlled machining apparatus to machine surface features and holes in each of two or more orthogonal planes in a single machining setup. 5. The method of claim 1 , wherein the aircraft part, three-dimensional geometry model and numerically-controlled machining program are each a first thereof, and wherein the method further comprises: creating a second three-dimensional geometry model for a second aircraft part having surface features and holes represented thereby, the surface features of the first aircraft part and second aircraft part in respectively the first three-dimensional geometry model and second three-dimensional geometry model having an identical mating surface feature profile; generating a second numerically-controlled machining program directly from the second three-dimensional geometry model; and machining the second aircraft part including its surface features and holes on a single numerically-controlled machining apparatus utilizing the second numerically-controlled machining program, wherein the surface features of the first aircraft part and second aircraft part in respectively the first three-dimensional geometry model and second three-dimensional geometry model have the identical mating surface feature profile, and the first numerically-controlled machining program and the second numerically-controlled machining program are generated directly from respectively the first three-dimensional geometry model and second three-dimensional geometry model, to thereby enable machining the first aircraft part and second aircraft part with a substantially identical mating surface feature profile. 6. The method of claim 5 , wherein the holes of the second aircraft part in the second three-dimensional geometry model are sized to a nominal hole diameter, and wherein the single numerically-controlled machining apparatus that machines the second aircraft part utilizes a hole-forming tool for machining the holes of the second aircraft part, the hole-forming tool for machining the holes of the second aircraft part being set at substantially the nominal hole diameter of the holes of the second aircraft part, whereby the holes of the second aircraft part are machined to substantially the nominal hole diameter thereof. 7. The method of claim 6 , wherein the nominal hole diameter substantially to which the holes of the first aircraft part and second aircraft part are machined is the same and a final hole size for a class hole diameter corresponding to a fastener, thereby enabling installation of fasteners to assemble the first aircraft part and second aircraft part without any subsequent drilling, reaming or shimming operations. 8. A method of manufacturing an aircraft part for an assembly, the method comprising: creating a three-dimensional geometry model for an aircraft part having surface features and holes represented thereby, the surface features and holes in the three-dimensional geometry model being sized to respectively a nominal surface feature dimension and a nominal hole diameter, and having respectively a surface-feature tolerance range and a hole-diameter tolerance range related thereto; generating a numerically-controlled machining program directly from the three-dimensional geometry model, the numerically-controlled machining program having instructions for a single numerically-controlled machining apparatus to machine the aircraft part including its surface features and holes, including instructions to machine the surface features to the nominal surface feature dimension; and machining the aircraft part including its surface features and holes on the single numerically-controlled machining apparatus utilizing the numerically-controlled machining program, wherein the numerically-controlled machining apparatus utilizes a surface machining tool for machining the surface features, the surface machining tool being set at substantially the nominal surface feature dimension, instead of at a high side or a low side of the surface-feature tolerance range to allow for tight geometric dimensioning and tolerancing requirements, whereby the surface features are machined to substantially the nominal surface feature dimension, wherein the instructions of the numerically-controlled machining program include instructions to machine the holes to the nominal hole diameter, wherein the numerically-controlled machining apparatus utilizes a hole-forming tool for machining the holes, the hole-forming tool being set at substantial