Patent Number: 
Section: claims

1. A method for fabricating an x-ray collimator, comprising:identifying 3-dimensional structures and positions of the 3-dimensional structures in a collimator design;selecting a number of collimator layers;determining 2-dimensional shapes corresponding to the respective identified 3-dimensional structures for each layer;determining, in each collimator layer, positions of the 2-dimensional shapes corresponding to the respective identified 3-dimensional structures for each layer;forming apertures in at least one laminated layer to produce the selected number of collimator layers, each having apertures according to its respective determined 2-dimensional shapes at the respective determined positions;stacking the collimator layers in a position of alignment to form the identified 3-dimensional structures;attaching the stacked and aligned collimator layers to form a composite collimator structure with the identified 3-dimensional structures therein; andhoning the 3-dimensional structures within the composite collimator structure. 2. The method of claim 1, wherein the forming apertures in at least one laminated layer comprises:creating the collimator layers from as few as a single laminated layer by simultaneously forming a plurality of collimator layers at different sections of the as few as a single laminated layer, and extracting the plurality of collimator layers from its laminated layer. 3. The method of claim 1, wherein:the step of forming apertures in at least one laminated layer comprises photo-etching the at least one laminated layer to form the apertures. 4. The method of claim 1, wherein:the step of forming apertures in at least one laminated layer comprises punching the at least one laminated layer to form the apertures. 5. The method of claim 1, wherein:the step of forming apertures in at least one laminated layer comprises laser cutting the at least one laminated layer to form the apertures. 6. A method for fabricating an x-ray collimator, comprising:identifying 3-dimensional structures and positions of the 3-dimensional structures in a collimator design;selecting a number of collimator layers;determining 2-dimensional shapes corresponding to the respective identified 3-dimensional structures for each layer;determining, in each collimator layer, positions of the 2-dimensional shapes corresponding to the respective identified 3-dimensional structures for each layer;forming apertures in at least one laminated layer to produce the selected number of collimator layers, each having apertures according to its respective determined 2-dimensional shapes at the respective determined positions;stacking the collimator layers in a position of alignment to form the identified 3-dimensional structures; andattaching the stacked and aligned collimator layers to form a composite collimator structure with the identified 3-dimensional structures therein; andhoning the apertures of each collimator layer prior to stacking and attaching the collimator layers. 7. An x-ray collimator comprising:a plurality of collimator layers, each collimator layer corresponding to a respective cross-section of the x-ray collimator and each collimator layer having at least one aperture, the plurality of collimator layers stacked and attached to form a composite collimator structure wherein the apertures of the respective collimator layers are aligned to form 3-dimensional hollow pyramidal structures that direct x-rays generated by an x-ray source into x-ray beams. 8. The x-ray collimator of claim 7, wherein the plurality of collimator layers are made from thin laminated sheets. 9. The x-ray collimator of claim 7, wherein the plurality of collimator layers comprise Tungsten. 10. The x-ray collimator of claim 7, wherein at least one of the apertures of the collimator layers is honed. 11. The x-ray collimator of claim 7, wherein the 3-dimensional hollow pyramidal structures are fan beam apertures which collimate x-rays from the x-ray source into fan beams. 12. The x-ray collimator of claim 7, wherein the at least one of the apertures of the composite collimator structure has smooth meeting points between the layers so as to form a smooth surface through at least one of the 3-dimensional hollow pyramidal structures. 13. An x-ray collimator, comprising:a plurality of laminated layers having apertures therein, the plurality of laminated layers stacked and attached to form a composite collimator structure wherein the apertures of the respective laminated layers align to form 3-dimensional pyramidal apertures that direct x-rays generated by an x-ray source into x-ray beams. 14. The x-ray collimator of claim 13, wherein the at least one of the apertures of the composite collimator structure has smooth meeting points between the laminated layers so as to form a smooth surface through at least one of the 3-dimensional pyramidal apertures.