Patent Number: 
Section: claims

1. A multilayer grid containing alternate layers of an opaque or absorptive material and a transparent material for a neutron, hard X-ray, gamma-ray, imaging instrument containing a grid tray having openings to receive multilayer grids, the multilayer grid being a regular polyhedron having faces transparent to photons of interest, the polyhedron having two larger faces in the form of congruent polygons forming front and back surfaces of the polyhedron, remaining faces being smaller polygons separating the front and back surfaces a predetermined distance equal to the width of the two materials contained therein, the larger faces being shaped to form a multilayer grid fitting slidably within the grid opening in the grid tray, and the polyhedron containing a piston formed of a material transparent to photons of interest, which, through a drive shaft, compresses and retains the multilayers in place within the polyhedron, and which is allowed to remain in the polyhedron when, as a grid, the polyhedron is placed in the grid tray. 2. The multilayer grid of  claim 1  wherein the parallelogram is an octagon. claim 1 3. The multilayer grid of  claim 1  wherein the imaging instrument is a telescope, and the smaller polygons are parallelograms with perpendicular sides. claim 1 4. The multilayer grid of  claim 2  wherein the piston drive shaft is coupled to a micrometer through a straight gear. claim 2 5. The multilayer grid of  claim 2  wherein the piston drive shaft is coupled to a micrometer through a reciprocating double rack. claim 2 6. The multilayer grid of  claim 2  wherein the polyhedron and the piston therein are made of glass. claim 2 7. The multilayer grid of  claim 2  wherein the polyhedron and the piston therein are made of aluminum. claim 2 8. A method for improving a telescope used for neutron, hard X-ray and gamma-ray imaging, the telescope being one containing a grid tray having openings to receive multilayer grids, the improvement including assembling a regular polyhedron utilizing faces transparent to photons of interest, with two larger faces in the form of congruent polygons which form front and back surfaces of the polyhedron, and with smaller polygonal faces separating the front and back surfaces, the two larger faces being shaped to fit slidably within the grid opening in the grid tray, sizing a plurality of strips of absorptive and transparent materials so that their widths are equal to the width of the faces of the smaller polygons, inserting in the polyhedron, through an open face, alternate strips of the sized materials to form a multilayer, and compressing the multilayer to form a multilayer grid for insertion in the telescope grid tray. 9. The method of  claim 8  wherein the uniform compressing of the inserted layers is accomplished by a piston sized to be inserted in the polyhedron through its open face, and contoured to fit slidably within the polyhedron. claim 8 10. The method of  claim 9  wherein the piston is driven by a straight gear. claim 9 11. The method of  claim 9  wherein the piston is driven by a reciprocating double rack. claim 9 12. The method of  claim 9  wherein the piston is formed of a material transparent to photons of interest, and wherein it is allowed to remain in place within the polyhedron during use. claim 9