3-D object comprising a sandwich of one or more composite layers, of one or more layers of metal patterns and optionally of one or more layers of possibly dense polymers for electromagnetic applications in antennas and/or radomes

The invention claimed is: 1 . A process for manufacturing a composite stack of 3-D shape, comprising a stack of layers of resin and fibre and at least one layer of metal patterns, said process comprising the following steps, a periodic or pseudo-periodic organization in 2-D of first patterns similar to a standard unit pattern having been determined for said layer of metal patterns depending on the electromagnetic function desired for the layer of metal patterns: i/ computing first patterns of said periodic organization once laid on the 3-D shape; then projecting, onto a plane, said patterns computed on the 3-D shape, thus defining a planar organization of second patterns; ii/ partially polymerizing, flat, by using a vacuum oven, at least one sub-set of first layers of said stack of layers, so as to make it electrochemically etchable, but to keep it deformable, said first layers being flat and comprising at least one metal layer on the surface of said sub-set to form a flat composite stack; iii/ electrochemically etching said organization of second patterns that was defined in step i into the metal layer of the flat composite stack resulting from step ii to form an etched composite stack: iv/ completely polymerizing the etched composite stack after said etched composite stack has been placed in a mould having the desired 3-D shape. 2 . The process for manufacturing a composite stack of 3-D shape according to claim 1 , wherein the shape is a non-developable shape. 3 . The process for manufacturing a composite stack of 3-D shape according to claim 1 , wherein, at the end of step i: the value of at least one parameter indicating deformations between the patterns projected onto said 3-D shape and a target unit pattern is computed; and said computed value is compared to a threshold; and if said value is higher than the threshold, a modification is made to said periodic or pseudo-periodic organization in 2-D of first patterns and/or to one or more first patterns; and before step ii is implemented, step i is iterated on the basis of said periodic or pseudo-periodic organization in 2-D of first patterns that was obtained after modification, steps ii to iv then being implemented on the basis of the planar organization of second patterns that was obtained after modification. 4 . The process for manufacturing a composite stack of 3-D shape according to claim 3 , wherein one or more parameters are computed among a parameter indicating a lengthwise deformation of the patterns and a parameter indicating an anglewise deformation of the patterns. 5 . The process for manufacturing a composite stack of 3-D shape according to claim 3 , wherein a deformation map is computed that represents, as a function of the position, on said 3-D shape, of the projected pattern, a deformation level. 6 . The process for manufacturing a composite stack of 3-D shape according to claim 1 , wherein the sub-set of first layers considered in step i comprises a metal layer on the bottom face of said sub-set and a metal layer on the top face of said sub-set and patterns are etched into each of the two metal layers in step iii. 7 . The process for manufacturing a composite stack of 3-D shape according to claim 1 , wherein the stack of layers comprises a plurality of sub-sets each comprising a stack of one or more layers of resin and fibre and of one or more periodic or pseudo-periodic metal layers: all of steps i, ii and iii are implemented on each sub-set, each sub-set being associated with its own organization of periodic or pseudo-periodic patterns; and step iv of complete polymerization in the mould is then implemented once the sub-sets each resulting from steps i, ii and iii have been stacked or laid together in the mould. 8 . The process according to claim 1 , wherein the function of said metal patterns is at least one function among that of filtering electromagnetic waves, of being an assembly or sub-assembly of the radiating element of an antenna and/or of modifying the EM-wave polarization. 9 . The process according to claim 1 , wherein the function of said metal patterns is to receive or transmit electromagnetic waves. 10 . A process for manufacturing an element, comprising the process for manufacturing a composite stack according to claim 1 , wherein the element is an element among an antenna, a radome and/or a polarizing surface.