Gradient structure for transmitting and/or reflecting an electromagnetic signal

The invention claimed is: 1. A gradient structure ( 100 ) for transmitting and/or reflecting an electromagnetic signal, comprising a plurality of interconnected cells ( 110 ), wherein each cell comprises a through cavity ( 112 ) surrounded by walls ( 111 ), wherein the walls of each cell have a gradually varying thickness along a longitudinal direction of the cavity of each cell. 2. The gradient structure ( 100 ) according to claim 1 , wherein each cell ( 110 ) is built up of a plurality of layers extending across a longitudinal direction of each cell. 3. The gradient structure ( 100 ) according to claim 2 , wherein the density is gradually varying in different layers of the cells ( 110 ). 4. The gradient structure ( 100 ) according to claim 1 , wherein the gradient structure is configured to transmit and/or reflect an electromagnetic signal within at least one predetermined bandwidth range. 5. The gradient structure ( 100 ) according to claim 4 , wherein a thickness of the walls (t h ) of the cells is selected to obtain a permittivity of each layer of the gradient structure such that the gradient structure is transmissive or reflective to an electromagnetic signal, within the at least one predetermined bandwidth range. 6. The gradient structure ( 100 ) according to claim 1 , wherein the cells ( 110 ) of the plurality of interconnected cells have a different diameter (d cell ) and/or geometrical shape. 7. The gradient structure ( 100 ) according to claim 1 , wherein the cells ( 110 ) has a hexagonal shape or any other geometrical shape. 8. The gradient structure ( 100 ) according to claim 4 , wherein the gradient structure is provided with an additional layer ( 120 ), such as a conductive layer, a frequency selective surface, or a skin, which is arranged to transmit, reflect, filter or absorb wavelengths within the at least one predetermined bandwidth range. 9. The gradient structure ( 100 ) according claim 8 , comprising a plurality of gradient structures arranged on top of each other, wherein the plurality of gradient structures being separated by at least one additional layer ( 120 ). 10. The gradient structure ( 100 ) according to claim 4 , wherein the diameter of each cell (d cell ) is smaller than the smallest wavelength within the at least one predetermined bandwidth range. 11. The gradient structure ( 100 ) according to claim 1 , wherein the walls ( 111 ) of the cells comprises a dielectric material. 12. The gradient structure ( 100 ) according to claim 1 , wherein the cavity ( 112 ) of the cells comprises a dielectric material, which is different from the dielectric material of the walls ( 111 ). 13. The gradient structure ( 100 ) according to claim 11 , wherein each cell ( 110 ) further comprises a conductive material, such as a metal or a conductive polymer. 14. The gradient structure ( 100 ) according to claim 1 , wherein the gradient structure is planar or curved. 15. The gradient structure ( 100 ) according to claim 1 , wherein the gradient structure is designed as a lens. 16. A cover structure ( 200 ) comprising at least a gradient structure ( 100 ) according to claim 1 , further comprising at least one skin ( 210 a , 210 b ) attached to the topmost and/or bottommost portion of the gradient structure. 17. The cover structure ( 200 ) according to claim 16 , wherein the thickness of the walls ( 111 ) is selected to obtain a permittivity of each layer of the gradient structure ( 100 ) such that reflections in the gradient structure substantially cancel or increase reflections in the gradient structure caused by the skin ( 210 a , 210 b ). 18. The cover structure ( 200 ) according to claim 16 , wherein the at least one skin ( 210 a , 210 b ) is made of a composite material. 19. A system ( 300 ) comprising at least one transmitter and/or receiver ( 310 ) and a cover structure ( 200 ) according to claim 16 . 20. A structure element ( 400 ) having integrated therein the system ( 300 ) according to claim 19 , wherein an outer surface of the cover structure ( 200 ) forms part of a surface of the structure element. 21. A method ( 500 ) for optimizing the transmittance and/or reflectance of an electromagnetic signal of a gradient structure, said gradient structure comprising a plurality of interconnected cells, wherein each cell comprises a through cavity surrounded by walls, wherein the walls of each cell have a gradually varying thickness along a longitudinal direction of the cavity of each cell, said method comprising: selecting at least one bandwidth range ( 501 ), within which the gradient structure should transmit and/or reflect the electromagnetic signal, selecting at least one incident angle ( 502 ) of a transmitter and/or a receiver arranged within the gradient structure, selecting a thickness of the gradient structure ( 503 ), dividing each cell into a plurality of layers ( 504 ) extending across a longitudinal direction of the cell, optimizing values of the permittivity ( 506 ) for each of the plurality of layers, in order to maximize the performance of the gradient structure, selecting a cell diameter ( 507 ) for the cells, wherein the cell diameter is smaller than the smallest wavelength within the at least one bandwidth range, selecting the wall thickness ( 508 ) for each layer of the cell such that the permittivity of each of the plurality of layers corresponds to the optimized permittivity values. 22. The method according to claim 21 , comprising a step of providing at least one additional layer ( 505 ) with a known permittivity, to the topmost and/or bottommost portions of the gradient structure prior to the step of dividing each cell into a plurality of layers. 23. The method ( 500 ) according to claim 21 , wherein the step of optimizing values ( 506 ) of the permittivity is performed by any optimization method, such as the gradient descent projection method. 24. The method ( 500 ) according to claim 21 , wherein in the step of optimizing values ( 506 ) of the permittivity, the transmittance or reflectance of the gradient structure is calculated by a scattering parameter calculation method for stratified media. 25. The method ( 500 ) according to claim 21 , wherein inverse homogenization is performed in the step of selecting a wall thickness for each layer of the cell ( 508 ) such that the permittivity of each of the plurality of layers corresponds to the optimized permittivity values. 26. The method ( 500 ) according to claim 21 , comprising a step of converting the plurality of layers into a continuous layer ( 509 ). 27. The method ( 500 ) according to claim 21 , further comprising a step of manufacturing the gradient structure and/or optional additional layers by 3D printing ( 510 ).