Full-function holographic antenna and method for fabricating same

What is claimed is: 1. A holographic antenna for recording an interference pattern and reconstructing waveform of a target antenna, comprising a feed antenna and a holographic structure, the holographic structure comprising a substrate and a plurality of spaced metal strips disposed on the substrate, wherein heights of portions of each of the metal strips are negatively correlated with interference intensities of the interference pattern, portions of each of the metal strips having a height H1 are located on the substrate corresponding to a minimum intensity value T1 of the interference pattern and portions of each of the metal strips having a height H2 are located on the substrate corresponding to a maximum intensity value T2 of the interference pattern, remaining portions of each of the metal strips having heights H less than H1 but larger than H2 are located on the substrate corresponding to the intensity values T of the interference pattern larger than T1 but less than T2, the interference intensity values T, T1, and T2 and heights H, H1, and H2 of each of the metal strips satisfy the functions: 0≤H2≤H≤H1; and H=T×(T2−T1)/(H1−H2). 2. The holographic antenna according to claim 1 , wherein each of the metal strips has a partially elliptical ribbon structure bent toward the feed antenna, each of the metal strips has an inner side toward the feed antenna and an outer side away from the feed antenna, the number of the metal strips is greater than 15 and the metal strips are arranged in a radial shape toward the feed antenna, an inner radius of an i-th metal strip of the metal strips is 0.66×λ×(2×i−1) and an outer radius of the i-th metal strip is 0.66×λ×2×i, wherein 1≤i≤15, and λ is a free space wavelength. 3. The holographic antenna according to claim 2 , wherein each of the metal strips comprises a plurality of metal patches, the metal patches are sheets of square shape having a side length of 0.01λ, the metal patches are spliced or overlapped to each other to form the metal strips. 4. The holographic antenna according to claim 1 , wherein the feed antenna is a pyramid horn antenna comprising a waveguide of rectangular shape and four inclined trapezoid side surfaces connected to the waveguide, the side surfaces are connected in order to surround the waveguide and form a horn termination surface at an end away from the waveguide. 5. The holographic antenna according to claim 4 , wherein the waveguide has a length between 1.0 cm and 1.4 cm, a width between 0.5 cm and 0.7 cm, and a height between 1.6 cm and 1.8 cm, the horn termination surface has a length between 4.2 cm and 4.4 cm, and a width between 1.6 cm and 1.8 cm, a distance between the waveguide and the horn termination surface is between 3.2 cm and 3.6 cm, a center axis of the pyramid horn antenna coincides with an apex of the substrate. 6. The holographic antenna according to claim 1 , wherein the substrate comprises a parallelepiped casing and a filling medium infilled in the casing, the filling medium is a ceramic-filled polytetrafluoroethylene material. 7. A method for fabricating a holographic antenna of claim 1 , comprising the steps of: S 1 : providing a base board, the base board having a length of L1, a width of L2, and a height of L3; S 2 : drawing N elliptical strip patterns on the base board, the N elliptical strip patterns having negative semi-axes overlapped with each other and a same left focal point, the N elliptical strip patterns constituting an elliptical strip group, wherein N is a natural number greater than 30; S 3 : cutting the base board to produce the substrate, wherein an apex of the substrate is located on the left focal point of the N elliptical strip patterns, an angle of the substrate corresponding to the apex is 90°, and a side length of the substrate is between 9.2 cm and 9.4 cm, a diagonal line of the substrate overlaps with the negative semi-axes of the N elliptical strip patterns, wherein part of each of the N elliptical strip patterns is on the substrate; S 4 : splicing a plurality of metal patches and attaching the metal patches to the substrate where the parts of the N elliptical strip patterns are located to form single-layer metal strips, wherein each of the single-layer metal strip has a shape coinciding with a shape of the part of a corresponding one of the elliptical strip patterns; S 5 : mounting a feed antenna at the apex of the substrate and aligning a center axis of four inclined trapezoid side surfaces of the feed antenna with the apex of the substrate, and mounting a microwave camera near the feed antenna; S 6 : starting the feed antenna to interfere with a target antenna on a surface of the substrate, recording interference intensities at different positions of the substrate by the microwave camera, converting the interference intensities into grayscale values of 0 to 255 by a computer device, and height values corresponding to portions of each of the metal strips are calculated according to the grayscale values by the computer device; S 7 : laminating a plurality of metal patches on the single-layer metal strips according to the height values to produce the metal strips, so that the portions of each of the metal strips have heights corresponding to the height values. 8. The method according to claim 7 , wherein the base board comprises a rectangular parallelepiped casing and a filling medium infilled in the casing, the filling medium is a ceramic-filled polytetrafluoroethylene material. 9. The method according to claim 8 , wherein the base board has the length L1>50×λ and the width L2>40×λ, wherein λ is a free space wavelength. 10. The method according to claim 9 , wherein the length L1 of the base board is between 9.2 cm and 9.4 cm, the width L2 of the base board is between 9.2 cm and 9.4 cm, and a thickness L3 of the base board is 0.635 cm. 11. The method according to claim 7 , wherein the N elliptical strip patterns are radially arranged toward the feed antenna, wherein an inner radius of an i-th elliptical strip pattern is 0.66×(2×i−1)×λ, and an outer radius of the i-th elliptical strip pattern is 0.66×2×i×λ, wherein 1≤i≤15, and λ is a free-space wavelength. 12. The method according to claim 7 , wherein the metal patches are sheets of square shape having a side length of 0.01λ, λ is a free-space wavelength. 13. The method according to claim 12 , wherein the metal patches are copper sheets. 14. The method according to claim 13 , wherein the metal patches are spliced by soldering, and laminated by bonding or other adhesion.