Ridge gap waveguide crossover structure including intersecting transmission lines with impedance transformers disposed between upper and bottom planar metal plates and having a gap therein

We claim: 1. A ridge gap waveguide millimeter-wave crossover bridge structure device, comprising: an upper planar metal plate and a bottom planar metal plate arranged in parallel; a supporting structure fixedly arranged between the upper planar metal plate and the bottom planar metal plate; a ridge waveguide fixed on a surface of the bottom planar metal plate facing but not contacting the upper planar metal plate, wherein the ridge waveguide includes two transmission lines arranged crosswise with respect to each other and four impedance transformation structures, one of the two transmission lines having two ends respectively connected to two of the four impedance transformation structures, the other of the two transmission lines having two ends respectively connected to the other two of the four impedance transformation structures, each of the impedance transformation structures having a distal end for external connection; four input ports opened in the bottom planar metal plate and respectively located around the distal ends of the four impedance transformation structures; and a plurality of metal pins fixed on the surface of the bottom planar metal plate facing but not contacting the upper planar metal plate, wherein the plurality of metal pins are evenly arranged around the ridge waveguide, wherein an air gap is present between the ridge waveguide and the plurality of metal pins on the bottom planar metal plate and the upper planar metal plate. 2. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 1 , wherein four corners are defined around an area where the two transmission lines cross each other; and two of the four corners are diagonally opposite to each other and each of the two of the four corners comprises a chamfered corner with a chamfer edge. 3. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 2 , further comprising two pins fixed on the surface of the bottom planar metal plate and facing the upper planar metal plate, wherein the height of the two pins is the same as the height of the plurality of metal pins, and each of the two pins has a respective surface opposite to the chamfer edge of a respective one of the two chamfered corners. 4. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 3 , wherein the chamfer edge of each of the two chamfered corners has an inclined surface, and each of the two pins has a shape of a triangular prism with one side surface of the triangular prism opposite to the inclined surface of the chamfer edge of a respective one of the two chamfered corners. 5. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 2 , wherein each of the upper planar metal plate and the bottom planar metal plate has a shape of a cross consisting of two intersecting rectangles, each of the two intersecting rectangles having eight outer corners of 90 degrees each, the two intersecting rectangles forming four interior intersected corners, where the two intersecting rectangles intersect. 6. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 5 , wherein the supporting structure comprises a plurality of supporting pins fixed on the surface of the bottom planar metal plate facing the upper planar metal plate and respectively located at the eight outer corners and the four intersected corners of the two intersecting rectangles corresponding to the shape of the bottom planar metal plate. 7. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 1 , wherein each of the four impedance transformation structures comprises a first transformation sub-structure and a second transformation sub-structure, wherein the first transformation sub-structure has a first end connected to the corresponding transmission line and a second end connected to a first end of the second transformation sub-structure, and the second transformation sub-structure has a second end corresponding to the distal end of the corresponding impedance transformation structure; and the first transformation sub-structure is narrower than the corresponding transmission line, and the first transformation sub-structure is wider than the second transformation sub-structure. 8. The ridge gap waveguide millimeter-wave crossover bridge structure device as claimed in claim 7 , wherein two corners are formed where the first transformation sub-structure of each of the four impedance transformation structures is connected to the corresponding transmission line, and the two corners are rounded or chamfered. 9. A center-structure module for a ridge gap waveguide millimeter-wave crossover bridge structure device, comprising: an upper planar metal plate and a bottom planar metal plate arranged in parallel; a ridge waveguide fixed on a surface of the bottom planar metal plate facing but not contacting the upper planar metal plate, wherein the ridge waveguide includes two transmission lines arranged crosswise with respect to each other, each of the two transmission lines having two ends for respectively connecting to two respective wave port feeding pieces; a plurality of metal pins fixed on the surface of the bottom planar metal plate facing but not contacting the upper planar metal plate, wherein the plurality of metal pins are evenly arranged around the ridge waveguide; and two pins fixed on the surface of the bottom planar metal plate facing the upper planar metal plate, wherein the height of the two pins is the same as the height of the plurality of metal pins, wherein an air gap is present waveguide and the plurality of metal pins on one side and the upper planar metal plate; wherein four corners are defined around an area where the two transmission lines cross each other, two of the four corners are diagonally opposite to each other, and each of the two of the four corners comprises a chamfered corner with a chamfer edge; wherein each of the two pins has a respective surface opposite to the chamfer edge of a respective one of the two chamfered corners. 10. The center-structure module as claimed in claim 9 , wherein the chamfer edge of each of the two chamfered corners has an inclined surface, and each of the two pins has a shape of a triangular prism with one side surface of the triangular prism opposite to the inclined surface of the chamfer edge of a respective one of the two chamfered corners.