Ridge gap waveguide and multilayer antenna array including the same

What is claimed is: 1. A ridge gap waveguide, comprising: a conductive base; a conductive ridge protruding upward from the conductive base and extending along a predetermined wave transmission direction; an upper conductive wall located over the conductive base and the conductive ridge and spaced apart from the conductive ridge by a gap; and an electromagnetic bandgap (EBG) structure arranged adjacent to the conductive ridge between the conductive base and the upper conductive wall, wherein the EBG structure includes a plurality of cells that are arranged in a two-dimensional periodic lattice structure and are not electrically coupled to each other, and wherein each of the plurality of cells includes: a dielectric layer, a first conductive pattern and a second conductive pattern respectively formed at a lower surface and an upper surface of the dielectric layer, and a conductive via passing through the dielectric layer and connecting the first conductive pattern to the second conductive pattern. 2. The ridge gap waveguide of claim 1 , wherein the EBG structure is spaced apart from at least one of the conductive base and the upper conductive wall by an air gap. 3. The ridge gap waveguide of claim 1 , further comprising a spacer arranged in at least one of a position between the EBG structure and the conductive base and a position between the EBG structure and the upper conductive wall, the spacer fixing the EBG structure and providing an air gap in at least one of a position between the EBG structure and the conductive base and a position between the EBG structure and the upper conductive wall. 4. The ridge gap waveguide of claim 3 , wherein the spacer includes a shape protruding toward the EBG structure from an upper surface of the conductive base or a lower surface of the upper conductive wall. 5. The ridge gap waveguide of claim 3 , wherein the spacer is located not to simultaneously contact adjacent cells that are included in the EBG structure and are adjacent to each other. 6. The ridge gap waveguide of claim 5 , wherein the EBG structure is formed based on a double-sided printed circuit board. 7. The ridge gap waveguide of claim 6 , wherein the double-sided printed circuit board includes a concave portion, and wherein the conductive ridge is arranged at the concave portion. 8. The ridge gap waveguide of claim 1 , wherein the conductive ridge includes a pattern for filtering an electromagnetic wave of a predetermined frequency. 9. The ridge gap waveguide of claim 1 , further comprising an upper ridge protruding toward the conductive ridge from the upper conductive wall and maintaining a distance from the conductive ridge. 10. An antenna array, comprising: the ridge gap wave guide of claim 1 , the conductive ridge being connected to an input port; an electromagnetic bandgap (EBG) structure arranged adjacent to the conductive ridge over the conductive base; and a substrate integrated waveguide (SIW) resonator arranged over the conductive ridge and the EBG structure, wherein the SIW resonator includes: the upper conductive wall as a lower conductive layer spaced apart from the conductive ridge by a gap and forming a waveguide with the conductive ridge, and an upper conductive layer forming a resonant cavity with the lower conductive layer. 11. The antenna array of claim 10 , wherein the EBG structure includes a plurality of cells that are arranged in a two-dimensional periodic lattice structure and are not electrically coupled to each other, and wherein each of the plurality of cells includes: a first dielectric layer, a first conductive pattern and a second conductive pattern respectively formed at a lower surface and an upper surface of the first dielectric layer, and a conductive via passing through the first dielectric layer and connecting the first conductive pattern to the second conductive pattern. 12. The antenna array of claim 11 , wherein the EBG structure is formed based on a first double-sided printed circuit board. 13. The antenna array of claim 11 , wherein the SIW resonator includes: an input layer including the lower conductive layer and an input slot; an output layer including the upper conductive layer and an output slot; and an intermediate layer including a second dielectric layer arranged between the input layer and the output layer, and a plurality of conductive elements connecting the input layer to the output layer and forming a sidewall of the resonant cavity. 14. The antenna array of claim 13 , wherein the conductive element includes a metallic via passing through the second dielectric layer. 15. The antenna array of claim 13 , wherein the SIW resonator is formed based on a second double-sided printed circuit board. 16. The antenna array of claim 13 , wherein a distance between the plurality of conductive elements is set to prevent a power leakage to outside from the SIW resonator. 17. The antenna array of claim 13 , further comprising an additional conductive element located in the resonant cavity and used for matching with the SIW resonator. 18. The antenna array of claim 13 , further comprising a radiator arranged over the SIW resonator and including a conductive patch facing the output slot. 19. The antenna array of claim 18 , further comprising a spacer located between the radiator and the SIW resonator and providing an air gap between the radiator and the SIW resonator. 20. The antenna array of claim 10 , wherein the input port is located at a center portion of the waveguide formed by the conductive ridge and the lower conductive layer. 21. The antenna array of claim 13 , wherein the input slot included in the SIW resonator includes a plurality of input slots, and wherein the conductive ridge includes a shape that distributes power to the plurality of input slots at equal amplitude and phase.