Broadband antennas mounted on vehicle

The invention claimed is: 1. An antenna assembly comprising: a dielectric substrate; and mesh grid-like conductive patterns disposed on the dielectric substrate, wherein the mesh grid-like conductive patterns comprise: a radiator region in which a first side and a second side corresponding to an opposite side of the first side form end portions of conductive patterns such that the conductive patterns having different widths are formed in a plurality of step structures; a feed line electrically connected with the radiator region; a first ground region disposed on a first side of the feed line; and a second ground region disposed on a second side of the feed line, wherein the first ground region is formed to have a length greater than or equal to that of the second ground region in one axial direction, and wherein a first number of steps on the second side is greater than or equal to a second number of steps on the first side. 2. The antenna assembly of claim 1 , wherein the radiator region is disposed only in an upper region of either the first ground region or the second ground region. 3. The antenna assembly of claim 2 , wherein the first side in the radiator region is formed in a linear structure, and the second side in the radiator region forms a plurality of step structures by the conductive patterns having different widths. 4. The antenna assembly of claim 1 , wherein the first side in the radiator region adjacent to the first ground region in one axial direction is formed in a linear structure. 5. The antenna assembly of claim 1 , wherein the first side of the radiator region is formed in M step structures in an upper part of the first ground region, the second side of the radiator region disposed over the second ground region is formed in N step structures, where N is a number greater than M, and the first ground region is made longer than the second ground region in one axial direction. 6. The antenna assembly of claim 1 , wherein the first ground region is smaller in width than the second ground region in the other axial direction, which reduces the width of the antenna assembly. 7. The antenna assembly of claim 1 , wherein end portions on the first side of the radiator region formed over the first ground region are formed between opposite ends of the first ground region, so that the antenna assembly operates over a wide band by an interaction between a current in the radiator region and a current in the second ground region. 8. The antenna assembly of claim 1 , wherein end portions on the second side of the radiator region formed over the second ground region are formed between opposite ends of the second ground region, so that the antenna assembly operates over a wide band by an interaction between a current in the radiator region and a current in the second ground region. 9. The antenna assembly of claim 1 , wherein the feed line is disposed in a lower region of the dielectric substrate, and the conductive patterns of the radiator region are configured in such a way as to become wider in the other axial direction toward a higher position in the one axial direction. 10. The antenna assembly of claim 1 , wherein the conductive patterns of the radiator region are configured in such a way as to become shorter in the one axial direction toward the feed line in the one axial direction. 11. The antenna assembly of claim 1 , wherein the conductive patterns of the radiator region are disposed symmetrically in the other axial direction with respect to an extension line of the feed line formed in the one axial direction. 12. The antenna assembly of claim 1 , wherein the conductive patterns of the radiator region are disposed asymmetrically in the other axial direction with respect to an extension line of the feed line formed in the one axial direction, which reduces the width of the antenna assembly. 13. The antenna assembly of claim 1 , wherein the radiator region includes: a first region corresponding to an upper region, and consisting of a plurality of conductive patterns whose end portions on the first side are in different positions on the first side; and a second region corresponding to a lower region which lies under the first region, and formed such that end portions on the first side are spaced apart from a boundary of the first ground region, wherein the width of the conductive patterns in the first region is greater in a higher position. 14. The antenna assembly of claim 13 , wherein a boundary of the first side of the radiator region in the second region is disposed to face the boundary of the first ground region, spaced apart therefrom. 15. The antenna assembly of claim 13 , wherein at least part of the first side formed by the conductive patterns of the radiator region is formed in a liner structure, and the second side in the radiator region forms a plurality of step structures by the conductive patterns having different widths. 16. The antenna assembly of claim 15 , wherein the antenna assembly is implemented as a transparent antenna on the dielectric substrate, and the radiator region, the feed line, the first ground region, and the second ground region, which constitute the transparent antenna, are disposed on the dielectric substrate, thereby forming a co-planar waveguide (CPW) structure. 17. An antenna system for a vehicle, the vehicle including a conductive vehicle body operating as an electrical ground, the antenna system comprising: a glass constituting a window of the vehicle; a dielectric substrate that is attached to the glass; and mesh grid-like conductive patterns disposed on the dielectric substrate, wherein the mesh grid-like conductive patterns comprise: a radiator region in which a first side and a second side corresponding to an opposite side of the first side form end portions of conductive patterns such that the conductive patterns having different widths are formed in a plurality of step structures; a feed line electrically connected with the radiator region; a first ground region disposed on a first side of the feed line; and a second ground region disposed on a second side of the feed line, wherein the first ground region is formed to have a length greater than or equal to that of the second ground region in one axial direction, and wherein a first number of steps on the second side is greater than or equal to a second number of steps on the first side. 18. The antenna system for a vehicle of claim 17 , wherein at least part of the first side formed by the conductive patterns of the radiator region is formed in a liner structure, and the second side in the radiator region forms a plurality of step structures by the conductive patterns having different widths. 19. The antenna system for a vehicle of claim 17 , wherein the radiator region, the first ground region, and the second ground region constitute an antenna module, and the antenna system further comprises: a transceiver circuit operably coupled to the antenna module through the feed line, that controls the antenna module so that a radio signal in at least one of first to third bands is radiated through the antenna module; and a processor operably coupled to the transceiver circuit, and configured to control the transceiver circuit. 20. The antenna system for a vehicle of claim 19 , wherein the processor is configured to perform carrier aggregation CA or dual connectivity DC through a first antenna element and a second antenna element of the antenna module, by controlling the transceiver circuit s