Beam scanning apparatus and optical apparatus including the same

What is claimed is: 1. A beam scanning apparatus comprising: a rotary meta lens comprising a plurality of meta areas, each of the plurality of meta areas comprising a plurality of fine phase shift elements arranged therein; and a rotation drive device configured to rotate the rotary meta lens, wherein a first meta area of the plurality of meta areas is configured to direct light transmitted therethrough to a first location within a scanning area and a second meta area of the plurality of meta areas is configured to direct light transmitted therethrough to a second location within the scanning area, different from the first location, wherein the rotary meta lens comprises a transparent substrate having a disc shape, and the plurality of meta area are arranged in a circumferential direction of the substrate, wherein the plurality of meta areas are a plurality of inner meta areas, each disposed at a first radial distance of the transparent substrate, and the rotary meta lens further comprises a plurality of outer meta areas, each disposed at a second radial distance of the transparent substrate, different from the first radial distance of the transparent substrate, and wherein the beam scanning apparatus further comprises a first light source facing to the first radial distance of the transparent substrate and a second light source facing to the second radial distance of the transparent substrate. 2. The beam scanning apparatus of claim 1 , wherein an arrangement of the plurality of fine phase shift elements in the first meta area is different from an arrangement of the plurality of fine phase shift elements in the second meta area. 3. The beam scanning apparatus of claim 2 , wherein each of the plurality of fine phase shift elements comprises a column arranged on the transparent substrate and each of the plurality of fine phase shift elements has a refractive index that is higher than a refractive index of the transparent substrate. 4. The beam scanning apparatus of claim 2 , wherein each of the plurality of meta areas comprises a first sub-area and a second sub-area, each of the first sub-area and the second sub-area comprising a same arrangement of the plurality of fine phase shift elements. 5. The beam scanning apparatus of claim 4 , wherein a period of the first sub-area and the second sub-area is different for each of the plurality of meta areas. 6. The beam scanning apparatus of claim 1 , wherein the plurality of meta areas are configured such that light transmitted through the plurality of meta areas is directed to a plurality of scanning positions that are uniformly distributed within the scanning area. 7. The beam scanning apparatus of claim 1 , wherein the plurality of meta areas are configured such that light transmitted through the plurality of meta areas is directed to a plurality of scanning positions within the scanning area, wherein a distribution density of the plurality of scanning positions in a central part of the scanning area is higher than a distribution density of the plurality of scanning positions in a peripheral part of the scanning area. 8. The beam scanning apparatus of claim 1 , wherein the rotation drive device is a first rotation device, and the beam scanning apparatus further comprises: a polygon mirror that reflects light transmitted through the rotary meta lens and scans the light in one direction; and a second rotation drive device that rotates the polygonal mirror. 9. The beam scanning apparatus of claim 1 , wherein the rotary meta lens is a first rotary meta lens and the rotation drive device is a first rotation drive device, and the beam scanning apparatus further comprises: a second rotary meta lens that is configured to change a traveling direction of light transmitted through the second rotary meta lens; and a second rotation drive device that rotates the second rotary meta lens. 10. The beam scanning apparatus of claim 9 , wherein the second rotary meta lens comprises a second plurality of meta areas, each of the second plurality of meta areas comprising a plurality of fine phase shift elements arranged therein, and the second plurality of meta areas of the second rotary meta lens are configured to direct light transmitted therethrough to different locations within a scanning area. 11. The beam scanning apparatus of claim 1 , further comprising a mirror that reflects light transmitted through the plurality of meta areas, wherein the mirror comprises a reflective surface inclined at about 45 degrees with respect to a rotation axis of the rotary meta lens. 12. An optical apparatus comprising: a light source; a beam scanning apparatus that scans light emitted from the light source; and a photodetector that senses light emitted from the light source and reflected from an external object, wherein the beam scanning apparatus comprises: a rotary meta lens comprising a plurality of meta areas, each of the plurality of meta areas comprising plurality of fine phase shift elements arranged therein; and a rotation drive device configured to rotate the rotary meta lens, wherein a first meta area of the plurality of meta areas is configured to direct light transmitted there through to a first location within a scanning area and a second meta area of the plurality of meta areas is configured to direct light transmitted therethrough to a second location within the scanning area, wherein the rotary meta lens comprises a transparent substrate having a disc shape, and the plurality of meta areas are arranged in a circumferential direction of the substrate, wherein the plurality of meta areas are a plurality of inner meta areas, each disposed at a first radial distance of the transparent substrate, and the rotary meta lens further comprises a plurality of outer meta areas, each disposed at a second radial distance of the transparent substrate, different from the first radial distance of the transparent substrate, and wherein the light source comprises a first light source facing to the first radial distance of the transparent substrate and a second light source facing to the second radial distance of the transparent substrate. 13. The optical apparatus of claim 12 , further comprising a beam splitter, disposed between the light source and the rotary meta lens, wherein the beam splitter transmits the light emitted from the light source to the rotary meta lens and transmits or reflects light reflected from an external object to the photodetector. 14. The optical apparatus of claim 12 , further comprising a calculator that calculates information about a location of an external object, based on a measurement result of the photodetector. 15. The optical apparatus of claim 12 , wherein an arrangement of the plurality of fine phase shift elements in the first meta area is different from an arrangement of the plurality of fine phase shift elements in the second meta area. 16. The optical apparatus of claim 12 , wherein each of the plurality of fine phase shift elements comprises a column arranged on the transparent substrate and each of the plurality of fine phase shift elements has a refractive index that is higher than a refractive index of the transparent substrate. 17. The optical apparatus of claim 12 , wherein the plurality of meta areas are additionally arranged in a radial direction of the substrate. 18. The optical apparatus of claim 12 , wherein the rotation drive device is a first rotation device, and the beam scanning apparatus further comprises: a polygon mirror that reflects light transmitted through the rot