Antenna

What is claimed is: 1 . An antenna comprising: a radio wave deflection element formed as a plate-like member including a plurality of stacked layers, having a principal surface perpendicular to a first direction, and having a longitudinal direction in a second direction perpendicular to the first direction; and a radio wave source disposed so as to be separated from the radio wave deflection element in the first direction and offset from a center of the radio wave deflection element by a predetermined distance in the first direction, and configured to emit a radio wave to the radio wave deflection element, wherein dielectric constants of the plurality of dielectric layers decrease in a stepwise manner as a distance from the center of the radio wave deflection element increases in the first direction. 2 . The antenna according to claim 1 , wherein the plurality of dielectric layers are arranged in a nested manner from the center of the radio wave deflection element. 3 . The antenna according to claim 1 , wherein the plurality of dielectric layers are formed by stacking flat dielectric layers in the first direction. 4 . The antenna according to claim 1 , wherein a length of the radio wave deflection element in a direction perpendicular to the first and second directions is substantially equal to or shorter than a wavelength of the radio wave. 5 . The antenna according to claim 1 , further comprising a cavity cover made of conductive material and configured to cover a surface of the radio wave deflection element facing in a direction perpendicular to the first direction and a cavity, the cavity being a space between the radio wave deflection element and the radio wave source. 6 . The antenna according to claim 5 , wherein the cavity cover is formed as a box-shaped member with an opening formed on a side thereof on which the radio wave deflection element is held, and the radio wave source is provided on an inner surface of a bottom plate of the box-shaped member opposed to the opening. 7 . The antenna according to claim 6 , further comprising a prism made of dielectric and disposed so as to be in contact with the radio wave deflection element in the cavity, wherein a thickness of the prism gradually increases from a position at which the radio wave source is disposed in a receding direction from the center of the radio wave deflection element through the center thereof. 8 . The antenna according to claim 1 , wherein the radio wave deflection element is formed as a planar Luneburg lens, the planar Luneburg lens being obtained by compressing an ideal spherical Luneburg lens in the first direction. 9 . The antenna according to claim 8 , wherein the radio wave deflection element is formed by cutting out a part of the planar Luneburg lens so as to have a predetermined width in a direction perpendicular to the first and second directions. 10 . The antenna according to claim 8 , wherein when a radius of the ideal spherical Luneburg lens is represented by R; compressibility of the radio wave deflection element to the ideal spherical Luneburg lens is represented by δ; a coordinate in the receding direction from the center of the radio wave deflection element in the first direction is represented by z; a dielectric constant of dielectric material of which the radio wave deflection element is made at a z-coordinate is represented by ε z ; and a wavelength of a radio wave emitted from the radio wave source is 28.5 GHz±1.0 GHz, a below-shown expression holds for the z-coordinate: [ Expression ⁢ 1 ]  z = δ ⁢ 2 - ε z * δ R , [ 1 ] and dielectric constants of the plurality of dielectric layers in the first direction are defined by points discretely set on a curve represented by Expression [1]. 11 . The antenna according to claim 10 , wherein based on Expression [1], when in a graph of which a vertical axis indicates z-coordinates and a horizontal axis indicates dielectric constants ε x at z-coordinates of the dielectric material, the number of dielectric layers stacked in the receding direction from the center of the radio wave deflection element in the first direction is represented by N, a dielectric constant and a length in the first direction of each of N dielectric layers are determined so that: in the horizontal axis, z-coordinates of N−1 points at which a region between an origin of the graph and an intersection of the curve and the horizontal axis is divided into N sections respectively become coordinates of boundaries of second to N-th dielectric layers as viewed from the center of the radio wave deflection element, the boundary of each dielectric layer being on a side thereof far from the center of the radio wave deflection element; and a z-coordinate of a point included in a predetermined range including, among z-coordinates of three points corresponding to coordinates on the horizontal axis at which a region between a point having a minimum z-coordinate among the N−1 points and the intersection of the curve and the horizontal axis is divided into four sections, a point having a minimum z-coordinate becomes a z-coordinate of a boundary between a first dielectric layer and a second dielectric layer as viewed from the center of the radio wave deflection element. 12 . The antenna according to claim 11 , wherein when a maximum value of a dielectric constant is represented by ε max ; a coordinate in a receding direction from the center of the radio wave deflection element in the second direction is represented by x; and a dielectric constant of an x-coordinate of dielectric material of which the radio wave deflection element is made is represented by ε x , a below-shown Expression holds for the x-coordinate: [ Expression ⁢ 2 ]  x =