Single feed and dual polarization antenna

What is claimed is: 1 . An antenna, comprising: a substrate comprising a magnetodielectric material; and an electromagnetic, EM, radiator comprising an electrically conductive material disposed on an upper surface of the substrate, the EM radiator including a plurality of chamfered sides extending contiguously from one another to define an octagon-shaped EM radiator. 2 . The antenna of claim 1 , wherein: the substrate extends from a first substrate end to an opposing second substrate end parallel to first axis, X-axis, to define a substrate length, Subx, and extends from a third substrate end to a fourth substrate end parallel to the second axis, Y-axis, to define a substrate width, Suby, and further extends from a lower substrate surface to an upper substrate surface parallel to the third axis, Z-axis, to define a substrate thickness, Subz; wherein the X, Y, and Z, axes form an orthogonal X-Y-Z coordinate system. 3 . The antenna of claim 1 , wherein the antenna is a patch antenna. 4 . The antenna of claim 1 , wherein the magnetodielectric material comprises hexagonal ferrite particles and PTFE or PPS polymer. 5 . The antenna of claim 4 , wherein the hexagonal ferrite material includes Z-type (Co2Z), or Y-type (Co2Y) hexaferrite. 6 . The antenna of claim 1 , wherein the substrate is a single layer comprising the magnetodielectric material. 7 . The antenna of claim 1 , wherein the EM radiator defines a chamfer function based on the plurality of chamfered sides. 8 . The antenna of claim 7 , wherein the chamfer function utilizes a vertex of the EM radiator as a reference point and removes metallic portions of the EM radiator to achieve edge truncation of the EM radiator to define the chamfered sides, which control radiating modes of the EM radiator at specific frequencies. 9 . The antenna of claim 8 , wherein adjusting the chamfer function increases or decreases an effective aperture of the EM, radiator for a specific frequency. 10 . The antenna of claim 1 , wherein the plurality of chamfered sides includes: a first chamfered side arranged adjacent to the third substrate end; a second chamfered side arranged opposite and parallel to the first chamfered side and adjacent to the fourth substrate end, the first and second chamfered sides extending parallel to the first axis, X-axis, to define a first side length, L1; a third chamfered side arranged adjacent to the first substrate end; a fourth chamfered side arranged opposite and parallel to the third chamfered side and adjacent to the second substrate end, the third and fourth chamfered sides extending parallel to the second axis, Y-axis, to define a second side length, L2; a fifth chamfered side extending from the first chamfered side to the third chamfered side at a distance defining a third side length, L3; a sixth chamfered side arranged opposite and parallel to the fifth chamfered side and extending from the second chamfered side to the fourth chamfered side at the distance defining the third side length, L3; a seventh chamfered side extending from the first chamfered side to the fourth chamfered side at a distance defining a fourth side length, L4; and an eighth chamfered side arranged opposite and parallel to the seventh chamfered side and extending from the third chamfered side to the second chamfered side at the distance defining the fourth side length, L4. 11 . The antenna of claim 10 , wherein a combination of the first side length L1, the second side length L2 and the third side length L3 controls an operating performance of the antenna 102 in the L2 and L5 bands, and the fourth side length L4 controls the operating performance of the antenna in the L1 band. 12 . The antenna of claim 11 , wherein: the first side length, L1, and the second side length, L2, are greater than the third side length, L3; and wherein the fourth side length, L4, is greater than the first side length, L1, the second side length, L2, and the third side length, L3. 13 . The antenna of claim 10 , wherein: the first chamfered side and the second chamfered side are each located a first distance, C_L1 Distance , away from the center point, C; the third chamfered side and the fourth chamfered side are each located a second distance, C_L2 Distance , away from the center point, C; the fifth chamfered side and the sixth chamfered side are each located a third distance, C_L3 Distance , away from the center point, C; and the seventh chamfered side and the eighth chamfered side are each located a fourth distance, C_L4 Distance , away from the center point, C. 14 . The antenna of claim 1 , wherein the substrate includes a permittivity of (ε), equal to or greater than 2.0 and equal to or less than 7.0, and a permeability (μ) equal to or greater than 0.5 and equal to or less than 3. 15 . The antenna of claim 1 , wherein the substrate has a loss tangent parameter (tan δ) equal to or greater than 0.001 and equal to or less than 0.015, and a magnetic loss tangent (tan μ) equal to or greater than 0.01 and equal to or less than 0.09. 16 . An antenna assembly, comprising: the antenna of claim 1 , and further comprising: a host board including an upper dielectric surface and a lower dielectric surface located opposite the upper dielectric surface, wherein the substrate is disposed on the upper dielectric surface. 17 . The antenna assembly of claim 16 , further comprising an electrically conductive via extending through the EM radiator, the substrate, and the host board, the via configured to establish electrical conductivity with the EM radiator and the substrate. 18 . The antenna assembly of claim 1 , wherein the antenna is operational over at least three frequency bands. 19 . The antenna assembly of claim 18 , wherein the antenna is operational to discriminate frequencies between individual ones of the at least three frequency bands. 20 . The antenna assembly of claim 18 , wherein a first of the at least three frequency bands is a L5 band. 21 . The antenna assembly of claim 18 , wherein a second of the at least three frequency bands is a L2 band. 22 . The antenna assembly of claim 18 , wherein a third of the at least three frequency bands is a L1 band. 23 . The antenna assembly of claim 1 , wherein the antenna is operational with a gain equal to or greater than 3 dBi at each respective operational band. 24 . The antenna assembly of claim 1 , wherein the antenna is operational with an axial ratio equal to or less than 6 dBi, alternatively equal to or less than 3 dBi, at +/−30-degrees from each radiation boresight of the antenna. 25 . The antenna assembly of claim 1 , wherein the antenna is operational with right-hand-circular-polarization. 26 . The antenna assembly of claim 22 , wherein the antenna is operational with an efficiency greater than 60% within one or more of the L1 band, the L2 band, and the L5 band. 27 . The antenna assembly of claim 1 , wherein the antenna is operational at a broad axial ratio bandwidth at 3 dBi of equal to or greater than 10 MHz.