Array antenna apparatus and communication device

1 . An array antenna apparatus comprising: a dielectric substrate; a plurality of radiation conductors formed on a first plane of the dielectric substrate; a first ground conductor formed on portions of the first plane of the dielectric substrate at locations that surround the plurality of radiation conductors and that create clearances between the plurality of radiation conductors; a second ground conductor formed on a portion of a second plane of the dielectric substrate at a location opposite to the first ground conductor; a plurality of connecting conductors each provided inside the dielectric substrate in such a manner that one end of the connecting conductor is connected to the first ground conductor and another end of the connecting conductor is connected to the second ground conductor, a location of the one end connected to the first ground conductor being a location that surrounds any one of the plurality of radiation conductors; a dielectric layer having one surface bonded to the second plane of the dielectric substrate and the second ground conductor; and a feeding substrate having one surface bonded to another surface of the dielectric layer, the feeding substrate electromagnetically coupling radio waves to the plurality of radiation conductors through the dielectric layer and the dielectric substrate. 2 . The array antenna apparatus according to claim 1 , wherein the dielectric substrate is a multi-layer substrate having a plurality of dielectric substrates stacked on top of each other. 3 . The array antenna apparatus according to claim 2 , wherein each of the plurality of radiation conductors formed on the first plane is a first radiation conductor, and second radiation conductors are formed one by one at locations between the plurality of dielectric substrates included in the multi-layer substrate, the locations opposite to the respective plurality of first radiation conductors. 4 . The array antenna apparatus according to claim 1 , wherein when a layer thickness of the dielectric layer is h, free-space wavelength is λ 0 , and a dielectric constant of the dielectric layer is ε r , a following inequality holds true for the layer thickness h. h ≤ 0.3 ⁢ λ 0 2 ⁢ π ⁢ ϵ r [ Inequality ] 5 . The array antenna apparatus according to claim 1 , wherein an arrangement of the plurality of radiation conductors on the first plane of the dielectric substrate is a square arrangement. 6 . The array antenna apparatus according to claim 1 , wherein an arrangement of the plurality of radiation conductors on the first plane of the dielectric substrate is a triangular arrangement. 7 . The array antenna apparatus according to claim 1 , wherein an arrangement of the plurality of radiation conductors on the first plane of the dielectric substrate is a non-periodic arrangement. 8 . The array antenna apparatus according to claim 1 , wherein the feeding substrate includes a line for electromagnetically coupling radio waves to the respective plurality of radiation conductors. 9 . A communication device comprising: an array antenna apparatus to transmit and receive radio waves; and a communicator to output an electrical signal corresponding to a transmission-target radio wave to the array antenna apparatus, and collect electrical signals corresponding to radio waves received by the array antenna apparatus, wherein the array antenna apparatus includes: a dielectric substrate; a plurality of radiation conductors formed on a first plane of the dielectric substrate; a first ground conductor formed on portions of the first plane of the dielectric substrate at locations that surround the plurality of radiation conductors and that create clearances between the plurality of radiation conductors; a second ground conductor formed on a portion of a second plane of the dielectric substrate at a location opposite to the first ground conductor; a plurality of connecting conductors each provided inside the dielectric substrate in such a manner that one end of the connecting conductor is connected to the first ground conductor and another end of the connecting conductor is connected to the second ground conductor, a location of the one end connected to the first ground conductor being a location that surrounds any one of the plurality of radiation conductors; a dielectric layer having one surface bonded to the second plane of the dielectric substrate and the second ground conductor; and a feeding substrate having one surface bonded to another surface of the dielectric layer, the feeding substrate electromagnetically coupling radio waves to the plurality of radiation conductors through the dielectric layer and the dielectric substrate.