Abstract: A device includes a first housing having a first end configured to couple to an electric meter and a second end configured to couple to an electric meter socket. A power module is disposed at least partially within the first housing and is configured to couple to electrical wiring at a premises. The device includes a second housing having an antenna array, a feed network communicatively coupled to the power module and configured to split power and distribute the power to at least one element of one or more sub-arrays of the antenna array, a wireless wide area network (WWAN) module communicatively coupled to the antenna array and the power module, and a broadband over powerline (BPL) interface communicatively coupled to the WWAN module and the power module.

Abstract: A device includes a modem having a first feed port and a second feed port. A first planar dual-polarized sub-array has a first beamwidth and includes a first orthogonally polarized element communicatively coupled to the first feed port and a second orthogonally polarized element communicatively coupled to the second feed port. A second planar dual-polarized sub-array has a second beamwidth and includes a third orthogonally polarized element communicatively coupled to the second feed port and a fourth orthogonally polarized element communicatively coupled to the first feed port. The first dual-polarized sub-array and the second planar dual-polarized sub-array generate a collective beamwidth that exceeds the first beamwidth and the second beamwidth.

Abstract: A device includes a first housing having a first end configured to couple to an electric meter and a second end configured to couple to an electric meter socket. A power module is disposed at least partially within the first housing and is configured to couple to electrical wiring at a premises. The device includes a second housing having an antenna array, a feed network communicatively coupled to the power module and configured to split power and distribute the power to at least one element of one or more sub-arrays of the antenna array, a wireless wide area network (WWAN) module communicatively coupled to the antenna array and the power module, and a broadband over powerline (BPL) interface communicatively coupled to the WWAN module and the power module.

Abstract: An electronic device includes a first housing including a power module and a second housing coupled to the first housing. The second housing includes a first antenna communicatively coupled to the power module, and oriented in a first direction. The second housing further includes a second antenna communicatively coupled to the power module, and oriented in a second direction that is different than the first direction. At least one printed circuit board (PCB) is disposed in the second housing and communicatively coupled to the power module, the first antenna, and the second antenna A modem module resides within the second housing and communicatively couples to the power module, the first antenna, the second antenna, and the at least one PCB. An interface resides within the second housing and communicatively couples to the power module, the first antenna, the second antenna, the at least one PCB, and the modem module.

Abstract: A device includes a modem having a first feed port and a second feed port. A first planar dual-polarized sub-array has a first beamwidth and includes a first orthogonally polarized element communicatively coupled to the first feed port and a second orthogonally polarized element communicatively coupled to the second feed port. A second planar dual-polarized sub-array has a second beamwidth and includes a third orthogonally polarized element communicatively coupled to the second feed port and a fourth orthogonally polarized element communicatively coupled to the first feed port. The first dual-polarized sub-array and the second planar dual-polarized sub-array generate a collective beamwidth that exceeds the first beamwidth and the second beamwidth.

Abstract: An electronic device includes a first housing including a power module and a second housing coupled to the first housing. The second housing includes a first antenna communicatively coupled to the power module, and oriented in a first direction. The second housing further includes a second antenna communicatively coupled to the power module, and oriented in a second direction that is different than the first direction. At least one printed circuit board (PCB) is disposed in the second housing and communicatively coupled to the power module, the first antenna, and the second antenna A modem module resides within the second housing and communicatively couples to the power module, the first antenna, the second antenna, and the at least one PCB. An interface resides within the second housing and communicatively couples to the power module, the first antenna, the second antenna, the at least one PCB, and the modem module.

Abstract: A concealed antenna node for mounting on a street pole comprises an antenna with an associated radio module which are pre-wired together and housed within a radome of the concealed antenna node. The antenna comprises a plurality of antenna columns arranged about a central section within which the radio module is located. The antenna columns are arranged in a spaced-apart formation such that a gap is realised between adjacent antenna columns.

Abstract: The present invention is directed towards a Multiple-Input Multiple-Output (MIMO) omnidirectional antenna. The Multiple-Input Multiple-Output (MIMO) omnidirectional antenna comprising three or more column sets, where the three or more column sets are arranged in a centrosymmetric arrangement about a centre point of the antenna. Each column set comprises two or more antenna columns and each of the antenna columns mounts a plurality of radiators thereon. Each antenna column receives no more than two signals to be transmitted, and, each of the antenna columns is arranged to be axisymmetric about a radially-directed axis created between the centre point of the antenna and a transverse cross-sectional midpoint on the antenna column. Therefore, each radiation pattern established by each of the three or more column sets is centrosymmetric about the centre point of the antenna, and, is axisymmetric about the radially-directed axis.

Abstract: The present invention is directed towards a Multiple-Input Multiple-Output (MIMO) omnidirectional antenna. The Multiple-Input Multiple-Output (MIMO) omnidirectional antenna comprising three or more column sets, where the three or more column sets are arranged in a centrosymmetric arrangement about a centre point of the antenna. Each column set comprises two or more antenna columns and each of the antenna columns mounts a plurality of radiators thereon. Each antenna column receives no more than two signals to be transmitted, and, each of the antenna columns is arranged to be axisymmetric about a radially-directed axis created between the centre point of the antenna and a transverse cross-sectional midpoint on the antenna column. Therefore, each radiation pattern established by each of the three or more column sets is centrosymmetric about the centre point of the antenna, and, is axisymmetric about the radially-directed axis.

Abstract: The present invention is directed towards a Multiple-Input Multiple-Output (MIMO) omnidirectional antenna. The Multiple-Input Multiple-Output (MIMO) omnidirectional antenna comprising three or more column sets, where the three or more column sets are arranged in a centrosymmetric arrangement about a centre point of the antenna. Each column set comprises two or more antenna columns and each of the antenna columns mounts a plurality of radiators thereon. Each antenna column receives no more than two signals to be transmitted, and, each of the antenna columns is arranged to be axisymmetric about a radially-directed axis created between the centre point of the antenna and a transverse cross-sectional midpoint on the antenna column. Therefore, each radiation pattern established by each of the three or more column sets is centrosymmetric about the centre point of the antenna, and, is axisymmetric about the radially-directed axis.

Abstract: The present invention relates to a Multiple-Input Multiple-Output (MIMO) omnidirectional antenna comprising three or more column sets arranged in a centrosymmetricly. Each column set comprises two or more antenna columns, each having a plurality of radiators mounted thereon. Each antenna column receives no more than two signals to be transmitted, and is arranged axisymmetricly about a radially-directed axis created between the center point of the antenna and a transverse cross-sectional midpoint on the antenna column. Therefore, each radiation pattern established by each of the three or more column sets is centrosymmetric about the center point of the antenna and axisymmetric about the radially-directed axis. The MIMO omnidirectional antenna can fit within a radome of small diameter, while providing relatively uniform radiation plot coverage across a microcell where it is deployed. As no phase shifting is utilized, there is little ripple effect and all of the ports have a similar gain.

Abstract: A concealed antenna node for mounting on a street pole comprises an antenna with an associated radio module which are pre-wired together and housed within a radome of the concealed antenna node. The antenna comprises a plurality of antenna columns arranged about a central section within which the radio module is located. The antenna columns are arranged in a spaced-apart formation such that a gap is realised between adjacent antenna columns.

Abstract: The present invention relates to a Multiple-Input Multiple-Output (MIMO) omnidirectional antenna comprising three or more column sets arranged in a centrosymmetricly. Each column set comprises two or more antenna columns, each having a plurality of radiators mounted thereon. Each antenna column receives no more than two signals to be transmitted, and is arranged axisymmetricly about a radially-directed axis created between the centre point of the antenna and a transverse cross-sectional midpoint on the antenna column. Therefore, each radiation pattern established by each of the three or more column sets is centrosymmetric about the centre point of the antenna and axisymmetric about the radially-directed axis. The MIMO omnidirectional antenna can fit within a radome of small diameter, while providing relatively uniform radiation plot coverage across a microcell where it is deployed. As no phase shifting is utilised, there is little ripple effect and all of the ports have a similar gain.