A combination antenna includes a conductive block having at least one electrical component mounted on the surface. A metallic housing is connected to the conductive block via at least one electronic element having a front surface and a rear surface. The front surface includes one or more plates separated by gaps of a predetermined width. The rear surface includes a continuous plate separated from the front surface by a gap of a second predetermined width. One or more antenna feeds are disposed between the front surface and the rear surface of the metallic housing and are connected to the metallic housing directly or via the at least one electronic element. A grounding plane includes one or more grounding points connected to the front surface and the rear surface directly or via the at least one electronic element.

The invention relates to a balanced antenna system comprising a radiator connected via a matching circuit to a balun. In certain embodiments, the radiator comprises a first radiating element and a second radiating element and the matching circuit comprises a first impedance-matching circuit connected to the first radiating element and a second impedance-matching circuit connected to the second radiating element. The first and second matching circuits may be identical and are connected through the balun to a single port. To minimise the component count, the design of the matching circuit and balun is co-optimised.

The invention relates to a balanced antenna system comprising a radiator connected via a matching circuit to a balun. In certain embodiments, the radiator comprises a first radiating element and a second radiating element and the matching circuit comprises a first impedance-matching circuit connected to the first radiating element and a second impedance-matching circuit connected to the second radiating element. The first and second matching circuits may be identical and are connected through the balun to a single port. To minimise the component count, the design of the matching circuit and balun is co-optimised.

The present disclosure relates to a pre-5.sup.th-Generation (5G) or 5G communication system to be provided for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication system such as Long Term Evolution (LTE). The present invention relates to an antenna structure for signal radiation in a transmission device. An apparatus for signal radiation includes a feeding unit configured to radiate a signal, and a guiding unit, that consists of a plurality of elements physically spaced from one another, configured to adjust a radiation pattern of the signal radiated by the feeding unit by generating a radio wave in a Transverse Electric (TE) mode. Further, the present invention also includes embodiments different from the above-described embodiment.

The present disclosure relates to a pre-5.sup.th-Generation (5G) or 5G communication system to be provided for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication system such as Long Term Evolution (LTE). The present invention relates to an antenna structure for signal radiation in a transmission device. An apparatus for signal radiation includes a feeding unit configured to radiate a signal, and a guiding unit, that consists of a plurality of elements physically spaced from one another, configured to adjust a radiation pattern of the signal radiated by the feeding unit by generating a radio wave in a Transverse Electric (TE) mode. Further, the present invention also includes embodiments different from the above-described embodiment.

A multi-band antenna includes a metal backing plate, a radiating conductor, a non-conductor and a connector. The non-conductor is interleaved between the metal backing plate and the radiating conductor. The connector is connected to the metal backing plate and the radiating conductor, and the connector is configured to adjust a connection path between the metal backing plate and the radiating conductor to adjust an antenna operation band.

A communication system is provided, including one or more antennas coupled to multiple RF paths, one or more matching blocks, each block including multiple matching networks, a look-up table including characterization data according to frequency bands and conditions, and a controller configured to control the multiple matching networks by referring to the look-up table to provide optimum impedance for a frequency band selected and a condition detected during a time interval. The matching block may further include switches and adjustment circuits.

A communication system is provided, including one or more antennas coupled to multiple RF paths, one or more matching blocks, each block including multiple matching networks, a look-up table including characterization data according to frequency bands and conditions, and a controller configured to control the multiple matching networks by referring to the look-up table to provide optimum impedance for a frequency band selected and a condition detected during a time interval. The matching block may further include switches and adjustment circuits.

An antenna device includes a substrate, a first antenna element disposed on a surface of the substrate, a second antenna element disposed on the surface of the substrate, the second antenna element being a linear shape, a length of the second antenna element being shorter than twice a length of a side that determines a lowest operating frequency of the first antenna element, a grounding conductor disposed so as not to overlap with the first antenna element and the second antenna element, a feeder coupled to the first antenna element, a first switch and a second switch disposed at the feeder wire, a first matching element and a second matching element disposed between the feeder wire and the grounding conductor, respectively, a third switch configured to switch connecting states of the first antenna element and the second antenna element.

An antenna device includes a substrate, a first antenna element disposed on a surface of the substrate, a second antenna element disposed on the surface of the substrate, the second antenna element being a linear shape, a length of the second antenna element being shorter than twice a length of a side that determines a lowest operating frequency of the first antenna element, a grounding conductor disposed so as not to overlap with the first antenna element and the second antenna element, a feeder coupled to the first antenna element, a first switch and a second switch disposed at the feeder wire, a first matching element and a second matching element disposed between the feeder wire and the grounding conductor, respectively, a third switch configured to switch connecting states of the first antenna element and the second antenna element.