In a meta-structure having multifunctional properties according to an exemplary embodiment of the present invention, a plurality of unit blocks controlling a property of a wave is combined on a plane or in a space in a predetermined pattern to form one structure, at least one of the plurality of unit blocks is formed to have a different size, and a frequency range of a wave controlled is changed according to the size of the unit block.

In a meta-structure having multifunctional properties according to an exemplary embodiment of the present invention, a plurality of unit blocks controlling a property of a wave is combined on a plane or in a space in a predetermined pattern to form one structure, at least one of the plurality of unit blocks is formed to have a different size, and a frequency range of a wave controlled is changed according to the size of the unit block.

A system for forming a beam includes one or more wave sources; one or more surface scattering antennas (for example, one or more holographic metasurface antennas) coupled to the one or more wave sources, wherein each of the one or more surface scattering antennas comprises an array of scattering elements that are dynamically adjustable in response to one or more waves provided by the one or more wave sources to produce a beam; and a beam shaper configured to receive the beam from each of the one or more surface scattering antennas and to redirect the beam, preferably, with gain.

A system for forming a beam includes one or more wave sources; one or more surface scattering antennas (for example, one or more holographic metasurface antennas) coupled to the one or more wave sources, wherein each of the one or more surface scattering antennas comprises an array of scattering elements that are dynamically adjustable in response to one or more waves provided by the one or more wave sources to produce a beam; and a beam shaper configured to receive the beam from each of the one or more surface scattering antennas and to redirect the beam, preferably, with gain.

A system for forming a beam includes one or more wave sources; one or more surface scattering antennas (for example, one or more holographic metasurface antennas) coupled to the one or more wave sources, wherein each of the one or more surface scattering antennas comprises an array of scattering elements that are dynamically adjustable in response to one or more waves provided by the one or more wave sources to produce a beam; and a beam shaper configured to receive the beam from each of the one or more surface scattering antennas and to redirect the beam, preferably, with gain.

A system for forming a beam includes one or more wave sources; one or more surface scattering antennas (for example, one or more holographic metasurface antennas) coupled to the one or more wave sources, wherein each of the one or more surface scattering antennas comprises an array of scattering elements that are dynamically adjustable in response to one or more waves provided by the one or more wave sources to produce a beam; and a beam shaper configured to receive the beam from each of the one or more surface scattering antennas and to redirect the beam, preferably, with gain.

A radio frequency (RF) communications system may include a local RF communications device and an RF antenna coupled to the local RF communications device. The RF antenna may include a cavity backing housing, a conical RF launch structure having an apex positioned within the cavity backing housing, and an elongate electrical conductor having a proximal end extending through the apex of the conical RF launch structure and a distal end spaced apart from the conical RF launch structure to define an elongate RF coverage pattern. The system may further include at least one remote RF communications device within the elongate RF coverage pattern to wirelessly communicate with the local RF communications device.

A radio frequency (RF) communications system may include a local RF communications device and an RF antenna coupled to the local RF communications device. The RF antenna may include a cavity backing housing, a conical RF launch structure having an apex positioned within the cavity backing housing, and an elongate electrical conductor having a proximal end extending through the apex of the conical RF launch structure and a distal end spaced apart from the conical RF launch structure to define an elongate RF coverage pattern. The system may further include at least one remote RF communications device within the elongate RF coverage pattern to wirelessly communicate with the local RF communications device.

An electronic device is provided. The electronic device includes a sensor, an antenna, a positioning circuit configured to receive satellite signals through the antenna using a specified frequency band, a resonant frequency adjustment circuit configured to adjust a resonant frequency of the antenna, and a processor, wherein the processor is configured to, identify whether the electronic device is in water using the sensor, when the electronic device is not in water, adjust the resonant frequency to a first frequency band specified according to a first permittivity of air in relation to the specified frequency band using the resonant frequency adjustment circuit, when the electronic device is in water, adjust the resonant frequency of the antenna to a second frequency band specified according to a second permittivity of water in relation to the specified frequency band using the resonant frequency adjustment circuit, receive the satellite signals through the antenna of which the resonant frequency has been adjusted to a frequency band corresponding to one of the first frequency band and the second frequency band using the positioning circuit; and determine a position of the electronic device primarily on the basis of the received satellite signals using the positioning circuit.

An electronic device is provided. The electronic device includes a sensor, an antenna, a positioning circuit configured to receive satellite signals through the antenna using a specified frequency band, a resonant frequency adjustment circuit configured to adjust a resonant frequency of the antenna, and a processor, wherein the processor is configured to, identify whether the electronic device is in water using the sensor, when the electronic device is not in water, adjust the resonant frequency to a first frequency band specified according to a first permittivity of air in relation to the specified frequency band using the resonant frequency adjustment circuit, when the electronic device is in water, adjust the resonant frequency of the antenna to a second frequency band specified according to a second permittivity of water in relation to the specified frequency band using the resonant frequency adjustment circuit, receive the satellite signals through the antenna of which the resonant frequency has been adjusted to a frequency band corresponding to one of the first frequency band and the second frequency band using the positioning circuit; and determine a position of the electronic device primarily on the basis of the received satellite signals using the positioning circuit.