WiGig Antenna
WiGig Antenna subsystem would require 25% fractional bandwidth.
The antenna subsystem module would be comprised of apertures, feeding and impedance matching networks.
The more sophisticated antenna subsystem could even have dynamic impedance and aperture matching network which are tailored for the used channel on the fly.
Advanced 5G or even 6G wireless systems will support holographic 3D connectivity for virtual reality, which requires 10’s of Gbps connection.
The access points will be local and available at designated location where virtual reality services are supported.
This technology will be relying on both beamforming and MIMO.
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6G Multi Antenna Technology
6G would follow 5G multi antenna technology with some changes.
5G mmW has not been universally accepted terrestrial radio communication platform of choice.
The reason for 5G mmW delayed implementation is capital cost, CAPEX entrance threshold. The cost of beamforming ASIC and mmW antennas are BOM differentiators compare to 4G and previous terrestrial radio communication 3GPP standards.
The number of gNB would increase in 6G as the cellular area is function of electrical length. Another way put, as the frequency increases, the wavelength decreases, and the cell area in wavelength remain the same.
ORTENGA provides structured engineering leadership across antenna architecture, realization planning, integration, and deployment validation to reduce downstream realization risk and improve alignment between engineering execution and business objectives.