Abstract
We propose a technique for adaptive multichannel communication in the low-terahertz frequency regime through simultaneous and independent multifrequency multibeam scanning via a single time-modulated metasurface consisting of graphene micro-patch antennas whose Fermi energy levels are modulated by radio-frequency biasing signals. For this purpose, we divide the metasurface aperture into interleaved orthogonally modulated sub-array antennas with distinct modulation frequencies, rendering a shared aperture in space-time. The higher-order frequency harmonics generated by the sub-arrays in such a space-time shared-aperture metasurface are mutually orthogonal as they do not yield an observable interference pattern. A distinct constant progressive modulation phase delay can be adopted in each sub-array to independently scan its corresponding higher-order frequency harmonics via dispersionless modulation-induced phase gradient with minimal sidelobe level and full angle-of-view over a wide bandwidth. The number of sub-arrays and distinct channels can be scaled easily without suffering from cross-talk due to orthogonality of the channels. The concept is established theoretically and verified through numerical simulations. We characterize active beam-scanning performance of the space-time shared aperture metasurface in terms of gain and half power beamwidth and their dependence to the array architecture. We consider both one-dimensional and two-dimensional interleaving for scanning the beams along elevation and azimuth angles. We also obtain the upper bounds for the number of independent channels attainable without compromising angle-of-view as 8 and 64 for one-dimensional and two-dimensional interleaving, respectively within the same physical aperture. Our results point toward high-capacity platforms with low size, weight and power for next generations of terahertz communication systems.
Highlights
The unprecedented growth of the data exchanged between wireless devices and the rapid emergence of high quality wireless services have raised the demand for the communication bandwidth and data transmission rates
ORTHOGONALITY CONDITION AND CROSS-TALK EFFECTS In this subsection, we investigate the conditions for the orthogonality of the channels established by distinct sub-arrays in a 1D-interleaved space-time shared aperture metasurfaces (STSAM) and explore the cross-talk effects between them induced by the undesired frequency mixing products
In conclusion, we have introduced the concept of space-time shared aperture metasurfaces (STSAM) consisting of orthogonally modulated sub-array antennas interleaved within the same physical area
Summary
The unprecedented growth of the data exchanged between wireless devices and the rapid emergence of high quality wireless services have raised the demand for the communication bandwidth and data transmission rates. This has motivated the migration of wireless networks toward utilization of carrier waves with higher frequencies beyond millimeter wave band for data collection and transmission which can offer larger bandwidth and higher speeds. THz communications are expected to enable backhaul interconnection between existing networks as well as providing broadband services to several wireless devices in a distributed local network [1], [2] The latter is of particular importance in wireless internet of things applications [3] where there is a need for new communication paradigms capable of simultaneously addressing multiple mobiles users in real-time with potentially independent services.
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