In order to improve the information processing efficiency and the multi-task processing capabilities of the metasurfaces, researchers have developed and designed a kind of dual-polarized metasurfaces that can respond to electromagnetism differentially under different polarizations and thus provide two independent information channels in parallel. Compared to the single-polarized metasurfaces, the dual-polarized metasurfaces can achieve muchmore complex functions, such as multi-channel information processing, polarization division multiplexing and dual-polarized caliber sharing. Inthis sense, the dual-polarized metasurfaces can realize more advanced functional devices. However, the current dual-polarized metasurfaces are static or can only be slightly adjustable, as a result, their functions cannot be switched by real-time programming, which has greatly limited their versatility and application to ultrafast switching and scanning systems.
In order to solve the above problem, the researchers designed a kind of dual-programmable metasurfaces that can independently regulate the x-polarized and y-polarized electromagnetic waves. To this end, the researchers first carefully designed a kind of active metasurface units capable for independently regulating the reflection phase of x-polarized and y-polarized electromagnetic waves. Such active metasurface units feature a specially designed metal pattern and integrate two varactors in the x direction and the y direction respectively. And the capacitance of such two varactors can be independently regulated at these two directions via two bias lines as designed so as to control the reflection phase of the x-polarized and y-polarized electromagnetic waves independently. In order to obtain the dual-programmable metasurfaces and implement multiple complex electromagnetic functions, the researchers adopted 24x24 metasurface units to form an array that contained 48 independent control interfaces. In order to effectively control the dual-programmable metasurfaces containing multiple independent control interfaces via a single FPGA, the researchers further designed and implemented an extended interface circuit and a DC voltage conversion circuit, the former of which, mainly composed of a decoder and a latch, can greatly expand few FPGA interfaces in an exponential manner. Meanwhile, the voltage conversion circuit, mainly composed of transistors and resistors, can convert the voltage output from the FPGA to the bias voltage as demanded by the varactors in the dual-programmable metasurfaces. In this way, the dual-programmable metasurface platform as finally developed features rich programmability and can realize multiple complex electromagnetic functions. As demonstrated in the experiment, the researchers have experimentally verified three different electromagnetic functions on a single platform for XOR logic operations controlled by spinning of circularly polarized waves, fixed-frequency large-angle dual-beam scanning and dual-polarized caliber sharing respectively. Thus such dual-programmable metasurfaces have provided a new technological solution to develop large-scale, highly-integrated electromagnetic devices and systems; in addition, they are expected to be applied to advanced devices and systems such as wave-based logic computing platforms, high-speed scanning radars and multi-channel spatial light processors, etc..
Submitted by: School of Information Science and Engineering
(Editor-in-charge: Wu Hanyu, reviewed by: Song Yechun)