image: The metasurface platform is realized by integrating a high-speed and high-sensitivity photoelectric detection circuit into the back of a programmable microwave metasurface, where the reflection spectrum of metasurface can be manipulated by the light in real time, thus realizing the direct light-to-microwave signal conversion. By further using the dispersion characteristics of the metasurface, one designed light intensity signal can be converted directly to two different microwave signals. With this metasurface-enabled transmitter, a dual-channel light-to-microwave wireless link is built up, in which two different videos can be transmitted and received simultaneously and independently. view more
Credit: by Xin Ge Zhang, Ya Lun Sun, Bingcheng Zhu, Wei Xiang Jiang, Qian Yu, Han Wei Tian, Cheng-Wei Qiu, Zaichen Zhang, and Tie Jun Cui
Today, wireless communications play an increasingly important role in our daily lives. For future “freewheeling” sixth generation (6G) wireless communications, the hybrid communication systems that can exploit advantages of both optical and microwave wireless technologies are critical. However, the traditional hybrid communication systems typically require a complicated relay to perform multiple operations, which will consume additional hardware/time/energy resources. Hence, this solution will make eventually the hybrid systems with high cost and high complexity.
In a new paper published in Light Science & Application, a team of scientists, led by Professors Wei Xiang Jiang and Tie Jun Cui from State Key Laboratory of Millimeter Waves, School of Information Science and Engineering, Southeast University, China, and co-workers have developed a light-to-microwave transmitter based on the optically programmed time-varying metasurface for hybrid wireless communications. Such a metasurface transmitter is able to convert the light signal to the microwave domain directly, without using down-conversion process to baseband. More interestingly, a single designed light signal can be converted to two microwave signals by using the dispersion characteristics of the metasurface. Based on the light-to-microwave transmitter, a dual-channel hybrid wireless communication system was realized, which can transmit simultaneously two different videos by using frequency division multiplexing (FDM) scheme. The reported method and technique will open new avenues for developing low-cost and low-complexity hybrid communication systems.
The hybrid transmitter is implemented by an optically programmed time-varying metasurface, which is constructed via the heterogeneous integration of a high-speed and linear photoelectric detection circuit into a reflective programmable metasurface. The profile of the whole platform is around 2 mm. With this hybrid integration strategy, the microwave reflection spectrum of the metasurface can be modulated by light intensity in high speed, thus achieving the direct light-to-microwave signal conversion and transmission. These scientists summarize the operational principle of their hybrid transmitter:
“We design an optically programmed time-varying metasurface for three purposes in one: (1) to perform real-time microwave manipulation by time-varying light signal; (2) to realize the direct light-to-microwave signal conversion based on spectrum control; (3) to implement the FDM using the dispersion response of the metasurface for achieving the dual-channel data transmissions in a light-to-microwave link.”
“Using the transmitter, we further build a dual-channel hybrid wireless communication system, in which two different videos can be transferred from the optical transmitter to microwave receiver simultaneously and independently. The whole signal conversion process can be completed fully on a single platform, without any additional microwave devices and optical components.” they added.
“The presented technique is able to implement the visible light communication and microwave communication simultaneously, which could be used for some typical applications where the two different communication links are required. Therefore, this breakthrough could open a new venue for future multi-domain integrated and full-spectrum 6G wireless communications,” the scientists forecast.
Journal
Light Science & Applications