HIROSHIMA, JAPAN�Hiroshima University, the National Institute of Information and Communications Technology of Japan, and Panasonic Corporation recently announced the development of a terahertz (THz) transmitter capable of transmitting digital data at a rate exceeding 100 gigabits per second over a single radio channel in the 300 GHz band.
Phys.orgreports that this technology enables data rates 10 times or faster than that offered by the fifth-generation mobile networks (5G) expected to appear around 2020. �
The THz band is a �vast new frequency resource expected to be used for future ultra-high-speed wireless communications.� �The research group has developed a transmitter that achieves a communication speed of 105 gigabits per second using the frequency range from 290 GHz to 315 GHz. This range of frequencies is currently unallocated, but fall within the frequency range from 275 GHz to 450 GHz, whose usage is to be discussed at the World Radiocommunication Conference (WRC) 2019.
Last year, the same group demonstrated that the speed of a wireless link in the 300 GHz band could be greatly enhanced by using (QAM). This year, they showed a six times higher per-channel data rate exceeding 100 gigabits per second for the first time as an integrated-circuit-based transmitter.
At this data rate, the contents of an entire DVD can be transferred in a fraction of a second, according to the same article.
"This year, we developed a transmitter with 10 times higher transmission power than the previous versions. This made possible a per-channel data rate above 100 Gbit/s at 300 GHz," said Prof. Minoru Fujishima, Graduate School of Advanced Sciences of Matter, Hiroshima University. "We usually talk about wireless data rates in megabits per second or gigabits per second. But we are now approaching terabits per second using a single communication channel. Fiber optics realized ultra-high-speed wired links, and wireless links have been left far behind. Terahertz could offer ultra-high-speed links to satellites as well, which can only be wireless. That could, in turn, significantly boost in-flight network connection speeds, for example. Other possible applications include fast download from content servers to mobile devices and ultrafast wireless links between base stations," said Prof. Fujishima.
"Another, completely new possibility offered by terahertz wireless is high-data-rate, minimum-latency communications. Optical fibers are made of glass, and the speed of light slows down in fibers. That makes fiber optics inadequate for applications requiring real-time responses. Today, you must make a choice between 'high data rate' (fiber optics) and 'minimum latency' (microwave links). You can't have them both. But with terahertz wireless, we could have light-speed, minimum-latency links supporting fiber-optic data rates," he said.�