by Volker Jungnickel, Fraunhofer Heinrich Hertz Institute
Today’s Internet of Things (IoT), covering any communication between devices, is narrowband and not always provides reliability and low latency at the same time. A wide range of future IoT applications, i.e. flexible manufacturing, augmented reality and autonomous cars, will use artificial intelligence in the cloud to process sensor data jointly in real time.
This future IoT will need mobile communication providing high bandwidth, reliable connectivity and low latency at the same time. While radio spectrum is densely populated, light communication (LC) can use unlicensed optical spectrum and enable high data rates over short distances for future IoT. By networking multiple LC-enabled access points, also known as Li-Fi, one can build a new mobile communication system integrated with lighting infrastructure that enables the future IoT.
The main challenge to approach future IoT is to develop Li-Fi further into the mass-market serving a greater variety of use cases than today. Therefore, Li-Fi needs an open architecture, consensus building towards standards, a roadmap to support future IoT and technology demonstrations in real environments, such as indoors, manufacturing, logistics, conference rooms and outdoors for fixed-wireless access.
The talk will introduce ideas and solutions developed in the Horizon2020 ICT project Enhance Lighting for the Internet of Things (ELIOT) funded by the European Union. ELIOT is the first industry-driven large-scale innovation action on Li-Fi. ELIOT will focus on challenges and solutions paving the way from research to real-world scenarios and promising applications.
What drives you?
To make LiFi a commercial reality.
Why should the delegate attend your presentation?
To get introduced into a new application for LiFi.
What emerging technologies/trends do you see as having the greatest potential in the short and long run?
5G integrated with mm-wave, WiFi and LiFi.
What kind of impact do you expect them to have?
Closing the gaps in wireless access techniques in order to address the needs of new application domains like URLLC and IoT.
What are the barriers that might stand in the way?
Experts from communications, lighting and photonic components need to focus on a new technology, agree on one standard for baseband processing, more trials in real application scenarios.
About Volker Jungnickel
Volker Jungnickel (M) received doctoral and habilitation degrees in Physics and Communications Engineering from Humboldt University and Technical University in Berlin in 1995 and 2015, respectively. He joined Fraunhofer HHI in 1997 working on optical wireless communication, multiple antenna techniques in mobile networks and new fixed acess network infrastructures. Besides, he serves as Privatdozent at Technical University in Berlin with lectures and supervises Masters and Ph.D. thesis. Volker serves as Chair of IEEE P802.15.13 task group on Multi-Gbit/s Optical Wireless Communications and as Technical Editor for the IEEE P802.11bb task group on Light Communications.
About Fraunhofer Heinrich Hertz Institute
Innovations for the digital society of the future are the focus of research and development work at the Fraunhofer Heinrich Hertz Institute HHI. In this area, Fraunhofer HHI is a world leader in the development of mobile and optical communication networks and systems, fiber optical sensor systems as well as the processing and coding of video signals.
Together with international partners from research and industry, Fraunhofer HHI works in the whole spectrum of digital infrastructure – from fundamental research to the development of prototypes and solutions. The institute develops standards for information and communication technologies and creates new applications as an industry partner.