Shaping the future of optical networks by uniting industry, research, standards, and industry bodies

Dr. David Hillerkuss is a prominent expert in optical networking and communications technology, currently serving as a key innovator within Nokia. His work focuses on developing modern, efficient network infrastructures to support the "AI Era". 

Professional Roles & Affiliations

• Nokia: Following the planned acquisition of Infinera by Nokia, Hillerkuss is an integral part of the combined optical networking leadership.
• Infinera: He previously held significant roles at Infinera, where he moderated industry-shaping webinars and drove standards for optical networks.
• Industry Leadership: He is a frequent moderator and speaker for Optica (formerly OSA) webinar series, such as "Optical Networks toward 2030" (ON2030), focusing on high-speed optics like 1.6T ZR/ZR+.
• Academic Background: He earned his doctorate at the Karlsruhe Institute of Technology (KIT), where he specialized in high-capacity optical transmission systems. 

Key Contributions & Awards

• World Record Transmission: He was part of the team that achieved a 32.5 Tbit/s Nyquist WDM transmission using a single laser, a milestone in spectral efficiency.
• IOWN Global Forum Contributor Award: Recognized in May 2025 for his work on energy efficiency and sustainability in technology working groups.
• Charles Kao Award (2015): Received the IEEE Communications Society award for the Best Optical Communications & Networking Paper.
• Research Areas: His extensive publication record covers OFDM (Orthogonal Frequency-Division Multiplexing), silicon modulators, and CV-QKD (Continuous-Variable Quantum Key Distribution). 

Chigo Okonkwo is a Professor leading the high capacity optical transmission laboratory of the Electro-Optical Communications Group at the Institute for Photonics Integration, TU/e. He currently works on two key areas: Firstly, he is working to maximise the capacity of presently deployed single-mode fibre systems by employing advanced-coded modulation schemes and Probabilistic/Geometrically shaped signals and low complexity digital signal processing. More importantly, he is working on future proof transmission systems based on Space Division Multiplexing, and developing the new optical components required to scale the capacity of the optical transmission systems towards Petabit/s transmission. This can be done by exploiting the various spatial channel of a multi-mode fibre or multi-core fibre.

Chigo’s research is also focused on the development of new measurement systems, and his work has led to a provisional patent and several critical publications in Nature Photonics, JLT and Optics Express. Since 2010, Chigo has built up a world-class high capacity optical transmission laboratory and collaborates with several industrial partners.

Over 99% of all data generated will go through an optical fibre. Optical transmission systems form the foundation of the Internet and are slowly running out of capacity. We need a paradigm shift in how we design and test our systems to develop next-generation low-energy, robust and high capacity photonic networks