Hybrid Photonic Integrated Circuits for Wireless Transceivers

• Published in: Photonics Vol. 12; no. 4; p. 371
• Main Authors: Qian, Tianwen, Schuler, Ben, Gupta, Y. Durvasa, Deumer, Milan, Andrianopoulos, Efstathios, Lyras, Nikolaos K., Kresse, Martin, Weigel, Madeleine, Reck, Jakob, Mihov, Klara, Winklhofer, Philipp, Keuer, Csongor, Emden, Laurids von, Amberg, Marcel, Zawadzki, Crispin, Kleinert, Moritz, Nellen, Simon, Felipe, Davide de, Avramopoulos, Hercules, Kohlhaas, Robert B., Keil, Norbert, Schell, Martin
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.04.2025
• Subjects: Antenna arrays; Antennas; Antennas (Electronics); Bandwidths; Beam steering; Directivity; Emitters; Energy conservation; Form factors; Frequency locking; high-speed wireless communication; hybrid integration; Indium phosphides; Innovations; Integrated circuits; Lasers; Nitrides; Optical frequency; Optics; Phased arrays; photonic integrated circuits; Photonics; Photoresponse; Polymers; Power consumption; Power management; Receivers & amplifiers; Semiconductor chips; Semiconductors; Silicon nitride; Transceivers; Tunable lasers; Waveguides; Wireless carriers; Wireless communications; Wireless networks; wireless transceivers
• ISSN: 2304-6732; 2304-6732
• DOI: 10.3390/photonics12040371

Recent advancements in hybrid photonic integrated circuits (PICs) for wireless communications are reviewed, with a focus on innovations developed at Fraunhofer HHI. This work leverages hybrid integration technology, which combines indium phosphide (InP) active elements, silicon nitride (Si3N4) low-loss waveguides, and high-efficient thermal-optical tunable polymers with micro-optical functions to achieve fully integrated wireless transceivers. Key contributions include (1) On-chip optical injection locking for generating phase-locked optical beat notes at 45 GHz, enabled by cascaded InP phase modulators and hybrid InP/polymer tunable lasers with a 3.8 GHz locking range. (2) Waveguide-integrated THz emitters and receivers, featuring photoconductive antennas (PCAs) with a 22× improved photoresponse compared to top-illuminated designs, alongside scalable 1 × 4 PIN-PD and PCA arrays for enhanced power and directivity. (3) Beam steering at 300 GHz using a polymer-based optical phased array (OPA) integrated with an InP antenna array, achieving continuous steering across 20° and a 10.6 dB increase in output power. (4) Demonstration of fully integrated hybrid wireless transceiver PICs combining InP, Si3N4, and polymer material platforms, validated through key component characterization, on-chip optical frequency comb generation, and coherent beat note generation at 45 GHz. These advancements result in compact form factors, reduced power consumption, and enhanced scalability, positioning PICs as an enabling technology for future high-speed wireless networks.