LOLIPOP Project is taking #photonic integration to the next level, harnessing CSEM's LNOI process to create hybrid TriPleX #PICs with advanced functionalities and broad wavelength capabilities.
🔑 Here’s a look at our key objectives:
🔹 Objective 1: Integrate LNOI on TriPleX for high-speed modulation and nonlinear functions, with sub-circuits tailored for applications from phase modulation to second harmonic generation.
🔹 Objective 2: Develop Ge photodiodes for wideband detection (400-1600 nm) with high responsivity, enabling efficient, side-illuminated detectors on the TriPleX platform.
🔹 Objective 3: Create ultra-narrow linewidth external cavity lasers, offering tunable output for high-precision LIDAR and neural network modules.
🔹 Objective 4: Design CMOS drivers and amplifiers for high-bandwidth (up to 30 GHz) operation, delivering low power consumption.
🔹 Objective 5: Demonstrate the use of LOLIPOP technology for Laser Doppler Vibrometers at 532 nm with ultra-high detection bandwidth (6 GHz).
🔹 Objective 6: Demonstrate the use of LOLIPOP technology for FMCW LIDAR modules at 905 nm with ultra-high chirp (10 GHz) and beam scanning mechanism on-chip.
🔹 Objective 7: Demonstrate the use of LOLIPOP technology for photonic integrated convolutional neural networks with ultra-high computation speed (24 TOPS)
🔹 Objective 8: Build integrated squeezed state sources for quantum protocols, pushing the envelope in quantum key distribution and computation.
🔹 Objective 9: Establish a roadmap for LOLIPOP’s technology, focusing on micro-transfer printing for LNOI-on-TriPleX to drive commercial applications across visible and near-infrared wavelengths.
👉 Stay tuned as we make integrated photonic technologies more versatile and accessible than ever!
🔗 https://lnkd.in/edVWvmsW
#PhotonicsEU #research #horizoneurope #TechInnovation #ResearchAndDevelopment #HorizonEurope
