Periodic Reporting for period 2 - TeraSlice (Terahertz Analogue-to-Digital Conversion Using Photonic Chipscale Soliton Frequency Combs and Massively Parallel Spectrally Sliced Detection)
Periodo di rendicontazione: 2021-01-01 al 2023-06-30
The TeraSlice approach has the potential to disrupt a wide field of highly relevant applications, ranging from high-speed communications to metrology and sensing and further to high-field electron paramagnetic resonance (EPR) spectroscopy.
TeraSlice has the following overall scientific and technological objectives:
(i) to establish unprecedentedly compact and efficient Kerr soliton frequency comb generators for realizing an ultra-fast photonic ADC
(ii) to establish a novel class of high speed electro-optic modulators using capacitively-coupled silicon-organic hybrid (SOH) devices
(iii) to establish a new paradigm for Terahertz photonic analogue-to-digital conversion based on integrated photonics and soliton Kerr frequency combs
THALES has worked on the conceptual system design of the demonstrator, and defined the complete architecture and theoretical model. It has also performed additional simulations predicting key performance; such as signal to noise ratio (SNR), effective number of bits (ENOB) and dynamic range (DR).
Chip-level building blocks are key to demonstrating the TeraSlice signal processing concept. The first-generation CC-SOH modulators were internally fabricated and characterized at KIT. The results have been accepted for publication. Detector arrays and spectral slicing filters were designed with support by LGT and external foundries.
EPFL focused on developing a local oscillator consisting of a compact soliton microcomb with very low noise. EPFL fabricated the first generation of silicon nitride microresonators for TeraSlice with support by LGT, providing the required specifications for the TeraSlice comb source, and successfully generated a single soliton microcomb. It further studied the phase noise performance of the self-injection locked lasers, the soliton microcomb repetition rate and the nonlinear dynamics that govern the phase noise transduction between the pump and the comb lines.
VANGUARD focused on the optical interconnects for the multi-chip assembly within TeraSlice. The first generation of optical interfaces and the corresponding photonic wire bonding process was developed. The individual interfaces can now be arbitrarily connected with each other for the TeraSlice assembly, using the photonic wire bonding process.
CNIT and KIT have progressed towards the development and implementation of the dedicated DSP software for slice stitching. This is part of the full test performance of the packaged ADC system.
All members engaged with different audiences to raise awareness of TeraSlice. CNIT designed and implemented the Teraslice website which was officially launched in April 2020 [https://www.teraslice-fetopen.eu/].
Acquisition of large-bandwidth signals in the 0 … 320 GHz domain is of dramatic interest for a variety of applications. These applications comprise areas of high commercial impact, e.g. ultra-broadband wireless communications within and beyond 5G and Internet-of-Things networks or security applications related to next-generation radar systems and secure wireless transmission. In this context, THALES explores the application potential of the TeraSlice approach for the analysis of radio frequency (RF) spectrum occupation, also referred to as spectrum sensing, which is of highest practical interest in several fields. Similar challenges exist in the area of high-performance radar systems that are addressed both by CNIT and THALES.
TeraSlice will enable photonic ADC that are disruptive, both with respect to performance and to viability of fully integrated chip-scale systems, and that provide a cost-effective approach to ultra-broadband signal processing. The impact of TeraSlice will unlock new markets with substantial economic potential worldwide. In fact, given the unique expertise and the strong international position of the participating research groups and companies, TeraSlice has the clear potential to reinforce and establish European leadership in the field of high-speed photonic-electronic signal processing.