G. Contestabile scite author profile

The ability to process optical signals without passing into the electrical domain has always attracted the attention of the research community. Processing photons by photons unfolds new scenarios, in principle allowing for unseen signal processing and computing capabilities. Optical computation can be seen as a large scientific field in which researchers operate, trying to find solutions to their specific needs by different approaches; although the challenges can be substantially different, they are typically addressed using knowledge and technological platforms that are shared across the whole field. This significant know-how can also benefit other scientific communities, providing lateral solutions to their problems, as well as leading to novel applications. The aim of this Roadmap is to provide a broad view of the state-of-the-art in this lively scientific research field and to discuss the advances required to tackle emerging challenges, thanks to contributions authored by experts affiliated to both academic institutions and high-tech industries. The Roadmap is organized so as to put side by side contributions on different aspects of optical processing, aiming to enhance the cross-contamination of ideas between scientists working in three different fields of photonics: optical gates and logical units, high bit-rate signal processing and optical quantum computing. The ultimate intent of this paper is to provide guidance for young scientists as well as providing research-funding institutions and stake holders with a comprehensive overview of perspectives and opportunities offered by this research field.

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Multiple Wavelength Conversion for WDM Multicasting by FWM in an SOA

Contestabile

Presi

Ciaramella

2004

IEEE Photon. Technol. Lett.

139

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output pulses of wavelength conversion based on NPR assisted with red-shifted filtering. It is obvious that simulated results in Figure 4 are in well agreement with experimental results in Figure 7, which proves the validity of the model developed by us. The output ERs of the two kinds of wavelength conversion schemes are about 4 dB and 15.6 dB, respectively. The difference of the output ERs between simulated results and experimental results derives from the fact that ASE of SOA is not considered in simulation. CONCLUSIONSA wavelength conversion scheme based on NPR assisted with red-shifted filtering is presented. To investigate the performance of the wavelength conversion scheme, we develop a model of wavelength conversion based on NPR assisted with red-shifted filtering. Simulated results based on this model agree well with the experimental results. Simulated analyses and experimental results show that high performance wavelength conversion based on NPR is achieved using a red-shifted filtering scheme. TRANSMISSION CHARACTERISTICS OF MULTIPLE ELLIPTICLE RIDGE WAVEQUIDE

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Cross-Gain Modulation in Quantum-Dot SOA at 1550 nm

Contestabile

Maruta

Sekiguchi

et al. 2010

IEEE J. Quantum Electron.

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Chirp management in silicon-graphene electro absorption modulators

Sorianello¹,

Contestabile²,

Midrio³

et al. 2017

Opt. Express

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Abstract:We study the frequency chirp properties of graphene-on-silicon electro-absorption modulators (EAMs). By experimentally measuring the chirp of a 100 µm long single layer graphene EAM, we show that the optoelectronic properties of graphene induce a large positive linear chirp on the optical signal generated by the modulator, giving rise to a maximum shift of the instantaneous frequency up to 1.8 GHz. We exploit this peculiar feature for chromatic-dispersion compensation in fiber optic transmission thanks to the pulse temporal lensing effect. In particular, we show dispersion compensation in a 10Gb/s transmission experiment on standard single mode fiber with temporal focusing distance (0-dB optical-signal-to-noise ratio penalty) of 60 km, and also demonstrate 100 km transmission with a bit error rate largely lower than the conventional Reed-Solomon forward error correction threshold of 10 −3 .

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1.28-Tb/s (32 $\times$ 40 Gb/s) Free-Space Optical WDM Transmission System

Ciaramella

Arimoto

Contestabile

et al. 2009

IEEE Photon. Technol. Lett.

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Full daylight quantum-key-distribution at 1550 nm enabled by integrated silicon photonics

et al. 2021

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The future envisaged global-scale quantum-communication network will comprise various nodes interconnected via optical fibers or free-space channels, depending on the link distance. The free-space segment of such a network should guarantee certain key requirements, such as daytime operation and the compatibility with the complementary telecom-based fiber infrastructure. In addition, space-to-ground links will require the capability of designing light and compact quantum devices to be placed in orbit. For these reasons, investigating available solutions matching all the above requirements is still necessary. Here we present a full prototype for daylight quantum key distribution at 1550 nm exploiting an integrated silicon-photonics chip as state encoder. We tested our prototype in the urban area of Padua (Italy) over a 145 m-long free-space link, obtaining a quantum bit error rate around 0.5% and an averaged secret key rate of 30 kbps during a whole sunny day (from 11:00 to 20:00). The developed chip represents a cost-effective solution for portable free-space transmitters and a promising resource to design quantum optical payloads for future satellite missions.

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G. Contestabile

Graphene–silicon phase modulators with gigahertz bandwidth

1.28 terabit/s (32x40 Gbit/s) wdm transmission system for free space optical communications

Roadmap on all-optical processing

Multiple Wavelength Conversion for WDM Multicasting by FWM in an SOA

Cross-Gain Modulation in Quantum-Dot SOA at 1550 nm

Chirp management in silicon-graphene electro absorption modulators

1.28-Tb/s (32 $\times$ 40 Gb/s) Free-Space Optical WDM Transmission System

Full daylight quantum-key-distribution at 1550 nm enabled by integrated silicon photonics

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