80 research outputs found
Low-Noise Operation of Mid-Infrared Quantum Cascade Lasers Using Injection Locking
Quantum cascade lasers are the most promising optical source for emission in the mid-infrared and THz region, and they are already used in a large number of applications such as free-space communications, absorption spectroscopy, sensing and so on. In all these applications, the noise properties of the optical sources are critical for the system performance. In this work, the authors present a theoretical study on the intensity noise characteristics of quantum cascade lasers (QCLs) under external non-coherent optical injection. The injection locking has been proven in the past beneficial for noise properties of bipolar lasers, and thus this technique is utilized here in quantum cascade lasers. With the help of various analytical and numerical models, it is shown that intensity noise reduction can be achieved in the operation of the so-called locked slave laser compared to its free-running values. The detailed analysis reveals the contribution of the various noise sources to the intensity noise of the laser and how they affect the injection locking process. Using different numerical models, two distinct schemes are investigated, analysed and discussed, injection on the lasing mode or on non-lasing residual modes of the slave laser cavity
All-Optical Regeneration Based on Phase-Sensitive Nondegenerate Four-Wave Mixing in Optical Fibers
An optical regeneration scheme based on nondegenerate phase-sensitive amplification in highly nonlinear fibers is numerically investigated. The proposed regenerator exhibits significant amplitude and phase noise suppression properties and eliminates the need for precise phase and frequency locking with the input return-to-zero differential phase-shift keying signal
Free space intra-datacenter interconnects based on 2D optical beam steering enabled by photonic integrated circuits
Data centers are continuously growing in scale and can contain more than one million servers spreading across thousands of racks; requiring a large-scale switching network to provide broadband and reconfigurable interconnections of low latency. Traditional data center network architectures, through the use of electrical packet switches in a multi-tier topology, has fundamental weaknesses such as oversubscription and cabling complexity. Wireless intra-data center interconnection solutions have been proposed to deal with the cabling problem and can simultaneously address the over-provisioning problem by offering efficient topology re-configurability. In this work we introduce a novel free space optical interconnect solution for intra-data center networks that utilizes 2D optical beam steering for the transmitter, and high bandwidth wide-area photodiode arrays for the receiver. This new breed of free space optical interconnects can be developed on a photonic integrated circuit; offering ns switching at sub-µW consumption. The proposed interconnects together with a networking architecture that is suitable for utilizing those devices could support next generation intra-data center networks, fulfilling the requirements of seamless operation, high connectivity, and agility in terms of the reconfiguration time.Peer ReviewedPostprint (published version
Colorless Regenerative Amplification of Constant Envelope Phase-Modulated Optical Signals Based on Injection-Locked Fabry–Pérot Lasers
An efficient phase preserving amplitude noise limiter suitable for constant envelope phase-modulated signals is experimentally demonstrated for 10-Gb/s differential phase-shift-keying (DPSK) signals exploiting injection locking in Fabry–Pérot lasers. The limiter operates successfully over a 16.4-nm tuning range leading to 12 dB of power penalty reduction for 10^-3 of bit-error-rate (BER) performance
Spatial Photonic Reservoir Computing based on Non-Linear Phase-to-Amplitude Conversion in Micro-Ring Resonators
We present a photonic reservoir computing, relying on a non-linear
phase-to-amplitude mapping process, able to classify in real-time multi-Gbaud
time traces subject to transmission effects. This approach delivers an
all-optical, low-power neuromorphic dispersion compensator.Comment:
Pseudo-Random Generator based on a Photonic Neuromorphic Physical Unclonable Function
In this work we provide numerical results concerning a silicon-on-insulator
photonic neuromorphic circuit configured as a physical unclonable function. The
proposed scheme is enhanced with the capability to be operated as an
unconventional deterministic pseudo-random number generator, suitable for
cryptographic applications that alleviates the need for key storage in
non-volatile digital media. The proposed photonic neuromorphic scheme is able
to offer NIST test compatible numbers with an extremely low false
positive/negative probability below 10-14. The proposed scheme offers
multi-functional capabilities due to the fact that it can be simultaneously
used as an integrated photonic accelerator for machine-learning applications
and as a hardware root of trust.Comment: 8 pages, 7 figure
Multichannel Nonlinear Equalization in Coherent WDM Systems based on Bi-directional Recurrent Neural Networks
Kerr nonlinearity in the form of self- and cross-phase modulation imposes a
fundamental limitation to the capacity of wavelength division multiplexed (WDM)
optical communication systems. Digital back-propagation (DBP), that requires
solving the inverse-propagating nonlinear Schr\"odinger equation (NLSE), is a
widely adopted technique for the mitigation of impairments induced by Kerr
nonlinearity. However, multi-channel DBP is too complex to be implemented
commercially in WDM systems. Recurrent neural networks (RNNs) have been
recently exploited for nonlinear signal processing in the context of optical
communications. In this work, we propose multi-channel equalization through a
bidirectional vanilla recurrent neural network (bi-VRNN) in order to improve
the performance of the single-channel bi-VRNN algorithm in the transmission of
WDM M-QAM signals. We compare the proposed digital algorithm to full-field DBP
and to the single channel bi-RNN in order to reveal its merits with respect to
both performance and complexity. We finally provide experimental verification
through a QPSK metro link, showcasing over 2.5 dB optical signal-to-noise ratio
(OSNR) gain and up to 43% complexity reduction with respect to the
single-channel RNN and the DBP.Comment: 9 page
Field-trial of an all-optical PSK regenerator/multicaster in a 40 Gbit/s, 38 channel DWDM transmission experiment
The performance of future ultra-long haul communication systems exploiting phase-encoded signals is likely to be compromised by noise generated during signal transmission. One potential way to mitigate such noise is to use Phase Sensitive Amplifiers (PSAs) which have been demonstrated to help remove phase as well as amplitude noise from phase-encoded signals. Recently, we showed that a PSA-based signal regenerator based on degenerate four-wave mixing can be implemented in a network-compatible manner in which only the (noisy) signal is present at the device input (black-box operation). The developed regenerator was also able to perform simultaneous wavelength conversion and multicasting, details/analysis of which are presented herein. However, this scheme was tested only with artificial noise generated in the laboratory and with the regenerator placed in front of the receiver, rather than in-line where even greater performance benefits are to be expected. Here, we address both theoretically and experimentally the important issue of how such a regenerator, operating for convenience in a multicasting mode, performs as an in-line device in an installed transmission fiber link. We also investigate the dispersion tolerance of the approach
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