26 research outputs found
High performance photonic reservoir computer based on a coherently driven passive cavity
Reservoir computing is a recent bio-inspired approach for processing
time-dependent signals. It has enabled a breakthrough in analog information
processing, with several experiments, both electronic and optical,
demonstrating state-of-the-art performances for hard tasks such as speech
recognition, time series prediction and nonlinear channel equalization. A
proof-of-principle experiment using a linear optical circuit on a photonic chip
to process digital signals was recently reported. Here we present a photonic
implementation of a reservoir computer based on a coherently driven passive
fiber cavity processing analog signals. Our experiment has error rate as low or
lower than previous experiments on a wide variety of tasks, and also has lower
power consumption. Furthermore, the analytical model describing our experiment
is also of interest, as it constitutes a very simple high performance reservoir
computer algorithm. The present experiment, given its good performances, low
energy consumption and conceptual simplicity, confirms the great potential of
photonic reservoir computing for information processing applications ranging
from artificial intelligence to telecommunicationsComment: non
Silicon photonics for neuromorphic information processing
We present our latest results on silicon photonics neuromorphic information processing based a.o. on techniques like reservoir computing. We will discuss aspects like scalability, novel architectures for enhanced power efficiency, as well as all-optical readout. Additionally, we will touch upon new machine learning techniques to operate these integrated readouts. Finally, we will show how these systems can be used for high-speed low-power information processing for applications like recognition of biological cells
Integrated Photonic Reservoir Computing with All-Optical Readout
Integrated photonic reservoir computing has been demonstrated to be able to
tackle different problems because of its neural network nature. A key advantage
of photonic reservoir computing over other neuromorphic paradigms is its
straightforward readout system, which facilitates both rapid training and
robust, fabrication variation-insensitive photonic integrated hardware
implementation for real-time processing. We present our recent development of a
fully-optical, coherent photonic reservoir chip integrated with an optical
readout system, capitalizing on these benefits. Alongside the integrated
system, we also demonstrate a weight update strategy that is suitable for the
integrated optical readout hardware. Using this online training scheme, we
successfully solved 3-bit header recognition and delayed XOR tasks at 20 Gbps
in real-time, all within the optical domain without excess delays
Online Training of an Opto-Electronic Reservoir Computer
Reservoir Computing is a bio-inspired computing paradigm for processing time dependent signals. Its analog implementations equal and sometimes outperform other digital algorithms on a series of benchmark tasks. Their performance can be increased by switching from offline to online training method. Here we present the first online trained opto-electronic reservoir computer. The system is tested on a channel equalisation task and the algorithm is executed by an FPGA chip. We report performances close to previous implementations and demonstrate the benefits of online training on a non-stationary task that could not be easily solved using offline methods.info:eu-repo/semantics/publishe
Role of non-linear data processing on speech recognition task in the framework of reservoir computing
The reservoir computing neural network architecture is widely used to test
hardware systems for neuromorphic computing. One of the preferred tasks for
bench-marking such devices is automatic speech recognition. However, this task
requires acoustic transformations from sound waveforms with varying amplitudes
to frequency domain maps that can be seen as feature extraction techniques.
Depending on the conversion method, these may obscure the contribution of the
neuromorphic hardware to the overall speech recognition performance. Here, we
quantify and separate the contributions of the acoustic transformations and the
neuromorphic hardware to the speech recognition success rate. We show that the
non-linearity in the acoustic transformation plays a critical role in feature
extraction. We compute the gain in word success rate provided by a reservoir
computing device compared to the acoustic transformation only, and show that it
is an appropriate benchmark for comparing different hardware. Finally, we
experimentally and numerically quantify the impact of the different acoustic
transformations for neuromorphic hardware based on magnetic nano-oscillators.Comment: 13 pages, 5 figure
A neuromorphic silicon photonics nonlinear equalizer for optical communications with intensity modulation and direct detection
We present the design and numerical study of a nonlinear equalizer for optical communications based on silicon photonics and reservoir computing. The proposed equalizer leverages the optical information processing capabilities of integrated photonic reservoirs to combat distortions both in metro links of a few hundred kilometers and in high-speed short-reach intensity-modulation-direct-detection links. We show nonlinear compensation in unrepeated metro links of up to 200 km that outperform electrical feedforward equalizers based equalizers, and ultimately any linear compensation device. For a high-speed short-reach 40Gb/s link based on a distributed feedback laser and an electroabsorptive modulator, and considering a hard decision forward error correction limit of 0.2 x 10(-2), we can increase the reach by almost 10 km. Our equalizer is compact (only 16 nodes) and operates in the optical domain without the need for complex electronic DSP, meaning its performance is not bandwidth constrained. The approach is, therefore, a viable candidate even for equalization techniques far beyond 100G optical communication links