152 research outputs found
Bayesian quantification for coherent anti-Stokes Raman scattering spectroscopy
We propose a Bayesian statistical model for analyzing coherent anti-Stokes
Raman scattering (CARS) spectra. Our quantitative analysis includes statistical
estimation of constituent line-shape parameters, underlying Raman signal,
error-corrected CARS spectrum, and the measured CARS spectrum. As such, this
work enables extensive uncertainty quantification in the context of CARS
spectroscopy. Furthermore, we present an unsupervised method for improving
spectral resolution of Raman-like spectra requiring little to no \textit{a
priori} information. Finally, the recently-proposed wavelet prism method for
correcting the experimental artefacts in CARS is enhanced by using
interpolation techniques for wavelets. The method is validated using CARS
spectra of adenosine mono-, di-, and triphosphate in water, as well as,
equimolar aqueous solutions of D-fructose, D-glucose, and their disaccharide
combination sucrose
Introduction to Dynamic Linear Models for Time Series Analysis
Dynamic linear models (DLM) offer a very generic framework to analyse time
series data. Many classical time series models can be formulated as DLMs,
including ARMA models and standard multiple linear regression models. The
models can be seen as general regression models where the coefficients can vary
in time. In addition, they allow for a state space representation and a
formulation as hierarchical statistical models, which in turn is the key for
efficient estimation by Kalman formulas and by Markov chain Monte Carlo (MCMC)
methods. A dynamic linear model can handle non-stationary processes, missing
values and non-uniform sampling as well as observations with varying
accuracies. This chapter gives an introduction to DLM and shows how to build
various useful models for analysing trends and other sources of variability in
geodetic time series.Comment: A chapter submitted to a book with a proposed title: Geodetic Time
Series Analysis and Applications, editors. J.-P. Montillet and M. Bo
Extraction of Airways with Probabilistic State-space Models and Bayesian Smoothing
Segmenting tree structures is common in several image processing
applications. In medical image analysis, reliable segmentations of airways,
vessels, neurons and other tree structures can enable important clinical
applications. We present a framework for tracking tree structures comprising of
elongated branches using probabilistic state-space models and Bayesian
smoothing. Unlike most existing methods that proceed with sequential tracking
of branches, we present an exploratory method, that is less sensitive to local
anomalies in the data due to acquisition noise and/or interfering structures.
The evolution of individual branches is modelled using a process model and the
observed data is incorporated into the update step of the Bayesian smoother
using a measurement model that is based on a multi-scale blob detector.
Bayesian smoothing is performed using the RTS (Rauch-Tung-Striebel) smoother,
which provides Gaussian density estimates of branch states at each tracking
step. We select likely branch seed points automatically based on the response
of the blob detection and track from all such seed points using the RTS
smoother. We use covariance of the marginal posterior density estimated for
each branch to discriminate false positive and true positive branches. The
method is evaluated on 3D chest CT scans to track airways. We show that the
presented method results in additional branches compared to a baseline method
based on region growing on probability images.Comment: 10 pages. Pre-print of the paper accepted at Workshop on Graphs in
Biomedical Image Analysis. MICCAI 2017. Quebec Cit
Higher-order mesoscopic fluctuations in quantum wires: Conductance and current cumulants
We study conductance cumulants and current cumulants
related to heat and electrical transport in coherent mesoscopic quantum wires
near the diffusive regime. We consider the asymptotic behavior in the limit
where the number of channels and the length of the wire in the units of the
mean free path are large but the bare conductance is fixed. A recursion
equation unifying the descriptions of the standard and Bogoliubov--de Gennes
(BdG) symmetry classes is presented. We give values and come up with a novel
scaling form for the higher-order conductance cumulants. In the BdG wires, in
the presence of time-reversal symmetry, for the cumulants higher than the
second it is found that there may be only contributions which depend
nonanalytically on the wire length. This indicates that diagrammatic or
semiclassical pictures do not adequately describe higher-order spectral
correlations. Moreover, we obtain the weak-localization corrections to
with .Comment: 7 page
A generative model for natural sounds based on latent force modelling
Generative models based on subband amplitude envelopes of natural sounds have resulted in convincing synthesis, showing subband amplitude modulation to be a crucial component of auditory perception. Probabilistic latent variable analysis can be particularly insightful, but existing approaches don’t incorporate prior knowledge about the physical behaviour of amplitude envelopes, such as exponential decay or feedback. We use latent force modelling, a probabilistic learning paradigm that encodes physical knowledge into Gaussian process regression, to model correlation across spectral subband envelopes. We augment the standard latent force model approach by explicitly modelling dependencies across multiple time steps. Incorporating this prior knowledge strengthens the interpretation of the latent functions as the source that generated the signal. We examine this interpretation via an experiment showing that sounds generated by sampling from our probabilistic model are perceived to be more realistic than those generated by comparative models based on nonnegative matrix factorisation, even in cases where our model is outperformed from a reconstruction error perspective
Enhancement by postfiltering for speech and audio coding in ad-hoc sensor networks
Enhancement algorithms for wireless acoustics sensor networks~(WASNs) are
indispensable with the increasing availability and usage of connected devices
with microphones. Conventional spatial filtering approaches for enhancement in
WASNs approximate quantization noise with an additive Gaussian distribution,
which limits performance due to the non-linear nature of quantization noise at
lower bitrates. In this work, we propose a postfilter for enhancement based on
Bayesian statistics to obtain a multidevice signal estimate, which explicitly
models the quantization noise. Our experiments using PSNR, PESQ and MUSHRA
scores demonstrate that the proposed postfilter can be used to enhance signal
quality in ad-hoc sensor networks
An advanced Bayesian model for the visual tracking of multiple interacting objects
Visual tracking of multiple objects is a key component of many visual-based systems. While there are reliable
algorithms for tracking a single object in constrained scenarios, the object tracking is still a challenge in
uncontrolled situations involving multiple interacting objects that have a complex dynamics. In this article, a novel
Bayesian model for tracking multiple interacting objects in unrestricted situations is proposed. This is accomplished
by means of an advanced object dynamic model that predicts possible interactive behaviors, which in turn depend
on the inference of potential events of object occlusion. The proposed tracking model can also handle false and
missing detections that are typical from visual object detectors operating in uncontrolled scenarios. On the other
hand, a Rao-Blackwellization technique has been used to improve the accuracy of the estimated object trajectories,
which is a fundamental aspect in the tracking of multiple objects due to its high dimensionality. Excellent results
have been obtained using a publicly available database, proving the efficiency of the proposed approach
Assessing the opportunities of landfill mining as a source of critical raw materials in Europe
Many of the metals in landfill constitute valuable and scarce natural resources. It
has already been recognised that the recovery of these elements is critical for the sustainability
of a number of industries. Arsenic (which is an essential part of the production of transistors and
LEDs) is predicted to run out sometime in the next five to 50 years if consumption continues at
the present rate. Nickel used for anything involving stainless steel and platinum group metals
(PGMs) used in catalytic converters, fertilisers and others are also identified as critical materials
(CM) to the EU economy at risk of depletion However, despite the increasing demand, none of
this supply is supported by recycling. This is due to the high cost of recovery from low
concentrations when compared to conventional mining. As demonstrated by the two pilot case
studies of this study, mining landfill sites only for their metals content is not expected to be
financially viable. However, other opportunities such as Waste-derived fuels from excavated
materials exist which if combined , form the concept of ‘enhanced landfill mining’. have the
potential to be highly energetic. The energy potential is comparable to the levels of energy of
Refuse-Derived Fuels (RDF) produced from non-landfilled wastes
Coherent control of three-spin states in a triple quantum dot
Spin qubits involving individual spins in single quantum dots or coupled
spins in double quantum dots have emerged as potential building blocks for
quantum information processing applications. It has been suggested that triple
quantum dots may provide additional tools and functionalities. These include
the encoding of information to either obtain protection from decoherence or to
permit all-electrical operation, efficient spin busing across a quantum
circuit, and to enable quantum error correction utilizing the three-spin
Greenberger-Horn-Zeilinger quantum state. Towards these goals we demonstrate
for the first time coherent manipulation between two interacting three-spin
states. We employ the Landau-Zener-St\"uckelberg approach for creating and
manipulating coherent superpositions of quantum states. We confirm that we are
able to maintain coherence when decreasing the exchange coupling of one spin
with another while simultaneously increasing its coupling with the third. Such
control of pairwise exchange is a requirement of most spin qubit architectures
but has not been previously demonstrated.Comment: 12 pages, 13 figures, and 2 table
- …