970 research outputs found
Towards Bayesian Data Compression
In order to handle large data sets omnipresent in modern science, efficient
compression algorithms are necessary. Here, a Bayesian data compression (BDC)
algorithm that adapts to the specific measurement situation is derived in the
context of signal reconstruction. BDC compresses a data set under conservation
of its posterior structure with minimal information loss given the prior
knowledge on the signal, the quantity of interest. Its basic form is valid for
Gaussian priors and likelihoods. For constant noise standard deviation, basic
BDC becomes equivalent to a Bayesian analog of principal component analysis.
Using Metric Gaussian Variational Inference, BDC generalizes to non-linear
settings. In its current form, BDC requires the storage of effective instrument
response functions for the compressed data and corresponding noise encoding the
posterior covariance structure. Their memory demand counteract the compression
gain. In order to improve this, sparsity of the compressed responses can be
obtained by separating the data into patches and compressing them separately.
The applicability of BDC is demonstrated by applying it to synthetic data and
radio astronomical data. Still the algorithm needs further improvement as the
computation time of the compression and subsequent inference exceeds the time
of the inference with the original data.Comment: 39 pages, 15 figures, 1 table, for code, see
https://gitlab.mpcdf.mpg.de/jharthki/bd
Photoionization in the time and frequency domain
Ultrafast processes in matter, such as the electron emission following light
absorption, can now be studied using ultrashort light pulses of attosecond
duration (s) in the extreme ultraviolet spectral range. The lack of
spectral resolution due to the use of short light pulses may raise serious
issues in the interpretation of the experimental results and the comparison
with detailed theoretical calculations. Here, we determine photoionization time
delays in neon atoms over a 40 eV energy range with an interferometric
technique combining high temporal and spectral resolution. We spectrally
disentangle direct ionization from ionization with shake up, where a second
electron is left in an excited state, thus obtaining excellent agreement with
theoretical calculations and thereby solving a puzzle raised by seven-year-old
measurements. Our experimental approach does not have conceptual limits,
allowing us to foresee, with the help of upcoming laser technology, ultra-high
resolution time-frequency studies from the visible to the x-ray range.Comment: 5 pages, 4 figure
Characterization of uncertainties in atmospheric trace gas inversions using hierarchical Bayesian methods
We present a hierarchical Bayesian method for atmospheric trace gas
inversions. This method is used to estimate emissions of trace gases as well
as "hyper-parameters" that characterize the probability density functions
(PDFs) of the a priori emissions and model-measurement covariances. By
exploring the space of "uncertainties in uncertainties", we show that the
hierarchical method results in a more complete estimation of emissions and
their uncertainties than traditional Bayesian inversions, which rely heavily
on expert judgment. We present an analysis that shows the effect of
including hyper-parameters, which are themselves informed by the data, and
show that this method can serve to reduce the effect of errors in assumptions
made about the a priori emissions and model-measurement uncertainties. We
then apply this method to the estimation of sulfur hexafluoride (SF6)
emissions over 2012 for the regions surrounding four Advanced Global
Atmospheric Gases Experiment (AGAGE) stations. We find that improper
accounting of model representation uncertainties, in particular, can lead to
the derivation of emissions and associated uncertainties that are unrealistic
and show that those derived using the hierarchical method are likely to be
more representative of the true uncertainties in the system. We demonstrate
through this SF6 case study that this method is less sensitive to
outliers in the data and to subjective assumptions about a priori emissions
and model-measurement uncertainties than traditional methods
Self-Similar Liquid Lens Coalescence
A basic feature of liquid drops is that they can merge upon contact to form a
larger drop. In spite of its importance to various applications, drop
coalescence on pre-wetted substrates has received little attention. Here, we
experimentally and theoretically reveal the dynamics of drop coalescence on a
thick layer of a low-viscosity liquid. It is shown that these so-called "liquid
lenses" merge by the self-similar vertical growth of a bridge connecting the
two lenses. Using a slender analysis, we derive similarity solutions
corresponding to the viscous and inertial limits. Excellent agreement is found
with the experiments without any adjustable parameters, capturing both the
spatial and temporal structure of the flow during coalescence. Finally, we
consider the crossover between the two regimes and show that all data of
different lens viscosities collapse on a single curve capturing the full range
of the coalescence dynamics
Folding of a donor–acceptor polyrotaxane by using noncovalent bonding interactions
Mechanically interlocked compounds, such as bistable catenanes and bistable rotaxanes, have been used to bring about actuation in nanoelectromechanical systems (NEMS) and molecular electronic devices (MEDs). The elaboration of the structural features of such rotaxanes into macromolecular materials might allow the utilization of molecular motion to impact their bulk properties. We report here the synthesis and characterization of polymers that contain π electron-donating 1,5-dioxynaphthalene (DNP) units encircled by cyclobis(paraquat-p-phenylene) (CBPQT4+), a π electron-accepting tetracationic cyclophane, synthesized by using the copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC). The polyrotaxanes adopt a well defined “folded” secondary structure by virtue of the judicious design of two DNP-containing monomers with different binding affinities for CBPQT4+. This efficient approach to the preparation of polyrotaxanes, taken alongside the initial investigations of their chemical properties, sets the stage for the preparation of a previously undescribed class of macromolecular architectures
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