4,723 research outputs found
Continuous dynamical decoupling magnetometry
Solid-state qubits hold the promise to achieve unmatched combination of
sensitivity and spatial resolution. To achieve their potential, the qubits need
however to be shielded from the deleterious effects of the environment. While
dynamical decoupling techniques can improve the coherence time, they impose a
compromise between sensitivity and bandwidth, since to higher decoupling power
correspond higher frequencies of the field to be measured. Moreover, the
performance of pulse sequences is ultimately limited by control bounds and
errors. Here we analyze a versatile alternative based on continuous driving. We
find that continuous dynamical decoupling schemes can be used for AC
magnetometry, providing similar frequency constraints on the AC field and
improved sensitivity for some noise regimes. In addition, the exibility of
phase and amplitude modulation could yield superior robustness to driving
errors and a better adaptability to external experimental scenarios
Maximally Entangled Mixed-State Generation via Local Operations
We present a general theoretical method to generate maximally entangled mixed
states of a pair of photons initially prepared in the singlet polarization
state. This method requires only local operations upon a single photon of the
pair and exploits spatial degrees of freedom to induce decoherence. We report
also experimental confirmation of these theoretical results.Comment: 5 pages, 2 figures, to be published in Physical Review
Algebraic synthesis of time-optimal unitaries in SU(2) with alternating controls
We present an algebraic framework to study the time-optimal synthesis of
arbitrary unitaries in SU(2), when the control set is restricted to rotations
around two non-parallel axes in the Bloch sphere. Our method bypasses commonly
used control-theoretical techniques, and easily imposes necessary conditions on
time-optimal sequences. In a straightforward fashion, we prove that
time-optimal sequences are solely parametrized by three rotation angles and
derive general bounds on those angles as a function of the relative rotation
speed of each control and the angle between the axes. Results are substantially
different whether both clockwise and counterclockwise rotations about the given
axes are allowed, or only clockwise rotations. In the first case, we prove that
any finite time-optimal sequence is composed at most of five control
concatenations, while for the more restrictive case, we present scaling laws on
the maximum length of any finite time-optimal sequence. The bounds we find for
both cases are stricter than previously published ones and severely constrain
the structure of time-optimal sequences, allowing for an efficient numerical
search of the time-optimal solution. Our results can be used to find the
time-optimal evolution of qubit systems under the action of the considered
control set, and thus potentially increase the number of realizable unitaries
before decoherence
The NV center as a quantum actuator: time-optimal control of nuclear spins
Indirect control of qubits by a quantum actuator has been proposed as an
appealing strategy to manipulate qubits that couple only weakly to external
fields. While universal quantum control can be easily achieved when the
actuator-qubit coupling is anisotropic, the efficiency of this approach is less
clear. Here we analyze the time-efficiency of the quantum actuator control. We
describe a strategy to find time-optimal control sequence by the quantum
actuator and compare their gate times with direct driving, identifying regimes
where the actuator control performs faster. As an example, we focus on a
specific implementation based on the Nitrogen-Vacancy center electronic spin in
diamond (the actuator) and nearby carbon-13 nuclear spins (the qubits)
Parametric studies of advanced turboprops
The effects of geometric variables (sweep and twist) on the structural performance of advanced turboprops are investigated. The investigation is limited to aerodynamically efficient turboprops using an acceptable design configuration as a baseline. The baseline configuration is modified using a seven by seven array of independently varying sweep and twist parameters while maintaining acceptable aerodynamic efficiency. The turboprop structural performance is evaluated in terms of critical speeds, tip displacements, and vibration frequencies where geometric nonlinearities are included. The results obtained are presented in such a manner as to highlight the effects of sweep and twist on the structural performance of aerodynamically efficient turboprop configurations
Smelly maps: the digital life of urban smellscapes
Smell has a huge influence over how we perceive places. Despite its importance, smell has been crucially overlooked by urban planners and scientists alike, not least because it is difficult to record and analyze at scale. One of the authors of this paper has ventured out in the urban world and conducted ``smellwalks'' in a variety of cities: participants were exposed to a range of different smellscapes and asked to record their experiences. As a result, smell-related words have been collected and classified, creating the first dictionary for urban smell. Here we explore the possibility of using social media data to reliably map the smells of entire cities. To this end, for both Barcelona and London, we collect geo-referenced picture tags from Flickr and Instagram, and geo-referenced tweets from Twitter. We match those tags and tweets with the words in the smell dictionary. We find that smell-related words are best classified in ten categories. We also find that specific categories (e.g., industry, transport, cleaning) correlate with governmental air quality indicators, adding validity to our study
VIRTUAL MUSEUMS AS A MEANS FOR PROMOTION AND ENHANCEMENT OF CULTURAL HERITAGE
Abstract. The use of virtual reality and ICT in the museum context provides a new key to understand and promote Cultural Heritage: thanks to these technologies the user has the opportunity to experience without the need to come into contact with the real objects. For the museum institutions VR and ICT are a valuable tool that allows them to perform different cultural tasks, addressing the public in a much more effective way than has previously been possible. Especially through VR, it is possible to reconstruct the original context of the artworks through the interconnection of contents: the virtual visitor, while viewing the artwork, can consult useful contents for the learning process. Another revolutionary element introduced by the new technologies is linked to the possibility of creating virtual exhibitions through which it is possible to exhibit works that are not accessible or not visible. These reflections and these theoretical principles were the basis for the development of the project proposal presented in these pages, that was born as a collaboration between the R3D Lab of the Museo della Rappresentazione of University of Catania and the CIMS Lab of Carleton University, Ottawa. It consists in the creation of a virtual museum, the Timeless Museum, in order to create an educational experience, able to make the users reflect on topics such as the value of history, the sense of beauty, the relationship with our past and our future, the protection and transmission to future generations of the artistic heritage we have.</p
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