28 research outputs found
Embedded mobile application for controlling acoustic panels
Abstract. This thesis work is about acoustic panels and planning a software that would control these kinds of panels. The software is supposed to take information from the panels and then use that information for moving the acoustic panels to a desired location. The application is for mobile environment for both smart phones and tablets. This means that there are some constraints for the software such as scaling the panels so that all the panels can be used when moving the panels. This work introduces heuristic and design science theory and builds the application plan as an artifact from there onwards. The plan is based upon the original requirements for this application. This plan for the application meets the requirements set upon it by the customer.
The plan was created so that the basic functionalities that were discussed with the customer were satisfied. This included connection to panels, drawing a scaling panel view, moving panels, centring panels and so forth. The application was evaluated with two sets of heuristics. First one was the heuristics created by Nielsen 1995 and second heuristic was self-built. Nielsen’s heuristics were meant for a more general usage while the set of heuristics that were self-build were meant for more general usage.
The heuristic evaluation provided results which were that the application needs at least more error prevention, documentation and a better way or representing panels actual physical location on the wall. Error prevention was a major issue in a case that one or more of the panels were broken and needed to be fixed. Documentation was more of an issue from the user’s perspective in case some of the actions or error messages were such that the user did not understand them. Last issue of presenting the panel positions better in relation to the physical wall was an issue basically because the user needs to know where the panels are without too much difficulty. If the user is confused about panel location, they cannot be sure which panels to move.
These issues were discussed in the second iteration of the plan for this application. The second iteration was done in writing and a picture of the new user interface after the heuristic evaluation was done. This iteration discussed and solved these problems. For the limitations of this work there were issues with author doing the heuristic evaluation while not being an expert, implementation not being done in the scope of this work and implementation details not being discussed. For future research, the implementation should be done and the heuristics that were self-built need more though put into the
Nambu-Jona-Lasinio model with Wilson fermions
12 pages, 5 figuresWe present a lattice study of a Nambu Jona-Lasinio (NJL) model using Wilson fermions. Four fermion interactions are a natural part of several extensions of the Standard Model, appearing as a low energy description of a more fundamental theory. In models of dynamical electroweak symmetry breaking they are used to endow the Standard Model fermions with masses. In infrared conformal models these interaction, when sufficiently strong, can alter the dynamics of the fixed point, turning the theory into a (near) conformal model with desirable features for model building. As a first step toward the nonperturbative study of these models, we study the phase space of the ungauged NJL model
Wilson Fermions with Four Fermion Interactions
Contribution to proceedings of the 33rd International Symposium on Lattice Field Theory (Lattice 2015), 14-18 July 2015, Kobe, JapanWe present a lattice study of a four fermion theory, known as Nambu Jona-Lasinio (NJL) theory, via Wilson fermions. Four fermion interactions naturally occur in several extensions of the Standard Model as a low energy parameterisation of a more fundamental theory. In models of dynamical electroweak symmetry breaking these operators, at an effective level, are used to endow the Standard Model fermions with masses. Furthermore these operators, when sufficiently strong, can drastically modify the fundamental composite dynamics by, for example, turning a strongly coupled infrared conformal theory into a (near) conformal one with desirable features for model building. As first step, we study spontaneous chiral symmetry breaking for the lattice version of the NJL model
Template Composite Dark Matter : SU(2) gauge theory with 2 fundamental flavours
Contribution to proceedings of the 33rd International Symposium on Lattice Field Theory (Lattice 2015), 14-18 July 2015, Kobe, JapanWe present a non perturbative study of SU(2) gauge theory with two fundamental Dirac flavours. We discuss how the model can be used as a template for composite Dark Matter (DM). We estimate one particular interaction of the DM candidate with the Standard Model : the interaction through photon exchange computing the electric polarizability of the DM candidate. Finally, we briefly discuss the viability of the model given the present experimental constraints
Computing general observables in lattice models with complex actions
The study of QFTs at finite density is hindered by the presence of the so-called sign problem. The action definition of such systems is, in fact, complex-valued making standard importance sampling Monte Carlo methods ineffective. In this work, we shall review the generalized density of states method for complex action systems and the Linear Logarithmic Relaxation algorithm (LLR). We will focus on the recent developments regarding the bias control of the LLR method and the evaluation of general observables in the DoS+LLR framework. Recent results on the well-known relativistic Bose gas will be presented, proving that in our approach the phase factor can be consistently evaluated over hundreds of orders of magnitude. A first exploratory study on the Thirring model in the DoS formalism will be presented as well. © Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0).Peer reviewe
A simple method to optimize HMC performance
7 pages, 5 figures, talk presented at the 34th International Symposium on Lattice Field Theory, 24-30 July 2016, Southampton, UKWe present a practical strategy to optimize a set of Hybrid Monte Carlo parameters in simulations of QCD and QCD-like theories. We specialize to the case of mass-preconditioning, with multiple time-step Omelyan integrators. Starting from properties of the shadow Hamiltonian we show how the optimal setup for the integrator can be chosen once the forces and their variances are measured, assuming that those only depend on the mass-preconditioning parameter
Dilaton EFT framework for lattice data
We develop an effective-field-theory (EFT) framework to analyze the spectra emerging from lattice simulations of a large class of confining gauge theories. Simulations of these theories, for which the light-fermion count is not far below the critical value for transition to infrared conformal behavior, have indicated the presence of a remarkably light singlet scalar particle. We incorporate this particle by including a scalar field in the EFT along with the Nambu-Goldstone bosons (NGB's), and discuss the application of this EFT to lattice data. We highlight the feature that data on the NGB's alone can tightly restrict the form of the scalar interactions. As an example, we apply the framework to lattice data for an SU(3) gauge theory with eight fermion flavors, concluding that the EFT can describe the data well
Meson screening masses from lattice QCD with two light and the strange quark
We present results for screening masses of mesons built from light and
strange quarks in the temperature range of approximately between 140 MeV to 800
MeV. The lattice computations were performed with 2+1 dynamical light and
strange flavors of improved (p4) staggered fermions along a line of constant
physics defined by a pion mass of about 220 MeV and a kaon mass of 500 MeV. The
lattices had temporal extents Nt = 4, 6 and 8 and aspect ratios of Ns / Nt \geq
4. At least up to a temperature of 140 MeV the pseudo-scalar screening mass
remains almost equal to the corresponding zero temperature pseudo-scalar (pole)
mass. At temperatures around 3Tc (Tc being the transition temperature) the
continuum extrapolated pseudo-scalar screening mass approaches very close to
the free continuum result of 2 \pi T from below. On the other hand, at high
temperatures the vector screening mass turns out to be larger than the free
continuum value of 2 \pi T. The pseudo-scalar and the vector screening masses
do not become degenerate even for a temperature as high as 4Tc. Using these
mesonic spatial correlation functions we have also investigated the restoration
of chiral symmetry and the effective restoration of the axial symmetry. We have
found that the vector and the axial-vector screening correlators become
degenerate, indicating chiral symmetry restoration, at a temperature which is
consistent with the QCD transition temperature obtained in previous studies. On
the other hand, the pseudo-scalar and the scalar screening correlators become
degenerate only at temperatures larger than 1.3Tc, indicating that the
effective restoration of the axial symmetry takes place at a temperature larger
than the QCD transition temperature.Comment: Published versio
Determining the conformal window: SU(2) gauge theory with N_f = 4, 6 and 10 fermion flavours
We study the evolution of the coupling in SU(2) gauge field theory with
, 6 and 10 fundamental fermion flavours on the lattice. These values are
chosen close to the expected edges of the conformal window, where the theory
possesses an infrared fixed point. We use improved Wilson-clover action, and
measure the coupling in the Schr\"odinger functional scheme. At four flavours
we observe that the couping grows towards the infrared, implying QCD-like
behaviour, whereas at ten flavours the results are compatible with a Banks-Zaks
type infrared fixed point. The six flavour case remains inconclusive: the
evolution of the coupling is seen to become slower at the infrared, but the
accuracy of the results falls short from fully resolving the fate of the
coupling. We also measure the mass anomalous dimension for the case.Comment: 22 pages, 12 figures. Proof readin
Experimental determination of the interaction potential between a helium atom and the interior surface of a C60 fullerene molecule
The interactions between atoms and molecules may be described by a potential
energy function of the nuclear coordinates. Non-bonded interactions are
dominated by repulsive forces at short range and attractive dispersion forces
at long range. Experimental data on the detailed interaction potentials for
non-bonded interatomic and intermolecular forces is scarce. Here we use
terahertz spectroscopy and inelastic neutron scattering to determine the
potential energy function for the non-bonded interaction between single He
atoms and encapsulating C60 fullerene cages, in the helium endofullerenes 3He
and 4He, synthesised by molecular surgery techniques. The experimentally
derived potential is compared to estimates from quantum chemistry calculations,
and from sums of empirical two-body potentials.Comment: 25 pages, 14 figures, submitted to Journal of Chemical Physic