Physically correct simulation of 2D-waves
UPDATED VERSION ON GITHUB! http://github.com/AtiX/wavesim This is a physically correct simulation of waves on a surface, for example water-waves. It can also be used to simulate Microwaves, and has features like the support for different refraction indices, different wave sources and custom borders. Therefore, experiments like the double-slit-experiment can be easily simulated.
Software developed for the analysis of Neutron Reflectivity data.
self-consistent schrodinger-poisson code for core-shell nanowires
PAMELA (Pseudospectral Analysis Method with Exchange & Local Approximations) is a self-contained suite of MATLAB codes that can calculate electronic energies, densities, wavefunctions, and band-bending diagrams within a self-consistent Schrödinger-Poisson formalism.
Calculates multiple forces in various angles.
This force calculator is the same as the Java Force Calculator with the bugs removed.
Convertit différentes unitées de mesures
Programmé en VB.NET, cet outil convertit des unitées de durée, d'énergie, de longueur, de poids, de superficie, de température, de vitesse ou de volume.
An ideal gas simulator 2D developed in Java
Virtual Physics Laboratory - PhenoSim3D
PhenoSim3D is an application that presents computer simulations of real physical experiments, which could be used for demonstrating laws and effects in the field of Physics. Unlike real experiments, the simulations with PhenoSim3D could be done in a time convenient for the user; in addition, the greater data precision makes the phenomena analysis understandable, and due to the lack of external factors PhenoSim3D allows for repetition of the experiments without changes in the results. The application is suitable for use in class, during self-preparation and is accessible to students with special educational needs.
Converts temperature from fahrenheit to celcius and back.
Designed by B.J Erasmus and written in java.
Dynamics of quantum systems, controlled by external fields
WavePacket is a program package for numerical simulation of quantum-mechanical wavepacket dynamics for distinguishable particles. It can be used to solve one or more (i.e. coupled channels) time-independent or time-dependent (linear) Schrödinger and Liouville-von Neumann-equations. Optionally accounting for the interaction with external electric fields within the semiclassical dipole approximation, WavePacket can simulate modern experiments using ultrashort light pulses in photo-induced physics or chemistry, including optimal control. The extended graphical capabilities allow visualization 'on the fly', including Wigner transforms to phase space. WavePacket is especially suitable for teaching of quantum mechanics as well as for research projects in physics and chemistry, see also http://www.youtube.com/channel/UC1-0XnOHS0cE1H2pjvOsSBA While the Matlab version is already in a stable and mature state, the C++ version is still under construction aiming at an object-oriented rewrite.
Finding the hyper space particle :d
Merging neuronal nets with attractor visualisation to show the unknown particle, which makes travel much faster. https://projects.zoho.com/portal/surfingjoomla#myworkcalendar