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Variational Monte Carlo solver template for FYS4411

Example class structure for the first VMC project of FYS4411 (spring 2023). You may, if you wish, fork this repository and make it the basis of your project. If you choose to do this, you will have to implement a lot of the crucial functions yourself. The relevant functions you need to implement are spread throughout the project, but they are all commented with a note saying what each function should do.

Please note that this is only a start, and when you have implemented all of these functions you will only have completed the first exercise. However, once this is done, you will have a very good basis for further work, and adding functionality will be easier with a good class structure.

If you want to write your own code from scratch, you are of course welcome to do so, and feel free to use this code as inspiration for your own class structure.

  • If you choose to use this code as a basis for your work, the first thing you should do is fork it, pull it down to your computer, and make sure it compiles and runs. See the next section on how to compile and run the project. After this you should spend at least 10 minutes looking at the structure and familiarizing yourself with how the classes interact with eachother.
  • A good way to do this may be to simply start at the top of the main.cpp file, and go through all the calls to the System class functions. Consider also the base classes WaveFunction, Hamiltonian, MonteCarlo and the function in initialstate.h, and see which functions are virtual (i.e., functions that NEED to be implemented by any sub-class).
  • You can skip over the output function in the Sampler class and the entire Random class in the beginning.

Compiling and running the project

The recommend way to compile this project is by using CMake to create a Makefile that you can then run. You can install CMake through one of the Linux package managers, e.g., apt install cmake, pacman -S cmake, etc. For Mac you can install using brew install cmake. Other ways of installing are shown here: https://cmake.org/install/.

Compiling the project using CMake

In a Linux/Mac terminal this can be done by the following commands

# Create build-directory
mkdir build

# Move into the build-directory
cd build

# Run CMake to create a Makefile
cmake ../

# Make the Makefile using two threads
make -j2

# Move the executable to the top-directory
mv vmc ..

Or, simply run the script compile_project via

./compile_project

and the same set of commands are done for you. Now the project can be run by executing

./vmc

in the top-directory.

Cleaning the directory

Run make clean in the top-directory to remove the executable vmc and the build-directory.

Windows

Compilation of the project using Windows should work using CMake as it is OS-independent, but make does not work on Windows so the compile_project-script will not work.

Completing the missing parts

Here follows a suggestion for how you can work to complete the missing parts of the code:

  • Start by implementing the SimpleGaussian wave function: Write the evaluate function. Assume for now that the number of particles is always one, and the number of dimensions is always one. Next, compute the Laplacian analytically, and implement the computeDoubleDerivative function.
  • Secondly, use the Random class (or your own favorite random number generator, should you have one) to implement the missing part of the setupRandomUniformInitialState function.
  • Next, implement the metropolisStep function in the System class. Implement also the small missing part of the runMetropolisSteps function.
  • Now, the last big thing needed is to implement the energy calculation. This is done by the Hamiltonian sub-class HarmonicOscillator. Here you will have to use the Laplacian you calculated for the wave function earlier.
  • Now the code should be functioning and you should see (somewhat) reasonable results. Try to set the oscillator frequency to 1 and calculate analytically the energy of the oscillator. Recall the form of the ground state wave function of the harmonic oscillator, and set the parameter alpha accordingly. What is the resulting energy?
  • If this energy is NOT correct, the last bit missing is to take a look at the computeAverages function in the Sampler class. What is missing here?

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Example class structure for use in FYS4411: Quantum mechanical systems at UiO.

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