Stress

class py4vasp.data.Stress(*args, **kwargs)

Bases: Mixin, Refinery

The stress acting on the unit cell for selected steps of the simulation.

You can use this class to analyze the stress on the shape of the cell. In particular, you can check whether the stress is small at the end of the calculation.

Examples

If you access a method of this class, the result will depend on the steps that you selected with the [] operator. Without any selection the results from the final step will be used.

>>> calc.stress.read()

To select the results for all steps, you don’t specify the array boundaries.

>>> calc.stress[:].read()

You can also select specific steps or a subset of steps as follows

>>> calc.stress[5].read()
>>> calc.stress[1:6].read()

Attributes Summary

path

Returns the path from which the output is obtained.

Methods Summary

from_data(raw_data)

Create the instance directly from the raw data.

from_file(file)

Read the quantities from the given file.

from_path([path])

Read the quantities from the given path.

print()

Print a string representation of this instance.

read(*args, **kwargs)

Convenient wrapper around to_dict.

to_dict()

Read the stress and associated structural information for one or more selected steps of the trajectory.

Attributes Documentation

path

Returns the path from which the output is obtained.

Methods Documentation

classmethod from_data(raw_data)

Create the instance directly from the raw data.

Use this approach when the data is put into the correct format by other means than reading from the VASP output files. A typical use case is to read the data with from_path and then act on it with some postprocessing and pass the results to this method.

Parameters:

raw_data – The raw data required to produce this Refinery.

Return type:

A Refinery instance to handle the passed data.

classmethod from_file(file)

Read the quantities from the given file.

You want to use this method if you want to avoid using the Calculation wrapper, for example because you renamed the output of the VASP calculation.

Parameters:

file (str or io.BufferedReader) – Filename from which the data is extracted. Alternatively, you can open the file yourself and pass the Reader object. In that case, you need to take care the file is properly closed again and be aware the generated instance of this class becomes unusable after the file is closed.

Returns:

The returned instance handles opening and closing the file for every function called on it, unless a Reader object is passed in which case this is left to the user.

Return type:

Refinery

Notes

VASP produces multiple output files whereas this routine will only link to the single specified file. Prefer from_path routine over this method unless you renamed the VASP output files, because from_path can collate results from multiple files.

classmethod from_path(path=None)

Read the quantities from the given path.

The VASP schema determines the particular files accessed. The files will only be accessed when the data is required for a particular postprocessing call.

Parameters:

path (str or pathlib.Path) – Path to the directory with the outputs of the VASP calculation. If not set explicitly the current directory will be used.

Returns:

The returned instance handles opening and closing the files for every function called on it.

Return type:

Refinery

print()

Print a string representation of this instance.

read(*args, **kwargs)

Convenient wrapper around to_dict. Check that function for examples and optional arguments.

to_dict()

Read the stress and associated structural information for one or more selected steps of the trajectory.

Returns:

Contains the stress for all selected steps and the structural information to know on which cell the stress acts.

Return type:

dict

Examples

If you access this method, the result will depend on the steps of the class that you selected with the [] operator. Without any selection the results from the final step will be used.

>>> calc.stress.to_dict()

To select the results for all steps, you don’t specify the array boundaries.

>>> calc.stress[:].to_dict()

You can also select specific steps or a subset of steps as follows

>>> calc.stress[5].to_dict()
>>> calc.stress[1:6].to_dict()