Source code for pyrfu.pyrf.medfilt
#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Built-in imports
from typing import Optional
# 3rd party imports
import numpy as np
import xarray as xr
from numpy.typing import NDArray
from scipy import signal
from xarray.core.dataarray import DataArray
__author__ = "Louis Richard"
__email__ = "louisr@irfu.se"
__copyright__ = "Copyright 2020-2024"
__license__ = "MIT"
__version__ = "2.4.13"
__status__ = "Prototype"
[docs]def medfilt(inp: DataArray, kernel_size: Optional[int] = None) -> DataArray:
r"""Applies a median filter over npts points to inp.
Parameters
----------
inp : DataArray
Time series of the input variable.
kernel_size : int, Optional
Number of points of median filter. Default is a 3-point median filter.
Returns
-------
DataArray
Time series of the median filtered input variable.
Raises
------
TypeError
If inp is not a DataArray.
ValueError
If inp is not 1D, 2D or 3D.
Examples
--------
>>> import numpy
>>> from pyrfu import mms, pyrf
Time interval
>>> tint = ["2019-09-14T07:54:00.000", "2019-09-14T08:11:00.000"]
Spacecraft indices
>>> mms_list = numpy.arange(1,5)
Load magnetic field and electric field
>>> r_mms, b_mms = [[] * 4 for _ in range(2)]
>>> for mms_id in range(1, 5):
>>> r_mms.append(mms.get_data("R_gse", tint, mms_id))
>>> b_mms.append(mms.get_data("B_gse_fgm_srvy_l2", tint, mms_id))
>>>
Compute current density, etc
>>> j_xyz, _, b_xyz, _, _, _ = pyrf.c_4_j(r_mms, b_mms)
Get J sampling frequency
>>> fs = pyrf.calc_fs(j_xyz)
Median filter over 1s
>>> j_xyz = pyrf.medfilt(j_xyz,fs)
"""
# Check input
if not isinstance(inp, xr.DataArray):
raise TypeError("Input must be a DataArray")
# Get number of times
n_times: int = len(inp)
# Check kernel size
if kernel_size is None:
# Set default kernel size to 3
kernel_size = 3
elif kernel_size % 2 == 0:
# If kernel size is even, add 1.
kernel_size += 1
# Check if input is 1D, 2D or 3D
if inp.ndim == 1:
# Add a dimension to the input if it is 1D
inp_data: NDArray[np.float32] = inp.data[:, np.newaxis]
elif inp.ndim == 2:
# Keep input as is if it is 2D
inp_data = inp.data
elif inp.ndim == 3:
# Reshape input if it is 3D to 2D (n_times, 9)
inp_data = np.reshape(inp.data, [n_times, 9])
else:
raise ValueError("Input must be 1D, 2D or 3D")
# Preallocate output
out_data: NDArray[np.float32] = np.zeros(inp_data.shape, dtype=np.float32)
# Apply median filter
for i in range(inp_data.shape[1]):
out_data[:, i] = signal.medfilt(inp_data[:, i], kernel_size)
# Reshape output if input was 3D
if inp_data.shape[1] == 9:
out_data = np.reshape(out_data, [n_times, 3, 3])
# Create output DataArray
out: DataArray = xr.DataArray(
np.squeeze(out_data), coords=inp.coords, dims=inp.dims, attrs=inp.attrs
)
return out