.. DO NOT EDIT. .. THIS FILE WAS AUTOMATICALLY GENERATED BY SPHINX-GALLERY. .. TO MAKE CHANGES, EDIT THE SOURCE PYTHON FILE: .. "auto_examples/gsd/_01_gsd_iluz.py" .. LINE NUMBERS ARE GIVEN BELOW. .. only:: html .. note:: :class: sphx-glr-download-link-note :ref:`Go to the end ` to download the full example code .. rst-class:: sphx-glr-example-title .. _sphx_glr_auto_examples_gsd__01_gsd_iluz.py: .. _gsd_iluz: GSD Iluz ======== This example shows how to use the GSD Iluz algorithm and some examples on how the results compare to the original matlab implementation. We start by defining some helpers for plotting and loading the data. You can skip them for now and jump directly to "Performance on a single lab trial", if you just want to see how to apply the algorithm. .. GENERATED FROM PYTHON SOURCE LINES 16-20 Plotting Helper --------------- We define a helper function to plot the results of the algorithm. Just ignore this function for now. .. GENERATED FROM PYTHON SOURCE LINES 20-44 .. code-block:: default import matplotlib.pyplot as plt def plot_gsd_outputs(data, **kwargs): fig, ax = plt.subplots() ax.plot(data["acc_x"].to_numpy(), label="acc_x") color_cycle = iter(plt.rcParams["axes.prop_cycle"]) y_max = 1.1 plot_props = [ {"data": v, "label": k, "alpha": 0.2, "ymax": (y_max := y_max - 0.1), "color": next(color_cycle)["color"]} for k, v in kwargs.items() ] for props in plot_props: for gsd in props.pop("data").itertuples(index=False): ax.axvspan(gsd.start, gsd.end, label=props.pop("label", None), **props) ax.legend() return fig, ax .. GENERATED FROM PYTHON SOURCE LINES 45-55 Loading some example data ------------------------- .. note :: More infos about data loading can be found in the :ref:`data loading example `. We load example data from the lab dataset together with the INDIP reference system. We will use the INDIP "WB" output as ground truth. Note, that the "WB" (Walking Bout) output is further processed than a normal "Gait Sequence". This means we expect Gait Sequences to contain some false positives compared to the "WB" output. However, a good gait sequence detection algorithm should have high sensitivity (i.e. contain all the "WBs" of the reference system). .. GENERATED FROM PYTHON SOURCE LINES 55-83 .. code-block:: default import json import pandas as pd from mobgap import PACKAGE_ROOT from mobgap.data import LabExampleDataset lab_example_data = LabExampleDataset(reference_system="INDIP") def load_matlab_output(datapoint): p = datapoint.group_label with ( PACKAGE_ROOT.parent / f"example_data/original_results/gsd_iluz/lab/{p.cohort}/{p.participant_id}/GSDA_Output.json" ).open() as f: original_results = json.load(f)["GSDA_Output"][p.time_measure][p.test][p.trial]["SU"]["LowerBack"]["GSD"] if not isinstance(original_results, list): original_results = [original_results] return ( pd.DataFrame.from_records(original_results).rename( {"GaitSequence_Start": "start", "GaitSequence_End": "end"}, axis=1 )[["start", "end"]] * datapoint.sampling_rate_hz ) .. GENERATED FROM PYTHON SOURCE LINES 84-87 Performance on a single lab trial --------------------------------- Below we apply the algorithm to a lab trail, where we only expect a single gait sequence. .. GENERATED FROM PYTHON SOURCE LINES 87-98 .. code-block:: default from mobgap.gsd import GsdIluz short_trial = lab_example_data.get_subset(cohort="HA", participant_id="001", test="Test5", trial="Trial2") short_trial_matlab_output = load_matlab_output(short_trial) short_trial_reference_parameters = short_trial.reference_parameters_.wb_list short_trial_output = GsdIluz().detect(short_trial.data_ss, sampling_rate_hz=short_trial.sampling_rate_hz) print("Reference Parameters:\n\n", short_trial_reference_parameters) print("\nMatlab Output:\n\n", short_trial_matlab_output) print("\nPython Output:\n\n", short_trial_output.gs_list_) .. rst-class:: sphx-glr-script-out .. code-block:: none Reference Parameters: start end ... avg_stride_length_m termination_reason wb_id ... 1 392 862 ... 1.211187 Pause [1 rows x 9 columns] Matlab Output: start end 0 299.0 1049.0 Python Output: start end 0 150 1052 .. GENERATED FROM PYTHON SOURCE LINES 99-102 When we plot the output, we can see that the python version is a little more sensitive than the matlab version. It includes a section of the signal before the region classified as WB by the reference system. Both algorithm implementations produce a gait sequence that extends beyond the end of the reference system. .. GENERATED FROM PYTHON SOURCE LINES 102-111 .. code-block:: default fig, ax = plot_gsd_outputs( short_trial.data_ss, reference=short_trial_reference_parameters, matlab=short_trial_matlab_output, python=short_trial_output.gs_list_, ) fig.show() .. image-sg:: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_001.png :alt: 01 gsd iluz :srcset: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_001.png :class: sphx-glr-single-img .. GENERATED FROM PYTHON SOURCE LINES 112-116 Performance on a longer lab trial --------------------------------- Below we apply the algorithm to a lab trail that contains activities of daily living. This is a more challenging scenario, as we expect multiple gait sequences. .. GENERATED FROM PYTHON SOURCE LINES 116-126 .. code-block:: default long_trial = lab_example_data.get_subset(cohort="MS", participant_id="001", test="Test11", trial="Trial1") long_trial_matlab_output = load_matlab_output(long_trial) long_trial_reference_parameters = long_trial.reference_parameters_.wb_list long_trial_output = GsdIluz().detect(long_trial.data_ss, sampling_rate_hz=long_trial.sampling_rate_hz) print("Reference Parameters:\n\n", long_trial_reference_parameters) print("\nMatlab Output:\n\n", long_trial_matlab_output) print("\nPython Output:\n\n", long_trial_output.gs_list_) .. rst-class:: sphx-glr-script-out .. code-block:: none Reference Parameters: start end ... avg_stride_length_m termination_reason wb_id ... 1 1019 1768 ... 0.942678 Pause 2 4534 5549 ... 0.483923 Pause 3 9665 10569 ... 0.506458 Pause 4 12337 14633 ... 0.803933 Pause 5 20151 20982 ... 0.507484 Pause 6 21378 22129 ... 0.599360 Pause [6 rows x 9 columns] Matlab Output: start end 0 899.0 1799.0 1 13049.0 13949.0 2 14099.0 14849.0 3 20249.0 21149.0 4 21299.0 22349.0 Python Output: start end 0 750 1652 2 4650 6152 5 12900 14852 6 20100 21152 7 21300 22502 .. GENERATED FROM PYTHON SOURCE LINES 127-129 When we plot the output, we can see again that the python version is more sensitive. It detects longer gait sequences and even one entire gait sequence that is not detected by the matlab version. .. GENERATED FROM PYTHON SOURCE LINES 129-138 .. code-block:: default fig, _ = plot_gsd_outputs( long_trial.data_ss, reference=long_trial_reference_parameters, matlab=long_trial_matlab_output, python=long_trial_output.gs_list_, ) fig.show() .. image-sg:: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_002.png :alt: 01 gsd iluz :srcset: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_002.png :class: sphx-glr-single-img .. GENERATED FROM PYTHON SOURCE LINES 139-150 Changing the parameters ----------------------- The Python version aims to expose all relevant parameters of the algorithm. The `GsdlIluz` algorithm has a lot of parameters that can be modified. Finding a combination of parameters that works well for all scenarios is difficult. Below we show, just how to modify them in general. We modify one of the basic parameters, the window length. This can effect all parts of the output. In this case, we can see that all GSDs are slightly longer and that we now detect a gait sequence that was not detected before. .. GENERATED FROM PYTHON SOURCE LINES 150-167 .. code-block:: default long_trial_output_modified = GsdIluz(window_length_s=5, window_overlap=0.8).detect( long_trial.data_ss, sampling_rate_hz=long_trial.sampling_rate_hz ) print("Reference Parameters:\n\n", long_trial_reference_parameters) print("\nPython Output:\n\n", long_trial_output.gs_list_) print("\nPython Output Modified:\n\n", long_trial_output_modified.gs_list_) fig, _ = plot_gsd_outputs( long_trial.data_ss, reference=long_trial_reference_parameters, python=long_trial_output.gs_list_, python_modified=long_trial_output_modified.gs_list_, ) fig.show() .. image-sg:: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_003.png :alt: 01 gsd iluz :srcset: /auto_examples/gsd/images/sphx_glr__01_gsd_iluz_003.png :class: sphx-glr-single-img .. rst-class:: sphx-glr-script-out .. code-block:: none Reference Parameters: start end ... avg_stride_length_m termination_reason wb_id ... 1 1019 1768 ... 0.942678 Pause 2 4534 5549 ... 0.483923 Pause 3 9665 10569 ... 0.506458 Pause 4 12337 14633 ... 0.803933 Pause 5 20151 20982 ... 0.507484 Pause 6 21378 22129 ... 0.599360 Pause [6 rows x 9 columns] Python Output: start end 0 750 1652 2 4650 6152 5 12900 14852 6 20100 21152 7 21300 22502 Python Output Modified: start end 0 600 1902 1 4500 6202 2 9700 10302 3 12700 14902 4 20100 22702 .. GENERATED FROM PYTHON SOURCE LINES 168-172 Evaluation of the algorithm against a reference -------------------------------------------------- To quantify how the Python output compares to the reference labels, we are providing a range of evaluation functions. See the :ref:`example on GSD evaluation ` for more details. .. rst-class:: sphx-glr-timing **Total running time of the script:** (0 minutes 4.628 seconds) **Estimated memory usage:** 60 MB .. _sphx_glr_download_auto_examples_gsd__01_gsd_iluz.py: .. only:: html .. container:: sphx-glr-footer sphx-glr-footer-example .. container:: sphx-glr-download sphx-glr-download-python :download:`Download Python source code: _01_gsd_iluz.py <_01_gsd_iluz.py>` .. container:: sphx-glr-download sphx-glr-download-jupyter :download:`Download Jupyter notebook: _01_gsd_iluz.ipynb <_01_gsd_iluz.ipynb>` .. only:: html .. rst-class:: sphx-glr-signature `Gallery generated by Sphinx-Gallery `_