mot-metrics / my_metricv2.py
bascobasculino's picture
a
e9e38c2
raw
history blame
8.89 kB
# Copyright 2020 The HuggingFace Datasets Authors and the current dataset script contributor.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import evaluate
import datasets
import motmetrics as mm
import numpy as np
_CITATION = """\
@InProceedings{huggingface:module,
title = {A great new module},
authors={huggingface, Inc.},
year={2020}
}\
@article{milan2016mot16,
title={MOT16: A benchmark for multi-object tracking},
author={Milan, Anton and Leal-Taix{\'e}, Laura and Reid, Ian and Roth, Stefan and Schindler, Konrad},
journal={arXiv preprint arXiv:1603.00831},
year={2016}
}
"""
_DESCRIPTION = """\
The MOT Metrics module is designed to evaluate multi-object tracking (MOT)
algorithms by computing various metrics based on predicted and ground truth bounding
boxes. It serves as a crucial tool in assessing the performance of MOT systems,
aiding in the iterative improvement of tracking algorithms."""
_KWARGS_DESCRIPTION = """
Calculates how good are predictions given some references, using certain scores
Args:
predictions: list of predictions to score. Each predictions
should be a string with tokens separated by spaces.
references: list of reference for each prediction. Each
reference should be a string with tokens separated by spaces.
max_iou (`float`, *optional*):
If specified, this is the minimum Intersection over Union (IoU) threshold to consider a detection as a true positive.
Default is 0.5.
Returns:
summary: pandas.DataFrame with the following columns:
- idf1 (IDF1 Score): The F1 score for the identity assignment, computed as 2 * (IDP * IDR) / (IDP + IDR).
- idp (ID Precision): Identity Precision, representing the ratio of correctly assigned identities to the total number of predicted identities.
- idr (ID Recall): Identity Recall, representing the ratio of correctly assigned identities to the total number of ground truth identities.
- recall: Recall, computed as the ratio of the number of correctly tracked objects to the total number of ground truth objects.
- precision: Precision, computed as the ratio of the number of correctly tracked objects to the total number of predicted objects.
- num_unique_objects: Total number of unique objects in the ground truth.
- mostly_tracked: Number of objects that are mostly tracked throughout the sequence.
- partially_tracked: Number of objects that are partially tracked but not mostly tracked.
- mostly_lost: Number of objects that are mostly lost throughout the sequence.
- num_false_positives: Number of false positive detections (predicted objects not present in the ground truth).
- num_misses: Number of missed detections (ground truth objects not detected in the predictions).
- num_switches: Number of identity switches.
- num_fragmentations: Number of fragmented objects (objects that are broken into multiple tracks).
- mota (MOTA - Multiple Object Tracking Accuracy): Overall tracking accuracy, computed as 1 - ((num_false_positives + num_misses + num_switches) / num_unique_objects).
- motp (MOTP - Multiple Object Tracking Precision): Average precision of the object localization, computed as the mean of the localization errors of correctly detected objects.
- num_transfer: Number of track transfers.
- num_ascend: Number of ascended track IDs.
- num_migrate: Number of track ID migrations.
Examples:
>>> import numpy as np
>>> module = evaluate.load("bascobasculino/my_metricv2")
>>> predicted =[
[1,1,10,20,30,40,0.85],
[1,2,50,60,70,80,0.92],
[1,3,80,90,100,110,0.75],
[2,1,15,25,35,45,0.78],
[2,2,55,65,75,85,0.95],
[3,1,20,30,40,50,0.88],
[3,2,60,70,80,90,0.82],
[4,1,25,35,45,55,0.91],
[4,2,65,75,85,95,0.89]
]
>>> ground_truth = [
[1, 1, 10, 20, 30, 40],
[1, 2, 50, 60, 70, 80],
[1, 3, 85, 95, 105, 115],
[2, 1, 15, 25, 35, 45],
[2, 2, 55, 65, 75, 85],
[3, 1, 20, 30, 40, 50],
[3, 2, 60, 70, 80, 90],
[4, 1, 25, 35, 45, 55],
[5, 1, 30, 40, 50, 60],
[5, 2, 70, 80, 90, 100]
]
>>> predicted = [np.array(a) for a in predicted]
>>> ground_truth = [np.array(a) for a in ground_truth]
>>> results = module._compute(predictions=predicted, references=ground_truth, max_iou=0.5)
>>> print(results)
{'idf1': 0.8421052631578947, 'idp': 0.8888888888888888, 'idr': 0.8, 'recall': 0.8, 'precision': 0.8888888888888888,
'num_unique_objects': 3,'mostly_tracked': 2, 'partially_tracked': 1, 'mostly_lost': 0, 'num_false_positives': 1,
'num_misses': 2, 'num_switches': 0, 'num_fragmentations': 0, 'mota': 0.7, 'motp': 0.02981870229007634,
'num_transfer': 0, 'num_ascend': 0, 'num_migrate': 0}
"""
@evaluate.utils.file_utils.add_start_docstrings(_DESCRIPTION, _KWARGS_DESCRIPTION)
class MyMetricv2(evaluate.Metric):
"""TODO: Short description of my evaluation module."""
def _info(self):
# TODO: Specifies the evaluate.EvaluationModuleInfo object
return evaluate.MetricInfo(
# This is the description that will appear on the modules page.
module_type="metric",
description=_DESCRIPTION,
citation=_CITATION,
inputs_description=_KWARGS_DESCRIPTION,
# This defines the format of each prediction and reference
features=datasets.Features({
"predictions": datasets.Sequence(
datasets.Sequence(datasets.Value("float"))
),
"references": datasets.Sequence(
datasets.Sequence(datasets.Value("float"))
)
}),
# Additional links to the codebase or references
codebase_urls=["http://github.com/path/to/codebase/of/new_module"],
reference_urls=["http://path.to.reference.url/new_module"]
)
def _download_and_prepare(self, dl_manager):
"""Optional: download external resources useful to compute the scores"""
# TODO: Download external resources if needed
pass
def _compute(self, predictions, references):
"""Returns the scores"""
# TODO: Compute the different scores of the module
return calculate(predictions, references)
def calculate(predictions, references, max_iou: float = 0.5):
"""Returns the scores"""
try:
np_predictions = np.array(predictions)
except:
raise ValueError("The predictions should be a list of np.arrays in the format [frame number, object id, bb_left, bb_top, bb_width, bb_height, confidence]")
try:
np_references = np.array(references)
except:
raise ValueError("The references should be a list of np.arrays in the format [frame number, object id, bb_left, bb_top, bb_width, bb_height]")
if np_predictions.shape[1] != 7:
raise ValueError("The predictions should be a list of np.arrays in the format [frame number, object id, bb_left, bb_top, bb_width, bb_height, confidence]")
if np_references.shape[1] != 6:
raise ValueError("The references should be a list of np.arrays in the format [frame number, object id, bb_left, bb_top, bb_width, bb_height]")
if np_predictions[:, 0].min() <= 0:
raise ValueError("The frame number in the predictions should be a positive integer")
if np_references[:, 0].min() <= 0:
raise ValueError("The frame number in the references should be a positive integer")
num_frames = max(np_references[:, 0].max(), np_predictions[:, 0].max())
acc = mm.MOTAccumulator(auto_id=True)
for i in range(1, num_frames+1):
preds = np_predictions[np_predictions[:, 0] == i, 1:6]
refs = np_references[np_references[:, 0] == i, 1:6]
C = mm.distances.iou_matrix(refs[:,1:], preds[:,1:], max_iou = max_iou)
acc.update(refs[:,0].astype('int').tolist(), preds[:,0].astype('int').tolist(), C)
mh = mm.metrics.create()
summary = mh.compute(acc).to_dict()
for key in summary:
summary[key] = summary[key][0]
return summary