Keras implementation of RetinaNet object detection as described in Focal Loss for Dense Object Detection by Tsung-Yi Lin, Priya Goyal, Ross Girshick, Kaiming He and Piotr Dollár.
- Clone this repository.
- In the repository, execute
pip install . --user
. Note that due to inconsistencies with howtensorflow
should be installed, this package does not define a dependency ontensorflow
as it will try to install that (which at least on Arch Linux results in an incorrect installation). Please make suretensorflow
is installed as per your systems requirements. Also, make sure Keras 2.1.3 or higher is installed. - Optionally, install
pycocotools
if you want to train / test on the MS COCO dataset by runningpip install --user git+https://github.com/cocodataset/cocoapi.git#subdirectory=PythonAPI
.
An example of testing the network can be seen in this Notebook. In general, inference of the network works as follows:
boxes, scores, labels = model.predict_on_batch(inputs)
Where boxes
are shaped (None, None, 4)
(for (x1, y1, x2, y2)
), scores is shaped (None, None)
(classification score) and labels is shaped (None, None)
(label corresponding to the score).
Loading models can be done in the following manner:
from keras_retinanet.models import load_model
model = load_model('/path/to/model.h5', backbone='resnet50')
Execution time on NVIDIA Pascal Titan X is roughly 75msec for an image of shape 1000x800x3
.
The training procedure of keras-retinanet
works with training models. These are stripped down versions compared to the inference model and only contains the layers necessary for training (regression and classification values). If you wish to do inference on a model (perform object detection on an image), you need to convert the trained model to an inference model. This is done as follows:
# Running directly from the repository:
keras_retinanet/bin/convert_model.py /path/to/training/model.h5 /path/to/save/inference/model.h5
# Using the installed script:
retinanet-convert-model /path/to/training/model.h5 /path/to/save/inference/model.h5
Most scripts (like retinanet-evaluate
and retinanet-evaluate-coco
) also support converting on the fly, using the --convert-model
argument.
keras-retinanet
can be trained using this script.
Note that the train script uses relative imports since it is inside the keras_retinanet
package.
If you want to adjust the script for your own use outside of this repository,
you will need to switch it to use absolute imports.
If you installed keras-retinanet
correctly, the train script will be installed as retinanet-train
.
However, if you make local modifications to the keras-retinanet
repository, you should run the script directly from the repository.
That will ensure that your local changes will be used by the train script.
The default backbone is 'resnet50'. You can change this using the '--backbone=xxx' argument in the running script. xxx can be one of the backbones in resnet models (resnet50, resnet101, resnet152), mobilenet models (mobilenet128_1.0, mobilenet128_0.75, mobilenet160_1.0, etc), densenet models or vgg models. The different options are defined by each model in their corresponding python scripts (resnet.py, mobilenet.py, etc).
Trained models can't be used directly for inference. To convert a trained model to an inference model, check here.
For training on Pascal VOC, run:
# Running directly from the repository:
keras_retinanet/bin/train.py pascal /path/to/VOCdevkit/VOC2007
# Using the installed script:
retinanet-train pascal /path/to/VOCdevkit/VOC2007
For training on MS COCO, run:
# Running directly from the repository:
keras_retinanet/bin/train.py coco /path/to/MS/COCO
# Using the installed script:
retinanet-train coco /path/to/MS/COCO
The pretrained MS COCO model can be downloaded here. Results using the cocoapi
are shown below (note: according to the paper, this configuration should achieve a mAP of 0.357).
Average Precision (AP) @[ IoU=0.50:0.95 | area= all | maxDets=100 ] = 0.345
Average Precision (AP) @[ IoU=0.50 | area= all | maxDets=100 ] = 0.533
Average Precision (AP) @[ IoU=0.75 | area= all | maxDets=100 ] = 0.368
Average Precision (AP) @[ IoU=0.50:0.95 | area= small | maxDets=100 ] = 0.189
Average Precision (AP) @[ IoU=0.50:0.95 | area=medium | maxDets=100 ] = 0.380
Average Precision (AP) @[ IoU=0.50:0.95 | area= large | maxDets=100 ] = 0.465
Average Recall (AR) @[ IoU=0.50:0.95 | area= all | maxDets= 1 ] = 0.301
Average Recall (AR) @[ IoU=0.50:0.95 | area= all | maxDets= 10 ] = 0.482
Average Recall (AR) @[ IoU=0.50:0.95 | area= all | maxDets=100 ] = 0.529
Average Recall (AR) @[ IoU=0.50:0.95 | area= small | maxDets=100 ] = 0.364
Average Recall (AR) @[ IoU=0.50:0.95 | area=medium | maxDets=100 ] = 0.565
Average Recall (AR) @[ IoU=0.50:0.95 | area= large | maxDets=100 ] = 0.666
For training on OID, run:
# Running directly from the repository:
keras_retinanet/bin/train.py oid /path/to/OID
# Using the installed script:
retinanet-train oid /path/to/OID
# You can also specify a list of labels if you want to train on a subset
# by adding the argument 'labels_filter':
keras_retinanet/bin/train.py oid /path/to/OID --labels_filter=Helmet,Tree
For training on KITTI, run:
# Running directly from the repository:
keras_retinanet/bin/train.py kitti /path/to/KITTI
# Using the installed script:
retinanet-train kitti /path/to/KITTI
If you want to prepare the dataset you can use the following script:
https://github.com/NVIDIA/DIGITS/blob/master/examples/object-detection/prepare_kitti_data.py
For training on a [custom dataset], a CSV file can be used as a way to pass the data. See below for more details on the format of these CSV files. To train using your CSV, run:
# Running directly from the repository:
keras_retinanet/bin/train.py csv /path/to/csv/file/containing/annotations /path/to/csv/file/containing/classes
# Using the installed script:
retinanet-train csv /path/to/csv/file/containing/annotations /path/to/csv/file/containing/classes
In general, the steps to train on your own datasets are:
- Create a model by calling for instance
keras_retinanet.models.resnet50_retinanet
and compile it. Empirically, the following compile arguments have been found to work well:
model.compile(
loss={
'regression' : keras_retinanet.losses.smooth_l1(),
'classification': keras_retinanet.losses.focal()
},
optimizer=keras.optimizers.adam(lr=1e-5, clipnorm=0.001)
)
- Create generators for training and testing data (an example is show in
keras_retinanet.preprocessing.PascalVocGenerator
). - Use
model.fit_generator
to start training.
The CSVGenerator
provides an easy way to define your own datasets.
It uses two CSV files: one file containing annotations and one file containing a class name to ID mapping.
The CSV file with annotations should contain one annotation per line. Images with multiple bounding boxes should use one row per bounding box. Note that indexing for pixel values starts at 0. The expected format of each line is:
path/to/image.jpg,x1,y1,x2,y2,class_name
Some images may not contain any labeled objects.
To add these images to the dataset as negative examples,
add an annotation where x1
, y1
, x2
, y2
and class_name
are all empty:
path/to/image.jpg,,,,,
A full example:
/data/imgs/img_001.jpg,837,346,981,456,cow
/data/imgs/img_002.jpg,215,312,279,391,cat
/data/imgs/img_002.jpg,22,5,89,84,bird
/data/imgs/img_003.jpg,,,,,
This defines a dataset with 3 images.
img_001.jpg
contains a cow.
img_002.jpg
contains a cat and a bird.
img_003.jpg
contains no interesting objects/animals.
The class name to ID mapping file should contain one mapping per line. Each line should use the following format:
class_name,id
Indexing for classes starts at 0. Do not include a background class as it is implicit.
For example:
cow,0
cat,1
bird,2
Creating your own dataset does not always work out of the box. There is a debug.py
tool to help find the most common mistakes.
Particularly helpful is the --annotations
flag which displays your annotations on the images from your dataset. Annotations are colored in green when there are anchors available and colored in red when there are no anchors available. If an annotation doesn't have anchors available, it means it won't contribute to training. It is normal for a small amount of annotations to show up in red, but if most or all annotations are red there is cause for concern. The most common issues are that the annotations are too small or too oddly shaped (stretched out).
Example output images using keras-retinanet
are shown below.
- 4k video example. This demo shows the use of keras-retinanet on a 4k input video.
- boring-detector. I suppose not all projects need to solve life's biggest questions. This project detects the "The Boring Company" hats in videos.
- comet.ml. Using keras-retinanet in combination with comet.ml to interactively inspect and compare experiments.
If you have a project based on keras-retinanet
and would like to have it published here, shoot me a message on Slack.
- This repository requires Keras 2.1.3 or higher.
- This repository is tested using OpenCV 3.4.
- This repository is tested using Python 2.7 and 3.6.
Contributions to this project are welcome.
Feel free to join the #keras-retinanet
Keras Slack channel for discussions and questions.