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📚 This guide explains how to train your own custom dataset with YOLOv5 🚀.
UPDATED 26 March 2023.
Before You Start
Clone repo and install requirements.txt in a Python>=3.7.0 environment, including PyTorch>=1.7. Models and datasets download automatically from the latest YOLOv5 release.
git clone https://github.com/ultralytics/yolov5 # clone
cd yolov5
pip install -r requirements.txt # install
Train On Custom Data
Creating a custom model to detect your objects is an iterative process of collecting and organizing images, labeling your objects of interest, training a model, deploying it into the wild to make predictions, and then using that deployed model to collect examples of edge cases to repeat and improve.
1. Create Dataset
YOLOv5 models must be trained on labelled data in order to learn classes of objects in that data. There are two options for creating your dataset before you start training:
Use Roboflow to manage your dataset in YOLO format
1.1 Collect Images
Your model will learn by example. Training on images similar to the ones it will see in the wild is of the utmost importance. Ideally, you will collect a wide variety of images from the same configuration (camera, angle, lighting, etc.) as you will ultimately deploy your project.
If this is not possible, you can start from a public dataset to train your initial model and then sample images from the wild during inference to improve your dataset and model iteratively.
1.2 Create Labels
Once you have collected images, you will need to annotate the objects of interest to create a ground truth for your model to learn from.
Roboflow Annotate is a simple web-based tool for managing and labeling your images with your team and exporting them in YOLOv5's annotation format.
1.3 Prepare Dataset for YOLOv5
Whether you label your images with Roboflow or not, you can use it to convert your dataset into YOLO format, create a YOLOv5 YAML configuration file, and host it for importing into your training script.
Create a free Roboflow account
and upload your dataset to a Public
workspace, label any unannotated images,
then generate and export a version of your dataset in YOLOv5 Pytorch
format.
Note: YOLOv5 does online augmentation during training, so we do not recommend applying any augmentation steps in Roboflow for training with YOLOv5. But we recommend applying the following preprocessing steps:
- Auto-Orient - to strip EXIF orientation from your images.
- Resize (Stretch) - to the square input size of your model (640x640 is the YOLOv5 default).
Generating a version will give you a point in time snapshot of your dataset so you can always go back and compare your future model training runs against it, even if you add more images or change its configuration later.
Export in YOLOv5 Pytorch
format, then copy the snippet into your training
script or notebook to download your dataset.
Now continue with 2. Select a Model
.
Or manually prepare your dataset
1.1 Create dataset.yaml
COCO128 is an example small tutorial dataset composed of the first 128 images in COCO train2017. These same 128 images are used for both training and validation to verify our training pipeline is capable of overfitting. data/coco128.yaml, shown below, is the dataset config file that defines 1) the dataset root directory path
and relative paths to train
/ val
/ test
image directories (or *.txt files with image paths) and 2) a class names
dictionary:
# Train/val/test sets as 1) dir: path/to/imgs, 2) file: path/to/imgs.txt, or 3) list: [path/to/imgs1, path/to/imgs2, ..]
path: ../datasets/coco128 # dataset root dir
train: images/train2017 # train images (relative to 'path') 128 images
val: images/train2017 # val images (relative to 'path') 128 images
test: # test images (optional)
# Classes (80 COCO classes)
names:
0: person
1: bicycle
2: car
...
77: teddy bear
78: hair drier
79: toothbrush
1.2 Create Labels
After using a tool like Roboflow Annotate to label your images, export your labels to YOLO format, with one *.txt
file per image (if no objects in image, no *.txt
file is required). The *.txt
file specifications are:
- One row per object
- Each row is
class x_center y_center width height
format. - Box coordinates must be in normalized xywh format (from 0 - 1). If your boxes are in pixels, divide
x_center
andwidth
by image width, andy_center
andheight
by image height. - Class numbers are zero-indexed (start from 0).
The label file corresponding to the above image contains 2 persons (class 0
) and a tie (class 27
):
1.3 Organize Directories
Organize your train and val images and labels according to the example below. YOLOv5 assumes /coco128
is inside a /datasets
directory next to the /yolov5
directory. YOLOv5 locates labels automatically for each image by replacing the last instance of /images/
in each image path with /labels/
. For example:
../datasets/coco128/images/im0.jpg # image
../datasets/coco128/labels/im0.txt # label
2. Select a Model
Select a pretrained model to start training from. Here we select YOLOv5s, the second-smallest and fastest model available. See our README table for a full comparison of all models.
3. Train
Train a YOLOv5s model on COCO128 by specifying dataset, batch-size, image size and either pretrained --weights yolov5s.pt
(recommended), or randomly initialized --weights '' --cfg yolov5s.yaml
(not recommended). Pretrained weights are auto-downloaded from the latest YOLOv5 release.
python train.py --img 640 --epochs 3 --data coco128.yaml --weights yolov5s.pt
!!! tip "Tip"
💡 Add `--cache ram` or `--cache disk` to speed up training (requires significant RAM/disk resources).
!!! tip "Tip"
💡 Always train from a local dataset. Mounted or network drives like Google Drive will be very slow.
All training results are saved to runs/train/
with incrementing run directories, i.e. runs/train/exp2
, runs/train/exp3
etc. For more details see the Training section of our tutorial notebook.
4. Visualize
Comet Logging and Visualization 🌟 NEW
Comet is now fully integrated with YOLOv5. Track and visualize model metrics in real time, save your hyperparameters, datasets, and model checkpoints, and visualize your model predictions with Comet Custom Panels! Comet makes sure you never lose track of your work and makes it easy to share results and collaborate across teams of all sizes!
Getting started is easy:
pip install comet_ml # 1. install
export COMET_API_KEY=<Your API Key> # 2. paste API key
python train.py --img 640 --epochs 3 --data coco128.yaml --weights yolov5s.pt # 3. train
To learn more about all the supported Comet features for this integration, check out the Comet Tutorial. If you'd like to learn more about Comet, head over to our documentation. Get started by trying out the Comet Colab Notebook:
ClearML Logging and Automation 🌟 NEW
ClearML is completely integrated into YOLOv5 to track your experimentation, manage dataset versions and even remotely execute training runs. To enable ClearML:
pip install clearml
- run
clearml-init
to connect to a ClearML server (deploy your own open-source server here, or use our free hosted server here)
You'll get all the great expected features from an experiment manager: live updates, model upload, experiment comparison etc. but ClearML also tracks uncommitted changes and installed packages for example. Thanks to that ClearML Tasks (which is what we call experiments) are also reproducible on different machines! With only 1 extra line, we can schedule a YOLOv5 training task on a queue to be executed by any number of ClearML Agents (workers).
You can use ClearML Data to version your dataset and then pass it to YOLOv5 simply using its unique ID. This will help you keep track of your data without adding extra hassle. Explore the ClearML Tutorial for details!
Local Logging
Training results are automatically logged with Tensorboard and CSV loggers to runs/train
, with a new experiment directory created for each new training as runs/train/exp2
, runs/train/exp3
, etc.
This directory contains train and val statistics, mosaics, labels, predictions and augmented mosaics, as well as metrics and charts including precision-recall (PR) curves and confusion matrices.
Results file results.csv
is updated after each epoch, and then plotted as results.png
(below) after training completes. You can also plot any results.csv
file manually:
from utils.plots import plot_results
plot_results('path/to/results.csv') # plot 'results.csv' as 'results.png'
Next Steps
Once your model is trained you can use your best checkpoint best.pt
to:
- Run CLI or Python inference on new images and videos
- Validate accuracy on train, val and test splits
- Export to TensorFlow, Keras, ONNX, TFlite, TF.js, CoreML and TensorRT formats
- Evolve hyperparameters to improve performance
- Improve your model by sampling real-world images and adding them to your dataset
Environments
YOLOv5 may be run in any of the following up-to-date verified environments (with all dependencies including CUDA/CUDNN, Python and PyTorch preinstalled):
- Notebooks with free GPU:
- Google Cloud Deep Learning VM. See GCP Quickstart Guide
- Amazon Deep Learning AMI. See AWS Quickstart Guide
- Docker Image. See Docker Quickstart Guide
Status
If this badge is green, all YOLOv5 GitHub Actions Continuous Integration (CI) tests are currently passing. CI tests verify correct operation of YOLOv5 training, validation, inference, export and benchmarks on macOS, Windows, and Ubuntu every 24 hours and on every commit.