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true Step-by-step guide to train YOLOv8 models with Ultralytics YOLO with examples of single-GPU and multi-GPU training. Efficient way for object detection training. Ultralytics, YOLOv8, YOLO, object detection, train mode, custom dataset, GPU training, multi-GPU, hyperparameters, CLI examples, Python examples

Train mode is used for training a YOLOv8 model on a custom dataset. In this mode, the model is trained using the specified dataset and hyperparameters. The training process involves optimizing the model's parameters so that it can accurately predict the classes and locations of objects in an image.

!!! tip "Tip"

* YOLOv8 datasets like COCO, VOC, ImageNet and many others automatically download on first use, i.e. `yolo train data=coco.yaml`

Usage Examples

Train YOLOv8n on the COCO128 dataset for 100 epochs at image size 640. See Arguments section below for a full list of training arguments.

!!! example "Single-GPU and CPU Training Example"

Device is determined automatically. If a GPU is available then it will be used, otherwise training will start on CPU.

=== "Python"

    ```python
    from ultralytics import YOLO

    # Load a model
    model = YOLO('yolov8n.yaml')  # build a new model from YAML
    model = YOLO('yolov8n.pt')  # load a pretrained model (recommended for training)
    model = YOLO('yolov8n.yaml').load('yolov8n.pt')  # build from YAML and transfer weights

    # Train the model
    results = model.train(data='coco128.yaml', epochs=100, imgsz=640)
    ```

=== "CLI"

    ```bash
    # Build a new model from YAML and start training from scratch
    yolo detect train data=coco128.yaml model=yolov8n.yaml epochs=100 imgsz=640

    # Start training from a pretrained *.pt model
    yolo detect train data=coco128.yaml model=yolov8n.pt epochs=100 imgsz=640

    # Build a new model from YAML, transfer pretrained weights to it and start training
    yolo detect train data=coco128.yaml model=yolov8n.yaml pretrained=yolov8n.pt epochs=100 imgsz=640
    ```

Multi-GPU Training

The training device can be specified using the device argument. If no argument is passed GPU device=0 will be used if available, otherwise device=cpu will be used.

!!! example "Multi-GPU Training Example"

=== "Python"

    ```python
    from ultralytics import YOLO

    # Load a model
    model = YOLO('yolov8n.pt')  # load a pretrained model (recommended for training)

    # Train the model with 2 GPUs
    results = model.train(data='coco128.yaml', epochs=100, imgsz=640, device=[0, 1])
    ```

=== "CLI"

    ```bash
    # Start training from a pretrained *.pt model using GPUs 0 and 1
    yolo detect train data=coco128.yaml model=yolov8n.pt epochs=100 imgsz=640 device=0,1
    ```

Apple M1 and M2 MPS Training

With the support for Apple M1 and M2 chips integrated in the Ultralytics YOLO models, it's now possible to train your models on devices utilizing the powerful Metal Performance Shaders (MPS) framework. The MPS offers a high-performance way of executing computation and image processing tasks on Apple's custom silicon.

To enable training on Apple M1 and M2 chips, you should specify 'mps' as your device when initiating the training process. Below is an example of how you could do this in Python and via the command line:

!!! example "MPS Training Example"

=== "Python"

    ```python
    from ultralytics import YOLO

    # Load a model
    model = YOLO('yolov8n.pt')  # load a pretrained model (recommended for training)

    # Train the model with 2 GPUs
    results = model.train(data='coco128.yaml', epochs=100, imgsz=640, device='mps')
    ```

=== "CLI"

    ```bash
    # Start training from a pretrained *.pt model using GPUs 0 and 1
    yolo detect train data=coco128.yaml model=yolov8n.pt epochs=100 imgsz=640 device=mps
    ```

While leveraging the computational power of the M1/M2 chips, this enables more efficient processing of the training tasks. For more detailed guidance and advanced configuration options, please refer to the PyTorch MPS documentation.

Resuming Interrupted Trainings

Resuming training from a previously saved state is a crucial feature when working with deep learning models. This can come in handy in various scenarios, like when the training process has been unexpectedly interrupted, or when you wish to continue training a model with new data or for more epochs.

When training is resumed, Ultralytics YOLO loads the weights from the last saved model and also restores the optimizer state, learning rate scheduler, and the epoch number. This allows you to continue the training process seamlessly from where it was left off.

You can easily resume training in Ultralytics YOLO by setting the resume argument to True when calling the train method, and specifying the path to the .pt file containing the partially trained model weights.

Below is an example of how to resume an interrupted training using Python and via the command line:

!!! example "Resume Training Example"

=== "Python"

    ```python
    from ultralytics import YOLO

    # Load a model
    model = YOLO('path/to/last.pt')  # load a partially trained model

    # Resume training
    results = model.train(resume=True)
    ```

=== "CLI"

    ```bash
    # Resume an interrupted training
    yolo train resume model=path/to/last.pt
    ```

By setting resume=True, the train function will continue training from where it left off, using the state stored in the 'path/to/last.pt' file. If the resume argument is omitted or set to False, the train function will start a new training session.

Remember that checkpoints are saved at the end of every epoch by default, or at fixed interval using the save_period argument, so you must complete at least 1 epoch to resume a training run.

Arguments

Training settings for YOLO models refer to the various hyperparameters and configurations used to train the model on a dataset. These settings can affect the model's performance, speed, and accuracy. Some common YOLO training settings include the batch size, learning rate, momentum, and weight decay. Other factors that may affect the training process include the choice of optimizer, the choice of loss function, and the size and composition of the training dataset. It is important to carefully tune and experiment with these settings to achieve the best possible performance for a given task.

Key Value Description
model None path to model file, i.e. yolov8n.pt, yolov8n.yaml
data None path to data file, i.e. coco128.yaml
epochs 100 number of epochs to train for
patience 50 epochs to wait for no observable improvement for early stopping of training
batch 16 number of images per batch (-1 for AutoBatch)
imgsz 640 size of input images as integer
save True save train checkpoints and predict results
save_period -1 Save checkpoint every x epochs (disabled if < 1)
cache False True/ram, disk or False. Use cache for data loading
device None device to run on, i.e. cuda device=0 or device=0,1,2,3 or device=cpu
workers 8 number of worker threads for data loading (per RANK if DDP)
project None project name
name None experiment name
exist_ok False whether to overwrite existing experiment
pretrained False whether to use a pretrained model
optimizer 'auto' optimizer to use, choices=[SGD, Adam, Adamax, AdamW, NAdam, RAdam, RMSProp, auto]
verbose False whether to print verbose output
seed 0 random seed for reproducibility
deterministic True whether to enable deterministic mode
single_cls False train multi-class data as single-class
rect False rectangular training with each batch collated for minimum padding
cos_lr False use cosine learning rate scheduler
close_mosaic 10 (int) disable mosaic augmentation for final epochs (0 to disable)
resume False resume training from last checkpoint
amp True Automatic Mixed Precision (AMP) training, choices=[True, False]
fraction 1.0 dataset fraction to train on (default is 1.0, all images in train set)
profile False profile ONNX and TensorRT speeds during training for loggers
lr0 0.01 initial learning rate (i.e. SGD=1E-2, Adam=1E-3)
lrf 0.01 final learning rate (lr0 * lrf)
momentum 0.937 SGD momentum/Adam beta1
weight_decay 0.0005 optimizer weight decay 5e-4
warmup_epochs 3.0 warmup epochs (fractions ok)
warmup_momentum 0.8 warmup initial momentum
warmup_bias_lr 0.1 warmup initial bias lr
box 7.5 box loss gain
cls 0.5 cls loss gain (scale with pixels)
dfl 1.5 dfl loss gain
pose 12.0 pose loss gain (pose-only)
kobj 2.0 keypoint obj loss gain (pose-only)
label_smoothing 0.0 label smoothing (fraction)
nbs 64 nominal batch size
overlap_mask True masks should overlap during training (segment train only)
mask_ratio 4 mask downsample ratio (segment train only)
dropout 0.0 use dropout regularization (classify train only)
val True validate/test during training

Logging

In training a YOLOv8 model, you might find it valuable to keep track of the model's performance over time. This is where logging comes into play. Ultralytics' YOLO provides support for three types of loggers - Comet, ClearML, and TensorBoard.

To use a logger, select it from the dropdown menu in the code snippet above and run it. The chosen logger will be installed and initialized.

Comet

Comet is a platform that allows data scientists and developers to track, compare, explain and optimize experiments and models. It provides functionalities such as real-time metrics, code diffs, and hyperparameters tracking.

To use Comet:

!!! example ""

=== "Python"
    ```python
    # pip install comet_ml
    import comet_ml
    
    comet_ml.init()
    ```

Remember to sign in to your Comet account on their website and get your API key. You will need to add this to your environment variables or your script to log your experiments.

ClearML

ClearML is an open-source platform that automates tracking of experiments and helps with efficient sharing of resources. It is designed to help teams manage, execute, and reproduce their ML work more efficiently.

To use ClearML:

!!! example ""

=== "Python"
    ```python
    # pip install clearml
    import clearml
    
    clearml.browser_login()
    ```

After running this script, you will need to sign in to your ClearML account on the browser and authenticate your session.

TensorBoard

TensorBoard is a visualization toolkit for TensorFlow. It allows you to visualize your TensorFlow graph, plot quantitative metrics about the execution of your graph, and show additional data like images that pass through it.

To use TensorBoard in Google Colab:

!!! example ""

=== "CLI"
    ```bash
    load_ext tensorboard
    tensorboard --logdir ultralytics/runs  # replace with 'runs' directory
    ```

To use TensorBoard locally run the below command and view results at http://localhost:6006/.

!!! example ""

=== "CLI"
    ```bash
    tensorboard --logdir ultralytics/runs  # replace with 'runs' directory
    ```

This will load TensorBoard and direct it to the directory where your training logs are saved.

After setting up your logger, you can then proceed with your model training. All training metrics will be automatically logged in your chosen platform, and you can access these logs to monitor your model's performance over time, compare different models, and identify areas for improvement.