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true Explore Meituan YOLOv6, a top-tier object detector balancing speed and accuracy. Learn about its unique features and performance metrics on Ultralytics Docs. Meituan YOLOv6, object detection, real-time applications, BiC module, Anchor-Aided Training, COCO dataset, high-performance models, Ultralytics Docs

Meituan YOLOv6

Overview

Meituan YOLOv6 is a cutting-edge object detector that offers remarkable balance between speed and accuracy, making it a popular choice for real-time applications. This model introduces several notable enhancements on its architecture and training scheme, including the implementation of a Bi-directional Concatenation (BiC) module, an anchor-aided training (AAT) strategy, and an improved backbone and neck design for state-of-the-art accuracy on the COCO dataset.

Meituan YOLOv6 Model example image Overview of YOLOv6. Model architecture diagram showing the redesigned network components and training strategies that have led to significant performance improvements. (a) The neck of YOLOv6 (N and S are shown). Note for M/L, RepBlocks is replaced with CSPStackRep. (b) The structure of a BiC module. (c) A SimCSPSPPF block. (source).

Key Features

  • Bidirectional Concatenation (BiC) Module: YOLOv6 introduces a BiC module in the neck of the detector, enhancing localization signals and delivering performance gains with negligible speed degradation.
  • Anchor-Aided Training (AAT) Strategy: This model proposes AAT to enjoy the benefits of both anchor-based and anchor-free paradigms without compromising inference efficiency.
  • Enhanced Backbone and Neck Design: By deepening YOLOv6 to include another stage in the backbone and neck, this model achieves state-of-the-art performance on the COCO dataset at high-resolution input.
  • Self-Distillation Strategy: A new self-distillation strategy is implemented to boost the performance of smaller models of YOLOv6, enhancing the auxiliary regression branch during training and removing it at inference to avoid a marked speed decline.

Performance Metrics

YOLOv6 provides various pre-trained models with different scales:

  • YOLOv6-N: 37.5% AP on COCO val2017 at 1187 FPS with NVIDIA Tesla T4 GPU.
  • YOLOv6-S: 45.0% AP at 484 FPS.
  • YOLOv6-M: 50.0% AP at 226 FPS.
  • YOLOv6-L: 52.8% AP at 116 FPS.
  • YOLOv6-L6: State-of-the-art accuracy in real-time.

YOLOv6 also provides quantized models for different precisions and models optimized for mobile platforms.

Usage Examples

This example provides simple YOLOv6 training and inference examples. For full documentation on these and other modes see the Predict, Train, Val and Export docs pages.

!!! Example

=== "Python"

    PyTorch pretrained `*.pt` models as well as configuration `*.yaml` files can be passed to the `YOLO()` class to create a model instance in python:

    ```python
    from ultralytics import YOLO

    # Build a YOLOv6n model from scratch
    model = YOLO("yolov6n.yaml")

    # Display model information (optional)
    model.info()

    # Train the model on the COCO8 example dataset for 100 epochs
    results = model.train(data="coco8.yaml", epochs=100, imgsz=640)

    # Run inference with the YOLOv6n model on the 'bus.jpg' image
    results = model("path/to/bus.jpg")
    ```

=== "CLI"

    CLI commands are available to directly run the models:

    ```bash
    # Build a YOLOv6n model from scratch and train it on the COCO8 example dataset for 100 epochs
    yolo train model=yolov6n.yaml data=coco8.yaml epochs=100 imgsz=640

    # Build a YOLOv6n model from scratch and run inference on the 'bus.jpg' image
    yolo predict model=yolov6n.yaml source=path/to/bus.jpg
    ```

Supported Tasks and Modes

The YOLOv6 series offers a range of models, each optimized for high-performance Object Detection. These models cater to varying computational needs and accuracy requirements, making them versatile for a wide array of applications.

Model Type Pre-trained Weights Tasks Supported Inference Validation Training Export
YOLOv6-N yolov6-n.pt Object Detection
YOLOv6-S yolov6-s.pt Object Detection
YOLOv6-M yolov6-m.pt Object Detection
YOLOv6-L yolov6-l.pt Object Detection
YOLOv6-L6 yolov6-l6.pt Object Detection

This table provides a detailed overview of the YOLOv6 model variants, highlighting their capabilities in object detection tasks and their compatibility with various operational modes such as Inference, Validation, Training, and Export. This comprehensive support ensures that users can fully leverage the capabilities of YOLOv6 models in a broad range of object detection scenarios.

Citations and Acknowledgements

We would like to acknowledge the authors for their significant contributions in the field of real-time object detection:

!!! Quote ""

=== "BibTeX"

    ```bibtex
    @misc{li2023yolov6,
          title={YOLOv6 v3.0: A Full-Scale Reloading},
          author={Chuyi Li and Lulu Li and Yifei Geng and Hongliang Jiang and Meng Cheng and Bo Zhang and Zaidan Ke and Xiaoming Xu and Xiangxiang Chu},
          year={2023},
          eprint={2301.05586},
          archivePrefix={arXiv},
          primaryClass={cs.CV}
    }
    ```

The original YOLOv6 paper can be found on arXiv. The authors have made their work publicly available, and the codebase can be accessed on GitHub. We appreciate their efforts in advancing the field and making their work accessible to the broader community.

FAQ

What is Meituan YOLOv6 and what makes it unique?

Meituan YOLOv6 is a state-of-the-art object detector that balances speed and accuracy, ideal for real-time applications. It features notable architectural enhancements like the Bi-directional Concatenation (BiC) module and an Anchor-Aided Training (AAT) strategy. These innovations provide substantial performance gains with minimal speed degradation, making YOLOv6 a competitive choice for object detection tasks.

How does the Bi-directional Concatenation (BiC) Module in YOLOv6 improve performance?

The Bi-directional Concatenation (BiC) module in YOLOv6 enhances localization signals in the detector's neck, delivering performance improvements with negligible speed impact. This module effectively combines different feature maps, increasing the model's ability to detect objects accurately. For more details on YOLOv6's features, refer to the Key Features section.

How can I train a YOLOv6 model using Ultralytics?

You can train a YOLOv6 model using Ultralytics with simple Python or CLI commands. For instance:

!!! Example

=== "Python"

    ```python
    from ultralytics import YOLO

    # Build a YOLOv6n model from scratch
    model = YOLO("yolov6n.yaml")

    # Train the model on the COCO8 example dataset for 100 epochs
    results = model.train(data="coco8.yaml", epochs=100, imgsz=640)
    ```

=== "CLI"

    ```bash
    yolo train model=yolov6n.yaml data=coco8.yaml epochs=100 imgsz=640
    ```

For more information, visit the Train page.

What are the different versions of YOLOv6 and their performance metrics?

YOLOv6 offers multiple versions, each optimized for different performance requirements:

  • YOLOv6-N: 37.5% AP at 1187 FPS
  • YOLOv6-S: 45.0% AP at 484 FPS
  • YOLOv6-M: 50.0% AP at 226 FPS
  • YOLOv6-L: 52.8% AP at 116 FPS
  • YOLOv6-L6: State-of-the-art accuracy in real-time scenarios

These models are evaluated on the COCO dataset using an NVIDIA Tesla T4 GPU. For more on performance metrics, see the Performance Metrics section.

How does the Anchor-Aided Training (AAT) strategy benefit YOLOv6?

Anchor-Aided Training (AAT) in YOLOv6 combines elements of anchor-based and anchor-free approaches, enhancing the model's detection capabilities without compromising inference efficiency. This strategy leverages anchors during training to improve bounding box predictions, making YOLOv6 effective in diverse object detection tasks.

Which operational modes are supported by YOLOv6 models in Ultralytics?

YOLOv6 supports various operational modes including Inference, Validation, Training, and Export. This flexibility allows users to fully exploit the model's capabilities in different scenarios. Check out the Supported Tasks and Modes section for a detailed overview of each mode.