Neural Magic (original) (raw)
Optimizing YOLO11 Inferences with Neural Magic's DeepSparse Engine
When deploying object detection models like Ultralytics YOLO11 on various hardware, you can bump into unique issues like optimization. This is where YOLO11's integration with Neural Magic's DeepSparse Engine steps in. It transforms the way YOLO11 models are executed and enables GPU-level performance directly on CPUs.
This guide shows you how to deploy YOLO11 using Neural Magic's DeepSparse, how to run inferences, and also how to benchmark performance to ensure it is optimized.
Neural Magic's DeepSparse
Neural Magic's DeepSparse is an inference run-time designed to optimize the execution of neural networks on CPUs. It applies advanced techniques like sparsity, pruning, and quantization to dramatically reduce computational demands while maintaining accuracy. DeepSparse offers an agile solution for efficient and scalable neural network execution across various devices.
Benefits of Integrating Neural Magic's DeepSparse with YOLO11
Before diving into how to deploy YOLO11 using DeepSparse, let's understand the benefits of using DeepSparse. Some key advantages include:
- Enhanced Inference Speed: Achieves up to 525 FPS (on YOLO11n), significantly speeding up YOLO11's inference capabilities compared to traditional methods.
- Optimized Model Efficiency: Uses pruning and quantization to enhance YOLO11's efficiency, reducing model size and computational requirements while maintaining accuracy.
- High Performance on Standard CPUs: Delivers GPU-like performance on CPUs, providing a more accessible and cost-effective option for various applications.
- Streamlined Integration and Deployment: Offers user-friendly tools for easy integration of YOLO11 into applications, including image and video annotation features.
- Support for Various Model Types: Compatible with both standard and sparsity-optimized YOLO11 models, adding deployment flexibility.
- Cost-Effective and Scalable Solution: Reduces operational expenses and offers scalable deployment of advanced object detection models.
How Does Neural Magic's DeepSparse Technology Work?
Neural Magic's Deep Sparse technology is inspired by the human brain's efficiency in neural network computation. It adopts two key principles from the brain as follows:
- Sparsity: The process of sparsification involves pruning redundant information from deep learning networks, leading to smaller and faster models without compromising accuracy. This technique reduces the network's size and computational needs significantly.
- Locality of Reference: DeepSparse uses a unique execution method, breaking the network into Tensor Columns. These columns are executed depth-wise, fitting entirely within the CPU's cache. This approach mimics the brain's efficiency, minimizing data movement and maximizing the CPU's cache use.
For more details on how Neural Magic's DeepSparse technology works, check out their blog post.
Creating A Sparse Version of YOLO11 Trained on a Custom Dataset
SparseZoo, an open-source model repository by Neural Magic, offers a collection of pre-sparsified YOLO11 model checkpoints. With SparseML, seamlessly integrated with Ultralytics, users can effortlessly fine-tune these sparse checkpoints on their specific datasets using a straightforward command-line interface.
Check out Neural Magic's SparseML YOLO11 documentation for more details.
Usage: Deploying YOLO11 using DeepSparse
Deploying YOLO11 with Neural Magic's DeepSparse involves a few straightforward steps. Before diving into the usage instructions, be sure to check out the range of YOLO11 models offered by Ultralytics. This will help you choose the most appropriate model for your project requirements. Here's how you can get started.
Step 1: Installation
To install the required packages, run:
Installation
CLI
# Install the required packages pip install deepsparse[yolov8]
Step 2: Exporting YOLO11 to ONNX Format
DeepSparse Engine requires YOLO11 models in ONNX format. Exporting your model to this format is essential for compatibility with DeepSparse. Use the following command to export YOLO11 models:
Model Export
CLI
# Export YOLO11 model to ONNX format yolo task=detect mode=export model=yolo11n.pt format=onnx opset=13
This command will save the yolo11n.onnx model to your disk.
Step 3: Deploying and Running Inferences
With your YOLO11 model in ONNX format, you can deploy and run inferences using DeepSparse. This can be done easily with their intuitive Python API:
Deploying and Running Inferences
Python
`from deepsparse import Pipeline
Specify the path to your YOLO11 ONNX model
model_path = "path/to/yolo11n.onnx"
Set up the DeepSparse Pipeline
yolo_pipeline = Pipeline.create(task="yolov8", model_path=model_path)
Run the model on your images
images = ["path/to/image.jpg"] pipeline_outputs = yolo_pipeline(images=images) `
Step 4: Benchmarking Performance
It's important to check that your YOLO11 model is performing optimally on DeepSparse. You can benchmark your model's performance to analyze throughput and latency:
Benchmarking
CLI
# Benchmark performance deepsparse.benchmark model_path="path/to/yolo11n.onnx" --scenario=sync --input_shapes="[1,3,640,640]"
Step 5: Additional Features
DeepSparse provides additional features for practical integration of YOLO11 in applications, such as image annotation and dataset evaluation.
Additional Features
CLI
`# For image annotation deepsparse.yolov8.annotate --source "path/to/image.jpg" --model_filepath "path/to/yolo11n.onnx"
For evaluating model performance on a dataset
deepsparse.yolov8.eval --model_path "path/to/yolo11n.onnx" `
Running the annotate command processes your specified image, detecting objects, and saving the annotated image with bounding boxes and classifications. The annotated image will be stored in an annotation-results folder. This helps provide a visual representation of the model's detection capabilities.
After running the eval command, you will receive detailed output metrics such as precision, recall, and mAP (mean Average Precision). This provides a comprehensive view of your model's performance on the dataset. This functionality is particularly useful for fine-tuning and optimizing your YOLO11 models for specific use cases, ensuring high accuracy and efficiency.
Summary
This guide explored integrating Ultralytics' YOLO11 with Neural Magic's DeepSparse Engine. It highlighted how this integration enhances YOLO11's performance on CPU platforms, offering GPU-level efficiency and advanced neural network sparsity techniques.
For more detailed information and advanced usage, visit the DeepSparse documentation by Neural Magic. You can also explore the YOLO11 integration guide and watch a walkthrough session on YouTube.
Additionally, for a broader understanding of various YOLO11 integrations, visit the Ultralytics integration guide page, where you can discover a range of other exciting integration possibilities.
FAQ
What is Neural Magic's DeepSparse Engine and how does it optimize YOLO11 performance?
Neural Magic's DeepSparse Engine is an inference runtime designed to optimize the execution of neural networks on CPUs through advanced techniques such as sparsity, pruning, and quantization. By integrating DeepSparse with YOLO11, you can achieve GPU-like performance on standard CPUs, significantly enhancing inference speed, model efficiency, and overall performance while maintaining accuracy. For more details, check out the Neural Magic's DeepSparse section.
How can I install the needed packages to deploy YOLO11 using Neural Magic's DeepSparse?
Installing the required packages for deploying YOLO11 with Neural Magic's DeepSparse is straightforward. You can easily install them using the CLI. Here's the command you need to run:
pip install deepsparse[yolov8]
Once installed, follow the steps provided in the Installation section to set up your environment and start using DeepSparse with YOLO11.
How do I convert YOLO11 models to ONNX format for use with DeepSparse?
To convert YOLO11 models to the ONNX format, which is required for compatibility with DeepSparse, you can use the following CLI command:
yolo task=detect mode=export model=yolo11n.pt format=onnx opset=13
This command will export your YOLO11 model (yolo11n.pt) to a format (yolo11n.onnx) that can be utilized by the DeepSparse Engine. More information about model export can be found in the Model Export section.
How do I benchmark YOLO11 performance on the DeepSparse Engine?
Benchmarking YOLO11 performance on DeepSparse helps you analyze throughput and latency to ensure your model is optimized. You can use the following CLI command to run a benchmark:
deepsparse.benchmark model_path="path/to/yolo11n.onnx" --scenario=sync --input_shapes="[1,3,640,640]"
This command will provide you with vital performance metrics. For more details, see the Benchmarking Performance section.
Why should I use Neural Magic's DeepSparse with YOLO11 for object detection tasks?
Integrating Neural Magic's DeepSparse with YOLO11 offers several benefits:
- Enhanced Inference Speed: Achieves up to 525 FPS, significantly speeding up YOLO11's capabilities.
- Optimized Model Efficiency: Uses sparsity, pruning, and quantization techniques to reduce model size and computational needs while maintaining accuracy.
- High Performance on Standard CPUs: Offers GPU-like performance on cost-effective CPU hardware.
- Streamlined Integration: User-friendly tools for easy deployment and integration.
- Flexibility: Supports both standard and sparsity-optimized YOLO11 models.
- Cost-Effective: Reduces operational expenses through efficient resource utilization.
For a deeper dive into these advantages, visit the Benefits of Integrating Neural Magic's DeepSparse with YOLO11 section.