--- license: other license_name: intel-custom license_link: LICENSE library_name: openvino pipeline_tag: object-detection tags: - openvino - intel - yolo - yolo26 - object-detection - coco - edge-ai - metro - dlstreamer datasets: - detection-datasets/coco language: - en --- # Object Detection | Property | Value | |---|---| | **Category** | General Object Detection (80-class COCO) | | **Base Model** | [YOLO26](https://docs.ultralytics.com/models/yolo26/) (Ultralytics) | | **Source Framework** | PyTorch (Ultralytics) | | **Supported Precisions** | FP32, FP16, INT8 (mixed-precision) | | **Inference Engine** | OpenVINO | | **Hardware** | CPU, GPU, NPU | | **Detected Class(es)** | All 80 COCO classes | --- ## Overview Object Detection is a Metro Analytics use case that detects and classifies objects across the full 80-class COCO taxonomy (person, vehicle, animal, everyday objects, etc.). It is built on [YOLO26](https://docs.ultralytics.com/models/yolo26/), a state-of-the-art real-time object detector, quantized to INT8 for efficient inference on Intel hardware. Unlike the specialized person or vehicle detectors, this model keeps all 80 classes active, making it suitable for general-purpose scene understanding. Typical Metro deployments include: - **Scene Understanding** -- identify and classify all objects visible in a camera feed. - **Inventory Monitoring** -- detect specific items (bags, suitcases, bottles) on platforms. - **Anomaly Detection** -- flag unexpected objects in restricted areas. - **Multi-Class Analytics** -- gather statistics across people, vehicles, and other categories. Available variants: `yolo26n`, `yolo26s`, `yolo26m`, `yolo26l`, `yolo26x`. Smaller variants (`yolo26n`, `yolo26s`) are recommended for high-FPS edge deployment; larger variants improve recall for small objects. --- ## Prerequisites - Python 3.11+ - [Install OpenVINO](https://docs.openvino.ai/2026/get-started/install-openvino.html) (latest version) - [Install Intel DLStreamer](https://docs.openedgeplatform.intel.com/2026.0/edge-ai-libraries/dlstreamer/get_started/install/install_guide_ubuntu.html) (latest version) Create and activate a Python virtual environment before running the scripts: ```bash python3 -m venv .venv --system-site-packages source .venv/bin/activate ``` > **Note:** The `--system-site-packages` flag is required so the virtual > environment can access the system-installed OpenVINO and DLStreamer Python > packages. --- ## Getting Started ### Download and Quantize Model Run the provided script to download, export to OpenVINO IR, and optionally quantize: ```bash chmod +x export_and_quantize.sh ./export_and_quantize.sh ``` This exports the default **yolo26n** model in **FP16** precision. #### Optional: Select a Different Variant or Precision ```bash ./export_and_quantize.sh yolo26n FP32 # full-precision ./export_and_quantize.sh yolo26n INT8 # quantized ./export_and_quantize.sh yolo26s # larger variant, default FP16 ``` Replace `yolo26n` with any variant (`yolo26s`, `yolo26m`, `yolo26l`, `yolo26x`). The second argument selects the precision (`FP32`, `FP16`, `INT8`); the default is **FP16**. The script performs the following steps: 1. Installs dependencies (`openvino`, `ultralytics`; adds `nncf` for INT8). 2. Downloads a sample test image (`test.jpg`) and a sample test video (`test_video.mp4`). 3. Downloads the PyTorch weights and exports to OpenVINO IR. 4. *(INT8 only)* Quantizes the model using NNCF post-training quantization. Output files: - `yolo26n_openvino_model/` -- FP32 or FP16 OpenVINO IR model directory. - `yolo26n_objdet_int8.xml` / `yolo26n_objdet_int8.bin` -- INT8 quantized model *(only when `INT8` is selected)*. #### Precision / Device Compatibility | Precision | CPU | GPU | NPU | |---|---|---|---| | FP32 | Yes | Yes | No | | FP16 | Yes | Yes | Yes | | INT8 | Yes | Yes | Yes | > **Note:** The INT8 calibration uses the bundled sample image. > For production accuracy, replace it with a representative set of frames from > the target deployment site. ### OpenVINO Sample The sample below runs YOLO26 inference on all 80 COCO classes and prints every detected object with its class name and confidence. YOLO26 is end-to-end (NMS-free), so no manual non-maximum suppression is needed. Change the `device` string to run on CPU, GPU, or NPU. ```python import cv2 import numpy as np import openvino as ov COCO_NAMES = [ "person","bicycle","car","motorcycle","airplane","bus","train","truck", "boat","traffic light","fire hydrant","stop sign","parking meter","bench", "bird","cat","dog","horse","sheep","cow","elephant","bear","zebra", "giraffe","backpack","umbrella","handbag","tie","suitcase","frisbee", "skis","snowboard","sports ball","kite","baseball bat","baseball glove", "skateboard","surfboard","tennis racket","bottle","wine glass","cup", "fork","knife","spoon","bowl","banana","apple","sandwich","orange", "broccoli","carrot","hot dog","pizza","donut","cake","chair","couch", "potted plant","bed","dining table","toilet","tv","laptop","mouse", "remote","keyboard","cell phone","microwave","oven","toaster","sink", "refrigerator","book","clock","vase","scissors","teddy bear","hair drier", "toothbrush", ] CONF_THRESHOLD = 0.4 INPUT_SIZE = 640 core = ov.Core() model = core.read_model("yolo26n_openvino_model/yolo26n.xml") # Change device to "GPU" or "NPU" to run on integrated GPU or NPU. compiled = core.compile_model(model, "CPU") image = cv2.imread("test.jpg") h0, w0 = image.shape[:2] blob = cv2.resize(image, (INPUT_SIZE, INPUT_SIZE)) blob = cv2.cvtColor(blob, cv2.COLOR_BGR2RGB).astype(np.float32) / 255.0 blob = blob.transpose(2, 0, 1)[np.newaxis, ...] # NCHW # YOLO26 end-to-end output: [1, 300, 6] = [x1, y1, x2, y2, confidence, class_id] output = compiled([blob])[compiled.output(0)][0] mask = output[:, 4] >= CONF_THRESHOLD dets = output[mask] sx, sy = w0 / INPUT_SIZE, h0 / INPUT_SIZE print(f"Total detections: {len(dets)}") colors = np.random.RandomState(42).randint(0, 255, (80, 3)).tolist() for det in dets: x1 = int(det[0] * sx) y1 = int(det[1] * sy) x2 = int(det[2] * sx) y2 = int(det[3] * sy) cid = int(det[5]) conf = float(det[4]) label = f"{COCO_NAMES[cid]} {conf:.2f}" color = colors[cid] cv2.rectangle(image, (x1, y1), (x2, y2), color, 2) cv2.putText(image, label, (x1, y1 - 5), cv2.FONT_HERSHEY_SIMPLEX, 0.6, color, 2) print(f" {label} at ({x1},{y1})-({x2},{y2})") cv2.imwrite("output_openvino.jpg", image) ``` **Device targets:** - `"CPU"` -- default, works on all Intel platforms. - `"GPU"` -- Intel integrated or discrete GPU. - `"NPU"` -- Intel NPU (validate with `benchmark_app -d NPU`). ### Try It on a Sample Image The `export_and_quantize.sh` script downloads `test.jpg` automatically. Re-run the OpenVINO sample above. The script reads `test.jpg`, prints each detected object to the console, and writes the annotated frame to `output_openvino.jpg`. Expected console output (representative): ```text Total detections: 5 person 0.92 at (49,396)-(236,904) bus 0.92 at (0,229)-(804,744) person 0.91 at (670,393)-(809,880) person 0.90 at (223,403)-(345,862) person 0.50 at (0,553)-(68,869) ``` #### Expected Output ![OpenVINO expected output](expected_output_openvino.jpg) ### DLStreamer Sample The pipeline below runs the FP16 YOLO26 detector on the sample video via `gvadetect`, overlays bounding boxes, saves the annotated result to `output_dlstreamer.mp4`, and prints all detections per frame. > **Notes on running this sample:** > > - Use the FP16 IR (`yolo26n_openvino_model/yolo26n.xml`). Class names are > read automatically from the model's embedded `metadata.yaml` by > DLStreamer 2026.0+ -- no external `labels-file` is required. > - Export `PYTHONPATH` so the DLStreamer Python module is importable: > > ```bash > source /opt/intel/openvino_2026/setupvars.sh > source /opt/intel/dlstreamer/scripts/setup_dls_env.sh > export PYTHONPATH=/opt/intel/dlstreamer/python:\ > /opt/intel/dlstreamer/gstreamer/lib/python3/dist-packages:${PYTHONPATH:-} > ``` ```python import gi gi.require_version("Gst", "1.0") gi.require_version("GstVideo", "1.0") from gi.repository import Gst from gstgva import VideoFrame Gst.init(None) INPUT_VIDEO = "test_video.mp4" # For CPU: change device=GPU to device=CPU. # For NPU: change device=GPU to device=NPU (batch-size=1, nireq=4 recommended). pipeline_str = ( f"filesrc location={INPUT_VIDEO} ! decodebin3 ! " "videoconvert ! " "gvadetect model=yolo26n_openvino_model/yolo26n.xml " "device=GPU " "threshold=0.4 ! queue ! " "gvawatermark ! videoconvert ! video/x-raw,format=I420 ! " "openh264enc ! h264parse ! " "mp4mux ! filesink name=sink location=output_dlstreamer.mp4" ) pipeline = Gst.parse_launch(pipeline_str) def on_buffer(pad, info): buf = info.get_buffer() caps = pad.get_current_caps() frame = VideoFrame(buf, caps=caps) for region in frame.regions(): print(f" {region.label()} at ({region.rect().x},{region.rect().y})", flush=True) return Gst.PadProbeReturn.OK sink = pipeline.get_by_name("sink") sink_pad = sink.get_static_pad("sink") sink_pad.add_probe(Gst.PadProbeType.BUFFER, on_buffer) pipeline.set_state(Gst.State.PLAYING) bus = pipeline.get_bus() bus.timed_pop_filtered( Gst.CLOCK_TIME_NONE, Gst.MessageType.EOS | Gst.MessageType.ERROR, ) pipeline.set_state(Gst.State.NULL) ``` #### Expected Output ![DLStreamer expected output](expected_output_dlstreamer.gif) **Device targets:** - `device=GPU` -- default in the sample code. - `device=CPU` -- change `device=GPU` to `device=CPU`. - `device=NPU` -- change `device=GPU` to `device=NPU`; use `batch-size=1` and `nireq=4` for best NPU utilization. --- ## License Copyright (C) Intel Corporation. All rights reserved. Licensed under the MIT License. See [LICENSE](LICENSE) for details. ## References - [YOLO26 Documentation](https://docs.ultralytics.com/models/yolo26/) - [OpenVINO YOLO26 Notebook](https://github.com/openvinotoolkit/openvino_notebooks/blob/latest/notebooks/yolov26-optimization/yolov26-object-detection.ipynb) - [COCO Dataset](https://cocodataset.org/) - [OpenVINO Documentation](https://docs.openvino.ai/) - [NNCF Post-Training Quantization](https://docs.openvino.ai/latest/nncf_ptq_introduction.html) - [Intel DLStreamer](https://docs.openedgeplatform.intel.com/2026.0/edge-ai-libraries/dlstreamer/index.html)