This new class, AI on the Edge, will use Python as the primary programming language. If you are not familiar with python, this video lesson will teach the essentials in one go. Go through the video, and follow the examples. Practice the things in the video, and then do the homework. If you can learn these basics, you should be able to follow along with the balance of the class.
AI on the Edge LESSON 2: Raspberry Pi Operating System for Artificial Intelligence
The major challenge we face in this AI on the Edge class is getting a Raspberry Pi 5 configures where you have all the AI Models, Libraries, Modules and Methods installed, and where they all play nicely together. Often, when you add a new model, the old model becomes broken. This is because when you install something new, it often times updates the dependencies. That means it updates a library already on your system. For example, lets say you have numpy 14, working with YOLO 11. Now you install mediapipe, and it updates numpy 14 to numpy 15. This then ‘Breaks’ your YOLO, as it wanted a different version of numpy. Likely you will get frustrated and quit before you get the dependency problems solved. In order to get around this, you can use a special education version of the Bookworm OS, which has all the needed libraries installed already and working nicely with each other. The video above shows you how to install this OS. Once you do, no not update it, do not upgrade it, do not touch it. Use it to develop your programs and projects for this class. If you want to do something else with your pi, have a separate SD card.
AI on the Edge LESSON 1: Introduction and Class Overview
Welcome to our all new AI on the Edge class! I will need you to buckle up, get your hardware together, and get ready to teach AI who is boss! We will be using a Pi 5, and the Fusion AI Lab kit. I will show links to the hardware below. In today’s lesson I describe the Class Introduction, and will show you some demos of the types of projects we will be doing. You will either Drive AI or your will be Destroyed by AI. Don’t be one of the ones who will be eaten by it
Guys, get your gear, and make sure you end up on the right side of the Dystopian future that awaits the world.
I have provided Amazon links, so you can order everything in the same place
You Will need a Raspberry Pi 5
Order Pi 5
You will need a heat sink and fan
Order Heat Sink and Fan
You Will Need the Fusion AI Lab Kit
Order Fusion AI Lab Kit
You Will Need a 25 Watt Power Supply
Order Power Supply
You Will Need a Micro HDMI Cable
Order Micro HDMI Cable
You Will Need a Keyboard and Mouse
Order Wireless Keyboard and Mouse
OK, get Geared Up with the equipment above, and then next week’s lesson will show you how to configure your pi 5 for this class.
Object Detection Using YOLO and RTSP Camera on Raspberry Pi 5
OK guys, you spoke, and I listened. You all are asking for a lesson on how to do object detection on a Pi 5 using YOLO and an IP Camera. Well, you are about to get what you asked for. We will make this work, or we will DIE TRYING. Never fear, once you watch the video you will both understand and be able to do it on your own. First, I am assuming you watched our previous lesson where I showed you how to do the basic install and setup of YOLO. If not, never fear, I have the commands below. NOTE: This tutorial is geared towards bookworm OS. I strongly suggest you start with a fresh bookworm SC card, as there are many dependencies, and it is most likely to work if you start exactly where I am starting . . . with a fresh OS. Thes these are the commands I shared last week to get YOLO up and working: (just open a terminal, and paste these commands one at a time)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 | # 1. Configure X11 (manual steps required) sudo raspi-config # → Go to Advanced Options → X11 → Enable X11 # → Finish and reboot when prompted # 5. Update system and install OpenCV sudo apt update sudo apt full-upgrade -y sudo apt install python3-opencv -y # Verify OpenCV python3 -c "import cv2; print('OpenCV version:', cv2.__version__)" # Expected output: something like "OpenCV version: 4.6.0" or higher # Create and activate virtual environment for YOLO11 (Ultralytics) python3 -m venv --system-site-packages YOLO source YOLO/bin/activate # You are now inside the (YOLO) virtual environment # Install Ultralytics YOLO11 inside it pip install "numpy<2.0" ultralytics # Now create a Pi friendly YOLO11 model yolo export model=yolo11n.pt format=ncnn # Optional: Verify YOLO installation python -c "from ultralytics import YOLO; print('Ultralytics YOLO ready')" # When finished working with YOLO, you can deactivate with: # deactivate #Now open Thonny, and you need to point thonny to the virtual environment you #just created. Open tools- options, select 'interpreter' tab, then click they Python #executable, selecting ... and navigate from home directory, #to YOLO, to bin, and then select python |
Now, I will explain this code, and will help you configure it for your cameras, but you will need to open up thonny, and paste in the following code as a start. IMPORTANT, as mentioned above, you need to set interpreter in thonny to the virtual environment set up in the process above. If this is not familiar to you, go back and watch last weeks lesson (click previous at the bottom of this post). Without further adue, here is the code we will work with today:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 | import cv2 from ultralytics import YOLO #import secret import threading import time W=1280 H=720 #Now, as eplained in the video, edit the line below where #you put your wifi user name in place of user, and your #wifi password in place of password, and you put in your #IP address RTSP_URL = "rtsp://user:password@192.168.88.44:554/cam/realmonitor?channel=1&subtype=0" #RTSP_URL = secret.RTSP_URL1 #I have put my wifi credentials in a secret file so no #one sees my credentials. You will just use the RTSP_URL line above. # Load the exported NCNN model (replace with your model path) model = YOLO("/home/pjm/yolo11n_ncnn_model/", task="detect") lock = threading.Lock() running = True def frameGrabber(url): global ipFrame, running cap = cv2.VideoCapture(url, cv2.CAP_FFMPEG) cap.set(cv2.CAP_PROP_BUFFERSIZE, 1) cap.set(cv2.CAP_PROP_POS_FRAMES, 0) # Reset frame position while running: ret, frame = cap.read() if ret: with lock: #frame = cv2.resize(frame, (W, H)) ipFrame = frame.copy() cap.release() print("Thread Terminated") thread = threading.Thread(target=frameGrabber, args=(RTSP_URL,), daemon=True) thread.start() tStart=time.time() time.sleep(2) fps=0 cnt=0 # Set resolution for faster processing (optional, adjust based on your needs) while True: deltaT=time.time()-tStart fps= fps*.9 + .1/deltaT tStart=time.time() with lock: ipFrameShow=ipFrame.copy() results = model(ipFrameShow, conf=0.25, verbose=False)[0] # conf: confidence threshold; adjust as needed # Annotate the frame with detections (boxes, labels, scores) annotatedFrame = results.plot() annotatedFrame=cv2.resize(annotatedFrame, (W,H)) cv2.putText(annotatedFrame, "FPS: "+str(round(fps,1)), (int(W*.01), int(H*.075)), cv2.FONT_HERSHEY_SIMPLEX, H*.002, (0, 0, 255), 3) cv2.imshow("IP Camera", annotatedFrame) #cv2.moveWindow("IP Camera",100,100) if cv2.waitKey(1)==ord('q'): break running=False thread.join() # Wait for thread to fully exit time.sleep(1) cv2.destroyAllWindows() import gc gc.collect() # Force garbage collection to reclaim memory/connections #Make Extra sure all processes are killed import os os._exit(0) print("Program Terminated") |
The video explains everything, please watch it!
AI on the Edge: Install and Run YOLO Object Detection on the Raspberry Pi 5
In today’s Lesson we will see just how far we can push things on the Raspberry Pi 5. I will show you how to install YOLO11 on the Pi . I will show you a simple program that will run YOLO11 under Python and openCV. The objective in today’s lesson is to see if the Pi5, without a Hailo accelerator hat, has sufficient power to do useful object detection. We will not use an accelerator hat, but the work is computationally intensive, so you must use active cooling. This is the low cost cooling fan we are using. It is sufficient to do the job, low cost and is a thin form factor that allows other hats to still fit on the Raspberry Pi 5. You can pick up the fan I am using HERE. Also, we are using an 8GB Pi 5. If you already have a Pi 5, it will probably work. The Pi 5 we are using is available HERE. These appliations are power hungry, so make sure you are using an official Pi Power supply.
In this lesson, I assume you are already familiar with the Pi 5. Note we are using Bookworm OS. Not all the dependencies work yet on Trixie, so I strongly recommend starting by flashing a fresh bookworm SD card.
YOLO11 is a powerful AI object detection model that runs well on the Raspberry Pi 5. The model below:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 | # 1. Configure X11 (manual steps required) sudo raspi-config # → Go to Advanced Options → X11 → Enable X11 # → Finish and reboot when prompted # 5. Update system and install OpenCV sudo apt update sudo apt full-upgrade -y sudo apt install python3-opencv -y # Verify OpenCV python3 -c "import cv2; print('OpenCV version:', cv2.__version__)" # Expected output: something like "OpenCV version: 4.6.0" or higher # 6. Install MediaPipe pip install mediapipe --break # Verify MediaPipe python3 -c "import mediapipe as mp; print('MediaPipe version:', mp.__version__)" # 7. Create and activate virtual environment for YOLO11 (Ultralytics) python3 -m venv --system-site-packages YOLO source YOLO/bin/activate # You are now inside the (YOLO) virtual environment # Install Ultralytics YOLO11 inside it pip install "numpy<2.0" ultralytics # Now create a Pi friendly YOLO11 model yolo export model=yolo11n.pt format=ncnn # Optional: Verify YOLO installation python -c "from ultralytics import YOLO; print('Ultralytics YOLO ready')" # When finished working with YOLO, you can deactivate with: # deactivate #Now open Thonny, and you need to point thonny to the virtual environment you #just created. Open tools- options, select 'interpreter' tab, then click they Python #executable, selecting ... and navigate from home directory, #to YOLO, to bin, and then select python |
Now you should be set up to use YOLO11 on the Raspberry Pi 5!
We will start with this program, which is a simple grab a frame and show a frame openCV Program
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 | import cv2 from picamera2 import Picamera2 import time piCam = Picamera2() W=1280 H=720 RES = (W,H) piCam.preview_configuration.main.size = RES piCam.preview_configuration.main.format = "RGB888" piCam.preview_configuration.controls.FrameRate=60 piCam.preview_configuration.align() piCam.configure("preview") piCam.start() fps=0 tStart=time.time() while True: frame= piCam.capture_array() #frame=cv2.flip(frame,-1) deltaT=time.time()-tStart tStart=time.time() fps= fps*.9 + .1/deltaT cv2.putText(frame, "FPS: "+str(round(fps,1)), (int(W*.01), int(H*.075)), cv2.FONT_HERSHEY_SIMPLEX, H*.002, (0, 0, 255), 2) cv2.imshow("Camera", frame) cv2.moveWindow("Camera",100,100) if cv2.waitKey(1)==ord('q'): break cv2.destroyAllWindows() |
In the video, we show how to use YOLO11 object detection in this simple program.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 | import cv2 from ultralytics import YOLO from picamera2 import Picamera2 import time piCam = Picamera2() W=1280 H=720 RES = (W,H) piCam.preview_configuration.main.size = RES piCam.preview_configuration.main.format = "RGB888" piCam.preview_configuration.controls.FrameRate=60 piCam.preview_configuration.align() piCam.configure("preview") piCam.start() # Load the exported NCNN model (replace with your model path) model = YOLO("/home/pjm/yolo11n_ncnn_model", task = 'detect') fps=0 tStart=time.time() # Set resolution for faster processing (optional, adjust based on your needs) while True: frame= piCam.capture_array() results = model(frame, conf=0.25, verbose=False) frame = results[0].plot() # Plots old boxes on new frame! deltaT=time.time()-tStart tStart=time.time() fps= fps*.8 + .2/deltaT cv2.putText(frame, "FPS: "+str(round(fps,1)), (int(W*.01), int(H*.075)), cv2.FONT_HERSHEY_SIMPLEX, H*.002, (0, 0, 255), 2) # Display the result cv2.imshow("YOLO11 Detection", frame) # Exit on 'q' key if cv2.waitKey(1) == ord('q'): break # Cleanup cv2.destroyAllWindows() import gc gc.collect() # Force garbage collection to reclaim memory/connections #Make Extra sure all processes are killed import os os._exit(0) print("Program Terminated") |