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computer vision

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Mann Patel
2025-01-01 01:48:15 -07:00
parent c9cd98a03a
commit c1b1b8fec9
16 changed files with 368 additions and 643 deletions
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Computer Vision/1.py
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import cv2
import numpy as np
from scipy.spatial import distance as dist, distance
import main1
class Robot:
def __init__(self, pos=None, team='-no team!-', ID='-no ID!-'):
self.pos = pos if pos is not None else []
self.team = team
self.ID = ID
self.circles = []
def add_marking(self, circle=None):
if circle is None:
circle = [0, 0, [0, 0, 0]]
self.circles.append(circle)
class Ball:
def __init__(self, pos=None):
self.pos = pos if pos is not None else []
# Initialize the ball with default position
ball = Ball()
# Initialize empty lists for robots and ID markings
robotList = []
robotMarks = []
def Color_Detection(blue, green, red):
if blue > 220 and green < 50 and red < 50:
return 'Blue'
if blue < 50 and green > 200 and red > 200:
return 'Yellow'
if blue > 200 and green < 50 and red > 200:
return 'Purple'
if blue < 50 and green > 220 and red < 50:
return 'Green'
if blue < 50 and green < 200 and red > 180:
return 'Orange'
return 'Unidentified'
def IdentifyCircles(img, circle):
global ball
x, y = int(circle[0]), int(circle[1])
blue, green, red = img[y, x, 0], img[y, x, 1], img[y, x, 2]
color = Color_Detection(blue, green, red)
# Debugging statements
print(f"Circle at ({x}, {y}) with BGR ({blue}, {green}, {red}) detected as {color}")
if color == 'Blue' or color == 'Yellow':
robotList.append(Robot([x, y], color))
elif color == 'Green' or color == 'Purple':
robotMarks.append([x, y, color])
print('ROBOT FOUND')
elif color == 'Orange':
ball.pos = [x, y]
print(f"Ball found at ({x}, {y})")
def assignIDmarks():
if robotList is not None:
for idx, robot in enumerate(robotList):
distances = []
for i, mark in enumerate(robotMarks):
mark_dist = distance.euclidean(mark[:2], robot.pos)
distances.append((i, mark_dist))
distances.sort(key=lambda x: x[1])
closest_marks_indices = [i for i, _ in distances[:4]]
robot.circles = [robotMarks[i] for i in closest_marks_indices]
robot.ID = idx + 1
def detect_circles(image):
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
blurred = cv2.GaussianBlur(gray, (9, 9), 0)
circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=15,
maxRadius=50)
return [circles]
def annotate_image(img):
for robot in robotList:
team_color = "B" if robot.team == 'Blue' else "Y"
cv2.putText(img, f'{team_color}', (robot.pos[0] + 20, robot.pos[1] - 40), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'ID{robot.ID}', (robot.pos[0] + 20, robot.pos[1] - 20), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'{robot.pos}', (robot.pos[0] + 20, robot.pos[1]), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
if ball.pos:
cv2.putText(img, f'Ball {ball.pos}', (ball.pos[0] + 20, ball.pos[1] + 20), cv2.FONT_HERSHEY_SIMPLEX, 1,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.circle(img, (ball.pos[0], ball.pos[1]), 10, (0, 165, 255), -1) # Orange color for the ball
# Main function
def main():
global robotList, robotMarks
global ball
while True:
# Initialize globals
robotList = []
robotMarks = []
ball = Ball() # Ensure ball is always an instance of Ball
# Load and process the image
imgpath = "Assets/Images/BotsAndBall.png"
img = cv2.imread(imgpath)
if img is None:
print(f"Failed to load image at path: {imgpath}")
return
cv2.imshow("Original Image", img)
# Detect circles in the image
circles = detect_circles(img)
if circles is not None:
circles = np.uint8(np.around(circles))
for circle in circles[0, :]:
IdentifyCircles(img, circle)
cv2.circle(img, (circle[0], circle[1]), circle[2], (0, 255, 0), 2)
cv2.circle(img, (circle[0], circle[1]), 2, (0, 0, 255), 3)
assignIDmarks()
for robot in robotList:
print(f'There is a {robot.team} robot with these ID circles:')
for mark in robot.circles:
print(mark)
if ball.pos:
print(f'Ball found at {ball.pos}')
for robot in robotList:
if robot.pos:
cv2.circle(img, (robot.pos[0], robot.pos[1]), 10, (0, 0, 0), 5)
for mark in robot.circles:
cv2.circle(img, (mark[0], mark[1]), 10, (0, 0, 0), 5)
else:
print("No circles detected")
annotate_image(img)
cv2.imshow("Annotated Image", img)
cv2.waitKey(0)
cv2.destroyAllWindows()
if __name__ == "__main__":
main()

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Computer Vision/main1.py
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import cv2
import numpy as np
from scipy.spatial import distance as dist
# Initialize empty lists for robots and ID markings
robotList = []
robotMarks = []
class Robot:
def __init__(self, pos=None, team='-no team!-', ID='-no ID!-'):
self.pos = pos if pos is not None else []
self.team = team
self.ID = ID
self.circles = [] # ID markings [x, y, color]
def add_marking(self, circle=None):
if circle is None:
circle = [0, 0, [0, 0, 0]]
self.circles.append(circle)
class Ball:
def __init__(self, pos=None):
self.pos = pos if pos is not None else []
# Initialize the ball with default position
ball = Ball()
def Color_Detection(blue, green, red):
if blue > 220 and green < 50 and red < 50:
return 'Blue'
elif blue < 50 and green > 200 and red > 200:
return 'Yellow'
elif blue > 200 and green < 50 and red > 200:
return 'Purple'
elif blue < 50 and green > 220 and red < 50:
return 'Green'
elif blue < 50 and green < 200 and red > 220:
return 'Orange'
return f'Unidentified Color R:{red}, G:{green}, B:{blue}'
def IdentifyCircles(img, circle):
global ball
x, y = int(circle[0]), int(circle[1])
blue, green, red = img[y, x, 0], img[y, x, 1], img[y, x, 2]
color = Color_Detection(blue, green, red)
if color == 'Blue' or color == 'Yellow':
robotList.append(Robot([x, y], color))
elif color == 'Green' or color == 'Purple':
robotMarks.append([x, y, color])
elif color == 'Orange':
ball = Ball([x, y])
def assignIDmarks():
if robotList is not None:
for idx, robot in enumerate(robotList):
distances = []
for i, mark in enumerate(robotMarks):
mark_dist = dist.euclidean(mark[:2], robot.pos)
distances.append((i, mark_dist))
distances.sort(key=lambda x: x[1])
closest_marks_indices = [i for i, _ in distances[:4]]
robot.circles = [robotMarks[i] for i in closest_marks_indices]
robot.ID = idx + 1
def detect_circles(image):
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
blurred = cv2.GaussianBlur(gray, (9, 9), 0)
circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=15, maxRadius=50)
return circles
def annotate_image(img):
for robot in robotList:
team_color = "B" if robot.team == 'Blue' else "Y"
cv2.putText(img, f'{team_color}', (robot.pos[0] + 20, robot.pos[1] - 40), cv2.FONT_HERSHEY_SIMPLEX, .75, (255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'\nID{robot.ID}', (robot.pos[0] + 20, robot.pos[1] - 20), cv2.FONT_HERSHEY_SIMPLEX, .75, (255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'{robot.pos }', (robot.pos[0] + 20, robot.pos[1]), cv2.FONT_HERSHEY_SIMPLEX, .75, (255, 255, 255), 2, cv2.LINE_AA)
if ball:
cv2.putText(img, f'Ball {ball.pos}', (ball.pos[0] + 20, ball.pos[1] + 20), cv2.FONT_HERSHEY_SIMPLEX, 1, (255, 255, 255), 2, cv2.LINE_AA)
# Main function
def main():
global robotList, robotMarks, ball
# Initialize globals
robotList = []
robotMarks = []
ball = None
# Load and process the video
video_path = "/Users/mannpatel/Desktop/Robocup/Assets/Video/Test2.mp4"
cap = cv2.VideoCapture(video_path)
while cap.isOpened():
ret, frame = cap.read()
if not ret:
break
# Reset robot and mark lists for each frame
robotList = []
robotMarks = []
# Detect circles in the frame
circles = detect_circles(frame)
if circles is not None:
circles = np.uint16(np.around(circles))
for circle in circles[0, :]:
IdentifyCircles(frame, circle)
cv2.circle(frame, (circle[0], circle[1]), circle[2], (0, 255, 0), 2)
cv2.circle(frame, (circle[0], circle[1]), 2, (0, 0, 255), 3)
assignIDmarks()
# for robot in robotList:
# print(f'There is a {robot.team} robot with these ID circles:')
# for mark in robot.circles:
# print(mark)
if ball:
print(f'Ball found at {ball.pos}')
for robot in robotList:
cv2.circle(frame, (robot.pos[0], robot.pos[1]), 10, (0, 0, 0), 5)
for mark in robot.circles:
cv2.circle(frame, (mark[0], mark[1]), 10, (0, 0, 0), 5)
else:
print("No circles detected")
annotate_image(frame)
cv2.imshow("Annotated Video", frame)
if cv2.waitKey(1) & 0xFF == ord('q'):
break
cap.release()
cv2.destroyAllWindows()
if __name__ == "__main__":
main()

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Computer Vision/main2.py
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# import cv2
# import numpy as np
# from scipy.spatial import distance as dist, distance
#
# class Robot:
# def __init__(self, pos=None, team='-no team!-', ID='-no ID!-'):
# self.pos = pos if pos is not None else []
# self.team = team
# self.ID = ID
# self.circles = []
#
# def add_marking(self, circle=None):
# if circle is None:
# circle = [0, 0, [0, 0, 0]]
# self.circles.append(circle)
#
# class Ball:
# def __init__(self, pos=None):
# self.pos = pos if pos is not None else []
#
# ball = Ball()
# robotList = []
# robotMarks = []
#
# def Color_Detection(blue, green, red):
# if blue >= 220 and green <= 50 and red <= 50:
# return 'Blue'
# if blue <= 50 and green >= 200 and red >= 200:
# return 'Yellow'
# if blue >= 200 and green <= 50 and red >= 200:
# return 'Purple'
# if blue <= 50 and green >= 220 and red <= 50:
# return 'Green'
# if blue <= 50 and green <= 200 and red >= 180:
# return 'Orange'
# return 'Unidentified'
#
#
# def IdentifyCircles(img, circle):
# global ball
#
# x, y = int(circle[0]), int(circle[1])
# blue, green, red = img[y, x, 0], img[y, x, 1], img[y, x, 2]
# color = Color_Detection(blue, green, red)
#
# if color == 'Blue' or color == 'Yellow':
# robotList.append(Robot([x, y], color))
# elif color == 'Green' or color == 'Purple':
# robotMarks.append([x, y, color])
# print('ROBOT FOUND')
# elif color == 'Orange':
# ball.pos = [x, y]
# print(f"Ball found at ({x}, {y})")
#
#
# def assignIDmarks():
# if robotList is not None:
# for idx, robot in enumerate(robotList):
# distances = []
#
# for i, mark in enumerate(robotMarks):
# mark_dist = distance.euclidean(mark[:2], robot.pos)
# distances.append((i, mark_dist))
# distances.sort(key=lambda x: x[1])
# closest_marks_indices = [i for i, _ in distances[:4]]
# robot.circles = [robotMarks[i] for i in closest_marks_indices]
# robot.ID = idx + 1
#
#
# def detect_circles(image):
# gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
# blurred = cv2.GaussianBlur(gray, (9, 9), 0)
# circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=15,
# maxRadius=50)
# return circles
#
#
# def annotate_image(img):
# for robot in robotList:
# team_color = "B" if robot.team == 'Blue' else "Y"
# sting = f'Team: {team_color} | ID: {robot.ID} | POS: {robot.pos}'
# cv2.putText(img, sting, (robot.pos[0] + 20, robot.pos[1] - 40), cv2.FONT_HERSHEY_SIMPLEX, .75,
# (255, 255, 255), 2, cv2.LINE_AA)
#
# if ball.pos:
# cv2.putText(img, f'Ball {ball.pos}', (ball.pos[0] + 20, ball.pos[1] + 20), cv2.FONT_HERSHEY_SIMPLEX, 1,
# (255, 255, 255), 2, cv2.LINE_AA)
#
# # Main function
# def main():
# global robotList, robotMarks
# global ball
#
# while True:
# # Initialize globals
# robotList = []
# robotMarks = []
# ball = Ball() # Ensure ball is always an instance of Ball
#
# # Load and process the image
# imgpath = "/Users/mannpatel/Desktop/Project/Computer Vision/Test2.jpeg"
# img = cv2.imread(imgpath)
# if img is None:
# print(f"Failed to load image at path: {imgpath}")
# return
#
# cv2.imshow("Original Image", img)
#
# # Detect circles in the image
# circles = detect_circles(img)
#
# if circles is not None:
# circles = np.uint16(np.around(circles))
# for circle in circles[0, :]:
# IdentifyCircles(img, circle)
# cv2.circle(img, (circle[0], circle[1]), circle[2], (0, 255, 0), 2)
# cv2.circle(img, (circle[0], circle[1]), 2, (0, 0, 255), 3)
# assignIDmarks()
#
# for robot in robotList:
# print(f'There is a {robot.team} robot with these ID circles:')
# for mark in robot.circles:
# print(mark)
#
# if ball.pos:
# print(f'Ball found at {ball.pos}')
#
# for robot in robotList:
# if robot.pos:
# cv2.circle(img, (robot.pos[0], robot.pos[1]), 10, (0, 0, 0), 5)
# for mark in robot.circles:
# cv2.circle(img, (mark[0], mark[1]), 10, (0, 0, 0), 5)
#
# else:
# print("No circles detected")
#
# annotate_image(img)
# cv2.imshow("Annotated Image", img)
# cv2.waitKey(0)
# cv2.destroyAllWindows()
#
#
# if __name__ == "__main__":
# main()
import cv2
import numpy as np
from scipy.spatial import distance as dist, distance
class Robot:
def __init__(self, pos=None, team='-no team!-', ID='-no ID!-'):
self.pos = pos if pos is not None else []
self.team = team
self.ID = ID
self.circles = []
def add_marking(self, circle=None):
if circle is None:
circle = [0, 0, [0, 0, 0]]
self.circles.append(circle)
class Ball:
def __init__(self, pos=None):
self.pos = pos if pos is not None else []
# Initialize the ball with default position
ball = Ball()
# Initialize empty lists for robots and ID markings
robotList = []
robotMarks = []
def Color_Detection(blue, green, red):
if blue >= 220 and green <= 50 and red <= 50:
return 'Blue'
if blue <= 50 and green >= 200 and red >= 200:
return 'Yellow'
if blue >= 200 and green <= 50 and red >= 200:
return 'Purple'
if blue <= 50 and green >= 220 and red <= 50:
return 'Green'
if blue <= 50 and green <= 200 and red >= 220:
return 'Orange'
return 'Unidentified'
# def Color_Detection(blue, green, red):
# if blue == 246 and green == 0 and red == 0:
# return 'Blue'
# if blue <= 0 and green >= 250 and red > 350:
# return 'Yellow'
# if blue == 247 and green == 51 and red == 235:
# return 'Purple'
# if blue == 77 and green == 252 and red == 118:
# return 'Green'
# if blue == 50 and green == 113 and red == 228:
# return 'Orange'
# return 'Unidentified'
def IdentifyCircles(img, circle):
global ball
x, y = int(circle[0]), int(circle[1])
blue, green, red = img[y, x, 0], img[y, x, 1], img[y, x, 2]
color = Color_Detection(blue, green, red)
# Debugging statements
print(f"Circle at ({x}, {y}) with BGR ({blue}, {green}, {red}) detected as {color}")
if color == 'Blue' or color == 'Yellow':
robotList.append(Robot([x, y], color))
elif color == 'Green' or color == 'Purple':
robotMarks.append([x, y, color])
print('ROBOT FOUND')
elif color == 'Orange':
ball.pos = [x, y]
print(f"Ball found at ({x}, {y})")
def assignIDmarks():
if robotList is not None:
for idx, robot in enumerate(robotList):
distances = []
for i, mark in enumerate(robotMarks):
mark_dist = distance.euclidean(mark[:2], robot.pos)
distances.append((i, mark_dist))
distances.sort(key=lambda x: x[1])
closest_marks_indices = [i for i, _ in distances[:4]]
robot.circles = [robotMarks[i] for i in closest_marks_indices]
robot.ID = idx + 1
def detect_circles(image):
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
blurred = cv2.GaussianBlur(gray, (9, 9), 0)
circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=15,
maxRadius=50)
return circles
def annotate_image(img):
for robot in robotList:
team_color = "B" if robot.team == 'Blue' else "Y"
cv2.putText(img, f'{team_color}', (robot.pos[0] + 20, robot.pos[1] - 40), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'ID{robot.ID}', (robot.pos[0] + 20, robot.pos[1] - 20), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.putText(img, f'{robot.pos}', (robot.pos[0] + 20, robot.pos[1]), cv2.FONT_HERSHEY_SIMPLEX, .75,
(255, 255, 255), 2, cv2.LINE_AA)
if ball.pos:
cv2.putText(img, f'Ball {ball.pos}', (ball.pos[0] + 20, ball.pos[1] + 20), cv2.FONT_HERSHEY_SIMPLEX, 1,
(255, 255, 255), 2, cv2.LINE_AA)
cv2.circle(img, (ball.pos[0], ball.pos[1]), 10, (0, 165, 255), -1) # Orange color for the ball
# Main function
def main():
global robotList, robotMarks
global ball
# Initialize globals
robotList = []
robotMarks = []
ball = Ball() # Ensure ball is always an instance of Ball
# Load and process the image
imgpath = "/Users/mannpatel/Desktop/Robocup/Computer Vision/Template1.png"
img = cv2.imread(imgpath)
if img is None:
print(f"Failed to load image at path: {imgpath}")
return
cv2.imshow("Original Image", img)
# Detect circles in the image
circles = detect_circles(img)
if circles is not None:
circles = np.uint16(np.around(circles))
for circle in circles[0, :]:
IdentifyCircles(img, circle)
cv2.circle(img, (circle[0], circle[1]), circle[2], (0, 255, 0), 2)
cv2.circle(img, (circle[0], circle[1]), 2, (0, 0, 255), 3)
assignIDmarks()
for robot in robotList:
print(f'There is a {robot.team} robot with these ID {robot.ID}')
for mark in robot.circles:
print(mark)
if ball.pos:
print(f'Ball found at {ball.pos}')
for robot in robotList:
if robot.pos:
cv2.circle(img, (robot.pos[0], robot.pos[1]), 10, (0, 0, 0), 5)
for mark in robot.circles:
cv2.circle(img, (mark[0], mark[1]), 10, (0, 0, 0), 5)
else:
print("No circles detected")
annotate_image(img)
cv2.imshow("Annotated Image", img)
# Use cv2.waitKey() to display the window until a key is pressed
while True:
key = cv2.waitKey(1) & 0xFF
if key == ord('q'):
break
cv2.destroyAllWindows()
if __name__ == "__main__":
main()

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35
Computer Vision/2.py → ComputerVision/Image_Processing.py
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@@ -2,9 +2,8 @@ import cv2
import numpy as np
from scipy.spatial import distance as dist, distance
class Robot:
def __init__(self, pos=None, team='-no team!-', ID='-no ID!-'):
def __init__(self, pos=None , team=None , ID=None):
self.pos = pos if pos is not None else []
self.team = team
self.ID = ID
@@ -28,18 +27,31 @@ robotList = []
robotMarks = []
def Color_Detection(blue, green, red):
if blue > 220 and green < 50 and red < 50:
if blue >= 220 and green <= 50 and red <= 50:
return 'Blue'
if blue < 50 and green > 200 and red > 200:
if blue <= 50 and green >= 200 and red >= 200:
return 'Yellow'
if blue > 200 and green < 50 and red > 200:
if blue >= 200 and green <= 50 and red >= 200:
return 'Purple'
if blue < 50 and green > 220 and red < 50:
if blue <= 50 and green >= 220 and red <= 50:
return 'Green'
if blue <= 50 and green <= 200 and red >= 180:
if blue <= 50 and green <= 200 and red >= 220:
return 'Orange'
return 'Unidentified'
# def Color_Detection(blue, green, red):
# if blue == 246 and green == 0 and red == 0:
# return 'Blue'
# if blue <= 0 and green >= 250 and red > 350:
# return 'Yellow'
# if blue == 247 and green == 51 and red == 235:
# return 'Purple'
# if blue == 77 and green == 252 and red == 118:
# return 'Green'
# if blue == 50 and green == 113 and red == 228:
# return 'Orange'
# return 'Unidentified'
def IdentifyCircles(img, circle):
global ball
@@ -48,9 +60,6 @@ def IdentifyCircles(img, circle):
blue, green, red = img[y, x, 0], img[y, x, 1], img[y, x, 2]
color = Color_Detection(blue, green, red)
# Debugging statements
print(f"Circle at ({x}, {y}) with BGR ({blue}, {green}, {red}) detected as {color}")
if color == 'Blue' or color == 'Yellow':
robotList.append(Robot([x, y], color))
elif color == 'Green' or color == 'Purple':
@@ -131,7 +140,7 @@ def main():
assignIDmarks()
for robot in robotList:
print(f'There is a {robot.team} robot with these ID circles:')
print(f'There is a {robot.team} robot with these ID {robot.ID}')
for mark in robot.circles:
print(mark)
@@ -157,7 +166,3 @@ def main():
break
cv2.destroyAllWindows()
if __name__ == "__main__":
main()

7
Computer Vision/3.py → ComputerVision/Video_Processing.py
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@@ -73,8 +73,7 @@ def assignIDmarks():
def detect_circles(image):
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
blurred = cv2.GaussianBlur(gray, (9, 9), 0)
circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=1,
maxRadius=99)
circles = cv2.HoughCircles(blurred, cv2.HOUGH_GRADIENT, 1, minDist=20, param1=50, param2=14, minRadius=20, maxRadius=59)
return circles
@@ -100,8 +99,8 @@ def main():
global ball
# Open the video file
video_path = "Assets/Images/BotsAndBall.png"
cap = cv2.VideoCapture(1)
video_path = "Assets/Video/Test2.mp4"
cap = cv2.VideoCapture(video_path)
if not cap.isOpened():
print(f"Failed to open video file: {video_path}")

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# import pygame
# import numpy as np
# # Constants based on the image provided
# FIELD_WIDTH = 13.4 # meters
# FIELD_HEIGHT = 10.4 # meters
# GOAL_WIDTH = 1.8 # meters
# GOAL_HEIGHT = 1.8 # meters
# GOAL_DEPTH = 0.7 # meters
# SCALE = 50 # pixels per meter
# FPS = 60
# # Colors
# WHITE = (255, 255, 255)
# BLACK = (0, 0, 0)
# BLUE = (0, 0, 255)
# GREEN = (0, 255, 0)
# RED = (255, 0, 0)
# ORANGE = (255, 165, 0)
# class RoboCupSSLEnv:
# def __init__(self):
# pygame.init()
# self.screen = pygame.display.set_mode((int(FIELD_WIDTH * SCALE), int(FIELD_HEIGHT * SCALE)))
# pygame.display.set_caption("RoboCup SSL Environment")
# self.clock = pygame.time.Clock()
# self.total_reward = 0
# self._reset_positions()
# def _reset_positions(self):
# self.robot_pos = np.array([6.7, 5.2])
# self.robot_angle = 0
# self.ball_pos = np.array([6.7, 3.2])
# self.ball_in_possession = False
# def reset(self):
# self.total_reward = 0
# self._reset_positions()
# return self._get_obs()
# def _get_obs(self):
# return np.array([
# self.robot_pos[0], self.robot_pos[1], self.robot_angle,
# self.ball_pos[0], self.ball_pos[1], int(self.ball_in_possession)
# ])
# def step(self, action):
# if action == 0: # Turn left
# self.robot_angle -= np.pi / 18 # Turn 10 degrees
# elif action == 1: # Turn right
# self.robot_angle += np.pi / 18 # Turn 10 degrees
# elif action == 2: # Move forward
# self.robot_pos[0] += 0.1 * np.cos(self.robot_angle)
# self.robot_pos[1] += 0.1 * np.sin(self.robot_angle)
# elif action == 3: # Move backward
# self.robot_pos[0] -= 0.1 * np.cos(self.robot_angle)
# self.robot_pos[1] -= 0.1 * np.sin(self.robot_angle)
# elif action == 4: # Kick
# if self.ball_in_possession:
# self.ball_pos = self.robot_pos + 2 * np.array([np.cos(self.robot_angle), np.sin(self.robot_angle)])
# self.ball_in_possession = False
# # Ball possession
# if not self.ball_in_possession and np.linalg.norm(self.robot_pos - self.ball_pos) < 0.2:
# self.ball_in_possession = True
# # Move ball with robot if in possession
# if self.ball_in_possession:
# self.ball_pos = self.robot_pos + np.array([0.2 * np.cos(self.robot_angle), 0.2 * np.sin(self.robot_angle)])
# # Collision with field boundaries
# self.robot_pos = np.clip(self.robot_pos, [0, 0], [FIELD_WIDTH, FIELD_HEIGHT])
# self.ball_pos = np.clip(self.ball_pos, [0, 0], [FIELD_WIDTH, FIELD_HEIGHT])
# # Check for goal on the right side
# reward = 0
# done = False
# if self.ball_pos[0] >= FIELD_WIDTH and (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) <= self.ball_pos[1] <= (FIELD_HEIGHT / 2 + GOAL_HEIGHT / 2):
# reward += 1 # Scored a goal
# self.total_reward += reward
# print("---> Goal! Total Reward:", self.total_reward)
# self._reset_positions() # Reset player and ball positions
# return self._get_obs(), reward, done, {}
# def handle_keys(self):
# keys = pygame.key.get_pressed()
# if keys[pygame.K_LEFT]:
# return 0 # Turn left
# elif keys[pygame.K_RIGHT]:
# return 1 # Turn right
# elif keys[pygame.K_UP]:
# return 2 # Move forward
# elif keys[pygame.K_DOWN]:
# return 3 # Move backward
# elif keys[pygame.K_SPACE]:
# return 4 # Kick
# return -1 # No action
# def render(self):
# self.screen.fill(BLACK) # Clear screen
# # Draw field
# pygame.draw.rect(self.screen, GREEN, pygame.Rect(0, 0, FIELD_WIDTH * SCALE, FIELD_HEIGHT * SCALE))
# # Draw center line
# pygame.draw.line(self.screen, WHITE, (FIELD_WIDTH * SCALE / 2, 0), (FIELD_WIDTH * SCALE / 2, FIELD_HEIGHT * SCALE), 2)
# # Draw center circle
# pygame.draw.circle(self.screen, WHITE, (int(FIELD_WIDTH * SCALE / 2), int(FIELD_HEIGHT * SCALE / 2)), int(1.0 * SCALE), 2)
# # Draw goals
# # Left goal
# pygame.draw.rect(self.screen, WHITE, pygame.Rect(0, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_DEPTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# pygame.draw.rect(self.screen, WHITE, pygame.Rect(0, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_WIDTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# # Right goal
# pygame.draw.rect(self.screen, RED, pygame.Rect((FIELD_WIDTH - GOAL_DEPTH) * SCALE, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_DEPTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# pygame.draw.rect(self.screen, RED, pygame.Rect((FIELD_WIDTH - GOAL_WIDTH) * SCALE, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_WIDTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# # Draw robot
# robot_center = (int(self.robot_pos[0] * SCALE), int(self.robot_pos[1] * SCALE))
# pygame.draw.circle(self.screen, BLUE, robot_center, 10)
# # Draw direction arrow
# robot_arrow_end = (robot_center[0] + int(20 * np.cos(self.robot_angle)), robot_center[1] + int(20 * np.sin(self.robot_angle)))
# pygame.draw.line(self.screen, BLUE, robot_center, robot_arrow_end, 3)
# # Draw ball
# ball_center = (int(self.ball_pos[0] * SCALE), int(self.ball_pos[1] * SCALE))
# pygame.draw.circle(self.screen, ORANGE, ball_center, 8)
# pygame.display.flip()
# self.clock.tick(FPS)
# def close(self):
# pygame.quit()
# # Usage
# env = RoboCupSSLEnv()
# obs = env.reset()
# done = False
# while not done:
# for event in pygame.event.get():
# if event.type == pygame.QUIT:
# done = True
# action = env.handle_keys()
# if action != -1:
# obs, reward, done, info = env.step(action)
# env.render()
# if env.total_reward >= 25:
# done = True
# env.close()
import gym
from gym import spaces
import pygame
import numpy as np
# Constants based on the image provided
FIELD_WIDTH = 13.4 # meters
FIELD_HEIGHT = 10.4 # meters
GOAL_WIDTH = 1.8 # meters
GOAL_HEIGHT = 1.8 # meters
GOAL_DEPTH = 0.7 # meters
SCALE = 50 # pixels per meter
FPS = 60
# Colors
WHITE = (255, 255, 255)
BLACK = (0, 0, 0)
BLUE = (0, 0, 255)
GREEN = (0, 255, 0)
RED = (255, 0, 0)
ORANGE = (255, 165, 0)
class RoboCupSSLEnv(gym.Env):
metadata = {'render.modes': ['human']}
def __init__(self):
super(RoboCupSSLEnv, self).__init__()
# Define action and observation space
# They must be gym.spaces objects
self.action_space = spaces.Discrete(5) # 5 possible actions
self.observation_space = spaces.Box(
low=np.array([0, 0, -np.pi, 0, 0, 0]),
high=np.array([FIELD_WIDTH, FIELD_HEIGHT, np.pi, FIELD_WIDTH, FIELD_HEIGHT, 1]),
dtype=np.float32
)
self.total_reward = 0
self._reset_positions()
def _reset_positions(self):
self.robot_pos = np.array([6.7, 5.2])
self.robot_angle = 0
self.ball_pos = np.array([6.7, 3.2])
self.ball_in_possession = False
def reset(self):
self.total_reward = 0
self._reset_positions()
return self._get_obs()
def _get_obs(self):
return np.array([
self.robot_pos[0], self.robot_pos[1], self.robot_angle,
self.ball_pos[0], self.ball_pos[1], int(self.ball_in_possession)
])
def step(self, action):
if action == 0: # Turn left
self.robot_angle -= np.pi / 18 # Turn 10 degrees
elif action == 1: # Turn right
self.robot_angle += np.pi / 18 # Turn 10 degrees
elif action == 2: # Move forward
self.robot_pos[0] += 0.1 * np.cos(self.robot_angle)
self.robot_pos[1] += 0.1 * np.sin(self.robot_angle)
elif action == 3: # Move backward
self.robot_pos[0] -= 0.1 * np.cos(self.robot_angle)
self.robot_pos[1] -= 0.1 * np.sin(self.robot_angle)
elif action == 4: # Kick
if self.ball_in_possession:
self.ball_pos = self.robot_pos + 2 * np.array([np.cos(self.robot_angle), np.sin(self.robot_angle)])
self.ball_in_possession = False
# Ball possession
if not self.ball_in_possession and np.linalg.norm(self.robot_pos - self.ball_pos) < 0.2:
self.ball_in_possession = True
# Move ball with robot if in possession
if self.ball_in_possession:
self.ball_pos = self.robot_pos + np.array([0.2 * np.cos(self.robot_angle), 0.2 * np.sin(self.robot_angle)])
# Collision with field boundaries
self.robot_pos = np.clip(self.robot_pos, [0, 0], [FIELD_WIDTH, FIELD_HEIGHT])
self.ball_pos = np.clip(self.ball_pos, [0, 0], [FIELD_WIDTH, FIELD_HEIGHT])
# Check for goal on the right side
reward = 0
done = False
if self.ball_pos[0] >= FIELD_WIDTH and (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) <= self.ball_pos[1] <= (FIELD_HEIGHT / 2 + GOAL_HEIGHT / 2):
reward += 1 # Scored a goal
self.total_reward += reward
print("---> Goal! Total Reward:", self.total_reward)
self._reset_positions() # Reset player and ball positions
return self._get_obs(), reward, done, {}
def render(self, mode='human'):
if not hasattr(self, 'screen'):
pygame.init()
self.screen = pygame.display.set_mode((int(FIELD_WIDTH * SCALE), int(FIELD_HEIGHT * SCALE)))
pygame.display.set_caption("RoboCup SSL Environment")
self.clock = pygame.time.Clock()
self.screen.fill(BLACK) # Clear screen
# Draw field
pygame.draw.rect(self.screen, GREEN, pygame.Rect(0, 0, FIELD_WIDTH * SCALE, FIELD_HEIGHT * SCALE))
# Draw center line
pygame.draw.line(self.screen, WHITE, (FIELD_WIDTH * SCALE / 2, 0), (FIELD_WIDTH * SCALE / 2, FIELD_HEIGHT * SCALE), 2)
# Draw center circle
pygame.draw.circle(self.screen, WHITE, (int(FIELD_WIDTH * SCALE / 2), int(FIELD_HEIGHT * SCALE / 2)), int(1.0 * SCALE), 2)
# Draw goals
# Left goal
pygame.draw.rect(self.screen, WHITE, pygame.Rect(0, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_DEPTH * SCALE, GOAL_HEIGHT * SCALE), 2)
pygame.draw.rect(self.screen, WHITE, pygame.Rect(0, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_WIDTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# Right goal
pygame.draw.rect(self.screen, RED, pygame.Rect((FIELD_WIDTH - GOAL_DEPTH) * SCALE, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_DEPTH * SCALE, GOAL_HEIGHT * SCALE), 2)
pygame.draw.rect(self.screen, RED, pygame.Rect((FIELD_WIDTH - GOAL_WIDTH) * SCALE, (FIELD_HEIGHT / 2 - GOAL_HEIGHT / 2) * SCALE, GOAL_WIDTH * SCALE, GOAL_HEIGHT * SCALE), 2)
# Draw robot
robot_center = (int(self.robot_pos[0] * SCALE), int(self.robot_pos[1] * SCALE))
pygame.draw.circle(self.screen, BLUE, robot_center, 10)
# Draw direction arrow
robot_arrow_end = (robot_center[0] + int(20 * np.cos(self.robot_angle)), robot_center[1] + int(20 * np.sin(self.robot_angle)))
pygame.draw.line(self.screen, GREEN, robot_center, robot_arrow_end, 3)
# Draw ball
ball_center = (int(self.ball_pos[0] * SCALE), int(self.ball_pos[1] * SCALE))
pygame.draw.circle(self.screen, ORANGE, ball_center, 8)
pygame.display.flip()
self.clock.tick(FPS)
def close(self):
pygame.quit()

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ComputerVision/train_rl_model.py Normal file
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import gymnasium as gym
from stable_baselines3 import PPO
from stable_baselines3.common.env_checker import check_env
from robocup_ssl_env import RoboCupSSLEnv
# Create environment
env = RoboCupSSLEnv()
# Check if the environment follows the Gym interface
check_env(venv)
# Instantiate the agent
model = PPO('MlpPolicy', env, verbose=1)
# Train the agent
model.learn(total_timesteps=10000)
# Save the model
model.save("ppo_robocup_ssl")
# To reload the trained model
# model = PPO.load("ppo_robocup_ssl")
# Evaluate the trained agent
obs = env.reset()
for _ in range(1000):
action, _states = model.predict(obs, deterministic=True)
obs, reward, done, info = env.step(action)
env.render()
if done:
obs = env.reset()
env.close()

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main.py Normal file
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import ComputerVision.Image_Processing as file1
import ComputerVision.Video_Processing as file2
import sys
if sys.argv[1] == "file1":
if __name__ == '__main__':
file1.main()
elif sys.argv[1] == "file2":
if __name__ == '__main__':
file2.main()
else:
print("Invalid argument")