基于opencv-Python小车循线学习笔记

基于opencv-Python小车循线学习笔记,pid
加入摄像头模块,让小车实现自动循迹行驶
思路为:摄像头读取图像,进行二值化,将白色的赛道凸显出来
选择下方的一行像素,黑色为0,白色为255
找到白色值的中点
目标中点与标准中点(320)进行比较得出偏移量
根据偏移量,采用PID控制器来控制小车左右轮的转速

# coding:utf-8



import RPi.GPIO as gpio
import time
import cv2
import numpy as np

def sign(x):
    if x>0:
        return 1.0
    else:
        return -1.0

# 定义引脚
pin1 = 16
#pin2 = 12
pin3 = 22
#pin4 = 18

# 设置GPIO口为BOARD编号规范
gpio.setmode(gpio.BOARD)

# 设置GPIO口为输出
gpio.setup(pin1, gpio.OUT)
#gpio.setup(pin2, gpio.OUT)
gpio.setup(pin3, gpio.OUT)
#gpio.setup(pin4, gpio.OUT)

# 设置PWM波,频率为500Hz
pwm1 = gpio.PWM(pin1, 500)
#pwm2 = gpio.PWM(pin2, 500)
pwm3 = gpio.PWM(pin3, 500)
#pwm4 = gpio.PWM(pin4, 500)

# pwm波控制初始化
pwm1.start(0)
#pwm2.start(0)
pwm3.start(0)
#pwm4.start(0)

# center定义
center_now = 320
# 打开摄像头,图像尺寸640*480(长*高),opencv存储值为480*640(行*列)
cap = cv2.VideoCapture(0)

# PID 初始数据
error = [0.0] * 3
adjust = [0.0] * 3
# PID 参数配置
kp = 1.5
ki = 0.4
kd = 0.1
target = 320

while (1):
    ret, frame = cap.read()
    # 转化为灰度图
    gray = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
    # 大津法二值化
    retval, dst = cv2.threshold(gray, 0, 255, cv2.THRESH_OTSU)
    # 膨胀,白区域变大
    dst = cv2.dilate(dst, None, iterations=2)
    # # 腐蚀,白区域变小
    # dst = cv2.erode(dst, None, iterations=6)

    # 单看第400行的像素值s
    color = dst[400]
    # 找到白色的像素点个数
    white_count = np.sum(color == 255)
    # 找到白色的像素点索引
    white_index = np.where(color == 255)

    # 防止white_count=0的报错
    if white_count == 0:
        white_count = 1

    # 找到黑色像素的中心点位置
    center_now = (white_index[0][white_count - 1] + white_index[0][0]) / 2

    # 计算出center_now与标准中心点的偏移量
    direction = center_now - 320

    print(direction)

    # 停止
    if abs(direction) > 250:
        pwm1.ChangeDutyCycle(0)
       # pwm2.ChangeDutyCycle(0)
        pwm3.ChangeDutyCycle(0)
      #  pwm4.ChangeDutyCycle(0)

    # 更新PID误差
    error[0] = error[1]
    error[1] = error[2]
    error[2] = center_now - target

    # 更新PID输出(增量式PID表达式)
    adjust[0] = adjust[1]
    adjust[1] = adjust[2]
    # adjust(k+2) = adjust(k+1) + kp * (e(k+2) - e(k+1)) + ki * e(k+2) + kd * (e(k+2)-2*e(k+1)+e(k))
    adjust[2] = adjust[1] \
        + kp*(error[2] - error[1]) \
        + ki*error[2] \
        + kd*(error[2] - 2*error[1] + error[0]); 

    # 饱和输出限制在70绝对值之内
    if abs(adjust[2]) > 70:
        adjust[2] = sign(adjust[2]) * 70

    # 执行PID

    # 右转
    elif adjust[2] > 0:
        pwm1.ChangeDutyCycle(30+ adjust[2])
       # pwm2.ChangeDutyCycle(0)
        pwm3.ChangeDutyCycle(30)
      #  pwm4.ChangeDutyCycle(0)

    # 左转
    elif adjust[2] < 0:
        pwm1.ChangeDutyCycle(30)
       # pwm2.ChangeDutyCycle(0)
        pwm3.ChangeDutyCycle(30 + abs(adjust[2]))
       # pwm4.ChangeDutyCycle(0)

    if cv2.waitKey(1) & 0xFF == ord('q'):
        break
    else:
        time.sleep(0.05)

# 释放清理
cap.release()
cv2.destroyAllWindows()
pwm1.stop()
#pwm2.stop()
pwm3.stop()
#pwm4.stop()
gpio.cleanup()


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版权声明:本文为CSDN博主「六月初的一天」的原创文章,遵循CC 4.0 BY-SA版权协议,转载请附上原文出处链接及本声明。
原文链接:https://blog.csdn.net/weixin_45215354/article/details/107153899

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