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送药小车代码仓库:https://gitee.com/lcsc/medical_car
更好的观看体验请去:https://lceda001.feishu.cn/wiki/ZDYbwqDfCiwVlckUEcScF0KSnRh
送药小车立创开源平台资料:https://oshwhub.com/li-chuang-kai-fa-ban/21-dian-sai-f-ti-zhi-neng-song-yao-xiao-che
K210功能实现代码讲解
具体实现代码如下(在2_Code->application->sensor->k210->pyconde->main.py):
- # Hello World Example
- #
- # Welcome to the CanMV IDE! Click on the green run arrow button below to run the script!
- import sensor, image, time, lcd, struct, ustruct
- import gc
- from machine import UART,Timer,PWM
- from board import board_info
- from fpioa_manager import fm
- import KPU as kpu
- from Maix import GPIO,utils
- import gc
- import machine
- lcd.init() # Init lcd display
- lcd.clear(lcd.RED) # Clear lcd screen.
- sensor.reset(freq=22000000, dual_buff=1) # 设置摄像头频率 24M 开启双缓冲模式 会提高帧率 但内存占用增加
- sensor.set_auto_exposure(0) # 设置自动曝光
- sensor.set_auto_gain(False) # 颜色跟踪必须关闭自动增益
- sensor.set_auto_whitebal(False) # 颜色跟踪必须关闭白平衡
- sensor.set_pixformat(sensor.RGB565) # Set pixel format to RGB565 (or GRAYSCALE)
- sensor.set_framesize(sensor.QVGA) # Set frame size to QVGA (320x240)
- #kpu = KPU()
- #kpu.load_kmodel("/sd/KPU/mnist/uint8_mnist_cnn_model.kmodel")
- sensor.skip_frames(time = 2000) # Wait for settings take effect.
- clock = time.clock() # Create a clock object to track the FPS.
- sensor.set_auto_exposure(0) # 设置自动曝光
- sensor.set_vflip(1)
- #______________________________________________________________________________________________________________________________
- #打印内存分配情况
- print(utils.gc_heap_size())
- print("stack mem:"+str(gc.mem_free() / 1024)) # stack mem
- print("heap mem:"+str(utils.heap_free() / 1024)) # heap mem
- #第一次用执行一次下面这两个语句
- #utils.gc_heap_size(800*1024)
- #machine.reset()
- #______________________________________________________________________________________________________________________________
- #程序运行选择
- is_need_debug = 0
- is_patrol_line = 0
- is_upacker_debug = 0
- is_stack_heap_mem_debug = 0
- is_upacker_recive_debug = 1
- is_findflob_debug = 0
- #______________________________________________________________________________________________________________________________
- #程序运行状态
- work_mode = 0 #0是巡线模式,1是数字识别模式
- #______________________________________________________________________________________________________________________________
- #串口配置区
- fm.register(6, fm.fpioa.UART1_TX, force=True)
- fm.register(7, fm.fpioa.UART1_RX, force=True)
- k210_uart = UART(UART.UART1, 115200, 8, 0, 0, timeout=1000, read_buf_len=4096)
- uart_test_write_str = '1260808878'
- #______________________________________________________________________________________________________________________________
- #按键蜂鸣器配置区
- #注册IO,注意高速GPIO口才有中断
- fm.register(35, fm.fpioa.GPIO0)
- fm.register(16, fm.fpioa.GPIOHS0)
- #构建案件对象
- KEY=GPIO(GPIO.GPIOHS0, GPIO.IN, GPIO.PULL_UP)
- #PWM通过定时器配置,接到IO15引脚
- tim = Timer(Timer.TIMER1, Timer.CHANNEL0, mode=Timer.MODE_PWM)
- beep = PWM(tim, freq=1000, duty=0, pin=9)
- #按键标志位
- key_node = 0
- key_press_long = 0
- #中断回调函数
- def fun(KEY):
- global work_mode,key_node,key_press_long
- temp_count = 0
- time.sleep_ms(10) #消除抖动
- while KEY.value()== 0:
- key_node = 1
- time.sleep_ms(10) #长按延时
- #长按检测计数
- temp_count=temp_count+1
- print(temp_count)
- if temp_count >= 50:
- beep.duty(50)
- time.sleep_ms(500)
- beep.duty(0)
- time.sleep_ms(100)
- print(temp_count)
- key_node = 0
- key_press_long = 1
- #开启中断,下降沿触发
- KEY.irq(fun, GPIO.IRQ_FALLING)
- #______________________________________________________________________________________________________________________________
- #要传给梁山派的数据
- #work_mode:0是巡线模式,1是数字识别模式
- #recognition:0是未知(巡线状态下),1是药房门口区域(停车线),十字路口和T字路口由
- class uart_send_data_t:
- def __init__( self, work_mode=0, recognition=0,top_block_offset=0,center_block_offset=0,left_block_offset=0,right_block_offset=0,left_number = 0,right_number = 0):
- self.work_mode = work_mode
- self.recognition = recognition
- self.top_block_offset = top_block_offset
- self.center_block_offset = center_block_offset
- self.left_block_offset = left_block_offset
- self.right_block_offset = right_block_offset
- self.left_number = left_number
- self.right_number = right_number
- global_uart_send_data = uart_send_data_t()
- #______________________________________________________________________________________________________________________________
- #感兴趣区配置
- roi_area_width = 30
- roi_area_color = (0, 0, 200)
- roi_area_thickness = 2
- left_roi = [50,40,roi_area_width,sensor.height()-40]
- right_roi = [sensor.width()-roi_area_width-50,40,roi_area_width,sensor.height()-40]
- top_roi = [0,10,sensor.width(),roi_area_width]
- center_roi = [0,int(sensor.height()/2)-int(roi_area_width/2),sensor.width(),roi_area_width]
- #bottom_roi = [0,sensor.height()- roi_area_width,sensor.width(),roi_area_width]
- black_block_roi = [0,100,sensor.width(),100]
- def draw_roi(img):
- img.draw_rectangle(left_roi, color = roi_area_color, thickness = roi_area_thickness, fill = False)
- img.draw_rectangle(right_roi, color = roi_area_color, thickness = roi_area_thickness, fill = False)
- img.draw_rectangle(top_roi, color = roi_area_color, thickness = roi_area_thickness, fill = False)
- img.draw_rectangle(center_roi, color = roi_area_color, thickness = roi_area_thickness, fill = False)
- img.draw_rectangle(black_block_roi, color = (0, 255, 0), thickness = roi_area_thickness, fill = False)
- return
- #______________________________________________________________________________________________________________________________
- #寻找色块区配置
- red_threshold =[12, 68, 11, 63, 5, 81]
- black_threshold =[0, 50, -24,-1, -18, 6]
- class red_blob_location_t:
- def __init__( self, x=0, y=0,area = 0):
- self.x = x
- self.y = y
- self.area = area
- #______________
- #左部blob位置信息
- left_blob_location = red_blob_location_t()
- left_pixels_threshold = 20 #若一个色块的像素数小于 pixel_threshold ,则会被过滤掉。
- left_area_threshold = 20 #若一个色块的边界框区域小于 area_threshold ,则会被过滤掉。
- left_x_stride = 20 #是查找某色块时需要跳过的x像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 x_stride 来提高查找色块的速度。
- left_y_stride = 20 #是查找某色块时需要跳过的y像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 y_stride 来提高查找色块的速度。
- #______________
- #右部blob位置信息
- right_blob_location = red_blob_location_t()
- right_pixels_threshold = 20 #若一个色块的像素数小于 pixel_threshold ,则会被过滤掉。
- right_area_threshold = 20 #若一个色块的边界框区域小于 area_threshold ,则会被过滤掉。
- right_x_stride = 20 #是查找某色块时需要跳过的x像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 x_stride 来提高查找色块的速度。
- right_y_stride = 20 #是查找某色块时需要跳过的y像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 y_stride 来提高查找色块的速度。
- #______________
- #顶部blob位置信息
- top_blob_location = red_blob_location_t()
- top_pixels_threshold = 20 #若一个色块的像素数小于 pixel_threshold ,则会被过滤掉。
- top_area_threshold = 20 #若一个色块的边界框区域小于 area_threshold ,则会被过滤掉。
- top_x_stride = 15 #是查找某色块时需要跳过的x像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 x_stride 来提高查找色块的速度。
- top_y_stride = 20 #是查找某色块时需要跳过的y像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 y_stride 来提高查找色块的速度。
- #______________
- #中部blob位置信息
- center_blob_location = red_blob_location_t()
- center_pixels_threshold = 20 #若一个色块的像素数小于 pixel_threshold ,则会被过滤掉。
- center_area_threshold = 20 #若一个色块的边界框区域小于 area_threshold ,则会被过滤掉。
- center_x_stride = 20 #是查找某色块时需要跳过的x像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 x_stride 来提高查找色块的速度。
- center_y_stride = 20 #是查找某色块时需要跳过的y像素的数量。找到色块后,直线填充算法将精确像素。 若已知色块较大,可增加 y_stride 来提高查找色块的速度。
- blob_location=[0,0]
- def find_blob(img):
- global global_uart_send_data
- #top_blob_location.x = -1
- #top_blob_location.y = -1
- #center_blob_location.x = -1
- #center_blob_location.y = -1
- left_blob_location.x = -1
- left_blob_location.y = -1
- right_blob_location.x = -1
- right_blob_location.y = -1
- center_blob_location.area = 0
- for blob in img.find_blobs([red_threshold], roi = left_roi, x_stride = left_x_stride, y_stride = left_y_stride, pixels_threshold=left_pixels_threshold, area_threshold=left_area_threshold, merge=False, margin=10):
- img.draw_rectangle(blob.rect())
- img.draw_cross(blob.cx(), blob.cy())
- left_blob_location.x = blob.cx()
- left_blob_location.y = blob.cy()
- left_blob_location.area = blob.area()
- for blob in img.find_blobs([red_threshold], roi = right_roi,x_stride = right_x_stride, y_stride = right_y_stride, pixels_threshold=right_pixels_threshold, area_threshold=right_area_threshold, merge=True, margin=10):
- img.draw_rectangle(blob.rect())
- img.draw_cross(blob.cx(), blob.cy())
- right_blob_location.x = blob.cx()
- right_blob_location.y = blob.cy()
- right_blob_location.area = blob.area()
- for blob in img.find_blobs([red_threshold], roi = top_roi,x_stride = top_x_stride, y_stride = top_y_stride, pixels_threshold=top_pixels_threshold, area_threshold=top_area_threshold, merge=True, margin=10):
- img.draw_rectangle(blob.rect())
- img.draw_cross(blob.cx(), blob.cy())
- #print("-------"+str(blob.area()))
- top_blob_location.x = blob.cx()
- top_blob_location.y = blob.cy()
- top_blob_location.area = blob.area()
- for blob in img.find_blobs([red_threshold], roi = center_roi,x_stride = center_x_stride, y_stride = center_y_stride, pixels_threshold=center_pixels_threshold, area_threshold=center_area_threshold, merge=True, margin=10):
- img.draw_rectangle(blob.rect())
- img.draw_cross(blob.cx(), blob.cy())
- center_blob_location.x = blob.cx()
- center_blob_location.y = blob.cy()
- center_blob_location.area = blob.area()
- #print(blob.pixels())
- #for blob in img.find_blobs([black_threshold], roi = black_block_roi, pixels_threshold=30,merge=True,margin=50):
- #img.draw_rectangle(blob.rect())
- #img.draw_cross(blob.cx(), blob.cy())
- ##print(blob.count())
- #if(blob.count() >= 5):
- #print("tinche"+str(blob.count()))
- #global_uart_send_data.recognition = 1
- #else:
- #global_uart_send_data.recognition = 0
- if(center_blob_location.area == 0):
- print("tinche")
- global_uart_send_data.recognition = 1
- else:
- global_uart_send_data.recognition = 0
- return
- #______________________________________________________________________________________________________________________________
- #色块连线区配置
- lines_color = (0, 200, 0)
- lines_thickness = 1
- def draw_lines(img):
- img.draw_line(top_blob_location.x, top_blob_location.y, center_blob_location.x, center_blob_location.y, color = lines_color, thickness = lines_thickness)
- img.draw_line(left_blob_location.x, left_blob_location.y, right_blob_location.x, right_blob_location.y, color = lines_color, thickness = lines_thickness)
- return
- #______________________________________________________________________________________________________________________________
- #upacker python实现代码 :https://github.com/aeo123/upacker/blob/master/python/upacker.py
- #介绍请看这里:https://github.com/aeo123/upacker
- class Upacker():
- def __init__(self):
- self._STX_L = 0x55
- self._MAX_PACK_SIZE = 1024 + 4 + 128
- self._calc = 0
- self._check = 0
- self._cnt = 0
- self._flen = 0
- self._state = 0
- self._data = bytearray()
- def _decode(self, d):
- if (self._state == 0 and d == self._STX_L):
- self._state = 1
- self._calc = self._STX_L
- elif self._state == 1:
- self._flen = d & 0xff
- self._calc ^= d & 0xff
- self._state = 2
- elif self._state == 2:
- self._flen |= (d & 0xff) << 8
- self._calc ^= d & 0x3F
- # 数据包超长得情况下直接丢包
- if ((self._flen & 0x3FFF) > self._MAX_PACK_SIZE):
- self._state = 0
- return -1
- else:
- self._data = bytearray(self._flen & 0x3FFF)
- self._state = 3
- self._cnt = 0
- elif self._state == 3:
- header_crc = ((d & 0x03) << 4) | ((self._flen & 0xC000) >> 12)
- self._check = d
- if (header_crc != (self._calc & 0X3C)):
- self._state = 0
- return -1
- self._state = 4
- self._flen &= 0x3FFF
- elif self._state == 4:
- self._data[self._cnt] = d
- self._cnt += 1
- self._calc ^= d
- if self._cnt == self._flen:
- self._state = 0
- #接收完,检查check
- if ((self._calc & 0xFC) == (self._check & 0XFC)):
- return 0
- else:
- return -1
- else:
- self._state = 0
- return 1
- # 解包
- def unpack(self, bytes_data, callback):
- ret = 0
- for i in bytes_data:
- ret = self._decode(i)
- if ret == 0:
- callback(self._data)
- if(is_upacker_debug):
- print(self._data)
- elif ret == -1:
- # callback(None)
- print("err")
- # 打包
- def enpack(self, data):
- tmp = bytearray(4)
- tmp[0] = 0x55
- tmp[1] = len(data) & 0xff
- tmp[2] = (len(data) >> 8) & 0xff
- crc = tmp[0] ^ tmp[1] ^ tmp[2]
- tmp[2] |= (crc & 0x0c) << 4
- tmp[3] = 0x03 & (crc >> 4)
- for i in range(len(data)):
- crc ^= data[i]
- tmp[3] |= (crc & 0xfc)
- frame = struct.pack("BBBB%ds" % len(data), tmp[0], tmp[1], tmp[2],
- tmp[3], data)
- #python3.5之前bytes数据没有hex()属性,所以修改了下面这个
- #print(frame.hex())
- if(is_upacker_debug):
- print(''.join(map(lambda x:('' if len(hex(x))>=4 else '/x0')+hex(x)[2:],frame)))
- return frame
- #____________
- #串口命令切换模式
- uart_cmd_need_change_mode = 0
- def print_hex(bytes):
- global work_mode,uart_cmd_need_change_mode
- hex_byte = [hex(i) for i in bytes]
- if is_upacker_recive_debug:
- print("-----"+" ".join(hex_byte))
- if bytes[0] == 0x00:
- work_mode = 0
- if bytes[0] == 0x01:
- work_mode = 1
- uart_cmd_need_change_mode = 1
- #if __name__ == '__main__':
- #buf = bytearray([0x00, 0x01, 0x02,0x03,0x77])
- #pack = Upacker()
- #pkt = pack.enpack(buf)
- #pack.unpack(pkt, print_hex)
- #______________________________________________________________________________________________________________________________
- #upacker python实现代码结束
- def upacker_init():
- pack = Upacker()
- return pack
- yzh = 10
- #______________________________________________________________________________________________________________________________
- #发送数据到MCU,gd32是小端字节序
- #pack各字母对应类型
- #x pad byte no value 1
- #c char string of length 1 1
- #b signed char integer 1
- #B unsigned char integer 1
- #? _Bool bool 1
- #h short integer 2
- #H unsigned short integer 2
- #i int integer 4
- #I unsigned int integer or long 4
- #l long integer 4
- #L unsigned long long 4
- #q long long long 8
- #Q unsilong long long 8
- #f float float 4
- #d double float 8
- #s char[] string 1
- #p char[] string 1
- #P void * long
- def send_data_to_mcu(pack,global_uart_send_data):
- hex_data = ustruct.pack("<bbhhhhbb", #小端字节序
- global_uart_send_data.work_mode,
- global_uart_send_data.recognition,
- global_uart_send_data.top_block_offset, #以屏幕中线为0点
- global_uart_send_data.center_block_offset,
- global_uart_send_data.left_block_offset, #以屏幕中线为0点
- global_uart_send_data.right_block_offset,
- global_uart_send_data.left_number,
- global_uart_send_data.right_number,)
- pkg_data = pack.enpack(hex_data)
- k210_uart.write(pkg_data)
- #______________________________________________________________________________________________________________________________
- #pack解包后的回调函数
- #def data_callback(bytes):
- #hex_byte = [hex(i) for i in bytes]
- #print(" ".join(hex_byte))
- #______________________________________________________________________________________________________________________________
- #定时发送串口数据的定时器
- #构造函数
- # 定时器回调
- pack = upacker_init()
- def on_timer(timer):
- global work_mode
- global_uart_send_data.work_mode = work_mode
- if(top_blob_location.x != -1):
- global_uart_send_data.top_block_offset = top_blob_location.x-int(sensor.width()/2)
- else:
- global_uart_send_data.top_block_offset = 0
- if(center_blob_location.x != -1):
- global_uart_send_data.center_block_offset = center_blob_location.x-int(sensor.width()/2)
- else:
- global_uart_send_data.center_block_offset = 0
- if(left_blob_location.y != -1):
- global_uart_send_data.left_block_offset = left_blob_location.y-int(sensor.height()/2)
- else:
- global_uart_send_data.left_block_offset = 0
- if(right_blob_location.y != -1):
- global_uart_send_data.right_block_offset = right_blob_location.y-int(sensor.height()/2)
- else:
- global_uart_send_data.right_block_offset = 0
- global_uart_send_data.top_block_offset = top_blob_location.x-int(sensor.width()/2)
- global_uart_send_data.center_block_offset = center_blob_location.x-int(sensor.width()/2)
- send_data_to_mcu(pack,global_uart_send_data)
- # 配置定时器0通道0
- tim = Timer(Timer.TIMER0, Timer.CHANNEL0, mode=Timer.MODE_PERIODIC, period=20, unit=Timer.UNIT_MS, callback=on_timer, arg=on_timer, start=False, priority=1, div=0)
- #定时发送串口数据
- tim.start()
- #______________________________________________________________________________________________________________________________
- #数字识别配置区域
- anchors = [1.40625, 1.875, 1.09375, 1.1875, 1.25, 1.46875, 1.53125, 2.15625, 1.1875, 1.8125000000000002]
- labels = ["1", "2", "3", "4", "5", "6", "7", "8"]
- actual_number = [1,2,3,4,5,6,7,8]
- KPU = kpu.load("/sd/mx.kmodel")
- xy = [0,0]
- kpu.init_yolo2(KPU,0.7,0.01,len(anchors)//2,anchors)
- #______________________________________________________________________________________________________________________________
- #主循环
- while (True):
- gc.collect()
- img = sensor.snapshot() # Take a picture and return the image.
- # img.draw_cross(sensor.width()//2, sensor.height()//2, color = (0, 255, 0), size = 10, thickness = 2)
- clock.tick()
- #手动切换
- if key_press_long ==1:
- key_press_long = 0
- #长按后切换K210工作模式
- if work_mode == 0:
- work_mode =1
- print("work mode to 1")
- sensor.set_windowing((224, 224))
- else:
- work_mode =0
- print("work mode to 0")
- img = img.resize(320, 240)
- sensor.set_windowing((320, 240))
- #GD32控制切换
- if uart_cmd_need_change_mode == 1:
- uart_cmd_need_change_mode = 0
- #串口命令来切换K210工作模式
- if work_mode == 1:
- print("work mode to 1")
- sensor.set_windowing((224, 224))
- else:
- print("work mode to 0")
- img = img.resize(320, 240)
- sensor.set_windowing((320, 240))
- if work_mode == 0: # 巡线模式
- find_blob(img)
- draw_roi(img)
- draw_lines(img)
- if is_findflob_debug:
- print(clock.fps(), top_blob_location.x,center_blob_location.x, left_blob_location.y, right_blob_location.y) # Note: CanMV Cam runs about half as fast when connected,int(top.x),int(top.y)
- print(clock.fps(), global_uart_send_data.top_block_offset,global_uart_send_data.center_block_offset, global_uart_send_data.left_block_offset, global_uart_send_data.right_block_offset)
- print(global_uart_send_data.recognition)
- fps = clock.fps() # Update the FPS clock.
- img.draw_string(2, 2, ("%2.1ffps" % (fps)), color=(0, 128, 0), scale=2)
- lcd.display(img)
- else: # 数字识别模式
- img = sensor.snapshot() # Take a picture and return the image.
- code = kpu.run_yolo2(KPU, img)
- fps = clock.fps() # Update the FPS clock.
- img.draw_string(2, 2, ("%2.1ffps" % (fps)), color=(0, 128, 0), scale=2)
- #print(clock.fps())
- if bool(code):
- for i in code:
- img = img.draw_rectangle(i.rect(), (0, 255, 0), 2, 0)
- xy[0] = i.x()
- xy[1] = (i.y() - 20)
- img = img.draw_string(xy[0], xy[1], (labels[i.classid()]), (0, 255, 0), scale=2)
- img = img.draw_string(xy[0], xy[1] + 24, '%.3f' % i.value(), color=(255, 0, 0), scale=2)
- if(code[0].x()<code[-1].x()):
- global_uart_send_data.left_number = actual_number[code[0].classid()]
- global_uart_send_data.right_number = actual_number[(code[-1].classid())]
- else:
- global_uart_send_data.left_number = actual_number[(code[-1].classid())]
- global_uart_send_data.right_number = actual_number[(code[0].classid())]
- #print(global_uart_send_data.left_number,global_uart_send_data.right_number)
- lcd.display(img)
- read_data = k210_uart.read()
- if read_data:
- read_str = pack.unpack(read_data, print_hex)
- lcd.display(img) # Display image on lcd.
- if is_stack_heap_mem_debug:
- print("stack mem:"+str(gc.mem_free() / 1024)) # stack mem
- print("heap mem:"+str(utils.heap_free() / 1024)) # heap mem
复制代码
关键的注释都添加了,可以帮助理解代码,这段代码同时实现了寻红线和数字识别,但是还做不到同时运行,在寻红线的时候没法数字识别,这两个状态之间的切换可以通过长按K210上的用户按键或者由立创梁山派来控制切换。当送药小车到达数字识别处时就控制K210进入数字识别模式,识别到数字后再控制K210进入寻红线模式。
- 首先初始化LCD屏幕、配置摄像头、配置UART通信,并配置一个具有中断的按钮。然后,定义了感兴趣区域(ROIs)和一些用于在图像中查找色块的参数(具体可以去MaixPy的API文档中查找)。
- 设置了在图像中检测色块和在里面绘制连线的参数。共定义了四个感兴趣区域(ROI):左侧、右侧、顶部和中心。每个ROI都有自己的色块检测参数,如pixel_threshold、area_threshold、x_stride和y_stride。这些参数用于过滤掉过小的色块或者通过跳过一些像素来提高检测速度,避免一些微小噪声小色块的影响。
- find_blob函数处理输入图像(img),使用img.find_blobs方法在每个ROI中检测红色的色块。然后在色块周围绘制矩形并在其中心绘制十字标记来方便调试。检测到的色块的位置和面积信息存储在left_blob_location、right_blob_location、top_blob_location和center_blob_location结构中。如果在中心ROI中没有检测到色块,则将global_uart_send_data.recognition变量设置为1,否则设置为0,当红色线没了的时候就代表该停车了。draw_lines函数用于在上下和左右ROI的红色块之间绘制连线(上下左右ROI都识别到红色块就是一个交叉的十字),方便调试使用。
- 定义了一个名为send_data_to_mcu的函数,用于将数据发送到立创梁山派。这里使用了ustruct.pack函数将数据打包为字节序列,然后调用pack.enpack方法将数据打包,最后通过k210_uart.write将数据发送出去。
- 定义了一个名为on_timer的定时回调函数,用于定时发送串口数据。在这个函数中,根据图像中的各个位置计算出相应的偏移量,并将这些偏移量存储在global_uart_send_data对象中。然后,调用send_data_to_mcu函数将数据发送到立创梁山派的串口里面。然后,配置定时器0通道0,设置定时器的模式、周期、单位、回调函数等参数,并启动定时器。
- 进行数字识别的相关配置,用init_yolo2加载模型并初始化KPU。
- 在主循环中,根据工作模式选择执行巡线模式还是数字识别模式。在巡线模式下,调用find_blob、draw_roi、draw_lines等函数来处理摄像头采集到图像,并将处理后的图像显示在LCD上方便调试。在数字识别模式下,使用KPU运行模型并获取识别结果,将识别到的数字绘制在图像上,并将处理后的图像显示在LCD上。最后,程序会读取来自立创梁山篇串口发送来的数据,并使用pack.unpack方法解包数据。如果有数据,会执行解包,解包成功后会更新K210模式控制的标志位(巡线模式还是数字识别模式)。
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