# color tracking with conic mirror - By: EmaMaker - wed 15 jan 2020 # Based on: # color tracking - By: paolix - ven mag 18 2018 # Automatic RGB565 Color Tracking Example # import sensor, image, time, pyb, math from pyb import UART uart = UART(3,19200, timeout_char = 1000) # LED Setup ################################################################## red_led = pyb.LED(1) green_led = pyb.LED(2) blue_led = pyb.LED(3) red_led.off() green_led.off() blue_led.on() ############################################################################## #thresholds = [ (30, 100, 15, 127, 15, 127), # generic_red_thresholds # (30, 100, -64, -8, -32, 32), # generic_green_thresholds # (0, 15, 0, 40, -80, -20)] # generic_blue_thresholds #thresholds = [ (54, 93, -10, 25, 55, 70), # thresholds yellow goal # (30, 45, 1, 40, -60, -19)] # thresholds blue goal # thresholds = [ (55, 98, -14, 12, 7, 55), # thresholds yellow goal (26, 65, -11, 47, -95, -36)] # thresholds blue goal (6, 31, -15, 4, -35, 0) roi = (0, 6, 318, 152) # Camera Setup ############################################################### '''sensor.reset() sensor.set_pixformat(sensor.RGB565) sensor.set_framesize(sensor.QVGA) sensor.skip_frames(time = 2000) sensor.set_auto_gain(False) # must be turned off for color tracking sensor.set_auto_whitebal(False) # must be turned off for color tracking sensor.set_auto_exposure(False, 10000) #sensor.set_backlight(1) #sensor.set_brightness(+2) #sensor.set_windowing(roi) clock = time.clock()''' sensor.reset() sensor.set_pixformat(sensor.RGB565) sensor.set_framesize(sensor.QVGA) sensor.set_contrast(+0) sensor.set_saturation(+0) sensor.set_brightness(0) sensor.set_quality(0) sensor.set_auto_exposure(False, 8000) sensor.set_auto_gain(True) sensor.skip_frames(time = 300) clock = time.clock() ############################################################################## # [] list # () tupla '''while(True): clock.tick() img = sensor.snapshot()''' while(True): clock.tick() blue_led.off() tt_yellow = [(0,999,0,1)] ## creo una lista di tuple per il giallo, valore x = 999 : non trovata tt_blue = [(0,999,0,2)] ## creo una lista di tuple per il blue, valore x = 999 : non trovata img = sensor.snapshot() for blob in img.find_blobs(thresholds, pixels_threshold=500, area_threshold=700 , merge = True): img.draw_rectangle(blob.rect()) img.draw_cross(blob.cx(), blob.cy()) if (blob.code() == 1): tt_yellow = tt_yellow + [ (blob.area(),blob.cx(),blob.cy(),blob.code() ) ] if (blob.code() == 2): tt_blue = tt_blue + [ (blob.area(),blob.cx(),blob.cy(),blob.code() ) ] tt_yellow.sort(key=lambda tup: tup[0]) ## ordino le liste tt_blue.sort(key=lambda tup: tup[0]) ## ordino le liste ny = len(tt_yellow) nb = len(tt_blue) '''Yellow''' area,cx,cy,code = tt_yellow[ny-1] # coordinata x del piu' grande y se montata al contrario cx = img.width() / 2 - cx cy = img.height() / 2 - cy angle = math.pi/2 - math.atan2(cy, cx) dist = math.sqrt(cx*cx + cy*cy) string_yellow = "Y"+str(cx)+" | "+str(cy)+" | "+str(angle)+" | "+str(dist)+"y" print (string_yellow) # test on serial terminal '''Blue''' area,cx,cy,code = tt_blue[nb-1] # coordinata x del piu' grande y se montata al contrario cx = img.width() / 2 - cx cy = img.height() / 2 - cy angle = math.pi/2 - math.atan2(cy, cx) dist = math.sqrt(cx*cx + cy*cy) string_blue = "B"+str(cx)+" | "+str(cy)+" | |"+str(angle)+" | "+str(dist)+"b" print (string_blue) # test on serial terminal #print ("..................................") print(clock.fps())