Delete 'Color_Sorting/Program/Object_sorter.py'

Color_Sorting/Program/Object_sorter.py

@@ -1,232 +0,0 @@
-#!/usr/bin/env python3
-
-from time import sleep
-from ev3dev2.motor import Motor, MoveTank, SpeedPercent, OUTPUT_A, OUTPUT_B, OUTPUT_C, OUTPUT_D 
-from ev3dev2.sensor import INPUT_2,INPUT_3,INPUT_4
-from ev3dev2.sensor.lego import ColorSensor, UltrasonicSensor, GyroSensor
-from ev3dev2.led import Leds
-from pixycamev3.pixy2 import Pixy2
-
-class Object_Sorter(): 
-    # Define type of global variables
-    state: str
-    last_state: str
-    us: UltrasonicSensor
-    cs: ColorSensor
-    gyro: GyroSensor
-    m_left: Motor
-    m_right: Motor
-    tank: MoveTank
-    leds: Leds
-    pixy2: Pixy2
-    params: dict
-    states: dict
-    cylces: int
-
-    # Define all inputs, outputs of the Robot and initialize
-    def __init__(self, **args):
-        # Camera and sensors are inputs
-        self.us = UltrasonicSensor(args.get("ultrasonic_input",INPUT_2))
-        self.cs = ColorSensor(args.get("color_input",INPUT_3))
-        self.gyro = GyroSensor(args.get("gyro_input",INPUT_4))
-        self.pixy2 = Pixy2(port=args.get("camera_port",1), i2c_address=0x54)
-        # Motors are outputs
-        self.m_left = Motor(args.get("leftmotor_output",OUTPUT_A)) 
-        self.m_right = Motor(args.get("rightmotor_output",OUTPUT_D))
-        # Also define drive tank to move syncronized
-        self.tank = MoveTank(args.get("leftmotor_output",OUTPUT_A), args.get("rightmotor_output",OUTPUT_D)) 
-        self.leds = Leds()
-
-        # The motor is initialized to run counter-clockwise (gegen den Uhrzeigersinn)
-                # use 'normal' to initialize it to run clockwise (im Uhrzeigersinn)
-        self.m_left.polarity = args.get("leftmotor_polarity",'inversed')
-        self.m_right.polarity = args.get("rightmotor_polarity",'inversed') 
-        
-        # Read inputs for the given experiment / enviroment
-        params["sig_let"] = args.get("signature_dice_remains",1) # Signatur of orange dice
-        params["sig_sort"] = args.get("signature_dice_sorted",2)# Signatur of green dice
-        params["fast"] = args.get("speed_drive", 30) # driving speed
-        params["slow"] = args.get("speed_search", 10) # searching speed
-        params["dist_us"] = args.get("distance_us",12) # detection range ultrasonic sensor
-        params["line"] = args.get("max_reflection_outline", 10) # max. reflection of outline 
-        
-        # Safe Parameters for later, can be changed
-        self.params = params
-
-        # initalization state defined
-        self.state = "search" # Initiate search state for beginning
-        self.last_state = "search" # Variable for saving last state 
-        self.cycles = 0 # control variable
-        self.gyro.reset() # reset gyro sensor
-
-        self.states = { # dictionary of the states/classes 
-            "search": self.search,
-            "get": self.get,
-            "sort": self.sort,
-            "avoid": self.avoid,
-            "edge": self.edge
-        }
-
-    # Define method/state search
-    def search (self): 
-        # turn slowly aroud on place and search for blocks, 
-        # if nothing is found change searchplace
-        self.leds.set_color("LEFT", "BLACK")
-        self.leds.set_color("RIGHT", "BLACK")
-        # turn on place to the right
-        self.m_right.on(SpeedPercent(-1*self.params["slow"]))
-        self.m_left.on(SpeedPercent(self.params["slow"])) 
-        # search for blocks
-        nr_sort, sort_block = self.pixy2.get_blocks(self.params["sig_sort"], 2)
-        nr_let, let_block = self.pixy2.get_blocks(self.params["sig_let"], 2)
-        if self.cs.reflected_light_intensity < self.params["line"]: # if outline is reached change state to edge
-            self.tank.stop()
-            self.last_state = self.state
-            self.state = "edge"
-        elif self.us.distance_centimeters < self.params["dist_us"]: # if a block is currently in the arms change to sort
-            self.last_state = state 
-            self.state = "sort"
-        elif nr_sort > 0: # when block to sort is found then change to get 
-            self.tank.stop()
-            self.last_state = self.state
-            self.state = "get"
-        elif nr_let > 0: # when block that remains is found then change to avoid 
-            self.last_state = self.state
-            self.state = "avoid"
-        elif self.gyro.angle > 720: # when the robot does not find a block drive a little bit forward
-            rounds=0 # rounds of driving forward
-            while self.cs.reflected_light_intensity > self.params["line"] and rounds <= 5:
-                self.tank.on(self.params["fast"],self.params["fast"])
-                sleep(0.2)
-                rounds+=1 
-            if self.cs.reflected_light_intensity <= self.params["line"] : 
-                self.tank.stop()
-                self.last_state = self.state
-                self.state = "edge"
-            self.gyro.reset()
-            rounds=0 # Reset control variable
-
-    # Define method/state get  
-    def get (self): 
-        # drive twoards block and get it into arms
-        self.leds.set_color("LEFT", "GREEN")
-        self.leds.set_color("RIGHT", "BLACK")
-        # drive straight ahead
-        self.tank.on(self.params["fast"],self.params["fast"])
-        # find the block for sorting again
-        nr_sort, sort_block = self.pixy2.get_blocks(self.params["sig_sort"], 2)
-        if nr_sort > 0: # if block is found again get position
-            x = sort_block[0].x_center #get where in the field of vision the block lays
-            self.cylces = 0
-        else: # when block is not found, virtually place the robot in the middle of the vision 
-            x = 130 
-            self.cylces +=1
-            if 4 <= self.cylces < 6: # camera has not found block for 4 cycles
-                self.tank.on_for_seconds(-1*self.params["fast"],-1*self.params["fast"],0.4) # drive backwards max. 2 times
-            elif 6 == self.cylces: # if block is not found drive a little bit to left
-                self.m_right.on(SpeedPercent(self.params["slow"]))
-                self.m_left.on(SpeedPercent(-1*self.params["slow"])) 
-                sleep(0.2)
-            elif self.cylces > 6: # when block is still not found go back to search
-                self.cylces = 0
-                self.state = "search"   
-                self.gyro.reset()
-        # Decide what robot should do with the gathered information
-        if self.us.distance_centimeters <= self.params["dist_us"]: # block is in the arms of robot change to sort
-            self.last_state = self.state
-            self.state = "sort"  # when block distance is small switch state 
-        else: # correct drive direction to get block into arms
-            # when block on left side drive more left
-            if x < 110: # turn left
-                self.m_right.on(SpeedPercent(self.params["slow"]))
-                self.m_left.on(SpeedPercent(-1*self.params["slow"]))  
-            # when block on right side drive more right
-            elif x > 150: # turn right
-                self.m_right.on(SpeedPercent(-1*self.params["slow"]))
-                self.m_left.on(SpeedPercent(self.params["slow"]))   
-        if self.cs.reflected_light_intensity < self.params["line"]: # robot detected line change to edge
-            self.tank.stop()
-            self.last_state = self.state
-            self.state = "edge" # When colorsensor detects line then switch state 
-
-    # Define method/state sort
-    def sort (self):  
-        # block is caught, drive to the edge
-        self.leds.set_color("LEFT", "GREEN")
-        self.leds.set_color("RIGHT", "GREEN")
-        # drive straight ahead
-        self.tank.on(self.params["fast"],self.params["fast"])
-        # search for block to let be in area
-        nr_let, let_block = self.pixy2.get_blocks(sig_let, 2)
-        if self.cs.reflected_light_intensity < self.params["line"]: # when reached line change to edge
-            self.tank.stop()
-            self.last_state = self.state
-            self.state = "edge" 
-        elif nr_let > 0: 
-            self.last_state = self.state
-            self.state = "avoid"
-
-    # Define method/state avoid
-    def avoid (self):
-        # found green block, do not want to kick it out 
-        self.leds.set_color("LEFT", "ORANGE")
-        self.leds.set_color("RIGHT", "ORANGE")
-        # search for green block again
-        nr_let, let_block = self.pixy2.get_blocks(sig_let, 2)
-        if nr_let > 0: # if block is found again get position
-            x = let_block[0].x_center # get where in the field of vision the block lays
-        else: # when block is not found, virtually place the robot in the middle of the vision 
-            x = 130
-        # When block lays in middle of the vision drive around it 
-        if 100 < x < 150: 
-            self.m_right.on(SpeedPercent(-1*self.params["fast"]))
-            self.m_left.on(SpeedPercent(self.params["fast"]))
-            sleep(0.2)
-        self.state = self.last_state
-        self.last_state = "avoid"
-
-    # Define method/state edge
-    def edge (self):
-        # robot reached outerline and should turn around
-        self.leds.set_color("LEFT", "BLACK")
-        self.leds.set_color("RIGHT", "RED")
-        self.gyro.reset() # reset gyro sensor 
-        # drive straight backwards
-        self.tank.on_for_rotations(-1*self.params["fast"],-1*self.params["fast"],2)
-        while self.gyro.angle < 100: #turn around for 100 degrees
-            self.m_right.on(SpeedPercent(-1*self.params["fast"])) 
-            self.m_left.on(SpeedPercent(self.params["fast"]))
-        self.state = "search"
-        self.gyro.reset() # reset gyro sensor again
-    
-    def get_params(self):
-        return self.params
-
-    def run(self): 
-        print('start')
-        while True: # endless-loop for switching states        
-            func = self.states.get(self.state) # function that gets state 
-            func() # activate current state
-            sleep(0.3) # wait for 0.3 seconds between the different states 
-
-if __name__ == "__main__":
-    # All arguments that can be changed are given here
-    arguments = dict(
-        #ultrasonic_input = INPUT_2,
-        #color_input = INPUT_3,
-        #gyro_input = INPUT_4,
-        #camera_port = 1,
-        #leftmotor_output = OUTPUT_A,
-        #rightmotor_output = OUTPUT_D,
-        #signature_dice_remains = 1,   
-        #signature_dice_sorted = 2,
-        #speed_drive = 30,
-        #speed_search = 10,
-        #distance_us =10,
-        max_reflection_outline = 10
-
-    )
-    
-    os = Object_Sorter(arguments)
-    os.run()
-