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hazretimahmut.py
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hazretimahmut.py
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#!/usr/bin/env python3
# -*- coding: UTF-8 -*-
#/*
# @year: 2020/2021
# @authors: Sekomer, ubuntumevuz
# @touch: [email protected]
# @touch: [email protected]
#*/
import os
import sys
import csv
import math
import time
import rospy
import numba
import seaborn
import numpy as np
from numba import float32 as f32
from matplotlib import pyplot as plt
from rosserial_arduino.msg import Adc
from std_msgs.msg import String
from itertools import cycle
from sensor_msgs.msg import LaserScan, Joy
from numpy.lib.function_base import average
from geometry_msgs.msg import Point
#from pynput.keyboard import Key, Listener
np.seterr('raise')
# global variables #
TWO_THIRD_PARKING = True
REVERSE_PARKING = False
speed = 0
regen = 0
DURMAK = 0
steering_angle = 1800
speed_odometry = 0
brake_speed = 0
brake_motor_direction = 1
sol_laser = None
sag_laser = None
collecting_data = False
SOL = 0
ORTA = 1
SAG = 2
AUTONOMOUS_SPEED = 39 # never change this variable randomly!!!
AUTONOMOUS_SPEED_RECOVERY = AUTONOMOUS_SPEED
POT_CENTER = 1800
MAX_RPM_MODE_SPEED = 200
RPM_MODE = 1
CURRENT_MODE = 0
driving_mode = RPM_MODE
DORU = (1 == 1)
left_tracking = 0
right_tracking = 1
mid_tracking = 0
girildim_counter = 0
girildim_bool = True
NEUTRAL = 0
FORWARD = 1
REVERSE = 2
CAR_WIDTH = 1.5
CAR_LENGTH = 2.25
CURRENT = 0
BUS_VOLTAGE = 0
BICYCLE_LENGTH = 3.5
SOL_FIXED = 2.65
SAG_FIXED = 2.65
kararVerici = np.array([0, 1, 0])
recently_stopped = False
recently_stopped_kirmizi = False
orhandaldal = np.inf
mahmut_tuncer = np.inf
brake = False
brake_value = 0
roswtf = False
FULL_RIGHT = 0
FULL_LEFT = 3600
left_point_distance = 0
right_point_distance = 0
karar_verici_yakın_zamanda_calisti = False
kirmizida_dur_lan = False
ahaburasıdaboşmuşıheahıeah = False
olceriz_sıkıntı_yog = np.inf
YOLCU = 37
hazreticounter = 0
experimental_park_stage_1 = False
experimental_park_stage_2 = False
mahmutapozisyonçeşitliliği = np.array([.0, .0, .0])
igotthepose = False
yesil_gorundu = False
büllük = False
güllük = np.array([.0,.0,.0])
# durak experimental #
first_stop_counter = False
first_stop = False
second_stop_counter = False
second_stop = False
#*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-#
arduino_odometry = {
'speed': .0,
'steering_angle': .0,
'bus_voltage': .0,
'bus_current': .0
}
# terminal colors #
class bcolors:
HEADER = '\033[95m' #mor
OKBLUE = '\033[94m' #mavi
OKCYAN = '\033[96m' #turkuaz
OKGREEN = '\033[92m' #yeşil
WARNING = '\033[93m' #sarı
FAIL = '\033[91m' #kırmızı
ENDC = '\033[0m' #beyaz
BOLD = '\033[1m' #kalın beyaz
UNDERLINE = '\033[4m' #aktı çizili beyaz
#*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*#
# controller #
def gen():
gears = [NEUTRAL, FORWARD, NEUTRAL, REVERSE]
for i in cycle(gears):
yield i
gear_generator = gen()
AUTONOMOUS = False
GEAR = next(gear_generator)
DIRECTION = True
LIGHTS = False
EMERGENCY = False
CRUISE_CONTROL = False
YAVIZ = False
SEKO = False
TERMINATOR = False
l_left_right = 0
l_up_down = 0
r_left_right = 0
r_up_down = 0
left_trigger = 1
right_trigger = 1
BUTTON_A = 0
BUTTON_B = 0
BUTTON_X = 0
BUTTON_Y = 0
BUTTON_LB = 0
BUTTON_RB = 0
BUTTON_BACK = 0
BUTTON_START = 0
BUTTON_STICK_LEFT = 0
BUTTON_STICK_RIGHT = 0
stage1 = True
stage2 = False
stage3 = False
stage4 = False
#*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-#
# parking
is_parking_mode = False
is_curve_parking = False
is_durak_mode = False
park_coordinate = None
zed_x = None
zed_y = None
zed_z = None
durak_dik_start = None
denk_coef = None
closest_point = None
is_curve_created = False
CRITICAL_PARKING_DISTANCE = 15
CALCULATE_PARKING_SIGN_DISTANCE = 10
locked_on_target = False
parking_sign_current_distance = None
park_left_not_started = True
ACKERMAN_RADIUS = 4
LABEL_OFFSET = 9.
ERROR_ACCEPTANCE = .3
karsiya_geciyorum = False
DIKEY = 0 # 0->(dikey / x)
YATAY = 1 # 1->(yatay / y)
twothird = 1400
park_distance = np.inf
#*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-#
# helper funcs #
global_radius = None
@numba.jit(f32(f32, f32, f32), nopython=True, fastmath=True)
def ackermann(fi, L, t):
toa = math.tan(math.radians(fi))
radius = (L + (t/2 * toa)) / toa
return radius
@numba.jit(f32(f32, f32, f32, f32, f32), nopython=True, fastmath=True, cache=True)
def mapper(value, in_min, in_max, out_min, out_max):
return (value - in_min) * (out_max - out_min) / (in_max - in_min) + out_min
@numba.jit(f32(f32, f32), nopython=True, fastmath=True, cache=True)
def potingen_straße(desired, difference):
return (desired + 0.5 + difference) * 3600
@numba.jit(f32(f32, f32, f32, f32, f32, f32), nopython=True, fastmath=True, cache=True)
def fast_pid(p_error, Kp, i_error, Ki, d_error, Kd):
return (p_error * Kp) + (i_error * Ki) + (d_error * Kd)
@numba.jit(nopython=True, fastmath=True, cache=True)
def fast_pp(right_point_distance, left_point_distance, bicycle_length = BICYCLE_LENGTH):
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
hipotenus = math.sqrt(math.pow(right_point_distance,2) + math.pow(left_point_distance,2))
lookahead_distance = hipotenus / 2
theta = math.degrees(math.atan(right_point_distance / left_point_distance))
target_direction_angle = 90 - (2 * theta)
formula = (2 * bicycle_length * math.sin(math.radians(target_direction_angle))) / lookahead_distance
return math.degrees(math.atan(formula)) / 180
@numba.jit(nopython=True, fastmath=True, cache=True)
def fast_pp2(right_point_distance, left_point_distance, bicycle_length = BICYCLE_LENGTH):
hipotenus = math.sqrt(math.pow(right_point_distance,2) + math.pow(left_point_distance,2))
lookahead_distance = hipotenus / 2
theta = math.degrees(math.atan(right_point_distance / left_point_distance))
target_direction_angle = 90 - (2 * theta)
formula = (2 * bicycle_length * math.sin(math.radians(target_direction_angle))) / lookahead_distance
return math.degrees(math.atan(formula)) / 180
def control_mahmut(data):
# speed
if (data.adc0 > 1000):
data.adc0 = 1000
elif (data.adc0 < 0):
data.adc0 = 0
# steer
if (data.adc1 > 3600):
data.adc1 = 3600
elif (data.adc1 < 0):
data.adc1 = 0
#*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*-*#
class Steering_Algorithms:
class PID(object):
def __init__(self, kp, ki, kd):
self.Kp = kp
self.Ki = ki
self.Kd = kd
self.p_error = 0.0
self.d_error = 0.0
self.i_error = 0.0
self.prev_cte = 0.0
self.pidError = 0.0
self.teta = 0.0
self.error = 0.0
def calculate(self, distance):
self.error = distance - self.teta
self.p_error = self.error
self.i_error += self.error
self.d_error = self.error - self.prev_cte
self.prev_cte = self.error
if distance < 0.15:
self.i_error = 0
self.pidError = fast_pid(self.p_error, self.Kp, self.i_error, self.Ki, self.d_error, self.Kd)
self.teta += self.pidError
if self.teta < -0.5:
self.teta = -0.5
elif self.teta > 0.5:
self.teta = 0.5
print("teta: {:.2f}".format(self.teta))
return self.teta
class Pure_Pursuit_Controller():
def __init__(self, bicycle_length, lookahead_distance, target_direction_angle):
self.bicycle_length = bicycle_length
self.lookahead_distance = lookahead_distance
self.target_direction_angle = target_direction_angle
self.steering = 0
def target_finder(self, laser):
right_point_distance = np.average(laser.ranges[1080:1260])
left_point_distance = np.average(laser.ranges[180:360])
print("distance")
print(right_point_distance)
print(left_point_distance)
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
hipotenus = math.sqrt(math.pow(right_point_distance,2) + math.pow(left_point_distance,2))
self.lookahead_distance = hipotenus / 2
theta = math.degrees(math.atan(right_point_distance / left_point_distance))
self.target_direction_angle = 90 - 2 * theta
self.steering_calculator()
def steering_calculator(self):
formula = ((2 * self.bicycle_length * math.sin(math.radians(self.target_direction_angle))) / self.lookahead_distance)
self.steering = (math.degrees(math.atan((formula))))
print("steering")
print(self.steering)
print(self.steering / 180)
if self.steering < -.5:
self.steering = -.5
elif self.steering > .5:
self.steering = .5
#####################################################################################################################
"""
@future
Requires positional knowledge
"""
class park_seko(object):
def __init__(self, ackermann_radius, label_offset, error_acceptance = 0.5):
self.__target = []
self.__margin = np.inf
self.__destiny = False
self.__current_pos = []
self.__label_offset = label_offset
self.__error_acceptance = error_acceptance
self.__ackermann_radius = ackermann_radius
def __eval__(self):
# offset x mi y mi kontrol et
#@ZED değiştirilecek!
ackermann_target_x = self.__target[0] - ACKERMAN_RADIUS - LABEL_OFFSET # @!!!
ackermann_target_y = self.__target[1] - ACKERMAN_RADIUS # @!!!
xd = math.pow(ackermann_target_x - self.__current_pos[0], 2)
yd = math.pow(ackermann_target_y - self.__current_pos[1], 2)
self.__margin = math.sqrt(xd + yd)
if self.__margin < self.__error_acceptance:
self.__destiny = True
"""
Deprecated
"""
class serhatos(object):
def __init__(self):
self.coefficents = []
self.steering_angle = 0
self.CP = list()
def find_curve(self, x, y, degree):
self.coefficents = np.polyfit(x, y, degree)
return self.coefficents
def find_all_point_on_the_curve(self,coef,park_y):
all_y = np.zeros(shape=(10,))
all_x = np.linspace(-3,park_y,10)
for a,x in enumerate(all_x):
tot = 0
for i,j in enumerate(reversed(coef)):
tot += (x **i) * j
all_y[a] = tot
for i, j in zip(all_x,all_y):
#self.CP.append(CurvePoint(i, j))
print(i, j)
def choose_closest_point(self, x, y):
min_error = np.inf
return_obj = None
for obj in self.CP:
if obj.visited: continue
error_x = obj.x - x
error_y = obj.y - y
error = math.pow(error_x, 2) + math.pow(error_y, 2)
if error < min_error:
return_obj = obj
min_error = error
return return_obj
def is_that_point(self,p1,p2_x,p2_y):
if not p1 or not p2_x: return
error_x = p1.x-p2_x
error_y = p1.y-p2_y
error = math.sqrt(pow(error_x, 2) + pow(error_y, 2))
if error<5:
return True
else:
return False
def point2pointAngle(self,p1,p2):
error_x = p1.x-p2[0]
error_y = p1.y-p2[1]
angle = math.degrees(math.atan(error_x/error_y))
return angle
def distance_calculator(self,p1,p2):
distance_x = p1[0]-p2[0]
distance_y = p1[1]-p2[1]
distance = ((distance_x)**2+(distance_y)**2)**1/2
return distance
#####################################################################################################################
düz_gitmek = True
mid_start = np.array([.0, .0, .0], dtype=np.float32)
# main function #
def lidar_data(veri_durak):
global YOLCU
global DURMAK
global speed
global regen
global steering_angle
global is_parking_mode
global is_durak_mode
global park_coordinate
global speed_odometry
global AUTONOMOUS_SPEED
global FULL_RIGHT
global brake_speed
global brake_motor_direction
global stage1
global left_tracking
global right_tracking
global mid_tracking
global driving_mode
global pürşit
global is_curve_parking
# PARK #
global zed_x
global zed_y
global zed_z
global park_distance
global durak_dik_start
global denk_coef
global closest_point
global recently_stopped
####################################
# YAPAY ZEKA DUNYAYI ELE GECIRECEK #
####################################
global arduino_odometry
global sol_laser
global sag_laser
global collecting_data
global brake
global brake_value
global roswtf
global orhandaldal
global recently_stopped_kirmizi
global mahmut_tuncer
global parking_sign_current_distance
global right_point_distance
global left_point_distance
global kirmizida_dur_lan
global karar_verici_yakın_zamanda_calisti
global ahaburasıdaboşmuşıheahıeah
global olceriz_sıkıntı_yog
global sol_array
global right_array
global hazreticounter
global güllük
global büllük
global mahmutapozisyonçeşitliliği
global igotthepose
global TWO_THIRD_PARKING
global REVERSE_PARKING
global stage1
global stage2
global stage3
global stage4
global experimental_park_stage_1
global experimental_park_stage_2
global yesil_gorundu
global kirmizi_distance
global mid_start # array
global düz_gitmek # bool
global girildim_counter
global girildim_bool
global karsiya_geciyorum
#sol_laser = np.array(veri_durak.ranges[0:369], dtype=np.float32)
#sag_laser = np.array(veri_durak.ranges[1079:1439], dtype=np.float32)
#sol_laser[sol_laser>25] = 25
#sag_laser[sag_laser>25] = 25
print("trackings:", left_tracking, mid_tracking, right_tracking)
if ahaburasıdaboşmuşıheahıeah:
pass
# TUNE ET
"""
while olceriz_sıkıntı_yog + 3 > time.time():
mahmut.adc0 = AUTONOMOUS_SPEED
mahmut.adc1 = 1800
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = driving_mode
"""
while olceriz_sıkıntı_yog + 4 > time.time():
print("ahaburası da bosmus yav")
zol = np.array(veri_durak.ranges[560:672])
zag = np.array(veri_durak.ranges[224:336])
solumsu = zol[zol > 2.78] = 2.78
sagimsi = zag[zag > 2.78] = 2.78
xd = fast_pp(average(sagimsi), average(solumsu))
mahmut.adc0 = AUTONOMOUS_SPEED
mahmut.adc1 = int(xd)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = driving_mode
time.sleep(1/20)
arduino.publish(mahmut)
ahaburasıdaboşmuşıheahıeah = False
"""
if roswtf:
mahmut.adc0 = 0
mahmut.adc2 = 11000
arduino.publish(mahmut)
print(bcolors.WARNING+"Hoş geldiğiz!"+bcolors.ENDC)
start = time.time()
while time.time() - start < 10:
arduino.publish(mahmut)
mahmut.adc0 = AUTONOMOUS_SPEED_RECOVERY
mahmut.adc2 = 0
roswtf = False
orhandaldal = time.time()
print(bcolors.WARNING+"BBBBBB!"+bcolors.ENDC)
"""
if orhandaldal + 15 < time.time():
recently_stopped = False
#if roswtf and abs(math.sqrt(math.pow(durak_dik_start[0] - zed_x, 2) + math.pow(durak_dik_start[1] - zed_z, 2))) > 4:
if roswtf:
print(bcolors.WARNING+"DURAK START"+bcolors.ENDC)
start = time.time()
if not igotthepose:
mahmutapozisyonçeşitliliği[0] = zed_x
mahmutapozisyonçeşitliliği[1] = zed_y
mahmutapozisyonçeşitliliği[2] = zed_z
igotthepose = True
print("duraktan beri gittiğim yol: ", math.sqrt(math.pow(mahmutapozisyonçeşitliliği[0] - zed_x, 2) + math.pow(mahmutapozisyonçeşitliliği[2] - zed_z, 2)))
# pose difference
if math.sqrt(math.pow(mahmutapozisyonçeşitliliği[0] - zed_x, 2) + math.pow(mahmutapozisyonçeşitliliği[2] - zed_z, 2)) > 3.5:
while time.time() < start + YOLCU:
mahmut.adc0 = 0
mahmut.adc1 = 1800
mahmut.adc2 = 11000
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = driving_mode
arduino.publish(mahmut)
qoıwheqdw = round(time.time() - start, 2)
print(bcolors.WARNING + f"{qoıwheqdw} saniyedir DURAKTAYIZZZZ" + bcolors.ENDC)
time.sleep(1/20)
orhandaldal = time.time()
roswtf = False
igotthepose = False
left_tracking = True
right_tracking = False
mid_tracking = False
print(bcolors.WARNING+"DURAK FINISH!"+bcolors.ENDC)
if collecting_data:
writer.writerow([sol_laser, sag_laser, arduino_odometry['steering_angle']])
print(bcolors.WARNING + "COLLECTING DATA" + bcolors.ENDC)
#######
# END #
#######
""" sol_x = np.array(veri_durak.ranges[300:360])
sol_y = np.array(veri_durak.ranges[240:300])
sol_z = np.array(veri_durak.ranges[180:240])
sag_x = np.array(veri_durak.ranges[1080:1140])
sag_y = np.array(veri_durak.ranges[1140:1200])
sag_z = np.array(veri_durak.ranges[1200:1260]) """
on_array = np.array(veri_durak.ranges[440:456])
sol_array = np.array(veri_durak.ranges[560:672])
right_array = np.array(veri_durak.ranges[224:336])
sol_array[sol_array > 5] = 5
right_array[right_array > 5] = 5
distances = {
'right': np.average(right_array),
'left': np.average(sol_array),
'on' : np.average(on_array)
}
print(bcolors.WARNING + "ON MESAFE: " + bcolors.ENDC, distances['on'])
print(bcolors.WARNING + "park distance:" + bcolors.ENDC, park_distance)
print(bcolors.WARNING + "park coord: " + bcolors.ENDC, park_coordinate)
print("GIRILMEZ COUNTER", girildim_counter)
if TERMINATOR:
if AUTONOMOUS:
print(bcolors.WARNING + "AUTONOMOUS" + bcolors.ENDC)
driving_mode = RPM_MODE
if kirmizida_dur_lan:
print(bcolors.WARNING + "KIRMIZIYA GELDİM SANKİ" + bcolors.ENDC)
mahmut.adc0 = AUTONOMOUS_SPEED
mahmut.adc1 = int(1800)
mahmut.adc2 = 11000
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = driving_mode
elif mid_tracking == True:
if düz_gitmek:
mid_start[0] = zed_x
mid_start[1] = zed_y
mid_start[2] = zed_z
düz_gitmek = False
print(bcolors.FAIL + "MID_TRACKING" + bcolors.ENDC)
#
# CHECK THE DIRECTION
#pürşit.target_finder(laser=veri_durak)
mid_sol_array = np.array(veri_durak.ranges[399:435])
mid_sag_array = np.array(veri_durak.ranges[462:498])
right_point_distance = np.average(mid_sol_array)
left_point_distance = np.average(mid_sag_array)
if(right_point_distance > 25):
right_point_distance = 25
if(left_point_distance > 25):
left_point_distance = 25
print("right point distance", right_point_distance)
print("left point distance", left_point_distance)
steering = fast_pp2(right_point_distance, left_point_distance)
print("steering:", steering)
#pid method
#steering = pid_controller.calculate(distances['left'] - distances['right'])
if steering < -.5:
steering = -.5
elif steering > .5:
steering = .5
angle = potingen_straße(steering, POT_CENTER-1800)
print("aci:", angle)
print("desired direction angle:", angle)
# doldur
mahmut.adc0 = int(AUTONOMOUS_SPEED)
mahmut.adc1 = int(angle)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(RPM_MODE)
right_point_distance = np.average(right_array)
left_point_distance = np.average(sol_array)
anlık_fark = math.sqrt(math.pow(mid_start[0] - zed_x, 2) + math.pow(mid_start[2] - zed_z, 2))
print("ANLIKKKKK FARKKKK:::::", anlık_fark)
print("GIRLDIM BOOl", girildim_bool)
if right_point_distance < 3.0 and anlık_fark > 7:
left_tracking = True
mid_tracking = False
right_tracking = False
düz_gitmek = True
print(bcolors.FAIL + "ARANIYORUM HER YERDE KIRMIZI BULTENLE" + bcolors.ENDC)
girildim_bool = True
girildim_counter += 1
karsiya_geciyorum = False
elif left_point_distance < 3.0 and anlık_fark > 7:
left_tracking = True
mid_tracking = False
right_tracking = False
düz_gitmek = True
print(bcolors.FAIL + "ARANIYORUM HER YERDE KIRMIZI BULTENLE" + bcolors.ENDC)
girildim_bool = True
girildim_counter += 1
karsiya_geciyorum = False
elif left_tracking == DORU:
print(bcolors.FAIL + "LEFT_TRACKING" + bcolors.ENDC) #
# CHECK THE DIRECTION
#
right_point_distance = np.average(right_array)
left_point_distance = np.average(sol_array)
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
steering = fast_pp(SAG_FIXED, left_point_distance)
#pid method
#steering = pid_controller.calculate(distances['left'] - distances['right'])
if steering < -.5:
steering = -.5
elif steering > .5:
steering = .5
angle = potingen_straße(steering, POT_CENTER-1800)
# doldur
mahmut.adc0 = int(AUTONOMOUS_SPEED)
mahmut.adc1 = int(angle)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
elif right_tracking == DORU:
print(bcolors.FAIL + "RIGHT_TRACKING" + bcolors.ENDC)
right_point_distance = np.average(right_array)
left_point_distance = np.average(sol_array)
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
steering = fast_pp(right_point_distance, SOL_FIXED)
#pid method
#steering = pid_controller.calculate(distances['left'] - distances['right'])
if steering < -.5:
steering = -.5
elif steering > .5:
steering = .5
angle = potingen_straße(steering, POT_CENTER-1800)
# doldur
mahmut.adc0 = int(AUTONOMOUS_SPEED)
mahmut.adc1 = int(angle)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
# <Parking Autonomous>
elif is_parking_mode: #elif is_parking_mode:
print(bcolors.WARNING + 10 * '-' + "PARKING MODE \n" + 10 * '-' + bcolors.ENDC)
# full sag, ortalanınca middle takip park modu
if 0:
if park_distance > 10 and not experimental_park_stage_1:
right_point_distance = np.average(right_array)
left_point_distance = np.average(sol_array)
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
# !!!!!!!! 1.5 !!!!!!!!!!
steering = fast_pp(1.5 , left_point_distance)
if steering < -.5:
steering = -.5
elif steering > .5:
steering = .5
angle = potingen_straße(steering, POT_CENTER-1800)
if park_coordinate > 1600:
experimental_park_stage_1 = True
mahmut.adc0 = int(0)
mahmut.adc1 = int(angle)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
elif experimental_park_stage_1 and not experimental_park_stage_2:
mahmut.adc0 = int(AUTONOMOUS_SPEED)
mahmut.adc1 = int(FULL_RIGHT) # ölümüne sağ
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
if abs(850 - park_coordinate) < 100:
experimental_park_stage_2 = True
else:
print("EXPERiMENTAL PARKiNG LasT StaGE")
target_diff = (850 - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
mahmut.adc0 = int(AUTONOMOUS_SPEED)
mahmut.adc1 = int(steer) # face your destiny mahmut
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
if distances['on'] < 1.5:
while True:
mahmut.adc0 = DURMAK
mahmut.adc1 = 1800
mahmut.adc2 = 11000
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
arduino.publish(mahmut)
print("DURDUM \m/!")
time.sleep(1/20)
# raw two third mode
elif 0:
if distances['on'] > 7.5:
print("TWO THIRD PARK")
target_diff = (twothird - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
else:
print("MIDDLE PARk")
target_diff = (850 - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
if distances['on'] < 1.5:
while True:
mahmut.adc0 = DURMAK
mahmut.adc1 = 1800
mahmut.adc2 = 11000
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
arduino.publish(mahmut)
print("DURDUM \m/!")
time.sleep(1/20)
mahmut.adc0 = AUTONOMOUS_SPEED
mahmut.adc1 = int(steer)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
# first left track, düzgün park distance sonrası two_third/mid tracking
elif 1:
#stagei buradan kaldır ya da adını degistir xd
if stage1:
print(bcolors.FAIL+"ONEMLİ BURAYA GİRİYOR MU 1, sollu"+bcolors.ENDC)
right_point_distance = np.average(right_array)
left_point_distance = np.average(sol_array)
if(right_point_distance > 5):
right_point_distance = 5
if(left_point_distance > 5):
left_point_distance = 5
parksagdistance = 1.55
steering = fast_pp(parksagdistance, left_point_distance)
if steering < -.5:
steering = -.5
elif steering > .5:
steering = .5
angle = potingen_straße(steering, POT_CENTER-1800)
if park_coordinate > 1500:
stage1 = False
# doldur
mahmut.adc0 = int(37)
mahmut.adc1 = int(angle)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
else:
print("stage1 in else kısmı")
if park_distance > 6.1 and yavizseko: #yaviz
print("TWO THIRD PARK")
target_diff = (twothird - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
else:
print("MIDDLE PARk")
target_diff = (850 - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
mahmut.adc0 = int(37)
mahmut.adc1 = int(steer)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
if distances['on'] < 2.5:
mahmut.adc0 = DURMAK
mahmut.adc1 = 1900
mahmut.adc2 = 11000
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
print(bcolors.FAIL+"DURMAK \m/!"+bcolors.ENDC)
elif distances['on'] < 3.1:
mahmut.adc0 = int(37)
mahmut.adc1 = 2000
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
print(bcolors.FAIL+"YAVASLAMAK \m/!"+bcolors.ENDC)
# two third, mid, geri 2x, geri x, düz
elif 0:
if stage1:
if park_distance > 8:
print("TWO THIRD PARK")
target_diff = (twothird - park_coordinate) / 1700
steer = (target_diff + 0.5) * 3600
mahmut.adc0 = 25
mahmut.adc1 = int(steer)
mahmut.adc2 = 0
mahmut.adc3 = FORWARD
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
if distances['on'] < 3.5:
stage1 = False
stage2 = True
elif stage2:
mahmut.adc0 = 25
mahmut.adc1 = FULL_LEFT
mahmut.adc2 = 0
mahmut.adc3 = REVERSE
mahmut.adc4 = True
mahmut.adc5 = int(driving_mode)
if distances['on'] < 6.0:
stage2 = False
stage3 = True
elif stage3: