Exemplo n.º 1
0
 def draw_arm(self, arm, color='black'):
     p1 = Point2().polar(arm.l1, arm.t1)
     p2 = Point2().polar(arm.l2, arm.t2+arm.t1) + p1
     self.ez.line(Point2(), p1, color=color)
     self.ez.point(p1)
     self.ez.line(p1, p2, color=color)
     self.ez.point(p2)
Exemplo n.º 2
0
    def reset(self):
        mse = self.mse()
        print self.traj_step, mse

        if self.loop == TEST_NETWORK:
            self.net_logger.add_data(self.traj_step, mse)
        elif self.loop == JACOBIAN:
            self.jacobian_logger.add_data(self.traj_step, mse)


        self.traj_step += TRAJ_STEP_INC
        if self.traj_step > TRAJ_STEP_MAX:
            self.exit()

        self.trajectory = Trajectory(
            step_length=self.traj_step,
            restart=self.reset)
        self.errors = []
        self.arm = Arm()

        if self.loop == JACOBIAN:
            self.jacobian.arm = self.arm
            # temporary
            self.plot_errors.append(
                Point2(self.traj_step * 10, mse*1000)
            )
        elif self.loop == TEST_NETWORK:
            self.net.arm = self.arm
Exemplo n.º 3
0
    def spawnBall(self):
        pos = Point2(random.randint(10, SCREEN_WIDTH - 10),
                     random.randint(10, SCREEN_HEIGHT - 10))

        if (pos - DROPZONE_CENTER).r < DROPZONE_RADIUS:
            self.spawnBall()
        else:
            self.balls.append(Ball(pos))
Exemplo n.º 4
0
    def draw_info(self):
        # tamanho do passo atual
        val = self.traj_step
        val_text = "Step size.....{0}".format(val)
        self.ez.text(val_text, Point2(10,10), onScreen=True)
        # passo atual
        val = self.trajectory.curr_idx()
        val_text = "Current step..{0}".format(val)
        self.ez.text(val_text, Point2(10,20), onScreen=True)
        # erro medio
        val = self.mse()
        val_text = "Avg. error....{0}".format(val)
        self.ez.text(val_text, Point2(10,30), onScreen=True)

        if self.loop == JACOBIAN:
            # temporary
            if len(self.plot_errors) > 2:
                self.ez.lines(self.plot_errors,color='blue')
Exemplo n.º 5
0
    def drawRobot(self):
        pygame.draw.circle(screen, self.color, self.pos.rect(asInt=True),
                           ROBOT_RADIUS)
        end_point = Point2()
        end_point.r = ROBOT_RADIUS
        end_point.a = self.orientation
        end_point += self.pos

        pygame.draw.line(screen, RED, self.pos.rect(asInt=True),
                         end_point.rect(asInt=True), 2)
Exemplo n.º 6
0
    def __init__(self,
                 color=STRANGE_BLUE,
                 x=SCREEN_WIDTH / 2,
                 y=SCREEN_HEIGHT / 2):
        self.color = color
        self.pos = Point2(x, y)

        self.orientation = 0.0

        self.picked_balls = []
Exemplo n.º 7
0
    def __init__(self, name, color, x=SCREEN_WIDTH / 2, y=SCREEN_HEIGHT / 2):
        self.color = color
        self.name = name
        self.score = 0  # how many balls this robot dropped correctly
        self.pos = Point2(x, y)

        self.orientation = 0.0

        self.picked_balls = []
        self.picking = False
        self.dropping = False
Exemplo n.º 8
0
    def spawnBall(self):
        pos = Point2(random.randint(10, SCREEN_WIDTH - 10),
                     random.randint(10, SCREEN_HEIGHT - 10))

        # creates a ball in front of the initial position of the robot
        # for debugging
        # pos = Point2(SCREEN_WIDTH/2 + DROPZONE_RADIUS*2, SCREEN_HEIGHT/2)

        if (pos - DROPZONE_CENTER).r < DROPZONE_RADIUS + 30:
            self.spawnBall()
        else:
            self.balls.append(Ball(pos))
Exemplo n.º 9
0
    def drawRobot(self):
        pygame.draw.circle(screen, self.color, self.pos.rect(asInt=True),
                           ROBOT_RADIUS)
        end_point = Point2()
        end_point.r = ROBOT_RADIUS
        end_point.a = self.orientation
        end_point += self.pos

        pygame.draw.line(screen, RED, self.pos.rect(asInt=True),
                         end_point.rect(asInt=True), 2)

        name_surface = name_font.render(self.name, True, WHITE)
        name_width = name_surface.get_width()
        pos = (self.pos.rect(asInt=True)[0] - name_width / 2,
               self.pos.rect(asInt=True)[1] - ROBOT_RADIUS - 15)
        screen.blit(name_surface, pos)
Exemplo n.º 10
0
    def generate_samples_loop(self):
        sample = self.generate_sample()
        vector = Point2(sample[2], sample[3])
        if vector.r > MIN_STEP and vector.r < MAX_STEP:
            norm_sample = self.normalize_sample(sample)
            self.dataset_writer.writerow(norm_sample)
            self.sample_counter += 1
        else:
            self.invalid_counter += 1

        if self.sample_counter % 10000 == 0:
            print "{} samples generated in this loop.".format(self.sample_counter)
            avg = self.sample_counter/float((self.sample_counter + self.invalid_counter))
            print "{}% valid".format(avg*100.)

        if self.sample_counter >= 2000000:
            self.exit()
Exemplo n.º 11
0
    def __init__(self, width=100, height=100):
        self.width = width
        self.height = height
        self.size = (self.width, self.height)
        # self.origin = Point2(self.width/2, self.height/2)
        self.origin = Point2(300, self.height - 150)

        self.screen = None

        self.backgroundColor = '#FFFFFF'
        self.axisColor = '#D0D0D0'
        self.textColor = '#666666'

        self.loopFunction = None
        self.keepRunning = True

        self.clock = pygame.time.Clock()
        self.fps = 60

        self.keys = {K_ESCAPE: self.setQuit}

        self.gui = True
Exemplo n.º 12
0
 def setSize(self, w, h):
     self.width = w
     self.height = h
     self.size = (self.width, self.height)
     self.origin = Point2(self.width / 2, self.height / 2)
Exemplo n.º 13
0
                    dt1_y[i] += 1
                    break
        # check dt2
        if DT2_DISTRIBUTION:
            for i, interval in enumerate(dt2_x):
                y = scale(0., 1., np.radians(-MAX_DELTA),
                          np.radians(MAX_DELTA), float(row[5]))
                if y < interval:
                    dt2_y[i] += 1
                    break
        # check step
        if STEP_DISTRIBUTION:
            for i, interval in enumerate(step_x):
                dx = scale(0., 1., -MAX_STEP, MAX_STEP, float(row[2]))
                dy = scale(0., 1., -MAX_STEP, MAX_STEP, float(row[3]))
                p = Point2(dx, dy)
                y = p.r
                if y < interval:
                    step_y[i] += 1
                    break
        samples_checked += 1
        if samples_checked % 10000 == 0:
            print "Samples checked: {}/{}".format(samples_checked, row_count)
        # if samples_checked > 50000:
        #     break

if T1_DISTRIBUTION:
    print t1_y
    plt.figure(figsize=figsize)
    plt.plot(t1_x, t1_y)
    plt.legend([r'$\theta 1$'])
Exemplo n.º 14
0
 def generate(self):
     p = Point2(self.radius, 0)
     angle_step = 2*np.arcsin(self.step_length/(2.*self.radius))
     while len(self.points) < self.points_count:
         self.points.append(Point2(self.center+p))
         p.a += angle_step
Exemplo n.º 15
0
SCREEN_WIDTH = 800
SCREEN_HEIGHT = 600
BALL_RADIUS = 5
ROBOT_RADIUS = 30

# colors
BACKGROUND = (30, 30, 30)
DROPZONE_COLOR = (244, 144, 30)
STRANGE_BLUE = (0, 72, 82)
RED = (255, 0, 0)
GREEN = (0, 255, 0)

# simulation parameters
MAX_CARRY_BALLS = 3  # amount of balls a robot can carry
MAX_BALLS = 100  # max spawned balls
DROPZONE_CENTER = Point2((SCREEN_WIDTH / 2, SCREEN_HEIGHT / 2))
DROPZONE_RADIUS = 100
MOVE_STEP = 2
TURN_STEP = 0.02  # increment in radians to robot orientation

#CRTuple = namedtuple("Robot", "controller robot")

pygame.init()
screen = pygame.display.set_mode((SCREEN_WIDTH, SCREEN_HEIGHT))
clock = pygame.time.Clock()


class Ball(object):
    def __init__(self, pos):
        self.pos = pos
        self.owner = None
Exemplo n.º 16
0
 def transform(self, p):
     # transforms world coordinates to screen coordinates
     return Point2(p.x + self.origin.x, self.origin.y - p.y)
Exemplo n.º 17
0
from point2 import Point2
import numpy as np

TRAJ_CENTER = Point2(200, 300)

class Trajectory:
    def __init__(self, step_length=0.1, radius=100, points_count=1000, center=TRAJ_CENTER, restart=None):
        self.points  = []
        self.counter = 0
        self.center  = center
        self.radius  = radius
        self.step_length  = step_length
        self.points_count = points_count
        self.restart_function = restart

        self.generate()

    def generate(self):
        p = Point2(self.radius, 0)
        angle_step = 2*np.arcsin(self.step_length/(2.*self.radius))
        while len(self.points) < self.points_count:
            self.points.append(Point2(self.center+p))
            p.a += angle_step

    def current(self):
        return self.points[self.counter]

    def curr_idx(self):
        return self.counter

    def next(self):
Exemplo n.º 18
0
 def move(self):
     goal_position = Point2()
     goal_position.r = MOVE_STEP
     goal_position.a = self.orientation
     self.pos += goal_position
Exemplo n.º 19
0
 def endeffector(self):
     p1 = Point2().polar(self.l1, self.t1)
     return Point2().polar(self.l2, self.t2+self.t1) + p1