mayonesa/resampling_wheel_particle_filter.py

## resampling_wheel_particle_filter.py
# In this exercise, you should implement the
# resampler shown in the previous video.

from math import *
import random

landmarks  = [[20.0, 20.0], [80.0, 80.0], [20.0, 80.0], [80.0, 20.0]]
world_size = 100.0

class robot:
    def __init__(self):
        self.x = random.random() * world_size
        self.y = random.random() * world_size
        self.orientation = random.random() * 2.0 * pi
        self.forward_noise = 0.0;
        self.turn_noise    = 0.0;
        self.sense_noise   = 0.0;

    def set(self, new_x, new_y, new_orientation):
        if new_x < 0 or new_x >= world_size:
            raise ValueError, 'X coordinate out of bound'
        if new_y < 0 or new_y >= world_size:
            raise ValueError, 'Y coordinate out of bound'
        if new_orientation < 0 or new_orientation >= 2 * pi:
            raise ValueError, 'Orientation must be in [0..2pi]'
        self.x = float(new_x)
        self.y = float(new_y)
        self.orientation = float(new_orientation)


    def set_noise(self, new_f_noise, new_t_noise, new_s_noise):
        # makes it possible to change the noise parameters
        # this is often useful in particle filters
        self.forward_noise = float(new_f_noise);
        self.turn_noise    = float(new_t_noise);
        self.sense_noise   = float(new_s_noise);


    def sense(self):
        Z = []
        for i in range(len(landmarks)):
            dist = sqrt((self.x - landmarks[i][0]) ** 2 + (self.y - landmarks[i][1]) ** 2)
            dist += random.gauss(0.0, self.sense_noise)
            Z.append(dist)
        return Z


    def move(self, turn, forward):
        if forward < 0:
            raise ValueError, 'Robot cant move backwards'

        # turn, and add randomness to the turning command
        orientation = self.orientation + float(turn) + random.gauss(0.0, self.turn_noise)
        orientation %= 2 * pi

        # move, and add randomness to the motion command
        dist = float(forward) + random.gauss(0.0, self.forward_noise)
        x = self.x + (cos(orientation) * dist)
        y = self.y + (sin(orientation) * dist)
        x %= world_size    # cyclic truncate
        y %= world_size

        # set particle
        res = robot()
        res.set(x, y, orientation)
        res.set_noise(self.forward_noise, self.turn_noise, self.sense_noise)
        return res

    def Gaussian(self, mu, sigma, x):

        # calculates the probability of x for 1-dim Gaussian with mean mu and var. sigma
        return exp(- ((mu - x) ** 2) / (sigma ** 2) / 2.0) / sqrt(2.0 * pi * (sigma ** 2))


    def measurement_prob(self, measurement):

        # calculates how likely a measurement should be

        prob = 1.0;
        for i in range(len(landmarks)):
            dist = sqrt((self.x - landmarks[i][0]) ** 2 + (self.y - landmarks[i][1]) ** 2)
            prob *= self.Gaussian(dist, self.sense_noise, measurement[i])
        return prob

    def __repr__(self):
        return '[x=%.6s y=%.6s orient=%.6s]' % (str(self.x), str(self.y), str(self.orientation))


#myrobot = robot()
#myrobot.set_noise(5.0, 0.1, 5.0)
#myrobot.set(30.0, 50.0, pi/2)
#myrobot = myrobot.move(-pi/2, 15.0)
#print myrobot.sense()
#myrobot = myrobot.move(-pi/2, 10.0)
#print myrobot.sense()

####   DON'T MODIFY ANYTHING ABOVE HERE! ENTER CODE BELOW ####
myrobot = robot()
myrobot = myrobot.move(0.1, 5.0)
Z = myrobot.sense()

N = 1000
p = []
for i in range(N):
    x = robot()
    x.set_noise(0.05, 0.05, 5.0)
    p.append(x)

p2 = []
for i in range(N):
    p2.append(p[i].move(0.1, 5.0))
p = p2

ws = []
for i in range(N):
    ws.append(p[i].measurement_prob(Z))

def new_part(i, b):
    w_i = ws[i]
    return new_part((i + 1) % N, b - w_i) if w_i < b else (p[i], i, b)

def accumulate(ps, i, b):
    part_i = new_part(i, b + random.uniform(0, b_incr_max))
    return (ps + part_i[0:1]), part_i[1], part_i[2]

b_incr_max = 2 * max(ws)
print reduce(lambda (ps, i, b), _: accumulate(ps, i, b),
             range(N),
             ((), random.randrange(N), 0))[0]
	# In this exercise, you should implement the
	# resampler shown in the previous video.

	from math import *
	import random

	landmarks = [[20.0, 20.0], [80.0, 80.0], [20.0, 80.0], [80.0, 20.0]]
	world_size = 100.0

	class robot:
	def __init__(self):
	self.x = random.random() * world_size
	self.y = random.random() * world_size
	self.orientation = random.random() * 2.0 * pi
	self.forward_noise = 0.0;
	self.turn_noise = 0.0;
	self.sense_noise = 0.0;

	def set(self, new_x, new_y, new_orientation):
	if new_x < 0 or new_x >= world_size:
	raise ValueError, 'X coordinate out of bound'
	if new_y < 0 or new_y >= world_size:
	raise ValueError, 'Y coordinate out of bound'
	if new_orientation < 0 or new_orientation >= 2 * pi:
	raise ValueError, 'Orientation must be in [0..2pi]'
	self.x = float(new_x)
	self.y = float(new_y)
	self.orientation = float(new_orientation)


	def set_noise(self, new_f_noise, new_t_noise, new_s_noise):
	# makes it possible to change the noise parameters
	# this is often useful in particle filters
	self.forward_noise = float(new_f_noise);
	self.turn_noise = float(new_t_noise);
	self.sense_noise = float(new_s_noise);


	def sense(self):
	Z = []
	for i in range(len(landmarks)):
	dist = sqrt((self.x - landmarks[i][0]) 2 + (self.y - landmarks[i][1]) 2)
	dist += random.gauss(0.0, self.sense_noise)
	Z.append(dist)
	return Z


	def move(self, turn, forward):
	if forward < 0:
	raise ValueError, 'Robot cant move backwards'

	# turn, and add randomness to the turning command
	orientation = self.orientation + float(turn) + random.gauss(0.0, self.turn_noise)
	orientation %= 2 * pi

	# move, and add randomness to the motion command
	dist = float(forward) + random.gauss(0.0, self.forward_noise)
	x = self.x + (cos(orientation) * dist)
	y = self.y + (sin(orientation) * dist)
	x %= world_size # cyclic truncate
	y %= world_size

	# set particle
	res = robot()
	res.set(x, y, orientation)
	res.set_noise(self.forward_noise, self.turn_noise, self.sense_noise)
	return res

	def Gaussian(self, mu, sigma, x):

	# calculates the probability of x for 1-dim Gaussian with mean mu and var. sigma
	return exp(- ((mu - x) 2) / (sigma 2) / 2.0) / sqrt(2.0 * pi * (sigma ** 2))


	def measurement_prob(self, measurement):

	# calculates how likely a measurement should be

	prob = 1.0;
	for i in range(len(landmarks)):
	dist = sqrt((self.x - landmarks[i][0]) 2 + (self.y - landmarks[i][1]) 2)
	prob *= self.Gaussian(dist, self.sense_noise, measurement[i])
	return prob

	def __repr__(self):
	return '[x=%.6s y=%.6s orient=%.6s]' % (str(self.x), str(self.y), str(self.orientation))


	#myrobot = robot()
	#myrobot.set_noise(5.0, 0.1, 5.0)
	#myrobot.set(30.0, 50.0, pi/2)
	#myrobot = myrobot.move(-pi/2, 15.0)
	#print myrobot.sense()
	#myrobot = myrobot.move(-pi/2, 10.0)
	#print myrobot.sense()

	#### DON'T MODIFY ANYTHING ABOVE HERE! ENTER CODE BELOW ####
	myrobot = robot()
	myrobot = myrobot.move(0.1, 5.0)
	Z = myrobot.sense()

	N = 1000
	p = []
	for i in range(N):
	x = robot()
	x.set_noise(0.05, 0.05, 5.0)
	p.append(x)

	p2 = []
	for i in range(N):
	p2.append(p[i].move(0.1, 5.0))
	p = p2

	ws = []
	for i in range(N):
	ws.append(p[i].measurement_prob(Z))

	def new_part(i, b):
	w_i = ws[i]
	return new_part((i + 1) % N, b - w_i) if w_i < b else (p[i], i, b)

	def accumulate(ps, i, b):
	part_i = new_part(i, b + random.uniform(0, b_incr_max))
	return (ps + part_i[0:1]), part_i[1], part_i[2]

	b_incr_max = 2 * max(ws)
	print reduce(lambda (ps, i, b), _: accumulate(ps, i, b),
	range(N),
	((), random.randrange(N), 0))[0]