333 lines
8.8 KiB
Python
333 lines
8.8 KiB
Python
# -*- coding: utf-8 -*-
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"""Copyright 2015 Roger R Labbe Jr.
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Code supporting the book
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Kalman and Bayesian Filters in Python
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https://github.com/rlabbe/Kalman-and-Bayesian-Filters-in-Python
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This is licensed under an MIT license. See the LICENSE.txt file
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for more information.
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"""
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from __future__ import (absolute_import, division, print_function,
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unicode_literals)
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import numpy as np
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from numpy.random import randn, random, uniform
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import scipy.stats
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class RobotLocalizationParticleFilter(object):
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def __init__(self, N, x_dim, y_dim, landmarks, measure_std_error):
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self.particles = np.empty((N, 3)) # x, y, heading
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self.N = N
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self.x_dim = x_dim
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self.y_dim = y_dim
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self.landmarks = landmarks
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self.R = measure_std_error
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# distribute particles randomly with uniform weight
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self.weights = np.empty(N)
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#self.weights.fill(1./N)
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'''self.particles[:, 0] = uniform(0, x_dim, size=N)
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self.particles[:, 1] = uniform(0, y_dim, size=N)
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self.particles[:, 2] = uniform(0, 2*np.pi, size=N)'''
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def create_uniform_particles(self, x_range, y_range, hdg_range):
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self.particles[:, 0] = uniform(x_range[0], x_range[1], size=N)
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self.particles[:, 1] = uniform(y_range[0], y_range[1], size=N)
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self.particles[:, 2] = uniform(hdg_range[0], hdg_range[1], size=N)
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self.particles[:, 2] %= 2 * np.pi
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def create_gaussian_particles(self, mean, var):
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self.particles[:, 0] = mean[0] + randn(self.N)*var[0]
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self.particles[:, 1] = mean[1] + randn(self.N)*var[1]
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self.particles[:, 2] = mean[2] + randn(self.N)*var[2]
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self.particles[:, 2] %= 2 * np.pi
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def predict(self, u, std, dt=1.):
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""" move according to control input u (heading change, velocity)
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with noise std"""
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self.particles[:, 2] += u[0] + randn(self.N) * std[0]
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self.particles[:, 2] %= 2 * np.pi
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d = u[1]*dt + randn(self.N) * std[1]
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self.particles[:, 0] += np.cos(self.particles[:, 2]) * d
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self.particles[:, 1] += np.sin(self.particles[:, 2]) * d
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def update(self, z):
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self.weights.fill(1.)
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for i, landmark in enumerate(self.landmarks):
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distance = np.linalg.norm(self.particles[:, 0:2] - landmark, axis=1)
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self.weights *= scipy.stats.norm(distance, self.R).pdf(z[i])
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#self.weights *= Gaussian(distance, self.R, z[i])
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self.weights += 1.e-300
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self.weights /= sum(self.weights) # normalize
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def neff(self):
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return 1. / np.sum(np.square(self.weights))
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def resample(self):
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cumulative_sum = np.cumsum(self.weights)
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cumulative_sum[-1] = 1. # avoid round-off error
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indexes = np.searchsorted(cumulative_sum, random(self.N))
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# resample according to indexes
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self.particles = self.particles[indexes]
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self.weights = self.weights[indexes]
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self.weights /= np.sum(self.weights) # normalize
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def resample_from_index(self, indexes):
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assert len(indexes) == self.N
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self.particles = self.particles[indexes]
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self.weights = self.weights[indexes]
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self.weights /= np.sum(self.weights)
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def estimate(self):
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""" returns mean and variance """
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pos = self.particles[:, 0:2]
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mu = np.average(pos, weights=self.weights, axis=0)
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var = np.average((pos - mu)**2, weights=self.weights, axis=0)
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return mu, var
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def mean(self):
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""" returns weighted mean position"""
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return np.average(self.particles[:, 0:2], weights=self.weights, axis=0)
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def residual_resample(w):
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N = len(w)
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w_ints = np.floor(N*w).astype(int)
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residual = w - w_ints
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residual /= sum(residual)
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indexes = np.zeros(N, 'i')
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k = 0
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for i in range(N):
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for j in range(w_ints[i]):
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indexes[k] = i
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k += 1
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cumsum = np.cumsum(residual)
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cumsum[N-1] = 1.
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for j in range(k, N):
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indexes[j] = np.searchsorted(cumsum, random())
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return indexes
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def residual_resample2(w):
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N = len(w)
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w_ints =np.floor(N*w).astype(int)
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R = np.sum(w_ints)
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m_rdn = N - R
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Ws = (N*w - w_ints)/ m_rdn
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indexes = np.zeros(N, 'i')
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i = 0
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for j in range(N):
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for k in range(w_ints[j]):
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indexes[i] = j
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i += 1
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cumsum = np.cumsum(Ws)
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cumsum[N-1] = 1 # just in case
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for j in range(i, N):
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indexes[j] = np.searchsorted(cumsum, random())
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return indexes
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def systemic_resample(w):
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N = len(w)
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Q = np.cumsum(w)
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indexes = np.zeros(N, 'int')
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t = np.linspace(0, 1-1/N, N) + random()/N
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i, j = 0, 0
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while i < N and j < N:
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while Q[j] < t[i]:
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j += 1
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indexes[i] = j
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i += 1
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return indexes
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def Gaussian(mu, sigma, x):
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# calculates the probability of x for 1-dim Gaussian with mean mu and var. sigma
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g = (np.exp(-((mu - x) ** 2) / (sigma ** 2) / 2.0) /
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np.sqrt(2.0 * np.pi * (sigma ** 2)))
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for i in range(len(g)):
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g[i] = max(g[i], 1.e-229)
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return g
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def test_pf():
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#seed(1234)
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N = 10000
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R = .2
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landmarks = [[-1, 2], [20,4], [10,30], [18,25]]
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#landmarks = [[-1, 2], [2,4]]
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pf = RobotLocalizationParticleFilter(N, 20, 20, landmarks, R)
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plot_pf(pf, 20, 20, weights=False)
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dt = .01
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plt.pause(dt)
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for x in range(18):
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zs = []
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pos=(x+3, x+3)
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for landmark in landmarks:
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d = np.sqrt((landmark[0]-pos[0])**2 + (landmark[1]-pos[1])**2)
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zs.append(d + randn()*R)
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pf.predict((0.01, 1.414), (.2, .05))
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pf.update(z=zs)
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pf.resample()
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#print(x, np.array(list(zip(pf.particles, pf.weights))))
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mu, var = pf.estimate()
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plot_pf(pf, 20, 20, weights=False)
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plt.plot(pos[0], pos[1], marker='*', color='r', ms=10)
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plt.scatter(mu[0], mu[1], color='g', s=100)
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plt.tight_layout()
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plt.pause(dt)
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def test_pf2():
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N = 1000
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sensor_std_err = .2
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landmarks = [[-1, 2], [20,4], [-20,6], [18,25]]
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pf = RobotLocalizationParticleFilter(N, 20, 20, landmarks, sensor_std_err)
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xs = []
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for x in range(18):
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zs = []
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pos=(x+1, x+1)
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for landmark in landmarks:
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d = np.sqrt((landmark[0]-pos[0])**2 + (landmark[1]-pos[1])**2)
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zs.append(d + randn()*sensor_std_err)
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# move diagonally forward to (x+1, x+1)
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pf.predict((0.00, 1.414), (.2, .05))
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pf.update(z=zs)
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pf.resample()
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mu, var = pf.estimate()
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xs.append(mu)
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xs = np.array(xs)
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plt.plot(xs[:, 0], xs[:, 1])
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plt.show()
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if __name__ == '__main__':
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DO_PLOT_PARTICLES = False
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from numpy.random import seed
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import matplotlib.pyplot as plt
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#plt.figure()
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seed(5)
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for count in range(10):
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print()
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print(count)
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#numpy.random.set_state(fail_state)
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#if count == 12:
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# #fail_state = numpy.random.get_state()
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# DO_PLOT_PARTICLES = True
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N = 4000
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sensor_std_err = .1
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landmarks = np.array([[-1, 2], [2,4], [10,6], [18,25]])
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NL = len(landmarks)
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#landmarks = [[-1, 2], [2,4]]
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pf = RobotLocalizationParticleFilter(N, 20, 20, landmarks, sensor_std_err)
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#pf.create_gaussian_particles([3, 2, 0], [5, 5, 2])
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pf.create_uniform_particles((0,20), (0,20), (0, 6.28))
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if DO_PLOT_PARTICLES:
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plt.scatter(pf.particles[:, 0], pf.particles[:, 1], alpha=.2, color='g')
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xs = []
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for x in range(18):
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zs = []
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pos=(x+1, x+1)
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for landmark in landmarks:
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d = np.sqrt((landmark[0]-pos[0])**2 + (landmark[1]-pos[1])**2)
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zs.append(d + randn()*sensor_std_err)
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zs = np.linalg.norm(landmarks - pos, axis=1) + randn(NL)*sensor_std_err
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# move diagonally forward to (x+1, x+1)
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pf.predict((0.00, 1.414), (.2, .05))
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pf.update(z=zs)
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if x == 0:
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print(max(pf.weights))
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#while abs(pf.neff() -N) < .1:
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# print('neffing')
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# pf.create_uniform_particles((0,20), (0,20), (0, 6.28))
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# pf.update(z=zs)
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#print(pf.neff())
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#indexes = residual_resample2(pf.weights)
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indexes = systemic_resample(pf.weights)
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pf.resample_from_index(indexes)
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#pf.resample()
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mu, var = pf.estimate()
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xs.append(mu)
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if DO_PLOT_PARTICLES:
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plt.scatter(pf.particles[:, 0], pf.particles[:, 1], alpha=.2)
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plt.scatter(pos[0], pos[1], marker='*', color='r')
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plt.scatter(mu[0], mu[1], marker='s', color='r')
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plt.pause(.01)
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xs = np.array(xs)
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plt.plot(xs[:, 0], xs[:, 1])
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plt.show()
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