Kalman-and-Bayesian-Filters.../experiments/slam.py

# -*- coding: utf-8 -*-
"""
Created on Mon Oct  3 07:59:40 2016

@author: rlabbe
"""

from filterpy.kalman import UnscentedKalmanFilter as UKF, MerweScaledSigmaPoints
from math import tan, sin, cos, sqrt, atan2
import numpy as np
from numpy.random import randn
import matplotlib.pyplot as plt
from filterpy.stats import plot_covariance_ellipse


def move(x, u, dt, wheelbase):
    hdg = x[2]
    vel = u[0]
    steering_angle = u[1]
    dist = vel * dt

    if abs(steering_angle) > 0.001: # is robot turning?
        beta = (dist / wheelbase) * tan(steering_angle)
        r = wheelbase / tan(steering_angle) # radius

        sinh, sinhb = sin(hdg), sin(hdg + beta)
        cosh, coshb = cos(hdg), cos(hdg + beta)
        return x + np.array([-r*sinh + r*sinhb,
                              r*cosh - r*coshb, beta])
    else: # moving in straight line
        return x + np.array([dist*cos(hdg), dist*sin(hdg), 0])


def fx(x, dt, u):
    return move(x, u, dt, wheelbase)


def normalize_angle(x):
    x = x % (2 * np.pi)    # force in range [0, 2 pi)
    if x > np.pi:          # move to [-pi, pi)
        x -= 2 * np.pi
    return x


def residual_h(a, b):
    y = a - b
    # data in format [dist_1, bearing_1, dist_2, bearing_2,...]
    for i in range(0, len(y), 2):
        y[i + 1] = normalize_angle(y[i + 1])
    return y


def residual_x(a, b):
    y = a - b
    y[2] = normalize_angle(y[2])
    return y


def aa(x, y):
    if y is not None:
        return x % y
    else:
        return x

def bb(x,y):
    try:
        return x % y
    except:
        return x


def Hx(x, landmarks):
    """ takes a state variable and returns the measurement
    that would correspond to that state. """
    hx = []
    for lmark in landmarks:
        px, py = lmark
        dist = sqrt((px - x[0])**2 + (py - x[1])**2)
        angle = atan2(py - x[1], px - x[0])
        hx.extend([dist, normalize_angle(angle - x[2])])
    return np.array(hx)


def state_mean(sigmas, Wm):
    x = np.zeros(3)

    sum_sin = np.sum(np.dot(np.sin(sigmas[:, 2]), Wm))
    sum_cos = np.sum(np.dot(np.cos(sigmas[:, 2]), Wm))
    x[0] = np.sum(np.dot(sigmas[:, 0], Wm))
    x[1] = np.sum(np.dot(sigmas[:, 1], Wm))
    x[2] = atan2(sum_sin, sum_cos)
    return x


def z_mean(sigmas, Wm):
    z_count = sigmas.shape[1]
    x = np.zeros(z_count)

    for z in range(0, z_count, 2):
        sum_sin = np.sum(np.dot(np.sin(sigmas[:, z+1]), Wm))
        sum_cos = np.sum(np.dot(np.cos(sigmas[:, z+1]), Wm))

        x[z] = np.sum(np.dot(sigmas[:,z], Wm))
        x[z+1] = atan2(sum_sin, sum_cos)
    return x


dt = 1.0
wheelbase = 0.5

def run_localization(
    cmds, landmarks, sigma_vel, sigma_steer, sigma_range,
    sigma_bearing, ellipse_step=1, step=10):

    plt.figure()
    points = MerweScaledSigmaPoints(n=3, alpha=.00001, beta=2, kappa=0,
                                    subtract=residual_x)
    ukf = UKF(dim_x=3, dim_z=2*len(landmarks), fx=fx, hx=Hx,
              dt=dt, points=points, x_mean_fn=state_mean,
              z_mean_fn=z_mean, residual_x=residual_x,
              residual_z=residual_h)

    ukf.x = np.array([2, 6, .3])
    ukf.P = np.diag([.1, .1, .05])
    ukf.R = np.diag([sigma_range**2,
                     sigma_bearing**2]*len(landmarks))
    ukf.Q = np.eye(3)*0.0001

    sim_pos = ukf.x.copy()

    # plot landmarks
    if len(landmarks) > 0:
        plt.scatter(landmarks[:, 0], landmarks[:, 1],
                    marker='s', s=60)

    track = []
    for i, u in enumerate(cmds):
        sim_pos = move(sim_pos, u, dt/step, wheelbase)
        track.append(sim_pos)

        if i % step == 0:
            ukf.predict(fx_args=u)

            if i % ellipse_step == 0:
                plot_covariance_ellipse(
                    (ukf.x[0], ukf.x[1]), ukf.P[0:2, 0:2], std=6,
                     facecolor='k', alpha=0.3)

            x, y = sim_pos[0], sim_pos[1]
            z = []
            for lmark in landmarks:
                dx, dy = lmark[0] - x, lmark[1] - y
                d = sqrt(dx**2 + dy**2) + randn()*sigma_range
                bearing = atan2(lmark[1] - y, lmark[0] - x)
                a = (normalize_angle(bearing - sim_pos[2] +
                     randn()*sigma_bearing))
                z.extend([d, a])
            ukf.update(z, hx_args=(landmarks,))

            if i % ellipse_step == 0:
                plot_covariance_ellipse(
                    (ukf.x[0], ukf.x[1]), ukf.P[0:2, 0:2], std=6,
                     facecolor='g', alpha=0.8)
    track = np.array(track)
    plt.plot(track[:, 0], track[:,1], color='k', lw=2)
    plt.axis('equal')
    plt.title("UKF Robot localization")
    plt.show()
    return ukf


landmarks = np.array([[5, 10], [10, 5], [15, 15]])
cmds = [np.array([1.1, .01])] * 200
ukf = run_localization(
    cmds, landmarks, sigma_vel=0.1, sigma_steer=np.radians(1),
    sigma_range=0.3, sigma_bearing=0.1)
print('Final P:', ukf.P.diagonal())
Wording changes. 2016-11-02 16:38:18 +01:00			`# -- coding: utf-8 --`
			`"""`
			`Created on Mon Oct 3 07:59:40 2016`

			`@author: rlabbe`
			`"""`

			`from filterpy.kalman import UnscentedKalmanFilter as UKF, MerweScaledSigmaPoints`
			`from math import tan, sin, cos, sqrt, atan2`
			`import numpy as np`
			`from numpy.random import randn`
			`import matplotlib.pyplot as plt`
			`from filterpy.stats import plot_covariance_ellipse`



			`def move(x, u, dt, wheelbase):`
			`hdg = x[2]`
			`vel = u[0]`
			`steering_angle = u[1]`
			`dist = vel * dt`

			`if abs(steering_angle) > 0.001: # is robot turning?`
			`beta = (dist / wheelbase) * tan(steering_angle)`
			`r = wheelbase / tan(steering_angle) # radius`

			`sinh, sinhb = sin(hdg), sin(hdg + beta)`
			`cosh, coshb = cos(hdg), cos(hdg + beta)`
			`return x + np.array([-rsinh + rsinhb,`
			`rcosh - rcoshb, beta])`
			`else: # moving in straight line`
			`return x + np.array([distcos(hdg), distsin(hdg), 0])`


			`def fx(x, dt, u):`
			`return move(x, u, dt, wheelbase)`


			`def normalize_angle(x):`
			`x = x % (2 * np.pi) # force in range [0, 2 pi)`
			`if x > np.pi: # move to [-pi, pi)`
			`x -= 2 * np.pi`
			`return x`


			`def residual_h(a, b):`
			`y = a - b`
			`# data in format [dist_1, bearing_1, dist_2, bearing_2,...]`
			`for i in range(0, len(y), 2):`
			`y[i + 1] = normalize_angle(y[i + 1])`
			`return y`


			`def residual_x(a, b):`
			`y = a - b`
			`y[2] = normalize_angle(y[2])`
			`return y`


			`def aa(x, y):`
			`if y is not None:`
			`return x % y`
			`else:`
			`return x`

			`def bb(x,y):`
			`try:`
			`return x % y`
			`except:`
			`return x`



			`def Hx(x, landmarks):`
			`""" takes a state variable and returns the measurement`
			`that would correspond to that state. """`
			`hx = []`
			`for lmark in landmarks:`
			`px, py = lmark`
			`dist = sqrt((px - x[0])2 + (py - x[1])2)`
			`angle = atan2(py - x[1], px - x[0])`
			`hx.extend([dist, normalize_angle(angle - x[2])])`
			`return np.array(hx)`


			`def state_mean(sigmas, Wm):`
			`x = np.zeros(3)`

			`sum_sin = np.sum(np.dot(np.sin(sigmas[:, 2]), Wm))`
			`sum_cos = np.sum(np.dot(np.cos(sigmas[:, 2]), Wm))`
			`x[0] = np.sum(np.dot(sigmas[:, 0], Wm))`
			`x[1] = np.sum(np.dot(sigmas[:, 1], Wm))`
			`x[2] = atan2(sum_sin, sum_cos)`
			`return x`


			`def z_mean(sigmas, Wm):`
			`z_count = sigmas.shape[1]`
			`x = np.zeros(z_count)`

			`for z in range(0, z_count, 2):`
			`sum_sin = np.sum(np.dot(np.sin(sigmas[:, z+1]), Wm))`
			`sum_cos = np.sum(np.dot(np.cos(sigmas[:, z+1]), Wm))`

			`x[z] = np.sum(np.dot(sigmas[:,z], Wm))`
			`x[z+1] = atan2(sum_sin, sum_cos)`
			`return x`


			`dt = 1.0`
			`wheelbase = 0.5`

			`def run_localization(`
			`cmds, landmarks, sigma_vel, sigma_steer, sigma_range,`
			`sigma_bearing, ellipse_step=1, step=10):`

			`plt.figure()`
			`points = MerweScaledSigmaPoints(n=3, alpha=.00001, beta=2, kappa=0,`
			`subtract=residual_x)`
			`ukf = UKF(dim_x=3, dim_z=2*len(landmarks), fx=fx, hx=Hx,`
			`dt=dt, points=points, x_mean_fn=state_mean,`
			`z_mean_fn=z_mean, residual_x=residual_x,`
			`residual_z=residual_h)`

			`ukf.x = np.array([2, 6, .3])`
			`ukf.P = np.diag([.1, .1, .05])`
			`ukf.R = np.diag([sigma_range**2,`
			`sigma_bearing*2]len(landmarks))`
			`ukf.Q = np.eye(3)*0.0001`

			`sim_pos = ukf.x.copy()`

			`# plot landmarks`
			`if len(landmarks) > 0:`
			`plt.scatter(landmarks[:, 0], landmarks[:, 1],`
			`marker='s', s=60)`

			`track = []`
			`for i, u in enumerate(cmds):`
			`sim_pos = move(sim_pos, u, dt/step, wheelbase)`
			`track.append(sim_pos)`

			`if i % step == 0:`
			`ukf.predict(fx_args=u)`

			`if i % ellipse_step == 0:`
			`plot_covariance_ellipse(`
			`(ukf.x[0], ukf.x[1]), ukf.P[0:2, 0:2], std=6,`
			`facecolor='k', alpha=0.3)`

			`x, y = sim_pos[0], sim_pos[1]`
			`z = []`
			`for lmark in landmarks:`
			`dx, dy = lmark[0] - x, lmark[1] - y`
			`d = sqrt(dx2 + dy2) + randn()*sigma_range`
			`bearing = atan2(lmark[1] - y, lmark[0] - x)`
			`a = (normalize_angle(bearing - sim_pos[2] +`
			`randn()*sigma_bearing))`
			`z.extend([d, a])`
			`ukf.update(z, hx_args=(landmarks,))`

			`if i % ellipse_step == 0:`
			`plot_covariance_ellipse(`
			`(ukf.x[0], ukf.x[1]), ukf.P[0:2, 0:2], std=6,`
			`facecolor='g', alpha=0.8)`
			`track = np.array(track)`
			`plt.plot(track[:, 0], track[:,1], color='k', lw=2)`
			`plt.axis('equal')`
			`plt.title("UKF Robot localization")`
			`plt.show()`
			`return ukf`


			`landmarks = np.array([[5, 10], [10, 5], [15, 15]])`
			`cmds = [np.array([1.1, .01])] * 200`
			`ukf = run_localization(`
			`cmds, landmarks, sigma_vel=0.1, sigma_steer=np.radians(1),`
			`sigma_range=0.3, sigma_bearing=0.1)`
			`print('Final P:', ukf.P.diagonal())`