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ParticleFilter.m
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ParticleFilter.m
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%ParticleFilter Particle filter class
%
% Monte-carlo based localisation for estimating vehicle pose based on
% odometry and observations of known landmarks.
%
% Methods::
% run run the particle filter
% plot_xy display estimated vehicle path
% plot_pdf display particle distribution
%
% Properties::
% robot reference to the robot object
% sensor reference to the sensor object
% history vector of structs that hold the detailed information from
% each time step
% nparticles number of particles used
% x particle states; nparticles x 3
% weight particle weights; nparticles x 1
% x_est mean of the particle population
% std standard deviation of the particle population
% Q covariance of noise added to state at each step
% L covariance of likelihood model
% w0 offset in likelihood model
% dim maximum xy dimension
%
% Example::
%
% Create a landmark map
% map = PointMap(20);
% and a vehicle with odometry covariance and a driver
% W = diag([0.1, 1*pi/180].^2);
% veh = Vehicle(W);
% veh.add_driver( RandomPath(10) );
% and create a range bearing sensor
% R = diag([0.005, 0.5*pi/180].^2);
% sensor = RangeBearingSensor(veh, map, R);
%
% For the particle filter we need to define two covariance matrices. The
% first is is the covariance of the random noise added to the particle
% states at each iteration to represent uncertainty in configuration.
% Q = diag([0.1, 0.1, 1*pi/180]).^2;
% and the covariance of the likelihood function applied to innovation
% L = diag([0.1 0.1]);
% Now construct the particle filter
% pf = ParticleFilter(veh, sensor, Q, L, 1000);
% which is configured with 1000 particles. The particles are initially
% uniformly distributed over the 3-dimensional configuration space.
%
% We run the simulation for 1000 time steps
% pf.run(1000);
% then plot the map and the true vehicle path
% map.plot();
% veh.plot_xy('b');
% and overlay the mean of the particle cloud
% pf.plot_xy('r');
% We can plot the standard deviation against time
% plot(pf.std(1:100,:))
% The particles are a sampled approximation to the PDF and we can display
% this as
% pf.plot_pdf()
%
% Acknowledgement::
%
% Based on code by Paul Newman, Oxford University,
% http://www.robots.ox.ac.uk/~pnewman
%
% Reference::
%
% Robotics, Vision & Control,
% Peter Corke,
% Springer 2011
%
% See also Vehicle, RandomPath, RangeBearingSensor, PointMap, EKF.
% Copyright (C) 1993-2017, by Peter I. Corke
%
% This file is part of The Robotics Toolbox for MATLAB (RTB).
%
% RTB is free software: you can redistribute it and/or modify
% it under the terms of the GNU Lesser General Public License as published by
% the Free Software Foundation, either version 3 of the License, or
% (at your option) any later version.
%
% RTB is distributed in the hope that it will be useful,
% but WITHOUT ANY WARRANTY; without even the implied warranty of
% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
% GNU Lesser General Public License for more details.
%
% You should have received a copy of the GNU Leser General Public License
% along with RTB. If not, see <http://www.gnu.org/licenses/>.
%
% http://www.petercorke.com
%note this is not coded efficiently but rather to make the ideas clear
%all loops should be vectorized but that gets a little matlab-speak intensive
%and may obliterate the elegance of a particle filter....
classdef ParticleFilter < handle
%TODO
% x_est should be a weighted mean
% std should be a weighted std (x-mean)' W (x-mean) ???
properties
robot
sensor
nparticles
x % particle states; nparticles x 3
weight % particle weights; nparticles x 1
x_est % mean of the particle population
std % standard deviation of the particle population
Q % covariance of noise added to state at each step
L % covariance of likelihood model
history
keephistory
dim % maximum xy dimension
h % graphics handle for particles
randstream
seed0
w0
x0 % initial particle distribution
anim
end % properties
methods
function pf = ParticleFilter(robot, sensor, Q, L, np, varargin)
%ParticleFilter.ParticleFilter Particle filter constructor
%
% PF = ParticleFilter(VEHICLE, SENSOR, Q, L, NP, OPTIONS) is a particle
% filter that estimates the state of the VEHICLE with a landmark sensor
% SENSOR. Q is the covariance of the noise added to the particles
% at each step (diffusion), L is the covariance used in the
% sensor likelihood model, and NP is the number of particles.
%
% Options::
% 'verbose' Be verbose.
% 'private' Use private random number stream.
% 'reset' Reset random number stream.
% 'seed',S Set the initial state of the random number stream. S must
% be a proper random number generator state such as saved in
% the seed0 property of an earlier run.
% 'nohistory' Don't save history.
% 'x0' Initial particle states (Nx3)
%
% Notes::
% - ParticleFilter subclasses Handle, so it is a reference object.
% - If initial particle states not given they are set to a uniform
% distribution over the map, essentially the kidnapped robot problem
% which is quite unrealistic.
% - Initial particle weights are always set to unity.
% - The 'private' option creates a private random number stream for the
% methods rand, randn and randi. If not given the global stream is used.
%
%
% See also Vehicle, Sensor, RangeBearingSensor, PointMap.
pf.robot = robot;
pf.sensor = sensor;
pf.Q = Q;
pf.L = L;
pf.nparticles = np;
pf.dim = sensor.map.dim;
pf.history = [];
pf.x = [];
pf.weight = [];
pf.w0 = 0.05;
pf.x0 = [];
opt.private = false;
opt.reset = false;
opt.seed = [];
opt.history = true;
opt.x0 = [];
opt = tb_optparse(opt, varargin);
pf.keephistory = opt.history;
% create a private random number stream if required
if opt.private
pf.randstream = RandStream.create('mt19937ar');
else
pf.randstream = RandStream.getGlobalStream();
end
% reset the random number stream if required
if opt.reset
pf.randstream.reset();
end
% return the random number stream to known state if required
if ~isempty(opt.seed)
set(pf.randstream.set(opt.seed));
end
% save the current state in case it later turns out to give interesting results
pf.seed0 = pf.randstream.State;
if opt.x0
pf.x0 = opt.x0;
end
end
function init(pf)
%ParticleFilter.init Initialize the particle filter
%
% PF.init() initializes the particle distribution and clears the
% history.
%
% Notes::
% - If initial particle states were given to the constructor the states are
% set to this value, else a random distribution over the map is used.
% - Invoked by the run() method.
pf.robot.init();
pf.history = [];
if pf.x0
pf.x = pf.x0; % assign initial particle states
else
% create initial particle distribution as uniformly randomly distributed
% over the map area and heading angles
pf.x = (2*pf.rand([pf.nparticles,3]) - 1) * diag([pf.dim, pf.dim, pi]);
end
pf.weight = ones(pf.nparticles, 1);
pf.x_est = [];
pf.std = [];
end
function run(pf, niter, varargin)
%ParticleFilter.run Run the particle filter
%
% PF.run(N, OPTIONS) runs the filter for N time steps.
%
% Options::
% 'noplot' Do not show animation.
%
% Notes::
% - All previously estimated states and estimation history is
% cleared.
opt.plot = true;
opt.movie = [];
opt = tb_optparse(opt, varargin);
anim = Animate(opt.movie);
pf.init();
pf.sensor.map.plot();
a = axis;
a(5:6) = [-pi pi];
axis(a)
zlabel('heading (rad)');
% display the initial particles
pf.h = plot3(pf.x(:,1), pf.x(:,2), pf.x(:,3), 'g.');
set(pf.h, 'Tag', 'particles');
pf.robot.plot();
% iterate over time
for i=1:niter
pf.step(opt);
anim.add();
end
anim.close();
end
function step(pf, opt)
%fprintf('---- step\n');
odo = pf.robot.step(); % move the robot
% update the particles based on odometry
pf.predict(odo);
% get a sensor reading
[z,jf] = pf.sensor.reading();
if ~isnan(jf)
pf.observe(z, jf);
%fprintf(' observe beacon %d\n', jf);
pf.select();
end
% our estimate is simply the mean of the particles
mn = mean(pf.x);
pf.x_est = [pf.x_est; mn];
s = std(pf.x);
% std is more complex for angles, need to account for 2pi wrap
s(3) = sqrt(sum(angdiff(pf.x(:,3), mn(3)).^2)) / (pf.nparticles-1);
pf.std = [pf.std; s];
% display the updated particles
set(pf.h, 'Xdata', pf.x(:,1), 'Ydata', pf.x(:,2), 'Zdata', pf.x(:,3));
if opt.plot
pf.robot.plot();
drawnow
end
if ~isempty(pf.anim)
pf.anim.add();
end
if pf.keephistory
hist = [];
hist.x_est = pf.x;
hist.w = pf.weight;
pf.history = [pf.history hist];
end
end
function plot_pdf(pf)
%ParticleFilter.plot_pdf Plot particles as a PDF
%
% PF.plot_pdf() plots a sparse PDF as a series of vertical line
% segments of height equal to particle weight.
clf
hold on
for p = 1:pf.nparticles
x = pf.x(p,:);
plot3([x(1) x(1)], [x(2) x(2)], [0 pf.weight(p)], 'r');
plot3([x(1) x(1)], [x(2) x(2)], [0 pf.weight(p)], 'k.', 'MarkerSize', 12);
end
grid on
xyzlabel
zlabel('particle weight')
view(30,60);
rotate3d on
end
function plot_xy(pf, varargin)
%ParticleFilter.plot_xy Plot vehicle position
%
% PF.plot_xy() plots the estimated vehicle path in the xy-plane.
%
% PF.plot_xy(LS) as above but the optional line style arguments
% LS are passed to plot.
plot(pf.x_est(:,1), pf.x_est(:,2), varargin{:});
end
function display(pf)
%ParticleFilter.display Display status of particle filter object
%
% PF.display() displays the state of the ParticleFilter object in
% human-readable form.
%
% Notes::
% - This method is invoked implicitly at the command line when the result
% of an expression is a ParticleFilter object and the command has no trailing
% semicolon.
%
% See also ParticleFilter.char.
loose = strcmp( get(0, 'FormatSpacing'), 'loose');
if loose
disp(' ');
end
disp([inputname(1), ' = '])
disp( char(pf) );
end % display()
function s = char(pf)
%ParticleFilter.char Convert to string
%
% PF.char() is a string representing the state of the ParticleFilter
% object in human-readable form.
%
% See also ParticleFilter.display.
s = sprintf('ParticleFilter object: %d particles', pf.nparticles);
if ~isempty(pf.robot)
s = char(s, char(pf.robot) );
end
if ~isempty(pf.sensor)
s = char(s, char(pf.sensor));
end
s = char(s, ['Q: ' mat2str(pf.Q, 3)] );
s = char(s, ['L: ' mat2str(pf.L, 3)] );
s = char(s, sprintf('w0: %g', pf.w0) );
end
end % methods
methods(Access=protected)
% step 2
% update the particle state based on odometry and a random perturbation
function predict(pf, odo)
% Straightforward code:
%
% for i=1:pf.nparticles
% x = pf.robot.f( pf.x(i,:), odo)' + sqrt(pf.Q)*pf.randn(3,1);
% x(3) = angdiff(x(3));
% pf.x(i,:) = x;
%
% Vectorized code:
randvec = pf.randn(pf.nparticles,3);
pf.x = pf.robot.f( pf.x, odo) + randvec*sqrt(pf.Q);
pf.x(:,3) = angdiff(pf.x(:,3));
end
% step 3
% predict observation and score the particles
function observe(pf, z, jf)
% Straightforward code:
%
% for p = 1:pf.nparticles
% % what do we expect observation to be for this particle?
% % use the sensor model h(.)
% z_pred = pf.sensor.h( pf.x(p,:), jf);
%
% % how different is it
% innov(1) = z(1) - z_pred(1);
% innov(2) = angdiff(z(2), z_pred(2));
%
% % get likelihood (new importance). Assume Gaussian but any PDF works!
% % If predicted obs is very different from actual obs this score will be low
% % ie. this particle is not very good at predicting the observation.
% % A lower score means it is less likely to be selected for the next generation...
% % The weight is never zero.
% pf.weight(p) = exp(-0.5*innov'*inv(pf.L)*innov) + 0.05;
% end
%
% Vectorized code:
invL = inv(pf.L);
z_pred = pf.sensor.h( pf.x, jf);
z_pred(:,1) = z(1) - z_pred(:,1);
z_pred(:,2) = angdiff(z(2), z_pred(:,2));
LL = -0.5*[invL(1,1); invL(2,2); 2*invL(1,2)];
e = [z_pred(:,1).^2 z_pred(:,2).^2 z_pred(:,1).*z_pred(:,2)]*LL;
pf.weight = exp(e) + pf.w0;
end
% step 4
% select particles based on their weights
function select(pf)
% particles with large weights will occupy a greater percentage of the
% y axis in a cummulative plot
CDF = cumsum(pf.weight)/sum(pf.weight);
% so randomly (uniform) choosing y values is more likely to correspond to
% better particles...
iSelect = pf.rand(pf.nparticles,1);
% find the particle that corresponds to each y value (just a look up)
iNextGeneration = interp1(CDF, 1:pf.nparticles, iSelect, 'nearest', 'extrap');
% copy selected particles for next generation..
pf.x = pf.x(iNextGeneration,:);
end
function r = rand(pf, varargin)
r = pf.randstream.rand(varargin{:});
end
function r = randn(pf, varargin)
r = pf.randstream.randn(varargin{:});
end
end % private methods
end