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AstarMOO.m
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AstarMOO.m
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% AstarMOO A*-MOO navigation class
%
% A concrete subclass of the Navigation class that implements the A*
% navigation algorithm for multiobjective optimization (MOO) - i.e.
% optimizes over several objectives/criteria.
%
% Methods:
% plan Compute the cost map given a goal and map
% path Compute a path to the goal
% visualize Display the obstacle map (deprecated)
% plot Display the obstacle map
% costmap_modify Modify the costmap
% costmap_get Return the current costmap
% costmap_set Set the current costmap
% distancemap_get Set the current distance map
% heuristic_get Get the current heuristic map
% display Print the parameters in human readable form
% char Convert to string
%
% Properties:
% TBD
%
% Example::
%
% load map1 % load map
% goal = [50;30];
% start = [20;10];
% as = AstarMOO(map); % create Navigation object
% as.plan(goal,2); % setup costmap for specified goal
% as.path(start); % plan solution path star-goal, animate
% P = as.path(start); % plan solution path star-goal, return path
%
% Example 2:
% goal = [100;100];
% start = [1;1];
% as = AstarMOO(0); % create Navigation object with random occupancy grid
% as.addCost(1,L); % add 1st add'l cost layer L
% as.plan(goal,3); % setup costmap for specified goal
% as.path(start); % plan solution path start-goal, animate
% P = as.path(start); % plan solution path start-goal, return path
%
% Notes::
% - Obstacles are represented by Inf in the costmap.
%
% References::
% - A Pareto Optimal D* Search Algorithm for Multiobjective Path Planning, A. Lavin.
% - A Pareto Front-Based Multiobjective Path Planning Algorithm, A. Lavin.
% - Robotics, Vision & Control, Sec 5.2.2, Peter Corke, Springer, 2011.
%
% Author::
% Alexander Lavin
%
% See also Navigation, Astar, AstarPO.
% Copyright (C) 1993-2015, by Peter I. Corke, Alexander Lavin
%
% 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
%
% The RTB implementation of this algorithm is done by Alexander Lavin.
% http://alexanderlavin.com
% Implementation notes:
%
% All the state is kept in the structure called a
% X is an index into the array of states.
% state pointers are kept as matlab array index rather than row,col format
classdef AstarMOO < Navigation
properties (SetAccess=private, GetAccess=private)
% essential world info
costmap % world cost map: obstacle = Inf
G % index of goal point
N % number of objectives
% info kept per cell (state):
b % backpointer (0 means not set)
t % tag: NEW OPEN CLOSED
cost_g % path distance summation
cost_h % path heuristic (state to goal) cost
cost_01 % add'l cost layer 01 (unused)
cost_02 % add'l cost layer 02 (unused)
cost_03 % add'l cost layer 03 (unused)
% add more cost layers if needed...
priority
tie
% list of open states: 2xN matrix
% each open point is a column, row 1 = index of cell, row 2 = k
openlist
niter
changed
openlist_maxlen % keep track of maximum length
quiet
% tag state values
NEW = 0;
OPEN = 1;
CLOSED = 2;
end
methods % start of public methods
% AstarMOO class constructor:
function as = AstarMOO(world, varargin)
%AstarMOO.AstarMOO A*-MOO constructor
%
% AS = AstarMOO(MAP, OPTIONS) is a A* navigation object, and MAP is an
% occupancy grid, a representation of a planar world as a
% matrix whose elements are 0 (free space) or 1 (occupied).
% The occupancy grid is coverted to a costmap with a unit cost
% for traversing a cell.
%
% Options::
% 'goal',G Specify the goal point (2x1)
% 'metric',M Specify the distance metric as 'euclidean' (default)
% or 'cityblock'.
% 'inflate',K Inflate all obstacles by K cells.
% 'quiet' Don't display the progress spinner
%
% Other options are supported by the Navigation superclass.
%
% Notes::
% - If MAP == 0 a random map is created.
%
% See also Navigation.Navigation.
% invoke the superclass constructor
as = as@Navigation(world, varargin{:}); % includes the occgrid
% options
opt.quiet = false;
opt = tb_optparse(opt, varargin);
as.quiet = opt.quiet;
as.occgrid2costmap(as.occgrid);
% initialize the A* state variables
as.reset();
if ~isempty(as.goal)
as.goal_change();
end
as.changed = false;
end
function reset(as)
%AstarMOO.reset Reset the planner
%
% AS.reset() resets the A* planner. The next instantiation
% of AS.plan() will perform a global replan.
% build the matrices required to hold the state of each cell for A*
as.b = zeros(size(as.occgrid), 'uint32'); % backpointers
as.t = zeros(size(as.occgrid), 'uint8'); % tags, all NEW=0
as.cost_g = Inf*ones(size(as.costmap)); % path cost estimate
as.openlist = zeros(2,0); % the open list, one column per point
as.openlist_maxlen = -Inf;
end
%AstarMOO.goal_change Changes to costlayers due to new goal
%position
function goal_change(as)
if isempty(as.b)
return;
end
goal = as.goal;
% keep goal in index rather than row,col format
as.G = sub2ind(size(as.occgrid), goal(2), goal(1));
as.INSERT(as.G, as.projectCost(as.G), 'goalset');
as.cost_g(as.G) = 0;
% new goal changes cost layers:
as.calcHeuristic(as.occgrid, as.goal);
end
function s = char(as)
%AstarMOO.char Convert navigation object to string
%
% AS.char() is a string representing the state of the Astar
% object in human-readable form.
%
% See also AstarMOO.display, Navigation.char.
% most of the work is done by the superclass
s = char@Navigation(as);
end
function plot(as, varargin)
%AstarMOO.plot Visualize navigation environment
%
% AS.plot() displays the occupancy grid and the goal distance
% in a new figure. The goal distance is shown by intensity which
% increases with distance from the goal. Obstacles are overlaid
% and shown in red.
%
% AS.plot(P) as above but also overlays a path given by the set
% of points P (Mx2).
%
% See also Navigation.plot.
plot@Navigation(as, 'distance', as.cost_h, varargin{:});
end
% invoked by Navigation.step
function n = next(as, current)
% Backpropagate from goal to start
% Return [col;row] of previous step
if as.changed
error('Cost map has changed, replan');
end
X = sub2ind(size(as.occgrid), current(2), current(1));
X = as.b(X); % set X as the backpointer of X
if X == 0
n = []; % goal (no further backpointer)
else
[r,c] = ind2sub(size(as.costmap), X);
n = [c;r];
end
end
function plan(as, goal, N)
%AstarMOO.plan Prep the grid for planning.
%
% AS.plan() updates AS with a costmap of distance to the
% goal from every non-obstacle point in the map. The goal is
% as specified to the constructor.
%
% Inputs:
% goal: goal state coordinates
% N: number of optimization objectives; standard A* is 2
% (i.e. distance and heuristic)
as.N = N; % number of optimization objectives
as.openlist = zeros(as.N+1,0);
% Setup cost layers. If a
% cost layer is goal-dependent, it's setup function needs to
% also be called in AS.goal_change(). If more cost layers are
% needed, add similar to AS.cost_01.
% initializations first:
as.cost_g = zeros(size(as.occgrid));
as.cost_h = zeros(size(as.occgrid)); % filled after setting goal below
% if add'l costs haven't been added with addCost()
if isempty(as.cost_01)
as.cost_01 = zeros(size(as.occgrid));
end
if isempty(as.cost_02)
as.cost_02 = zeros(size(as.occgrid));
end
if isempty(as.cost_03)
as.cost_03 = zeros(size(as.occgrid));
end
if nargin > 1
as.goal = goal; % invokes superclass method set.goal()
end
if isempty(as.goal)
error('must specify a goal point');
end
% Setup cost layers AS.cost_g and AS.cost_h.
% assign values to the distance cost layer, set as AS.costmap
as.occgrid2costmap(as.occgrid);
% assign values to the heuristic cost layer, set as AS.cost_h
as.calcHeuristic(as.occgrid, as.goal);
% Additional cost layers are added by the user with the
% AS.addCost() method
% Cost priority/tiebreaker: cost_g (distance to node)
as.priority = as.cost_g;
as.tie = 1; % first cost: cost_g
end
function P = path(as, start)
%AstarMOO.path Find a path between two points
%
% AS.path(START) finds and displays a path from START to GOAL
% which is overlaid on the occupancy grid.
%
% P = AS.path(START) returns the path (2xM) from START to GOAL.
if nargin < 1
error('must specify start state');
end
% invoke the superclass path function, which iterates on our
% next method
start = [start; 1]; % Specifies backpropogation for NAV.path()
if nargout == 0
path@Navigation(as, start);
else
P = path@Navigation(as, start);
end
end
% Handler invoked by Navigation.path() to start the navigation process
% Calculate the solution path
% Line comments LN reference A* pseudocode in Lavin's "A Pareto
% Front-Based Multiobjective Path Planning Algorithm" where n is
% the line number.
function navigate_init(as, start)
as.openlist = zeros(as.N+1,0); % make sure openlist is empty
% begin with the start node
start = sub2ind(size(as.costmap), start(2), start(1));
as.openlist(1,1) = start;
as.t(start) = as.OPEN;
as.niter = 0; flag = 0; % init while loop
% Plan the A* path
while ~isempty(as.openlist) % L4
% Normalize costs on the open list, choose expansion state:
queue = normc(as.openlist(2:size(as.openlist,1),:)');
[~,ind]=min(sum(queue,2));
X = as.openlist(1,ind); % L5; minimum state on the open list
as.DELETE(X); % L6; remove state from the openlist
as.niter = as.niter + 1;
if ~as.quiet && mod(as.niter, 20) == 0 % i.e. spinner every 20 iterations
as.spinner();
end
% Populate the openlist:
for Y=as.neighbors(X) % L7,8; check node's 8 neighbors
if(Y==as.G) % L9; check for goal
as.b(Y) = X;
as.updateCosts(Y,X,as.N)
flag = 1; % flag for goal
break;
end
if as.t(Y)==as.NEW && as.costmap(Y)~=Inf % hasn't been checked and isn't an obstacle
as.b(Y) = X;
as.updateCosts(Y,X,as.N); % as.N = 2 -> base case w/ only distance cost parameters (g and h)
% project node's costs into objective space:
objspace = as.projectCost(Y,X);
as.INSERT(Y, objspace, '');
end
end
if as.verbose
disp(' ')
end
if flag==1 % goal found
break;
end
end
if ~as.quiet
fprintf('\r');
end
as.changed = false;
end
function layer = cost_get(as)
%AstarMOO.cost_get Get the specified cost layer
layer = as.cost_02;
end
function c = heuristic_get(as)
%AstarMOO.heuristic_get Get the current heuristic map
%
% C = AS.heuristic_get() is the current heuristic map. This map is the same size
% as the occupancy grid and the value of each element is the shortest distance
% from the corresponding point in the map to the current goal. It is computed
% by Astar.plan.
%
% See also Astar.plan.
c = as.cost_h;
end
function c = costmap_get(as)
%AstarMOO.costmap_get Get the current costmap
%
% C = AS.costmap_get() is the current costmap. The cost map is the same size
% as the occupancy grid and the value of each element represents the cost
% of traversing the cell. It is autogenerated by the class constructor from
% the occupancy grid such that:
% - free cell (occupancy 0) has a cost of 1
% - occupied cell (occupancy >0) has a cost of Inf
%
% See also Astar.costmap_set, Astar.costmap_modify.
c = as.costmap;
end
function costmap_set(as, costmap)
%AstarMOO.costmap_set Set the current costmap
%
% AS.costmap_set(C) sets the current costmap. The cost map is the same size
% as the occupancy grid and the value of each element represents the cost
% of traversing the cell. A high value indicates that the cell is more costly
% (difficult) to traverese. A value of Inf indicates an obstacle.
%
% Notes::
% - After the cost map is changed the path should be replanned by
% calling AS.plan().
%
% See also Astar.costmap_get, Astar.costmap_modify.
if ~all(size(costmap) == size(as.occgrid))
error('costmap must be same size as occupancy grid');
end
as.costmap = costmap;
as.changed = true;
end
function costmap_modify(as, point, newcost)
%AstarMOO.costmap_modify Modify cost map
%
% AS.costmap_modify(P, NEW) modifies the cost map at P=[X,Y] to
% have the value NEW. If P (2xM) and NEW (1xM) then the cost of
% the points defined by the columns of P are set to the corresponding
% elements of NEW.
%
% Notes::
% - After one or more point costs have been updated the path
% should be replanned by calling AS.plan().
%
% See also AstarMOO.costmap_set, AstarMOO.costmap_get.
if numel(point) == 2
% for case of single point ensure it is a column vector
point = point(:);
end
if numcols(point) ~= numcols(newcost)
error('number of columns in point must match columns in newcost');
end
for i=1:numcols(point)
X = sub2ind(size(as.costmap), point(2,i), point(1,i));
as.costmap(X) = newcost(i);
end
if as.t(X) == as.CLOSED
as.INSERT(X, as.h(X), 'modifycost');
end
as.changed = true;
end
function addCost(as, layer, values)
%AstarMOO.addCost Add an additional cost layer
%
% AS.addCost(LAYER, VALUES) adds the matrix specified by values as a
% cost layer. The layer number is given by LAYER, and VALUES has the same
% size as the original occupancy grid.
if size(values)~=size(as.occgrid)
display('Layer size does not match the environment')
return
end
if max(max(values))~=1 || min(min(values))~=0
display('Layer values are not normalized [0:1]')
return
end
if layer==1
as.cost_01 = values;
elseif layer==2
as.cost_02 = values;
elseif layer==3
as.cost_03 = values;
else
display('Layer index out of range')
end
% If more cost layers needed, add additional elseif statements
% as above.
end
end % end of public methods
methods (Access=protected) % start of private methods
function occgrid2costmap(as, og, cost)
if nargin < 3
cost = 1; % cost to traverse each cell
end
as.costmap = og;
as.costmap(as.costmap==1) = Inf; % occupied cells -> infinite path cost
as.costmap(as.costmap==0) = cost; % unoccupied cells -> path cost
end
function calcHeuristic(as, grid, goal)
as.cost_h=zeros(size(grid));
for ii=1:size(grid,1)
for jj=1:size(grid,2)
as.cost_h(ii,jj)=sqrt((ii-goal(1))^2+(jj-goal(2))^2);
end
end
end
% NOTE: Only for costs that accumulate (i.e. sum) over the
% path, and for dynamic costs.
% E.g. the heuristic parameter AS.cost_h only needs updating
% when the goal state changes; it's values are stored for each
% cell.
%
% Location moving from state b to a.
function k_new = updateCosts(as, a, b, obj)
if nargout > 0
k_new = as.cost_g(b) + as.dc(b,a);
return
end
if obj == 0 % just return what the new priority cost would be (k_new)
return
end
if obj > 1 % base case
as.cost_g(a) = as.cost_g(b) + as.dc(b,a);
% (no heuristic update needed)
end
if obj > 2 % w/ cost_01: elevation
% (no elevation update needed)
end
if obj > 3 % w/ cost_02: solar
sV = [cos(as.niter/100);sin(as.niter/100)]; % rotates 1rad per 100 steps
as.cost_02(a) = dot(sV,as.vc(b,a));
end
if obj > 4 % w/ cost_03: risk
% (no risk update needed)
end
end
% Returns the projection of state a into objective space. If
% specified, location is moving from b to a.
function pt = projectCost(as, a, b)
switch nargin
case 2
pt = [as.cost_g(a);
as.cost_h(a);
as.cost_01(a);
as.cost_02(a);
as.cost_03(a);
];
case 3
pt = [as.cost_g(b) + as.dc(a,b);
as.cost_h(a);
as.cost_01(a);
as.cost_02(a);
as.cost_03(a);
];
otherwise
return
end
end
% X is new node with costs in array pt
function INSERT(as, X, pt, where)
if nargin>2
as.message('insert (%s) %d = %f\n', where, X, pt);
end
i = find(as.openlist(1,:) == X);
if length(i) > 1
error('A*:INSERT: state in open list %d times', X);
end
if as.t(X) == as.NEW
% add a new column to the open list
as.openlist = [as.openlist [X; pt]];
elseif as.t(X) == as.OPEN
% L13: If a node with same position as successor is in the
% OPEN list & has a lower f than successor, then skip this
% successor.
if pt(as.tie) < as.priority(X) % break tie with the sum of path costs
% add a new column to the open list
as.openlist = [as.openlist [X; pt]];
end
elseif as.t(X) == as.CLOSED
% L14: If a node with same position as successor is in the
% CLOSED list & has a lower f than successor, then skip this
% successor.
if pt(as.tie) < as.priority(X) % break tie with the sum of path costs
% add a new column to the open list
as.openlist = [as.openlist [X; pt]];
end
end
% keep track of the max length of the openlist:
if numcols(as.openlist) > as.openlist_maxlen
as.openlist_maxlen = numcols(as.openlist);
end
as.t(X) = as.OPEN; % tag X as open
end
function DELETE(as, X)
as.message('delete %d\n', X);
i = find(as.openlist(1,:) == X);
if length(i) ~= 1
error('D*:DELETE: state %d doesnt exist', X);
end
as.openlist(:,i) = []; % remove the column
as.t(X) = as.CLOSED;
end
% return the distance cost of moving from state X to state Y
function cost = dc(as, X, Y)
[r,c] = ind2sub(size(as.costmap), [X; Y]);
dist = sqrt(sum(diff([r c]).^2));
dcost = (as.costmap(X) + as.costmap(Y))/2;
cost = dist * dcost;
end
% return the robot unit vector; direction of moving from state X to state Y
function vector = vc(as, X, Y)
[Xi,Xj] = ind2sub(size(as.occgrid),X);
[Yi,Yj] = ind2sub(size(as.occgrid),Y);
vector = [Yi-Xi;Yj-Xj];
vector = vector/norm(vector);
% slope = vector(2) / vector(1);
% theta = dot([0,1],[vector])/(norm([0,1])*norm(vector));
end
% return index of neighbor states (max 8) as a row vector
function Y = neighbors(as, X)
dims = size(as.costmap);
[r,c] = ind2sub(dims, X);
% list of 8-way neighbors:
Y = [r-1 r-1 r-1 r r r+1 r+1 r+1; c-1 c c+1 c-1 c+1 c-1 c c+1];
% only use neighbors w/in grid bounds...
k = (min(Y)>0) & (Y(1,:)<=dims(1)) & (Y(2,:)<=dims(2));
Y = Y(:,k);
Y = sub2ind(dims, Y(1,:)', Y(2,:)')';
end
end % end of private methods
end