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lspb.m
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lspb.m
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%LSPB Linear segment with parabolic blend
%
% [S,SD,SDD] = LSPB(S0, SF, M) is a scalar trajectory (Mx1) that varies
% smoothly from S0 to SF in M steps using a constant velocity segment and
% parabolic blends (a trapezoidal velocity profile). Velocity and
% acceleration can be optionally returned as SD (Mx1) and SDD (Mx1)
% respectively.
%
% [S,SD,SDD] = LSPB(S0, SF, M, V) as above but specifies the velocity of
% the linear segment which is normally computed automatically.
%
% [S,SD,SDD] = LSPB(S0, SF, T) as above but specifies the trajectory in
% terms of the length of the time vector T (Mx1).
%
% [S,SD,SDD] = LSPB(S0, SF, T, V) as above but specifies the velocity of
% the linear segment which is normally computed automatically and a time
% vector.
%
% LSPB(S0, SF, M, V) as above but plots S, SD and SDD versus time in a single
% figure.
%
% Notes::
% - If M is given
% - Velocity is in units of distance per trajectory step, not per second.
% - Acceleration is in units of distance per trajectory step squared, not
% per second squared.
% - If T is given then results are scaled to units of time.
% - The time vector T is assumed to be monotonically increasing, and time
% scaling is based on the first and last element.
% - For some values of V no solution is possible and an error is flagged.
%
% References::
% - Robotics, Vision & Control, Chap 3,
% P. Corke, Springer 2011.
%
% See also TPOLY, JTRAJ.
% 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
%TODO
% add a 'dt' option, to convert to everything to units of seconds
function [s,sd,sdd] = lspb(q0, q1, t, V)
t0 = t;
if isscalar(t)
t = (0:t-1)';
else
t = t(:);
end
plotsargs = {'Markersize', 16};
tf = max(t(:));
if nargin < 4
% if velocity not specified, compute it
V = (q1-q0)/tf * 1.5;
else
V = abs(V) * sign(q1-q0);
if abs(V) < abs(q1-q0)/tf
error('V too small');
elseif abs(V) > 2*abs(q1-q0)/tf
error('V too big');
end
end
if q0 == q1
s = ones(size(t)) * q0;
sd = zeros(size(t));
sdd = zeros(size(t));
return
end
tb = (q0 - q1 + V*tf)/V;
a = V/tb;
p = zeros(length(t), 1);
pd = p;
pdd = p;
for i = 1:length(t)
tt = t(i);
if tt <= tb
% initial blend
p(i) = q0 + a/2*tt^2;
pd(i) = a*tt;
pdd(i) = a;
elseif tt <= (tf-tb)
% linear motion
p(i) = (q1+q0-V*tf)/2 + V*tt;
pd(i) = V;
pdd(i) = 0;
else
% final blend
p(i) = q1 - a/2*tf^2 + a*tf*tt - a/2*tt^2;
pd(i) = a*tf - a*tt;
pdd(i) = -a;
end
end
switch nargout
case 0
if isscalar(t0)
% for scalar time steps, axis is labeled 1 .. M
xt = t+1;
else
% for vector time steps, axis is labeled by vector M
xt = t;
end
clf
subplot(311)
% highlight the accel, coast, decel phases with different
% colored markers
hold on
%plot(xt, p);
k = t<= tb;
plot(xt(k), p(k), 'r.-', plotsargs{:});
k = (t>=tb) & (t<= (tf-tb));
plot(xt(k), p(k), 'b.-', plotsargs{:});
k = t>= (tf-tb);
plot(xt(k), p(k), 'g.-', plotsargs{:});
grid; ylabel('$s$', 'FontSize', 16, 'Interpreter','latex');
hold off
subplot(312)
plot(xt, pd, '.-', plotsargs{:});
grid;
if isscalar(t0)
ylabel('$ds/dk$', 'FontSize', 16, 'Interpreter','latex');
else
ylabel('$ds/dt$', 'FontSize', 16, 'Interpreter','latex');
end
subplot(313)
plot(xt, pdd, '.-', plotsargs{:});
grid;
if isscalar(t0)
ylabel('$ds^2/dk^2$', 'FontSize', 16, 'Interpreter','latex');
else
ylabel('$ds^2/dt^2$', 'FontSize', 16, 'Interpreter','latex');
end
if ~isscalar(t0)
xlabel('t (seconds)')
else
xlabel('k (step)');
for c=findobj(gcf, 'Type', 'axes')
set(c, 'XLim', [1 t0]);
end
end
shg
case 1
s = p;
case 2
s = p;
sd = pd;
case 3
s = p;
sd = pd;
sdd = pdd;
end