groundreactionforcesOsman.m

```
function [grf,grt,cop] = groundreactionforcesOsman(t, x, walk)
%the original groundreactionforces doesn't seem to work added this looking
%at sw2
% GROUNDREACTIONFORCES Computes ground reaction forces for 2-D rimless
% wheel
% [grf, grt, cop] = groundreactionforces(t, x, walk) computes the ground
% reaction forces in grf, and ground reaction torques in grt, given input
% consisting of time t, state x, and a walk object containing the
% parameters.
% For this model, grf = [fx; fy], the forward horizontal and vertical
% components. grt = tz, the moment about the ground3 axis.
% cop = copx, the center of pressure along the forward horizontal axis.
parms = get(walk, 'parms');
gamma = parms.gamma; rgyr = parms.rgyr;
q1 = x(1);
u1 = x(2);
sigma2 = 1/(1 + rgyr*rgyr); % this is sigma-squared from McGeer (1990)
% u1dot = fwalk(t, x, walk); % need state-derivative
%
% % acceleration tangential to com path
% atang = -u1dot; % minus sign is because path is cw
%
% % acceleration normal to path, along leg
% anorm = u1*u1; % this is towards ground
%
% grf = [c1 s1; s1 -c1]*[atang; anorm]
u1dotAll = [];
for i = 1:length(t)
q1 = x(i,1); u1 = x(i,2); %u1 = x(i,3); u2 = x(i,4);
c1 = cos(q1); s1 = sin(q1);
xdot = fwalk(t(i), x(i,:), walk, parms); % need state-derivative
u1dot = xdot(2);
u1dotAll = [u1dotAll u1dot];
grf(i,1:2) = [ -c1*u1dot+s1*u1*u1 -s1*u1dot-c1*u1*u1+1 ];
cop(i) = 0;
grt(i) = 0; % ground reaction torque about z axis
end
figure; plot(u1dotAll); hold on; plot(x(:,1), 'r');; plot(x(:,2), 'b');
grt = 0;
cop = 0;
```