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segment_foot.m
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segment_foot.m
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function person = segment_foot(person,S)
P = person.segment(S).origin + person.segment(S).offset;
R = person.segment(S).Rglobal;
i_m = person.sex;
%% Foot
N = 100; % number of disks
ind = 1:N;
%% Measurements
b = person.meas{S}.all(1); %width at toes
c = person.meas{S}.all(2); %width at heel
h1 = person.meas{S}.all(3); %height of big toe
h2 = person.meas{S}.all(4) - h1; %height of ankle
L = person.meas{S}.all(5); %length of foot
d = person.meas{S}.all(6); % used for ground contact point
a = person.meas{S-1}.diam(end); % last leg width measurement
%% Calculations
l_i = a+(L-a)*ind./N; %A2.106
b_i = a+(b-a)*ind./N;
c_i = a+(c-a)*ind./N;
v = l_i.*(h2/N).*(b_i+c_i)/2;
v_11 = L*h1*(5*b+c)/36;
v_12 = L*h1*(b+5*c)/36;
v_13 = L*h1*(b+c)/4;
v_14 = 0.5*h2*(L*(a+b+c)/3+a^2); %from the fortran code - subroutine SEG147, equation S4V14
volume = v_11 + v_12 + v_13 + v_14;
m = person.density.foot(ind).*v;
m_11 = person.density.heel*v_11;
m_12 = person.density.heel*v_12;
m_13 = person.density.sole*v_13;
mass = m_11 + m_12 + m_13 + sum(m);
% Mass centroid:
xc = 0;
ycm = (m_11+m_12)*(-h2-h1*0.75) +...
m_13*(-h2-h1*0.25) + ...
sum(m.*(-ind.*h2/N));
zcm = ...
m_11*L*(-2/3+(7*b+2*c)/(45*b+9*c)) + ...
m_12*L*(b+8*c)/(9*b+45*c) + ...
m_13*L*(-2/3+(b+2*c)/(3*b+3*c)) + ...
sum(m.*(-a/2 - ind.*(2*L/3-a/2)/100 + ...
l_i.*(b_i+2*c_i)./(3*b_i+3*c_i)) ...
);
yc = ycm/mass;
zc = zcm/mass;
% Moments of inertia:
%%ALL REMAINING 'ERRORS' IN THE MOMENTS OF INERTIA RESULT
%%FROM HATZE'S USE OF 0.667 IN HIS CODE INSTEAD OF 2/3
Ix_i = m.*(l_i).^2/18.*(b_i.^2+4*b_i.*c_i+c_i.^2)./((b_i+c_i).^2);
Iz_i = m.*(b_i.^2+c_i.^2)/24;
Iy_i = Ix_i + Iz_i;
% Principal moments of inertia w.r.t. centroid;
bb=(b+2*c)/3;
cc=(2*b+c)/3;
Ip_x = m_11*( ...
(L/3)^2*(b^2+4*b*cc+cc^2)/(18*(b+cc)^2) + ...
(h2+3*h1/4+yc)^2 + (2*L/3 - L*(7*b+2*c)/(45*b+9*c) + zc )^2 ...
) + m_12*( ...
(L/3)^2*(bb^2+4*bb*c+c^2)/(18*(bb+c)^2) + ...
(h2+3*h1/4+yc)^2 + (L*(b+8*c)/(9*b+45*c) - zc)^2 ...
) + m_13*( ...
(L^2)*(b^2+4*b*c+c^2)/(18*(b+c)^2)+...
(h2+h1/4+yc)^2 + (2*L/3-L*(b+2*c)/(3*(b+c))+zc)^2 ...
) + sum( ...
Ix_i + m.*((ind.*h2/N+yc).^2 + ...
(a/2 + (2*L/3-a/2).*ind./N - l_i.*(b_i+2*c_i)./(3.*(b_i+c_i)) + zc).^2) ... %extra end bracket req in eq A2.108
);
I_y1 = ...
m_11*(...
(L/3)^2*(b^2+4*b*cc+(cc)^2)/(18*(b+cc)^2) + ...
(b^2+cc^2)/24+(2*L/3-L*(7*b+2*c)/(9*(5*b+c))+zc)^2 ...
) + m_12*( ...
(L/3)^2*((bb)^2 + 4*c*(bb)+c^2)/(18*(bb+c)^2) + ...
(c^2+bb^2)/24+(L*(b+8*c)/(9*(b+5*c))-zc)^2 ...
) + m_13*( ...
L^2*(b^2+4*b*c+c^2)/(18*(b+c)^2) + (b^2+c^2)/24 + (2*L/3-L*(bb/(b+c))+zc)^2 ...
) + sum( ...
Iy_i + m.*((a/2 + (2*L/3-a/2).*ind./N - l_i.*(b_i+2*c_i)./(3.*(b_i+c_i)) + zc).^2) ...
);
I_z1 = ...
m_11*( (b^2+cc^2)/24 + (h2+3*h1/4+yc)^2 ) + ...
m_12*( (bb^2+c^2)/24 + (h2+3*h1/4+yc)^2 ) + ...
m_13*( (b^2+c^2)/24 + (h2+h1/4+yc)^2) + ...
sum( Iz_i+m.*(ind.*h2/N+yc).^2 );
I_y1z1 = ...
m_11*(-h2-3*h1/4-yc)*(-2*L/3+L*(7*b+2*c)/(9*(5*b+c))-zc) + ...
m_12*(-h2-3*h1/4-yc)*(L*(b+8*c)/(9*b+45*c)-zc) + ...
m_13*(-h2-h1/4-yc)*(-2*L/3+L*(b+2*c)/(3*(b+c))-zc) + ...
sum( m.*(-ind.*h2/N-yc).* ...
(-a/2 - (2*L/3-a/2).*ind./N + l_i.*(b_i+2*c_i)./(3*(b_i+c_i))-zc) ...
);
Ip_y = (I_y1+I_z1)/2+sqrt(1/4*(I_y1-I_z1)^2+I_y1z1^2);
Ip_z = (I_y1+I_z1)/2-sqrt(1/4*(I_y1-I_z1)^2+I_y1z1^2);
theta = atan(I_y1z1/(I_z1-Ip_y));
%centroid w.r.t local coordinate systems (since principal axes differ from
%original segment axes)
xbc = 0;
ybc = yc*cos(theta)+zc*sin(theta);
zbc = zc*cos(theta)-yc*sin(theta);
%principal moments of inertia w.r.t local systems origin
PIOX = Ip_x+mass*(ybc^2+zbc^2);
PIOY = Ip_y+mass*(xbc^2+zbc^2);
PIOZ = Ip_z+mass*(xbc^2+ybc^2);
%coordinates of ground contact points (Heel and Toe)
VXH = 0;
r = person.meas{S-1}.ankle/2;
VYH = -(h2+h1)*cos(theta) + (0.208*L+r/2)*sin(theta);
VZH = (0.208*L+r/2)*cos(theta) + (h2+h1)*sin(theta);
VXT = 0;
VYT = -(h2+h1)*cos(theta) + (-d+r/2)*sin(theta);
VZT = (-d+r/2)*cos(theta) + (h2+h1)*sin(theta);
person.segment(S).mass = mass;
person.segment(S).volume = volume;
person.segment(S).centroid = [xc; yc; zc];
person.segment(S).Minertia = [Ip_x,Ip_y,Ip_z];
person.segment(S).theta = theta;
%% Plot
if person.plot || person.segment(S).plot
opt1 = {'opacity',person.segment(S).opacity(1),'edgeopacity',0,'colour',person.segment(S).colour};
opt = {'opacity',person.segment(S).opacity(1),'edgeopacity',person.segment(S).opacity(2),'colour',person.segment(S).colour};
for ii = ind
ph = -ii*h2/100; % plate height
s = -a/2-ii/100*(2/3*L-a/2);
plot_trapzoidal_plate(P+R*[0;ph;s+l_i(ii)/2],c_i(ii)/2,b_i(ii)/2,l_i(ii),h2/100,opt1{:},'rotate',R)
end
plot_trapzoidal_plate(P+R*[0;-h2;-L/6],c/2,b/2,L,-h1/2,opt{:},'rotate',R)
plot_trapzoidal_plate(P+R*[0;-h2-h1;L/6],c/2,(c+1/3*(b-c))/2,L/3,h1/2,opt{:},'rotate',R)
plot_trapzoidal_plate(P+R*[0;-h2-h1;-L/2],(b+1/3*(c-b))/2,b/2,L/3,h1/2,opt{:},'rotate',R)
end
end