Unable to perform assignment because the left and right sides have a different number of elements.

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Fares
Fares on 9 Feb 2024
Edited: Fares on 9 Feb 2024
Ran in:
I am trying to run this code but always get this error
r0=0.05;
k1=0.5;
k2=0.5;
mu=0.5;
rho=0.5;
epsilon=0.25;
K=1;
alpha=0.1;
q=0.1;
eta=0.05;
sigma=5;
zeta=0.05;
omega0=0.001;
NN1=5000;
NN2=5000;
TT=linspace(0.01,350,NN1);
syms M b Msol positive
Nut(M) = mu+(rho*M/(1+M)); % N(M)
gro(M) = r0*(1+k1*Nut(M)*(1-k2*Nut(M))); % r(M)
lam(M) = 1/(1+Nut(M)); % λ(Μ)
P(M) = epsilon*M/(1+M);
dNut(M) = diff(Nut(M),M); % Ν'(Μ)
dgro(M) = diff(gro(M),M); % r'(M)
dlam(M) = diff(lam(M),M); % λ'(M)
dP(M) = diff(P(M),M); % P'(M)
eqn = (q/b)*gro(M)*(eta+P(M))*(1+Nut(M))*(1-(((alpha*sigma*q*(eta+P(M))*(1+Nut(M))+b*(q+alpha)*(zeta*M-omega0)))/(b*alpha*sigma*K)))-(q/sigma)*(zeta*M-omega0)==0;
[num,den]=numden(lhs(eqn));
b_num = linspace(0.001,8,NN2);
for u = 1:numel(b_num)
Msol(u) = vpa(solve(subs(num,b,b_num(u))));
end
Unable to perform assignment because the left and right sides have a different number of elements.

Error in sym/privsubsasgn (line 1200)
L_tilde2 = builtin('subsasgn',L_tilde,struct('type','()','subs',{varargin}),R_tilde);

Error in indexing (line 1031)
C = privsubsasgn(L,R,inds{:});
However when the vector b_num starts from 0.008, the code works. Is there a way I can include the values of b_num less than 0.008? Many thanks!

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Accepted Answer

Torsten
Torsten on 9 Feb 2024
r0=0.05;
k1=0.5;
k2=0.5;
mu=0.5;
rho=0.5;
epsilon=0.25;
K=1;
alpha=0.1;
q=0.1;
eta=0.05;
sigma=5;
zeta=0.05;
omega0=0.001;
NN1=5000;
NN2=5000;
TT=linspace(0.01,350,NN1);
syms M b Msol positive
Nut(M) = mu+(rho*M/(1+M)); % N(M)
gro(M) = r0*(1+k1*Nut(M)*(1-k2*Nut(M))); % r(M)
lam(M) = 1/(1+Nut(M)); % λ(Μ)
P(M) = epsilon*M/(1+M);
dNut(M) = diff(Nut(M),M); % Ν'(Μ)
dgro(M) = diff(gro(M),M); % r'(M)
dlam(M) = diff(lam(M),M); % λ'(M)
dP(M) = diff(P(M),M); % P'(M)
eqn = (q/b)*gro(M)*(eta+P(M))*(1+Nut(M))*(1-(((alpha*sigma*q*(eta+P(M))*(1+Nut(M))+b*(q+alpha)*(zeta*M-omega0)))/(b*alpha*sigma*K)))-(q/sigma)*(zeta*M-omega0)==0;
[num,den]=numden(lhs(eqn));
b_num = linspace(0.001,8,NN2);
Msol = nan(size(b_num));
for u = 1:numel(b_num)
sol = vpa(solve(subs(num,b,b_num(u))));
if ~isempty(sol)
Msol(u) = sol;
end
end
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Torsten
Torsten on 9 Feb 2024
Edited: Torsten on 9 Feb 2024
Ran in:
What is the old one ? I thought it did not work.
If you want a fast solution, you must use the numerical function "roots" to solve for the roots of your polynomial in M of degree 7 instead of the symbolic "solve".
If your equation has more than one positive solution for M given b, I took the first one.
r0=0.05;
k1=0.5;
k2=0.5;
mu=0.5;
rho=0.5;
epsilon=0.25;
K=1;
alpha=0.1;
q=0.1;
eta=0.05;
sigma=5;
zeta=0.05;
omega0=0.001;
NN1=5000;
NN2=5000;
TT=linspace(0.01,350,NN1);
syms M b
Nut(M) = mu+(rho*M/(1+M)); % N(M)
gro(M) = r0*(1+k1*Nut(M)*(1-k2*Nut(M))); % r(M)
lam(M) = 1/(1+Nut(M)); % λ(Μ)
P(M) = epsilon*M/(1+M);
dNut(M) = diff(Nut(M),M); % Ν'(Μ)
dgro(M) = diff(gro(M),M); % r'(M)
dlam(M) = diff(lam(M),M); % λ'(M)
dP(M) = diff(P(M),M); % P'(M)
eqn = (q/b)*gro(M)*(eta+P(M))*(1+Nut(M))*(1-(((alpha*sigma*q*(eta+P(M))*(1+Nut(M))+b*(q+alpha)*(zeta*M-omega0)))/(b*alpha*sigma*K)))-(q/sigma)*(zeta*M-omega0)==0;
[num,den]=numden(lhs(eqn));
p = fliplr(coeffs(num,M));
p = matlabFunction(p);
b_num = linspace(0.001,8,NN2);
Msol = nan(size(b_num));
for u = 1:numel(b_num)
sol = roots(p(b_num(u)));
sol = sol(real(sol)>0 & abs(imag(sol)) < 1e-8);
if ~isempty(sol)
Msol(u) = sol(1);
end
end
plot(b_num,Msol)
grid on

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More Answers (1)

Matt J
Matt J on 9 Feb 2024
Edited: Matt J on 9 Feb 2024
Ran in:
Your code assumes that solve() will always return one and only one solution. There is no reason to think that will always be the case (see below). So, the question becomes, what do you want to do when situations like in the examples below arise?
syms x real
vpa(solve(x^2==1))
ans = 
vpa(solve(x^2==-1))
ans = Empty sym: 0-by-1
  5 Comments
Show 3 older comments
Torsten
Torsten on 9 Feb 2024
Edited: Torsten on 9 Feb 2024
By removing the semicolon behind the line
sol = roots(p(b_num(u)));
you can see the numerical values of the 7 computed roots before the negative and complex ones are rejected by the line
sol = sol(real(sol)>0 & abs(imag(sol)) < 1e-8);

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