MATLAB error using fzero function
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My following code generates the plot of V and D values in figure 1. In the graph, the parabolas and straight lines intersect, and I need to find the roots from the plot. So I tried to use fzero function, but the error appeared: Operands to the logical AND (&&) and OR (||) operators must be convertible to logical scalar values. Use the ANY or ALL functions to reduce operands to logical scalar values.
Error in fzero (line 326) elseif ~isfinite(fx) || ~isreal(fx)
Error in HW1 (line 35) x=fzero(fun,1);
My code is:
clear all; close all
W = 10000; %[N]
S = 40; %[m^2]
AR = 7;
cd0 = 0.01;
k = 1 / pi / AR;
clalpha = 2*pi;
Tsl=800;
figure(1);hold on; xlabel('V');ylabel('D')
for h=0:1:8;
i=0;
for alpha = 1:0.25:12
i=i+1;
rho(i)=1.2*exp(-h/10.4);
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho(i)/S/cl(i));
L(i) = 0.5 * rho(i) * V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho(i) * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
p(i) = D(i)*V(i);
ang(i) = alpha;
T(i)=Tsl*(rho(i)/1.2).^0.75;
end
figure(1); plot(V,D); hold on
plot(V,T);
end
fun = @(V) 0.5*V.*V.*rho.*S.*cd-T;
x=fzero(fun,1);
Probably, I should not use the fzero function, but the task is to find the roots of V from a plot (figure 1). There are parabolas and straight lines respectively.
Respuesta aceptada
I have no idea what intersections you want to find, so this is a guess.
It should at least get you started —
% clear all; close all
W = 10000; %[N]
S = 40; %[m^2]
AR = 7;
cd0 = 0.01;
k = 1 / pi / AR;
clalpha = 2*pi;
Tsl=800;
figure(1);hold on; xlabel('V');ylabel('D')
hv=0:1:8;
alphav = 1:0.25:12;
for k1 = 1:numel(hv)
h = hv(k1);
i=0;
for alpha = 1:0.25:12
i=i+1;
rho(i)=1.2*exp(-h/10.4);
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho(i)/S/cl(i));
L(i) = 0.5 * rho(i) * V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho(i) * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
p(i) = D(i)*V(i);
ang(i) = alpha;
T(i)=Tsl*(rho(i)/1.2).^0.75;
end
Vm(k1,:) = V; % Save Results
Dm(k1,:) = D; % Save Results
Tm(k1,:) = T; % Save Results
xix = find(diff(sign(0.5*V.*V.*rho.*S.*cd-T))); % Approximate Indices Of Intersections
if ~isempty(xix) % Skip If Empty
for k3 = 1:numel(xix)
idxrng = max(xix(k3)-1,1) : min(numel(V),xix(k3)+1);
xv(k3) = interp1(D(idxrng)-T(idxrng), V(idxrng), 0);
yv(k3) = interp1(V(idxrng),D(idxrng), xv(k3));
Xm{k1,k3} = xv(k3); % Intersection X-Matrix
Ym{k1,k3} = yv(k3); % Intersection Y-Matrix
end
end
figure(1)
plot(V,D, 'DisplayName',sprintf('D_{%d}',k1))
hold on
plot(V,T, 'DisplayName',sprintf('T_{%d}',k1))
plot(xv, yv, 's', 'DisplayName',sprintf('Intersections %d',k1)) % Plot Intersections (Optional)
end
legend('Location','eastoutside','NumColumns',2)
Intersections = cell2table(cat(2,Xm,Ym), 'VariableNames',{'X1','X2','Y1','Y2'})
% Vm
% Dm
% Tm
% fun = @(V) 0.5*V.*V.*rho.*S.*cd-T;
% x=fzero(fun,1);
.
10 comentarios
Alina Abdikadyr
el 23 de En. de 2023
Star Strider
el 23 de En. de 2023
My pleasure!
If my Answer helped you solve your problem, please Accept it!
.
Alina Abdikadyr
el 26 de En. de 2023
It was modified a bit too much, and eliminated the ‘k1’ loop count variable. That was the essential problem.
Creating:
rhov = 1.2:-0.15:0.6;
and then using:
for k1 = 1:numel(rhov);
rho = rhov(k1);
<REST OF THE LOOP CODE>
end
restored the original code architecture.
It now works as the orignal version did —
W = 10000;
S = 40;
AR = 7;
cd0 = 0.01;
k = 1 / pi / AR;
clalpha = 2*pi;
Tsl=800;
rhov = 1.2:-0.15:0.6;
figure(1);hold on; xlabel('V');ylabel('D')
for k1 = 1:numel(rhov);
rho = rhov(k1);
i=0;
for alpha = 1:0.25:15
i=i+1;
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho/S/cl(i));
L(i) = 0.5 * rho * V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
p(i) = D(i)*V(i);
ang(i) = alpha;
T(i)=Tsl*(rho/1.2).^0.75;
end
Vm(k1,:) = V; % Save Results
Dm(k1,:) = D; % Save Results
Tm(k1,:) = T; % Save Results
xix = find(diff(sign(0.5*V.*V.*rho.*S.*cd-T))); % Approximate Indices Of Intersections
if ~isempty(xix) % Skip If Empty
for k3 = 1:numel(xix)
idxrng = max(xix(k3)-1,1) : min(numel(V),xix(k3)+1);
xv(k3) = interp1(D(idxrng)-T(idxrng), V(idxrng), 0);
yv(k3) = interp1(V(idxrng),D(idxrng), xv(k3));
Xm{k1,k3} = xv(k3); % Intersection X-Matrix
Ym{k1,k3} = yv(k3); % Intersection Y-Matrix
end
end
figure(1)
plot(V,D, 'DisplayName',sprintf('D_{%d}',k1))
hold on
plot(V,T, 'DisplayName',sprintf('T_{%d}',k1))
xlim([0 100])
ylim([0 1000])
plot(xv, yv, 's', 'DisplayName',sprintf('Intersections %d',k1)) % Plot Intersections (Optional)
end
% Q = cat(1,Xm,Ym)
legend('Location','eastoutside','NumColumns',1)
Intersections = cell2table(cat(2,Xm,Ym), 'VariableNames',{'Xmax','Xmin','Y1','Y2'})
The rest of the code is essentialy unchanged.
.
Alina Abdikadyr
el 26 de En. de 2023
As always, my pleasure!
Adding:
[Dmin,idx] = min(D);
minD(k1,:) = Dmin;
VminD(k1,:) = V(idx);
and the appropriate table entries using the addvars function returns their values and ‘V’ coordinate values in the ‘Intersections’ table —
W = 10000;
S = 40;
AR = 7;
cd0 = 0.01;
k = 1 / pi / AR;
clalpha = 2*pi;
Tsl=800;
rhov = 1.2:-0.15:0.6;
figure(1);hold on; xlabel('V');ylabel('D')
for k1 = 1:numel(rhov);
rho = rhov(k1);
i=0;
for alpha = 1:0.25:15
i=i+1;
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho/S/cl(i));
L(i) = 0.5 * rho * V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
p(i) = D(i)*V(i);
ang(i) = alpha;
T(i)=Tsl*(rho/1.2).^0.75;
end
Vm(k1,:) = V; % Save Results
Dm(k1,:) = D; % Save Results
Tm(k1,:) = T; % Save Results
xix = find(diff(sign(0.5*V.*V.*rho.*S.*cd-T))); % Approximate Indices Of Intersections
if ~isempty(xix) % Skip If Empty
for k3 = 1:numel(xix)
idxrng = max(xix(k3)-1,1) : min(numel(V),xix(k3)+1);
xv(k3) = interp1(D(idxrng)-T(idxrng), V(idxrng), 0);
yv(k3) = interp1(V(idxrng),D(idxrng), xv(k3));
Xm{k1,k3} = xv(k3); % Intersection X-Matrix
Ym{k1,k3} = yv(k3); % Intersection Y-Matrix
end
end
figure(1)
plot(V,D, 'DisplayName',sprintf('D_{%d}',k1))
hold on
plot(V,T, 'DisplayName',sprintf('T_{%d}',k1))
xlim([0 100])
ylim([0 1000])
plot(xv, yv, 's', 'DisplayName',sprintf('Intersections %d',k1)) % Plot Intersections (Optional)
[Dmin,idx] = min(D);
minD(k1,:) = Dmin;
VminD(k1,:) = V(idx);
end
% Q = cat(1,Xm,Ym)
legend('Location','eastoutside','NumColumns',1)
Intersections = cell2table(cat(2,Xm,Ym), 'VariableNames',{'Xmax','Xmin','Y1','Y2'});
Intersections = addvars(Intersections, minD,VminD, 'After','Y2')
All the minima appear to have the same magnitude, however their ‘V’ coordinates (‘VminD’) differ.
.
Alina Abdikadyr
el 27 de En. de 2023
You omitted the ‘Pmax’ and ‘Pmin’ calculations.
Adding them back —
W = 10000;
S = 40;
AR = 7;
cd0 = 0.005;
k = 1 / pi / AR;
clalpha = 2*pi;
Psl=25000;
figure(1);hold on; xlabel('V');ylabel('P')
hv=0:1.6484:8.242;
for k1 = 1:numel(hv)
h = hv(k1);
i=0;
for alpha = 1:0.25:15
i=i+1;
rho(i)=1.225*exp(-h/10.4);
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho(i)/S/cl(i));
L(i) = 0.5 * rho(i)* V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho(i) * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
P(i) = D(i)*V(i);
ang(i) = alpha;
Ph(i)=Psl*(rho(i)/1.225).^0.75;
end
Vm(k1,:) = V;
Pm(k1,:) = P;
Pmh(k1,:) = Ph;
xix = find(diff(sign(D.*V-Ph)));
if ~isempty(xix)
for k3 = 1:numel(xix)
idxrng = max(xix(k3)-1,1) : min(numel(V),xix(k3)+1);
xv(k3) = interp1(P(idxrng)-Ph(idxrng), V(idxrng), 0);
yv(k3) = interp1(V(idxrng),P(idxrng), xv(k3));
Xm{k1,k3} = xv(k3); % Intersection X-Matrix
Ym{k1,k3} = yv(k3); % Intersection Y-Matrix
end
end
figure(1)
plot(V,P)
hold on
plot(V,Ph)
xlim([0 90])
ylim([0 45000])
plot(xv, yv, 's', 'DisplayName',sprintf('Intersections %d',k1)) % Plot Intersections (Optional)
[maxP,idx] = max(P);
[minP,idx] = min(P);
Pmax(k1,:) = maxP;
Pmin(k1,:) = minP;
[maxV,idx] = max(V);
[minV,idx] = min(V);
Vmax(k1,:) = maxV;
Vmin(k1,:) = minV;
end
%legend('Location','eastoutside','NumColumns',2)
Intersections = cell2table(cat(2,Xm,Ym), 'VariableNames',{'Xmax','Xmin','Y1','Y2'});
Intersections = addvars(Intersections, Pmax,Pmin,Vmax,Vmin, 'After','Y2')
% Xm1=cell2mat(Xm);
Please always include the intersection arrays ‘Xm’ and ‘Ym’ in the ‘Intersections’ table. (The ‘Xm’ and ‘Ym’ arrays are the intersection coordinates.) Some ‘P’ and ‘Ph’ vectors have one intersection and some have two intersections. Those that have only one intersection have empty cells for the second intersection. (This is to be expected.)
I assume ‘Pmax’, ‘Pmin’, ‘Vmax’ and ‘Vmin’ are calculated as you want them to be. I corrected the ‘Intersections’ table to include all of them. It is easiest to calculate them in the plotting loop, and then add them with the addvars call.
It would be straightforward to include the maxima and minima of the ‘Ph’ vectors as well, if you want to. Add their calculations in the existing loop, and then add their names to the addvars argument list.
.
Alina Abdikadyr
el 27 de En. de 2023
Sorry, but in the table, there are Vmax and Vmin, how could I find a corresponding values of P for calculated Vmax and Vmin
The table gives Pmax and Pmin from a plot, but how to get P values for Vmax and Vmin?
Xmax Xmin Y1 Y2 Pmax Pmin Vmax Vmin
______ ____________ _____ ______________ _____ ______ ______ ______
56.013 {0×0 double} 25000 {0×0 double } 30859 9283.1 61.008 15.752
55.822 {0×0 double} 22198 {0×0 double } 33404 10049 66.04 17.051
55.235 {0×0 double} 19710 {0×0 double } 36159 10878 71.486 18.458
53.92 {0×0 double} 17501 {0×0 double } 39141 11775 77.382 19.98
51.119 {[ 23.8756]} 15539 {[1.5539e+04]} 42369 12746 83.764 21.628
39.638 {[ 39.6377]} 13798 {[1.3798e+04]} 45863 13797 90.673 23.412
Use the returned indices to refer to them.
I calculated them as:
PmaxV(k1,:) = P(Vxidx);
PminV(k1,:) = P(Vnidx);
where ‘Vxidx’ and ‘Vnidx’ are returned from:
[maxV,Vxidx] = max(V);
[minV,Vnidx] = min(V);
And added them to the ‘Intersections’ table as well —
W = 10000;
S = 40;
AR = 7;
cd0 = 0.005;
k = 1 / pi / AR;
clalpha = 2*pi;
Psl=25000;
figure(1);hold on; xlabel('V');ylabel('P')
hv=0:1.6484:8.242;
for k1 = 1:numel(hv)
h = hv(k1);
i=0;
for alpha = 1:0.25:15
i=i+1;
rho(i)=1.225*exp(-h/10.4);
cl(i) = clalpha * alpha * pi/180;
V(i) = sqrt(2*W/rho(i)/S/cl(i));
L(i) = 0.5 * rho(i)* V(i) * V(i) * S * cl(i);
cd(i) = cd0 + k * cl(i) * cl(i);
D(i) = 0.5 * rho(i) * V(i) * V(i) * S * cd(i);
clcd(i) = cl(i)/cd(i);
P(i) = D(i)*V(i);
ang(i) = alpha;
Ph(i)=Psl*(rho(i)/1.225).^0.75;
end
Vm(k1,:) = V;
Pm(k1,:) = P;
Pmh(k1,:) = Ph;
xix = find(diff(sign(D.*V-Ph)));
if ~isempty(xix)
for k3 = 1:numel(xix)
idxrng = max(xix(k3)-1,1) : min(numel(V),xix(k3)+1);
xv(k3) = interp1(P(idxrng)-Ph(idxrng), V(idxrng), 0);
yv(k3) = interp1(V(idxrng),P(idxrng), xv(k3));
Xm{k1,k3} = xv(k3); % Intersection X-Matrix
Ym{k1,k3} = yv(k3); % Intersection Y-Matrix
end
end
figure(1)
plot(V,P)
hold on
plot(V,Ph)
xlim([0 90])
ylim([0 45000])
plot(xv, yv, 's', 'DisplayName',sprintf('Intersections %d',k1)) % Plot Intersections (Optional)
[maxP,idx] = max(P);
[minP,idx] = min(P);
Pmax(k1,:) = maxP;
Pmin(k1,:) = minP;
[maxV,Vxidx] = max(V);
[minV,Vnidx] = min(V);
Vmax(k1,:) = maxV;
Vmin(k1,:) = minV;
PmaxV(k1,:) = P(Vxidx);
PminV(k1,:) = P(Vnidx);
end
%legend('Location','eastoutside','NumColumns',2)
Intersections = cell2table(cat(2,Xm,Ym), 'VariableNames',{'Xmax','Xmin','Y1','Y2'});
Intersections = addvars(Intersections, Pmax,Pmin,Vmax,Vmin,PmaxV,PminV, 'After','Y2')
% Xm1=cell2mat(Xm);
.
Más respuestas (1)
John D'Errico
el 23 de En. de 2023
Editada: John D'Errico
el 23 de En. de 2023
0 votos
You cannot use fzero on a vector. A vector of elements is NOT a function. It is just a list of numbers. And while you may think of it as a function, it is not. Essentially, a vector of numbers is just a picture of a function.
Suppose you were not feeling well today, so you decided to visit your doctor. But rather than appearing for an examination, you decided to just send your doctor a picture of yourself. Would that be sufficient to solve your problem? Rather than bring your car in for an oil change, would you just send a picture of your car to the JiffyLube place? Fzero needs a function, not just a list of numbers.
Instead, you will need to use tools to identify where the curves cross, perhaps using methods of interpolation. Or, better yet, you could use the actual functions themselves, now as true functions that fzero can evaluate at any point.
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