how to plot a function where there is inside 1x1 sym?
Mostrar comentarios más antiguos
I want to plot T(OMEGA):
T=real(1i*n*alfak*(besselj(np+1,alfak))^2*(conj(A3)*B3-A3*conj(B3)))
where:
- np is known
- n is known
- alfak is known
- besselj(np+1, alfak) is the bessel function of the fisrt kind of order np+1
But A3 and B3 depends on OMEGA and they appears as 1x1 sym in the workspace.
I used this code:
fplot(T)
grid on
But this message appears:
Error in fplot>vectorizeFplot (line 191)
hObj = cellfun(@(f) singleFplot(cax,{f},limits,extraOpts,args),fn{1},'UniformOutput',false);
Error in fplot (line 161)
hObj = vectorizeFplot(cax,fn,limits,extraOpts,args);
Error in calcolo_grafico_coppia (line 100)
fplot(T)
I post the entire code if you want to try (the code is for sure correct, only the function plot is of interest for the question):
clear all
clc
a=10e-3;
b=10e-3;
c=5e-3;
d=5e-3;
e=8e-3;
z1=a;
z2=z1+b;
z3=z2+c;
z4=z3+d;
z5=z4+e;
Br=1.25; %T
R1=25e-3;
R2=65e-3;
R3=90e-3;
u0=4*pi*1e-7;
urb=1000;
sigmab=7e6; %M=1000000
sigmac=57e6;
syms OMEGA
alfa=0.9;
p=4;
%TORQUE T
A=(1:2:10); %vector in order to take n odd
summeT=0.0;
for n=A(1):A(length(A))
for k=1:10
np=n*p;
kind=1;
alfaks = (besselzero(np, k, kind))/R3;
alfak=alfaks(k);
gamma4=sqrt((alfak^2)+1i*np*sigmac*u0*OMEGA);
gamma5=sqrt((alfak^2)+1i*np*sigmab*urb*u0*OMEGA); %devo moltiplicare u0*urb?
syms r; %devo definire la variabile r
Mnksym=((8*Br)/(n*pi*u0*R3^2*(besselj(np+1,alfak*R3))^2))*sin(n*alfa*pi/2)*int(r*besselj(np,alfak*r),r,R1,R2);
Mnk=double(Mnksym); %in order to not have 1x1 sym
syms A1 B1 A2 B2 A3 B3 A4 B4 A5 B5 A6 B6 A7 B7 A8 B8 A9 B9 A10 B10;
eqn1 = A1-B1==0;
eqn2 = A1*exp(alfak*z1)+B1*exp(-alfak*z1)==A2*exp(alfak*z1)+B2*exp(-alfak*z1);
eqn3 = A1*exp(alfak*z1)-B1*exp(-alfak*z1)==(1/urb)*(A2*exp(alfak*z1)+B2*exp(-alfak*z1)+(Mnk/alfak));
eqn4 = A2*exp(alfak*z2)+B2*exp(-alfak*z2)==A3*exp(alfak*z2)+B3*exp(-alfak*z2);
eqn5 = A2*exp(alfak*z2)-B2*exp(-alfak*z2)==A3*exp(alfak*z2)-B3*exp(-alfak*z2)+(Mnk/alfak);
eqn6 = A3*exp(alfak*z3)+B3*exp(-alfak*z3)==(gamma4/(n^2*p^2*sigmac*u0*OMEGA))*(A4*exp(gamma4*z3)-B4*exp(-gamma4*z3));
eqn7 = A3*exp(alfak*z3)-B3*exp(-alfak*z3)==(alfak/(n^2*p^2*sigmac*u0*OMEGA))*(A4*exp(gamma4*z3)+B4*exp(-gamma4*z3));
eqn8 = A4*exp(gamma4*z4)+B4*exp(-gamma4*z4)==(sigmac/sigmab)*(A5*exp(gamma5*z4)+B5*exp(-gamma5*z4));
eqn9 = gamma4*A4*exp(gamma4*z4)-gamma4*B4*exp(-gamma4*z4)==(sigmac/(sigmab*urb))*(gamma5*A5*exp(gamma5*z4)-gamma5*B5*exp(-gamma5*z4));
eqn10 = A5*exp(gamma5*z5)+B5*exp(-gamma5*z5)==0;
sol = solve([eqn1, eqn2, eqn3, eqn4, eqn5, eqn6, eqn7, eqn8, eqn9, eqn10], [A1 B1 A2 B2 A3 B3 A4 B4 A5 B5]);
summeT=summeT+(1i*n*alfak*(besselj(np+1,alfak*R3))^2*(conj(A3)*B3-A3*conj(B3)));
end
end
T=(pi/2)*u0*R3^2*p*real(summeT);
fplot(T)
grid on
2 comentarios
Walter Roberson
el 12 de Mayo de 2020
Are you using https://www.mathworks.com/matlabcentral/fileexchange/48403-bessel-zero-solver for besselzero() ?
Luigi Stragapede
el 12 de Mayo de 2020
Respuesta aceptada
Walter Roberson
el 12 de Mayo de 2020
summeT=summeT+(1i*n*alfak*(besselj(np+1,alfak*R3))^2*(conj(A3)*B3-A3*conj(B3)));
That line is not using A3 and B3 from the solution, which are sol.A3 and sol.B3
7 comentarios
Walter Roberson
el 12 de Mayo de 2020
Note: the code is now Very Slow. Very slow.
Walter Roberson
el 12 de Mayo de 2020
A=(1:2:10); %vector in order to take n odd
summeT=0.0;
for n=A(1):A(length(A))
What is the point of creating A that way, to contain [1 3 5 7 9] ? The only place you use the content of A is in the |for n=A(1):A(length(A)) which is 1:9 without skipping any values -- in which case why not just make A = [1 9] ?
I suspect you should be using
for n=A
to have n iterate over the values stored in A.
Luigi Stragapede
el 12 de Mayo de 2020
Walter Roberson
el 12 de Mayo de 2020
With some adjustments to try to simplify the generated equations:
Q = @(v) sym(v);
V16 = @(v) vpa(v, 16);
a=Q(10e-3);
b=Q(10e-3);
c=Q(5e-3);
d=Q(5e-3);
e=Q(8e-3);
z1=a;
z2=z1+b;
z3=z2+c;
z4=z3+d;
z5=z4+e;
Br=Q(1.25); %T
R1=Q(25e-3);
R2=Q(65e-3);
R3=Q(90e-3);
u0=Q(4)*Q(pi)*Q(1e-7);
urb=Q(1000);
sigmab=Q(7e6); %M=1000000
sigmac=Q(57e6);
syms OMEGA real
alfa=Q(0.9);
p=(4);
%TORQUE T
A=(1:2:10); %vector in order to take n odd
summeT=Q(0.0);
for n=A
for k=1:10
np=n*p;
kind=1;
alfaks = (besselzero(np, k, kind))/R3;
alfak=alfaks(k);
gamma4=sqrt((alfak^2)+1i*np*sigmac*u0*OMEGA);
gamma5=sqrt((alfak^2)+1i*np*sigmab*urb*u0*OMEGA); %devo moltiplicare u0*urb?
syms r; %devo definire la variabile r
Mnksym=((8*Br)/(n*Q(pi)*u0*R3^2*(besselj(np+1,alfak*R3))^2))*sin(n*alfa*Q(pi)/2)*int(r*besselj(np,alfak*r),r,R1,R2);
Mnk=double(Mnksym); %in order to not have 1x1 sym
syms A1 B1 A2 B2 A3 B3 A4 B4 A5 B5 A6 B6 A7 B7 A8 B8 A9 B9 A10 B10;
eqn1 = A1-B1==0;
eqn2 = A1*exp(alfak*z1)+B1*exp(-alfak*z1)==A2*exp(alfak*z1)+B2*exp(-alfak*z1);
eqn3 = A1*exp(alfak*z1)-B1*exp(-alfak*z1)==(1/urb)*(A2*exp(alfak*z1)+B2*exp(-alfak*z1)+(Mnk/alfak));
eqn4 = A2*exp(alfak*z2)+B2*exp(-alfak*z2)==A3*exp(alfak*z2)+B3*exp(-alfak*z2);
eqn5 = A2*exp(alfak*z2)-B2*exp(-alfak*z2)==A3*exp(alfak*z2)-B3*exp(-alfak*z2)+(Mnk/alfak);
eqn6 = A3*exp(alfak*z3)+B3*exp(-alfak*z3)==(gamma4/(n^2*p^2*sigmac*u0*OMEGA))*(A4*exp(gamma4*z3)-B4*exp(-gamma4*z3));
eqn7 = A3*exp(alfak*z3)-B3*exp(-alfak*z3)==(alfak/(n^2*p^2*sigmac*u0*OMEGA))*(A4*exp(gamma4*z3)+B4*exp(-gamma4*z3));
eqn8 = A4*exp(gamma4*z4)+B4*exp(-gamma4*z4)==(sigmac/sigmab)*(A5*exp(gamma5*z4)+B5*exp(-gamma5*z4));
eqn9 = gamma4*A4*exp(gamma4*z4)-gamma4*B4*exp(-gamma4*z4)==(sigmac/(sigmab*urb))*(gamma5*A5*exp(gamma5*z4)-gamma5*B5*exp(-gamma5*z4));
eqn10 = A5*exp(gamma5*z5)+B5*exp(-gamma5*z5)==0;
sol = solve([eqn1, eqn2, eqn3, eqn4, eqn5, eqn6, eqn7, eqn8, eqn9, eqn10], [A1 B1 A2 B2 A3 B3 A4 B4 A5 B5]);
summeT = summeT + V16((1i*n*alfak*(besselj(np+1,alfak*R3))^2*(conj(sol.A3)*sol.B3-sol.A3*conj(sol.B3))));
end
summeT = V16(summeT);
end
T = V16( (Q(pi)/2)*u0*R3^2*p*real(summeT) );
Getting to this point does not take too long.
Notice that the plotting is not present. fplot() can be very slow. It can be a lot more efficient to
OM = V16(0 : .5 : 5);
Y = subs(T, OMEGA, OM);
plot(OM, Y)
When I tested, I got a straight line, but the T equations is clearly non-linear. That could indicate that it just is not obvious that there is a curve in the limited range that I plotted. Even just taking a single derivative takes a long time, so estimating the curve has to be done numerically.
Luigi Stragapede
el 12 de Mayo de 2020
I have to obtain this RED curve:
In particular the range must be from 0 to 209 (in the graph the range is from 0 to 2000 because it is rpm, it only a different scale).
If I reduce the iterations, I obtain more quickly the graph, but I nedd at least 7 iteretions for k and n in order to have an accurate result.
Now I try your code. You are very kind
Luigi Stragapede
el 12 de Mayo de 2020
Walter Roberson
el 12 de Mayo de 2020
I get a quite different plot
OT = [0 0.780189980083088;3 0.755430990896907;6 0.731442157697117;9 0.710036424788487;12 0.684280102527316;15 0.653856319703993;18 0.619574167961039;21 0.58233456579523;24 0.543020606219544;27 0.502475470603902;30 0.461477022475297;33 0.420714176591535;36 0.380771555309333;39 0.342123546085244;42 0.305136241153018;45 0.270075032704127;48 0.237115735452024;51 0.206357475581531;54 0.177836008357966;57 0.151536524675646;60 0.127405347444595;63 0.105360190826173;66 0.0852988590170856;69 0.0671064032686978;72 0.050660846343487;75 0.0358376340058246;78 0.0225129942476625;81 0.0105663861101363;84 -0.000117791338377977;87 -0.00964907745802768;90 -0.01813028456402;93 -0.025657178496177;96 -0.0323184152464476;99 -0.0381956615657892;102 -0.0433638428993567;105 -0.0478914749239129;108 -0.0518410455471591;111 -0.0552694227342512;114 -0.0582282702468524;117 -0.0607644586082755;120 -0.0629204626163232;123 -0.0647347397530944;126 -0.0662420860928605;129 -0.0674739679552964;132 -0.0684588287306016;135 -0.0692223711266604;138 -0.0697878156443812;141 -0.070176136444506;144 -0.0704062759806561;147 -0.0704953398798443;150 -0.0704587735839264;153 -0.0703105222465887;156 -0.0700631753275887;159 -0.0697280972516447;162 -0.0693155454127023;165 -0.0688347767117329;168 -0.0682941437222885;171 -0.0677011814857774;174 -0.0670626858498591;177 -0.0663847841797106;180 -0.0656729991938642;183 -0.0649323066041588;186 -0.0641671871731083;189 -0.0633816737415182;192 -0.0625793937242093;195 -0.0617636075219076;198 -0.0609372432523592;201 -0.0601029281631467;204 -0.0592630170521526;207 -0.0584196179887523;210 -0.0575746155993032];
omega = OT(:,1);
Tval = OT(:,2);
plot(omega, Tval);
The values decrease along a curve, becoming negative at roughly OMEGA=83
Más respuestas (0)
Categorías
Más información sobre Calculus en Centro de ayuda y File Exchange.
el 12 de Mayo de 2020
el 12 de Mayo de 2020
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!
Translated by 
