changing the scale on the Y axis
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Good evening sir
Sir I need -1 to 1 on Y-axis but i got this on X-axis. Now I request you please help me how to getting -1 to 1 on Y-axis. I attached my code and graph relating to my code.
Code:
xmesh1 = linspace(-1,0,10);
xmesh2 = linspace(0,1,10);
xmesh = [xmesh1,xmesh2];
yinit = [0 1 0 1 0 1 0 1];
init = bvpinit(xmesh,yinit);
sol = bvp5c(@f, @bc, init);
plot(sol.x,sol.y(2,:),'b-o',sol.x,sol.y(3 ,:),'r-o')
%line([1 1], [0 1], 'Color', 'k')
% legend('y1','y3')
% % title('A Three-Point BVP Solved with bvp5c')
% xlabel({'x', '\lambda = 2, \kappa = 5'})
% ylabel('v(x) and C(x)')
hold on
function dydx = f(x,y,region) % equations being solved
W=1;alpha=1;M=2;k1=1;k2=1;k3=1;k4=1;k=1; Ps=1;Po=1;R1=0;R2=2;
omega=1;
us = y(1);
usy = y(2);
uo = y(3);
u0y = y(4);
thetas = y(5);
thetasy = y(6);
thetao = y(7);
thetaoy = y(8);
dydx = zeros(8,1);
switch region
case 1 % x in [-1 0]
dydx(1) = usy;
dydx(2) = (M^2 + 1/k2)*us - alpha*Ps*R2;
dydx(3) = u0y;
dydx(4) = (M^2 + 1/k1 + 1i*omega*R2)*uo - alpha*Po*R2; % 1/K2 ?
dydx(5) = thetasy+thetas;
dydx(6) = k1*usy^2;
dydx(7) = thetaoy;
dydx(8) = k*thetao - k3*thetasy*thetaoy;
case 2 % x in [0 1]
dydx(1) = usy;
dydx(2) = (M^2 + 1/k1)*us - Ps*R1;
dydx(3) = u0y;
dydx(4) = (M^2 + 1/k1 + 1i*omega*R1)*uo - Po*R1;
dydx(5) = thetasy;
dydx(6) = k2*usy^2;
dydx(7) = thetaoy;
dydx(8) = k*thetao - k4*thetasy*thetaoy;
end
end
function res = bc(YL,YR)
mu1=1; mu2=1; k1=1; k2=1;
res = [YL(1,1)
YL(3,1)
YL(5,1)
YL(7,1)
YR(1,2)-1
YR(3,2)-1
YR(5,2)-1
YR(7,2)
YR(1,1)-YL(1,2)
mu1*YR(2,1)-mu2*YL(2,2)
YR(3,1)-YL(3,2)
mu1*YR(4,1)-mu2*YL(4,2)
YR(5,1)-YL(5,2)
k1*YR(6,1)-k2*YL(6,2)
YR(7,1)-YL(7,2)
k1*YR(8,1)-k2*YL(8,2)];
end
The graph relating to code is
But I need the -1 to 1 range on Y-axis like the following graph:
7 Comments
Torsten
on 11 Jul 2024
What is u, what is y and what is R_I in your code ?
mallela ankamma rao
on 11 Jul 2024
These are the equations relating to code sir
So y is the independent variable x in your code. But what function is plotted and which parameter is varied ?
Once you have found this, you can simply plot independent and dependent variables reversed:
plot(sol.y(2,:),sol.x,'b-o',sol.y(3,:),sol.x,'r-o')
instead of
plot(sol.x,sol.y(2,:),'b-o',sol.x,sol.y(3 ,:),'r-o')
But note that the solutions are complex-valued; thus it is only possible to plot abs(sol.y), real(sol.y) or imag(sol.y).
mallela ankamma rao
on 11 Jul 2024
Moved: Torsten
on 11 Jul 2024
Thank you Mr Torsten sir.I got the below graph sir 
But the graphs are reversed. I need graphs like the following graph sir and X range is 0 to 1 sir. Please Give me some suggestions sir.
But the graphs are reversed. I need graphs like the following graph sir and X range is 0 to 1 sir. Please Give me some suggestions sir.
If you know that your sol.y(2,:) and sol.y(3,:) are plotted in the article (real or imaginary part or absolute value) and your plot is different, then there must be something different in your code compared to the code that the authors used. So the only advice I can give is to compare your code to the mathematical equations.
mallela ankamma rao
on 12 Jul 2024
mallela ankamma rao
on 12 Jul 2024
Answers (2)
ScottB
on 11 Jul 2024
ylim([-1 1]);
y_values = [-1:0.2:1];
ha = gca;
set(ha, 'ytick', y_values);
yticklabels('manual');
yticklabels(y_values);
1 Comment
mallela ankamma rao
on 11 Jul 2024
Mr. Pavl M.
on 21 Nov 2024
Edited: Mr. Pavl M.
on 21 Nov 2024
xmesh1 = linspace(-1,0,10);
xmesh2 = linspace(0,1,10);
xmesh = [xmesh1,xmesh2];
yinit = [0 1 0 1 0 1 0 1];
init = bvpinit(xmesh,yinit);
sol = bvp5c(@f, @bc, init)
figure
plot(-abs(sol.y(2,:)),sol.x,'b-o',-abs(sol.y(3,:)),sol.x,'r-o')
ylim([-1 1]);
y_values = [-1:0.2:1];
ha = gca;
set(ha, 'ytick', y_values);
yticklabels('manual');
yticklabels(y_values);
%line([1 1], [0 1], 'Color', 'k')
% legend('y1','y3')
title('A Three-Point 8 values BVP Solved with bvp5c')
xlabel('u')
ylabel('y')
% xlabel({'x', '\lambda = 2, \kappa = 5'})
% ylabel('v(x) and C(x)')
function dydx = f(x,y,region) % equations being solved
W=1;alpha=1;M=2;k1=1;k2=1;k3=1;k4=1;k=1; Ps=1;Po=1;R1=0;R2=2;
omega=1;
us = y(1);
usy = y(2);
uo = y(3);
u0y = y(4);
thetas = y(5);
thetasy = y(6);
thetao = y(7);
thetaoy = y(8);
dydx = zeros(8,1);
switch region
case 1 % x in [-1 0]
dydx(1) = usy;
dydx(2) = (M^2 + 1/k2)*us - alpha*Ps*R2;
dydx(3) = u0y;
dydx(4) = (M^2 + 1/k1 + 1i*omega*R2)*uo - alpha*Po*R2; % 1/K2 ?
dydx(5) = thetasy+thetas;
dydx(6) = k1*usy^2;
dydx(7) = thetaoy;
dydx(8) = k*thetao - k3*thetasy*thetaoy;
case 2 % x in [0 1]
dydx(1) = usy;
dydx(2) = (M^2 + 1/k1)*us - Ps*R1;
dydx(3) = u0y;
dydx(4) = (M^2 + 1/k1 + 1i*omega*R1)*uo - Po*R1;
dydx(5) = thetasy;
dydx(6) = k2*usy^2;
dydx(7) = thetaoy;
dydx(8) = k*thetao - k4*thetasy*thetaoy;
end
end
function res = bc(YL,YR)
mu1=1; mu2=1; k1=1; k2=1;
res = [YL(1,1)
YL(3,1)
YL(5,1)
YL(7,1)
YR(1,2)-1
YR(3,2)-1
YR(5,2)-1
YR(7,2)
YR(1,1)-YL(1,2)
mu1*YR(2,1)-mu2*YL(2,2)
YR(3,1)-YL(3,2)
mu1*YR(4,1)-mu2*YL(4,2)
YR(5,1)-YL(5,2)
k1*YR(6,1)-k2*YL(6,2)
YR(7,1)-YL(7,2)
k1*YR(8,1)-k2*YL(8,2)];
end
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