I want to draw graph between "P" and "x" but it is throwing the following error.

4 views (last 30 days)
syms x
alpha = -0.1;
sigma = 0.1;
eps = -0.1;
lambda = 2;
M = 4;
psi = 0.1;
a = 2;
figure
A = eps + alpha^3 + (3 * sigma^2 * alpha);
B = alpha^2 + sigma^2;
hbar = @(x) a - a.*x + x;
a1 = @(x) tanh(M .* hbar(x));
b1 = @(x) 1 - (tanh(M .* hbar(x))).^2;
c1 = (M * alpha) - ((M^3 * A)/3);
d1 = @(x) (hbar(x) .* a1(x)) + (hbar(x) .* b1(x) .* c1) + (alpha * a1(x)) + (M * B .* b1(x));
e1 = @(x) ((hbar(x).^3) .* a1(x)) + ((hbar(x).^3) .* (1 - a1(x)) .* c1) + (A *a1(x)) + (3 .* (hbar(x).^2) .*alpha .* a1(x)) + (3 .* (hbar(x).^2) .* M * B) - (3 .* (hbar(x).^2) .* M * B .* a1(x)) + (3 .* hbar(x) .*B .* a1(x)) + (3 .* hbar(x) .* b1(x) .* M * A );
f1 = 2 * (M^2) * (1 + lambda);
g1 = @(x) (3 * lambda * d1(x)) + (f1 * e1(x)) - (3 *lambda *M * B);
g2 = @(x) f1 * (a1(x) + b1(x) .* c1);
G = @(x) (1/ (2 + lambda)) .* g1(x) .* (1./g2(x));
j1 = psi/(1 + lambda);
i1 = @(x) 0.5 .* hbar(x) .* (G(x) + j1).^(-1);
I1 = @(x) integral(i1,0,x);
i2 = @(x) (G(x) + j1) .^(-1);
I2 = @(x) integral(i2,0,x);
I3 = integral(i1,0,1);
I4 = integral(i2,0,1);
D = I3 / I4;
P = @(x) I1(x) + (D * I2(x));
ylim([0 0.5])
xlim([0 1])
fplot(P(x), [1 6])
Error using integral
Limits of integration must be double or single scalars.

Error in solution (line 27)
I1 = @(x) integral(i1,0,x);

Error in solution (line 37)
P = @(x) I1(x) + (D * I2(x));

Accepted Answer

Star Strider
Star Strider on 7 Jul 2022
The ‘x’ value is being used as an integration llimit, and integration limits must be scalars.
One solution is to devine the ‘x’ value as a vector, and then use arrayfun (essentially a for loop) to do the integration over the vector of limits —
% syms x
alpha = -0.1;
sigma = 0.1;
eps = -0.1;
lambda = 2;
M = 4;
psi = 0.1;
a = 2;
figure
A = eps + alpha^3 + (3 * sigma^2 * alpha);
B = alpha^2 + sigma^2;
hbar = @(x) a - a.*x + x;
a1 = @(x) tanh(M .* hbar(x));
b1 = @(x) 1 - (tanh(M .* hbar(x))).^2;
c1 = (M * alpha) - ((M^3 * A)/3);
d1 = @(x) (hbar(x) .* a1(x)) + (hbar(x) .* b1(x) .* c1) + (alpha * a1(x)) + (M * B .* b1(x));
e1 = @(x) ((hbar(x).^3) .* a1(x)) + ((hbar(x).^3) .* (1 - a1(x)) .* c1) + (A *a1(x)) + (3 .* (hbar(x).^2) .*alpha .* a1(x)) + (3 .* (hbar(x).^2) .* M * B) - (3 .* (hbar(x).^2) .* M * B .* a1(x)) + (3 .* hbar(x) .*B .* a1(x)) + (3 .* hbar(x) .* b1(x) .* M * A );
f1 = 2 * (M^2) * (1 + lambda);
g1 = @(x) (3 * lambda * d1(x)) + (f1 * e1(x)) - (3 *lambda *M * B);
g2 = @(x) f1 * (a1(x) + b1(x) .* c1);
G = @(x) (1/ (2 + lambda)) .* g1(x) .* (1./g2(x));
j1 = psi/(1 + lambda);
i1 = @(x) 0.5 .* hbar(x) .* (G(x) + j1).^(-1);
I1 = @(x) integral(i1,0,x);
i2 = @(x) (G(x) + j1) .^(-1);
I2 = @(x) integral(i2,0,x);
I3 = integral(i1,0,1);
I4 = integral(i2,0,1);
D = I3 / I4;
P = @(x) I1(x) + (D * I2(x));
xv = linspace(1, 6, 25);
Pv = arrayfun(@(x)P(x), xv);
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 3.6e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.6e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.7e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 2.1e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 2.1e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 8.9e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 3.8e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 2.1e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 9.0e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.6e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 3.3e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 3.1e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.7e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.9e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 3.2e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.4e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 2.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 8.9e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 2.6e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.1e+01. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 1.8e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
Warning: Reached the limit on the maximum number of intervals in use. Approximate bound on error is 7.7e+00. The integral may not exist, or it may be difficult to approximate numerically to the requested accuracy.
figure
plot(xv, Pv)
% ylim([0 0.5]) % There Is Nothing To Be Plotted In This Region!
% xlim([0 1]) % There Is Nothing To Be Plotted In This Region!
xlabel('x')
ylabel('P(x)')
.

More Answers (1)

Jan
Jan on 7 Jul 2022
Try:
fplot(P, [1 6]) % not P(x)

Categories

Find more on Mathematics in Help Center and File Exchange

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!