How do I fix "Index in position 2 exceeds array bounds (must not exceed 1)."
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clc;
clear;
close all;
%% Data
% Define the parameters
qe = 1;
n = 5e16;
p = 0.525;
E_0 = 10e3;
v_s = 3.5e3;
epsilon_d = 50;
ue = 1;
m0 = 9.1094e-31;
m = 0.44 * m0;
epsilon_0 = 1;
h = 4.1356e-15;
hBar = h / (2 * pi);
b = 0.142e-9;
a = 3 * b / (2 * hBar);
tt = 2.6;
delta = 5.7 / 2;
G = sqrt(delta^2 + 5 * tt^2);
% Define the range for ω_p and B^(-1)
omega_p = linspace(0, 10, 150);
B_inv = linspace(0.04, 1, 150);
k_q = omega_p / v_s;
v = (-2 * tt^2 * a * sin(p * a) / G);
tau = ue * p / (qe * v);
tau_1 = tau / 2;
omega_c = qe * B_inv' * v / p;
gamma = 1 + 1i * omega_c * tau_1;
sigma_g = qe^2 * n * v * tau / p;
Six = p^2 / (2 * pi * hBar^2);
Rix = 2 * p / m / v;
b_g = 2 * pi * hBar^2 * epsilon_0 * v / (qe^2 * p);
beta_g = (k_q' .* v) ./ omega_c;
% Initialize the result matrix
j_x = zeros(numel(omega_p), numel(B_inv));
% Calculate sigma_xx
sigma_xx = zeros(numel(omega_p), numel(B_inv));
for r = -3:3
J_r = besselj(r, beta_g);
sigma_xx = sigma_xx + (2 * sigma_g' * J_r) ./ (1 - 1i * (omega_p' - r * omega_c) * tau);
end
% Calculate R_x
R_x = zeros(numel(omega_p), numel(B_inv));
for r = -3:3
J_r = besselj(r, beta_g);
R_x = R_x + (omega_c' ./ k_q) .* (J_r .^ 2) ./ (1 - 1i * (omega_p' - r * omega_c) * tau);
end
% Calculate g(omega_q, k_q)
g_omega_q_k_q = 1 + 1i / (epsilon_0 * (epsilon_d + 1)) * (sigma_xx ./ (v_s - R_x));
% Calculate the equation for each combination of omega_p and B^-1
for i = 1:numel(omega_p)
for j = 1:numel(B_inv)
sum_term = 0;
for r = -1:1
J_r = besselj(r, beta_g(i));
sum_term = sum_term + J_r / (1 - 1i * (omega_p(i) - r * omega_c(j)) * tau);
end
j_x(i, j) = (1 / (2 * qe * n * v(i))) * ((tau * omega_c(j) * p^2) / (8 * pi * (hBar^2))) * (abs((sigma_g(i, j) * E_0) / g_omega_q_k_q(i, j)))^2 ...
* ((1 / beta_g(i)) / (1 + (omega_c(j)^2 * tau_1^2)))^2 * (sum_term) ...
* (-1i * gamma(i, j)^2 * (sum_term + 1) * besselj(sum_term + 1, beta_g(i)) + 1i * conj(gamma(i, j))^2 * (sum_term - 1) * besselj(sum_term - 1, beta_g(i)));
end
end
% Plot the results
[Omega_P, B_inv] = meshgrid(omega_p, B_inv);
surf(Omega_P, B_inv, j_x);
xlabel('\omega_p');
ylabel('B^{-1}');
zlabel('j_x');
title('Plot of j_x against \omega_p and B^{-1}');
title('Plot of j_x against \omega_p and B^{-1}');
Accepted Answer
Before entering the loop after which the error message pops up, type
size(gamma)
size(sigma_g)
size(g_omega_q_k_q)
and check whether the second dimension of these arrays is really >= numel(B_inv) as required because of the following loop.
9 Comments
Samuel Suakye
on 11 Jul 2023
Did you fix the error with the arrays mentionned ? The second dimension of all these arrays is 1 in your code from above. And since I don't know how you modified the code, I cannot give you advice concerning the aforementionned new (or persistent) error.
Samuel Suakye
on 11 Jul 2023
Samuel Suakye
on 11 Jul 2023
Like this ? "gamma" still has a wrong 2nd dimension and sigma_g has a wrong 1st dimension.
clc;
clear;
close all;
%% Data
% Define the parameters
qe = 1;
n = 5e16;
p = 0.525;
E_0 = 10e3;
v_s = 3.5e3;
epsilon_d = 50;
ue = 1;
m0 = 9.1094e-31;
m = 0.44 * m0;
epsilon_0 = 1;
h = 4.1356e-15;
hBar = h / (2 * pi);
b = 0.142e-9;
a = 3 * b / (2 * hBar);
tt = 2.6;
delta = 5.7 / 2;
G = sqrt(delta^2 + 5 * tt^2);
% Define the range for ω_p and B^(-1)
omega_p = linspace(0, 10, 150);
B_inv = linspace(0.04, 1, 150);
k_q = omega_p / v_s;
v = (-2 * tt^2 * a * sin(p * a) / G);
tau = ue * p / (qe * v);
tau_1 = tau / 2;
omega_c = qe * B_inv' * v / p;
gamma = 1 + 1i * omega_c * tau_1;
sigma_g = qe^2 * n * v * tau / p;
Six = p^2 / (2 * pi * hBar^2);
Rix = 2 * p / m / v;
b_g = 2 * pi * hBar^2 * epsilon_0 * v / (qe^2 * p);
beta_g = (k_q' .* v) ./ omega_c;
% Initialize the result matrix
j_x = zeros(numel(omega_p), numel(B_inv));
% Calculate sigma_xx
sigma_xx = zeros(numel(omega_p), numel(B_inv));
for r = -3:3
J_r = besselj(r, beta_g);
sigma_xx = sigma_xx + (2 * sigma_g' * J_r) ./ (1 - 1i * (omega_p' - r * omega_c) * tau);
end
% Calculate R_x
R_x = zeros(numel(omega_p), numel(B_inv));
for r = -3:3
J_r = besselj(r, beta_g);
R_x = R_x + (omega_c' ./ k_q) .* (J_r .^ 2) ./ (1 - 1i * (omega_p' - r * omega_c) * tau);
end
% Calculate g(omega_q, k_q)
g_omega_q_k_q = 1 + 1i / (epsilon_0 * (epsilon_d + 1)) * (sigma_xx ./ (v_s - R_x));
% Adjust dimensions of gamma and sigma_g
gamma = repmat(1 + 1i * omega_c * tau_1, numel(omega_p), 1);
sigma_g = repmat(qe^2 * n * v * tau / p, 1, numel(B_inv));
% Calculate the equation for each combination of omega_p and B^-1
size(gamma)
size(sigma_g)
size(g_omega_q_k_q)
numel(B_inv)
numel(omega_p)
for i = 1:numel(omega_p)
for j = 1:numel(B_inv)
sum_term = 0;
for r = -1:1
J_r = besselj(r, beta_g(i));
sum_term = sum_term + J_r / (1 - 1i * (omega_p(i) - r * omega_c(j)) * tau);
end
j_x(i, j) = (1 / (2 * qe * n * v(i))) * ((tau * omega_c(j) * p^2) / (8 * pi * (hBar^2))) * (abs((sigma_g(i, j) * E_0) / g_omega_q_k_q(i, j)))^2 ...
* ((1 / beta_g(i)) / (1 + (omega_c(j)^2 * tau_1^2)))^2 * (sum_term) ...
* (-1i * gamma(i, j)^2 * (sum_term + 1) * besselj(sum_term + 1, beta_g(i)) + 1i * conj(gamma(i, j))^2 * (sum_term - 1) * besselj(sum_term - 1, beta_g(i)));
end
end
Index in position 2 exceeds array bounds. Index must not exceed 1.
% Plot the results
[Omega_P, B_inv] = meshgrid(omega_p, B_inv);
surf(Omega_P, B_inv, j_x);
xlabel('\omega_p');
ylabel('B^{-1}');
zlabel('j_x');
title('Plot of j_x against \omega_p and B^{-1}');
title('Plot of j_x against \omega_p and B^{-1}');
Samuel Suakye
on 11 Jul 2023
Samuel Suakye
on 11 Jul 2023
Torsten
on 11 Jul 2023
There is no trick. You have to know what you want to calculate.
Samuel Suakye
on 11 Jul 2023
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