Hi @Tina Hsiao,
When working with data, continuous data is typically represented by using finer discrete data points. To create a quiver plot that aligns with your use case, you might find the following sample code useful, as it effectively simulates continuous data, in this code, the following steps are undertaken:
- A finer grid is defined by generating more granular data points.
- Use “interp2” for interpolation of gradient data over this newly established grid.
- The interpolated vector field is then visualized using the “quiver” function.
v = 0:25:300;
[x, y] = meshgrid(v);
z = -cos(x).*(-x.^2 - y.^2) * 1e-4;
[px, py] = gradient(z);
% Continuous points
v_fine = 0:1:300; % Create a finer grid
[x_fine, y_fine] = meshgrid(v_fine);
% Interpolate the vector field
px_fine = interp2(x, y, px, x_fine, y_fine, 'cubic');
py_fine = interp2(x, y, py, x_fine, y_fine, 'cubic');
% Plot the continuous vector field
figure(2)
quiver(x_fine, y_fine, px_fine, py_fine)
title('Continuous Vector Field')
xlabel('x')
ylabel('y')
You can explore the “interp2” and “quiver” function’s documentation for a better understanding of the same.
