Hello Biplob,
I see that you are seeking to understand why the expected results for the phase and amplitude plot do not align with the Bessel function. Here are a few potential issues I found in the code:
- The Fourier transform of variable ‘B’ involves two symbolic variables. By default, function "fourier" determines the independent variable as x and provides a transformation variable w.
- To address this, I recommend using r as a symbolic variable, where “r = (x^2 + y^2)”, as r is treated as a unified value throughout the code and specifying the independent and transformation variable.
syms r w;
FT_B=fourier(B,r,w)
- Similarly, when using the function “ifourier”, I suggest specifying the independent and transformation variable.
IFT_B = ifourier(FT_B * H, w, r);
- Given that z is set to 5000, the transfer function H is a constant. As a result, the inverse Fourier transform would produce another Bessel function, with some scaling factor H.
- This suggests that the amplitude plot would exhibit a null value at the center, displaying a ring distribution, and the phase plot would show all values as null. Therefore, I suspect there might be an issue with the specified transfer function.
- To evaluate the symbolic expression, you can use the "subs" function:
radius=X.^2+Y.^2
subs(IFT_B, r, radius);
For better understanding, kindly refer to the following link:
- fourier: https://www.mathworks.com/help/symbolic/sym.fourier.html
- ifourier: https://www.mathworks.com/help/symbolic/sym.ifourier.html
- subs: https://www.mathworks.com/help/symbolic/subs.html
By following the suggestions, I believe that you can obtain the expected results for the plots. I hope this resolves your query.
Thanks,
Rangesh.
