Things are quite right to me, although I wouldn't use the symbol `j`

as a variable because (as `i`

does) it is the symbol for the imaginary unit (`sqrt(-1)`

). Doing so you are overriding it, thus things will work until you don't need complex numbers.

You should use element-wise operations such as (`.*`

) when you aim at combining arrays entries element by element, as you correctly did to obtain `F(\theta)`

. In fact, `cos(theta)`

is the array of the cosines of the angles contained in `theta`

and so on.

Finally, you can rotate the plot using the command `Rotate 3D`

in the plot window. Nonetheless, you have a 2D curve (`F(\theta)`

) therefore, you will keep on rotating a 2D graph obtaining some kind of *perspective view* of it, nothing more. To obtain genuine information you need an additional dependent variable (Or I misunderstood your question?).

**EDIT:** Now I see your point, you want the *Surface of revolution* around some axis, which I suppose by virtue of the symmetry therein to be `theta=0`

. Well, revolution surfaces can be obtained by a bit of analytic geometry and plotted e.g. by using `mesh`

. Check this out:

```
% // 2D polar coordinate radius (your j)
Rad= (cos(theta)+1).*(besselj(1,const*sin(theta))./(const*sin(theta)));
Rad = abs(Rad); % // We need its absolute value for sake of clarity
xv = Rad .* cos(theta); % // 2D Cartesian coordinates
yv = Rad .* sin(theta); % // 2D Cartesian coordinates
phi = -pi:.01:pi; % // 3D revolution angle around theta = 0
% // 3D points of the surface
xf = repmat(xv',size(phi));
yf = yv' * cos(phi);
zf = yv' * sin(phi);
mesh(xf,yf,zf)
```

You can also add graphics effects

this is done via

```
mesh(xf,yf,zf,'FaceColor','interp','FaceLighting','phong')
camlight right
```

and a finer angular discretization `(1e-3)`

.