The shell moves with velocity $\vec{u}$ towards the plane. Upon explosion, fragments are emitted with speed $v$ in all directions relative to the center of mass (CM). The velocity of any fragment in the laboratory frame is: $$ \vec{V}_{lab} = \vec{u} + \vec{v}_{rel} $$

If $v < u$, the fragments are confined within a cone. The maximum angle $\theta_{max}$ that a fragment's path makes with the central axis (normal to the plane) is determined by the condition where the relative velocity vector is tangent to the circle of possible velocities.

From the velocity vector triangle (Figure 3, Left), the maximum semi-vertical angle $\theta$ of the cone is given by:

$$ \sin \theta = \frac{v}{u} $$

The fragments travel in straight lines from the point of explosion (distance $l$ from the plane). The area on the plane is a circle of radius $r$:

$$ r = l \tan \theta $$

Using the trigonometric identity $\tan \theta = \frac{\sin \theta}{\sqrt{1 – \sin^2 \theta}}$:

$$ \tan \theta = \frac{v/u}{\sqrt{1 – (v/u)^2}} = \frac{v/u}{\sqrt{\frac{u^2 – v^2}{u^2}}} = \frac{v}{\sqrt{u^2 – v^2}} $$

Thus, the radius of the circle is:

$$ r = \frac{vl}{\sqrt{u^2 – v^2}} $$