1 problem found
A particle is projected from a point \(O\) on a horizontal plane
with speed \(V\) and at an angle
of elevation \(\alpha\). The vertical plane in which the motion takes place
is perpendicular to two vertical walls, both of height \(h\), at distances
\(a\) and \(b\) from \(O\). Given that the particle just passes over the
walls, find \(\tan\alpha\) in terms of \(a\), \(b\) and \(h\) and
show that
\[
\frac{2V^2} g = \frac {ab} h +\frac{ (a+b)^2 h}{ab} \;.
\]
The heights of the walls are now increased by the same small positive
amount \(\delta h\,\).
A second particle is projected so that it just passes over
both walls, and the new angle and speed of projection
are \(\alpha +\delta \alpha \) and \(V+\delta V\), respectively.
Show that
\[
\sec^2 \alpha \, \delta \alpha \approx \frac {a+b}{ab}\,\delta h \;,
\]
and deduce that \(\delta \alpha >0\,\). Show also that
\(\delta V\) is positive if \(h> ab/(a+b)\) and negative if \(h