STEP 1999 Paper 2 Question 11
By Neil Morrison (P1462) on Thursday,
August 3, 2000 - 07:27 pm :
An automated mobile dummy target for gunnery practice is moving
anti-clockwise around the circumference of a large circle of radius R in a
horizontal plane at a constant angular speed w. A shell is fired from O,
the centre of the circle, with initial speed V and angle of elevation a.
Show that if V2 < g R, the no matter what the value of a, or what
vertical plane the shell is fired in, the shell cannot hit the target.
[because, of course, the shell cannot travel R, but I'm giving the whole
question;]
Assume now that V2 > g R and that the shell hits the target
and let b be the angle through which the target rotates between the time
at which the shell is fired and the time of impact. Show that b
satisfies the equation:
g2 b4 - 4w2 V2 b2 + 4R2 w4 = 0
[I got this just by adding the bits up]
Deduce that there are exactly two possible values of b.
[This is the bit I don't get. Why are there two values? The quadric equation
would have to have its middle SP below the b axis or have the other two
SPs both sitting on the b axis. And the former is not possible as the
constant is < 0.]
Let b1 and b2 be the possible values of b
and let P1 and P2 be the corresponding points of impact. By considering
the quantities (b12 + b22) and b12 b22 or
otherwise show that the linear distance between P1 and P2 is
2R sin{[w/g](V2 - R g)1/2}
Neil M
By David Loeffler (P865) on Thursday,
August 3, 2000 - 10:58 pm :
Well, I suppose that the quartic can be regarded as a quadratic in b2.
This will have either two, or zero, positive roots since the constant term is
positive. In fact, it has exactly two, because V2 > g R, so the minimum is
less than the minimum of g2 b4 - 4gb2 rw2 + 4r2 w4 = (gb2 - 2rw2)2 = 0. Thus there are two distinct positive values of b2, giving rise to two
distinct positive (and two negative) roots of the quartic.
Hope this helps.
David
By Neil Morrison (P1462) on Friday,
August 4, 2000 - 10:18 am :
I think I had got to that stage, but I was trying to win the logic battle. But
the problem is it says exactly two possible values. And in your solution, we
have 2 positive and 2 negative, the negative ones (say A and B) can be
regarded as 2p+ A and 2p+ B. The only way I could resolve this is
to show that the "2p+" values end up being equal to the original
positive values, so in effect there are only two distinct solutions.
Thanks anyway
Neil M
By David Loeffler (P865) on Friday,
August 4, 2000 - 01:55 pm :
That would actually be impossible, surely, since p is transcendental? But
the physical situation implies that we're not looking for "position" angles
which are mod 2p, but for the angle the target has actually moved through.
This will not be mod 2p as, for example, 3p would correspond to one
and a half circuits, not to half a circuit. The target won't turn around and
go backwards, so perhaps that is why we can discard the negative solutions.
By Neil Morrison (P1462) on Friday,
August 4, 2000 - 04:43 pm :
But the net position of the target will be the same after 3p as if it had
moved p backwards.
However, I agree that this will not work. It was the only way I
could think of to justify the question. I think its badly
worded.
Neil M