Problem: 1.11
Two particles move in a uniform gravitational field with an acceleration \(g\). At the initial moment the particles were located at one point and moved with velocities \({v_1} = 3m/s\) and \({v_2} = 4m/s\) horizontally in opposite directions. Find the distance between the particles at the moment when their velocity vectors becomes mutually perpendicular.
Solution: 1.11
Here the two particle that was shot with \({v_1} = 3m/s\) and the one that was shot with \({v_2} = 4m/s\). Since \({v_1}\) and \({v_2}\) are supposed to be in opposite directions, we choose \({v_1}\) as the positive directions and \({v_2}\) as the negative direction. Further, we imagine that gravity acting downward is the negative direction.
Since, gravity acts vertically downwards, it does not effect the horizontal components of velocities. However both the particle accelerate at equal rates of \(g\) downwards from zero initial velocity component in downward direction.
The velocity of first particle after time \(t\) is given by \(\left( {{v_1}\hat i - gt\hat j} \right)\) and that second particle is given by \(\left( {{-
v_2}\hat i - gt\hat j} \right)\).
When the two velocity vectors are perpendicular to each other, the dot product of the vectors will be zero.
That is,
\(\left( {{v_1}\hat i - gt\hat j} \right).\left( { - {v_2}\hat i - gt\hat j} \right) = 0\)
Or, \(\left( { - {v_1}{v_2} + {g^2}{t^2}} \right) = 0\)
Or, \(\left( { - 12 + 100{t^2}} \right) = 0\)
Or, \(t = \sqrt {0.12} \)
The vertical distance traveled by the two particle will be identical, thus at any time \(t\) the distance between the two particles is only a function of the horizontal components of their positions is given by \(\left( {{v_1} + {v_2}} \right)t\).
Thus the distance between the two particles when their velocity vectors are mutually perpendicular are given by,
\( = \left( {{v_1} + {v_2}} \right) \times t = 7 \times \sqrt {0.12} = 2.5m\)
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