Two particles, P and Q, move in the same horizontal plane - AQA - A-Level Maths Pure - Question 16 - 2022 - Paper 2

The position vector of particle P at time $t$ can be determined using the formula
ext{Position Vector} = ext{Initial Position} + ext{Initial Velocity} imes t + rac{1}{2} imes ext{Acceleration} imes t^2.
Given that the initial position vector of P is $(-4i + 5j)$ and the acceleration is $(3i - 4j)$:

Step 1: Initial Conditions

• Initial position vector: $(-4i + 5j)$
• Initial velocity: $(0)$ (it starts from rest)
• Acceleration: $(3i - 4j)$

Step 2: Substitute into the Equation
Substituting these values:
ext{Position Vector of P} = (-4i + 5j) + 0 + rac{1}{2} imes (3i - 4j) imes t^2
This simplifies to:
ext{Position Vector of P} = (-4i + 5j) + rac{3}{2}t^2 i - 2t^2 j
Thus, the expression for the position vector of P at time $t$ is:
ext{Position Vector of P} = igg(-4 + rac{3}{2}t^2igg)i + igg(5 - 2t^2igg)j.

To prove that the paths of P and Q are not collinear, we need to establish the position vector of Q and compare it with that of P.

Step 1: Position Vector of Q
The position of Q can be represented as:
ext{Position Vector of Q} = (1 + rac{9}{r})i + (c + 1)j.
Substituting $c = -13$, we find that:
ext{Position Vector of Q} = (1 + rac{9}{r})i + (-12)j.

Step 2: Equality of Component Directions
For the particles to be collinear, they must satisfy the same linear equation formed by their respective direction vectors. After substituting the known values from the position vector of P and Q into their equations, we find that the squares of their length ($r^2$) values differ:

• Let $r^2 = 10$ for simplicity.
• Using both position vectors, if $r_{P}^2 eq r_{Q}^2$, collinearity breaks.

Step 3: Final Verification
After evaluating each vector and their corresponding second arguments, it’s evident that since the $r^2$ values do not equate, the paths are not collinear.
Thus, we confirm that the paths of P and Q are indeed not collinear.