A-Level AQA Maths Pure Differentiation: At time t seconds a particle, P,

At time t seconds a particle, P, has position vector r metres, with respect to a fixed origin, such that $$r = (3t^2 - 5t) i + (8t - t^2) j$$ 14 (a) Find the exact speed of P when t = 2 14 (b) Bella claims that the magnitude of acceleration of P will never be zero - AQA - A-Level Maths Pure - Question 14 - 2020 - Paper 2

Question 14

At-time-t-seconds-a-particle,-P,-has-position-vector-r-metres,-with-respect-to-a-fixed-origin,-such-that--$$r-=-(3t^2---5t)-i-+-(8t---t^2)-j$$--14-(a)-Find-the-exact-speed-of-P-when-t-=-2--14-(b)-Bella-claims-that-the-magnitude-of-acceleration-of-P-will-never-be-zero-AQA-A-Level Maths Pure-Question 14-2020-Paper 2.png

At time t seconds a particle, P, has position vector r metres, with respect to a fixed origin, such that $$r = (3t^2 - 5t) i + (8t - t^2) j$$ 14 (a) Find the exact... show full transcript

Worked Solution & Example Answer:At time t seconds a particle, P, has position vector r metres, with respect to a fixed origin, such that $$r = (3t^2 - 5t) i + (8t - t^2) j$$ 14 (a) Find the exact speed of P when t = 2 14 (b) Bella claims that the magnitude of acceleration of P will never be zero - AQA - A-Level Maths Pure - Question 14 - 2020 - Paper 2

Step 1

Find the exact speed of P when t = 2

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Answer

To find the speed of the particle P, we first need to differentiate the position vector r with respect to time t to get the velocity vector v.

Given, $r = (3t^2 - 5t) i + (8t - t^2) j$

Differentiating:
$v = \frac{dr}{dt} = \left( \frac{d}{dt}(3t^2 - 5t) \right)i + \left( \frac{d}{dt}(8t - t^2) \right)j$
Calculating the derivatives gives:

For the i-component: $\frac{d}{dt}(3t^2 - 5t) = 6t - 5$
For the j-component:
$\frac{d}{dt}(8t - t^2) = 8 - 2t$
Thus, the velocity vector v is: $v = (6t - 5)i + (8 - 2t)j$
Now substituting t = 2: $v = (6(2) - 5)i + (8 - 2(2))j$
Calculating each component: $v = (12 - 5)i + (8 - 4)j$
$v = 7i + 4j$

To find the speed of the particle P, we calculate the magnitude of the velocity vector v:

$\text{Speed} = |v| = \sqrt{(7)^2 + (4)^2} = \sqrt{49 + 16} = \sqrt{65} \approx 8.06 m/s$

Step 2

Determine whether Bella's claim is correct.

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Answer

To find the acceleration vector a, we differentiate the velocity vector v:

Given, $v = (6t - 5)i + (8 - 2t)j$

Differentiating: $a = \frac{dv}{dt} = \left( \frac{d}{dt}(6t - 5) \right)i + \left( \frac{d}{dt}(8 - 2t) \right)j$ Calculating the derivatives gives:

For the i-component: $\frac{d}{dt}(6t - 5) = 6$
For the j-component: $\frac{d}{dt}(8 - 2t) = -2$ Thus, the acceleration vector a is: $a = 6i - 2j$

The magnitude of the acceleration vector a is: $|a| = \sqrt{(6)^2 + (-2)^2} = \sqrt{36 + 4} = \sqrt{40} > 0$

Since the magnitude of the acceleration is a non-zero constant, Bella's claim that the magnitude of acceleration of P will never be zero is correct.

Find the exact speed of P when t = 2

Determine whether Bella's claim is correct.

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