A-Level AQA Maths Pure Differentiation: A particle is moving such that i

A particle is moving such that its position vector, r metres, at time t seconds, is given by r = e^t ext{cos} ext{i} + e^t ext{sin} ext{j} Show that the magnitude of the acceleration of the particle, a ext{ } ms}^{-2} ext{, is given by} a = 2e^t Fully justify your answer. - AQA - A-Level Maths Pure - Question 17 - 2022 - Paper 2

Question 17

$A-particle-is-moving-such-that-its-position-vector,---r---metres,-at-time---t---seconds,-is-given-by----r-=-e^t--ext{cos}--ext{i}-+-e^t--ext{sin}--ext{j}----Show-that-the-magnitude-of-the-acceleration-of-the-particle,---a--ext{-}-ms}^{-2}--ext{,-is-given-by}----a-=-2e^t----Fully-justify-your-answer.-AQA-A-Level Maths Pure-Question 17-2022-Paper 2.png$

A particle is moving such that its position vector, r metres, at time t seconds, is given by r = e^t ext{cos} ext{i} + e^t ext{sin} ext{j} Show tha... show full transcript

Worked Solution & Example Answer:A particle is moving such that its position vector, r metres, at time t seconds, is given by r = e^t ext{cos} ext{i} + e^t ext{sin} ext{j} Show that the magnitude of the acceleration of the particle, a ext{ } ms}^{-2} ext{, is given by} a = 2e^t Fully justify your answer. - AQA - A-Level Maths Pure - Question 17 - 2022 - Paper 2

Step 1

Find the velocity vector \frac{dr}{dt}

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Answer

To find the velocity vector, we differentiate the position vector with respect to time:

$\frac{dr}{dt} = \frac{d}{dt} \left( e^t \text{cos} ext{i} + e^t \text{sin} ext{j} \right)$

Using the product rule:

$\frac{dr}{dt} = e^t \text{cos} ext{i} + e^t \text{sin} ext{j} + e^t(-\text{sin}) ext{i} + e^t \text{cos} ext{j}$

Simplifying gives:

$v = (e^t \text{cos} + e^t \text{cos}) ext{j} + (e^t \text{sin} - e^t \text{sin}) ext{i}$

Step 2

Find the acceleration vector \frac{d^2r}{dt^2}

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Answer

Next, differentiate the velocity to find the acceleration vector:

$a = \frac{d^2r}{dt^2} = \frac{d}{dt} \left( (e^t \text{cos} - e^t \text{sin}) ext{i} + (e^t \text{sin} + e^t \text{cos}) ext{j} \right)$

Applying the product rule again,

$a = (e^t \text{cos} + e^t \text{sin}) ext{i} + (e^t \text{sin} - e^t \text{cos}) ext{j}$

Step 3

Find the magnitude of the acceleration |a|

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Answer

To find the magnitude of the acceleration, we compute:

$|a| = \sqrt{(2e^t)^2 + (e^t \text{sin})^2}$

This simplifies to:

$|a| = \sqrt{4e^{2t}} = 2e^t$

Hence, we have proved that the magnitude of the acceleration vector is indeed given by:

$a = 2e^t$

Find the velocity vector \frac{dr}{dt}

Find the acceleration vector \frac{d^2r}{dt^2}

Find the magnitude of the acceleration |a|

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