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3.08 Kinematics

Worksheet
Motion in a straight line
1

The position (in metres) of an object along a straight line after t seconds is modelled by: x \left( t \right) = 6 t^{2}

a

State the velocity v \left( t \right) of the object at time t.

b

State whether the following represent the velocity of the object after 4 seconds:

i

x' \left( 4 \right)

ii

v' \left( 4 \right)

iii

x \left( 4 \right)

iv

v \left( 4 \right)

c

Hence, find the velocity of the object after 4 seconds.

2

The position (in metres) of an object along a straight line after t seconds is modelled by: x \left( t \right) = 18 \sqrt{t}

a

Find v \left( t \right), the velocity function.

b

Find the velocity of the object after 9 seconds.

3

An object moves in a straight line, with its position from a point O given by the equation: x \left( t \right) = t^{3} - 4 t^{2} + 5

a

Find v \left( t \right), the velocity function.

b

Find the exact times at which the object changes direction.

c

Sketch a graph of the object's position over time.

d

Find the exact total distance that the object has travelled by the time t = \dfrac{8}{3} units.

4

A particle moves in a straight line and its displacement after t seconds is given by x = 19 t^{2} - 2 t^{3} where x is its displacement in metres.

Let v and a represent its velocity and acceleration at time t respectively.

a

Find an expression for the acceleration a of the particle after t seconds.

b

Find the acceleration of the particle after 4 seconds.

c

State whether the particle is speeding up or slowing down after 4 seconds.

5

The position of a particle in metres relative to a point O along a straight line is given by: x \left( t \right) = t^{3} - 9 t^{2} + 24 t where t is in seconds.

a

Find the velocity of the particle in terms of t.

b

Find the acceleration of the particle in terms of t.

c

Construct a sign diagram for the particle's:

i

Velocity

ii

Acceleration

d

State the values of t where the particle changes direction.

e

At what times is the particle's speed decreasing?

f

At what times is the particle's velocity decreasing?

g

Find the total distance travelled by the particle in the first 5 seconds.

6

The position of a particle relative to a fixed position O along a straight line is shown by the following graph. The particle starts - 17 \text{ m} to the left of the point O.

a

State the times at which the particle is at the point O.

b

For what values of t is the velocity positive?

c

For what values of t is the velocity equal to zero?

1
2
3
4
5
6
7
8
9
10
11
t
-16
-14
-12
-10
-8
-6
-4
-2
2
4
6
x (t)
7

The position in metres of a particle relative to a fixed position O along a straight line is shown by the following graph, where t is in seconds. If the particle is positioned to the right of the point O, then it has positive displacement.

a

State the value of t where the particle is stationary.

b

State the values of t where the particle is moving to the right.

c

How far from the point O does the particle go to the right?

d

Find an expression for x in terms of t.

e

How long does it take to return to the point O?

f

Find the velocity of the particle in terms of t.

g

Find the velocity when t = 3.

1
2
3
4
t
1
2
3
4
x
8

The position in metres of a particle relative to a fixed position O along a straight line is shown by the following graph, along with a tangent line at t = 8, where t is in seconds. If the particle is positioned to the right of the point O, then it has positive displacement.

a

State the position of the particle when.

i

t = 2

ii

t = 12

b

Find the average velocity of the particle from t = 2 and t = 4.

c

Find the instantaneous velocity at t = 8.

2
4
6
8
10
12
14
t
-22
-20
-18
-16
-14
-12
-10
-8
-6
-4
-2
2
4
6
8
x
9

The position of a particle relative to a fixed position O along a straight line is shown by the following graph, along with a tangent line at t = 10, where t is in seconds. If the particle is positioned to the right of the point O, then it has positive displacement.

a

State the initial position of the particle.

b

At what times does the particle return to the point O?

c

In which direction is the particle moving at t = 5?

d

At what time does the particle change from moving left to right?

e

Find the instantaneous velocity of the particle when t = 10.

2
4
6
8
10
12
14
16
t
-12
-10
-8
-6
-4
-2
2
4
6
8
10
x (\text{metres})
10

A particle moves in a straight line. Its velocity (in metres per second), t seconds after passing the origin is given by: v = 2 t^{2} - 10 t Find the exact velocity when the acceleration of the particle is zero.

11

A particle moves in a straight line and its displacement after t seconds is given by x = 12 t - 2 t^{2} where x is its displacement in metres from the starting point. Let v and a represent its velocity and acceleration at time t respectively.

a

Find an equation for the velocity v of the particle after t seconds.

b

After how many seconds t does the particle change its direction of motion?

c

Sketch the graph of displacement against time.

d

Find the displacement of the particle after 9 seconds.

e

Hence find the total distance that the particle has travelled in the first 9 seconds.

12

A particle moves in a straight line, starting from rest at the point O. At time t seconds after leaving O, the speed v of the particle (in \text{m/s}) is given by: v \left( t \right) = \left( 3 t - 2 t^{2}\right)^{2}

a

Find the time t \gt 0 at which the particle instantaneously comes to rest.

b

Determine a \left( 2 \right), the acceleration of the particle after 2 seconds.

c

Describe the motion of the particle.

13

The displacement (in metres) of a body moving along a straight line after t seconds is modelled by: x \left( t \right) = - t^{3} + a t^{2} + b t + 7 The initial velocity of the body is 8 \text{ m/s}. The body is momentarily at rest at t = 2 seconds.

Find the values of a and b.

14

A particle moves in a straight line and its displacement, x \text{ cm}, from a fixed origin point after t seconds is given by the function:

x \left( t \right) = \sin t - \sin t \cos t - 5 t
a

State the initial displacement of the particle.

b

The velocity is the rate at which displacement changes over time. Find an equation for v \left( t \right), in terms of \cos t.

c

Hence find the initial velocity, v \left( 0 \right).

15

The displacement (in metres) of an object along a straight line after t seconds is modelled by x \left( t \right) = 4 t e^{ - 2 t }.

a

Find the velocity function for the object, v \left( t \right).

b

Find the acceleration function for the object, a \left( t \right).

c

Find the object's initial displacement in metres.

d

At what value of t does the object change direction?

e

Find the object's initial acceleration.

f

At what value of t is the object travelling at the greatest speed towards the origin?

Projectile motion
16

A boy throws a ball vertically. The height of the ball h in metres is given by h = 1 + 17 t - 5 t^{2} where t is given in seconds.

a

Find the velocity of the ball after 3 seconds.

b

Find the acceleration due to gravity.

17

A boy throws a ball vertically. The height of the ball h in metres is given by h = 12 + 2 t - 2 t^{2} where t is given in seconds.

a

Find the velocity of the ball after 1 seconds.

b

Find the acceleration due to gravity.

c

At what time, t, will the ball reach its maximum height?

d

How long does it take for the ball to hit the ground?

18

The height in metres of a projectile above level, flat ground is given by h = 9 + 8 t - t^{2}, where t is given in seconds.

a

State the initial height of the projectile.

b

Find the maximum height reached.

c

At what time will the projectile reach the ground?

d

Sketch the graph of the height of the projectile over time.

e

What is the distance covered by the projectile in the first 5 seconds?

19

A boy stands on the edge of a sea-cliff with a height of 48 \text{ m}. He throws a stone off the cliff so that its vertical height above the cliff is given by h = 16 t - 4 t^{2} where t is given in seconds.

a

Find the maximum value of h reached by the stone above the cliff top.

b

Find the time that elapses before the stone hits the ocean below.

c

Find the velocity with which the stone hits the ocean.

Motion graphs
20

A ball moves horizontally in a 30 \text{ m} long tube. Its position from the centre is shown by the following graph:

a

State the difference in displacement of the ball between 12 \text{ s} and 24 \text{ s}.

b

Find the total distance travelled by the ball between 12 \text{ s} and 24 \text{ s}.

4
8
12
16
20
24
t
-12
-9
-6
-3
3
6
9
12
x
21

The graph shows the particle's position against time. Sketch the graph of the particle's velocity against time.

5
10
15
20
t
5
10
15
20
x
22

A particle, P, starts from rest at point O, and its velocity t seconds after it starts moving is modelled by the equation: v = t^{2} \left(9 - t\right) After 9 seconds it comes to rest and stops moving.

a

Find an equation for the acceleration a of the particle after t seconds.

b

At what time 0 \lt t \lt 9 is the velocity of the particle greatest.

c

Find the greatest velocity that the particle obtains in the first 9 seconds.

d

Sketch the graph of the acceleration of the particle over the first 9 seconds on a number plane.

e

State the magnitude of the greatest acceleration that the particle achieves in the first 9 seconds.

23

A particle passes through a hole in a wall. It's displacement from the wall, s, metres at time t seconds after it passes through the hole is given by:s = \dfrac{1}{3} t + \dfrac{1}{9} t^{2} - \dfrac{1}{27} t^{3}In this case, t may be negative.

a

Sketch the graph of s for t \in [-3, 6].

b

Find the velocity of the particle in terms of t.

c

Sketch the graph of \dfrac{d s}{d t} for t \in [-3, 6].

d

The wall is positioned between two points A and B, at which the particle stops and changes direction. How long does it take for the particle to travel from point A before passing through the wall, to point B after passing through the wall?

e

Find the displacement from the wall at point A.

f

Find the displacement from the wall at point B.

g

Find the average velocity between the two points.

Applications
24

A car starts at rest and has a displacement of s \text{ m} in t seconds, where s = \dfrac{1}{6} t^{3} + \dfrac{1}{4} t^{2}.

a

Find the acceleration of the car in terms of t.

b

Find the initial acceleration of the car.

c

Find the acceleration of the car when t = 16.

25

The displacement (in metres) of a particle moving in rectilinear motion after t seconds is modelled by x \left( t \right) = 2 t^{2} - 4 t + 5.

a

Find v \left( t \right), the velocity function.

b

Find the time t at which the particle changes direction.

c

Find a \left( t \right) , the acceleration function.

26

The displacement (in metres) of a body from an origin O at time t seconds is modelled by: x \left( t \right) = t^{2} - 7 t + 5

a

Find the velocity function, v \left( t \right).

b

Find the initial velocity of the body.

c

Find the acceleration function, a \left( t \right).

d

Find the acceleration of the body at t = 8.

e

Find the value(s) of t for which the body has a velocity of 3 \text{ m/s}.

f

Find the value(s) of t for which the body has a speed of 3 \text{ m/s}.

27

The displacement d in metres of a train travelling from Station A to Station B: d = 0.86 t^{2} - 0.0084 t^{3} where t is given in seconds.

a

Write an equation for the velocity of the train in metres per second.

b

Find the time taken to travel between the two stations. Round your answer to the nearest second.

c

Find the distance between the two train stations. Round your answer to the nearest metre.

d

Find the maximum velocity of the train. Round your answer to the nearest m/s.

e

Find the maximum acceleration of the train.

28

An object, P, moves in rectilinear motion such that its displacement x (in metres) from the origin at time t seconds is given by: x \left( t \right) = \left(t + 1\right) \left(4 - t\right) \left(t + 4\right)Its velocity and acceleration at time t are given by x' \left( t \right) and x'' \left( t \right) respectively.

a

Find the time t at which the particle reverses direction.

b

Find the equation for the acceleration of the particle at time t.

c

Find the acceleration when the particle is instantaneously at rest.

d

Find the average velocity of the particle in the first 3 seconds.

29

The following table represents data for a typical driver approaching a red traffic light. At a given speed, the driver must first react and then press the brake. The distance travelled during this period is called the thinking distance. After the brakes are applied, the driver slows down to a stop and covers a distance called the braking distance.

Speed (km/h)Thinking distance (m)Breaking distance (m)
3699
481216
601525
721836
842149
962464
a

Find the thinking time for a driver travelling at 96 \text{ km/h}.

b

The distance s \left( t \right) travelled by an object travelling at an initial speed of u m/s, braking with acceleration a \text{ m/s}^2 is given by s \left( t \right) = u t + \dfrac{1}{2} a t^{2}. Find the derivative of s.

c

Hence find t when a car with initial velocity u comes to rest.

d

Find the braking acceleration (in \text{m/s}^2) for the driver travelling at 96 \text{ km/h}.

30

The displacement of an object is a measure of how far it is from a fixed origin point at time, \\t seconds. Displacement to the left of the origin point is negative and displacement to the right of the origin is positive. At time t seconds, velocity is given by v \left( t \right) = x'(t), and acceleration is given by a \left( t \right) = x''(t).

If the displacement of an object x \text{ cm} about a fixed origin is given by: x \left( t \right) = - 5 \cos 2 t

a

Describe the initial position of the object, from the fixed origin point.

b

Write an expression for v \left( t \right).

c

Show that a \left( t \right) = - 4 x \left( t \right).

d

Find the acceleration of the object, when t = \dfrac{\pi}{2}.

31

The arm of a pendulum swings between its two extreme points A to the left and B to the right. Its horizontal displacement x \text{ cm} from the centre of the swing, at time t seconds after it starts swinging, is given by:

x \left( t \right) = 16 \sin 3 \pi t
a

Find the intial position of the pendulum.

b

Find the maximum distance of the pendulum from the central position of its swing.

c

Find an expression for the velocity function, v \left( t \right)= x'\left( t \right).

d

Find the first two times at which the pendulum comes to rest, v \left( t \right)= 0 .

e

Find the displacement of the pendulum when it first comes to rest.

f

Find the displacement of the pendulum when it comes to rest for the second time.

g

Hence determine the distance between the two points A and B.

32

The arm of a pendulum swings between its two extreme points A to the left and B to the right. Its horizontal displacement x \text{ cm} from the centre of the swing at time t seconds after it starts swinging is given by:

x \left( t \right) = 19 \sin 4 \pi t
a

Find an expression for the velocity function, v \left( t \right)=x'\left( t \right).

b

Find the maximum velocity of the pendulum.

c

Find the first two times, after it starts swinging, at which the pendulum reaches its maximum speed, v' \left( t \right) = 0 and x' \left( t \right) < 0 .

d

Describe the position of the pendulum when it reaches its maximum velocity.

33

The displacement of a particle moving in rectilinear motion is given by: x \left( t \right) = \left(t - 2\right)^{2} + \sin \left(t - 4 \pi\right) + 3 t + 25

a

State the initial displacement of the particle.

b

Write an expression for the velocity of the particle, v \left( t \right) = x' \left( t \right) .

c

Write an expression for the acceleration of the particle, a \left( t \right) = v' \left( t \right).

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Outcomes

3.1.4

use exponential functions and their derivatives to solve practical problem

3.1.6

use trigonometric functions and their derivatives to solve practical problems

3.1.9

apply the product, quotient and chain rule to differentiate functions such as xe^x, tan⁡x,1/x^n, x sin⁡x, e^(−x)sin⁡x and f(ax-b)

3.1.12

identify acceleration as the second derivative of position with respect to time

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