Goa Board Class 9 Solutions for Physics – Motion (English Medium)
Page No. 100:
Question 1:
An object has moved through a distance. Can it have zero displacement? If yes, support your answer with an example.
Solution:
Yes. An object that has moved through a distance can have zero displacement. Displacement is the shortest distance between the initial and the final position of an object. An object which has covered a distance can have zero displacement if it comes back to its starting point i.e., the initial position.
Consider the following situation. A man is walking along the boundary of a square park of side 20 m (as shown in the following figure). He starts walking from point A and after moving along all the sides of the park (AB, BC, CD, DA), he again comes back to the same point i.e., A.
In this case, the total distance covered by the man is 20 m + 20 m + 20 m + 20 m = 80 m. However, his displacement is zero because the shortest distance between his initial and final position is zero.
Question 2:
A farmer moves along the boundary of a square field of side 10 m in 40 s. What will be the magnitude of displacement of the farmer at the end of 2 minutes 20 seconds from his initial position?
Solution:
The farmer takes 40 s to cover 4 × 10 = 40 m.
In 2 min and 20 s (140 s), he will cover a distance =(40/40) x 140 = 140 m
Therefore, the farmer completes 140/40 =3.5 rounds (3 complete rounds and a half round) of the field in 2 min and 20 s.
That means, after 2 min 20 s, the farmer will be at the opposite end of the starting point.
Now, there can be two extreme cases.
In this case, the farmer will be at the diagonally opposite corner of the field after 2 min 20 s.
Therefore, the displacement will be equal to the diagonal of the field.
Hence, the displacement will be
= 14.14 m
In this case the farmer will be at the middle point of the opposite side of the field after 2 min 20 s.
Therefore, the displacement will be equal to the side of the field, i.e., 10 m.
For any other starting point, the displacement will be between 14.1 m and 10 m.
Concept Insight: – Be careful about considering the cases, as the displacement in both the cases is different.
Question 3:
Which of the following is true for displacement?
(a) It cannot be zero.
(b) Its magnitude is greater than the distance travelled by the object.
Solution:
(a) Not true
Displacement can become zero when the initial and final positions of the object are the same.
Concept Insight – Displacement is always less than or equal to the distance covered.
Page No. 102:
Question 1:
Distinguish between speed and velocity.
Solution:
Speed | Velocity |
Speed is the distance travelled by an object per unit time. It does not have any direction. | Velocity is the displacement of an object per unit time. It has a unique direction. |
Speed is a scalar quantity. | Velocity is a vector quantity. |
The speed of an object can never be negative. At the most, it can become zero. This is because distance travelled can never be negative. | The velocity of an object can be negative, positive, or equal to zero. This is because displacement can take any of these three values. |
Question 2:
Under what condition(s) is the magnitude of average velocity of an object equal to its average speed?
Solution:
Concept Insight – Distance and displacement may or may not be equal to each other.
Question 3:
What does the odometer of an automobile measure?
Solution:
The odometer of an automobile measures the distance covered by an automobile.
Question 4:
What does the path of an object look like when it is in uniform motion?
Solution:
An object having uniform motion has a straight line path.
Question 5:
During an experiment, a signal from a spaceship reached the ground station in five minutes. What was the distance of the spaceship from the ground station? The signal travels at the speed of light, that is, 3×108 ms-1.
Solution:
Time taken by the signal to reach the ground station from the spaceship
= 5 min = 5 × 60 = 300 s
Concept Insight – Convert all the quantities in the same units and then proceed to calculations.
Speed of the signal = 3 × 108 m/s
Distance travelled = Speed × Time taken = 3 × 108 × 300 = 9 × 1010 m
Hence, the distance of the spaceship from the ground station is 9 × 1010 m.
Page No. 103:
Question 1:
Solution:
(i) A body is said to have uniform acceleration if it travels in a straight path in such a way that its velocity changes at a uniform rate, i.e., the velocity of the body increases or decreases by equal amounts in an equal intervals of time. The motion of a freely falling body is an example of uniform acceleration.
(ii) A body is said to have non-uniform acceleration if its velocity changes at a non-uniform rate, i.e., the velocity of the body increases or decreases by unequal amounts in an equal intervals of time. The motion of a car on a crowded city road is an example of non-uniform acceleration.
Question 2:
A bus decreases its speed from 80 km h-1 to 60 km h-1 in 5 s. Find the acceleration of the bus.
Solution:
Question 3:
A train starting from a railway station and moving with uniform acceleration attains a speed 40 km h-1 in 10 minutes. Find its acceleration.
Solution:
Page No. 107:
Question 1:
What is the natureWhat can you say about the motion of an object whose distance-time graph is a straight line parallel to the time axis? of the distance-time graphs for uniform and non-uniform motion of an object?
Solution:
The distance-time graph for uniform motion of an object is a straight line (as shown in the following figure).
Question 2:
What can you say about the motion of an object whose distance-time graph is a straight line parallel to the time axis?
Solution:
When an object is at rest, its distance-time graph is a straight line parallel to the time axis.
Question 3:
What can you say about the motion of an object if its speed-time graph is a straight line parallel to the time axis?
Solution:
Object is moving uniformly.
Question 4:
What is the quantity which is measured by the area occupied below the velocity-time graph?
Solution:
Distance
Let the velocity of the body at time (t) be v.
Area of the shaded region = length × breath
Length = t
Breath = v
Area = vt = velocity × time …(i)
We know,
Distance = Velocity x Time …(ii)
Hence, the area occupied below the velocity-time graph measures the distance covered by the body.
Page No. 109:
Question 1:
A bus starting from rest moves with a uniform acceleration of 0.1 m s-2 for 2 minutes. Find
(a) the speed acquired,
(b) the distance travelled.
Solution:
(a) Initial speed of the bus, u = 0 (since the bus is initially at rest)
Acceleration, a = 0.1 m/s2
Time taken, t = 2 minutes = 120 s
Let v be the final speed acquired by the bus.
(12)2 – (0)2 = 2(0.1) s
So, speed acquired by the bus is 12 m/s.
Distance travelled by the bus is 720 m.
Page No. 110:
Question 2:
A train is travelling at a speed of 90 km h-1. Brakes are applied so as to produce a uniform acceleration of -0.5 m s-2. Find how far the train will go before it is brought to rest.
Solution:
Initial speed of the train, u = 90 km/h = 25 m/s
Final speed of the train, v = 0 (finally the train comes to rest)
Acceleration = -0.5 m s-2
According to third equation of motion:
v 2 = u 2 + 2as
Concept Insight – Wisely choose the equation of motion out of the three, to minimize the calculations.
(0)2 = (25)2 + 2 (-0.5) s
where, s is the distance covered by the train
The train will cover a distance of 625 m before it comes to rest.
Question 3:
A trolley, while going down an inclined plane, has an acceleration of 2 cm s-2. What will be its velocity 3 s after the start?
Solution:
Initial velocity of the trolley, u = 0 (since the trolley was initially at rest)
Acceleration, a = 2 cm s-2 = 0.02 m/s2
Time, t = 3s
According to the first equation of motion:
v = u + at
Concept Insight – Choose the equation of motion wisely out of the three, to minimize the number of steps in calculations.
where, v is the velocity of the trolley after 3s from start
v = 0 + 0.02 × 3 = 0.06 m/s
Hence, the velocity of the trolley after 3s from start is 0.06 m/s.
Question 4:
A racing car has a uniform acceleration of 4 m s-2 . What distance will it cover in 10 s after start?
Solution:
Initial velocity of the racing car, u = 0 (since the racing car is initially at rest)
Acceleration, a = 4 m/s2
Time taken, t = 10 s
According to the second equation of motion:
Concept Insight – Choose the equation of motion wisely out of the three, to minimize the number of steps in calculations.
where, s is the distance covered by the racing car
Hence, the distance covered by the racing car after 10 s from start is 200 m.
Question 5:
A stone is thrown in a vertically upward direction with a velocity of 5 m s -1 . If the acceleration of the stone during its motion is 10 m s-2 in the downward direction, what will be the height attained by the stone and how much time will it take to reach there?
Solution:
Initially, velocity of the stone, u = 5 m/s
Final velocity, v = 0 (since the stone comes to rest when it reaches its maximum height)
Acceleration of the stone, a = acceleration due to gravity, g = 10 m/s2 (in downward direction)
There will be a change in the sign of acceleration because the stone is being thrown upwards.
Acceleration, a = -10 m/s2
Let s be the maximum height attained by the stone in time t.
According to the first equation of motion:
v = u + at
0 = 5 + (-10) t
v 2 = u 2 + 2 as
(0) 2 = (5) 2 + 2(-10) s
Hence, the stone attains a height of 1.25 m in 0.5 s.
Page No. 112:
Question 1:
An athlete completes one round of a circular track of diameter 200 m in 40 s. What will be the distance covered and the displacement at the end of 2 minutes 20 s?
Solution:
Diameter of the circular track, d = 200 m
Radius of the track, r = d/2 = 100 m
Circumference = 2Πr = 2Π(100) = 200Π m
Concept Insight – Circumference of a circle is given by (2 × Π × r) where, r is the radius of the circle and Π = 22/7.
In 40 s, the given athlete covers a distance of 200Π m.
In 1 s, the given athlete covers a distance = 200/40 m
Total distance covered in 140 s =
The athlete covers one round of the circular track in 40 s. This means that after every 40 s, the athlete comes back to his original position. Hence, in 140 s he had completed 3 rounds of the circular track and is taking the fourth round.
Then, the net displacement of the athlete is in 20 s only. In this interval of time, he moves at the opposite end of the initial position. Since displacement is equal to the shortest distance between the initial and final position of the athlete, displacement of the athlete will be equal to the diameter of the circular track.
Displacement of the athlete = 200 m
Distance covered by the athlete in 2 min 20 s is 2200 m and his displacement is 200 m.
Question 2:
Joseph jogs from one end A to the other end B of a straight 300 m road in 2 minutes 30 seconds and then turns around and jogs 100 m back to point C in another 1 minute. What are Joseph’s average speeds and velocities in jogging (a) from A to B and (b) from A to C?
Solution:
(a) From end A to end B
Average velocity = 200/210 = 0.95 m/s
Question 3:
Abdul, while driving to school, computes the average speed for his trip to be 20 km h-1. On his return trip along the same route, there is less traffic and the average speed is 30 km h-1. What is the average speed for Abdul’s trip?
Solution:
Case I: While driving to school
Average speed of Abdul’s trip = 20 km/h
Total distance = Distance travelled to reach school = d
Let total time taken = t1
Total distance = Distance travelled while returning from school = d
Now, total time taken = t2
From equations (i) and (ii)
Question 4:
A motorboat starting from rest on a lake accelerates in a straight line at a constant rate of 3.0 m s-2 for 8.0 s. How far does the boat travel during this time?
Solution:
Initial velocity, u = 0 (since the motor boat is initially at rest)
Acceleration of the motorboat, a = 3 m/s2
Question 5:
A driver of a car travelling at 52 km h-1 applies the brakes and accelerates uniformly in the opposite direction. The car stops in 5 s. Another driver going at 3 km h-1 in another car applies his brakes slowly and stops in 10 s. On the same graph paper, plot the speed versus time graphs for the two cars. Which of the two cars travelled farther after the brakes were applied?
Solution:
For first car:
Initial speed of the car, u1 = 52 km/h =52 x (5/18) = 14.4 m/s
Time taken to stop the car, t1 = 5 s
Final speed of the car becomes zero after 5s of application of brakes.
For second car:
Initial speed of the car, u2 = 3 km/h = 3 x (5/18) = 0.83 m/s
Time taken to stop the car, t2 = 10 s
Final speed of the car becomes zero after 10 s of application of brakes.
Plot of the speed versus time graph for the two cars is shown in the following figure:
= Area of triangle OAB
= ½ x 5 x 14.4 = 36 m
Distance covered by second car = Area under the graph line CD
= Area of triangle OCD
= ½ x 10 x 0.83 = 4.15 m
Area of triangle OAB > Area of triangle OCD
Thus, the distance covered by first car is greater than the distance covered by second car.
Hence, the car travelling with a speed of 52 km/h travelled farther after brakes were applied.
Question 6:
Figure shows the distance-time graph of three objects A, B and C. Study the graph and answer the following questions:
(a) Which of the three is travelling the fastest?
(b) Are all three ever at the same point on the road?
(c) How far has C travelled when B passes A?
(d)How far has B travelled by the time it passes C?
Solution:
(a) Object B
(b) No
(c) 5.714 km
(d) 5.143 km
(b) The distance-time graphs of the three objects A, B and C never meet at a single point. Thus, they are never at the same point on the road.
1 small box = 4/7 km
Initial distance of object C from origin= 16/7 km
Page No. 112:
Question 7:
A ball is gently dropped from a height of 20 m. If its velocity increases uniformly at the rate of 10 ms-2, with what velocity will it strike the ground? After what time will it strike the ground?
Solution:
Distance covered by the ball, s = 20 m
Acceleration, a = 10 m/s2
Initial velocity, u = 0 (since the ball was initially at rest)
Final velocity of the ball with which it strikes the ground, v
According to the third equation of motion:
v 2 = u 2 + 2 as
v 2 = 0 + 2 (10) (20)
v = 20 m/s
Concept Insight – Choose the equation of motion wisely out of the three, to minimize the number of steps in calculations.
The ball will strike the ground with a velocity 20 m/s.
According to the first equation of motion:
v = u + at
20 = 0 + 10 (t)
t = 2s
Hence, the ball will strike the ground after 2s with a velocity of 20 m/s.
Question 8:
(b) Which part of the graph represents uniform motion of the car?
Solution:
Number of squares in the shaded part of the graph = 62
Concept Insight: While counting the number of squares in the shaded part of the graph, the squares which are half or more than half are counted as complete squares but the squares which are less than half are not counted.
On X-axis,
5 squares represent 2 s.
1 square represents 2/5 s.
On Y-axis,
3 squares represent 2 m/s.
1 square represents 2/3 m/s.
So, area of 1 square on the graph = 2/5 s x 2/3 m/s = 4/15 m
Area of the shaded region of the graph = 62 x (4/15) = 1653 m
Therefore, the car travels a distance of 16.53 m in the first 4 seconds.
(b) The uniform motion of the car is represented by the part AB of the graph, which represents constant speed.
Question 9:
State which of the following situations are possible and give an example for each of these:
(a) An object with a constant acceleration but with zero velocity.
(b) An object moving in a certain direction with an acceleration in the perpendicular direction.
Solution:
(a) Possible
When a ball is just released from a height, then it is being acted upon by a constant acceleration equal to the
acceleration due to gravity i.e. 9.8 m/s2 but its initial velocity is zero.
Concept Insight – An object with a constant acceleration but with zero velocity is possible.
When a car is moving in a circular track, its acceleration is perpendicular to its direction of motion at each instant.
Question 10:
An artificial satellite is moving in a circular orbit of radius 42250 km. Calculate its speed if it takes 24 hours to resolve around the Earth?
Solution:
Concept Insight – Circumference of a circle is given by (2 x Π x r) where, r is the radius of the circle and Π = 22/7 = 3.14
Radius of the circular orbit, r = 42250 km
Hence, the speed of the artificial satellite is 3.07 km/s