MOTION
If we look around us, we find that there are number of objects which are in motion. An object is said to be in motion if it change its position with the passage of time. In other words, the movement of an object is known as the motion of the object.
Now observe the following bodies or objects and we will be able to understand the meaning of the term "motion". Cars, cycles, motorcycles, scooters, buses, rickshaws, trucks etc. running on the road, Birds flying in the sky, Fish swimming in water. All these objects are in motion. Very small objects like atoms and molecules and very large objects like planets, stars and galaxies are in motion.
Thus, all objects ranging from a smallest atom to the largest galaxy are in continuous motion.
Types of Motion :
(A) Linear motion : A body has linear motion if it moves in a straight line or path.
Ex.
(i) Motion of a moving car on a straight road.
(ii) Motion of a ball dropped from the roof of a building.
(B) Circular (or rotational) Motion : A body has circular motion if it moves around a fixed point.
A vertical passing through the fixed point around which the body moves is known as axis of rotation.
Ex.
(i) Motion of an electric fan.
(ii) Motion of merry-go-round
(iii) Motion of a spinning top.
(C) Vibratory motion :
A body has vibratory motion if it moves to and fro about a fixed point.
Ex. (i) Motion of a pendulum of a wall clock.
(ii) Motion of a simple pendulum.
MOTION IN LIVING AND NON-LIVING OBJECTS :
It is a common observation that all living objects, whether plants or animals can move in some way or the other. The motion in animals is more apparent than the motion in plants.
The motion in animals is called LOCOMOTION.
Plants also move but their motion is not apparent as they cannot move from place to place. Their motion takes place in parts. As a plant grows so does its roots and its leaves.
MECHANICS :
The branch of physics which deals with the motion of non-living objects in everyday life is called mechanics or Classical mechanics. It is of two types.
i) Statics and (ii) Dynamics
STATICS : Statics deals with bodies at rest under the effect of different forces.
DYNAMICS : Dynamics deals with the bodies in motion. It is further of two types :
(i) Kinematics : Kinematics, which is derives from a Greek word kinema meaning motion,is a branch of Physics, which deals with the motion of a body without taking into account the cause of motion.
(ii) Dynamics proper : Dynamics proper, which is derived from a Greek word dyna meaning power it is a branch of Physics, which deals with the motion of bodies by taking into account the cause of motion (force).
Concept of a point object, Rest and motion
Point object : An extended object can be treated as a point object when the distance travelled by the object is much greater than its own size.
"A point object is one, which has no linear dimensions but possesses mass."
Ex.
(i) Study of motion of a train travelling from Kota to New Delhi.
(ii) Revolution of earth around the sun for one complete revolution.
Rest :– A body is said to be at rest when its position does not change with time respect to the observer.
Motion :– A body is said to be in motion when its position changes with time respect to the observer.
Describe motion :
When a tree, is observed by an observer A sitting on a bench, the tree is at rest. This is because position of the tree is not changing with respect to the observer A.
Now, When the same tree T is observed by an observer sitting in a superfast train moving with a velocity n, then the tree is moving with respect to the observer because the position of tree is changing with respect to the observer B.
Rest and motion are relative terms : There is nothing like absolute rest. This means that an object can be at rest and also in motion at the same time i.e. all objects, which are stationary on earth, are said to be at rest with respect to each other, but with respect to the sun are making revolutions at 30 kmh–1. In order to study motion, therefore, we have to choose a fixed position or point with respect to which the motion has to be studied. Such a point or fixed position is called a reference point or the origin. In order to describe the motion of an object we need to keep in mind three things;
(i) The distance of the body from a reference point. This reference point is called the origin of the motion of the body.
(ii) The direction of motion of the body.
(iii) The time of motion.
Scalar and vector quantities
Scalar Quantity :– A quantity that has only magnitude no direction is called a scalar quantity.
Ex. mass, time, distance, speed, work, power, energy, charge, area, volume, density, pressure, potential, temperature etc.
Vector Quantity :– The physical quantity that has magnitude as well as direction are called vector quantity.
Ex.velocity, acceleration, force, displacement, momentum, weight, electric field etc.
Differece between scalar & vector quantities :
Scalar quantities | Vector quantities | |
1 | These are completely specified by their magnitude only. | These are completely specified by their magnitude as well as direction |
2 | These change by change of their magnitude only | These change by change of either their magnitude or direction or both |
3 | These are added or subtracted by laws of ordinary algebra like 4m+5m=9m. |
These are added or subtracted by laws of vector addition. |
DISTANCE AND DISPLACEMENT
Distance : The length of the actual path between the initial and the final position of a moving object in the given time interval is known as the distance travelled by the object.
Distance = Length of path I (ACB)
Distance is a scalar quantity.
Unit In SI system : metre (m)
In CGS system : centimetre (cm)
Large unit Kilometre (km)
Displacement:– The shortest distance between the initial position and the final position of a moving object in the given interval of time from initial to the final position of the object is known as the displacement of the object.
Displacement of an object may also be defined as the change in position of the object in a particular direction. That is,
Displacement of an object = Final position – Initial position of the object.
Displacement of an object may be zero but the distance travelled by the object in never zero.
Distance travelled by an object is either equal or greater than the magnitude of displacement of the object.
Displacement = Length of path II (AB) A to B,
displacement is vector quantities.
Units In SI system : metre (m)
In CGS system : centimetre (cm)
Ex. A train goes from station A to station B as shown in figure. Calculate
(i) the distance travelled by the train and
(ii) the magnitude of the displacement of the train on reaching station B.
Sol. (i) Distance travelled by the train = 50 100 200 400 = 750 km.
(ii) Magnitude of the displacement in going from station A to station B = 400 km.
DIFFERENCES BETWEEN DISTANCE AND DISPLACEMENT |
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Distance |
Displacement |
|
1 |
It is defined as the actual path traversed by a body. |
It is the shortest distance between two points which the body moves. |
2 |
It is a scalar quantity |
It is a vector quantity' |
3 |
It can never be negative or zero |
It can be negative, zero or positive. |
|
|
|
4 |
Distance can be equal to or greater than displacement |
Displacement can be equal to or less than distance. |
5 |
Distance travelled is not a unique path between two points. |
Displacement is a unique path between two points. |
6 |
The distance between two points gives full information of the type of path followed by the body. |
Displacement between two points does not give full information of the type of path followed by the body. |
' |
Distance never decreases with tune, for a moving body it is never zero. |
Displacement can decrease with time for a moving body it canbe zero. |
S |
Distance in SI is measured in metre |
Displacement in SI is measured in metre. |
Distance > |displacement|
Uniform and non-uniform motion
A moving body may cover equal distances in equal intervals of time or different distances in equal intervals of time. On the basis of above assumption, the motion of a body can be classified as uniform motion and non-uniform motion.
Uniform motion:
Time Cm second) |
0 |
1 |
2 |
3 |
4 |
5 |
6 |
Distance covered (in metre) |
0 |
10 |
20 |
30 |
40 |
50 |
60 |
When a body covers equal distances in equal intervals of time, however, small may be time intervals, the body is said to describe a uniform motion.
Example of uniform motion –
(i) An aeroplane flying at a speed of 600 km/h
(ii) A train running at a speed of 120 km/h
(iii) Light energy travelling at a speed of 3 × 108 m/s
(iv) A spaceship moving at a speed of 100 km/s
Non-uniform motion:
Time (in second) |
0 |
1 |
2 |
3 |
4 |
Distance (in metre) |
0 |
1 |
4 |
9 |
16 |
When a body covers unequal distances in equal intervals of time, the body is said to be moving with a non-uniform motion.
Example of non-uniform motion –
(i) An aeroplane running on a runway before taking off.
(ii) A freely falling stone under the action of gravity.
(iii) An object thrown vertically upward.
(iv) When the brakes are applied to a moving car.
Speed
Speed of a body is the distance travelled by the body per unit time. or The rate of change of motion is called speed.
(speed = (distance travelled / time taken))
If a body covers a distance S in time t then speed,
(v = S/t)
Unit : In SI system : m/s or ms–1
In CGS system : cm/s or cms–1
Other km/h or kmh–1
Important note : While comparing the speed of different bodies we must convert all speeds into same units. Speed is a scalar quantity, because it has the magnitude but no direction.
Uniform speed :- When a body covers equal distance in equal intervals of time, the body is to be moving with a uniform speed or constant speed.
Ex.
(i) A train running with a speed of 120 km/h
(ii) An aeroplane flying with a speed of 600 km/h
Non-uniform speed :- When a body covers unequal distances in equal intervals of time, the body is said to be moving with non-uniform speed or variable speed.
Ex.
(i) A car running on busy road.
(ii) An aeroplane landing on runway.
Average speed :- The average speed of the body in a given time interval is defined as the total distance travelled, divided by the time interval.
Ex. A car travels first half distance with a uniform u and next half distance travels with a uniform speed v. Find its average speed.
Sol. Total distances = + = d
Total time = t1 + t2 = t
t1 = ...(i)
t2 = ...(ii)
Vav = Putting the value of equation (i) and (ii)
Vav = = =
Ex. A car travels first half time with a uniform speed u and next half time with a uniform speed v. Find its average speed.
Sol.
Total distances d = +
d =
Total time = T
Average speed =
Vav = =
Instantaneous speed
The speed of a body at any particular instant of time during its motion is called the instantaneous speed of the body.
It is measured by speedometer in vehicles.
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Comment : It can be very easily argued that
(a) The relative speed between two bodies A and B moving in the same direction with speed |VA| and |VB| i.e.
|Vsame| = difference in the speeds of two bodies A and B = |VA| |VB| or |VB| |VA| ... (A)
depending upon the fact whether |VA| > |VB| or |VB| > |VA|
(b) The relative speed between the two bodies A and B moving in the opposite direction with speed |VA| and |VB| i.e.
|Vopposite| = sum of the speed of the two bodies A and B = |VA| + |VB| ... (B)
It should be carefully noted that equation A and B are valid only for one-dimensional motion and not in two and three dimension motion.
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Velocity
The velocity of a body is the displacement of a body per unit time.
The displacement covered by a body per unit time or the speed of a body in specified direction is called the velocity.
Unit: In SI system : m/s or ms_1
In CGS system : cm/s or cms_1
Other km/h or kmh_1, km/min.
Uniform velocity
When a body covers equal displacement in equal interval of time, the body is said to be moving with a uniform velocity.
Conditions for uniform velocity :_
(i) The body must cover equal displacement in equal intervals of time.
(ii) The direction of motion of the body should not change.
Ex. (i) A train running towards south with a speed of 120 km/h.
(ii) A aeroplane flying due north-east with a speed of 600 km/h.
Very important note :_
Direction of velocity represent direction of motion of body.
OR
Sign of velocity represent the direction of motion of body.
Non-uniform velocity/variable velocity :
When a body covers unequal displacement in equal intervals of time, the body is said to be moving with variable velocity.
When a body covers equal distance in equal intervals of time, but its direction changes, then the body is said to be moving with variable velocity.
Conditions for variable velocity :_
(i) It should cover unequal displacement in equal intervals of time.
(ii) It should cover equal distances in equal intervals of time but its direction must change.
Ex. (i) A car running towards north on a busy road has a variable velocity as the displacement covered by it per unit time changes with change in the road condition.
(ii) The blades of a rotating ceiling fan, a person running around a circular track with constant speed etc. are the example of variable velocity, as the direction of the moving body changes in each case.
Average velocity :
Total displacement divided by total time is called an average velocity.
Vav =
OR
The arithmetic mean of initial velocity and final velocity for a given time period, is called average velocity.
vav = where u = initial velocity, v = final velocity
Memorise : When a body moves with constnat velocity, the average velocity is equal to instantaneous velocity. The body is said to be in uniform motion.
Difference between Speed and Velocity:
Speed | Velocity |
It is defined as the rate of change of distance | It is the shortest distance between two points between which the body moves. |
It is a scalar quantity | It is a vector quantity |
It can never be negative or zero | It can be negative, zero or positive |
Speed is velocity without direction. | Velocity is directed speed |
Speed may or may not be equal to velocity. | A body mass possess different velocities but the same speed. |
Speed never decreases with time. For a moving body it is never zero. |
Velocity can decrease with time. For a moving body it can be zero. |
Speed in SI is measured in ms–1 | Velocity in SI, is measured in ms–1. |
Acceleration
The rate of change of velocity of a moving body with time is called acceleration.
but change in velocity = final velocity - initial velocity.
If body moves with uniform velocity, then v = u and then acceleration is zero i.e. a = o.
Unit of accelration
Acceleration = , Acceleration = , Acceleration = = m/s2
In SI system is m/s2 or ms-2
In CGS system is cm/s2 or cms-2
Positive Acceleration : If the velocity of an object increases with time in the direction of the motion of the object, then the acceleratin of the body is known as positive acceleration.
In this case, the object pick up the speed in a particular direction (i.e., velocity). For example, if an object starts from rest and its velocity goes on increasing with time in the direction of its motion, then the object has positive acceleration. The direction of positive acceleration is in the direction of motion of the object.
Negative Acceleration : If the velocity of an object decreases with time, then the acceleration of the object is known as negative acceleration.
It is written as -
For example, if an object moving with certain velocity is brought to rest then the object is said to have negative acceleration.
Acceleration without changing speed :
When an object moves in a circular path with constant speed, then its velocity changes due to the change in the direction of motion of the object. hence, the object is accelerated without changing its speed.
In this case, the direction of acceleration is towards the centre of the circular path.
Uniform acceleration :
When a body undergoes equal changes in velocity in equal intervals of time, the body is said to be moving with a uniform acceleration
Ex. (i) Motion of a freely falling body.
(ii) Motion of a ball rolling down on an inclined plane.
Non-uniform acceleration or variable acceleration :
When a body describes unequal change in velocity in equal intervals of time, the body is said to be moving with non-uniform acceleration.
Ex. (i) The motion of a bus leaving or entering the bus stop.
(ii) The motion of a train leaving or entering the platform.
(iii) A car moving on a busy road has non-uniform acceleration.
Equations of uniformly accelerated motion
These equations give relationship between initial velocity, final velocity, time taken, acceleration and distnace travelled by the bodies.
First equation of motion :
A body having an initial velocity 'u' acted upon by a uniform acceleration 'a' for time 't' such that final velocity of the body is 'v'.
Acceleration = Acceleration =
a = v _ u = at
Where ; v = final velocity of the body u = initial velocity of the body
a = Acceleration t = time taken
Second equation of motion :
It gives the distance travelled by a body in time t.
A body having an initial velocity 'u' acted upon by a uniform acceleration 'a' for time 't' such that final velocity of the body is 'v' and the distance covered is 's'.
The average velocity is given by :-
Average velocity = Vav =
distance covered = average velocity × time s = × t
but v = u + at (from first equation of motion)
Thus, s = × t = × t
Where ; s = distance travelled by the body in time t
u = initial velocity of the body
a = Acceleration
t = time taken
Third equation of motion :
A body having an initial velocity 'u' moving with a uniform acceleration 'a' for time 't' such that final velocity 'v' and the distance covered is 's'. the third equation of motion is v2 = u2 + 2 at. it gives the velocity acquired by a body in travelling a distance s.
v = u + at .....(i)
s = ut + .....(ii)
Squaring eq. (i), we have
v2 = (u + at)2
v2 = u2 + 2uat + a2t2
v2 = u2 + 2a .....(iii)
Substituting the value of eq (ii) in eq.(iii), we get.
Ncert questions with solution
Important note:_
Velocity in m/s = × velocity in km/h.
36 km h_1 = 36000 m h_1
= ms_1 = 10 ms_1
1 km h_1 = or 1 km h_1 =
To convert km h_1 to ms_1, multiply by 5/18.
To convert ms_1 to km h_1 , multiply by 18/5.
1 km = 1000 m
1m = 100 cm = 1000 mm
· Distance in kilometres should be converted into metre.
· Before solving problems, asure that the data provided have the same system of unit, i.e. either they should be in SI system or CGS system.
· If a body start from rest, its initial velocity (u) is zero, (u =0)
· If a moving body comes to rest/stops, its final velocity (v) is zero, (v =0)
· If a body is moving with uniform velocity, its acceleration is zero, (a =0)
Graphical representation of motion
Graph :
A graph is a line, straight line or curved, showing the relation between two variable quantities of which one varies as a result of the change in the other.
The quantity which changes independently is called independent variable and the one which changes as a result of the change in the other is called dependent variable.
Plotting a graph :
Uses of graph :
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Distance/Displacement-Time graph :
This graph is plotted between the time taken and the distance covered, the time is taken along the x-axis and the distance covered is taken along the y-axis.
Speed =
When the body is at rest :
When position of the body does not change with time then it is said to be stationary, the distance-time graph of such a body is a straight line parallel to x-axis.
distance-time graph for a stationary body.
When the body is in uniform speed:
When the position of the body changes by equal intervals of time then body is said to be moving with uniform speed. The distance-time graph of such a body is a straight line, inclined to x-axis.
Slope =
Slope =
= velocity V = Δx/Δt OR (distance/ time)= speed
Special case-I
In uniform motion along a straight line the position x of the body at any time t is related to the constant velocity as,
xA = vt Starting form zero
xB = x0 + vt starting from x0
Special case-II
Slope of line A = tanqA = tan0 (Q qA = 0)
= zero velocity
Slope of line B = tanθB = positive velocity
Slope of line C = tanθc = more positive velocity
θC > θB (tanθC > θB )
Then vC > vB
Slope of line D = tan (_ θD) = negative velocity.
When the body is in motion with a non-uniform (variable) speed.
Distance-Time graph for a body moving with non-unifrom speed.
The position-time graph is not a straight line, but is a curve.
The speed of the body at any point is known as instantaneous speed and can be calculated by finding the slope at that point.
So instantaneous speed of the body at point A.
Slope at point A = tanqA =
instantaneous speed of the body at point B
Slope at point B = tanqB =
qB > qA so slope at point B is greater than the slope at point A.
Hence speed of body at point B is a greater than, the speed of body at point A.
When the speed decreases with passage of time:
Slope at point A > slope at point B (θA > θB)
So, speed at point A > speed at point B
Important note : A distance time graph can never be parallel to y-axis (representing distance) because this line has slope of 90° and slope = tanq = tan90° = infinite, which means infinite speed. It is impossible.
Acceleration from displacement-time graph.
For line A : A straight line displacement-time graph represents a
uniform velocity and zero acceleration
for line B : A curved displacement-time graph rising upward represents an increasing velocity and positive acceleration
For line C : A curved displacement-time graph falling downwards, represents a decreasing velocity and negative acceleration.
Velocity-time graph :
The variation in velocity with time for an object moving in a straight line can be represented by a velocity-time graph. In this graph, time is represented along the x-axis and velocity is represented along the y-axis.
Acceleration = (speed or velocity/ time)
hence the slope of the speed/velocity-time graph, gives the acceleration of the body.
Distance = speed × time
hence, area enclosed between the speed-time graph line and x-axis (time axis) gives the distance covered by the body. Similarly area enclosed between the velocity-time graph line and the x-axis (time axis) gives the displacement of the body.
Note: Since the graph takes into account, only the magnitude hence velocity-time graph is not different from speed-time graph.
When the body is moving with constant velocity :
When the body moves with constant velocity i.e. its motion is uniform.
The speed or velocity of the body is uniform hence the magnitude remains same. The graph is a straight line parallel to x-axis (time-axis). Since the velocity is uniform. Its acceleration is zero. The slope of the graph in this case is zero.
Conclusion : Velocity-time graph of a body moving with constant velocity is a straight line parallel to time axis.
When the body is moving with a uniform acceleration.
Time
The speed or velocity is changing by equal amounts in equal interval of time, the speed or velocity time graph of such a body is a straight line inclined to x-axis (time-axis).
When the body is moving with a non-uniform (variable) acceleration.
The speed or velocity-time graph is not a straight line but is a curve.
The line has different slopes at different times, its acceleration is variable. At point A, slope is less hence acceleratoin is less. At point B slope is more hence acceleration is more.
Note: Speed or velocity-time graph line can never be paralled to y-axis (speed axis), because slope angle becomes 90° than tan90° is infinite it is impossible.
Distance or displacement from speed or velocity-time graph.
As distance or displacement = speed or velocity x time, hence the distance or displacement can be calculated from speed or velocity-time graph.
When speed or velocity is uniform (constant)
Distance/displacement = Area of rectangle ABCD = AB × AD
Thus, We find that the area enclosed by velocity-time graph and the time axis gives the distance travelled by the body.
When acceleration is uniform (constant)
distance or displacement = area of right triangle OAB =
When speed or velocity as well as acceleration is non-uniform (variable).
The speed-time graph of a body moving irregularly with variable speed and acceleration. For a small interval of time Dt, as there is not much change in speed, hence the speed can be taken as constant.
For this small time interval.
Distance Ds = vDt = Area of the blackened strip.
For whole time interval between t1 and t2, distance = sum of areas of all the strips, between t1 and t2 = area of shaded figure ABCD.
Application of Velocity- time Graphs :
A number of useful results can be deduced from velocity time graph.
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Graphical represantation of equation of motion :
Represents a velocity-time graph BC, in which AB represents the initial velocity u, CE represents final velocity v, such that the change in velocity is represented by CD, which takes place in time t, represented by AE.
Derivation of v = u + at
Acceleration = slope of the graph line BC.
a = = OR a =
v _ u = at
Derivation of s = ut + 1/2at2
Distance travelled = Area of trapezium ABCE
= Area of rectangle ABDE + Area of triangle BCD
= AB × AE + (BD × CD) = t × u + [t × (v_u)]
Q v = u + at = u × t + [t × (u + at _ u)]
Derivation of v2= u2+2as
From the velocity-time graph distance covered = Area of trapezium ABCE
Þ S = (AB + CE) × AE S = (u + v) × t ...(i)
Acceleration =
a = t = ...(ii)
Substituting the value of t in eq (i)
S = Q A2 _ B2 = (A + B) × (A _ B)
S =
v2 _ u2 = 2as
Circular motion
Motion of a particle (small body)along a circle (circular path), is called circular motion.
If the body covers equal distances along the circumference of the circle, in equal intervals of time, then motion is said to be a uniform circular motion. When a body moves along a circular path, then its direction of motion changes continuously.
Note: A uniform circular motion is a motion in which speed remain constant but direction of velocity changes continuously.
Examples of uniform circular motion are:
(i) Motion of moon around the earth.
(ii) Motion of a satellite around its planet.
(iii) Motion of earth around the sun.
(iv) An athlete running on a circular track with constant speed.
(v) Motion of tips of the second hand, minute hand and hour hand of a wrist watch.
Difference between a uniform linear motion and a uniform circular motion.
Uniform linear motion | Uniform circular motion |
The direction of motion does not change. | The direction of motion changes continuously |
The motion is non-accelerated | The motion is accelerated |
RADIAN
It is a convenient unit for measuring angles in physics.
The arc AB of the circle, has length l and subtends an angle q at the centre C.
If = q radians
Then q = q =
when l = r then q = 1 radian.
One radian is defined as the angle subtended at the centre of the circle by an arc which is equal in length to its radius.
Angle subtended by the circumference at the centre.
q = = 2p radians 2p radians = 360° 1 radian =
Angular displacement and angular velocity :
The angle covered by a body in 1 sec. is called angular velocity.
It is usually denoted by w and measured in radian per sec.
If q is the angle covered in time 't' then :
Angular velocity =
Unit Angular displacement = q (in radian)
Angular velocity w
Þ Þ rad/s
Relation between linear velocity and angular velocity.
Linear displacement = l
Angular displacement = q
q =
l = rq
for a time inervals t
Linear velocity v =
Angular velocity
w =
Higher order thinking skill
Projectile's Motion
A projectile is an object moving in space (or air) under the effect of gravitational effect of earth alone (without any other external force) is called the projectile motion and the object is caled the projectile.
The examples of projectile are missile shot from a gun, a bomb released from an airplane, a batted cricket ball, a ball thrown at some angle with horizontal and a rocket after its fuel is exhausted.
The motion of a projectile may always be resolved into two perpendicular straight line motions, viz, horizontal and vertical motions. These motions in perpendicular directions are quite independent of each other.
Path of Projectile :-
Consider a body is projected with velocity , making an angle q, point of projection O as the origin the axis OX and OY being horizontal and vertical directions respectively. The initial velocity may be resolved into horizontal and vertical components.
Horizontal Component ux = u cos q
Vertical Component uy = u sin q
The trajectory of the projectile is parabolic.
Time of flight T :-
The time in which the porjectile again meets the horizontal plane is called the time of flight. The net vertical displacement of projectile in time of flight is zero (i.e. y = 0) ; therefore, time of flight (T) of projectile from the relation s = ut + at2 is given by :-
Maximum height H :-
At maximum height vertical component of projectile's velocity is zero, i.e., vy = 0
from relation v2 = u2 + 2 as, we have
This equation shows that the height H is maximum when sin q = 1 or q = . That is why the athlete in high jump tries to throw his body vertically upward.
Range of Projectile :-
The horizontal distance traversed by the projectile in time of flight T is called the range of projectile.
Range R = horizontal speed × time of flight = ux T
(∵ sin 2θ = 2 sin θ cos θ)
For maximum range sin 2θ = 1 or 2θ = 90° or θ = 45°
and the maximum range,
Obviously the maximum range is achieved when angle of projection is 45°.
1. What is motion? |
2. What is the difference between speed and velocity? |
3. What is Newton's First Law of Motion? |
4. What is the formula for calculating acceleration? |
5. What is the difference between distance and displacement? |
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