Speed of Moving Objects - Examples and Formula
An object is said to be moving only when it changes its position. Therefore, a moving object is characterized by its position, its direction of motion, and its direction of movement.
Let’s consider a block of mass, ‘m’ kept on the table.
(Image to be added soon)
Now, if we give it a push, it starts moving in the direction of force.
Newton's first law states that if an external force is applied to this block, it changes its position or sets into motion.
Before learning about the Speed of moving projects, let us discuss moving objects.
Moving Objects
When an object changes its position, we can say it is moving.
We can characterize a moving object based on its direction of motion, movement, and position.
If we give this object a push, it starts to move in the force we push it.
Newton's First Law is applied here. It states that if an external force is applied to this block, it will change its position or set into particular Motion.
Motion Can Be Found In Many Real-life Objects
We can find it in objects like:
A ball thrown upward
A flying aeroplane
The falling of the dust particles on the floor mat.
Running animals
An electron moving in a direction perpendicular to the magnetic field.
Types of Motion
There are several types of Motion. Let us look at these different types in detail.
Rectilinear Motion: It is a body's motion along the straight line.
IMAGE
Periodic Motion: A body's motion repeats after a fixed time interval.
One example is, Planets revolving around the sun in a fixed interval of time.
This Motion can also be referred to as simple harmonic motion.
IMAGE
Circular Motion: A body's Motion in a uniform circular locus towards the center of the circle is its circular Motion.
One example is when we tie a stone to a string and apply even a little force to the string. The stone starts rotating at a fixed point.
IMAGE
Examples Of Moving Objects
Motion can be of various types, some of them are discussed with examples below:
Rectilinear Motion: Motion of a body along the straight line.
(Image to be added soon)
Periodic Motion: The motion repeated after a fixed interval of time.
(Image to be added soon)
The revolution of planets around the sun in a fixed interval of time.
Such a motion is also called the simple harmonic motion.
Circular Motion: A body follows a circular locus such that the force required to move a body uniformly in a circle acts along the radius and towards the center of the circle. With continuous change in the direction of motion of the body, there is a change in velocity of the body and hence, it undergoes an apparent acceleration called the centripetal acceleration. For example, when a stone is tied to a string and on applying the force, the stone starts rotating about a fixed point.
(Image to be added soon)
What Is The Speed of Moving Objects?
The rate at which an object changes its position is called its Speed.
We can define the a body's Speed as:
s = Distance travelled/ time taken
Speed is a scalar quantity because it has a magnitude, but the direction of a body is unknown.
If we take a body with the mass of 'm' and push it with force 'F,' it changes its position because of Speed.
In terms of the SI system, we measure it in meters per second, while in the cgs system, we measure it in cm/s.
We can understand this with an example,
If we take a vehicle and its Speed is constant, we can calculate its constant Speed.
This will mean that if it is in a uniform motion, we will cover equal distances in equal interviews of time.
But suppose that the same body covers an equal distance in equal intervals of time and vice versa, no matter how small the intervals are. In that case, we can calculate such variations in Speed by calculating an average speed.
The Average Speed = Vₐᵥ = Total distance travelled/Total time taken = 2 v₁v₂/(v₁+v₂) m/s
Take an example of a path in which a body starts moving from a point to reach another point.
Here we can observe the distance between two points during the time t represented by a vector drawn from the initial to the final position.
What Is The Velocity of a Moving Object?
Taking displacement into consideration, the shortest distance to reach this destination would be:
A body will move from A to reach B in time, ‘t.’
Here, we observe the distance between these two points in time t and we can represent this by a vector drawn from the starting to the ending position.
If we take displacement into consideration, it will be the shortest distance to reach that certain destination.
So, we will calculate velocity by,
V = Displacement/ time taken (in m/s) = ΔX/Δ t = (X₂ - X₁)/(t₂ - t₁) m/s
A body in a circular motion will move with a constant velocity. The velocity vector will keep on changing this time.
(Image to be added soon)
A body moving 5 m/s north is a vector.
Then it moves 5 m/s west , with the same speed moves to the south and then to the west.
Here, the magnitude (speed) is the same while the direction is changing.
So, that’s why velocity is a vector quantity.
Slow and Fast Motion
Whether the body is moving slow or fast can be determined by measuring the relative velocity of both objects and comparing them to each other. We can define it as the rate at which the relative position of an object changes concerning each other.
(Image to be added soon)
If we take the example of a train and a car, both moving in the same direction. We can imagine that the car driver would be able to see the train passing it. This tells us that the train is in a fast motion.
But at the same time, the passenger in that train would observe the car and see that it was slow, which would tell us that the car is in slow motion.
Both the car and the train are moving here, but they have different velocities. By this, we understand that:
Here, these two vehicles (the train and the car) are moving with separate velocities.
Let us take the velocity of the train as v₁ and the car's as v₂.
The relative velocity of train in comparison to the car’s velocity, even when they are moving in the same direction, will be represented by:
v = (v₁ - v₂)
Hence, v₁ is greater than v₂ and v's value is positive.
By this we conclude that:
We can observe Slow Motion in the car's movement with respect to the train as it is moving at a slower speed.
Fast Motion can be observed in the train's movement concerning the car as it moves faster.
FAQs on Speed of Moving Objects
1. What is speed and how is it different from velocity?
Speed is a scalar quantity that describes 'how fast an object is moving'. It is defined as the rate at which an object covers a certain distance. The key difference is that speed only has magnitude (e.g., 50 km/h), while velocity is a vector quantity, meaning it has both magnitude and direction (e.g., 50 km/h, North).
2. How do you calculate the speed of a moving object using its formula?
To calculate the speed of a moving object, you divide the total distance the object has travelled by the total time it took to cover that distance. The formula is expressed as:
Speed = Total Distance / Total Time
The standard SI unit for speed is metres per second (m/s).
3. What are the main types of speed, with real-world examples?
The motion of an object can be described using four main types of speed:
- Uniform Speed: This is when an object travels equal distances in equal intervals of time. For example, a train moving at a constant 80 km/h on a straight track.
- Variable Speed: This occurs when an object travels unequal distances in equal time intervals. An example is a person jogging in a park who speeds up and slows down.
- Average Speed: This is the overall speed for a whole journey, calculated as total distance divided by total time. If you drive 150 km in 3 hours, your average speed is 50 km/h, even if you stopped or varied your speed.
- Instantaneous Speed: This is the speed of an object at one specific moment in time. The reading on a car's speedometer shows its instantaneous speed.
4. What is the difference between average speed and instantaneous speed?
The main difference lies in the time interval being considered. Average speed is calculated over a significant duration of a journey (total distance ÷ total time), providing an overall measure of how fast the journey was completed. In contrast, instantaneous speed is the speed measured at a specific, infinitesimally small moment, such as the speed a car's speedometer shows at any given second.
5. Why is speed considered a scalar quantity?
Speed is classified as a scalar quantity because it only describes the magnitude (the numerical value or 'how much') of an object's motion. It effectively tells you how fast an object is moving, such as "15 metres per second," but it provides no information about the direction of that movement. Quantities that require both magnitude and direction, like velocity, are known as vector quantities.
6. How can an object moving with a constant speed have a changing velocity?
This is a fundamental concept in physics, best illustrated by an object in uniform circular motion. For example, a satellite orbiting the Earth at a constant speed is continuously changing its direction of travel as it follows its circular path. Since velocity is defined by both speed and direction, any change in direction—even if the speed value remains constant—results in a change in velocity. This change in velocity means the object is technically accelerating.
7. What instruments are used to measure the speed and distance of a moving vehicle?
Two primary instruments are used in vehicles:
- A speedometer is the gauge that measures and displays the vehicle's instantaneous speed.
- An odometer is the instrument that records the total distance the vehicle has travelled over time.
