Definition
For the students of science subjects, it is very much important to know the terms exactly. This is to say, it is important for the science students to know the definitions of the term because it makes the meaning very clear and also in a concise manner. Also, many times the terms seem the same and therefore the students get confused about the meaning, in such cases, if the students have the definitions at hand, they can easily differentiate between the two. And hence Vedantu provides the same to the students of science for free.
A quick overview of the terms Angular Velocity, and Linear Velocity.
Angular Velocity: A relation by which the position of one line with the other line is established, is called angular position. And the rate at which the angular position of a rotating body changes is called angular velocity.
Linear Velocity: In simple terms, Linear Velocity refers to the velocity of an object in a straight line. That is to say, it shows the time taken by an object for moving from point A to point B.
Difference between the angular velocity and Linear Velocity.
Advantages of having the Definitions, along with the relations, of the linear and angular Velocity
To understand science better it is very important for the students to have a clear understanding of the words and the terms used in science, which is to say the students must have a good scientific vocabulary. And the best way of having that effective vocabulary is by having the definitions and the meaning of the terms available. And the same goes for the definition of linear Velocity and Angular Velocity.
The concept of linear velocity and angular velocity does seem completely different by learning the definitions of it. But still, there are some relations between the two as well, and hence Vedantu provides the same to the students for completely free of cost.
Also, sometimes students may find the concept of linear velocity and angular velocity a little difficult to understand, hence Vedantu provides the explanation of the same in a simple and lucid language. That is to say, along with the definition, the explanation is also given.
Once the students have understood the concept of linear velocity and angular velocity in a good manner then other things become pretty easy. Such as the definition of linear and angular velocity can be remembered easily because you already know what exactly it means. Also, finding the difference between the both becomes quite easy, as well as its relations.
Why is angular displacement considered as an axial vector?
We know that angular displacement is the angle traced by a particle under circular motion. Since the direction of the displacement is along the axis, that’s why angular displacement is an axial vector.
A particle in a circular motion exhibits two types of displacements; these are:
Along the circumference: Linear Displacement (s).
Making an angle θ: Angular Displacement.
If ‘r’ is the radius of the circle, then the relation between angular and linear displacement is:
\[S=R\theta \] or \[\theta =\frac{s}{r}\] . . . . . . . (1)
Linear velocity is defined as the rate of change of linear displacement. For a particle P, it is given by:
\[V=\frac{\Delta s}{\Delta t}\].....(2)
Angular velocity of the particle is the rate of change of angular displacement, i.e., how fast an angle is changing. It is given by:
\[w=\frac{\Delta \theta }{\Delta t}\].....(3)
Relation Between Linear Velocity and Angular Velocity
We know that the linear velocity of particle P is given by:
\[\mid v \mid =\frac{\Delta (s)}{\Delta t}\].....(2), and S = rθ
Now, putting the value of eq (1) in (3), we get:
\[v=\frac{\Delta r\theta }{\Delta t}\].....(2)
We know that the radius ‘r’ is a constant value, so we get:
\[v=\frac{\Delta r\theta }{\Delta t}\].....(2) (As \[\frac{\Delta \theta }{\Delta t}\] = w)
⇒ |v| = rω, which is the ‘relation between linear and angular velocity.
Here, v depends on r and ω in the following manner:
ω = How fast an object is rotating, and
r = The linear velocity of the particle at the center will be zero. As the particle starts moving away from the center, the linear velocity starts increasing. It is maximum at the circumference of the circle.
The tangent to the circle gives the direction of the linear velocity.
Point to Remember
Putting the value of θ in radians in the equation: S = rθ makes the calculation easier.
Similar to the displacement, the angular velocity is also an axial vector quantity. We can find its direction by using the Right-hand Thumb Rule. This rule says:
Curl your fingers in a counterclockwise direction, and the thumb pointing outwards (along the axis) is the direction of the angular velocity. Similarly, if you curl your fingers in a clockwise direction, then the thumb pointing inwards gives the direction of ω.
Angular Velocity and Linear Velocity Relation
For a body in a uniform circular motion, the relation between linear and angular velocity is:
v = rω
This equation states that the linear velocity (v) is directly proportional to the distance of the particle from the center of the circular path and its angular velocity.
The linear velocity is different at different points on the circle.
It is zero at the center.
It is minimum in between the center and any point on the circumference.
It is maximum at the circumference of the circle. However, angular velocity remains the same at all points on the circular path.
Angular Velocity to Linear Velocity
From our knowledge of the circular motion, we can infer that the magnitude of the linear velocity of a particle moving in a circle links to the angular velocity of the particle by the following relation:
\[r=\frac{v}{w}\]
At any moment, this relationship applies to every particle that has a rigid body.
FAQs on Angular Velocity and Linear Velocity
1. What is the fundamental definition of angular velocity and linear velocity in Physics?
In the context of circular motion as per the CBSE syllabus, these two terms are defined as follows:
- Linear velocity (v) is the rate at which an object covers distance in a straight line. It is a vector quantity, and its direction is always tangent to the circular path at any given point. It is measured in metres per second (m/s).
- Angular velocity (ω) is the rate at which an object rotates or revolves around an axis. It measures how quickly the angular position or orientation of the object changes over time. Its standard unit is radians per second (rad/s).
2. What is the basic relationship between linear velocity (v) and angular velocity (ω)?
The relationship between linear velocity and angular velocity for an object in uniform circular motion is given by the formula v = rω. Here, 'v' is the linear velocity, 'ω' (omega) is the angular velocity in rad/s, and 'r' is the radius of the circular path. This formula shows that the linear velocity of a point on a rotating object is directly proportional to its distance from the axis of rotation.
3. What are the key differences between angular velocity and linear velocity?
While related, angular and linear velocity describe different aspects of motion. The main differences are:
- Nature of Motion: Linear velocity measures straight-line motion, while angular velocity measures rotational motion.
- Dependency on Position: For a rigid rotating body, the angular velocity (ω) is the same for all points on the body. However, the linear velocity (v) varies, being zero at the center of rotation (r=0) and maximum at the outermost edge.
- Direction: The direction of linear velocity is tangential to the path. The direction of angular velocity is along the axis of rotation, determined by the right-hand thumb rule.
- Units: Linear velocity is measured in m/s, while angular velocity is measured in rad/s.
4. How is the relationship between linear and angular velocity expressed in vector form?
In vector notation, the relationship is expressed using a cross product, which accurately accounts for the directions of all quantities. The formula is v⃗ = ω⃗ × r⃗. In this equation, v⃗ is the linear velocity vector, ω⃗ is the angular velocity vector (pointing along the axis of rotation), and r⃗ is the position vector from the axis of rotation to the point. The cross product correctly yields a linear velocity vector 'v' that is perpendicular to both the radius and the axis of rotation, which means it is tangent to the circular path.
5. What are some real-world examples that illustrate the concepts of angular and linear velocity?
These concepts are visible in many everyday scenarios:
- A spinning fan: All points on a fan blade have the same angular velocity (they complete a circle in the same time). However, a point at the tip of the blade has a much higher linear velocity than a point near the center.
- Planet Earth: The Earth has a constant angular velocity as it spins on its axis (one rotation per 24 hours). A person standing on the equator has a high linear velocity, while someone at the North or South Pole has a linear velocity of nearly zero.
- A car's wheel: The top of the tire has a linear velocity twice that of the car's speed relative to the ground, while the bottom of the tire is momentarily at rest. All points on the tire, however, share the same angular velocity relative to the axle.
6. Why is the angular velocity constant for all particles of a rotating rigid body, but the linear velocity is not?
This is a crucial concept. A rigid body is one where the distance between any two internal points remains constant. When such a body rotates, every single particle in it completes a full 360-degree turn in the exact same amount of time. Since angular velocity (ω = Δθ/Δt) depends only on the angle turned (Δθ) and the time taken (Δt), it must be the same for all particles.
However, linear velocity (v = rω) also depends on the radius 'r'. Particles farther from the axis of rotation (larger 'r') must travel a longer circular path in the same amount of time, meaning they must move faster. This is why their linear velocity is greater.
7. How do you determine the direction of angular velocity?
The direction of the angular velocity vector is found using the Right-Hand Thumb Rule. To apply it: curl the fingers of your right hand in the direction of the object's rotation. Your thumb will then point in the direction of the angular velocity vector (ω⃗). For a wheel spinning counter-clockwise when viewed from the front, the angular velocity vector points outwards, along the axle. For a clockwise spin, it points inwards.
8. What is the linear velocity of a particle at the exact axis of rotation, and why?
The linear velocity of a particle at the exact axis of rotation is zero. This can be understood from the core relationship v = rω. At the axis of rotation, the distance from the center, or the radius (r), is zero. Therefore, regardless of how fast the object is spinning (its angular velocity ω), the linear velocity 'v' will be zero because v = 0 × ω = 0. This point is spinning on the spot but not moving through space.
