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Resultant Force And Equilibrant Force:Exhaustive Comparison

January 1, 2024November 4, 2021 by Keerthana Srikumar

Resultant force is one single force replaced by multiple forces and equilibrium force is the balanced force where the net force acting is zero that is direct opposite to resultant force. Hence this is basic difference between resultant force and equilibrant force.

Resultant force is the sum of all individual forces acting on a body by vector determination. Resultant force can be zero if one force is opposite to the other combination. There are several forces acting on a body and they are dealt separately in terms of vertical and horizontal forces.

When the magnitude is the same and directions are opposites the forces cancel out each other we get a value of force which is the resultant force. For instance, 5N force on the left and 9N force on the right gives resultant force as 4N.

Resultant force examples

Let us have four forces acting on a system at the same time, 60N, 70N, 40N, -20N. The force 20N is negative because it is acting on the opposite direction to that of the others. Evaluate the resultant force.

F_R = f1 + f2 + f3 + f4

F_R = 60N + 70N + 40N – 20N

F_R = 150N

Let two forces act perpendicular to each other, 9N and 4N. Determine the resultant force.

The formula for resultant force acting perpendicular to each other is

F = [(F1)² + (F2)²]^1/2

F = [(9)² + (4)²]^1/2

The resultant force or any other type of force can be explained easily using a free-body diagram. In this diagram we use arrows to indicate the magnitude and direction of the forces acting. The arrows pointing to a direction is the path of the force followed, and the length of the arrow shows specifies the magnitude.

While calculating the force present in the body, several forces come into play but resultant force gives value for the entire force present. Multiple forces acting on them goes balanced and unbalanced.

When the individual force have the same magnitude as the other they sum up also when the direction is the same then the system is said to have unbalanced force. But when the magnitude is the same and the direction is opposite to each other they cancel out each other and the system is said to have balanced force.

In a system there are several possible forces acting namely, normal force, frictional force, tensional force, gravitational force and so on. Resultant force is the final value of adding up these forces acting upon a body.

Equilibrant Force Concept

When the magnitude and the direction of the force acting on a body are balanced, showing zero net force and zero torque present in the system is known as the equilibrant force.

The state of balanced force occurs when a system in equilibrium. This happens when different forces acting upon the object are considered to be balanced.

The balancing of force in a system occurs when leftward force balances the rightward force and upward force balances the downward force.

Generally when the system is said to have balanced force, the individual forces cannot have the same value. For example, when a body is said to have balanced force, the individual force may differ and is explained using a free-body diagram.

Let’s consider a simple experiment to understand the concept of equilibrium force.

In physics lab, an object is suspended by two or more strings; force exerted is measured at angles made by the string with the object. Now the total number of forces acting on the object is measured.

If the object was to be in equilibrium the net force acting on the object should be of 0N. also, by adding up the force should be equal to zero.

Equilibrium Force Examples

Consider a man standing on the ground motionless. The forces acting on him will be zero since there is no acceleration and velocity. Due to this the man is said to be in static equilibrium.

Since the number of forces acting on the man is zero, and then the condition calls for equilibrium force in existence.

A car moves on a highway with constant acceleration and velocity. When it does not move the whole system stays motionless. The forces acting on the system is in each direction.

When children are seated on a see-saw, a rotating system, are said to be in equilibrium. If they are motionless and the forces acting on them becomes zero, by this way the torque becomes zero and it gives way for equilibrium force.

Therefore by all means, the total number of forces acting upon a body is balanced, making the net force zero, and the equilibrium force is achieved.

And when the entire force acting upon the object its magnitude and direction values are taken into account, by which on adding the resultant force is obtained.

Frequently asked Questions

Why does a force in equilibrium be zero?

In this condition two equal and opposite force exists balancing each other and the acceleration becomes zero.

The word equilibrium simply means balancing. In order for a system to be in equilibrium, there must be a balance of all the forces in the system and net force becomes zero.

When a net force does becomes zero in an equilibrium system?

The net force in a system becomes zero when all the forces acting in the system is balanced and when the acceleration turns to be zero.

This process occurs when all the forces in a system is balanced from all directions. Acceleration being zero the torque acting in a rotating system also becomes zero.

Will torque become zero if the net force is zero?

Torque is a cross product of distance and force, so when the net force is zero, torque will be zero.

If the displacement appears right after applying the force then the torque will be bigger than force. If displacement is missing even after the force application then force will be zero as well as the torque.

What is dynamic equilibrium?

Dynamic equilibrium is state of a system with motion and net force not equal to zero.

Dynamic equilibrium differs from static because dynamic mean the body is in motion with changing velocity and acceleration. The constant change in the acceleration velocity and torque (in rotating systems), is dynamic equilibrium.

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Physical Irreversible Change Example: Detailed Analysis

January 21, 2024November 4, 2021 by Rabiya Khalid

Physical changes can either be reversible or irreversible. Let us discuss some physical irreversible change examples.

Cutting trees into logs
Broken glass
Growth of tree
Pulverizing a rock
Mixing paint colors
Cracking an egg
Shredding paper
Sharpening pencil
Stitching dress out of a piece of fabric
Rock erosion
Grinding wood into sawdust
Chopping vegetables

Cutting trees into logs

tree 576846 1280 — Cutting trees into log is a physical change
Image Credit: https://pixabay.com/vectors/tree-log-fallen-cartoon-nature-576846/

This is one of the most common physical irreversible change example. On chopping trees to form logs, there is no involvement of internal energy. The chemical elements of the wood and the logs are just the same. It is clearly seen that only the size and shape are changed. Hence it is an example of physical change. But it is not a temporary change that is not reversible. Chopping a tree into small pieces of wood or logs is an irreversible change as we cannot obtain the whole tree back from these logs. Once the cutting is done, it becomes a permanent change.

Broken glass

When we drop a bowl made of glass, it accidentally gets broken into many smaller pieces. The small pieces of glass and the bowl as a whole are of the same material. We can find that the glass’s internal energy and chemical reactivity remains the same. But can we get back the bowl from the shattered and broken pieces of glass? The answer would be no. Of course, we can not bring back the bowl. Even if we try to weld the glass to join the pieces, we won’t get the exact bowl. So broken glass is an example of irreversible physical change.

Growth of tree

ezgif 6 41b2d38c58d2 — Image Credit: https://pixabay.com/vectors/branch-grow-growing-leaf-nature-2029756/

The growth of a small plant into a big tree is a unique chance. It is an example of both physical and chemical change; as for the growth of the tree, a chemical reaction such as photosynthesis occurs. The growth of a tree leads to stretching and growth of its branches and heights; hence it is also a physical change since we can not reverse and bring a seedling or a small plant back from a tree, so it is an irreversible change.

Pulverizing a rock

Breaking down the rocks into smaller and minute particles by either crushing, grinding, or beating them is known as pulverizing. The rock gets changed into powder form, but the chemical reactivity before and after the pulverization remains the same. Therefore, pulverizing a rock is classified as a physical change. Further, once the rock is crushed down, it can not be undone; that is, we can not bring it back to its original position. So we can say that pulverizing a rock is one of the physical irreversible change examples.

Mixing paint colors

ezgif 6 4e7f6c5c561d — Mixing Paint colors
Image Credit: https://pixabay.com/vectors/palette-paints-colors-mixing-33882/

Mixing paint colors to obtain a new color is another example of irreversible physical change. When paints are mixed, no new substance is formed; only the color is changed. The zero change in the internal energy of the object makes it a physical change. Secondly, once a new color is obtained, we can not bring back the exact same colors no matter what color we obtain. Therefore mixing paints together is an irreversible change.

Cracking an egg

A cracked egg is the simplest example of physical change. When the shell is cracked, the egg comes out, as only the shape is changed; it is considered as a physical change. Further, we know that it is in no way practical to make the cracked eggshell go back to its initial position. Also, it is obvious that in no way can it be put back into the shell. So cracked egg is an irreversible physical change.

Shredding paper

physical irreversible change example — Image Credit: https://pixabay.com/vectors/shredder-document-paper-shredder-311638/

We all know that shredding or tearing paper is a physical change, as only the size and shape of the paper are changed without altering its chemical composition. A sheet of paper is changed into strips of paper. Now once the paper is shredded into strips, it becomes impossible to bring back the original sheet. Some might question that by sticking the paper strips with tape, we can recover the paper. But that’s not the reality, the shape and size remain distorted to some extent, and the exact original piece of paper can not be restored. Hence it is also one of the physical irreversible change examples.

Sharpening pencil

When we sharpen the pencil every time, its size gets reduced. The change in the size of the pencil makes it a physical change. Secondly, since the process can not be undone, the pencil size can not be increased; it is irreversible. The sharpener only cuts the wood or graphite of which the pencil is made. It brings no change in the atomic structure or composition of wood and graphite.

Stitching dress out of a piece of fabric

For stitching a dress out of a piece of fabric, it has to be in different shapes. Since the dress is made of fabric, its chemical nature would be the same. Firstly as only the shape and size of the fabric are altered, it is a physical change. Now once the dress is stitched, can the process be reversed? Of course not. We can bring back the initial fabric out of the piece of the dress. Even if we cut out the stitches, some of the parts of the fabrics can not be undone. Hence the stitching of a dress out of a piece of fabric is a physical irreversible change example.

Rock erosion

arid 21799 1280 — Image Credit: https://pixabay.com/photos/arid-cracked-erosion-cracks-desert-21799/

Erosion is a natural phenomenon involving removing natural resources from their initial positions due to weathering. The rock erosion is the same but with one exception; it does not involve the movement of rocks. Rock erosion or weathering is the phenomenon in which the rocks are broken down into smaller pieces and change into the soil. The chemical constituents of the rock before and after the erosion remains the same. So it is considered as a physical change. Once the rock is changed into the soil, it can not be reversed back; hence it is an irreversible physical change.

Grinding wood into sawdust

The grinding of the wood changes it into sawdust. The sawdust has the same atomic stability and chemical structure as the wood. Due to no change in internal energy, it is termed as physical change. During this process, the wood just changes into minute powder. It is impossible to generate the wood from the sawdust; therefore, it is also an irreversible change.

Chopping vegetables

ezgif 6 01927365cbe2 — Image Credit: https://pixabay.com/photos/cucumber-food-vegetable-78789/

Chopping vegetables is another physical irreversible change example. When we cut or slice vegetables into small pieces for cooking, only the size is changed, and everything else like chemical constituents remains the same. Also, once the vegetables are chopped, they can not be brought back into their original state. Since this process can not be reversed using any method, therefore, it is an irreversible change.

All these are the physical irreversible change examples. Through these, we get to know that physical change does not necessarily have to be reversible; it can be irreversible too. Now we can define physical change as the reversible or irreversible change that occurs about the object’s physical properties.

Also Read:

Is Physical Change Reversible: Detailed Analysis

January 21, 2024November 2, 2021 by Rabiya Khalid

In reaction, when the changes occur about the reactants’ physical characteristics, they are said to be a physical change. Let’s know if this change is reversible.

The answer to the question is physical change reversible or not is yes. Yes, the physical changes are reversible in nature and can be brought to their original state. Hence we can say that the physical changes are temporary, and there is no change in their chemical properties.

On reaction, the changes that occur can be differentiated into physical changes and chemical changes. The changes in the physical properties of the object or compound are said to be a physical changes. At the same time, a chemical change is defined as changes in chemical properties. Tearing up paper is the basic example of physical change. On tearing paper gets smaller in size, but there is no change in the chemical properties.

Physical change is reversible changes that are it can be brought back to its original state. It usually involves a change in the shape, size, and state of the object. Since all these changes can be reversed, the physical change is also termed as the temporary change. Stretching of a rubber band, balloon inflation, and water boiling are all examples of reversible physical change.

paper 6276204 1280 — Image Credit: https://cdn.pixabay.com/photo/2021/05/23/13/23/paper-6276204_1280.png

Why is physical change reversible

When the bonds that keep the elements intact together break, the changes occur in the compound’s chemical properties. The bond on breaking brings about the internal energy of the body. In a physical change, all these phenomena do not occur. The name itself suggests that the changes occur in the physical properties that are size, shape, or state. These changes do not break bonds, and hence, the internal energy remains the same. Therefore the physical change is reversible in nature.

To understand the reversibility of physical change, let us see the example of water, on cooling liquid water changes into ice that is the solid form. From the liquid state, water has changed into a solid-state that is changing has happened in the state of the water. On melting, ice can again change into water. We know that the chemical formula for ice and water is H₂O, which means there is no change in chemical property. Hence the physical change that takes place on cooling water can be reversed on melting.

In the same when we heat water, it changes into water vapors. The chemical formula of both of them remains H₂O. We can reverse back water vapors into the water by condensation process. This whole conversion of water into ice and vapors and back to its original form explains the reversibility of physical changes.

Are physical changes always reversible

We have understood is physical change reversible or not. But is it always reversible? The answer to this is No. The physical change is not necessarily always reversible. Some of the changes can not be brought back to their initial stage.

To understand this, let us take the example of raw egg. When we break it down, the inner material comes out. The whole thing still remains the same, and there is no change in the chemical composition of the egg. Therefore it is a physical change. But can we put back the yolk into the eggshell? The answer is No. We cannot reverse this change; hence it is an irreversible physical change.

ezgif 7 8664fe84c653 — Growth of a tree
Image Credit: https://pixabay.com/vectors/tree-trunk-nature-leaves-branches-576836/

Therefore we understand now that physical change does not always have to be reversible. There are a lot of physical changes that can not be brought back. There are many who says the growth of a tree is completely chemical change as it is irreversible, but that is not the case. It is both chemical as well physical change. The growth of trees is an example of irreversible physical change.

We know now that not all irreversible changes are chemical changes; they can also be physical changes. Abd physical change not always has to be reversible.

Frequently Asked Questions (FAQs)

What are the two types of changes?

On reaction, there can occur two kinds of changes; chemical change and physical change.

When a reaction takes place, and a completely new substance is formed with different chemical properties, the change is said to be a chemical change. When no new substance is formed and its properties remain the same before and after the reaction, the change is known as physical change.

What is a physical change?

The changes in the physical properties of the substance or object are known as physical changes.

Physical changes are temporary that do not involve any change in the internal energy of the object. They generally bring changes in the size, shape, and state of matter. These types of changes are generally temporary.

Give an example of physical change.

The forces that bring about changes in a physical state if the object is said to be physical changes.

To explain the physical change, let’s suppose you have a large piece of cloth and you cut it into small pieces. Here the change has occurred in the size of the cloth. So this is an example of physical change. The freezing of water is also an example of physical change.

Is physical change reversible? Explain

Physical changes are those which does not involve any interference with the internal energy of the object.

Since the internal energy remains the same before and after the reaction, there is no change in the object’s chemical composition. Therefore the physical changes are reversible in nature. That is, they can be brought back to their original state, for example, freezing of water into ice.

Is physical change always reversible?

No, physical change is not always reversible; it can be irreversible too. There are many examples of irreversible physical change.

The cutting of trees into logs is a basic example of physical change. Since both are wood and there is no change in their composition, they are physical changes. But we cannot bring back the tree from the log, so it is an irreversible change.

Also Read:

How To Find Angular Velocity:7 Scenarios With Solved Problem

November 3, 2023October 28, 2021 by Rabiya Khalid

Definition and Importance of Angular Velocity

angular velocity is defined as the rate of change of angular displacement with respect to time. It measures how quickly an object rotates and is typically denoted by the Greek letter omega (ω). angular velocity is an essential parameter in rotational dynamics, as it relates to other rotational quantities like angular acceleration, angular momentum, and moment of inertia.

Image by Svjo – Wikimedia Commons, Wikimedia Commons, Licensed under CC BY-SA 3.0.

Image by dnet – Wikimedia Commons, Wikimedia Commons, Licensed under CC BY-SA 3.0.

how to find angular velocity — Image by Svjo – Wikimedia Commons, Wikimedia Commons, Licensed under CC BY-SA 4.0.

angular velocity is an essential concept in physics and mechanics that describes the rate at which an object rotates around a fixed axis. Understanding angular velocity is crucial for various applications, such as analyzing the motion of rotating objects, calculating torque, or studying the behavior of pendulums. In this blog post, we will explore different methods and formulas to find angular velocity in various scenarios. So, let’s dive in!

Finding Angular Velocity from Frequency

A. Understanding the Relationship between Angular Velocity and Frequency

Frequency (f) represents the number of complete revolutions or cycles an object completes in a given time. The relationship between angular velocity (ω) and frequency is given by the formula:

$ω = 2πf$

B. Step-by-step Process to Determine Angular Velocity from Frequency

To find angular velocity from frequency, follow these steps:

Identify the frequency (f) of the rotating object.
Multiply the frequency by 2π to obtain the angular velocity (ω).

Examples:

Problem: A ceiling fan has blades that rotate at a speed of 120 revolutions per minute (rpm). Determine the angular velocity of the fan blades in radians per second (rad/s).

$\text{Step 1: Convert frequency from rpm to Hz.}$

$f (\text{in Hz}) = \frac{120 \text{ rpm}}{60 \text{ s/min}}$

$f = 2 \text{ Hz}$

$\text{Step 2: Calculate the angular velocity.}$

$\omega = 2\pi f$

$\omega = 2\pi \times 2 \text{ Hz}$

$\omega = 4\pi \text{ rad/s}$

$\text{Result:}$

$\text{The angular velocity of the ceiling fan blades is: }$

$\omega = 4\pi \text{ rad/s}$

$\text{For a numerical approximation:}$

$\omega \approx 4 \times 3.14159 \text{ rad/s}$

$\omega \approx 12.566 \text{ rad/s}$

$\text{Therefore, the fan blades have an angular velocity of approximately 12.566 radians per second.}$

Finding Angular Velocity Given Radius and Speed

A. The Role of Radius and Speed in Angular Velocity

When an object moves in a circular path, the distance traveled by a point on the object’s circumference in a given time is called linear speed (v). Angular velocity (ω) is related to linear speed and radius (r) by the formula:

$ω = \frac{v}{r}$

B. Detailed Procedure to Calculate Angular Velocity with Radius and Speed

To determine angular velocity using radius and speed, follow these steps:

Measure the radius (r) of the circular path.
Determine the linear speed (v) of the object.
Divide the linear speed by the radius to obtain the angular velocity.

Example:

Problem: A point on the edge of a merry-go-round is traveling at a linear speed (tangential speed) of 3 meters per second (m/s). If the radius of the merry-go-round is 2 meters, what is the angular velocity of the merry-go-round in radians per second (rad/s)?

$\text{Given:}$

$v = 3 \text{ m/s} \quad \text{(linear speed)}$

$r = 2 \text{ m} \quad \text{(radius)}$

$\text{The relationship between linear speed, angular velocity, and radius is:}$

$v = \omega r$

$\text{Solve for angular velocity:}$

$\omega = \frac{v}{r}$

$\omega = \frac{3 \text{ m/s}}{2 \text{ m}}$

$\omega = 1.5 \text{ rad/s}$

$\text{Therefore, the angular velocity of the merry-go-round is 1.5 radians per second.}$

Finding Angular Velocity from Linear Velocity

A. Connection between Linear Velocity and Angular Velocity

Linear velocity (v) refers to the rate at which an object moves along a straight path. The relationship between linear velocity and angular velocity is given by the formula:

$v = ωr$

B. Detailed Steps to Find Angular Velocity from Linear Velocity

To calculate angular velocity using linear velocity, follow these steps:

Measure the linear velocity (v) of the object.
Determine the radius (r) of the circular path.
Divide the linear velocity by the radius to obtain the angular velocity.

Example:

Problem: A bicycle tire has a diameter of 0.7 meters. The bicycle is moving at a linear speed of 5 meters per second along a path. What is the angular velocity of the tire in radians per second?

$\text{Given:}$

$d = 0.7 \text{ m} \quad \text{(diameter of the tire)}$

$v = 5 \text{ m/s} \quad \text{(linear speed)}$

$\text{The radius (r) is half of the diameter:}$

$r = \frac{d}{2} = \frac{0.7 \text{ m}}{2}$

$\text{The relationship between linear velocity, angular velocity, and radius is:}$

$v = \omega r$

$\text{Solve for angular velocity:}$

$\omega = \frac{v}{r} = \frac{5 \text{ m/s}}{\frac{0.7 \text{ m}}{2}}$

$\omega \approx \frac{5 \text{ m/s}}{0.35 \text{ m}}$

$\omega \approx 14.29 \text{ rad/s}$

$\text{Therefore, the angular velocity of the bicycle tire is approximately 14.29 radians per second.}$

Finding Angular Velocity from Torque and Moment of Inertia

A. Understanding Torque and Moment of Inertia in Angular Velocity

Torque (τ) is a rotational force that causes objects to rotate. The moment of inertia (I) represents an object’s resistance to changes in its rotational motion. Angular velocity can be found using torque and moment of inertia through the formula:

$τ = Iω$

B. Procedure to Determine Angular Velocity from Torque and Moment of Inertia

To find angular velocity using torque and moment of inertia, follow these steps:

Determine the torque (τ) acting on the object.
Identify the moment of inertia (I) of the object.
Divide the torque by the moment of inertia to obtain the angular velocity.

Example:

Problem: A disk with a moment of inertia of 0.2 kg·m² is initially at rest. A constant torque of 0.5 N·m is applied to the disk. After 4 seconds, what is the angular velocity of the disk?

$\text{Given:}$

$I = 0.2 \text{ kg}\cdot\text{m}^2 \quad (\text{moment of inertia})$

$\tau = 0.5 \text{ N}\cdot\text{m} \quad (\text{torque})$

$t = 4 \text{ s} \quad (\text{time})$

$\omega_0 = 0 \text{ rad/s} \quad (\text{initial angular velocity})$

$\text{Step 1: Calculate the angular acceleration:}$

$\alpha = \frac{\tau}{I}$

$\text{Step 2: Calculate the final angular velocity:}$

$\omega = \omega_0 + \alpha t$

$\text{Compute the values:}$

$\alpha = \frac{0.5}{0.2} = 2.5 \text{ rad/s}^2$

$\omega = 0 + 2.5 \times 4 = 10 \text{ rad/s}$

$\text{Therefore, the disk's angular velocity after 4 seconds is 10 rad/s.}$

Finding Angular Velocity in Specific Scenarios

A. How to Find Angular Velocity of a Rotating Object

To determine the angular velocity of a rotating object, follow the respective method discussed earlier based on the available parameters such as frequency, radius and speed, linear velocity, or torque and moment of inertia.

B. How to Find Angular Velocity in Simple Harmonic Motion

In simple harmonic motion, the angular velocity is related to the angular frequency (ω) by the equation:

$ω = \sqrt{\frac{k}{I}}$

where k represents the spring constant and I is the moment of inertia.

C. How to Find Angular Velocity of Earth

The angular velocity of the Earth can be calculated by dividing the Earth’s angular displacement by the time taken. However, it is important to note that the Earth’s angular velocity is very small, as it completes one full rotation in approximately 24 hours.

D. How to Find Angular Velocity of a Pendulum

For a simple pendulum, the angular velocity is given by the formula:

$ω = \sqrt{\frac{g}{L}}$

where g is the acceleration due to gravity and L represents the length of the pendulum.

Finding Angular Velocity without Certain Parameters

A. How to Find Angular Velocity without Time

If the time is not given, it is not possible to directly calculate angular velocity. However, if other parameters like angular displacement or frequency are provided, it may still be possible to determine the angular velocity using the relevant formulas.

B. How to Find Angular Velocity without Radius

When the radius of the circular path is unknown, it is not possible to find the angular velocity directly. However, if linear velocity or torque and moment of inertia are provided, it is still possible to calculate the angular velocity using the appropriate formulas.

15 Examples Of Angular Velocity

January 1, 2024October 24, 2021 by Rabiya Khalid

The angular velocity is the angular displacement per time of a body on an axis during circular motion or oscillation. Angular velocity examples in daily life are:

Ferris wheel
Race Car on the racetrack
Earth revolution
A rock tied with a rope and spinning around
Ceiling and Electric Fan
Simple Pendulum
Wheels
Hands of clock
Blades of Helicopter
The motion of electrons around the nucleus
Satellites orbiting around planets
Electric Beater
Washing Machine
Yo-Yo
Swing

Ferris wheel

The Ferris wheel moves in a circular motion. Due to the rotation, its angle changes and it attains angular velocity. Most of the time the angular velocity remains constant, that is it moves with uniform velocity but on the top and bottom position, the velocity gets accelerated. Due to the changes in velocity that leads to centripetal acceleration the rider feels heavy or light at the bottom and top position. Ferris Wheel is the basic example of an object moving in a circular motion with angular velocity.

Race Car on the racetrack

When a body moves on a straight path it has only a linear component of velocity. But if we take the example of a race car running on the race track then the angular velocity also comes into action. The racetracks are circular or they have curves. When the car turns on the track the angle changes with time and hence the car attains angular velocity.

Earth revolution

solar system 414388 1280 — Image Credit: https://cdn.pixabay.com/photo/2014/08/09/21/30/solar-system-414388_1280.jpg

The Earth and all the other planets revolve around the sun in a circular orbit. When they revolve their phase, that is angle keeps changing with respective time. This leads to the emergence of orbital angular velocity in Earth and heavenly bodies that revolve around the Sun. As planets go closer to the sun their angular velocity increases. This is due to an increase in gravitational pull and hence to maintain the angular momentum the angular velocity rises.

Rock tied with a rope and spinning around

When a rock tied with a rope or string is spun around, it orbits in a circular motion. Due to which the angle of the rock keeps changing concerning time. The angular displacement leads to the development of the angular velocity of the rock spinning around. This velocity is always direct along the axis of rotation. The centripetal force pushes the rock to gain angular velocity and allows their spinning. To gain maximum angular velocity a string with a shorter length is needed and vice versa. The angular momentum of the rock remains conserved at every point of the motion.

Ceiling and Electric Fan

air 2260 1280 — Image Credit: https://pixabay.com/photos/air-blade-blowing-chrome-cool-2260/

On switching the ceiling or electronic fans they start rotating. It spins in a circular motion and completes the cycles. The angular velocity of the fan is measured as the revolutions that it completes in a given time. The angular velocity of the fan changes by increasing and decreasing the speed. When the velocity changes the fan gets angular acceleration.

Simple Pendulum

The simple pendulum is a small bob hanging from a massless string. On striking the bob the pendulum starts oscillating from mean position to extreme points at both ends. While oscillating the pendulum keeps changing the phase which leads to the angular velocity. The angular velocity is the same concept as linear velocity, the difference is the type of motion. The angular velocity of the pendulum is never constant. When it reaches the endpoints the velocity tends to 0 but never becomes completely negligible. For pendulum one should be careful to not confuse the angular velocity with angular frequency.

Wheels

wheel rim 254714 1280 — Image Credit: https://pixabay.com/photos/wheel-rim-rim-of-wheel-wheel-tire-254714/

The rotation and motion of wheels is the most common example of angular velocity in everyday life. The wheels keep rotating on a fixed axis and keep changing the phase. The angular velocity is calculated by dividing the angle change with time. The angular component of the velocity of the wheel is also determined by specifying the revolution completed by the rotating wheel. The one revolution of the wheel is equal to 2π. Now suppose that the wheel completes 6 revolutions in one minute, then the angular speed would be 12π radians per minute.

Hands of clock

ezgif 7 63cb0ee3c003 — Image Credit: https://pixabay.com/photos/clock-alarm-alarm-clock-dial-time-1031503/

The minute hand and second hand of the clock keep rotating all day long at a fixed axis. Due to their rotation, their angle changes concerning time. Both of their velocities are different as they complete a different number of revolutions in a given time. It gives the idea about how fast the hands of the clock are moving.

Blades of Helicopter

helicopter 2116170 1280 — Image Credit: https://pixabay.com/illustrations/helicopter-rotors-aircraft-cockpit-2116170/

The blades of the helicopter start rotating as the engine starts. On rotation, the blades change the angle and complete the cycle. The number of cycles that it completes in a given time constitute the angular velocity of the helicopter. It is due to this velocity that the helicopter moves upward. The blades are rotated with an angular velocity which pushes the air downwards and uplifts the helicopter.

The motion of electrons around the nucleus

atom 1674878 1280 — Image Credit: https://pixabay.com/vectors/atom-chemistry-science-model-1674878/

In an atom, the negative subatomic particle i.e. electrons revolve around the nucleus in a uniform circular orbit. They move with angular speed which remains constant throughout the motion. Hence the electrons do not radiate energy while revolving. The angular component of the velocity of an electron is inversely proportional to its orbital number. The electrons which are nearer to the nucleus will have greater angular velocity rather than those farther from the nucleus. Along with the revolution, the electrons further spin on their own axis that also contributes to their angular velocity.

Satellites orbiting around planets

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The motion of satellites around the planets is analogous to electrons’ revolution around the sun or we can say the other way around. The satellite orbits on a circular path around the planets to provide information about them. When they revolve there emerges angular velocity that helps in their motion. When the angular velocity of the satellite changes then the angular acceleration generates. To keep itself moving in orbit, the satellite speed remains near to constant.

Electric Beater

The electric beater is another device that has an angular component of velocity. When we switch on the beater its blade starts rotating on an axis. This rotation leads to the angular speed of the electric beater. Greater the angular speed greater would be the intensity with which the blade would move and faster the product would be whisked.

Washing Machine

The washing machine is another example of angular velocity. When the machine operates it spins and rotates on a fixed axis. The uniform circular motion brings the angular velocity into action. The centripetal force and the angular velocity contributes to the mechanism of the washing machine.

Yo-Yo

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Yo-yo is a simple toy that swings due to its angular velocity. When we throw the yo-yo it starts swinging and spinning to climb to the string. Its angular velocity keeps changing and hence it gets angularly accelerated.

Swing

The swings in the children’s park is also an example of angular velocity. It swings back and forth at continuous intervals. Moving ahead it makes an angle and with the same angle, it moves backwards. The change in angle leads to the emergence of the angular speed of the swing. Both the angular and linear velocity component helps in the swinging.

Linear Frequency: 5 Important Facts You Should Know

January 2, 2024October 20, 2021 by Rabiya Khalid

Linear frequency is a fundamental concept in the field of signal processing and wave analysis. It plays a crucial role in understanding periodic motion and its relationship to simple harmonic motion. In this section, we will delve into the definition and explanation of periodic motion, as well as explore the connection between simple harmonic motion and periodic motion.

Definition and Explanation of Periodic Motion

Periodic motion refers to any motion that repeats itself after a certain interval of time. It is characterized by a regular pattern and can be observed in various natural phenomena, such as the swinging of a pendulum, the oscillation of a spring, or the rotation of celestial bodies.

One key aspect of periodic motion is its frequency, which represents the number of complete cycles or oscillations that occur in a given time period. Frequency is typically measured in hertz (Hz), where 1 Hz corresponds to one cycle per second. The linear frequency of a periodic motion refers to the frequency at which the motion occurs in a linear fashion, without any deviation or nonlinearity.

Linear frequency is essential in analyzing and understanding the behavior of periodic systems. By studying the linear frequency of a system, we can gain insights into its dynamics, stability, and response characteristics.

Relationship between Simple Harmonic Motion and Periodic Motion

Simple harmonic motion (SHM) is a special type of periodic motion that follows a sinusoidal pattern. It occurs when a restoring force is proportional to the displacement from an equilibrium position. Examples of simple harmonic motion include the back-and-forth motion of a mass-spring system or the oscillation of a pendulum.

The relationship between simple harmonic motion and periodic motion lies in the fact that simple harmonic motion is a specific form of periodic motion. While all simple harmonic motion is periodic, not all periodic motion is necessarily simple harmonic.

In simple harmonic motion, the linear frequency is directly related to the physical properties of the system, such as the mass and spring constant in a mass-spring system or the length and gravitational acceleration in a pendulum. The linear frequency determines the rate at which the system oscillates and is independent of the amplitude of the motion.

Understanding the relationship between simple harmonic motion and periodic motion allows us to analyze and predict the behavior of various systems in fields such as physics, engineering, and even music.

To summarize, linear frequency is a fundamental concept in the study of periodic motion. By examining the linear frequency of a system, we can gain valuable insights into its behavior and response characteristics. Additionally, understanding the relationship between simple harmonic motion and periodic motion helps us analyze and predict the dynamics of various systems. In the following sections, we will explore different aspects of linear frequency and its applications in more detail.

Linear Frequency and its Calculation

Definition of Linear Frequency

Linear frequency refers to the rate at which a wave oscillates or repeats in a linear fashion. It is a fundamental concept in physics and engineering, particularly in the study of waves and vibrations. The linear frequency of a wave is measured in hertz (Hz) and represents the number of complete cycles or oscillations that occur in one second.

Linear frequency can be understood as the inverse of the time period of a wave. It provides information about the speed at which the wave is oscillating or vibrating. The higher the linear frequency, the faster the wave is oscillating, and vice versa.

Calculation of Linear Frequency using Time Period

The linear frequency of a wave can be calculated using its time period. The time period of a wave is the time it takes for one complete cycle or oscillation to occur. It is denoted by the symbol T and is measured in seconds (s).

To calculate the linear frequency using the time period, we can use the formula:

Linear Frequency (f) = 1 / Time Period (T)

For example, if a wave has a time period of 0.02 seconds, we can calculate its linear frequency as:

Linear Frequency (f) = 1 / 0.02 = 50 Hz

This means that the wave completes 50 cycles or oscillations in one second.

Calculation of Linear Frequency using Wave Equation

Another way to calculate the linear frequency of a wave is by using the wave equation. The wave equation relates the linear frequency, wavelength, and the speed of the wave. It is given by the formula:

Linear Frequency (f) = Speed of the Wave (v) / Wavelength (λ)

The speed of the wave represents how fast the wave is propagating through a medium and is measured in meters per second (m/s). The wavelength of a wave is the distance between two consecutive points in a wave that are in phase with each other and is measured in meters (m).

By knowing the speed of the wave and the wavelength, we can calculate the linear frequency using the wave equation.

Relation between Linear Frequency and Angular Frequency

Linear frequency and angular frequency are two related concepts in wave analysis. Angular frequency, denoted by the symbol ω (omega), represents the rate at which the phase of a wave changes. It is measured in radians per second (rad/s).

The relationship between linear frequency (f) and angular frequency (ω) is given by the formula:

Angular Frequency (ω) = 2π × Linear Frequency (f)

Here, 2π represents a full cycle or 360 degrees in radians. By multiplying the linear frequency by 2π, we can obtain the angular frequency of a wave.

Units and Symbol of Linear Frequency

Linear frequency is a fundamental concept in the field of signal processing and engineering. It refers to the rate at which a signal or waveform repeats itself in a linear manner. In this section, we will discuss the units used to measure linear frequency and the symbols commonly employed to represent it.

Units of Linear Frequency

The most commonly used unit to measure linear frequency is the Hertz (Hz). One Hertz represents one cycle per second. It is named after Heinrich Hertz, a German physicist who made significant contributions to the study of electromagnetic waves.

Another unit that is sometimes used to express linear frequency is revolutions per minute (RPM). This unit is commonly used in the context of rotating machinery, such as engines or motors. It represents the number of complete rotations that occur in one minute.

To better understand the relationship between Hertz and RPM, consider a rotating object that completes one full revolution every second. In this case, the linear frequency would be 1 Hz or 60 RPM, as there are 60 seconds in a minute.

Symbol Used to Represent Linear Frequency

In mathematical equations and scientific notations, linear frequency is typically represented by the symbol “f” or the Greek letter “ν” (nu). The symbol “f” is derived from the word “frequency” and is widely used in various scientific disciplines.

The Greek letter “ν” is often used as an alternative symbol for linear frequency. It is derived from the Greek word “νεῦμα” (neuma), which means “nod” or “vibration.” The use of this symbol adds a touch of elegance and mathematical convention to the representation of linear frequency.

Both “f” and “ν” are widely recognized and accepted symbols for linear frequency in scientific literature and engineering applications. They are used interchangeably depending on the preference of the author or the field of study.

To summarize, linear frequency is measured in Hertz (Hz) or revolutions per minute (RPM). The symbol “f” or the Greek letter “ν” is used to represent linear frequency in mathematical equations and scientific notations. Understanding these units and symbols is essential for comprehending and working with linear frequency in various applications.

Angular Frequency vs Linear Frequency

Explanation of Angular Frequency and Linear Frequency

When discussing the concept of frequency, it is important to understand the difference between angular frequency and linear frequency. While both terms are related to the measurement of cycles or oscillations per unit of time, they are used in different contexts and have distinct meanings.

Angular Frequency:

Angular frequency, denoted by the symbol ω (omega), is a measure of how quickly an object or system rotates or oscillates. It is expressed in radians per second (rad/s). Angular frequency is commonly used in physics and engineering to describe the rate of change of angular displacement over time.

To better understand angular frequency, let’s consider an example. Imagine a wheel rotating at a constant speed. The angular frequency would represent how fast the wheel is turning, measured in radians per second. A higher angular frequency would indicate a faster rotation, while a lower angular frequency would correspond to a slower rotation.

Linear Frequency:

On the other hand, linear frequency, often simply referred to as frequency, is a measure of how many cycles or oscillations occur in a given unit of time. It is commonly denoted by the symbol f and expressed in hertz (Hz). Linear frequency is widely used in various fields, including physics, electronics, and telecommunications.

To illustrate linear frequency, let’s consider a simple example. Imagine a pendulum swinging back and forth. The linear frequency would represent how many complete swings the pendulum makes in one second. A higher linear frequency would indicate a faster oscillation, while a lower linear frequency would correspond to a slower oscillation.

Relationship between Angular Frequency and Linear Frequency

Although angular frequency and linear frequency have different units of measurement, they are closely related. In fact, there is a direct mathematical relationship between the two.

The relationship between angular frequency (ω) and linear frequency (f) can be expressed using the formula:

ω = 2πf

Here, π (pi) is a mathematical constant approximately equal to 3.14159. By multiplying the linear frequency by 2π, we can obtain the corresponding angular frequency.

This relationship allows us to convert between angular frequency and linear frequency. For example, if we know the linear frequency of a signal, we can easily calculate its angular frequency using the formula mentioned above.

Comparison of Symbols and Units Used for Angular Frequency and Linear Frequency

Angular frequency and linear frequency are represented by different symbols and units. Understanding these symbols and units is essential for correctly interpreting and working with frequency-related measurements.

Here is a comparison of the symbols and units used for angular frequency and linear frequency:

	Angular Frequency	Linear Frequency
Symbol	ω (omega)	f
Unit	radians per second (rad/s)	hertz (Hz)

As shown in the table, angular frequency is represented by the symbol ω (omega) and measured in radians per second (rad/s). On the other hand, linear frequency is denoted by the symbol f and expressed in hertz (Hz).

It is important to note that while angular frequency and linear frequency have different symbols and units, they are both fundamental concepts in the study of oscillations and waves. Understanding their relationship and how to convert between them is crucial in various scientific and engineering applications.

Finding Linear Frequency

Formulas for calculating linear frequency

When it comes to understanding linear frequency, there are a few formulas that can help us calculate it. Linear frequency refers to the rate at which a signal oscillates or repeats over time. It is an essential concept in various fields, including physics, engineering, and signal processing.

One of the most common formulas used to calculate linear frequency is:

f = 1 / T

In this formula, f represents the linear frequency, and T represents the period of the signal. The period is the time it takes for one complete cycle of the signal to occur. By taking the reciprocal of the period, we can determine the linear frequency of the signal.

Another formula that is often used is:

f = n / t

Here, f represents the linear frequency, n represents the number of cycles that occur in a given time period t. This formula allows us to calculate the linear frequency based on the number of cycles that occur within a specific time frame.

Examples of calculating linear frequency for different scenarios

Let’s explore a few examples to better understand how to calculate linear frequency in different scenarios.

Example 1: Simple Harmonic Motion

Consider a simple harmonic motion, such as a mass attached to a spring oscillating back and forth. If the period of this motion is 2 seconds, we can use the formula f = 1 / T to calculate the linear frequency:

f = 1 / 2 f = 0.5 Hz

Therefore, the linear frequency of this simple harmonic motion is 0.5 Hz.

Example 2: Sound Waves

In the context of sound waves, the linear frequency represents the pitch of the sound. Suppose we have a sound wave with a period of 0.01 seconds. Using the formula f = 1 / T, we can calculate the linear frequency:

f = 1 / 0.01 f = 100 Hz

Hence, the linear frequency of this sound wave is 100 Hz.

Example 3: Electrical Signals

Electrical signals also have linear frequencies that can be calculated using the formulas mentioned earlier. Let’s say we have an electrical signal with a period of 0.005 seconds and it completes 10 cycles within that time frame. Using the formula f = n / t, we can determine the linear frequency:

f = 10 / 0.005 f = 2000 Hz

Therefore, the linear frequency of this electrical signal is 2000 Hz.

By applying these formulas, we can calculate the linear frequency for various scenarios, whether it’s simple harmonic motion, sound waves, or electrical signals. Understanding linear frequency allows us to analyze and manipulate signals in different domains, such as audio processing, telecommunications, and radar systems.

Importance of Frequency

Explanation of the Significance of Frequency in Physics

Frequency is a fundamental concept in physics that plays a crucial role in understanding various phenomena. It refers to the number of cycles or oscillations of a wave that occur in a given time period. Whether we are talking about sound waves, light waves, or electrical signals, frequency is a key parameter that helps us analyze and comprehend these phenomena.

In physics, frequency is measured in hertz (Hz), which represents the number of cycles per second. The higher the frequency, the more cycles occur within a given time frame. Conversely, a lower frequency means fewer cycles occur in the same time period.

Frequency is significant in physics for several reasons. Firstly, it helps us determine the pitch of sound waves. For example, a high-frequency sound wave corresponds to a high-pitched sound, while a low-frequency sound wave corresponds to a low-pitched sound. This relationship between frequency and pitch is crucial in music, as different frequencies produce different musical notes.

Secondly, frequency is essential in analyzing and understanding wave phenomena. Waves, such as water waves, electromagnetic waves, and seismic waves, all exhibit characteristic frequencies. By studying the frequency of these waves, scientists can gain insights into their behavior, propagation, and interaction with the surrounding environment.

Lastly, frequency is vital in the field of electronics and electrical engineering. In alternating current (AC) circuits, the frequency of the electrical signal determines the rate at which the current alternates direction. This is particularly important in power distribution systems, where a consistent frequency is necessary for efficient transmission and operation of electrical devices.

Applications of Frequency in Various Phenomena

Frequency finds applications in a wide range of phenomena, including oscillation, waves, light, current, and voltage. Let’s explore some of these applications:

Oscillation: Frequency is central to the study of oscillatory motion. Whether it’s the swinging of a pendulum, the vibrations of a guitar string, or the motion of a simple harmonic oscillator, the frequency determines the rate at which the system oscillates. In simple terms, it determines how fast or slow an object vibrates back and forth.
Waves: Frequency is a fundamental property of waves. It determines the number of wave cycles that pass through a given point in a unit of time. For example, in the case of water waves, the frequency determines the number of wave crests that pass a fixed point in a second. In electromagnetic waves, such as radio waves, microwaves, and visible light, frequency determines the energy and wavelength of the wave.
Light: In the context of light, frequency determines its color. Different colors of light correspond to different frequencies. For instance, red light has a lower frequency than blue light. This relationship between frequency and color is essential in fields like optics, photography, and display technologies.
Current and Voltage: In electrical circuits, frequency plays a crucial role in determining the behavior of current and voltage. For example, in alternating current (AC) circuits, the frequency of the electrical signal determines the rate at which the current alternates direction. This is important in the design and operation of electrical devices, such as motors, generators, and transformers.

Understanding the importance of frequency in these various phenomena allows scientists, engineers, and researchers to manipulate and control these phenomena for practical applications. By manipulating the frequency, we can achieve desired outcomes, such as amplification, filtering, or modulation of signals.

Linear Frequency Modulation

Linear frequency modulation, also known as linear FM, is a modulation technique commonly used in various applications such as radar and pulse compression. It involves a continuous change in frequency over time, resulting in a linear relationship between the frequency and time. This section will provide a definition and explanation of linear frequency modulation, as well as explore its applications in radar and pulse compression.

Definition and Explanation of Linear Frequency Modulation

Linear frequency modulation is a method of modulating a carrier signal by varying its frequency in a linear manner. In this technique, the frequency of the carrier signal increases or decreases at a constant rate over time. The rate at which the frequency changes is known as the sweep rate or modulation rate.

One of the key characteristics of linear frequency modulation is that the frequency change is proportional to the time elapsed. This means that the frequency increases or decreases linearly with time. This linear relationship between frequency and time allows for precise control and manipulation of the carrier signal.

Linear frequency modulation is often used in various applications that require the transmission and reception of signals with specific frequency characteristics. It is particularly useful in radar systems and pulse compression techniques.

Applications of Linear Frequency Modulation in Radar and Pulse Compression

Radar systems utilize linear frequency modulation to accurately measure the distance and velocity of objects. By transmitting a signal with a linearly increasing or decreasing frequency, the radar system can calculate the time it takes for the signal to travel to the target and back. This information is then used to determine the distance to the target.

In pulse compression techniques, linear frequency modulation is employed to improve the resolution and range of radar systems. By using a linear frequency modulated signal, the radar system can achieve a compressed pulse with a longer duration. This extended pulse duration allows for better range resolution, enabling the detection of smaller targets and improved accuracy.

Linear frequency modulation is also utilized in sonar systems for underwater communication and object detection. By modulating the frequency of the sonar signal in a linear manner, it is possible to accurately measure the distance to underwater objects and detect their presence.

Frequency Separation in Photoshop

Frequency separation is a powerful technique used in image editing to separate the high-frequency details from the low-frequency tones in an image. This technique allows for precise control and manipulation of different aspects of an image, such as texture and color, without affecting the overall composition. In this section, we will explore the concept of frequency separation in Photoshop and discuss its importance and applications in image editing.

Explanation of Frequency Separation in Photoshop

Frequency separation works by decomposing an image into two separate layers: the high-frequency layer and the low-frequency layer. The high-frequency layer contains the fine details of the image, such as wrinkles, pores, and texture, while the low-frequency layer contains the broader tonal information, such as color transitions and gradients.

To create a frequency separation in Photoshop, follow these steps:

Open the image you want to edit in Photoshop.
Duplicate the image layer twice.
Rename the first duplicate layer as “High Frequency” and the second duplicate layer as “Low Frequency.”
Apply a high-pass filter to the “High Frequency” layer. This filter helps to enhance the details by removing the low-frequency information. Adjust the radius of the filter to control the level of detail.
Apply a Gaussian blur filter to the “Low Frequency” layer. This filter helps to smooth out the image and preserve the overall tonal information. Adjust the radius of the filter to control the level of smoothness.
Set the blending mode of the “High Frequency” layer to “Linear Light.” This blending mode allows the layer to interact with the layers below it while preserving the details.
Now, you can make adjustments to each layer separately. For example, you can use the healing brush tool on the “High Frequency” layer to remove blemishes and imperfections without affecting the overall color and tone of the image. On the other hand, you can adjust the brightness, contrast, and color balance on the “Low Frequency” layer to enhance the overall look of the image.

Importance and Application of Frequency Separation in Image Editing

Frequency separation is a valuable technique in image editing because it provides a non-destructive way to retouch and enhance images. By separating the high-frequency details from the low-frequency tones, photographers and retouchers can have more control over the editing process, resulting in more natural and realistic-looking images.

Here are some important applications of frequency separation in image editing:

Skin Retouching: Frequency separation is widely used in portrait retouching to smooth out skin imperfections while preserving the texture. By working on the high-frequency layer, retouchers can remove blemishes, wrinkles, and other skin flaws without affecting the overall skin tone and color.
Texture Enhancement: Frequency separation allows photographers to enhance the texture in their images. By selectively sharpening the high-frequency layer, they can bring out the fine details and make the image more visually appealing.
Color Correction: With frequency separation, it is possible to adjust the color and tone of an image without affecting the texture. By working on the low-frequency layer, photographers can make global color corrections, such as adjusting the white balance, saturation, and contrast, while leaving the fine details intact.
Object Removal: Frequency separation can be used to remove unwanted objects from an image seamlessly. By cloning or healing on the high-frequency layer, retouchers can remove distractions without leaving any visible traces.

Linear Frequency Modulation Waveform Synthesis

Explanation of Waveform Synthesis using Linear Frequency Modulation

Waveform synthesis using linear frequency modulation (LFM) is a technique that involves varying the frequency of a signal in a linear manner over time. This modulation technique is widely used in various applications, including radar, sonar, telecommunications, and music synthesis.

In LFM, the frequency of the signal increases or decreases linearly with time. This results in a continuous and smooth change in the pitch or frequency of the waveform. The rate at which the frequency changes is known as the sweep rate or chirp rate. By controlling the sweep rate, we can shape the characteristics of the synthesized waveform.

One common way to generate an LFM waveform is by using a voltage-controlled oscillator (VCO). The VCO produces a signal with a frequency that is directly proportional to the input voltage. By applying a linearly increasing or decreasing voltage to the VCO, we can achieve the desired linear frequency modulation.

Another method for LFM waveform synthesis is through digital signal processing techniques. By manipulating the digital representation of the waveform, we can achieve precise control over the frequency modulation. This approach is commonly used in software-based synthesizers and digital communication systems.

Applications and Benefits of Linear Frequency Modulation in Waveform Synthesis

Linear frequency modulation has a wide range of applications in various fields. Let’s explore some of the key applications and the benefits it offers:

Radar Systems: LFM is extensively used in radar systems for target detection and ranging. By transmitting LFM waveforms and analyzing the received signals, radar systems can accurately measure the distance to objects and detect their velocity. The linear frequency modulation allows for better resolution and range accuracy in radar systems.
Sonar Systems: Similar to radar, sonar systems also utilize LFM waveforms for underwater target detection and ranging. By emitting LFM signals and analyzing the echoes, sonar systems can determine the distance and location of underwater objects. The linear frequency modulation helps in distinguishing between different targets and reducing interference from reflections.
Telecommunications: LFM is employed in various telecommunications applications, such as frequency-modulated continuous wave (FMCW) radar and spread spectrum communication systems. In FMCW radar, LFM waveforms are used to measure the range and velocity of targets. Spread spectrum communication systems utilize LFM waveforms to achieve robust and secure communication by spreading the signal energy across a wide frequency band.
Music Synthesis: LFM is widely used in electronic music synthesis to create unique and evolving sounds. By modulating the frequency of oscillators with LFM waveforms, musicians can generate complex and dynamic timbres. The linear frequency modulation adds movement and expressiveness to the synthesized sounds, allowing for rich and evolving musical compositions.
Medical Imaging: LFM waveforms find applications in medical imaging techniques, such as ultrasound and magnetic resonance imaging (MRI). In ultrasound imaging, LFM signals are used to generate focused beams and improve the resolution of the images. In MRI, LFM waveforms are employed to encode spatial information and reconstruct detailed images of the body.

The benefits of using linear frequency modulation in waveform synthesis include improved resolution, enhanced range accuracy, better target detection, reduced interference, and the ability to create dynamic and evolving sounds. These advantages make LFM a versatile and powerful technique in various fields.

Linear Frequency Response

Definition and Explanation of Linear Frequency Response

In signal processing, the concept of linear frequency response plays a crucial role. It refers to the behavior of a system or device when subjected to different frequencies of input signals. A linear frequency response means that the system or device responds uniformly to all frequencies within its operating range.

When we talk about linear frequency response, we are essentially looking at how a system or device handles different frequencies without distorting the input signal. In simpler terms, it means that the output of the system or device is a faithful reproduction of the input signal, with no alterations in amplitude or phase.

To understand this concept better, let’s consider an example. Imagine you have a speaker system that claims to have a linear frequency response from 20 Hz to 20 kHz. This means that when you feed the speaker system with a sine wave at 50 Hz, it will produce an output that accurately represents the input signal. Similarly, if you input a sine wave at 10 kHz, the speaker system will faithfully reproduce that frequency as well.

Importance and Applications of Linear Frequency Response in Signal Processing

The concept of linear frequency response is of utmost importance in various fields of signal processing. Let’s explore some of its applications:

Audio Equipment: In the realm of audio, linear frequency response is crucial for high-fidelity reproduction of sound. Audio systems such as speakers, headphones, and amplifiers strive to achieve a linear frequency response to ensure accurate playback of music and other audio content. This ensures that the listener hears the audio as intended by the artist or sound engineer.
Telecommunications: Linear frequency response is vital in telecommunications systems, including telephones, cell phones, and VoIP (Voice over Internet Protocol) devices. These systems rely on accurate transmission and reception of audio signals, and a linear frequency response ensures that the transmitted voice signals are faithfully reproduced at the receiving end.
Equalization: Equalization is a technique used to adjust the frequency response of audio systems to compensate for deficiencies in the system or to achieve a desired sound. Linear frequency response is essential in equalization to ensure that the adjustments made to the frequency spectrum do not introduce distortion or alter the original sound beyond the intended modifications.
Instrumentation: Linear frequency response is crucial in various scientific and engineering instruments. For example, oscilloscopes, spectrum analyzers, and data acquisition systems need to accurately measure and display signals across a wide range of frequencies. A linear frequency response ensures that the measurements and analysis performed by these instruments are reliable and accurate.

Linear Frequency Modulation Chirp

Definition and Explanation of Linear Frequency Modulation Chirp

Linear Frequency Modulation Chirp is a technique used in various fields, such as radar, sonar, telecommunications, and audio synthesis. It involves the modulation of a signal’s frequency in a linear manner over time. This modulation creates a distinctive sound or waveform known as a chirp.

A chirp is characterized by a continuous change in frequency over a specified time period. Unlike a simple tone, which has a constant frequency, a chirp sweeps through a range of frequencies, either increasing or decreasing linearly. This linear frequency modulation allows for a wide range of applications and benefits.

One of the key aspects of linear frequency modulation chirp is the linear relationship between the frequency and time. As time progresses, the frequency of the chirp changes at a consistent rate. This linear relationship makes it easier to analyze and process the chirp signal.

Applications and Benefits of Linear Frequency Modulation Chirp

Linear frequency modulation chirp finds applications in various fields due to its unique properties and benefits. Let’s explore some of the key applications and advantages of this technique:

Radar and Sonar Systems: Linear frequency modulation chirp is widely used in radar and sonar systems for target detection and ranging. By transmitting a chirp signal and analyzing the received echo, these systems can accurately determine the distance, velocity, and direction of objects. The linear frequency modulation allows for precise measurements and improved target detection in noisy environments.
Telecommunications: In telecommunications, linear frequency modulation chirp is used for channel estimation and equalization. By transmitting chirp signals through a communication channel, the system can analyze the received signal to estimate the channel‘s frequency response. This information is crucial for equalizing the channel and improving the overall communication quality.
Audio Synthesis: Linear frequency modulation chirp is also utilized in audio synthesis to create unique and dynamic sounds. By modulating the frequency of an oscillator in a linear manner, composers and sound designers can generate interesting and evolving timbres. This technique is commonly used in electronic music and sound effects production.
Medical Imaging: Linear frequency modulation chirp is employed in medical imaging techniques such as ultrasound and magnetic resonance imaging (MRI). In ultrasound imaging, chirp signals are used to generate focused beams and improve image resolution. In MRI, chirp pulses are utilized for spatial encoding and signal acquisition.
Geophysical Exploration: Linear frequency modulation chirp is used in geophysical exploration, particularly in seismic surveys. By transmitting chirp signals into the ground and analyzing the reflected waves, geophysicists can gather information about subsurface structures and geological formations. The linear frequency modulation allows for better resolution and depth penetration.
Non-Destructive Testing: Linear frequency modulation chirp is applied in non-destructive testing (NDT) methods like ultrasonic testing. By transmitting chirp signals into materials and analyzing the reflected waves, defects and anomalies can be detected. The linear frequency modulation helps in distinguishing between different types of reflections and improving the accuracy of defect identification.

Linear Frequency Calculator

A linear frequency calculator is a useful tool that helps in determining the frequency of a signal or waveform. It is particularly helpful in fields such as electronics, telecommunications, and audio engineering. Understanding the concept of linear frequency is essential to comprehend how this calculator works.

Linear frequency refers to a frequency scale that increases or decreases in a linear manner. In other words, the frequency values are evenly spaced apart. This is in contrast to logarithmic frequency scales, where the spacing between values increases exponentially. The linear frequency scale is commonly used in applications where a linear relationship between frequency and some other parameter is desired.

Explanation of How to Use a Linear Frequency Calculator

Using a linear frequency calculator is straightforward and requires only a few simple steps. Let’s walk through the process:

Input the Start and End Frequencies: The first step is to input the start and end frequencies of the desired range. These frequencies define the span over which the linear frequency calculator will operate. For example, if you want to analyze frequencies from 100 Hz to 10 kHz, you would enter these values accordingly.
Specify the Number of Steps: Next, you need to specify the number of steps or intervals you want the linear frequency calculator to divide the range into. This determines the resolution or granularity of the frequency values. A higher number of steps will result in a more detailed analysis but may require more computational resources.
Calculate the Step Size: The step size is calculated by dividing the difference between the end and start frequencies by the number of steps. This value represents the increment between each frequency value in the linear scale.
Generate the Frequency Values: Once the step size is determined, the linear frequency calculator generates the frequency values within the specified range. These values are evenly spaced apart and cover the entire span from the start to the end frequency.
Utilize the Frequency Values: The generated frequency values can now be used for various purposes, such as analyzing the frequency response of a system, designing filters, or generating test signals. The linear frequency scale allows for easy interpretation and comparison of different frequency components.

Using a linear frequency calculator simplifies the process of working with frequency values and enables efficient analysis and manipulation of signals. It eliminates the need for manual calculations and ensures accuracy in determining the frequency range of interest.

Frequently Asked Questions

Q1: What is linear frequency modulation?

A1: Linear frequency modulation is a technique where the frequency of a signal varies linearly with time.

Q2: How is linear frequency modulation synthesized?

A2: Linear frequency modulation synthesis is achieved by varying the frequency of a waveform in a linear manner over time.

Q3: What is linear frequency modulation radar?

A3: Linear frequency modulation radar is a radar system that uses linear frequency modulation to transmit and receive signals, allowing for accurate range and velocity measurements.

Q4: How does linear frequency modulation sonar work?

A4: Linear frequency modulation sonar uses linear frequency modulation to transmit and receive sound waves in water, enabling the detection and location of underwater objects.

Q5: What is the linear frequency modulation equation?

A5: The linear frequency modulation equation describes the relationship between the frequency of a signal and time, typically represented as f(t) = f0 + kt, where f0 is the initial frequency and k is the rate of change.

Q6: Why is frequency important?

A6: Frequency is important because it determines the pitch of a sound or the rate of occurrence of a repeating event, and it is a fundamental parameter in many fields such as communication, signal processing, and physics.

Q7: How does the linear frequency response change when frequency increases?

A7: The linear frequency response describes how a system or device responds to different frequencies. When frequency increases, the linear frequency response may change, resulting in variations in amplitude, phase, or other characteristics of the system’s output.

Q8: What is the ratio of angular frequency and linear frequency?

A8: The ratio of angular frequency (ω) to linear frequency (f) is given by the equation ω = 2πf, where 2π represents a full cycle or 360 degrees.

Q9: How can I calculate the linear frequency?

A9: The linear frequency can be calculated using the formula f = 1/T, where f is the frequency and T is the period of the waveform.

Q10: Why would I want to linearize data?

A10: Linearizing data is often done to simplify analysis or modeling. By transforming non-linear data into a linear form, it becomes easier to apply linear regression techniques or make linear approximations for further analysis.

Angular Frequency Of Oscillation: 5 Facts You Should Know

January 3, 2024October 17, 2021 by Rabiya Khalid

The periodic motion of an object, particle, or quantity at regular intervals about a mean position is known as oscillation.

When a body oscillates, it comprises linear as well as angular displacement, this angular displacement is known as angular frequency of oscillation. There are also other terms in physics for angular frequency such as angular speed orbital frequency.

The angular frequency is the scalar measure of the angular displacement of an oscillating particle. For sinusoidal waves, it is referred to as the rate of phase change. When a ball tied to a rope is rotated in a circular motion, the rate at which it completes one oscillation of 360 degrees is known as the angular frequency.

800px Angularvelocity.svg — Image Credit: User:Stannered, Angularvelocity, CC BY-SA 3.0

Angular Frequency of Oscillation Formula

The change in angle that occurs in one second is termed angular frequency. Hence the basic formula to derive the angular frequency is;

$\omega =\frac{\Theta }{t}$

Here;

ω is the angular frequency

Θ is the angle through which an object is displaced.

t is for the time taken.

For the simple harmonic motion or simply oscillation, the formula of angular frequency is derived by multiplying the linear frequency with the angle that is covered by oscillating particles. For one complete cycle, the angle is 2π. Hence the formula for angular frequency becomes;

ω =2πf

Using the relationship between frequency and time period in the above equation the formula becomes;

$f=\frac{1}{T}$

$\omega =\frac{2\Pi }{T}$

Since angular frequency is angular displacement rate, its unit becomes radian per unit time, that is;

$1 \omega =1 rad\cdot sec^{-1}$

Angular Frequency of Oscillation Spring

Screenshot 2021 10 14 201658 — Angular frequency of oscillation of spring

In the above spring-mass system, on adding the load, the spring displaces to distance y, and the oscillation stretches it to a further x position.

According to Hooke’s law.

$F=ky$

From the diagram, we can see that

$W=mg=ky$

From the free body diagram, we can see that weight is acting downward. Inertia force that is ma is acting upward, and restoring force that is k(x+y) is also acting upward.

We will get:

$ma+kx+y-W=0$

$ma+kx+ky-W=0$

We know that W=ky; hence we get:

$ma+kx=0$

Dividing by m:

$\frac{ma}{m}+ \frac{k}{m}x=0$

$a+ \frac{k}{m}x=0$

On comparing it with the SHM equation, we get:

$\omega^{2} =\frac{k}{m}$

$\omega =\sqrt{\frac{k}{m}}$

This is the angular frequency of the spring oscillation.

Angular Frequency Of Oscillation Pendulum

Oscillation of the pendulum Image Credit: Wikinana38, ลูกตุ้มธรรมชาติ,

Through the figure above, we can see the forces acting on the bob of the pendulum. The gravitational weight is acting downwards. The restoring torque acting on the pendulum is the element of the weight of the bob. From the figure, we get the value of torque as;

$\tau =-L(mgsin\Theta)$

$I\alpha =-L(mgsin\Theta)$

$I\frac{\mathrm{d^{2}}\Theta }{\mathrm{d} x^{2}} =-L(mgsin\Theta)$

$m L^{2}\frac{\mathrm{d^{2}}\Theta }{\mathrm{d} x^{2}} =-L(mgsin\Theta)$

$\frac{\mathrm{d^{2}}\Theta }{\mathrm{d} x^{2}} =-\frac{g}{L}sin\Theta$

$\frac{\mathrm{d^{2}}\Theta }{\mathrm{d} x^{2}} +\frac{g}{L}sin\Theta=0$

For every small angle we have;

$sin\Theta\approx \Theta$

Hence we get;

$\frac{\mathrm{d^{2}}\Theta }{\mathrm{d} x^{2}} +\frac{g}{L}\Theta=0$

Comparing it with the simple harmonic motion equation:

$\frac{\mathrm{d^{2}}x }{\mathrm{d} t^{2}} +\omega^{2}x =0$

We get:

$\omega^{2}=\frac{g}{L}$

$\omega=\sqrt{\frac{g}{L}}$

Here;

g is the acceleration due to gravity, and L is the length of the pendulum.

Angular Frequency of Oscillation Of The Object

For an oscillating object, the SHM equation is given as:

$x=Asin(\omega t+\phi)$

Here;

x is the displacement of the object

A is the amplitude of the oscillation

???? is the phase change

ω is the angular frequency

Angular frequency of oscillation of the object

For the oscillating object, the angular frequency is given as;

ω =2πf

It tells about how much angle the object is rotating for displacing.

How to Find Angular Frequency of Oscillation

For the different objects and scenarios, a different formula is used to calculate the angular frequency of oscillation.

$x=Asin(\omega t+\phi)$

For instance, the amplitude of the oscillation is given to be 0.14m; the phase change is 0. Now to cover 14 cm in 8.5 seconds, the angular frequency is calculated using the formula;

$0.14=0.14sin(8.5\omega)$

$1=sin(8.5\omega)$

$sin^{-1}1=8.5\omega$

$\frac{\pi}{2}=8.5\omega$

$\omega=\frac{\pi}{16.2} rad\cdot s^{-1}$

For calculating the angular frequency of the pendulum, the formula used is;

$\omega=\sqrt{\frac{g}{L}}$

For example, if the length of the pendulum is 10 cm, then the angular frequency of oscillation is;

$\omega=\sqrt{\frac{10}{0.10}}$

$\omega=\sqrt{100}$

$\omega=10 rad. s^{-1}$

To calculate the angular frequency of spring, the formula is:

$\omega=\sqrt{\frac{k}{m}}$

If the spring constant is given to 2 N/m and mass is given to be 8 kg, then the angular frequency would be;

$\omega=\sqrt{\frac{2}{8}}$

$\omega=\sqrt{\frac{1}{4}}$

$\omega=\frac{1}{2}$

$\omega=0.5 rad. s^{-1}$

Frequently Asked Questions (FAQs)

What is the angular frequency of oscillation?

The repetitive motion of a particle about a fixed point is known as oscillation.

The angle change of the particle is the angular frequency of oscillation. In physics, it is also termed the rate of change of phase. It is a scalar element as it is just the angular displacement without any direction. The formula for the angular frequency is given as;

ω =2πf

How is angular frequency is related to the time period?

The oscillating objects are comprised of both linear displacements as well as angular displacement.

The basic formula for angular frequency is given as;

$\omega=\frac{\Theta }{t}$

It shows the relation of time and angular frequency of oscillation.

Now the general formula for angular frequency is:

ω =2πf

Substituting the given relation

$f=\frac{1}{T}$

We get;

$\omega=\frac{2\Pi }{T}$

This equation relates angular frequency and time period.

What is the unit of angular frequency?

The angular frequency is the change in angle of the oscillating particle in unit time.

The unit of the angular frequency is given as radian per unit sec such as;

$1 \omega=1 rad\cdot s^{-1}$

When the object covers one complete cycle in one second, then the angular frequency becomes 1.

Is angular frequency the same as frequency?

The number of oscillations the object makes in one second is known to be the frequency.

No, the frequency and angular frequency are not the same things. Angular frequency is the change in the angle of the oscillating particle in unit time, whereas the frequency is the oscillation made in one second. They both are different terms used for a different concept of physics.

9 Examples Of Angular Motion

January 1, 2024October 16, 2021 by Sanchari Chakraborty

Angular or rotational motion is an important part of kinematics in physics. The application of angular motion can be seen in several day-to-day activities.

Some angular motion examples are:

Figure skating, Acrobatics, Gymnastics
Freestyle swimming
Swinging of a cricket or baseball bat
Swinging of a badminton or tennis racket
Running or racing on a circular track
Leveraging on a hockey stick
Swinging
Paddling a bicycle
Rowing a boat
Churning milk

Let us learn about the angular motion examples in detail.

1. Figure skating, Acrobatics, Gymnastics:

In the sport of figure skating or gymnastics player or the performer is required to maintain an angular velocity while traveling in different patterns of circular or curved paths. These players move across an angle along an axis. Angular motion can be easily identified in this kind of activity.

angular motion examples — *A figure skater demonstrating the use of angular motion. *Angular motion examples* Image source:* *deerstop*, *Cup of Russia 2010 – Yuko Kawaguti (2)*, *CC0 1.0*

2. Freestyle swimming

Swimming involves the movement of the player in an angular motion around a very long axis. The swimmer is required to maintain a steady angular velocity during freestyle swimming so that they do not lose balance in the water. Angular motion can be easily identified in swimming also.

3. Swinging of a cricket or baseball bat:

In sports like cricket or baseball, the player is required to swing their bat to hit the ball. The motion of the swing is a type of angular motion. The batsman swings the bad with the steady angular velocity around an axis. The way that the bat is swung determines the direction in which the ball will travel and the location where the ball will land.

4. Swinging of a badminton or tennis racket:

In sports like badminton and tennis reply is required to hit the ball or the shuttlecock with the racket. This involves a swinging action that is a type of angular motion. The racquet is swung with a certain velocity around an axis of rotation. This Singh action determines the direction in which the ball or the shuttlecock will travel and the location where it will land.

5. Running or racing on a circular track:

Running a racing on a circular track in a car, bike, cycle, or by feet involves the action of angular motion. The person or the vehicle travels at a certain velocity around an axis. It is considered to be essential to retain a suitable angular momentum to elude the happening of any form of accident.

6. Leveraging on a hockey stick:

In the sports of hockey, one has to hit the hockey puck with a hockey stick. Leveraging the black with the hockey stick involves angular motion. The mistake revolves round an axis with a certain velocity. The angular motion of the hockey sticks in this case determines the direction and the distance that the puck will go.

7. Swinging:

Swings in playgrounds are operated totally on angular motion principles. This swing moves around a fixed axis of rotation. For the swinging action to occur, the person has to provide force externally.

8. Paddling a bicycle:

The paddling of a bicycle involves the rotation of the paddle around a fixed axis at a certain velocity. For the paddling action to take place the person needs to provide external force.

9. Rowing a boat:

To row a boat, one needs to swing the ore with a certain velocity along an axis of rotation. For the rowing action to take place force needs to be provided externally.

10. Churning milk:

To turn milk one uses a stick-shaped object to stir the milk. Stirring the stick involves the use of angular motion. This motion enables the stick to rotate around an axis at a certain velocity.

Therefore, we can find the application of angular motion in several sports activities. In fact, angular motion plays a major role in determining how the sport is played. To understand more about angular motion, give the following paragraphs a read.

FAQs

What is angular motion?

Angular motion is a common occurrence that we can see in our daily lives.

In physics, angular motion is said to represent the motion of an object rotating around a fixed axis or point at a certain velocity. Mathematically, angular motion is given by the angle subtended by the body in its course of motion along an axis or a fixed point. Suppose we fix a pin in the center of a table and attach a thread with the pin. On the other end of the thread if we attach an object and move it in a motion such that the thread remains straight throughout, then the angle covered during its motion is termed angular motion.

What is angular momentum?

Angular momentum (also known as moment of momentum or rotational momentum) refers to the rotational or angular equivalent of linear momentum.

Mathematically, angular momentum in three dimensions is given by the cross product of the position of the object i.e. position vector with the momentum vector of the object (Linear momentum vector of an object is given by the product of mass and velocity i.e. p = mv). This can be represented as r × p, and this makes angular momentum a pseudo-vector quantity.

Linear momentum does not depend on the origin reference point whereas the angular momentum depends largely on the reference point for the origin as the position vector of the object is measured from the reference point. The net angular momentum of a closed system is said to remain constant. For this reason, angular momentum is considered to be a conserved physical quantity.

*Diagrammatic representation of the angular momentum of an object with mass m. *Angular motion examples* Image source:* *Tfr000, Ang mom 2d,* *CC BY-SA 3.0*

What is angular velocity?

Angular velocity in physics can be further classified into two major subcategories: orbital angular velocity and other is spin angular velocity.

Orbital Angular velocity: Orbital angular velocity gives us information about how much time a rigid object takes to revolve around a fixed reference point or origin. Orbital angular momentum basically provides the rate of change of the angular position of a rigid body with respect to the given origin.

*Diagrammatic representation of orbital angular velocity. Angular motion examples Image source:* *dnet* *based on raster version released under GFDL,* *Angular velocity*, *CC BY-SA 3.0*

Spin angular velocity: Spin angular velocity gives us information about how much time a rigid object takes to rotate with respect to its central axis of rotation. Spin angular velocity does not depend on the reference point or the origin. This factor makes it different from the orbital angular velocity.

The dimension of angular velocity is given by angle per unit time which in SI unit becomes radian per unit second.

Does angular velocity change in circular motion?

Angular velocity of a rigid body moving in a circular motion remains constant i.e. it does not change with time.

When an object moves in a circular motion it covers an equal amount of angles in an equal amount of time around a fixed point. The position vector of the object from the origin remains constant in magnitude throughout i.e. R (radius of the circle). Hence we can say that the angular velocity remains constant for an object that travels in a circular motion.

What is the angular velocity of Earth?

Earth revolves around the sun in an angular motion. It also rotates around a fixed axis with a certain velocity.

The angular velocity of the Earth rotating around a fixed axis is given by w and is equivalent to 15.04108°/mean solar hour based on a sidereal day. This is equal to 360°/23 hours 56 minutes 4 seconds i.e. approximately one day. The angular velocity of the Earth can be denoted in terms of radian/second by the formula w(earth) = 2π/T, where T is the time taken to complete one rotation i.e. 23 hours 56 minutes 4 seconds.

Earth rotation 1 — Rotation of the Earth around its axis. Angular motion examples. Image source: Angular motion examples. Maulor, Earth rotation, CC BY-SA 4.0

We hope this post could provide the necessary information related to angular motion examples.

Amplitude Of Oscillation: 11 Complete Quick Facts

January 2, 2024October 15, 2021 by Rabiya Khalid

The regular change of the physical quantity about the central points is known as oscillation. The state is changed between two extreme points.

The maximum displacement of the oscillation from the mean position to either side of points is known as the amplitude of oscillation. It is also stated as the magnitude of change of oscillating quantity.

The constant to and fro movement of any variable or object between two fixed points is known as oscillation. The peak value or displacement that the oscillating object reaches is known as its amplitude. The pendulum, springs, guitar strings are all examples of oscillation. In the figure given above, the ball moves from point O to point A and then from there to point O then to B. On calculating the length between O and A or O and B we get the amplitude of the oscillation.

Amplitude of oscillation formula

The amplitude of oscillation is represented as A. For the full range oscillation, the magnitude is derived as 2A. Since oscillation is a periodic function, its wave equation is represented as a sine or cosine function. The formula for the amplitude of the oscillation is;

x = A sin ωt

x = A cos ωt

x is the displacement of the particle

A is the maximum amplitude

ω is the angular frequency

t is the time interval

Φ is phase shift

Frequency of oscillation units

The frequency provides you with the knowledge of oscillations made per unit second. It is also stated as the cycle completed in 1 second. One cycle means one complete oscillation.

The frequency is represented as f. The relationship between the frequency and time period is given as;

f = 1/T

f is the frequency and T is the time period of the oscillation.

The S.I unit of frequency is given as;

f = 1 cycle / 1 second

Hence the unit of frequency is Hertz, Hz.

Amplitude of oscillation spring

The motion of a spring is an example of oscillation. When we press or pull the spring, it comes into continuous motion. This type of continuous motion is known as simple harmonic motion.

The spring can be in two arrangements;

Vertical system
Horizontal system

Vertical System

1200px Vertical mass on spring 2.svg — Image Credit: MikeRun, Vertical-mass-on-spring-2,

Here as shown in the figure, the string is fixed at a point and hanging vertically. When the load hangs on the spring it stretches to the length y and then starts oscillating. The figure shows the maximum and minimum displacement as +A and -A.

The angular frequency is given as:

t = k/m

Where;

t = 2f

The solution equation of the spring oscillation is:

x = A sin ωt

Horizontal System

1200px Horizontal mass on spring.svg 1 — Image Credit: MikeRun, Horizontal-mass-on-spring, CC BY-SA 4.0

The amplitude of any kind of simple harmonic motion is using the given equation;

x = A sin ωt

The energy changes at every point between kinetic and potential energy. The total energy always remains constant. Hence, we get;

E_total = U + k

The position and velocity equation of the oscillation is defined as;

x = A cos ωt

Using the trigonometric identity:

cos² + sin² = 1

and

ω² = k/m

We get:

E_total = 1/2 KA²

This equation represents the relationship between the total energy of the spring system and the amplitude. Hence the given equation is used to calculate the amplitude of spring oscillation.

Amplitude of oscillation pendulum

768px Simple pendulum height.svg — Image credit: https://commons.wikimedia.org/wiki/File:Simple_pendulum_height.svg

A pendulum is a small bob tied to a thread. It swings to generate oscillation. The amplitude of pendulum oscillation is measured as the maximum displacement that a bob covers starting from the central position. The central position is the initial position of the bob when it is in the rest position. Some refer to this as origin or equilibrium position. The pendulum moves back and forth starting from this point. The largest distance that the bob covers on either side is its “amplitude.” On both sides, the amplitude remains the same. For instance, if a bob covers 3 cm on the left side, it will displace to the same extent on the right side.

Amplitude of oscillation units

The ampitude is the maximum length that a particle covers from its equilibrium position. Since amplitude is a distance travelled hence its unit is a meter that is ‘m’. The meter is the standard unit of amplitude, but other units are also used. Kilometre km’, centimetre cm,’ and millimetre mm’ are some other units.

Amplitude of oscillation of simple pendulum

The simple pendulum is a particular type of pendulum whose bob’s size is much smaller than the distance of the object’s centre of gravity and point of suspension. The amplitude of the simple pendulum does not have any effect on the time period. With the increase in amplitude, the restoring force also increases, which cancels out the effect.

On comparing the oscillation of simple pendulum with the uniform circular motion we get the following solution equation;

x = A cos ωt

x for instantaneous displacement

ω is the angular frequency

t is for time intervals.

This equation is used when the starting point of the pendulum oscillation is taken as the extreme point. In case the oscillation starts from the mean position, the equation becomes;

x = A sin ωt

Amplitude of oscillation diagram

Oscillation is a simple harmonic motion whose equation can be represented as a function of sine and cosine. Hence its diagram is depicted as a wave graph.

If an oscillating variable undergoes regular back and forth motion, then the peak value that the particle displaces gives out the amplitude of the variable. For all types of diagrams, the amplitude remains the same: the maximum displacement of waves.

Amplitude of oscillation of a particle

The absolute length of vibration or displacement of a sinusoidal oscillation from the equilibrium position is its amplitude. It is the maximum size of a periodically varying particle. The difference of any physical particle from its extreme position and mean position determines its amplitude.

It simply tells us the magnitude of the particle oscillation. The formula for sinusoidal oscillations is;

y = A sin ωt

where | A | is the absolute value of A.

The amplitude variable represents a sinusoidal oscillation. It provides the deflection of a particle from its mean point to a positive or negative value. The particle displacement is particle amplitude. A transverse wave can be described with its distinguished amplitude. Every particle frequency, such as a string, pendulum, and spring, has an amplitude.

How to find amplitude of oscillation

To find the amplitude of oscillation, the general formula used is;

x = A sin ωt + Φ

Where,

x is the displacement of the particle

A is the maximum amplitude

ω is the angular frequency

t is the time interval

Φ is a phase shift.

For instance, a pendulum is swinging with angular speed = π radians and phase shift = 0. Then the amplitude of the pendulum, which covers 14 cm in 8.50 seconds are;

x = A sin ωt + Φ = A sint (0.14*0.85) + 0 = 146 cm

Then the amplitude can be easily found by examining the equation. In this case, the amplitude is 6.

Screenshot 2021 10 14 200024 — Amplitude Of Oscillation

The next case is when the graph of the oscillation is provided. Here we can see the maximum displacement of the wave on either side is. Hence the amplitude is 5.

Frequency of oscillation of a spring-mass system

In the above spring-mass system on adding the load the spring displaces to distance y and the oscillation stretches it to a further x position.

According to Hooke’s law.

F=ky

From the diagram, we can see that

W = mg = ky

From the free body diagram, we can see that weight is acting downward. Inertia force that is ma is acting upward and restoring force that is k(x+y) is also acting upward.

We will get:

ma + k (x+y) – W = 0

We know that W= ky, hence we get:

ma + kx = 0

Dividing by m:

a + k/m x = 0

On comparing it with the SHM equation we get:

f = 1/2 √k/m

This is the frequency of the spring-mass system oscillation.

Frequently Asked Questions (FAQs)

What is oscillation?

The oscillation occurs in every area of physics and day-to-day life.

The oscillation is the repetitive too and fro motion of a particle, object, or quantity in time. The oscillating particles move about the mean position to the extreme points on either side. Simple pendulum, spring, playground swings are all examples of oscillation.

How are oscillation and periodic motion different?

The motion can be of two types oscillation or periodic motion.

The periodic motion is the regular movement of a particle at regular intervals. At the same time, oscillation is just the back-and-forth motion of a vibrating object. Every oscillatory motion is periodic, but the converse need not be true. The earth revolves around the sun, which is a periodic function as it keeps repeating itself after a fixed time. A swing is an oscillatory object.

What is the amplitude of oscillation?

The repetitive motion of a particle is known as oscillation.

The extent to which a particle can displace is its amplitude. The displacement is measured from the mean position to either side of the extreme position. ‘A’ represents the amplitude of oscillation, and its standard unit is meter.

Is oscillation a simple harmonic motion?

The motion proportional to the displacement and under the effect of retarding force is known as simple harmonic motion.

The SHM is an oscillatory motion. Or we can say that oscillation is a simple harmonic motion. For example, the spring moves under the influence of Hooke’s law, and its motion is proportional to displacement. Hence it is an SHM oscillation.

What is the equation of oscillating particles?

The oscillation is the simple harmonic motion.

The equation of oscillation is as follow;

x = A sin ωt + Φ

Where,

x is the displacement of the particle

A is the maximum amplitude

ω is the angular frequency

t is the time interval

Φ is phase shift

How to Find Magnitude of Net Force: 3 Scenarios Solved !

January 2, 2024October 10, 2021 by Rabiya Khalid

In physics, understanding the magnitude of net force is crucial for analyzing the motion of objects. net force refers to the combined effect of all the forces acting on an object. In this blog post, we will explore how to calculate the magnitude of net force, determine its direction, and calculate the magnitude of resultant force. We will cover the concepts, formulas, and provide worked-out examples to help you grasp the core ideas quickly and easily. So, let’s dive into the world of forces and learn how to find the magnitude of net force step by step.

How to Calculate the Magnitude of Net Force

Identifying the Forces Acting on an Object

To calculate the magnitude of net force, we must first identify all the forces acting on an object. forces can be classified into various types, such as gravitational force, frictional force, normal force, and applied force. Each force has its own unique characteristics, and they can either act in the same direction or in opposite directions.

Understanding the Direction of Forces

Before calculating the magnitude of net force, it is essential to understand the direction of forces. forces are vector quantities, which means they have both magnitude and direction. To determine the net force, we need to consider the sign or direction of each force. forces acting in the same direction can be added together, while forces acting in opposite directions can be subtracted from each other.

The Mathematical Approach to Calculating Net Force

The net force is the vector sum of all the forces acting on an object. To calculate the magnitude of net force, we can use the following formula:

$Net Force = F_1 + F_2 + F_3 + ... + F_n$

Here, (F_1, F_2, F_3, …, F_n) represent the individual forces acting on the object. The net force is the total of all these forces.

Worked Out Examples on Finding the Magnitude of Net Force

Example of Calculating Net Force in Linear Motion

Let’s consider an example to illustrate how to calculate the magnitude of net force in linear motion. Suppose a car is experiencing two forces: an applied force of 500 N in the forward direction and a frictional force of 200 N in the opposite direction. To find the net force, we can subtract the frictional force from the applied force:

$Net Force = 500 N - 200 N = 300 N$

Therefore, the magnitude of the net force acting on the car is 300 N.

Example of Calculating Net Force in Circular Motion

In circular motion, an object experiences a net force towards the center of the circle, known as the centripetal force. Let’s consider an example where a car is moving in a circular path with a radius of 10 meters at a constant speed of 20 m/s. The mass of the car is 1000 kg. To calculate the magnitude of net force, we can use the formula:

$Net Force = frac{m cdot v^2}{r}$

Substituting the given values, we have:

$Net Force = frac{1000 kg cdot (20 m/s)^2}{10 m} = 40000 N$

Therefore, the magnitude of the net force acting on the car in circular motion is 40000 N.

Example of Calculating Net Force without Acceleration

Sometimes, an object may experience forces that cancel each other out, resulting in no net force. Let’s consider an example where a box is resting on a table. The weight of the box is 50 N, and the normal force exerted by the table is also 50 N in the opposite direction. Since these two forces are equal in magnitude but opposite in direction, the net force on the box is zero. In this case, the box remains in equilibrium and does not accelerate.

How to Determine the Magnitude and Direction of Net Force

Understanding the Concept of Direction in Physics

In physics, direction plays a vital role when considering forces. When forces act in the same direction, their magnitudes can be added to find the net force. However, when forces act in opposite directions, their magnitudes can be subtracted to determine the net force.

Steps to Determine the Direction of Net Force

To determine the direction of the net force, you can follow these steps:

Identify all the forces acting on the object.
Assign positive (+) or negative (-) signs to each force depending on their direction.
Add the magnitudes of the forces with the appropriate signs.
The resulting sign (+ or -) will indicate the direction of the net force.

Worked Out Example on Finding the Direction of Net Force

Let’s consider an example to understand how to find the direction of net force. Suppose an object is experiencing an applied force of 100 N in the positive x-direction and a frictional force of 50 N in the negative x-direction. To find the direction of the net force, we subtract the magnitude of the frictional force from the applied force:

$Net Force = 100 N - 50 N = 50 N$

Since the magnitude of the net force is positive, we can conclude that the net force is acting in the positive x-direction.

How to Calculate the Magnitude of Resultant Force

Understanding the Concept of Resultant Force

The resultant force is the single force that has the same effect as all the individual forces acting on an object. It represents the combined effect of multiple forces. To calculate the magnitude of the resultant force, we need to consider both the magnitude and direction of the individual forces.

The Mathematical Approach to Calculating Resultant Force

To calculate the magnitude of the resultant force, we can use vector addition. For two forces, (F_1) and (F_2), acting at an angle (theta) to each other, the formula for calculating the resultant force is:

$Resultant Force = sqrt{F_1^2 + F_2^2 + 2 cdot F_1 cdot F_2 cdot cos(theta)}$

Here, (cos(theta)) represents the cosine of the angle between the two forces.

Worked Out Example on Finding the Magnitude of Resultant Force

Let’s consider an example to illustrate how to calculate the magnitude of the resultant force. Suppose two forces, (F_1) and (F_2), are acting on an object at an angle of 60 degrees to each other. If (F_1) is 50 N and (F_2) is 30 N, we can calculate the magnitude of the resultant force using the formula mentioned earlier:

$Resultant Force = sqrt{(50 N)^2 + (30 N)^2 + 2 cdot (50 N) cdot (30 N) cdot cos(60^circ)}$

Simplifying the equation, we get:

$Resultant Force = sqrt{2500 N^2 + 900 N^2 + 3000 N^2} = sqrt{6400 N^2} = 80 N$

Therefore, the magnitude of the resultant force is 80 N.

Remember, understanding the concepts, formulas, and steps to calculate net force, its direction, and resultant force is essential for solving physics problems effectively. By applying these principles, you can analyze the motion of objects and gain a deeper understanding of the forces at play. With practice and careful consideration, you’ll become more proficient at finding the magnitude of net force and interpreting its implications in various scenarios.

Quick Facts

Q: How do you find the net force of an object using the net force equation?

A: To find the net force acting on an object, you simply add together all the force vectors acting on the object. If some forces are acting in opposite directions, they will effectively cancel out in part or in whole. This process involves understanding how to correctly add vectors, which consider both the magnitude of the force and its direction.

Q: Can you explain the net force definition?

A: The definition of net force is the vector sum of all the forces acting on an object. In simpler terms, net force is the sum of all push and pull forces acting on an object. If all the forces cancel each other out, the net force is zero, and the object remains stationary or continues moving at a steady speed. If the forces do not cancel each other out, the net force is an unbalanced force, and the object will accelerate.

Q: What does a net force diagram look like?

A: In a net force diagram, also known as a force diagram, vectors are used to represent forces. Each vector’s length corresponds to the magnitude of a force, and its direction corresponds to the direction of the force. The net force is represented by the resultant vector, obtained from the vector sum of individual forces.

net force diagram

Q: Can you provide examples of net force applications?

A: Imagine you’re playing tug-of-war. The team that applies more force in its direction will make the rope move towards them. The net force in this case is the difference between the two teams’ forces. Another example would be pushing a block on a surface. If you push a block and friction pushes it back, the net force will be the difference between your force and the friction force.

net force in circular motion

Q: What happens when a single force acts on an object?

A: When a single force acts on an object, and no other forces are present or if all other forces balance out perfectly, the net force on the object is equal to that single force. The object will accelerate in the direction of the net force, according to Newton’s second law of motion.

Q: Could you explain acceleration of an object using a net force formula and force equation?

acceleration from net force

A: Sure! Newton’s second law states that the net force on an object is equal to the mass of the object multiplied by its acceleration. This can be expressed as F = ma, where F is the net force, m is the mass of the object, and a is its acceleration. To solve for acceleration, rearrange the equation as a = F/m. Meaning the acceleration of an object is equal to the net force acting upon it divided by its mass.

Q: What do horizontal and vertical components of a force vector represent?

A: Any force vector can be broken down into vertical and horizontal components. The vertical component of the force represents the force exerted in the up and down direction, while the horizontal component represents the force exerted in the left and right direction. These components are especially crucial in cases where forces are acting at angles.

Q: Can you calculate the magnitude of force using horizontal and vertical components?

A: Yes, you can. The magnitude of a force can be calculated by taking the square root of the sum of the squares of its horizontal and vertical components. This application stems from the Pythagorean theorem.

The formula for calculating the magnitude (F) of the force using its horizontal (F_x) and vertical (F_y) components is:

$F = sqrt{F_x^2 + F_y^2}$

Worked-Out Example:

Suppose we have a force with a horizontal component of 6 N and a vertical component of 8 N. To find the magnitude of this force, we will use the formula mentioned above.

Step 1: Square the components: $F_x^2 = (6 , text{N})^2 = 36 , text{N}^2$ $F_y^2 = (8 , text{N})^2 = 64 , text{N}^2$

Step 2: Add the squares of the components: $F_x^2 + F_y^2 = 36 , text{N}^2 + 64 , text{N}^2 = 100 , text{N}^2$

Step 3: Take the square root of the sum to find the magnitude: $F = sqrt{100 , text{N}^2} = 10 , text{N}$

Therefore, the magnitude of the force is 10 N.

Q: Why is the direction of the net force important?

A: The direction of the net force is important because force is a vector quantity, meaning it has both magnitude and direction. The net force’s direction determines the direction of the acceleration or movement of the object.