Displacement And Force: 9 Facts (Read This First!)

Introduction:

Displacement and force are fundamental concepts in physics that help us understand the motion of objects. Displacement refers to the change in position of an object, while force is a push or pull that can cause an object to move, stop, or change direction. These two concepts are closely related, as force can cause displacement, and displacement can be used to calculate the force applied to an object. Understanding the relationship between displacement and force is crucial in various fields, including engineering, mechanics, and sports.

Key Takeaways:

DisplacementForce
Change in position of an objectPush or pull that causes motion
Measured in meters (m)Measured in Newtons (N)
Can be positive or negativeCan be positive or negative
Vector quantityVector quantity
Can be calculated using initial and final positionsCan be calculated using mass and acceleration

Understanding the Relationship Between Displacement and Force

How Displacement is Related with Force?

524px SHM answer.svg
Wikimedia Commons

In the field of physics, the relationship between displacement and force is a fundamental concept that helps us understand the behavior of objects in motion. Displacement refers to the change in position of an object, while force is the push or pull applied to an object. These two concepts are closely intertwined, as force can cause displacement and displacement can also affect the force acting on an object.

When a force is applied to an object, it can cause the object to move from its initial position to a new position. The magnitude and direction of the force determine the magnitude and direction of the displacement. According to Newton’s Laws of Motion, the force acting on an object is directly proportional to the rate of change of its momentum, which is the product of its mass and velocity. Therefore, a larger force will result in a greater displacement, while a smaller force will result in a smaller displacement.

Different Effects of Force

The effects of force on an object can vary depending on the circumstances. Here are some different effects that force can have:

  1. Acceleration: When a force is applied to an object, it can cause the object to accelerate. Acceleration is the rate at which an object’s velocity changes over time. The relationship between force, mass, and acceleration is described by Newton’s second law of motion, which states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass.

  2. Work Done: When a force acts on an object and causes it to move, work is said to be done. Work is defined as the product of the force applied to an object and the displacement of the object in the direction of the force. The unit of work is the joule (J), and it represents the transfer of energy from one object to another.

  3. Energy and Power: The work done by a force can result in a change in the object’s energy. Energy is the ability to do work, and it exists in different forms such as kinetic energy and potential energy. Power, on the other hand, is the rate at which work is done or energy is transferred. It is calculated by dividing the work done by the time taken.

  4. Friction and Gravity: Forces such as friction and gravity can also affect the displacement of an object. Friction is a force that opposes the motion of an object when it is in contact with another surface. Gravity, on the other hand, is a force that attracts objects towards each other. Both of these forces can either assist or resist the displacement of an object, depending on the circumstances.

Displacement and Force Definition

To have a clear understanding of the relationship between displacement and force, it is important to define these terms:

  • Displacement: In physics, displacement refers to the change in position of an object from its initial position to its final position. It is a vector quantity, which means it has both magnitude and direction. Displacement is measured in units such as meters (m) or kilometers (km).

  • Force: Force is a vector quantity that represents the push or pull applied to an object. It is measured in units called newtons (N). Force can cause an object to accelerate, decelerate, or change direction. It can also deform or break objects depending on their elasticity.

Displacement and Force Relation

The relationship between displacement and force can be summarized as follows:

  • When a force is applied to an object, it can cause the object to undergo a displacement. The magnitude and direction of the displacement depend on the magnitude and direction of the force.

  • The relationship between force and displacement is described by Newton’s Laws of Motion. These laws provide a mathematical framework for understanding the behavior of objects in motion.

  • The first law, also known as the law of inertia, states that an object at rest will remain at rest, and an object in motion will continue moving in a straight line at a constant velocity unless acted upon by an external force.

  • The second law states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass.

  • The third law states that for every action, there is an equal and opposite reaction. This means that when a force is applied to an object, the object exerts an equal and opposite force back on the source of the original force.

Displacement Force Relationship

In conclusion, the relationship between displacement and force is a fundamental concept in physics. Understanding this relationship allows us to analyze and predict the behavior of objects in motion. Whether it’s calculating the acceleration of a moving car or determining the work done by a force, the concepts of displacement and force play a crucial role in our understanding of the physical world.

Mathematical Representation of Displacement and Force

In the field of physics, the mathematical representation of displacement and force plays a crucial role in understanding the principles of motion and the behavior of objects. These concepts are fundamental to Newton’s Laws of Motion and are essential for analyzing various physical phenomena.

What is the Formula of Force and Displacement?

Baseball pitching motion 2004
Wikipedia

The formula for force is given by Newton’s second law of motion, which states that force is equal to the product of mass and acceleration. Mathematically, it can be represented as:

Force (F) = Mass (m) x Acceleration (a)

On the other hand, displacement is a vector quantity that represents the change in position of an object. The formula for displacement can be expressed as:

Displacement (d) = Final Position (xf) – Initial Position (xi)

Formula for the Displacement

To calculate the displacement of an object, we need to know its initial and final positions. By subtracting the initial position from the final position, we can determine the change in position or displacement. This can be represented mathematically as:

Displacement (d) = xf – xi

Product of Force and Displacement

When a force acts on an object and causes it to move, the work done can be calculated by multiplying the force applied by the displacement of the object. The formula for the work done is given by:

Work (W) = Force (F) x Displacement (d)

Formula for the Work

Tension shear test load crosshead displacement curves
Wikimedia Commons

The work done on an object is equal to the force applied multiplied by the displacement of the object in the direction of the force. Mathematically, it can be expressed as:

Work (W) = F x d

Displacement Force Formula

In some cases, the force acting on an object may not be constant. In such situations, the displacement force formula can be used to calculate the work done. This formula takes into account the varying force acting on the object over a given displacement. It can be represented as:

Work (W) = ∫ F(x) dx

Here, ∫ represents the integral, F(x) is the force as a function of displacement, and dx represents an infinitesimal displacement.

By understanding and utilizing these mathematical representations of displacement and force, we can analyze and solve various problems related to motion, energy, and the behavior of objects in the physical world. These concepts are fundamental to many branches of physics, including kinematics, dynamics, and statics, and are essential for understanding the fundamental laws that govern the universe.

Remember, physics is a vast field that encompasses a wide range of topics, including thermodynamics, quantum mechanics, and relativity. Each of these areas has its own set of mathematical representations and formulas that are used to describe and analyze different phenomena. So, whether you’re studying the motion of objects, the behavior of waves, or the principles of fluid mechanics, the mathematical representation of displacement and force will always be a fundamental aspect of your studies.

Graphical Representation of Displacement and Force

Displacement and Force Graph

In the field of physics, graphical representation plays a crucial role in understanding various concepts related to motion, forces, and their interactions. One such representation is the graph that depicts the relationship between displacement and force. This graph provides valuable insights into the behavior of objects and the forces acting upon them.

When we talk about displacement, we refer to the change in position of an object with respect to a reference point. Displacement is a vector quantity, meaning it has both magnitude and direction. On the other hand, force is a scalar quantity that represents the push or pull exerted on an object.

The Displacement and Force Graph visually represents the relationship between these two quantities. The x-axis of the graph represents displacement, while the y-axis represents force. By plotting data points on this graph, we can observe patterns and trends that help us analyze the behavior of objects under different forces.

Let’s take an example to understand this better. Consider a simple scenario where an object is subjected to a constant force. As the displacement of the object increases, the force acting upon it also increases proportionally. This relationship is represented by a straight line on the Displacement and Force Graph.

Displacement Vector and Force

In addition to the Displacement and Force Graph, we also have the concept of displacement vectors and force. A displacement vector represents the magnitude and direction of the change in position of an object. It is denoted by an arrow, where the length of the arrow represents the magnitude of displacement, and the direction of the arrow represents the direction of displacement.

Similarly, force can also be represented as a vector quantity. The force vector depicts the magnitude and direction of the force acting upon an object. By considering both the displacement vector and force vector, we can analyze the relationship between the two quantities more comprehensively.

In the context of the Displacement and Force Graph, the displacement vector and force vector provide a visual representation of the magnitude and direction of these quantities. By examining the lengths and directions of these vectors, we can gain a deeper understanding of how displacement and force are related in a given scenario.

To summarize, the graphical representation of displacement and force through the Displacement and Force Graph, along with the concept of displacement vector and force vector, allows us to analyze the behavior of objects under different forces. This understanding is crucial in the study of physics and helps us apply Newton’s Laws, understand motion, velocity, acceleration, and various other concepts related to forces and their effects on objects.

Remember, if you want to explore more about physics or any other topic, you can always refer to reliable sources or consult experts in the field.

The Role of Angles in Displacement and Force

In the study of physics, angles play a crucial role in understanding the relationship between displacement and force. By examining the angle between these two quantities, we can gain valuable insights into the nature of motion and the work done on an object. Let’s explore the significance of angles in displacement and force in more detail.

Angle Between Displacement and Force

The angle between displacement and force is an important factor in determining the work done on an object. When a force is applied to an object and causes it to move, the displacement of the object and the direction of the force may not always align perfectly. The angle between these two vectors affects the amount of work done on the object.

To calculate the work done, we use the formula:

Work = Force x Displacement x cos(θ)

Here, θ represents the angle between the force vector and the displacement vector. The cosine of the angle is used because it accounts for the component of the force that is parallel to the displacement. If the force and displacement vectors are perpendicular (θ = 90°), the work done will be zero since the cosine of 90° is zero.

What is the Angle Between Force and Displacement in Negative Work?

Negative work occurs when the force and displacement vectors are in opposite directions. In this case, the angle between the force and displacement vectors is 180°. When the force opposes the direction of displacement, the work done on the object is negative. This means that energy is being transferred out of the system.

For example, when you push a box across a rough surface, the force you apply is in the forward direction, while the displacement of the box is in the opposite direction. The angle between the force and displacement vectors is 180°, resulting in negative work being done on the box due to the frictional force.

What is the Angle Between Force and Displacement in Minimum Work?

The angle between the force and displacement vectors in minimum work depends on the specific scenario. In some cases, the angle may be zero, indicating that the force and displacement vectors are perfectly aligned. This occurs when the force is applied in the same direction as the displacement, resulting in maximum work being done on the object.

On the other hand, if the force is applied at an angle to the displacement vector, the angle will be greater than zero. In such cases, the work done on the object will be less than the maximum possible value. The angle between the force and displacement vectors determines the efficiency of the work done on the object.

Understanding the role of angles in displacement and force allows us to analyze and predict the behavior of objects in various physical scenarios. By considering the angle between these vectors, we can calculate the work done, determine the direction of energy transfer, and gain insights into the dynamics of motion.

Remember to check out our other articles on various topics related to physics, such as Newton’s Laws, motion, velocity, acceleration, mass, momentum, vector quantity, scalar quantity, work done, energy, power, friction, gravity, mechanical advantage, simple machines, kinematics, dynamics, statics, equilibrium, torque, impulse, conservation laws, elasticity, inertia, kinetic energy, potential energy, centripetal force, angular momentum, oscillations, waves, fluid mechanics, thermodynamics, quantum mechanics, and relativity.

For more information about the city of Austin, including business, health, and government services, you can visit the official city website.

Practical Applications and Problem Solving

Physics, with its foundation in Newton’s Laws, is a fundamental science that helps us understand the motion, forces, and interactions of objects in the universe. It has numerous practical applications in various fields, from engineering and technology to medicine and environmental sciences. By applying the principles of physics, we can solve real-world problems and make informed decisions.

Problem Statement with Solution 1

Let’s consider a scenario where we have a car of mass 1000 kg moving with an initial velocity of 10 m/s. The car applies a constant force of 5000 N to accelerate. We need to find the final velocity of the car after 5 seconds.

To solve this problem, we can use the equation of motion:

Final Velocity = Initial Velocity + (Acceleration * Time)

Here, the initial velocity is 10 m/s, the acceleration can be calculated using Newton’s second law (F = ma), and the time is 5 seconds. Plugging in the values, we can find the final velocity of the car.

Problem Statement with Solution 2

Let’s consider another problem where we have a block of mass 5 kg resting on a horizontal surface. The coefficient of friction between the block and the surface is 0.2. We need to find the minimum force required to move the block.

To solve this problem, we need to consider the force of friction acting on the block. The force of friction can be calculated using the equation:

Force of Friction = Coefficient of Friction * Normal Force

The normal force is equal to the weight of the block, which can be calculated using the equation (Weight = Mass * Gravity). By substituting the values and solving the equation, we can find the minimum force required to move the block.

How to Find Displacement with Work and Force

In physics, displacement refers to the change in position of an object. It can be calculated using the work done on the object and the force applied. The formula to find displacement is:

Displacement = Work Done / Force

Work done is the product of force and displacement in the direction of the force. By rearranging the formula, we can find the displacement when the work done and force are known.

How to Find Velocity with Displacement and Force

Velocity is a vector quantity that represents the rate of change of displacement with respect to time. To find the velocity of an object, we can use the formula:

Velocity = Displacement / Time

By rearranging the formula, we can find the velocity when the displacement and time are known.

These problem-solving techniques and formulas are just a glimpse of the vast applications of physics in our daily lives. From understanding the mechanics of vehicles and structures to analyzing the behavior of fluids and waves, physics plays a crucial role in shaping our world. By applying the principles of physics, we can solve complex problems, make accurate predictions, and improve our understanding of the universe.

Special Cases in Displacement and Force

When Force and Displacement are in the Same Direction

When the force and displacement are in the same direction, it means that the force is applied in the same direction as the motion of an object. In this case, the work done on the object is positive. Work is defined as the product of force and displacement, and when they are in the same direction, the work done is equal to the magnitude of the force multiplied by the magnitude of the displacement.

For example, imagine pushing a box across the floor. The force you apply is in the same direction as the displacement of the box. As a result, you are doing positive work on the box, transferring energy to it and causing it to move.

When Force and Displacement are in Opposite Direction

In some cases, the force and displacement can be in opposite directions. This means that the force is acting against the motion of an object. When the force and displacement are in opposite directions, the work done on the object is negative. This indicates that energy is being taken away from the object.

For instance, consider a person lowering a heavy object down from a height. The force exerted by the person is directed upwards, while the displacement of the object is downwards. As a result, the work done on the object is negative, indicating that energy is being transferred away from the object.

When Force and Displacement are in Perpendicular Direction

There are situations where the force and displacement are perpendicular to each other. In this case, the work done on the object is zero. This occurs because the force is not contributing to the displacement of the object.

For example, imagine pushing a box horizontally across a table. The force you apply is perpendicular to the displacement of the box, which is in the horizontal direction. As a result, no work is done on the box, as the force is not contributing to its displacement.

In summary, the relationship between force and displacement can vary depending on their direction. When they are in the same direction, positive work is done. When they are in opposite directions, negative work is done. And when they are perpendicular, no work is done. Understanding these special cases in displacement and force is crucial in analyzing the motion and energy transfer of objects in various scenarios.

Advanced Topics in Displacement and Force

Displacement Force and Torque Measurement

In the field of physics, the measurement of displacement, force, and torque plays a crucial role in understanding the behavior of objects and systems. Displacement refers to the change in position of an object, while force is the push or pull acting upon an object. Torque, on the other hand, is the rotational force that causes an object to rotate around an axis.

To accurately measure displacement, force, and torque, various techniques and instruments are employed. These include displacement sensors, force gauges, load cells, and torque sensors. These devices utilize principles such as strain gauges, piezoelectric materials, and optical interferometry to provide precise measurements.

Displacement and Force in Two Dimensions

The study of displacement and force extends beyond one-dimensional motion. In many real-world scenarios, objects move in two dimensions, requiring a more comprehensive understanding of their motion. This involves considering both the horizontal and vertical components of displacement and force.

In two-dimensional motion, displacement is represented by a vector quantity, which includes both magnitude and direction. Similarly, force is also a vector quantity, with both magnitude and direction affecting the resulting motion of an object. By analyzing the components of displacement and force separately, one can accurately predict the trajectory and behavior of objects in two dimensions.

Displacement Force and Motion

The relationship between displacement, force, and motion is governed by Newton’s laws of motion. These fundamental principles describe how objects respond to the forces acting upon them. Newton’s laws provide a framework for understanding the causes and effects of motion, including concepts such as velocity, acceleration, and mass.

By applying Newton’s laws, one can analyze the forces acting on an object and determine its resulting motion. This analysis involves considering the net force, which is the vector sum of all the forces acting on an object. Understanding the relationship between displacement, force, and motion allows for the prediction and control of object behavior in various scenarios.

Displacement and Force Control

In many applications, precise control over displacement and force is essential. This is particularly true in fields such as robotics, manufacturing, and engineering, where accurate positioning and force application are crucial. Displacement and force control systems utilize feedback mechanisms to achieve the desired outcomes.

These control systems often incorporate sensors to measure displacement and force, which are then used to adjust the applied forces accordingly. By continuously monitoring and adjusting the displacement and force, these systems can achieve precise positioning and force application, ensuring optimal performance and efficiency.

Displacement Method and Force Method

When analyzing systems and objects, two common approaches are the displacement method and the force method. The displacement method focuses on understanding and predicting the behavior of objects based on their displacement characteristics. This involves analyzing the displacement-time graphs, velocity-time graphs, and acceleration-time graphs to determine the object’s motion.

On the other hand, the force method emphasizes the forces acting on an object and their effects on its motion. By considering the forces involved, such as friction, gravity, and applied forces, one can determine the resulting motion and behavior of the object.

Both the displacement method and the force method are valuable tools in understanding and analyzing the behavior of objects and systems. Depending on the specific scenario and requirements, one method may be more suitable than the other.

In conclusion, the advanced topics in displacement and force encompass various aspects of measurement, analysis, and control. By understanding the principles and techniques involved in displacement force and torque measurement, two-dimensional motion, force and motion relationships, displacement and force control, as well as the displacement method and force method, one can gain a comprehensive understanding of the behavior of objects and systems in the field of physics.

Conclusion

In conclusion, displacement and force are two fundamental concepts in physics that are closely related. Displacement refers to the change in position of an object, while force is the push or pull that causes an object to move or change its state of motion. Through the study of displacement and force, we can understand how objects move and interact with each other in the physical world. By applying Newton’s laws of motion, we can analyze and predict the behavior of objects under the influence of various forces. Displacement and force are essential in many areas of science and engineering, providing the foundation for understanding motion and the forces that govern it.

Frequently Asked Questions

Here are some frequently asked questions about physics and related topics:

  1. What are Newton’s Laws of Motion?
    Newton’s Laws of Motion are three fundamental principles that describe the relationship between the motion of an object and the forces acting upon it. They form the basis of classical mechanics and are essential for understanding how objects move and interact.

  2. What is the difference between velocity and acceleration?
    Velocity is a vector quantity that describes the rate at which an object changes its position in a specific direction. Acceleration, on the other hand, is the rate at which an object’s velocity changes over time. While velocity tells us the speed and direction of motion, acceleration tells us how quickly the velocity is changing.

  3. What is the concept of momentum?
    Momentum is a vector quantity that represents the motion of an object and is defined as the product of its mass and velocity. It describes the tendency of an object to keep moving in the same direction with the same speed unless acted upon by an external force.

  4. What is the difference between a vector quantity and a scalar quantity?
    A vector quantity has both magnitude and direction, such as velocity or force. On the other hand, a scalar quantity only has magnitude, such as mass or temperature. Vector quantities require both magnitude and direction to fully describe them, while scalar quantities only require magnitude.

  5. What is work done and how is it related to energy?
    Work done is the transfer of energy that occurs when a force acts upon an object and causes it to move in the direction of the force. It is directly related to energy because work done on an object can change its energy state. Work done is positive when the force and displacement are in the same direction, and negative when they are in opposite directions.

  6. What is the concept of friction?
    Friction is a force that opposes the relative motion or tendency of motion between two surfaces in contact. It acts in the opposite direction to the applied force and can cause objects to slow down or come to a stop. Friction plays a crucial role in everyday life, affecting the movement of vehicles, the grip of shoes on the ground, and many other phenomena.

  7. What is gravity and how does it affect objects?
    Gravity is the force of attraction between two objects with mass. It is responsible for the phenomenon of weight and is the reason why objects fall to the ground when dropped. Gravity also governs the motion of celestial bodies, such as planets and moons, and plays a significant role in the formation of galaxies and the universe as a whole.

These are just a few of the frequently asked questions about physics and its various concepts. If you have any more questions or need further clarification, feel free to explore the resources available or consult with experts in the field.

Additional Resources

Departments Offering Further Information on Displacement and Force

If you’re looking for more information on displacement and force, there are several departments that can provide valuable resources. These departments cover a wide range of topics related to physics, Newton’s laws, motion, velocity, acceleration, mass, momentum, vector quantity, scalar quantity, work done, energy, power, friction, gravity, mechanical advantage, simple machines, kinematics, dynamics, statics, equilibrium, torque, impulse, conservation laws, elasticity, inertia, kinetic energy, potential energy, centripetal force, angular momentum, oscillations, waves, fluid mechanics, thermodynamics, quantum mechanics, relativity, and more.

Here are some departments you can explore:

  1. City of Austin Department of Health and Environmental Services: This department focuses on the health and environmental aspects of displacement and force. They provide information on how displacement and force can impact the well-being of residents and the environment. You can visit their website for more information.

  2. Austin Business Start Center: If you’re interested in the business side of displacement and force, the Austin Business Start Center can provide valuable resources. They offer guidance and support for entrepreneurs and businesses in the city. Check out their website to learn more.

  3. Austin City Government Information and Services: The city government provides a wealth of information on displacement and force. Their website offers resources on various topics related to physics and its applications. You can find information on utilities, government services, job opportunities, and more. Visit their website to explore further.

Navigation Guide for Further Study

If you’re looking to dive deeper into the study of displacement and force, this navigation guide will help you find additional resources. Whether you’re a student or a curious individual, these resources will enhance your understanding of physics and related concepts.

  1. Austin Public Library: The Austin Public Library is a great resource for accessing books, journals, and online databases related to physics and displacement. They have a wide range of materials available for both beginners and advanced learners. Check out their website for more information.

  2. Board of Record and Commission Meetings: The board of record and commission meetings in Austin often discuss topics related to physics and displacement. Attending these meetings or accessing the meeting records can provide valuable insights and information. You can find more details on the City of Austin’s website.

  3. Austin City Government Job Opportunities: If you’re interested in pursuing a career in physics or related fields, the Austin City Government offers job opportunities in various departments. Exploring these opportunities can give you a better understanding of how physics is applied in real-world scenarios. Visit the City of Austin’s job portal for more information.

Remember, these resources are just a starting point. There are many other avenues to explore when it comes to displacement and force. Whether you’re a resident, a student, or simply curious about the subject, these resources will help you expand your knowledge and understanding.

Frequently Asked Questions

1. What is the role of Navigation in Physics?

Navigation in Physics refers to the process of determining the path or direction of an object in motion. It involves the use of concepts such as velocity, acceleration, and displacement to predict the object’s future position.

2. How frequently do Departments use displacement and force angle in their studies?

Physics departments frequently use displacement and force angle in their studies, especially in the fields of kinematics and dynamics. These concepts are fundamental in understanding the motion of objects under the influence of forces.

3. What is Action Navigation in the context of Newton’s Laws?

Action Navigation is not a standard term in Newton’s Laws. However, in a broader sense, it could refer to the process of determining an object’s motion path based on the actions (forces) applied to it.

4. How does Navigation GTranslate relate to displacement force and torque measurement?

Navigation GTranslate doesn’t directly relate to displacement force and torque measurement. The former is a tool for translating languages, while the latter is a physics concept related to motion and forces.

5. Can you explain the concept of displacement vector and force in Action Navigation GTranslate?

Action Navigation GTranslate is not directly related to the concept of displacement vector and force. Displacement vector and force are physics concepts used in the study of motion, while Action Navigation GTranslate is a tool for language translation.

6. How to find displacement with work and force in terms of Newton’s Laws?

According to Newton’s second law, the work done on an object is equal to the force applied multiplied by the displacement of the object in the direction of the force. So, if you know the work done and the force applied, you can find the displacement by dividing the work by the force.

7. What happens when force and displacement are in the same direction in terms of kinetic energy of the body?

When force and displacement are in the same direction, the work done on the body is positive. This work gets converted into kinetic energy, increasing the speed of the body.

8. Can you provide a definition for displacement and force in the context of Physics?

In physics, displacement is a vector quantity that refers to the change in position of an object. Force, on the other hand, is a vector quantity that refers to any interaction that changes the motion of an object.

9. How does displacement field relate to the concept of vector quantity?

A displacement field is a vector field that describes the displacement of a point in the field from its original position. Each point in the field has a displacement vector associated with it, indicating the direction and magnitude of the displacement.

10. What is the relationship between displacement force and motion in terms of Newton’s Laws?

According to Newton’s second law of motion, force is equal to the mass of an object multiplied by its acceleration. Since acceleration is the rate of change of velocity, and velocity is the rate of change of displacement, there is a direct relationship between displacement, force, and motion.

Also Read: