You are viewing an old version of this page. View the current version.

Compare with Current View Page History

Version 1 Next »

Unknown macro: {table}
Unknown macro: {tr}
Unknown macro: {td}
Error formatting macro: live-template: java.lang.NullPointerException
Unknown macro: {td}
Unknown macro: {HTMLcomment}

The header above sets up the left navigation column.

Force and Interactions

Force is the prime mover in Newtonian Mechanics.  Without force, everything continues to move with constant velocity, passing through other objects due to the lack of contact forces.

When force acts, it is important to note kind of force it is, as this gives clues about which category of models is appropriate:

Net (vector) force on a body causes accelerationof its center of mass

External force changes the momentum of a system, even if they act on only one part of it.

Non-conservative forces change the energy of a system

Forces acting around an axis (torques) change the angular momentum about that axis.

Force produces a change in the momentum of a mass on which it acts, according to F=ma (Newton's Second Law). Forces result from various types of physical interactions, which always generate a pair of opposite forces acting on two different objects (Newton's Third Law). Historically the first mathematical description of interactions was by forces and force laws, and this formulation is still the most commonly used in Newtonian Mechanics. In the traditional approach to Newtonian Mechanics, all other descriptions of interactions (e.g. potential energy) are defined in terms of force. In this WIKI, "force" is often used interchangeably with "interaction". For example, the earth and the moon are attracted by the force of gravity, OR by their gravitational interaction.

Motivation for Concept

Consider a bowling ball (or some other heavy object that moves with little resistance). If you want a stationary ball to move, you have to exert a force on it in the direction you want it to move, which will accelerate it. If you want the moving ball to turn, you have to exert a force on it toward the side you want it to turn toward. If you want the ball to stop moving, you have to exert a force opposite to its velocity.  To change the motion of the bowling ball, you will probably apply a force by using your hands or feet or some object you push against the ball. There are other kinds of forces, however. The earth, for example, can alter the ball's motion through the invisible action-at-a-distance of gravity, often represented as a gravitational field acting on the body at the site of the body.

Newton's Laws

Newton's famous Three Laws of Motion together comprise his definition of force.

  • Newton's First Law: If an object is moving with no force acting upon it, then it will move with constant velocity. Note that velocity is a vector, so this statement implies that the object will keep the same speed and the same direction of motion.  This directly contradicts the animistic view of motion in which the natural condition of a body is at rest with respect to its surroundings - the First Law says the natural state of a body is moving with zero acceleration, not zero velocity.
  • Newton's Second Law: The mathematical relationship between force and momentum, or, for systems with constant mass, the relationship between force and acceleration.
  • Newton's Third Law: Every force exerted on one body by a second body is paired with another force of equal magnitude and opposite direction exerted on the second body by the first.

Classification of Forces

There are many ways to classify forces. For the purposes of the modeling approach to physics, the most important classifications to understand are Internal vs. External and Conservative vs. Non-Conservative. Another commonly encountered classification of forces is by their status as "fundamental" vs. phenomenological.

Internal vs. External

Conservative vs. Non-Conservative

Fundamental vs. Phenomenological

  • Phenomenological Forces: Macroscopic bodies are composed of huge numbers of elementary particles, which means that the effects of the fundamental forces on macroscopic bodies are complicated by the collective interactions of these particles. As a result, it is often advantageous to construct new force laws to describe the interactions of macroscopic bodies, even though these "new" forces are actually manifestations of the fundamental forces.
">

Force produces a change in the momentum of a mass on which it acts, according to F=ma (Newton's Second Law). Forces result from various types of physical interactions, which always generate a pair of opposite forces acting on two different objects (Newton's Third Law). Historically the first mathematical description of interactions was by forces and force laws, and this formulation is still the most commonly used in Newtonian Mechanics. In the traditional approach to Newtonian Mechanics, all other descriptions of interactions (e.g. potential energy) are defined in terms of force. In this WIKI, "force" is often used interchangeably with "interaction". For example, the earth and the moon are attracted by the force of gravity, OR by their gravitational interaction.

Motivation for Concept

Consider a bowling ball (or some other heavy object that moves with little resistance). If you want a stationary ball to move, you have to exert a force on it in the direction you want it to move, which will accelerate it. If you want the moving ball to turn, you have to exert a force on it toward the side you want it to turn toward. If you want the ball to stop moving, you have to exert a force opposite to its velocity.  To change the motion of the bowling ball, you will probably apply a force by using your hands or feet or some object you push against the ball. There are other kinds of forces, however. The earth, for example, can alter the ball's motion through the invisible action-at-a-distance of gravity, often represented as a gravitational field acting on the body at the site of the body.

Newton's Laws

Newton's famous Three Laws of Motion together comprise his definition of force.

  • Newton's First Law: If an object is moving with no force acting upon it, then it will move with constant velocity. Note that velocity is a vector, so this statement implies that the object will keep the same speed and the same direction of motion.  This directly contradicts the animistic view of motion in which the natural condition of a body is at rest with respect to its surroundings - the First Law says the natural state of a body is moving with zero acceleration, not zero velocity.
  • Newton's Second Law: The mathematical relationship between force and momentum, or, for systems with constant mass, the relationship between force and acceleration.
  • Newton's Third Law: Every force exerted on one body by a second body is paired with another force of equal magnitude and opposite direction exerted on the second body by the first.

Classification of Forces

There are many ways to classify forces. For the purposes of the modeling approach to physics, the most important classifications to understand are Internal vs. External and Conservative vs. Non-Conservative. Another commonly encountered classification of forces is by their status as "fundamental" vs. phenomenological.

Internal vs. External

Conservative vs. Non-Conservative

Fundamental vs. Phenomenological

  • Phenomenological Forces: Macroscopic bodies are composed of huge numbers of elementary particles, which means that the effects of the fundamental forces on macroscopic bodies are complicated by the collective interactions of these particles. As a result, it is often advantageous to construct new force laws to describe the interactions of macroscopic bodies, even though these "new" forces are actually manifestations of the fundamental forces.
Unknown macro: {HTMLcomment}

The footer completes the page layout and adds the license and acknowledgments.

Error formatting macro: live-template: java.lang.NullPointerException
  • No labels