LAWS OF MOTION:

Σ F = Ma. The vector sum of all forces acting on an object of mass M equals that mass times the acceleration vector a of the object.
Operationally, the “weight” of an object, in Newtons, is the force required to support it completely in any given frame of reference. The mass of an object is a measure of its inertia, and the operational way to measure mass is to compare a given mass to a standard mass. Note that there is no real excuse in physics to ever use the term “weight.” It does not appear under that name in any physical law.



The fundamental forces we encounter in everyday life include gravity, and the electromagnetic forces between systems of atoms.  These are the only two forces that can act across significant distances. All the forces of nature involve particles called bosons, or force carriers, which are emitted by one object and absorbed by the other. 


The laws of motion can only be applied in non-accelerating frames of reference, called inertial. Viewed in an accelerating frame, a car rounding a curve, a ball resting on a table appears to accelerate, but there is no horizontal force acting on it (sketch 1). When we view the system from outside, where we can see the car is accelerating, we see the ball is moving at constant velocity relative to the ground while the car accelerates perpendicular to that velocity (sketch 2).  Do not try to set up the laws of motion in noninertial (accelerating) frames of reference!




How do we understand the reading of a spring scale on which we are standing, in an elevator? The spring scale measures the normal force n which is exerted upward on us to support us in that frame of reference. The only other force acting is gravity, mg. Thus our acceleration, taking components along y, satisfies ma = n - mg. Given the acceleration of the elevator, we can solve for n, the reading of the spring scale.





The Third Law is used when we have two or more interacting objects. In such a case the forces form pairs; a force exerted by object 1 on object 2 results in a corresponding force exerted by object 2 on object 1. You can't touch without being touched. All interactions between objects involve force pairs with the same magnitude but different directions.  By the way, in general the forces do not have to be in opposite directions, but they do have to have the same magnitude.


Take components of vector equations, so that you can do algebra.

Draw ALL forces acting on EACH object, and use the 3rd Law where appropriate to relate the magnitudes of different forces acting on different interacting objects. Then apply the 2nd Law to EACH object, taking vector components, and using the simplifications that the 3rd Law indicates; then, do the algebra needed to solve for whatever quantity is unknown in the problem, in terms of the others. Here is some good advice.

To stretch a spring a distance x, a force Fx = kx must be applied. That means the spring resists with a force Fs = − kx. Here k is a constant for the given spring.


When two or more bodies interact, the 3rd law of motion must be applied to every interacting pair. For example, when a force F is applied to two boxes on a horizontal table with friction negligible, each box exerts a contact force on the other. If the force box 1 exerts on box 2 is F12 and the force box 2 exerts on box 1 is F21, then the two contact forces have the same magnitude. It is also vital to note that the contact forces are less than the magnitude of F, since if the boxes are accelerating, a net force must act on each box, and it must be a net force on each box that would satisfy the 2nd Law for each of the boxes, since both boxes have to move, in contact, with the same acceleration!

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