Unit 2 Force and Translational Dynamics

Free Body Diagrams (FBDs)

Newton's Second Law

Circular Motion

Kinetic and Static Friction

Gravitational Force

100

Where the forces are drawn from in a Free Body Diagram

The middle (center of mass)

100

The equation for Newton's Second Law

Net F=ma (Net Force=mass x acceleration)

100

The time taken for one full revolution to be completed in circular motion is defined as

The period (T)

100

The reaction between two forces that resists relative motion

Friction

100

True or False: Contact is required for gravitational force

False, gravity is a field force

200

The direction that a force should be pointing relative to the object

away from

200

The unit of measurement for acceleration

m/s (meters per second)

200

True or false: an object moving in a circular path at a constant velocity is not accelerating

false (the object is consistently changing direction, therefore accelerating)

200

The difference between kinetic and static friction

One is the force that opposes an object from beginning to move from rest (static friction) while the other opposes an object from continuing to move while already in motion (kinetic friction)

200

The equation for force of gravity

F_g= mg (force of gravity is equal to the product of the mass of an object and the acceleration due to gravity).

300

Represented by the length of arrows in a FBD

magnitude of the forces

300

The relationship between acceleration and mass

acceleration is proportional to 1/mass (inversely proportional)

300

The direction that centripetal force and acceleration act in

Towards the center of the circular path

300

The type of friction that can cause an object to accelerate

static friction

300

The acceleration due to gravity

9.8 m/s (accepted 10 m/s)

400

What the forces on an object sum to when the object is not accelerating

Zero (0)

400

Increasing mass also increases _____ proportionally

Net force

400

The equation for centripetal accelration

a_c= v²/r (centripetal acceleration is equal to the velocity squared divided by the radius)

400

A variable that affects the amount of friction between two surfaces

Surface area, type of surface, speed of object, weight, and tension or pull force

400

Mass is the measurement of

The amount of matter that makes up an object

500

The practice of breaking forces down into their parallel and perpendicular parts

Components (finding the components)

500

acceleration occurs in the same direction as this force

net force

500

The equation that is derived from Newton's Second Law that identifies the net force, or cause, for centripetal acceleration

net F= mv²/r (net force is equal to the mass times the velocity squared, with the product of those two divided by the radius)

500

For any two surfaces, this coefficient of friction is always larger than the other

static friction

500

In the equation F_g= G m₁m₂/r², or the equation for Universal Gravitation, r represents

The distance between the center of masses of two objects or planets