The more momentum an object has, the more difficult it is to stop
... be the same number regardless of the time involved. However, the force can change drastically depending upon the amount of time in which the object is brought to a halt. As the length of time is increased, the force decreases. In stopping an object, force and time are inversely proportional. Damage ...
... be the same number regardless of the time involved. However, the force can change drastically depending upon the amount of time in which the object is brought to a halt. As the length of time is increased, the force decreases. In stopping an object, force and time are inversely proportional. Damage ...
force
... how much matter an object contains force or speed of movement; mass in motion, example: a moving train has much more than a moving soccer ball Note: momentum = mass of an object x velocity (increasing the mass or speed increases the momentum) an object changing position over time; change in position ...
... how much matter an object contains force or speed of movement; mass in motion, example: a moving train has much more than a moving soccer ball Note: momentum = mass of an object x velocity (increasing the mass or speed increases the momentum) an object changing position over time; change in position ...
NEWTON`S LAWS OF MOTION
... 1. Identify all forces acting on the object -Pushes or Pulls -Frictional forces -Tension in a string -Gravitational Force (or weight = mg where g is 9.8 m/s2) - “Normal forces” (one object touching another). 2. Draw a “Freebody Diagram” -draw the object, show all forces acting on that object as vect ...
... 1. Identify all forces acting on the object -Pushes or Pulls -Frictional forces -Tension in a string -Gravitational Force (or weight = mg where g is 9.8 m/s2) - “Normal forces” (one object touching another). 2. Draw a “Freebody Diagram” -draw the object, show all forces acting on that object as vect ...
Newton`s First Law
... Newton’s First Law of Motion • Definition: An object in motion stays in motion, or an object at rest stays at rest until an unbalanced net force acts on it. • Under these conditions the first law says that if an object is not pushed or pulled upon, its velocity will naturally remain constant. This ...
... Newton’s First Law of Motion • Definition: An object in motion stays in motion, or an object at rest stays at rest until an unbalanced net force acts on it. • Under these conditions the first law says that if an object is not pushed or pulled upon, its velocity will naturally remain constant. This ...
Study Guide - Chapter 6
... Air resistance - the force that opposes the motion of objects through air 1. The amount of air resistance depends on the size, shape and speed of the object Terminal Velocity - the constant velocity of a falling object when the force of air resistance is equal in magnitude and opposite in direction ...
... Air resistance - the force that opposes the motion of objects through air 1. The amount of air resistance depends on the size, shape and speed of the object Terminal Velocity - the constant velocity of a falling object when the force of air resistance is equal in magnitude and opposite in direction ...
Review sheet for - The Russell Elementary Science Experience
... 2. If two objects have the same velocity but different masses, which object has the greater momentum? The object with the greater mass will have a greater momentum. 3. If two objects have the same mass but different velocities, which object has the greater momentum? The object with the greater veloc ...
... 2. If two objects have the same velocity but different masses, which object has the greater momentum? The object with the greater mass will have a greater momentum. 3. If two objects have the same mass but different velocities, which object has the greater momentum? The object with the greater veloc ...
End of Course Exam Review
... position). These quantities have the ability to be the same magnitude in basic linear motion but can also be different when there is a change in direction. Speed is just how “fast” an object is moving regardless of direction. Speed is based on the distance traveled per the time of travel. Velocity ...
... position). These quantities have the ability to be the same magnitude in basic linear motion but can also be different when there is a change in direction. Speed is just how “fast” an object is moving regardless of direction. Speed is based on the distance traveled per the time of travel. Velocity ...
Newton`s Laws of Motion Notes
... ---direction in straight line (not time) **travel time to the store is different than the actual distance to the store in a straight line (GPS) ...
... ---direction in straight line (not time) **travel time to the store is different than the actual distance to the store in a straight line (GPS) ...
Slide 1
... x’y’z’ moving with a fixed velocity relative to reference frame xyz, such that the reference frames coincide at t=0, and the relative velocity is along the x-axis. This is called the Galilean Transformation. The coordinates x’y’z’t’ give the location of a point as measured from the fixed frame in te ...
... x’y’z’ moving with a fixed velocity relative to reference frame xyz, such that the reference frames coincide at t=0, and the relative velocity is along the x-axis. This is called the Galilean Transformation. The coordinates x’y’z’t’ give the location of a point as measured from the fixed frame in te ...
