Physics/Graphing Notes
... An object in motion will remain in motion or an object at rest will remain at rest, unless an unbalanced force acts upon it. Example: A car slamming into a telephone pole. The driver is thrown from the vehicle. This is because the person stays in motion because there is not an unbalanced force to st ...
... An object in motion will remain in motion or an object at rest will remain at rest, unless an unbalanced force acts upon it. Example: A car slamming into a telephone pole. The driver is thrown from the vehicle. This is because the person stays in motion because there is not an unbalanced force to st ...
Slajd 1 - pravos.hr
... holding clothing, using any part of the body to hold an opponent & "Sandwiching", spitting at an opponent, even if it doesn't hit the opponent, deliberately handling the ball etc. ...
... holding clothing, using any part of the body to hold an opponent & "Sandwiching", spitting at an opponent, even if it doesn't hit the opponent, deliberately handling the ball etc. ...
Module 1 - Kinematics Module 2
... Depending on the application, certain reference frames can approximate an Inertial reference frame. Example ...
... Depending on the application, certain reference frames can approximate an Inertial reference frame. Example ...
Honors Physics 2012 Objectives
... 7.1 A ETM I can use words, diagrams, pie charts, and bar graphs (LOLs) to represent the way the flavor and total amount of energy in a system changes (or doesn’t change). 7.2 A ETM I identify when the total energy of a system is changing or not changing, and I can identify the reason for the change. ...
... 7.1 A ETM I can use words, diagrams, pie charts, and bar graphs (LOLs) to represent the way the flavor and total amount of energy in a system changes (or doesn’t change). 7.2 A ETM I identify when the total energy of a system is changing or not changing, and I can identify the reason for the change. ...
force
... The truck stops moving. The car starts moving. Which one will be the hardest to accelerate? The truck because it has the most mass. ...
... The truck stops moving. The car starts moving. Which one will be the hardest to accelerate? The truck because it has the most mass. ...
Types of Variation
... A free-falling body is a special case of uniform acceleration where the object is falling at a rate of 9.81 m/s2 (towards the center of the Earth). Position, time, velocity and acceleration are mathematically related by the following equations. ...
... A free-falling body is a special case of uniform acceleration where the object is falling at a rate of 9.81 m/s2 (towards the center of the Earth). Position, time, velocity and acceleration are mathematically related by the following equations. ...
Types of Variation
... A free-falling body is a special case of uniform acceleration where the object is falling at a rate of 9.81 m/s2 (towards the center of the Earth). Position, time, velocity and acceleration are mathematically related by the following equations. ...
... A free-falling body is a special case of uniform acceleration where the object is falling at a rate of 9.81 m/s2 (towards the center of the Earth). Position, time, velocity and acceleration are mathematically related by the following equations. ...
Unit 3 Notes
... unbalanced forces cause objects to accelerate with an acceleration which is directly proportional to the net force and inversely proportional to the mass. This one is telling us that big heavy objects don’t move as fast or as easily as smaller lighter objects. It takes more to slow down a charging b ...
... unbalanced forces cause objects to accelerate with an acceleration which is directly proportional to the net force and inversely proportional to the mass. This one is telling us that big heavy objects don’t move as fast or as easily as smaller lighter objects. It takes more to slow down a charging b ...
Semester 1 – Review Problems
... 7. Draw a force diagram for the ball while it is in the air. 8. How would your answers to questions 2–5 change if the ball’s mass doubled? Problems 9–16: A 2,500 kg tow truck pulls a broken down, 1,500 kg car down the road. The force of friction is 3,000 N. 9. Draw a force diagram for the car. 10. W ...
... 7. Draw a force diagram for the ball while it is in the air. 8. How would your answers to questions 2–5 change if the ball’s mass doubled? Problems 9–16: A 2,500 kg tow truck pulls a broken down, 1,500 kg car down the road. The force of friction is 3,000 N. 9. Draw a force diagram for the car. 10. W ...
