exam1-F03
... Name ________________________________________________________________________ C-4 (20 points) A hockey puck (Puck A) sliding on frictionless ice collides with another puck (Puck B) initially at rest. Each puck has mass = 0.150 kg. The initial velocity of Puck A is 10.0 m/s in the +X direction. The ...
... Name ________________________________________________________________________ C-4 (20 points) A hockey puck (Puck A) sliding on frictionless ice collides with another puck (Puck B) initially at rest. Each puck has mass = 0.150 kg. The initial velocity of Puck A is 10.0 m/s in the +X direction. The ...
ws3 diff
... 7. Tarzan prepares to swing and much to his dismay, gets his loincloth stuck on a branch. He's left hanging with the vine pulling upward at a 40-degree angle and his loincloth pulling him horizontally to the right. a. Draw a force diagram for Tarzan. Be sure to break angled forces into components an ...
... 7. Tarzan prepares to swing and much to his dismay, gets his loincloth stuck on a branch. He's left hanging with the vine pulling upward at a 40-degree angle and his loincloth pulling him horizontally to the right. a. Draw a force diagram for Tarzan. Be sure to break angled forces into components an ...
Newton`s Laws of Motion
... The action force is gravity pulling the ball down Every object exerts a gravitational force (creates gravity) That means that the ball is also creating a gravitational force on the Earth Why can’t you see the effect of the ball’s gravity on Earth? Earth is so massive, that you can not ...
... The action force is gravity pulling the ball down Every object exerts a gravitational force (creates gravity) That means that the ball is also creating a gravitational force on the Earth Why can’t you see the effect of the ball’s gravity on Earth? Earth is so massive, that you can not ...
TEKS 4B : investigate and describe applications of Newton`s laws
... stopper (it will continue to move and fall into the cart) 3. Repeat above but secure the stopper to the cart with a rubber band (this time the stopper will be held in place by the rubber band) 4. Ask the students what they observed and why it ...
... stopper (it will continue to move and fall into the cart) 3. Repeat above but secure the stopper to the cart with a rubber band (this time the stopper will be held in place by the rubber band) 4. Ask the students what they observed and why it ...
Newton`s 1st & 2nd Law PowerPoint Notes
... • Also maybe something about looking at force diagrams and telling what an object will do…what direction it will accelerate. Add velocity in there too…this could help us lead to circular motion! Like if its moving right and it accelerates down, what will it’s path look like. Stress that net force an ...
... • Also maybe something about looking at force diagrams and telling what an object will do…what direction it will accelerate. Add velocity in there too…this could help us lead to circular motion! Like if its moving right and it accelerates down, what will it’s path look like. Stress that net force an ...
Chapter 2
... If an object weighs 10 lb, what must the air resistance force be if the object is falling and has reached terminal velocity? (a) 10 lb ...
... If an object weighs 10 lb, what must the air resistance force be if the object is falling and has reached terminal velocity? (a) 10 lb ...
Chapter 6 - MrCrabtreesScience
... 6-2 Conservation of Momentum • Momentum is a conserved quantity • Imagine a soccer ball traveling at some velocity hits a stationary soccer ball. • What would happen? • It is likely that soccer ball one will slow down and soccer ball two will accelerate. ...
... 6-2 Conservation of Momentum • Momentum is a conserved quantity • Imagine a soccer ball traveling at some velocity hits a stationary soccer ball. • What would happen? • It is likely that soccer ball one will slow down and soccer ball two will accelerate. ...
Situation Diagram Free-body diagram
... The object does not necessarily have to moving in one direction or another, but the directions of the force vectors will change accordingly. ...
... The object does not necessarily have to moving in one direction or another, but the directions of the force vectors will change accordingly. ...
Where to aim in order to Hit the Falling object (ignore air friction)?
... It is the total force or net force ftable 2 N (to the left) that determines an object’s acceleration. Fnet 10 N 2 N If there is more than one 8 N (to the right) vector acting on an object, the forces are added together as F 8N vectors, taking into account a net m 5 kg their directions. ...
... It is the total force or net force ftable 2 N (to the left) that determines an object’s acceleration. Fnet 10 N 2 N If there is more than one 8 N (to the right) vector acting on an object, the forces are added together as F 8N vectors, taking into account a net m 5 kg their directions. ...
Lecture Notes: Chapter 2 Motion
... Q: Frame of reference picture: Using the picture on this slide what would you use as your frame of reference? ...
... Q: Frame of reference picture: Using the picture on this slide what would you use as your frame of reference? ...
The Law of Conservation of Mechanical Energy
... The law of conservation of mechanical energy states that “The sum of the kinetic energy and the potential energy in a system is constant if no resistant forces do work”. Mathematically, this law can be stated as: KE1 + PE1 = KE2 + PE2 = …….KEn + PEn In other words the sum of the kinetic and potentia ...
... The law of conservation of mechanical energy states that “The sum of the kinetic energy and the potential energy in a system is constant if no resistant forces do work”. Mathematically, this law can be stated as: KE1 + PE1 = KE2 + PE2 = …….KEn + PEn In other words the sum of the kinetic and potentia ...
Classical central-force problem
In classical mechanics, the central-force problem is to determine the motion of a particle under the influence of a single central force. A central force is a force that points from the particle directly towards (or directly away from) a fixed point in space, the center, and whose magnitude only depends on the distance of the object to the center. In many important cases, the problem can be solved analytically, i.e., in terms of well-studied functions such as trigonometric functions.The solution of this problem is important to classical physics, since many naturally occurring forces are central. Examples include gravity and electromagnetism as described by Newton's law of universal gravitation and Coulomb's law, respectively. The problem is also important because some more complicated problems in classical physics (such as the two-body problem with forces along the line connecting the two bodies) can be reduced to a central-force problem. Finally, the solution to the central-force problem often makes a good initial approximation of the true motion, as in calculating the motion of the planets in the Solar System.