Chapter 5 Powerpoint - School District of La Crosse
... 2. weight- The gravitational force exerted by a large body ...
... 2. weight- The gravitational force exerted by a large body ...
Newton`s Laws of Motion - Tamalpais Union High School District
... • The law of inertia states that no force is required to maintain motion. Why, then, do you have to keep pedaling your bicycle to maintain motion? • A space probe may be carried by a rocket into outer space. What keeps the probe going after the rocket no longer pushes it? • Your friend says that ine ...
... • The law of inertia states that no force is required to maintain motion. Why, then, do you have to keep pedaling your bicycle to maintain motion? • A space probe may be carried by a rocket into outer space. What keeps the probe going after the rocket no longer pushes it? • Your friend says that ine ...
Chapter 1 The Science of Physics
... tendency of an object to maintain its state of motion? a. acceleration b. velocity c. force d. inertia ...
... tendency of an object to maintain its state of motion? a. acceleration b. velocity c. force d. inertia ...
Unit 2 Worksheet – Motion and Forces Do Not Write on this Paper
... freighter on the high seas and Earth. c) the moon and an astronaut standing on the moon d) the moon and Earth. 12. The law that states that every object maintains constant velocity unless acted on by an unbalanced force is ___. 13. The law that states that for every action force there is an equal an ...
... freighter on the high seas and Earth. c) the moon and an astronaut standing on the moon d) the moon and Earth. 12. The law that states that every object maintains constant velocity unless acted on by an unbalanced force is ___. 13. The law that states that for every action force there is an equal an ...
File
... 4. A curious kitten pushes a ball of yarn at rest with its nose, displacing the ball of yarn 17.5 cm in 2.00 s. Calculate the acceleration of the ball of yarn. 5. A man hikes 6.6 km north along a straight path with an average velocity of 4.2 km/h to the north. He rests at a bench for 15 min. Then, h ...
... 4. A curious kitten pushes a ball of yarn at rest with its nose, displacing the ball of yarn 17.5 cm in 2.00 s. Calculate the acceleration of the ball of yarn. 5. A man hikes 6.6 km north along a straight path with an average velocity of 4.2 km/h to the north. He rests at a bench for 15 min. Then, h ...
IPC Review - Humble ISD
... A force does work on an object if a component of the force is perpendicular to the displacement of the object. is parallel to the displacement of the object. perpendicular to the displacement of the object moves the object along a path that returns the object to its starting position. d. parallel to ...
... A force does work on an object if a component of the force is perpendicular to the displacement of the object. is parallel to the displacement of the object. perpendicular to the displacement of the object moves the object along a path that returns the object to its starting position. d. parallel to ...
The NET Force
... Net force = 0 • An object may have many forces acting on it at the same time. • If all the forces oppose each other exactly then the net force = 0 and the object will either be at rest or move with constant velocity. • If the net force is zero and the object is at rest, this is called static equili ...
... Net force = 0 • An object may have many forces acting on it at the same time. • If all the forces oppose each other exactly then the net force = 0 and the object will either be at rest or move with constant velocity. • If the net force is zero and the object is at rest, this is called static equili ...
Phys. 1st Sem Rev 95-96
... x-direction. Write the equation which describes the forces which act in the y-direction. Suppose that the magnitude of T1 is 50N. Determine the magnitude of T2. ...
... x-direction. Write the equation which describes the forces which act in the y-direction. Suppose that the magnitude of T1 is 50N. Determine the magnitude of T2. ...
Forces
... A force is a push or a pull that one object applies to another. A force can also cause an object’s motion to change. EX) Sports Balanced forces are equal in size and opposite in direction. ...
... A force is a push or a pull that one object applies to another. A force can also cause an object’s motion to change. EX) Sports Balanced forces are equal in size and opposite in direction. ...
Three Laws of Motion Webquest Score: ______/25 Name: 1. Using
... an object traveling at a constant speed in a straight line? 8. The presentation frequently discusses the use of an external force. What were three examples of an external force described in the presentation? Hint: External force was used in parenthesis at the bottom of some of the slides. 9-10. List ...
... an object traveling at a constant speed in a straight line? 8. The presentation frequently discusses the use of an external force. What were three examples of an external force described in the presentation? Hint: External force was used in parenthesis at the bottom of some of the slides. 9-10. List ...
Sample Problem
... and a meter stick, determine the launch velocity of sports projectiles that you punt, pass, or kick. • Theory: Use horizontal (unaccelerated) motion to determine Vx, and vertical (accelerated) motion to determine Vy. Ignore air resistance. • Data: Prepare your lab book to collect xi, xf, yo, and t ...
... and a meter stick, determine the launch velocity of sports projectiles that you punt, pass, or kick. • Theory: Use horizontal (unaccelerated) motion to determine Vx, and vertical (accelerated) motion to determine Vy. Ignore air resistance. • Data: Prepare your lab book to collect xi, xf, yo, and t ...
newtons laws_ppt
... Law of Conservation of Momentum • For a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision • MV = MV ...
... Law of Conservation of Momentum • For a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision • MV = MV ...
