pompton lakes high school - Pompton Lakes School District
... conceptual, mathematical, physical, and computational tools that need to be applied when constructing and evaluating claims. ...
... conceptual, mathematical, physical, and computational tools that need to be applied when constructing and evaluating claims. ...
Energy 09-10
... on a 3 m ledge. A 10 kg rock is at the top of a 20 m tall hill. How much potential energy does it have? How high up is a 3 kg object that has 300 J of energy? An object with 20 J of energy sits on a cliff that is 15 kg high. What is the mass of the object? A skater travels 150 m with 38 J of energy. ...
... on a 3 m ledge. A 10 kg rock is at the top of a 20 m tall hill. How much potential energy does it have? How high up is a 3 kg object that has 300 J of energy? An object with 20 J of energy sits on a cliff that is 15 kg high. What is the mass of the object? A skater travels 150 m with 38 J of energy. ...
Apply knowledge of fundamental engineering science
... world of work to gain an understanding of the world as a set of related systems, by recognizing that problem solving contexts do not exist in isolation but that they may differ from context to context according to the area of application. ...
... world of work to gain an understanding of the world as a set of related systems, by recognizing that problem solving contexts do not exist in isolation but that they may differ from context to context according to the area of application. ...
sy16_oct26_f11a
... Net Work is F x = 10 x 5 N m = 50 J 1 N m ≡ 1 Joule (energy) Work reflects energy transfer Physics 207: Lecture 15, Pg 3 ...
... Net Work is F x = 10 x 5 N m = 50 J 1 N m ≡ 1 Joule (energy) Work reflects energy transfer Physics 207: Lecture 15, Pg 3 ...
Spring Energy
... Work and Energy Work is a measure of energy transfer. In the absence of friction, when positive work is done on an object, there will be an increase in its kinetic or potential energy. In order to do work on an object, it is necessary to apply a force along or against the direction of the object’s m ...
... Work and Energy Work is a measure of energy transfer. In the absence of friction, when positive work is done on an object, there will be an increase in its kinetic or potential energy. In order to do work on an object, it is necessary to apply a force along or against the direction of the object’s m ...
Cornell Notes Topic/Objective: Physics / Newton`s Laws Name
... A: The brakes stop the car but not your body, so your body keeps moving forward because of inertia. Inertia & Mass: The inertia of an object depends on its mass. Objects with greater mass also have greater inertia. It would be easier to push just one person on a skateboard than two of them. With jus ...
... A: The brakes stop the car but not your body, so your body keeps moving forward because of inertia. Inertia & Mass: The inertia of an object depends on its mass. Objects with greater mass also have greater inertia. It would be easier to push just one person on a skateboard than two of them. With jus ...
Chapter 6: Energy
... At point “B” the planet is the farthest from the Sun. At point “A” the planet is at its closest approach to the sun. Starting from point “B” (where the planet moves the slowest), as the planet moves in its orbit r begins to decrease. As it decreases the planet moves faster. At point “A” the planet r ...
... At point “B” the planet is the farthest from the Sun. At point “A” the planet is at its closest approach to the sun. Starting from point “B” (where the planet moves the slowest), as the planet moves in its orbit r begins to decrease. As it decreases the planet moves faster. At point “A” the planet r ...
Centripetal Force / Gravity (very good practice)
... Centripetal Acceleration and Centripetal Force 1. What is the centripetal acceleration of a point on the perimeter of a bicycle wheel of diameter 70. cm when a bike is moving at 8.0 m/s? 2. A pilot makes an outside loop (in which the center of the loop is beneath him) of radius 3.20 x 103 m. At the ...
... Centripetal Acceleration and Centripetal Force 1. What is the centripetal acceleration of a point on the perimeter of a bicycle wheel of diameter 70. cm when a bike is moving at 8.0 m/s? 2. A pilot makes an outside loop (in which the center of the loop is beneath him) of radius 3.20 x 103 m. At the ...
Lecture 14ba
... Section 8-4: Torque • Newton’s 1st Law (rotational language version): “A rotating body will continue to rotate at a constant angular velocity unless an external TORQUE acts.” • Clearly, to understand this, we need to define the concept of TORQUE. • Newton’s 2nd Law (rotational language version): Al ...
... Section 8-4: Torque • Newton’s 1st Law (rotational language version): “A rotating body will continue to rotate at a constant angular velocity unless an external TORQUE acts.” • Clearly, to understand this, we need to define the concept of TORQUE. • Newton’s 2nd Law (rotational language version): Al ...
EQUILIBRIUM
... The examples in questions 3.1 and 3.2 are simple illustrations of equilibrium. In both cases the velocity of the block is constant, i.e. its acceleration is zero, and the total force on it is zero. However it is not enough that the forces balance in order to have equilibrium. This guarantees only th ...
... The examples in questions 3.1 and 3.2 are simple illustrations of equilibrium. In both cases the velocity of the block is constant, i.e. its acceleration is zero, and the total force on it is zero. However it is not enough that the forces balance in order to have equilibrium. This guarantees only th ...
Springs ppt
... Springs and rubber bands store potential energy that can be transformed into kinetic energy. The spring force is not constant as an object is pushed or pulled. The motion of the mass is not constant-acceleration motion, and therefore we cannot use our old kinematics equations. One way to ana ...
... Springs and rubber bands store potential energy that can be transformed into kinetic energy. The spring force is not constant as an object is pushed or pulled. The motion of the mass is not constant-acceleration motion, and therefore we cannot use our old kinematics equations. One way to ana ...
Hunting oscillation
Hunting oscillation is a self-oscillation, usually unwanted, about an equilibrium. The expression came into use in the 19th century and describes how a system ""hunts"" for equilibrium. The expression is used to describe phenomena in such diverse fields as electronics, aviation, biology, and railway engineering.