for reference Name Period ______ Date ______ Motion Notes from
... Acceleration: The rate of change in velocity. To calculate acceleration, use this equation: Acceleration = (Final Velocity) - (Original Velocity) / Time Deceleration: A term commonly used to mean a decrease in speed. Force: any push or pull. Forces cause a change in motion. Friction: a force tha ...
... Acceleration: The rate of change in velocity. To calculate acceleration, use this equation: Acceleration = (Final Velocity) - (Original Velocity) / Time Deceleration: A term commonly used to mean a decrease in speed. Force: any push or pull. Forces cause a change in motion. Friction: a force tha ...
Newton`s Laws
... – the tendency of an object to resist a change in its motion In order to overcome an object’s inertia, a force must be exerted on the object. Newton’s 1st Law is also called the Law of Inertia Inertia ...
... – the tendency of an object to resist a change in its motion In order to overcome an object’s inertia, a force must be exerted on the object. Newton’s 1st Law is also called the Law of Inertia Inertia ...
Force, Net Force, and Inertia
... Types of Forces • Action-at-a-Distance, any force that does not need the objects touching – Gravity – Electro-Magnetic – Weak Nuclear – Strong Nuclear We will only deal with the first two ...
... Types of Forces • Action-at-a-Distance, any force that does not need the objects touching – Gravity – Electro-Magnetic – Weak Nuclear – Strong Nuclear We will only deal with the first two ...
Kinematics, Momentum and Energy
... Newton’s First Law Inertia An object at rest will stay at rest and an object in motion will stay in motion unless acted on by an external force. ...
... Newton’s First Law Inertia An object at rest will stay at rest and an object in motion will stay in motion unless acted on by an external force. ...
Document
... Newton’s 2nd Law of Motion • Force = mass x acceleration • Acc = Force/mass • Mass = Force/acc ...
... Newton’s 2nd Law of Motion • Force = mass x acceleration • Acc = Force/mass • Mass = Force/acc ...
17.4 Inertia and Newton`s 1st law of motion
... down if the engine stops, and that a bicycle on a level road will slow down if we stop pedalling. This happens because the force of friction, including water resistance and air resistance, slows them down (see Module 10.3 about friction). The more we reduce friction, the better we maintain speed. Th ...
... down if the engine stops, and that a bicycle on a level road will slow down if we stop pedalling. This happens because the force of friction, including water resistance and air resistance, slows them down (see Module 10.3 about friction). The more we reduce friction, the better we maintain speed. Th ...
Worksheet - 2
... g) Acceleration 2.Differences between a) Speed and velocity b) Uniform and Non-uniform speed c) Uniform and Non-uniform velocity d) Uniform acceleration and non-uniform acceleration 3. Define Uniform circular motion 4. What do you mean by the term retardation? Give an example 5. Describe the distanc ...
... g) Acceleration 2.Differences between a) Speed and velocity b) Uniform and Non-uniform speed c) Uniform and Non-uniform velocity d) Uniform acceleration and non-uniform acceleration 3. Define Uniform circular motion 4. What do you mean by the term retardation? Give an example 5. Describe the distanc ...
Newton Review
... 4. What is the force in Newton’s of an object whose mass is 100 kg and accelerates at 5 m/s2? F = ma; 500 N = 100 kg x 5 m/s2. 5. What is the acceleration of an object of 100 N that has a mass of 5 kg? 100N/5kg = 20 m/s2 6. What is matter? What is mass? What is volume? What is the volume of a box of ...
... 4. What is the force in Newton’s of an object whose mass is 100 kg and accelerates at 5 m/s2? F = ma; 500 N = 100 kg x 5 m/s2. 5. What is the acceleration of an object of 100 N that has a mass of 5 kg? 100N/5kg = 20 m/s2 6. What is matter? What is mass? What is volume? What is the volume of a box of ...
Newton`s Second Law
... Newton’s First Law: An object at rest remains at rest, and an object in motion remains in motion with the same speed and direction (maintains its velocity) unless it experiences an unbalanced force. Example: A soccer ball resting on the grass remains motionless until a force is applied (a kick). Th ...
... Newton’s First Law: An object at rest remains at rest, and an object in motion remains in motion with the same speed and direction (maintains its velocity) unless it experiences an unbalanced force. Example: A soccer ball resting on the grass remains motionless until a force is applied (a kick). Th ...
Motion In Review
... continues moving in the same direction has changed it’s velocity. A moving object that changes direction but retains the same speed has changed its velocity. ...
... continues moving in the same direction has changed it’s velocity. A moving object that changes direction but retains the same speed has changed its velocity. ...
amanda`sNewton`s First Law
... relationship between motion and force in the laws that we now call Newton’s laws of motion. His laws apply to a wide range of motion like a caterpillar crawling on a leaf, a person riding a bicycle, or a rocket ...
... relationship between motion and force in the laws that we now call Newton’s laws of motion. His laws apply to a wide range of motion like a caterpillar crawling on a leaf, a person riding a bicycle, or a rocket ...
Newton`s Second and Third Laws of Motion
... has more mass it accelerates at a lower rate because mass has inertia. ...
... has more mass it accelerates at a lower rate because mass has inertia. ...
Newton`s Laws Vocabulary
... Newton (N) – the unit for the amount of force an object contains. Traction – a kind of friction that allows wheels to turn without slipping on a surface. Weight – a measure of the heaviness of an object. ...
... Newton (N) – the unit for the amount of force an object contains. Traction – a kind of friction that allows wheels to turn without slipping on a surface. Weight – a measure of the heaviness of an object. ...
Newton`s First Law of Motion
... stop you from flying out of the windshield when you’re in a accident. The car comes to a sudden stop and your body would keep moving if it wasn’t for seatbelts. ...
... stop you from flying out of the windshield when you’re in a accident. The car comes to a sudden stop and your body would keep moving if it wasn’t for seatbelts. ...
Relativity, Inertia, and Equivalence Principle
... frame) Any accelerating system is non-inertial, there would be break in symmetry (a “special” direction would be established) If motion in one dimension is not acceleration, then we can consider an inertial frame along that direction – consider plane flying at constant speed… you could do experiment ...
... frame) Any accelerating system is non-inertial, there would be break in symmetry (a “special” direction would be established) If motion in one dimension is not acceleration, then we can consider an inertial frame along that direction – consider plane flying at constant speed… you could do experiment ...