Definitions
... reference system for measuring position and time that is not accelerating. If we wish to use Newton’s Second Law in an accelerating reference frame, we need to add extra terms to the equation that can be considered as forces operating on every object that we track using the accelerating reference fr ...
... reference system for measuring position and time that is not accelerating. If we wish to use Newton’s Second Law in an accelerating reference frame, we need to add extra terms to the equation that can be considered as forces operating on every object that we track using the accelerating reference fr ...
Sects. 4.9 & 4.10
... Non-Inertial Frames • The most common example of a non-inertial frame = Earth’s surface! Another is rigid body rotation. • We usually assume Earth’s surface is inertial, when it is not! – A coord system fixed on the Earth is accelerating (Earth’s rotation + orbital motion) & is thus non-inertial! – ...
... Non-Inertial Frames • The most common example of a non-inertial frame = Earth’s surface! Another is rigid body rotation. • We usually assume Earth’s surface is inertial, when it is not! – A coord system fixed on the Earth is accelerating (Earth’s rotation + orbital motion) & is thus non-inertial! – ...
ICNS 132 : Rotational Motion and Equilibrium
... constant velocity and constant angular velocity relative to an observer in an inertial reference frame. •Will deal now with the special case in which both of these velocities are equal to zero – This is called static equilibrium. ...
... constant velocity and constant angular velocity relative to an observer in an inertial reference frame. •Will deal now with the special case in which both of these velocities are equal to zero – This is called static equilibrium. ...
11.2 Questions Force and Mass Determine Acceleration 1. What 3
... 8. A mass is 2kg. What other information do you need to calculate acceleration? 2. Look at the picture on page 354. What do the arrows in the diagrams show? 9. If an object moves at a constant speed, but it accelerates, what changes? 3. What happens to the acceleration of an object when the force on ...
... 8. A mass is 2kg. What other information do you need to calculate acceleration? 2. Look at the picture on page 354. What do the arrows in the diagrams show? 9. If an object moves at a constant speed, but it accelerates, what changes? 3. What happens to the acceleration of an object when the force on ...
hp1f2013_class15_rolling_motion_and_accelerating_frames
... The Principle of Equivalence states that there is no way to distinguish locally* between a gravitational acceleration and an acceleration of the coordinate system. *Locally means that we don’t look outside the system for the cause of an acceleration or gravity. ...
... The Principle of Equivalence states that there is no way to distinguish locally* between a gravitational acceleration and an acceleration of the coordinate system. *Locally means that we don’t look outside the system for the cause of an acceleration or gravity. ...
Notes for Newton
... 1. An object in motion will remain in motion, an object at rest will remain at rest unless acted on by an outside force. 2. Inertia – a measure of the resistance to change motion i. Dependant on mass – as mass increases, inertia increases ii. Independent of Velocity 3. Equilibrium – When the sum of ...
... 1. An object in motion will remain in motion, an object at rest will remain at rest unless acted on by an outside force. 2. Inertia – a measure of the resistance to change motion i. Dependant on mass – as mass increases, inertia increases ii. Independent of Velocity 3. Equilibrium – When the sum of ...
cm16_9
... parallel and perpendicular axis theorems rigid body rotation, moment of inertia, precession ...
... parallel and perpendicular axis theorems rigid body rotation, moment of inertia, precession ...
Newton`s Second Law
... Friction: a force that occurs when two touching objects move past each other. Frictional force is always in the opposite direction to the motion. ...
... Friction: a force that occurs when two touching objects move past each other. Frictional force is always in the opposite direction to the motion. ...
Physics 430
... 2 rad W 7.3 10 5 rad/s. 24 3600 s We will assume that the inertial frame So and rotating frame S share the same origin, so the only motion of S relative to So is a rotation with angular velocity W. For example, the common origin could be the center of the Earth. Now consider an arbitrary ...
... 2 rad W 7.3 10 5 rad/s. 24 3600 s We will assume that the inertial frame So and rotating frame S share the same origin, so the only motion of S relative to So is a rotation with angular velocity W. For example, the common origin could be the center of the Earth. Now consider an arbitrary ...
physics140-f07-lecture5 - Open.Michigan
... You assume all responsibility for use and potential liability associated with any use of the material. Material contains copyrighted content, used in accordance with U.S. law. Copyright holders of content included in this material should contact [email protected] with any questions, correction ...
... You assume all responsibility for use and potential liability associated with any use of the material. Material contains copyrighted content, used in accordance with U.S. law. Copyright holders of content included in this material should contact [email protected] with any questions, correction ...
Air Pressure, Forces, and Motion
... Mass is a measure of an object’s inertia Mass is also a measure of the amount of an object’s matter content. (i.e. protons, neutrons, and electrons) ...
... Mass is a measure of an object’s inertia Mass is also a measure of the amount of an object’s matter content. (i.e. protons, neutrons, and electrons) ...
Lecture 1 Forces on a rotating planet Lecture 2 We will describe the
... relative to the stars appears to move when viewed from the Earth. 2. An object moving at constant velocity relative to the stars seems to change direction when viewed from the rotating Earth. ...
... relative to the stars appears to move when viewed from the Earth. 2. An object moving at constant velocity relative to the stars seems to change direction when viewed from the rotating Earth. ...
Definitions - Planetscience
... Every object in a state of uniform motion tends to remain in that state of motion unless an external force is applied to it. Force = Mass x Acceleration The relationship between an object's mass (m), its acceleration (a), and the applied force (f) is “F = ma”. Acceleration and force are vectors. In ...
... Every object in a state of uniform motion tends to remain in that state of motion unless an external force is applied to it. Force = Mass x Acceleration The relationship between an object's mass (m), its acceleration (a), and the applied force (f) is “F = ma”. Acceleration and force are vectors. In ...
Newton`s law clickview worksheet File
... Explain why a table cloth pulled slowly moves an object with it but when pulled quickly slides from underneath the object? ...
... Explain why a table cloth pulled slowly moves an object with it but when pulled quickly slides from underneath the object? ...
