Motion Relative to a non-inertial frame
... In Eq. (19), we have moved the centripetal and Coriolis accelerations to the force side of the equation. In this situation they are referred to as the centripetal and Coriolis apparent forces per unit mass. Hence, the signs of the centripetal and Coriolis apparent forces per unit mass are opposite t ...
... In Eq. (19), we have moved the centripetal and Coriolis accelerations to the force side of the equation. In this situation they are referred to as the centripetal and Coriolis apparent forces per unit mass. Hence, the signs of the centripetal and Coriolis apparent forces per unit mass are opposite t ...
Inclined Planes
... parallel vector. This is the vector that runs along the plane. This is also the force due to gravity. To solve for this we can use the formula Fgsin=Fg ...
... parallel vector. This is the vector that runs along the plane. This is also the force due to gravity. To solve for this we can use the formula Fgsin=Fg ...
Centripetal Force
... A 200. g mass hung is from a 50. cm string as a conical pendulum. The period of the pendulum in a perfect circle is 1.4 s. What is the angle of the pendulum? What is the tension on the string? ...
... A 200. g mass hung is from a 50. cm string as a conical pendulum. The period of the pendulum in a perfect circle is 1.4 s. What is the angle of the pendulum? What is the tension on the string? ...
Newton`s Laws
... 2. What equation summarizes Newton’s 2nd Law? Give the units used to measure each variable of the equation. ...
... 2. What equation summarizes Newton’s 2nd Law? Give the units used to measure each variable of the equation. ...
Linking Asteroids and Meteorites through Reflectance
... • Inertia - Resistance of any physical object to a change in its state of motion or rest • Gravity – Attractive Force • The inertia of each planet is offset by the sun's gravity • The result is stable orbits around the sun ...
... • Inertia - Resistance of any physical object to a change in its state of motion or rest • Gravity – Attractive Force • The inertia of each planet is offset by the sun's gravity • The result is stable orbits around the sun ...
Science in motion
... the woods by a bull moose which he was attempting to photograph. The enormous mass of the bull moose is extremely intimidating. Yet, if Ben makes a zigzag pattern through the woods, he will be able to use the large mass of the moose to his own advantage. Explain this in terms of inertia and Newton's ...
... the woods by a bull moose which he was attempting to photograph. The enormous mass of the bull moose is extremely intimidating. Yet, if Ben makes a zigzag pattern through the woods, he will be able to use the large mass of the moose to his own advantage. Explain this in terms of inertia and Newton's ...
Force, Net Force, and Inertia
... – Normal, perpendicular force between two objects in contact with each other – Tension of ropes, strings, chains, springs, etc. ...
... – Normal, perpendicular force between two objects in contact with each other – Tension of ropes, strings, chains, springs, etc. ...
Name
... 1. Consider a point on a bicycle wheel as the wheel turns about a fixed axis, neither speeding up nor slowing down. Compare the linear and centripetal accelerations of the point. a Both are zero. b Only the centripetal acceleration is zero. c Only the linear acceleration is zero. d Neither is zero. ...
... 1. Consider a point on a bicycle wheel as the wheel turns about a fixed axis, neither speeding up nor slowing down. Compare the linear and centripetal accelerations of the point. a Both are zero. b Only the centripetal acceleration is zero. c Only the linear acceleration is zero. d Neither is zero. ...
PHY 101 Lecture 4 - Force
... The object undergoes acceleration as it moves. Review: Acceleration is the rate of change of velocity. There are three kinds of acceleration: - The object speeds up. - The object slows down. - The direction of motion changes (the speed may remain constant). ...
... The object undergoes acceleration as it moves. Review: Acceleration is the rate of change of velocity. There are three kinds of acceleration: - The object speeds up. - The object slows down. - The direction of motion changes (the speed may remain constant). ...
Forces in Two Dimensions Section 7.1
... ground. • What angle are these two forces in relation to each other? ...
... ground. • What angle are these two forces in relation to each other? ...
Free Body Diagram
... A diagram of all the external forces on an object. The object is drawn as is floating in space (“free”). •Only include forces on the diagram, not other vectors such as acceleration or velocity. ...
... A diagram of all the external forces on an object. The object is drawn as is floating in space (“free”). •Only include forces on the diagram, not other vectors such as acceleration or velocity. ...
File
... Windows are painted black Move the car to outer space Now imagine placing a few objects on the dashboard of this blacked-out car, still in outer space. If the car accelerates forward, what happens to these objects on the dashboard? (Why?) If you didn’t know the car was accelerating, what would you i ...
... Windows are painted black Move the car to outer space Now imagine placing a few objects on the dashboard of this blacked-out car, still in outer space. If the car accelerates forward, what happens to these objects on the dashboard? (Why?) If you didn’t know the car was accelerating, what would you i ...
Slide 1
... as it applies to Newton’s Law of Gravitation. • To study the motion of objects in orbit as a special application of Newton’s Law of Gravitation. ...
... as it applies to Newton’s Law of Gravitation. • To study the motion of objects in orbit as a special application of Newton’s Law of Gravitation. ...
Newton`s 2nd Law
... In the equation for weight, g is no longer considered the acceleration due to gravity, but rather the gravitational field strength, with units of newtons/kilogram. Inertial and gravitational masses have been tested and are believed to always be equal in amount. This is why all objects freefall at th ...
... In the equation for weight, g is no longer considered the acceleration due to gravity, but rather the gravitational field strength, with units of newtons/kilogram. Inertial and gravitational masses have been tested and are believed to always be equal in amount. This is why all objects freefall at th ...
NOTES AP1 Angular Motion
... Example: A tire with a diameter of 90 cm starts from rest and makes 15 ...
... Example: A tire with a diameter of 90 cm starts from rest and makes 15 ...
Practice Problems Semester 1 Exam 1. Express the measurements
... 23. An object whose mass is 15.0 kg is pushed with a horizontal force of 20.0 N so that the object moves at a constant velocity. A. Draw the free body diagram, identifying the forces. B. Determine the size of all the forces and label them on the drawing. C. Determine the net force on the object. D. ...
... 23. An object whose mass is 15.0 kg is pushed with a horizontal force of 20.0 N so that the object moves at a constant velocity. A. Draw the free body diagram, identifying the forces. B. Determine the size of all the forces and label them on the drawing. C. Determine the net force on the object. D. ...