Chapter 7 - Circular Motion
... An inward net force is required to make a turn in a circle. This inward net force requirement is known as a centripetal force requirement. In the absence of any net force, an object in motion (such as the passenger) continues in motion in a straight line at constant speed. This is Newton's first la ...
... An inward net force is required to make a turn in a circle. This inward net force requirement is known as a centripetal force requirement. In the absence of any net force, an object in motion (such as the passenger) continues in motion in a straight line at constant speed. This is Newton's first la ...
Section 2.1,2.2,2.4
... 1) Using the geometry and trigonometry, resolve and write F1 and F2 in the Cartesian vector form. 2) Add F1 and F2 to get FR . 3) Determine the magnitude and angles , , . ...
... 1) Using the geometry and trigonometry, resolve and write F1 and F2 in the Cartesian vector form. 2) Add F1 and F2 to get FR . 3) Determine the magnitude and angles , , . ...
Name Pd ____ Date Physics Unit 6: Rotational Inertia Math Problems
... 12. For the same mass and radius you would expect a solid sphere to have a smaller / larger rotational inertia than a hollow sphere. 13. For a hollow sphere and solid sphere made of the same material and with the same radius you would expect the hollow / solid sphere to have the larger rotational in ...
... 12. For the same mass and radius you would expect a solid sphere to have a smaller / larger rotational inertia than a hollow sphere. 13. For a hollow sphere and solid sphere made of the same material and with the same radius you would expect the hollow / solid sphere to have the larger rotational in ...
Rotational speed
... center of gravity is A) displaced from its center. B) in the same place as its center of mass. C) stabilized by its structure. D) relatively low for such a tall building. E) above a place of support. ...
... center of gravity is A) displaced from its center. B) in the same place as its center of mass. C) stabilized by its structure. D) relatively low for such a tall building. E) above a place of support. ...
Ch15 - Oscillations
... A physical pendulum will not show SHM if pivoted about its com The center of oscillation of a physical pendulum is the length L0 of a simple pendulum with the same period ...
... A physical pendulum will not show SHM if pivoted about its com The center of oscillation of a physical pendulum is the length L0 of a simple pendulum with the same period ...
9.hamilton11e_ppt_11
... Angular to linear displacement: s = r C traveled farther than A or B, in the same time. C had a greater linear velocity than A or B. All three have the same angular velocity, but the linear velocity of the circular motion is proportional to the length of the lever. ...
... Angular to linear displacement: s = r C traveled farther than A or B, in the same time. C had a greater linear velocity than A or B. All three have the same angular velocity, but the linear velocity of the circular motion is proportional to the length of the lever. ...
Additional Science Physics 2a: Motion (1)
... Explain that the slope of distance-time graph represents the speed of an object Calculate the velocity of an object given the distance travelled and the time taken. Explain how the slope of a velocity-time graph represents the acceleration of an object Calculate the acceleration of an object given i ...
... Explain that the slope of distance-time graph represents the speed of an object Calculate the velocity of an object given the distance travelled and the time taken. Explain how the slope of a velocity-time graph represents the acceleration of an object Calculate the acceleration of an object given i ...
Momentum
... No, both are the same. Yes, less if it lands on the carpet. No, less if it lands on a hard floor. No, more if it lands on a hard floor. Explanation: The momentum becomes zero in both cases, so both change by the same amount. Although the momentum change and impulse are the same, the force is less wh ...
... No, both are the same. Yes, less if it lands on the carpet. No, less if it lands on a hard floor. No, more if it lands on a hard floor. Explanation: The momentum becomes zero in both cases, so both change by the same amount. Although the momentum change and impulse are the same, the force is less wh ...
Motion in One Dimension
... • Free-fall acceleration is the same for all objects, regardless of mass. • This book will use the value g = 9.81 m/s2. • Free-fall acceleration on Earth’s surface is – 9.81 m/s2 at all points in the object’s motion. • Consider a ball thrown up into the air. – Moving upward: velocity is decreasing, ...
... • Free-fall acceleration is the same for all objects, regardless of mass. • This book will use the value g = 9.81 m/s2. • Free-fall acceleration on Earth’s surface is – 9.81 m/s2 at all points in the object’s motion. • Consider a ball thrown up into the air. – Moving upward: velocity is decreasing, ...
Classical Mechanics - Manybody Physics Group.
... cylindrical coordinate representation of the position vector r with that of the Cartesian system. Since the motion along the z-axis is trivial, we will confine ourselves to the two-dimensional motion in which r = rˆ r. The translation of the particle’s coordinate from Cartesian to cylindrical system ...
... cylindrical coordinate representation of the position vector r with that of the Cartesian system. Since the motion along the z-axis is trivial, we will confine ourselves to the two-dimensional motion in which r = rˆ r. The translation of the particle’s coordinate from Cartesian to cylindrical system ...
8 Linear Momentum and Collisions
... The effect of a force on an object depends on how long it acts, as well as how great the force is. In Example 8.1, a very large force acting for a short time had a great effect on the momentum of the tennis ball. A small force could cause the same change in momentum, but it would have to act for a m ...
... The effect of a force on an object depends on how long it acts, as well as how great the force is. In Example 8.1, a very large force acting for a short time had a great effect on the momentum of the tennis ball. A small force could cause the same change in momentum, but it would have to act for a m ...
Chapter 2
... The Newton-Euler equations we have derived are not in an appropriate form for use in dynamic analysis and control design. They do not explicitly describe the input-output relationship, unlike the relationships we obtained in the kinematic and static analyses. In this section, we modify the Newton-Eu ...
... The Newton-Euler equations we have derived are not in an appropriate form for use in dynamic analysis and control design. They do not explicitly describe the input-output relationship, unlike the relationships we obtained in the kinematic and static analyses. In this section, we modify the Newton-Eu ...
Relativistic angular momentum
""Angular momentum tensor"" redirects to here.In physics, relativistic angular momentum refers to the mathematical formalisms and physical concepts that define angular momentum in special relativity (SR) and general relativity (GR). The relativistic quantity is subtly different from the three-dimensional quantity in classical mechanics.Angular momentum is a dynamical quantity derived from position and momentum, and is important; angular momentum is a measure of an object's ""amount of rotational motion"" and resistance to stop rotating. Also, in the same way momentum conservation corresponds to translational symmetry, angular momentum conservation corresponds to rotational symmetry – the connection between symmetries and conservation laws is made by Noether's theorem. While these concepts were originally discovered in classical mechanics – they are also true and significant in special and general relativity. In terms of abstract algebra; the invariance of angular momentum, four-momentum, and other symmetries in spacetime, are described by the Poincaré group and Lorentz group.Physical quantities which remain separate in classical physics are naturally combined in SR and GR by enforcing the postulates of relativity, an appealing characteristic. Most notably; space and time coordinates combine into the four-position, and energy and momentum combine into the four-momentum. These four-vectors depend on the frame of reference used, and change under Lorentz transformations to other inertial frames or accelerated frames.Relativistic angular momentum is less obvious. The classical definition of angular momentum is the cross product of position x with momentum p to obtain a pseudovector x×p, or alternatively as the exterior product to obtain a second order antisymmetric tensor x∧p. What does this combine with, if anything? There is another vector quantity not often discussed – it is the time-varying moment of mass (not the moment of inertia) related to the boost of the centre of mass of the system, and this combines with the classical angular momentum to form an antisymmetric tensor of second order. For rotating mass–energy distributions (such as gyroscopes, planets, stars, and black holes) instead of point-like particles, the angular momentum tensor is expressed in terms of the stress–energy tensor of the rotating object.In special relativity alone, in the rest frame of a spinning object; there is an intrinsic angular momentum analogous to the ""spin"" in quantum mechanics and relativistic quantum mechanics, although for an extended body rather than a point particle. In relativistic quantum mechanics, elementary particles have spin and this is an additional contribution to the orbital angular momentum operator, yielding the total angular momentum tensor operator. In any case, the intrinsic ""spin"" addition to the orbital angular momentum of an object can be expressed in terms of the Pauli–Lubanski pseudovector.