Examples of angular motion in the following topics:
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- The description of motion could be sometimes easier with angular quantities such as angular velocity, rotational inertia, torque, etc.
- The description of circular motion is described better in terms of angular quantity than its linear counter part.
- When we describe the uniform circular motion in terms of angular velocity, there is no contradiction.
- This is the first advantage of describing uniform circular motion in terms of angular velocity.
- For the description of the motion, angular quantities are the better choice.
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- Torque is equal to the moment of inertia times the angular acceleration.
- Torque and angular acceleration are related by the following formula where is the objects moment of inertia and $\alpha$ is the angular acceleration .
- Similar to Newton's Second Law, angular motion also obeys Newton's First Law.
- If no outside forces act on an object, an object in motion remains in motion and an object at rest remains at rest.
- Torque, Angular Acceleration, and the Role of the Church in the French Revolution
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- The familiar linear vector quantities such as velocity and momentum have analogous angular quantities used to describe circular motion.
- Linear motion is motion in a straight line.
- Similarly, circular motion is motion in a circle.
- However, we can define an angular momentum vector which is constant throughout this motion.
- Constant angular velocity in a circle is known as uniform circular motion.
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- Uniform circular motion is a motion in a circular path at constant speed.
- Under uniform circular motion, angular and linear quantities have simple relations.
- We define angular velocity $\omega$ as the rate of change of an angle.
- In symbols, this is $\omega = \frac{\Delta \theta}{\Delta t}$, where an angular rotation $\Delta\theta$ takes place in a time $\Delta t$.
- Under uniform circular motion, the angular velocity is constant.
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- Angular acceleration is the rate of change of angular velocity.
- Angular acceleration is defined as the rate of change of angular velocity.
- An object undergoing circular motion experiences centripetal acceleration (as seen in the diagram below.)
- Centripetal acceleration occurs as the direction of velocity changes; it is perpendicular to the circular motion.
- In circular motion, acceleration can occur as the magnitude of the velocity changes: a is tangent to the motion.
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- Constant angular acceleration describes the relationships among angular velocity, angle of rotation, and time.
- Kinematics is the description of motion.
- Similarly, the kinematics of rotational motion describes the relationships among rotation angle, angular velocity, angular acceleration, and time.
- To determine this equation, we use the corresponding equation for linear motion:
- This figure shows uniform circular motion and some of its defined quantities.
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- The motion of rolling without slipping can be broken down into rotational and translational motion.
- Rolling without slipping can be better understood by breaking it down into two different motions: 1) Motion of the center of mass, with linear velocity v (translational motion); and 2) rotational motion around its center, with angular velocity w.
- If we imagine a wheel moving forward by rolling on a plane at speed v, it must also be rotating about its axis at an angular speed $\omega$ since it is rolling.
- where $dx/dt$ is equal to the linear velocity $v$, and dθ/dt is equal to the angular velocity $\omega$.
- Distinguish the two different motions in which rolling without slipping is broken down
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- When an object rotates about an axis, as with a tire on a car or a record on a turntable, the motion can be described in two ways.
- Angular acceleration gives the rate of change of angular velocity.
- The angle, angular velocity, and angular acceleration are very useful in describing the rotational motion of an object.
- The object is rotating with an angular velocity equal to $\frac{v}{r}$.
- The direction of the angular velocity will be along the axis of rotation.
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- This fact is readily seen in linear motion.
- What if an rotational component of motion is introduced?
- For objects with a rotational component, there exists angular momentum.
- Angular momentum is defined, mathematically, as L=Iω, or L=rxp.
- An object that has a large angular velocity ω, such as a centrifuge, also has a rather large angular momentum.
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- The law of conservation of angular momentum states that when no external torque acts on an object, no change of angular momentum will occur.
- There appears to be a numerical quantity for measuring rotational motion such that the total amount of that quantity remains constant in a closed system.
- The symbol for angular momentum is the letter L.
- We can see this by considering Newton's 2nd law for rotational motion:
- If the change in angular momentum ΔL is zero, then the angular momentum is constant; therefore,