DaleSpam said:Remember that velocity is a vector. A vector has a magnitude and a direction. Speed is the magnitude of the velocity vector. So a velocity can change direction without changing speed. This is still a change in velocity and therefore an acceleration.
Uniform circular motion is a special case of continuous acceleration without a change in speed. Only the direction changes.
I believe that the inference is that the object is 'solid' or more precisely 'rigid', i.e. the points in the object are fixed within the object, in which case if all objects have the same angular velocity, then all points would have the same angular acceleration, i.e. the rate of change of angular velocity would the same for all points in the object.ln motion, on my book, it says "Since w (angular velocity) is the same for all points of a rotating object, a (alpha) also will be the same for all points.w and a are properties of the rotating object as a whole."
Astronuc said:I believe that the inference is that the object is 'solid' or more precisely 'rigid', i.e. the points in the object are fixed within the object, in which case if all objects have the same angular velocity, then all points would have the same angular acceleration, i.e. the rate of change of angular velocity would the same for all points in the object.
Do not confuse angular velocity with linear velocity, since the linear velocity is constantly changes (direction) and the magnitude depends on r, the distance from axis of rotation.
The same angular velocity means the radius to a point sweeps the same angle (angular displacement) during a given time period (same length of time).
Yes, an angular acceleration implies a change in angular velocity, but that is not what the statement is addressing.MIA6 said:but wouldn't the angular velocity change any direction or increase speed when there is an acceleration since I was thinking about the same concept as linear velocity.
Astronuc said:Yes, an angular acceleration implies a change in angular velocity, but that is not what the statement is addressing.
In a rotating object, the only way that every point can have the same angular velocity itex]\omega[/itex] is for the object to be rigid, and that rigidity also means that at a given instant, each point has the same angular acceleration [itex]\alpha[/itex] if a torque is applied to the object. That would not be the case for a fluid (liquid or gas).
Astronuc said:Well angular acceleration is measured in rad/s2, and angular velocity in rad/s, where rad means radians. One revolution represents an angular displacement of 2[itex]\pi[/itex] radians. Radians are dimensionless, i.e. they don't have length.
The magnitude of linear (tangential) velocity of a point in a rotating object is given by v=[itex]\omega[/itex]r, where r is the distance of said point from the axis of rotation.
So the linear (tangential) velocity varies with r.
See if this reference helps - http://hyperphysics.phy-astr.gsu.edu/hbase/rotq.html
http://hyperphysics.phy-astr.gsu.edu/hbase/mi.html
Note the equation [itex]\omega\,=\,\omega_0\,+\,\alpha{t}[/itex], where [itex]\omega\,=\,\omega(t)[/itex]
Astronuc said:If every point has angular velocity 24 rad/s, then some time later, every point has angular velocity of 30 rad/s, then every point accelerated at the same angular acceleration, since every point had the same change in angular velocity over the same period of time.
Close.MIA6 said:Oh, so what you said was, suppose the angular acceleration is 5 rad/s^2, then every point or every instant will increase the same amount 5 rad/s^2 at one second, and then the next second, it will still increase 5 rad/s^2, so that their velocity at every instant is the same, which is unlike translational motion that each point has different/increasing velocity when it undergoes acceleration?
Angular velocity is a measure of the rate at which an object rotates around a fixed point or axis. It is usually represented by the Greek letter omega (ω) and is measured in radians per second.
Angular velocity refers to the rotational motion of an object, while linear velocity refers to the straight-line motion of an object. Angular velocity is measured in radians per second, while linear velocity is measured in meters per second.
The relationship between angular velocity and linear velocity can be described by the equation v = rω, where v is linear velocity, r is the radius of rotation, and ω is angular velocity. This means that the linear velocity of an object increases as its distance from the axis of rotation increases.
Angular velocity is directly related to the speed of rotation of an object. The faster an object rotates, the greater its angular velocity. Additionally, changes in angular velocity can also impact the direction and stability of rotational motion.
Angular velocity is typically measured using a tool called an accelerometer, which detects changes in the rotational motion of an object and converts it into a readable value. It can also be calculated by dividing the change in angular position by the change in time.