8 ROTATIONAL MOTION 8.3 Is rotation a vector?
velocities are conventionally measured in radians per second, whereas angular
accelerations are measured in radians per second squared.
For a body rotating with constant angular velocity, ω, the angular accelerationis zero, and the rotation angle φ increases linearly with time:
φ(t) = φ 0 + ω t, (8.4)where φ 0 = φ(t = 0). Likewise, for a body rotating with constant angular accel-
eration, α, the angular velocity increases linearly with time, so that
ω(t) = ω 0 + α t, (8.5)and the rotation angle satisfies
φ(t) = φ 0
+ ω 0
t +1
α t^2. (8.6)
2Here, ω 0 = ω(t = 0). Note that there is a clear analogy between the above equa-
tions, and the equations of rectilinear motion at constant acceleration introduced
in Sect. 2.6—rotation angle plays the role of displacement, angular velocity plays
the role of (regular) velocity, and angular acceleration plays the role of (regular)
acceleration.
8.3 Is rotation a vector?
Consider a rigid body which rotates through an angle φ about a given axis. It
is tempting to try to define a rotation “vector” φ which describes this motion.
For example, suppose that φ is defined as the “vector” whose magnitude is the
angle of rotation, φ, and whose direction runs parallel to the axis of rotation.
Unfortunately, this definition is ambiguous, since there are two possible directions
which run parallel to the rotation axis. However, we can resolve this problem by
adopting the following convention—the rotation “vector” runs parallel to the axis
of rotation in the sense indicated by the thumb of the right-hand, when the fingers
of this hand circulate around the axis in the direction of rotation. This convention
is known as the right-hand grip rule. The right-hand grip rule is illustrated in
Fig. 68.