Analogies

We've looked at several analogies between straight-line motion and rotational motion, including:

VariableStraight-line motionRotational motionConnection
Displacement x θ θ = x/r
Velocity v ω ω = v/r
Acceleration a α α = a/r
Produces motion F τ τ = r × F
Inertia m I I = r2 dm
Second Law ΣF = ma Στ = I α
Work

W = F d

W = τ Δθ
Kinetic Energy K = ½ mv2 K = ½2
Power

P = F v

P = τ ω
Momentump = mv L = Iω L = r × p
Impulse Δp = F Δt ΔL = τ Δt

Gyroscopes

Gyroscopes can be very precise navigational tools. If they are well-balanced and there is no gravitational torque (or torque from anything else) then a gyroscope with a particular angular momentum should maintain that direction. A rotating gyroscope in a plane, for instance, will keep pointing in the same direction even when the plane changes direction.

Toy gyroscopes are generally built so that there is a torque from the force of gravity acting on the gyro. This is a good example of impulse in a rotational setting. A gyro with an angular momentum that is anything other than vertical will feel a gravitational torque directed horizontally, perpendicular to the direction of the angular momentum.

According to the impulse equation, ΔL = τ Δt, the torque will produce a change in the angular momentum, with the change in momentum and the torque pointing in the same direction. This has the effect of rotating the gyro's angular momentum about a vertical axis - this is known as precession.

Sample Problem

A cylinder of mass M and radius R has a string wrapped around it, with the string coming off the cylinder above the cylinder. If the string is pulled to the right with a force F, what is the acceleration of the cylinder if the cylinder rolls without slipping?

  1. a = F/M
  2. a < F/M
  3. a > F/M

One key to the problem is realizing that there is a static friction force acting on the cylinder. Let's assume this force acts to the left.

Draw the free-body diagram. Take positive to the right, and clockwise.

The normal force cancels Mg vertically. Apply Newton's Second Law for horizontal forces, and for torques:
Forces | Torques
ΣFx = Ma | Στ = I α
F - fs = Ma | RF + Rfs = ½ MR2α

For rolling without slipping, α = a/R.

The torque equation becomes:

RF + Rfs = ½ MR2a/R

R's cancel, leaving:

F + fs = ½ Ma

The force equation is:

F - fs = Ma

Subtracting the force equation from the torque equation gives:

fs = -(1/4)Ma

The minus sign means the force of friction is not to the left, as we assumed, but to the right.

The equations also show that fs = -(1/3)F

and that a = (4/3)F/M

This is rather surprising, but seeing as we've carefully applied Newton's Laws we can be confident in our answer.