Notice that v depends only on the physical characteristics of the string—its tension
and linear density. The medium (the rope) has no changed, so the wave speed does
not change. Because v = λf for a given stretched string, varying f will create
different waves that have different wavelengths, but v will not vary.
Questions 3-4
A horizontal rope with linear mass density μ = 0.5 kg/m has a
tension of 50 N. The non-attached end is oscillated vertically with a
frequency of 2 Hz.
- What are the speed and wavelength of the resulting wave?
- How would you answer these questions if f were increased to 5
Hz?
Here’s How to Crack It
- Wave speed is established by the physical characteristics of the rope.
With v, we can find the wavelength: λ = v/f = (10 m/s)/(2 Hz) = 5 m.
- If f were increased to 5 Hz, then v would not change, but λ would; the
new wavelength would be
λ′ = v / f′ = (10 m/s)/(5 Hz) = 2 m
Wave Rule #2: When a wave passes into a new medium, its frequency
stays the same.
The Skinny on
Wave Rule #2