The wave speed of a stretched string is determined by the properties of the medium, specifically its tension (τ) and linear mass density (μ), as described by the equation v = √(τ/μ). While the wave speed is independent of frequency and wavelength, these parameters are interrelated through the equation v = λƒ, where λ is the wavelength and ƒ is the frequency. The medium's characteristics, such as mass and density, significantly influence wave speed, with lower mass and higher density resulting in faster wave propagation. Additionally, the source of the wave affects frequency but does not directly impact wave speed in a uniform medium.
PREREQUISITESPhysics students, educators, and professionals in engineering fields who are interested in wave mechanics and the properties of different mediums affecting wave propagation.
The source does not play any role in wave speed other than through the fact that some media have dispersion relations such that the wave velocity is frequency dependent. The relation v = λf can rather be thought of as relating the frequency and wave length for a given wave velocity, i.e., for a wave with wave velocity v, a wave of frequency f will have wave length λ = v/f. Of course, if you measure the wave length and frequency, you can infer what the velocity is (and thus obtain information on the internal properties of the medium).Zachary Samples said:The medium plays a very big role in wave speed. If the waves travel along a string, the lower the mass and greater the density of the string, the faster waves travel across the string. Waves also travel much more slowly in the air than they do underwater or along a dense string. I'm sure the source of the wave plays a role in its speed as well, but I'm not sure how. This source has some information on it: http://dev.physicslab.org/Document.aspx?doctype=3&filename=WavesSound_WavesAlongStrings.xml