A standard guitar, whether acoustic or electric, has six strings, all with essentially the same total length between the bridge and the nut at the tuning head. Each string vibrates at a different frequency determined by the tension on the string and the mass per unit length of the string. In order to create pitches (notes) other than these six, the guitarist presses the strings down against the fretboard, thus shortening the length of the strings and changing their frequencies. In other words, the vibrating frequency of a string depends on tension, length, and mass per unit length of the string. The equation for the fundamental frequency of a vibrating string is given by
Where
f = frequency [IIz]
T = string tension [N]
µ = mass per unit length [kg/m]
L= string length [ m]
Many electric guitars have a device often called a "whammy" bar or a "tremolo" bar that allows the guitarist to change the tension on the strings quickly and easily, thus changing the frequency of the strings. (Think of Jimi Hendrix simulating "the rockets' red glare, the bombs bursting in air" in his rendition of The Star Spangled Banner-a true tour de force. ) In designing a new whammy bar, we test our design by collecting data using a single string on the guitar and creating a graph of the observed frequency at different string tensions as shown.
- a. What are the units of the coefficient (16.14 )?
- b. If the observed frequency is 150 hertz, what is the string tension in newtons?
- c. If mass per unit length is 2.3 grams per meter, what is the length of the string in meters?
- d. If the length of the string is 0.67 meters, what is the mass per unit length in kilograms per meter?
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