String Vibrations: Determine Wavelength & Fundamental Frequency

The fundamental frequency would be 120Hz. In summary, the wavelength of the standing wave on a 120-cm-long string driven at 120Hz is 60cm, and the fundamental frequency of the string is 120Hz.
  • #1
Husker70
90
0

Homework Statement


A standing wave is established in a 120-cm-long string fixed at both
ends. The string vibrates in four segments when driven at 120Hz.
(a) Determine the wavelength
(b) What is the fundamental frequency of the string?

Homework Equations


(a) Lambda = 2L/n


The Attempt at a Solution


(a) Lambda = 2(120cm) / 4 = 60cm

Is this right? doesn't seem to be
Kevin
 
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  • #2
Hi Husker70,

Husker70 said:

Homework Statement


A standing wave is established in a 120-cm-long string fixed at both
ends. The string vibrates in four segments when driven at 120Hz.
(a) Determine the wavelength
(b) What is the fundamental frequency of the string?

Homework Equations


(a) Lambda = 2L/n


The Attempt at a Solution


(a) Lambda = 2(120cm) / 4 = 60cm

Is this right? doesn't seem to be

That looks right to me.
 
  • #3
,

Your attempt at a solution is correct. The wavelength of the string would indeed be 60 cm. This can be determined by using the formula Lambda = 2L/n, where L is the length of the string and n is the number of segments in which the string vibrates. In this case, the string vibrates in four segments, so n=4. The length of the string is given as 120 cm, so the wavelength would be 60 cm.

To check if your answer is correct, we can also use the formula for frequency, f = v/lambda, where v is the speed of the wave. In this case, the wave is traveling along the string, so we can use the speed of the wave on a string, which is given by v = sqrt(T/m), where T is the tension in the string and m is the mass per unit length of the string. Since these values are not given, we can assume them to be constant for simplicity. Therefore, the frequency of the wave would be f = v/lambda = sqrt(T/m)/lambda. Since both T and m are constants, the frequency would be directly proportional to the inverse of the wavelength. This means that if the wavelength is halved, the frequency would double and vice versa. In our case, the wavelength has indeed halved from the original 120 cm to 60 cm, so the frequency must have doubled from the original 60 Hz to 120 Hz. This confirms that your answer for the wavelength is correct.

(b) To determine the fundamental frequency of the string, we can use the formula f = nv/2L, where n is the number of segments in which the string vibrates, v is the speed of the wave, and L is the length of the string. In this case, n=4, v is the same as before, and L=120 cm. Plugging in these values, we get f = (4*sqrt(T/m))/2(120 cm) = sqrt(T/m)/60 cm. Since T and m are constants, we can see that the fundamental frequency is directly proportional to the inverse of the length of the string. This means that if the length of the string is halved, the fundamental frequency would double and vice versa. In our case, the length of the string has been halved from the original 240 cm to 120 cm, so the fundamental frequency would double from the original 60 Hz
 

Related to String Vibrations: Determine Wavelength & Fundamental Frequency

1. What is the relationship between string length and wavelength?

The wavelength of a string vibration is directly proportional to the length of the string. This means that as the length of the string increases, the wavelength also increases.

2. How do you determine the fundamental frequency of a vibrating string?

The fundamental frequency of a vibrating string can be determined by dividing the speed of the wave by the string's length. This can be represented by the equation f = v/2L, where f is the fundamental frequency, v is the speed of the wave, and L is the length of the string.

3. What factors affect the fundamental frequency of a vibrating string?

The fundamental frequency of a vibrating string is affected by three main factors: tension, length, and mass per unit length. As tension increases, the fundamental frequency increases. As length decreases, the fundamental frequency increases. And as mass per unit length decreases, the fundamental frequency increases.

4. How does string thickness impact the wavelength and fundamental frequency?

The thickness of a string has a direct effect on the fundamental frequency and wavelength. A thicker string will have a lower fundamental frequency and a longer wavelength compared to a thinner string of the same length and tension.

5. Can the wavelength and fundamental frequency of a vibrating string be changed?

Yes, the wavelength and fundamental frequency of a vibrating string can be changed by altering the tension, length, or mass per unit length of the string. Additionally, changing the material or thickness of the string can also affect these values.

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