a. If a violin string vibrates at 480 Hz as its fundamental frequency, what are the...

A string of a violin vibrates in its fundamental mode of one loop with frequency of...

A string of a violin vibrates in its fundamental mode of one loop with frequency of 100 Hz. What will be the frequency of the wave that will produce a three-loop pattern on the same string?

1.An organ pipe is 151 cm long. The speed of sound in air is 343 m/s....

1.An organ pipe is 151 cm long. The speed of sound in air is 343 m/s. a. What are the fundamental and first three audible overtones if the pipe is closed at one end? Express your answers using three significant figures separated by commas. b. What are the fundamental and first three audible overtones if the pipe is open at both ends? Express your answers using three significant figures separated by commas. 2.A particular organ pipe can resonate at 252...

A cello string vibrates in its fundamental mode with a frequency of 159 1/s. The vibrating...

A cello string vibrates in its fundamental mode with a frequency of 159 1/s. The vibrating segment is 32.2 cm long and has a mass of 0.69 g. Find the tension in the string. Answer in units of N. Find the frequency of the string when it vibrates in eight segments. Answer in units of 1/s

A 2.0-mm-long string vibrates at its second-harmonic frequency with a maximum amplitude of 1.4 cmcm ....

A 2.0-mm-long string vibrates at its second-harmonic frequency with a maximum amplitude of 1.4 cmcm . One end of the string is at xxx =0cm=0cm. Find the oscillation amplitude at x =10cm. Express your answer to two significant figures and include the appropriate units. Find the oscillation amplitude at x =20cm. Express your answer to two significant figures and include the appropriate units. Find the oscillation amplitude at x =30cm. Express your answer to two significant figures and include the...

​A string is 6 m long and vibrates with a fundamental frequency of 2000 Hz. If...

​A string is 6 m long and vibrates with a fundamental frequency of 2000 Hz. If you fret down 1/3 ​of the way what is the new fundamental frequency? ​

Using special techniques called string harmonics (or "flageolet tones"), stringed instruments can produce the first few...

Using special techniques called string harmonics (or "flageolet tones"), stringed instruments can produce the first few overtones of the harmonic series. While a violinist is playing some of these harmonics for us, we take a picture of the vibrating string (see figures). Using an oscilloscope, we find the violinist plays a note with frequency f = 795 Hz in figure (a). (d) The fundamental frequency is the lowest frequency that a string can vibrate at (see figure (b)). What is...

A mass m at the end of a spring vibrates with a frequency of 0.88 Hz...

A mass m at the end of a spring vibrates with a frequency of 0.88 Hz . When an additional 660 g mass is added to m, the frequency is 0.56 Hz . What is the value of m? Express your answer using two significant figures.

#1 If the fundamental frequency of an 76 cm long guitar string is 460 Hz, what...

#1 If the fundamental frequency of an 76 cm long guitar string is 460 Hz, what is the speed of the traveling waves? #2: You have an organ pipe that resonates at frequencies of 800, 1120, and 1440 Hz but nothing between these. It may resonate at lower and higher frequencies as well. What is the fundamental frequency for this pipe?

A stretched wire vibrates in its fundamental mode at a frequency of 236 vibrations/s. What would...

A stretched wire vibrates in its fundamental mode at a frequency of 236 vibrations/s. What would be the fundamental frequency if the wire were half as long, with twice the diameter and 2.1 times the tension? Answer in units of Hz.

A thin taut string of mass 5.00 g is fixed at both ends and stretched such...

A thin taut string of mass 5.00 g is fixed at both ends and stretched such that it has two adjacent harmonics of 525 Hz and 630 Hz. The speed of a traveling wave on the string is 168 m/s. PART A: Determine which harmonic corresponds to the 630 Hz frequency. PART B: Find the linear mass density of this string. Express your answer with the appropriate SI units. PART C: Find the tension in the string. Express your answer...