Two stretched strings on a musical instrument each are fixed at both of their ends. String...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at successive (that is, modes m and m + 1) frequencies of 38 Hz and 42 Hz respectively. The tension in the string is 720 N. What is the fundamental frequency of the standing wave? Hint: recall that every harmonic frequency of a standing wave is a multiple of the fundamental frequency. What is the speed of the wave in the string? What is the...

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. (a) Determine which harmonic corresponds to the 630 Hz frequency. (b) Find the linear mass density of this string. (c) Find the tension in the string.

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...

A standing wave is set up in a L=2.00m long string fixed at both ends. The...

A standing wave is set up in a L=2.00m long string fixed at both ends. The string vibrates in its 5th harmonic when driven by a frequency f=120Hz source. The mass of the string is m=3.5grams. Recall that 1kg = 1000grams. A. Find the linear mass density of the string B. What is the wavelength of the standing wave C. What is the wave speed D. What is the tension in the string E. what is the first harmonic frequency...

Two violin strings each have a length of 0.32 m and are each under a tension...

Two violin strings each have a length of 0.32 m and are each under a tension of 51 N. The lighter string has a mass density of 6.43x10-4 kg/m, whereas the heavier string has a mass density of 2.48x10-3 kg/m. (Note, for stringed instruments, both ends of the string are fixed.) (a) What are the fundamental frequencies of the (i) lighter and (ii) heavier violin strings? (b) These strings are plucked simultaneously in such a way that the fundamental of...

1)Suppose you have a string with linear mass density u=4.5 g/m, with two fixed ends 1.0...

1)Suppose you have a string with linear mass density u=4.5 g/m, with two fixed ends 1.0 m apart. What is the velocity of a wave on the string if the tension of the string is supplied by a hanging mass of 250 g? 2) For the previous question, what are the three lwoest frequencies that you could observe in a standing wave?

A guitar string with a linear density of 2.0 g/m is stretched between supports that are...

A guitar string with a linear density of 2.0 g/m is stretched between supports that are 60 cm apart. The string is observed to form a standing wave with three antinodes when driven at a frequency of 420 Hz. What are (a) the frequency of the fifth harmonic of this string and (b) the tension in the string?

To apply Problem-Solving Strategy 12.1 Standing waves and normal modes. A cellist tunes the C string...

To apply Problem-Solving Strategy 12.1 Standing waves and normal modes. A cellist tunes the C string of her instrument to a fundamental frequency of 65.4 Hz H z . The vibrating portion of the string is 0.600 m m long and has a mass of 14.4 g g . With what tension must she stretch that portion of the string? What percentage increase in tension is needed to increase the frequency from 65.4 Hz H z to 73.4 Hz H...

A nylon guitar string has a linear density of 9.3 g/m and is under a tension...

A nylon guitar string has a linear density of 9.3 g/m and is under a tension of 151 N. The fixed supports are distance D = 98 cm apart. The string is oscillating in the standing wave pattern shown in the following figure. Calculate the frequency of the traveling waves for this standing wave.

Acoustic 7. One string of a certain musical instrument is 80 cm long and has mass...

Acoustic 7. One string of a certain musical instrument is 80 cm long and has mass of 8,72 gram. It is being played in a room where the speed of sound is 344 m/s. a. To what tension must you adjust the string so that, when vibrating in its second overtone, it produces sound of wavelength 3,40 cm? b. What frequency sound does this string produce in its fundamental mode of vibration? PLEASE ANSWER CLEARLY