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

A violin string of length 40 cm and mass 1.4 g has a frequency of 526...

A violin string of length 40 cm and mass 1.4 g has a frequency of 526 Hz when it is vibrating in its fundamental mode. (a) What is the wavelength of the standing wave on the string? (b) What is the tension in the string? (c) Where should you place your finger to increase the frequency to 676 Hz?cm from the fixed end of the string (from the peg of the violin)

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 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? ​

a) Strings on a full-scale violin are 32 centimeters long. The third harmonic of the fourth...

a) Strings on a full-scale violin are 32 centimeters long. The third harmonic of the fourth string vibrates at a frequency of 1320 Hz. What is the wavelength of the vibration of the string in this third-harmonic mode? (Hint: draw a sketch) b) What is the fundamental frequency of this tone? Show your work c) What is the speed of a wave on this string? Show your work d) The violinist firmly places a finger on the string 1/3 of...

A guitar string vibrates in its fundamental mode, with nodes at its ends. The length of...

A guitar string vibrates in its fundamental mode, with nodes at its ends. The length of the rope segment that vibrates freely is 0.386 m. The maximum transverse acceleration of a point at the midpoint of the segment is 8.40x103 m / s2, and the maximum transverse velocity is 3.80 m / s. a) Calculate the amplitude of this standing wave. b) How fast are transverse traveling waves in this rope? a a) 1.72 m b) 543 m/s b a)...

You are playing a violin, where the fundamental frequency of one of the strings is 440...

You are playing a violin, where the fundamental frequency of one of the strings is 440 ??, as you are standing in front of the opening of a long tube that is closed at the other end. As you play, you notice that the first time you hear an echo from the tube is when the sound from the 440 ?? string is in its fourth harmonic. Assuming you are playing this string on earth, what must be the length...

You are playing a violin, where the fundamental frequency of one of the strings is 440...

You are playing a violin, where the fundamental frequency of one of the strings is 440 ??, as you are standing in front of the opening of a long tube that is closed at the other end. As you play, you notice that the first time you hear an echo from the tube is when the sound from the 440 ?? string is in its fourth harmonic. Assuming you are playing this string on earth, what must be the length...

A typical steel B-string in a guitar resonates in its fundamental frequency at 240 Hz. The...

A typical steel B-string in a guitar resonates in its fundamental frequency at 240 Hz. The length of the string is 0.600 m. What is the wave velocity in the string? The tension in the above string is 81.2 N. Calculate the mass of a 4 m long piece of the steel string.   What is the wavelength of the third harmonic of the guitar string described above?

The D-string on a properly tuned guitar produces a tone with a fundamental frequency of 146.8...

The D-string on a properly tuned guitar produces a tone with a fundamental frequency of 146.8 Hz. The oscillating length of a D-string on a certain guitar is 0.63m. (a) What is the wavelength, in meters, of a standing wave in the D-string when it is oscillating at its third harmonic (also called its second overtone)? (b) Determine the frequency, in hertz, of the third harmonic of the tone produced by the properly tuned D-string. (c) The guitarist shortens the...

Each string on a violin is tuned a fifth higher than the one below it (there...

Each string on a violin is tuned a fifth higher than the one below it (there are four strings; from lowest pitch to highest they are G, D, A, and E), so that each has a frequency 3/2 that of the one below it. The A string typically has a frequency of 440 Hz, a diameter of 0.45mm and a bridge-to-pegbox length of 325 mm. Assume the strings are made of steel (density 7800 kg/m3). a. What is the tension...