the equation for the possible wavelengths of standing waves on a string in terms of the length of the string and the harmonic numbers:
lambda = ?
the equation for the possible wavelengths of standing waves on a string in terms of the...
Complete the equation for the possible wavelengths of standing waves in a closed-ended tube in terms of the length of the tube and the harmonic numbers lambda = ?
A string fixed at both ends has successive resonances with wavelengths of 0.55 m for the nth harmonic and 0.53 m for the (n + 1)th harmonic. (a) What are the following values? nth harmonic (n + 1)th harmonic (b) What is the length of the string? m Use the fact that the resonance frequencies are multiples of the fundamental frequency and are expressible in terms of the speed of the waves and their wavelengths to find the harmonic numbers....
a) Find the pattern of allowed wavelengths and frequencies for standing waves inside a pipe of length L open at both ends. Show how you arrive at your answer. b) If the length of the pipe is 1.00 m and it is filled with air, tell me the frequency of the 5th harmonic.
Standing Waves: Calculate the mass density of the following string: m=35.0 g L=75cm Mass per unit length= ?? kg/m Knowing the velocity of a wave in the string, we can calculate the frequencies and wavelengths of the harmonics in the string using: wavelength_n=2L/n f_n=f_1 f_1=v/2L (n=1,2,3...) Draw the standing wave and calculate the wavelength and frequency for the following harmonics, assuming a string with a length of 2.0 m. Harmonic number Wavelength Frequency Draw the standing wave n=1 Wavelength_1=? f_1=?...
What are the three longest wavelengths for standing waves on a 210-cm-long string that is fixed at both ends? Enter your answers in meters in ascending order separated by commas. If the frequency of the second-longest wavelength in part a is 50.0 Hz , what is the frequency of the third-longest wavelength?
consider the wavelengths 1.75m 3.5m 5m andd 7m which of these will produce standing waves on a string that is 3.5m long
In the standing waves experiment, the string has a mass of 40.6 g string and length of 1.20 m. The string is connected to a mechanical wave generator that produce standing waves with frequency of f. The other end of the string is connected to a mass holder (mholder = 50.0 g) that carries a weight of 5.00x102 g. Calculate the velocity of the standing waves in the string. (g = 9.80 m/s2)
4) In the Standing Waves experiment, the length of the string between the pulley and vibrator is 135 cm, the suspended mass is 160 g, the mass of a piece of the string of 10 m-length is 7.3 g.A student observes a standing wave of mode four. What is the vibrator's frequency?
4) In the Standing Waves experiment, the length of the string between the pulley and vibrator is 135 cm, the suspended mass is 160 g, the mass of...
In the standing waves experiment, the string has a mass of 39.4 g string and length of 1.11 m. The string is connected to a mechanical wave generator that produce standing waves with frequency of f. The other end of the string is connected to a mass holder (mholder = 50.0 g) that carries a weight of 5.00x102 g. Calculate the tension in the string. (g = 9.80 m/s2)
In the standing waves experiment, the string has a mass of 44.5 g string and length of 1.18 m. The string is connected to a mechanical wave generator that produce standing waves with frequency of f. The other end of the string is connected to a mass holder (mholder = 50.0 g) that carries a weight of 5.00x102 g. Calculate the the frequency of the mechanical wave generator f, if the number of antinodes was 2. (g = 9.80 m/s2)