Need Table F and how you do the calculations
I have no graph to show you but if you will draw a graph you will also get the same results. Thank you
Need Table F and how you do the calculations I. EXPERIMENT 1.10: STANDING WAVES ON STRINGS...
1,2 and 3 I. EXPERIMENT 1.10: STANDING WAVES ON STRINGS A. Abstract Waves on a string under tension and fixed at both ends result in well-defined modes of vibration with a spectrum of frequencies given by the formula below B. Formulas ē In=n (), n = 1,2,3,... v=JI where fn is the frequency of the nth standing wave mode on the string of length L, linear mass density , and under tension T, and v is the wave speed on...
Standing Waves! Questions: I. You have a fundamental standing wave at a frequency f, tension F, linear density μ and length L. What tension would you use to double the frequency? 2. You have a fundamental standing wave at a frequency f, tension F, linear density μ and length L. What length would you use to double the frequency? 3. You have a fundamental standing wave at a frequency f, tension F, linear density μ and length L. What linear...
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 this experiment you will drive the string with an oscillator of fixed frequency. The driving frequency cannot be varied to produce different normal-mode standing-wave patterns. Since v = VFT/μ. wherefis a constant. μ is also constant for a given string. By varying FT, appropriate wavelengths can be selected that will "fit" into a given string length, L, to produce standing waves. Pre-lab Assignment Rewrite equation (1) to obtain a form of an equation of a straight line, y =...
In the standing waves experiment, the string has a mass of 38.3 g string and length of 0.98 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 linear density of the string. I was not given any further information so I assume frequency and wavelength must...
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 done in physics lab, a string of mass density 0.375 ± 0.002 g/m was used. The distance between the (fixed) ends of the string is approximately 1.50 ± 0.02 m. Determine the wavelength of the n = 3 standing waves. If the oscillator frequency is 80.0 ± 0.2 Hz, determine the tension in the string needed for the n = 5 standing waves. answers >>[1.00 ± 0.01 m, 0.864 ± 0.032 N]
Question 4 to 11 plz Dr? Standing Waves on a String Physics Topics If necessary, review the following topics and relevant textbook sections from Serway / Jewett "Physics for Scientists and Engineers", 9th Ed. • Mathematics of Traveling Waves (Serway 17.2) • Speed of Waves on a String (Serway 17.3) • Superposition of Waves (Serway 18.1) • Standing Waves on a string (Serway 18.2, 18.3) Introduction Imagine two sinusoidal traveling waves with equal amplitudes and frequencies moving in opposite directions....
YOU MUST USE THE EXPERIMENTAL VALUES SHOWN IN THE PICTURES BELOW!! Physics Lab Experiment: Standing Wave (1) By using the experimental values, explain the change of the resonance frequency due to the number of anti-nodes? (2) By using the experimental values, explain the change of the resonance frequency due to the length of the string? (3) By using the experimental values, explain the change of the resonance frequency due to the tension? (4) By using the experimental values, explain the...
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)