The middle C string on a piano is under a tension of 574 N. The period...
The middle C string on a piano is under a tension of 953 N. The
period and wavelength of a wave on this string are 3.82 ms and 1.21
m, respectively. Find the linear density of the string.
Chapter 16, Problem 013 Your answer is partially correct. Try again. The middle C string on a piano is under a tension of 953 N. The period and wavelength of a wave on this string are 3.82 ms and 1.21 m, respectively....
The middle C string on a piano is under a tension of 990 N. The period and wavelength of a wave on this string are 3.82 ms and 1.22 m, respectively. Find the linear density of the string.
The middle C string on a piano is under a tension of 944N. The period and wavelength of a wave on this string are 3.82 ms and 1.26 m, respectively. Find the linear density of the string.
A 2.00-m long piano string of mass 10.0 g is under a tension of 320 N. Find the speed of a wave on this string. 253 m/s 358 m/s 506 m/s 80.0 m/s 126 m/s D View hint for Question 4
A piano string is under a tension of T = 989 N. When struck the wave has a period of t = 0.75 ms and a wavelength of λ = 0.84 m. Part (a) What is the linear density of the string, in kilograms per meter? Part (b) If the piano's soundboard is L= 1.0 m long, how much does the string weigh, in newtons?
A piano string having a mass per unit length equal to 5.00 X 10-3 kg/m is under a tension of 1 350 N. Find he speed with which a wave travels on this string.
A sinusoidal wave is travelling on a string under tension T = 8.0(N), having a mass per unit length of 1 = 0.0128(kg/m). It’s displacement function is D(x,t) = Acos(kx - t). It’samplitude is 0.001m and its wavelength is 0.8m. It reaches the end of this string, and continues on to a string with 2 = 0.0512(kg/m) and the same tension as the first string. Give the values of A, k, and , for the original wave, as well as...
A nylon guitar string has a linear density of 4.46 g/m and is under a tension of 126 N. The fixed supports are D = 72.7 cm apart. The string is oscillating in the standing wave pattern shown in the figure. Calculate the (a) speed, (b) wavelength, and (c) frequency of the traveling waves whose superposition gives this standing wave.
A string of mass 100g and length 2m is under a tension of 200 N. Find its (a) wave velocity, (b) fundamental frequency, (c) 3rd harmonic frequency, and (d) 5th overtone wavelength.
A string of mass 100 g and length 2 m is under a tension of 200 N. Find its (a) wave velocity, (b) fundamental frequency, (c) 3rd harmonic frequency, and (d) 5th overtone wavelength.