A 2.00 m long string has a mass of (A+1.50) g. A (B+25.0) g mass is...

A 2.00 m long string has a mass of (A + 1.50) g. A (B +...

A 2.00 m long string has a mass of (A + 1.50) g. A (B + 25.0) g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of (125 + C) Hz. Find the wavelength for the wave generated. Give your answer in centimeters (cm) and with 3 significant figures. A = 13 B = 427 C = 7

A 2.00 m long string has a mass of (9.50) g. A (726.0) g mass is...

A 2.00 m long string has a mass of (9.50) g. A (726.0) g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of (126) Hz. Find the wavelength for the wave generated. Give your answer in centimeters (cm) and with 2 significant figures.

A = 18, B = 693, C = 3. The speed of a wave in a...

A = 18, B = 693, C = 3. The speed of a wave in a string is given by v = sqrt(FT/μ), where FT is the tension in the string and μ = mass/length of the string. A 2.00 m long string has a mass of (A+1.50) g. A (B+25.0) g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at...

Let A be the sum of the last three digits, let B be the last three...

Let A be the sum of the last three digits, let B be the last three digits, and let C be the last digit of your 8-digit student ID. Example: for 20245347, A = 14, B = 347, and C=7. The speed of a wave in a string is given by v = √(FT /μ), where FT is the tension in the string and μ = mass / length of the string. A 2.00 m long string has a mass...

The speed of a wave in a string is given by v = sqrt(FT/μ), where FT...

The speed of a wave in a string is given by v = sqrt(FT/μ), where FT is the tension in the string and μ = mass/length of the string. A 2.00 m long string has a mass of 16.5 g. A 769 g mass is attached to the string and hung over a pulley . The end of the string is then vibrated at a frequency of 129 Hz. Find the wavelength for the wave generated. Give your answer in...

A long string of mass per unit length of 0.65 g/m is attached at the point...

A long string of mass per unit length of 0.65 g/m is attached at the point x = 0 to another long string of mass per unit length of 0.52 g/m. The strings are stretched out under a constant tension T = 81 N. A wave of amplitude 1.8 cm and wavelength 11 cm is generated in the lighter string. 1 (a) What is the speed of the wave in the lighter string? (b) What are the speed and wavelength...

A stretched string is 1.91 m long and has a mass of 20.9 g. When the...

A stretched string is 1.91 m long and has a mass of 20.9 g. When the string oscillates at 440 Hz , which is the frequency of the standard A pitch, transverse waves with a wavelength of 16.7 cm travel along the string. Calculate the tension ? in the string.

A standing wave pattern is created on a string with mass density μ = 3 ×...

A standing wave pattern is created on a string with mass density μ = 3 × 10-4 kg/m. A wave generator with frequency f = 63 Hz is attached to one end of the string and the other end goes over a pulley and is connected to a mass (ignore the weight of the string between the pulley and mass). The distance between the generator and pulley is L = 0.68 m. Initially the 3rd harmonic wave pattern is formed....

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 4.70-m-long string that is fixed at one end and attached to a long string of...

A 4.70-m-long string that is fixed at one end and attached to a long string of negligible mass at the other end is vibrating in its fifth harmonic, which has a frequency of 428 Hz. The amplitude of the motion at each antinode is 2.82 cm. (a) What is the wavelength of this wave? ?5 =  m (b) What is the wave number? k5 =  m?1 (c) What is the angular frequency? ?5 =  s?1 (d) Write the wave function for this standing...