6) (a) Draw a diagram to represent the standing wave patterns for the first five harmonics...

7) (a) Draw a diagram to represent the standing wave patterns for the first three harmonics...

7) (a) Draw a diagram to represent the standing wave patterns for the first three harmonics of a pipe with one open end. (i) How many nodes and antinodes are there for each harmonic? (ii) What are the relations for the length of the rope L, the wavelength λ, and the frequency f of the standing waves?

The standing wave properties of an ear canal are often modelled as a tube with one...

The standing wave properties of an ear canal are often modelled as a tube with one end open and one end closed. This is shown in the following diagram for a tube of length L = 2.1 cm. The fundamental mode for the sound-pressure standing wave is indicated.The standing wave properties of an ear canal are often modelled as a tube with one end open and one end closed. This is shown in the following diagram for a tube of...

Please Ensure that part e) is completed The standing wave properties of an ear canal are...

Please Ensure that part e) is completed The standing wave properties of an ear canal are often modelled as a tube with one end open and one end closed. This is shown in the following diagram for a tube of length L = 2.1 cm. The fundamental mode for the sound-pressure standing wave is indicated.The standing wave properties of an ear canal are often modelled as a tube with one end open and one end closed. This is shown in...

Four standing waves, labeled A through D, are described below: Wave A: first harmonic; pipe closed...

Four standing waves, labeled A through D, are described below: Wave A: first harmonic; pipe closed at one end; length = 1 m Wave B: first harmonic; pipe open at both ends; length = 1 m Wave C: second harmonic; pipe open at both ends; length = 3 m Wave D: second harmonic; pipe closed at one end; length = 3 m Rank the standing waves in order of decreasing frequency. Rank from greatest to smallest. To rank items as...

a) What are nodes and antinodes for a standing wave? b) How is the distance between...

a) What are nodes and antinodes for a standing wave? b) How is the distance between nodes related to the wavelength of a standing wave? c) How do standing waves look for a string? d) A pipe that is open at both ends? e) A pipe that is closed at one end and open at the other? please type your responses.

A standing wave is set up in a L=2.00m long string fixed at both ends. The...

A standing wave is set up in a L=2.00m long string fixed at both ends. The string vibrates in its 5th harmonic when driven by a frequency f=120Hz source. The mass of the string is m=3.5grams. Recall that 1kg = 1000grams. A. Find the linear mass density of the string B. What is the wavelength of the standing wave C. What is the wave speed D. What is the tension in the string E. what is the first harmonic frequency...

1a. Derive a formula for the wavelength of a standing wave on a fixed string at...

1a. Derive a formula for the wavelength of a standing wave on a fixed string at both ends in terms of the number of antinodes, n, and the length of the string. 1b. For an aluminum rod, when a wave is set up in the rod, do you expect the ends of the rod to allow vibrations or not? Are they considered open or closed for displacement? 1c. Draw schematic pictures of the two longest wavelengths that could fit on...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at successive (that is, modes m and m + 1) frequencies of 38 Hz and 42 Hz respectively. The tension in the string is 720 N. What is the fundamental frequency of the standing wave? Hint: recall that every harmonic frequency of a standing wave is a multiple of the fundamental frequency. What is the speed of the wave in the string? What is the...

A standing wave on a string fixed at both ends is described by y(x,t)=2 sin((π/3)x)cos((π/3)t), where...

A standing wave on a string fixed at both ends is described by y(x,t)=2 sin((π/3)x)cos((π/3)t), where x and y are given in cm and time t is given in s. Answer the following questions a) Find the two simplest travelling waves which form the above standing wave b) Find the amplitude, wave number, frequency, period and speed of each wave(Include unit in the answer) c) When the length of the string is 12 cm, calculate the distance between the nodes...

(1A) A vertical spring with a spring constant of 8 N/m and damping constant of 0.05...

(1A) A vertical spring with a spring constant of 8 N/m and damping constant of 0.05 kg/s has a 2 kg mass suspended from it. A harmonic driving force given by F = 2 cos(1.5 t ) is applied to the mass. What is the natural angular frequency of oscillation of the mass? What is the amplitude of the oscillations at steady state? Does this amplitude decrease with time due to the damping? Why or why not? (1B) Two traveling...