Draw diagrams showing the first harmonic or fundamental, the second harmonic and the third harmonic of...

7). An organ pipe, closed at one end, is vibrating in its first overtone (second harmonic),...

7). An organ pipe, closed at one end, is vibrating in its first overtone (second harmonic), has length 61cm. A second organ pipe, open at both ends, is vibrating in its fundamental mode (first harmonic), has length 41cm. What are the frequencies of the tones from each?

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...

An organ pipe open at both ends is to be designed so that the fundamental frequency...

An organ pipe open at both ends is to be designed so that the fundamental frequency it plays is 220 Hz. a. What length of pipe is needed? b. If one end of the pipe is stopped up, what other note (frequency) can this same pipe play? c. Draw the fundamental frequency for the pipe open at both ends and when it is closed at one end. d. Calculate and draw the next higher harmonic when one end of the...

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?

A string with both ends held fixed is vibrating in its third harmonic. The waves have...

A string with both ends held fixed is vibrating in its third harmonic. The waves have a speed of 193 m/s and a frequency of 235 Hz. The amplitude of the standing wave at an antinode is 0.380 cm. a)Calculate the amplitude at point on the string a distance of 16.0 cm from the left-hand end of the string. b)How much time does it take the string to go from its largest upward displacement to its largest downward displacement at...

Find the fundamental frequency and the frequency of the first three overtones of a pipe 90.0...

Find the fundamental frequency and the frequency of the first three overtones of a pipe 90.0 cm long, if the pipe is open at both ends. Please enter your answer as four numbers, separated with commas. ffund,fov1,fov2,fov3 =   Hz   Find the fundamental frequency and the frequency of the first three overtones of a pipe 90.0 cm long, if the pipe is closed at one end. Please enter your answer as four numbers, separated with commas. ffund,fov1,fov2,fov3 = Hz If the...

The second harmonic standing wave on a particular string fixed at both ends is given by:...

The second harmonic standing wave on a particular string fixed at both ends is given by: y(x, t) = 0.01 sin(2π x) cos(200π t) (in SI units). a) Fill in the following information: λ2 = f2 = v = b) How long is the string, and what is its fundamental frequency? L =   f1 = c) This second harmonic wave has total energy E2. If the string is plucked so that has the first harmonic wave on it instead at...

A pipe of fixed length is closed at one end. What is (third harmonic frequency of...

A pipe of fixed length is closed at one end. What is (third harmonic frequency of pipe) / (first harmonic frequency of pipe)?

An organ pipe is 1.2 m long. What are the fundamental and first two overtones is...

An organ pipe is 1.2 m long. What are the fundamental and first two overtones is the pipe is (a) closed at one end. (b) open at both ends?

Pipe A, which is 1.20 m long and open at both ends, oscillates at its third...

Pipe A, which is 1.20 m long and open at both ends, oscillates at its third lowest harmonic frequency. It is filled with air for which the speed of sound is 343 m/s. Pipe B, which is closed at one end, oscillates at its second lowest harmonic frequency. This frequency of B happens to match the frequency of A. An x axis extends along the interior of B, with x = 0 at the closed end. (a) How many nodes...