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

Two pipes are each open at one end and closed at the other. Pipe A has...

Two pipes are each open at one end and closed at the other. Pipe A has length L and pipe B has length 2L. Which harmonic of pipe B matches in frequency the fundamental of pipe A? The answer is E, could anyone explain it? A) The fundamental B) The second C) The third D) The fourth E) There are none

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...

The fundamental frequency of an organ pipe, closed at one end, is 255.6 Hz. a)What is...

The fundamental frequency of an organ pipe, closed at one end, is 255.6 Hz. a)What is the fundamental frequency of this organ pipe if the temperature drops to 1.20°C? (Hz) The fundamental frequency of an organ pipe, open at both ends, is 278.9 Hz. b) What is the fundamental frequency of this organ pipe if the temperature drops to 1.00°C?

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

Draw diagrams showing the first harmonic or fundamental, the second harmonic and the third harmonic of standing waves in the following: i). A vibrating string fastened at both ends. ii).A pipe closed at one end. iii). A pipe opened at both end

Consider a pipe with a length of 37.5 cm. If the temperature of the air is...

Consider a pipe with a length of 37.5 cm. If the temperature of the air is 14.5 °C and the pipe is closed at one end and open in the other, what is the frequency of the third harmonic (also called the 2nd overtone) for the pipe? Post your answer in hertz (Hz) and with 3 significant figures.

Consider a pipe with a length of (A+32.5) cm. If the temperature of the air is...

Consider a pipe with a length of (A+32.5) cm. If the temperature of the air is (12.5+B) °C and the pipe is closed at one end and open in the other, what is the frequency of the third harmonic (also called the second overtone) for the pipe? Post your answer in hertz (Hz) and with 3 significant figures. A = 13 B = 7

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...

(a) Calculate the 5th lowest frequency possible for an organ pipe that is open at one...

(a) Calculate the 5th lowest frequency possible for an organ pipe that is open at one end and closed at the other and has a length of 1.62 m. (b) List the n value (which harmonic this is).

d) An open-ended pipe contains a plunger so that the length of the closed-open pipe can...

d) An open-ended pipe contains a plunger so that the length of the closed-open pipe can be varied. The sound wave has frequency 2.1 kHz. (i) As the pipe length is increased from zero, what are the first 3 lengths that produce a standing wave? (ii) Draw the standing wave patterns in each case. (iii) The speed of sound varies increases with √? where T is the temperature of the air in Kelvin. Consider two identical pipes resonating at their...