08:45Standing wave harmonics in a tube with one closed end (Organ, Saxophone, Tuba) | Doc PhysicsDoc Schuster580views
04:23Physics - Mechanics: Sound and Sound Waves (40 of 47) Standing Waves in an Air ColumnMichel van Biezen395views
12:07Standing Waves In Organ Pipes - Closed & Open Tubes - Physics ProblemsThe Organic Chemistry Tutor815views
Multiple ChoiceThe fundamental frequency of your closed organ pipe is 200 Hz. The second overtone of this pipe has the same frequency as the 3rd harmonic of an open pipe. What is the length of this open pipe?317views8rank1comments
Textbook QuestionStanding sound waves are produced in a pipe that is 1.20 m long. For the fundamental and first two overtones, determine the locations along the pipe (measured from the left end) of the displacement nodes and the pressure nodes if (b) the pipe is closed at the left end and open at the right end.1444views
Textbook QuestionStanding sound waves are produced in a pipe that is 1.20 m long. For the fundamental and first two overtones, determine the locations along the pipe (measured from the left end) of the displacement nodes and the pressure nodes if (a) the pipe is open at both ends480views
Textbook QuestionThe fundamental frequency of a pipe that is open at both ends is 524 Hz. (c) the frequency of the new fundamental.384views
Textbook QuestionThe fundamental frequency of a pipe that is open at both ends is 524 Hz. If one end is now closed, find (b) the wavelength1430views
Textbook QuestionThe fundamental frequency of a pipe that is open at both ends is 524 Hz. (a) How long is this pipe? If one end is now closed1535views1rank
Textbook Question(II) A meteorite traveling 9400 m/s strikes the ocean. Determine the shock wave angle it produces(b) in the water just after entering. Assume T = 20 °C.115views
Textbook Question(II) A tight guitar string has a frequency of 540 Hz as its third harmonic. What will be its fundamental frequency if it is fingered at a length of only 70% of its original length?119views
Textbook Question(II) A pipe in air at 21.5°C is to be designed to produce two successive harmonics at 308 Hz and 352 Hz. How long must the pipe be, and is it open or closed?114views
Textbook Question(II) A uniform narrow tube 1.50 m long is open at both ends. It resonates at two successive harmonics of frequencies 275 Hz and 330 Hz. What is(a) the fundamental frequency, and129views
Textbook Question(II) An unfingered guitar string is 0.68 m long and is tuned to play E above middle C (330 Hz). (b) What is the wavelength on the string of this 440-Hz wave? 108views
Textbook Question(II) An unfingered guitar string is 0.68 m long and is tuned to play E above middle C (330 Hz). (c) What are the frequency and wavelength of the sound wave produced in air at 22°C by this fingered string?108views
Textbook Question(II) An unfingered guitar string is 0.68 m long and is tuned to play E above middle C (330 Hz). (a) How far from the end of this string must a fret (and your finger, Fig. 16–8) be placed to play A above middle C (440 Hz)? 133views
Textbook Question(II) A uniform narrow tube 1.50 m long is open at both ends. It resonates at two successive harmonics of frequencies 275 Hz and 330 Hz. What is (b) the speed of sound in the gas in the tube?123views
Textbook Question(II) A space probe enters the thin atmosphere of a planet where the speed of sound is only about 55 m/s .(b) What is the angle of the shock wave relative to the direction of motion?126views
Textbook QuestionA particular whistle produces sound by setting up the fundamental standing wave in an air column 8.40 cm long. The tube is closed at one end. The whistle blower is riding in a car moving away from you at 25 m/s. What frequency do you hear?116views
Textbook QuestionThe vibrating portion of an A-string on a particular violin measures 32 cm, and its fundamental frequency is precisely 440 Hz.(a) How far from the end of the string should the violinist place a finger so that the string plays a note at 588 Hz?103views
Textbook QuestionThe vibrating portion of an A-string on a particular violin measures 32 cm, and its fundamental frequency is precisely 440 Hz.(b) “Vibrato” in a violin is produced by sliding the finger back and forth along the vibrating string. If the violinist executes “vibrato” by moving the finger 0.5 cm to either side of the position found in part (a), what range of frequencies will result?118views
Textbook QuestionThe fundamental frequency of an open-open tube is 1500 Hz when the tube is filled with 0°C helium. What is its frequency when filled with 0°C air?467views
Textbook QuestionA bass clarinet can be modeled as a 120-cm-long open-closed tube. A bass clarinet player starts playing in a 20° C room, but soon the air inside the clarinet warms to where the speed of sound is 352 m/s . Does the fundamental frequency increase or decrease? By how much?371views
Textbook QuestionA 170-cm-long open-closed tube has a standing sound wave at 250 Hz on a day when the speed of sound is 340 m/s . How many pressure antinodes are there, and how far is each from the open end of the tube?437views1rank
Textbook QuestionBIO Deep-sea divers often breathe a mixture of helium and oxygen to avoid getting the 'bends' from breathing high-pressure nitrogen. The helium has the side effect of making the divers' voices sound odd. Although your vocal tract can be roughly described as an open-closed tube, the way you hold your mouth and position your lips greatly affects the standing-wave frequencies of the vocal tract. This is what allows different vowels to sound different. The 'ee' sound is made by shaping your vocal tract to have standing-wave frequencies at, normally, 270 Hz and 2300 Hz. What will these frequencies be for a helium-oxygen mixture in which the speed of sound at body temperature is 750 m/s ? The speed of sound in air at body temperature is 350 m/s .643views
Textbook QuestionA 280 Hz sound wave is directed into one end of the trombone slide seen in FIGURE P17.55. A microphone is placed at the other end to record the intensity of sound waves that are transmitted through the tube. The straight sides of the slide are 80 cm in length and 10 cm apart with a semicircular bend at the end. For what slide extensions s will the microphone detect a maximum of sound intensity? 568views
Textbook QuestionA 1.0-m-tall vertical tube is filled with 20°C water. A tuning fork vibrating at 580 Hz is held just over the top of the tube as the water is slowly drained from the bottom. At what water heights, measured from the bottom of the tube, will there be a standing wave in the tube above the water?734views
Textbook QuestionAn old mining tunnel disappears into a hillside. You would like to know how long the tunnel is, but it's too dangerous to go inside. Recalling your recent physics class, you decide to try setting up standing-wave resonances inside the tunnel. Using your subsonic amplifier and loudspeaker, you find resonances at 4.5 Hz and 6.3 Hz, and at no frequencies between these. It's rather chilly inside the tunnel, so you estimate the sound speed to be 335 m/s . Based on your measurements, how far is it to the end of the tunnel?326views
Textbook QuestionA flutist assembles her flute in a room where the speed of sound is 342 m/s . When she plays the note A, it is in perfect tune with a 440 Hz tuning fork. After a few minutes, the air inside her flute has warmed to where the speed of sound is 346 m/s. b. How far does she need to extend the 'tuning joint' of her flute to be in tune with the tuning fork?546views