Solve Wave Problems: Calculating Length for Higher Note on Slide Whistle

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In summary, to play a note one octave higher on a slide whistle with a length of 27 cm, the whistle should be 13.5 cm long. This is because the frequency of the note needs to be doubled, and the frequency is inversely proportional to the length of the whistle.
  • #1
manda
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Homework Statement


A slide whistle has a length of 27 cm. If you want to play a note one octave higher, the whistle should be how long?

Homework Equations



velocity=(wavelength)*(frequency)
speed of sound= 343 m/s

The Attempt at a Solution



343=6.75f
50.8=f

50.8*2= 101.63Hz

( i am so lost)
 
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  • #2
Q#1: What happens to the frequency when something goes one octave higher?
Q#2: What happens to the wavelength when {insert answer to Q#1 here} happens to the frequency?
 
  • #3
it doubles?
 
  • #4
Yes. What happens to the wavelength when the frequency doubles?
 
  • #5
it halves?

so is the answer 101.63? or 27/2?
 
  • #6
manda said:

Homework Statement



A slide whistle has a length of 27 cm. If you want to play a note one octave higher, the whistle should be how long?

Homework Equations



velocity=(wavelength)*(frequency)
speed of sound= 343 m/s

The Attempt at a Solution



343=6.75f
50.8=f

50.8*2= 101.63Hz

( i am so lost)


Hi Manda, I saw you cry for help. I'll give it a shot.

An octave is the interval between one musical pitch and another with half or double its frequency. For example, if one note has a frequency of 400 Hz, the note an octave above it is at 800 Hz, and the note an octave below is at 200 Hz.

Further octaves of a note occur at 2^n times the frequency of that note (where n is an integer), such as 2, 4, 8, 16, etc. and the reciprocal (1/2^n) of that series. For example, 50 Hz and 400 Hz are one and two octaves away from 100 Hz because they are ½ (or 2^−1) and 4 (or 2^2) times the frequency, respectively.

So first calculate the lowest frequency of the note in the whistle, using your relevant equations, as well as the length of the whistle. Then double that frequency to get the octave one higher. Let me know if I should clarify. ~M
 
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  • #7
Yes. One of those two is correct; which is referring to a length? (Since the question is asking for a length).

p.s. It might also help to find the equation involving whistle (or tube) length. Is there a discussion on tubes in your book, in the chapter dealing with sound or waves?
 
  • #8
27/2

umm yeah there is 2 paragraphs
all they say is open = Y/2
closed=y/4 and then y/2


does that sound right?
 
  • #9
Yes, that's right. In all those cases, the tube length is proportional to the wavelength.
So when the wavelength halves, the tube length _____ ?
 

1. What are waves and how do they work?

Waves are disturbances that travel through a medium, such as air or water. They transfer energy from one point to another without actually moving any matter. The particles in the medium vibrate or oscillate as the wave passes through, but they return to their original position once the wave has passed. This allows the wave to continue moving while the particles stay in place.

2. What is the difference between transverse and longitudinal waves?

Transverse waves are waves in which the particles in the medium vibrate perpendicular to the direction of the wave's motion. Examples of transverse waves include light waves, water waves, and electromagnetic waves. In contrast, longitudinal waves are waves in which the particles in the medium vibrate parallel to the direction of the wave's motion. Sound waves are an example of longitudinal waves.

3. How does wavelength relate to the frequency of a wave?

Wavelength and frequency are inversely proportional to each other. This means that as the wavelength increases, the frequency decreases and vice versa. This relationship is described by the wave equation, which states that wavelength equals the speed of the wave divided by the frequency.

4. Can you explain the concept of wave interference?

Wave interference occurs when two or more waves meet in the same medium. Depending on how the waves align, they can either amplify or cancel each other out. When waves are in phase (crest meets crest or trough meets trough), they produce constructive interference and create a larger wave. When waves are out of phase (crest meets trough), they produce destructive interference and cancel each other out. This phenomenon can be observed in everyday life, such as when two ripples in a pond meet and either create a bigger ripple or cancel each other out.

5. How do you calculate the speed of a wave?

The speed of a wave can be calculated by multiplying its frequency (in hertz) by its wavelength (in meters). This is represented by the equation v = f * λ. The speed of a wave is also affected by the properties of the medium through which it travels, such as temperature, density, and elasticity.

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