12,820 Hz Wavelength

How Long Is a 12820 Hz Wavelength?

A 12820 Hz sound wave has a wavelength of 0.03 meters, 2.68 cm, 0.09 feet (0 feet and 1.05 inches) or 1.05 inches when traveling in air at 20°C (68°F).

The formula for the wavelenght is λ = c/f where:

  • c is the celerity (speed) of sound = 343.21 m/s or 1126.03 ft/s in air at 20°C (68°F).
  • f is the frequency = 12820 Hz
which gives a wavelength λ of 0.03 meters, or 0.09 feet.

12820 Hz Wavelength Depending on Temperature

The speed of sound in air depends on temperature. Here is how the wavelenght of a 12820 Hz sound wave will vary according to temperature:

Temp (°C) Temp (°F) 12820 Hz wavelength (cm)12820 Hz wavelength (in)
-40-402.38750.9400
-35-312.41300.9500
-30-222.43820.9599
-25-132.46310.9697
-20-42.48780.9795
-1552.51230.9891
-10142.53650.9986
-5232.56051.0081
0322.58421.0174
5412.60781.0267
10502.63111.0359
15592.65431.0450
20682.67721.0540
25772.69991.0630
30862.72251.0718
35952.74481.0806
401042.76701.0894

12820 Hz Half Wavelength and Standing Waves

The half wavelength of a 12820 Hz sound wave is 0.01 meters, 1.34 cm, 0.04 feet (0 feet and 0.53 inches) or 0.53 inches when travelling in air at 20°C (68°F).

Modes (or standing waves) will occur at 12820 Hz in rooms where two opposing walls (axial mode), edges (tangential mode) or corners (oblique mode) are spaced by a distance d = nλ/2 where:

  • n is a natural (positive integer greater than or equal to 1)
  • λ is the 12820 Hz wavelength = 0.03 meters, or 0.09 feet in air at 20°C (68°F).

12820 Hz Standing Waves Distances

n Distance (m) Distance (ft)
10.010.04
20.030.09
30.040.13
40.050.18
50.070.22

We typically don't treat rooms for standing waves above 300 Hz.

Given the relatively small 12820 Hz half wavelength, you can treat your room by using thick acoustic foam. This will absorb frequencies as low as 250 Hz, and all the way up to 20,000 Hz.

How To Convert 12820 Hz To ms

A Hz (Hertz) is a cycle (or period) per second.

Because a 12820 Hz wave will ocillate 12820 times per second, we can find the time of a single cycle (or period) with the formula p = 1/f where:

  • f is the frequency of the wave = 12820 Hz

The result will be expressed in seconds, so let's multiply by 1000 to get miliseconds:

1 / 12820 Hz * 1000 = 0.08 ms.