The speed of sound in air changes clearly with temperature, a little bit with humidity − but not with air pressure (atmospheric pressure).
The speed of sound c = 331.3 + 0.606 × ϑ m/s.
At the temperature ϑ = 20°C the speed of sound is c ≈ 331 + (0.6 × 20) = 343 m/s.
Air pressure can affect a sound wave by changing the speed at which the wave travels. Higher air pressure leads to faster sound wave propagation due to increased molecular collisions, while lower air pressure can slow down sound waves. This can alter the pitch or tone of the sound.
A sound wave of high pressure is called a compression or a peak in the wave's amplitude. These high-pressure regions correspond to the portions of the wave where air particles are densely packed together.
Your ears and the sound pressure level meter like more the sound pressure of a sound wave.Note: Sound power (sound intensity) is the cause -and the sound pressure is the effect.The effect is of particular interest to the sound engineer.
The amount of energy in a sound wave is related to its amplitude, which is the height of the wave from its baseline. The larger the amplitude, the more energy the sound wave carries.
The higher pressure part of a sound wave is called the compression phase. It represents the regions of increased air pressure created by the vibration of a sound source.
Air pressure can affect a sound wave by changing the speed at which the wave travels. Higher air pressure leads to faster sound wave propagation due to increased molecular collisions, while lower air pressure can slow down sound waves. This can alter the pitch or tone of the sound.
No. A sound wave is a pressure wave.
A sound wave of high pressure is called a compression or a peak in the wave's amplitude. These high-pressure regions correspond to the portions of the wave where air particles are densely packed together.
Your ears and the sound pressure level meter like more the sound pressure of a sound wave.Note: Sound power (sound intensity) is the cause -and the sound pressure is the effect.The effect is of particular interest to the sound engineer.
The amount of energy in a sound wave is related to its amplitude, which is the height of the wave from its baseline. The larger the amplitude, the more energy the sound wave carries.
The higher pressure part of a sound wave is called the compression phase. It represents the regions of increased air pressure created by the vibration of a sound source.
Well, I take it you mean a wave in the air, like a sound wave (alternating compressions of air). Volume of a sound wave ( a type of compressional wave) is our perception of its amplitude, the amplitude is a measure in the intensity of the waves, or the amount of variation in air pressure. Our perception of pitch varies with the frequency, or how frequently the alternations in air pressure persist.
I don't understand your questions. I know that our ear drums and the microphone diaphragms are moved directly by the sound pressure p, that is a sound field quantity. Forget the sound energy quantities when you talk about ears.
A region of high pressure in a sound wave is called compression. This is the part where air particles are pushed closer together, resulting in higher pressure.
Sound waves are pressure waves.
The areas of higher pressure in a sound wave are called compressions. These regions correspond to the parts of the wave where air molecules are closer together, creating areas of increased pressure.
the amplitude of a sound wave is the air around you's temperature and the time of sound timed together. +++ No - the amplitude of any wave is its "height", which in sound is the wave's pressure. Time and temperature are not involved in amplitude.