It's not the sound intensity I (acoustic intensity) as sound power quantity, it's the sound pressure p as sound field quantity, which moves you ear drums. I ~ p²
Light intensity
Distance affects intensity by following the inverse square law, which states that as distance from a source increases, the intensity of the source decreases by the square of the distance. This means that the further you are from a source of intensity, the weaker the intensity will be.
Competitive Intensity
The power of a sound wave directly affects its intensity and amplitude. Higher power results in greater intensity and larger amplitude of the sound wave.
Light intensity affects voltage because the higher the intensity of light, the more volts are produced. It works exactly the same way in the case of: the lower the light intensity the less volts that are produced.
Temperature affects the rate. Because of it is using enzymes.
This is without importance.
Amplitude of light waves directly affects the intensity of light. As the amplitude increases, more energy is carried by the light wave, resulting in higher intensity. Conversely, a decrease in amplitude leads to lower light intensity.
by the bubbles that are produces the closer the faster the bubles move
It is less loud. Frequency affects what we hear as pitch. Amplitude affects volume.
No, the pitch of sound is determined by the frequency of the vibration, not the amplitude. Amplitude affects the loudness or intensity of sound, while frequency affects the pitch.
Sound intensity or acoustic intensity (I) is defined as the sound power Pac per unit area A. The usual context is the noise measurement of sound intensity in the air at a listener's location as a sound energy quantity. Our eardrums and microphone diaphragms are moved by sound pressure deviations (p), which is a sound field quantity. So we measure the sound with a SPL meter (Sound Pressure Level).