There are many different sound measuring systems available however, basically each system consists of a microphone, a processing unit and a display unit. The sound level meter is an instrument designed to give objective, reproducible measurements of sound pressure level. The use of a logarithmic scale is actually very useful because the ear reacts to a logarithmic change in level, which corresponds to the decibel scale where 1dB is the same relative change everywhere on the scale. The decibel is not an absolute unit of measurement it is a logarithmic ratio between a measured quantity and an agreed reference level.
![decibel scale logarithmic decibel scale logarithmic](http://www.phon.ox.ac.uk/jcoleman/SPL.jpg)
To overcome this problem we use the decibel (dB). Although the sound is actually a variation in pressure that the ear can detect it is simply too messy to measure the sound in terms of pressure because the ear can actually respond to a huge range of pressure variations and the numbers involved would become too unwieldy. The sound level meter displays what is known as a sound pressure level. Noise is measured using an instrument that is known as a sound level meter. For the ear to detect pressure variations as sounds the variations must occur 20 times per second. Sound is any variation in atmospheric pressure that can be detected by the ear. They are a clever and useful tool for making sense of the world of acoustics.Noise is unwanted sound. Decibels are not as confusing as they might appear at first glance. If it helps, think of decibels like a presentation tool, not as measured values. You have to return to absolute units to do math on a decibel quantity. This is true even for decibel values with identical references. All relative units, including the decibel, must be taken back to absolute units to be added or subtracted. Decibels cannot be directly added or subtracted. There is, however, one major pitfall to watch out for when working in decibels. The decibel also allows quantities-like sound pressure levels-to be graphed and analyzed more easily.
![decibel scale logarithmic decibel scale logarithmic](https://i.ytimg.com/vi/dSTMhvQO0sI/maxresdefault.jpg)
Also, it turns out that human hearing is generally logarithmic in nature, so decibels match well with human perception and experience. From a practical standpoint, the full range of pressures from just perceptible to the threshold of pain for human hearing can be represented with values from 0 to 140, which is much better than trying to compare 0.00002 to 200 Pa.
![decibel scale logarithmic decibel scale logarithmic](https://thumbs.dreamstime.com/z/decibel-scale-sound-level-102089548.jpg)
This fully developed decibel scale offers several distinct benefits over absolute measurements. If you are using power quantities, the expression is slightly different: Note that this expression is for root-power quantities. They then added a multiplicative scaling factor to the front of the logarithm to fine tune the range of the decibel, and the full mathematical expression for the decibel was born: The scientists at Bell Laboratories took the logarithm of the ratio of the measured value to the reference value inside the parentheses to make the relative values more manageable. In mathematical notation, this process looks like this: For example, if you want to represent 100 with a logarithm and your base is 10, you need to raise 10 to a power of 2 (or multiply 10 two times: 10 x 10) to reach 100. To remedy this problem, the people at the Bell System (the ones who invented the decibel) back in 1923 used a mathematical operation called a logarithm to compress the ratio into more reasonable numbers.Ī logarithm gives you the exponent you need to reach a certain number by repeatedly multiplying a base number by itself. (People like to read numbers in the 1 to 100 range because they are most commonly used.) More importantly, how do you know what a given sound pressure level sounds like to the human ear? Is it quiet or loud? And how can you represent such a large range of values on a graph? It would be quite difficult. That range of numbers is simply too large to be useful. The first is that quantities like sound pressure levels can span a large range-pressure levels might be anywhere from 0.00002 to 200 pascals. That would be a good idea, except for a couple of issues. So, why bother with more math in the first place? Shouldn’t it be enough to measure the ratio with respect to the reference? There is, of course, a bit more to decibels than dividing one number by another, but don’t worry-the math isn’t too bad.
![decibel scale logarithmic decibel scale logarithmic](https://i.ytimg.com/vi/SYu5YIYLDPE/hqdefault.jpg)
This means that decibels are always expressed as a ratio of a measured value to a known reference value. In the previous post, we learned that the decibels belongs to a group of units called a relative units.