Years passed and only rarely did I get the chance to wonder at this question – and meantime\u00a0my science education was getting the upper hand – I learned how sounds travel through the air and how the ear works –\u00a0how deep, low notes are the result of compression waves in the air, perhaps a few meters apart, while higher pitched sounds where compression waves much more tightly packed, perhaps millimeters apart. I also learned a note could have any<\/em>\u00a0frequency, and so no reason to pick out any ‘special’ frequencies.<\/p>\n However, \u00a0just recently I realized, in a flash of light, that with an infinite number of notes to choose from, musicians had very deliberately selected only a few to make music with, and I suddenly wanted to know why. Was it arbitrary? Was it the same in different cultures? Why did some notes seem to go together and others seem to clash? And of course, as The Provincial Scientist, I wanted to know if our early musicians had done well in their choices.<\/p>\n As it is now the era of the internet I set about to find out more and thought it was so interesting, it would be a crime not to report what I learned on my blog. So here is what I learned…<\/p>\n In Search of Middle C<\/strong><\/p>\n The best place to start is probably a vibrating string. The vibrating string is clearly key to pianos, harps, guitars and, of course, the entire ‘string’ section of an orchestra. If you stretch a string and pluck it, you are starting an amazing process – as you pull on the string, you create tension, you literally stretch the string and store energy in the fabric of the string. When you let go, the string shrinks under that tension, which pulls it straight. Alas, when its straight it has picked up some speed and the momentum keeps it going until the string is stretched again – thus the string swings back and forth – and it would continue forever were it not for frictional losses – energy is lost in heating the string, but some is also lost in buffeting the air around the string. The air is pushed then pushed again with each cycle creating compression waves that ripple out into the room – and into our ears.\u00a0Thus we hear the string.<\/p>\n You can see the vibrating string doing it’s magic here:<\/p>\n [youtube=http:\/\/www.youtube.com\/watch?NR=1&v=6JeyiM0YNo4]<\/p>\n You can see in the video that the string swinging back and forth is an awful lot like a wave moving up and down the string! Indeed it is!<\/p>\n The speed at which the wave moves (or string vibrates back and forth) – and thus the note we hear – is determined by a few simple factors – the tension in the string, and the weight of the string and the length of the string. The greater the tension, the greater the force trying to straighten the string, but the greater the weight, the more momentum there is to make it stretch out again.<\/p>\n It is therefore easy to get a wide range of notes from a string, start with a long, heavy wire and only tension it enough to remove all the slack. The note can then be gradually increased by decreased the length or the weight of the wire, or by increasing the tension. These are the tricks used in pianos, guitars and so on.<\/p>\n So far so good. But if you have several strings to tune up, what notes should you pick – from infinitely many – to make music with?<\/p>\n The human ear is an amazing device and can hear notes\u00a0ranging\u00a0anywhere from 20 to 20,000 compressions per second (the unit for\u00a0per second<\/em>\u00a0is called\u00a0Hertz or Hz for short). That is a lot of choice!<\/p>\n As I am sure you guessed, the key is to understand why some notes seem to ‘go together’, and the answer lies back in the vibrating string.<\/p>\n Overtones of Overtones<\/strong><\/em><\/p>\n Firstly, it turns out that when you pluck a string, you actually get more than one note. While the string may swing back and forth in one elegant sweep, it may also get shorter waves, with half or a third or quarter the wavelength hiding in there too. This video shows how one spring can vibrate at several speeds:<\/p>\n [youtube=http:\/\/www.youtube.com\/watch?v=3BN5-JSsu_4&feature=related]<\/p>\n Although the video shows the string vibrating at one speed each time, it is actually possible for a string to carry more than one wave at a time (this amazing fact deserves its own blog posting, but we will just accept it for now).<\/p>\n So when a string is plucked, the string ‘finds’ ways to store the energy with vibrations – it finds a few frequencies that carry the energy well, these are called ‘resonant<\/a> frequencies’, there will be several, but they will all be multiples of one low note. As these higher notes are all multiples of a single low ‘parent’ note, they also have consistent frequency relationships between one another, 3\/2, 4\/3, 5\/4 and many many others.<\/p>\n So clearly, once you have one string, and you want to add a second, you could tune the second string to try to match some of the harmonics of the first string. The best match is to pick a string whose fundamental note is at 2x the frequency of the first string. This string’s fundamental note will match the first string’s 2nd harmonic (also called its first overtone<\/em>). The second string’s harmonics will also perfectly match up with pre-existing harmonics from the first string. The strings are what is called consonant<\/em>, they ‘go together’.<\/p>\n Now although the second string will have some frequencies in common with the first string, it turns out that there is an even stronger reason why these notes will go together – it is because when you play several strings at once, you are no longer just playing the strings, the instrument you are playing is the listener’s eardrum<\/em>. The eardrum will vibrate with a pattern that is some complex combination of the wave-forms coming from the two (or more) strings.\u00a0When you add two notes together, it is like adding two waves\u00a0together\u00a0and you get an\u00a0interference<\/em>\u00a0pattern<\/a>\u00a0– the interference may create a nice new sound:<\/p>\n If we add a low note (G1) to a note one octave higher (G2) we get a totally new sound wave.<\/p><\/div>\n<\/div>\n This waveform may not repeat, and is unlikely to be consonant with any other notes you may care to add.<\/p>\n Sometimes, when your second string is fairly close in frequency to the first (say 1.1 x the first string’s frequency) then a second\u00a0phenomenon rears its head, beating<\/a><\/em>. This leads to the creation of entirely new (lower) frequencies that the ear can hear [click here to listen to a sample<\/a>]. The sum now looks like this:<\/p>\n We have seen that once you have selected one note, you have already greatly reduced the ‘infinite’ choice of other notes to use with it – because only some will be consonant. Although the best consonances are at exactly 2x the first frequency, we see that once you have picked two strings, the choice for the third string is more limited. Should you be consonant first the first string or the second? Can you be consonant with both? You can be fairly consonant with both, but only by being 2x and 4x their respective frequencies. If you picked all your strings as multiples of the first string, the ‘gaps’ between the notes would be very big, akin to playing a tune with only every 12th key on a piano. So how can we fill in the gaps?<\/p>\n Well, early thinkers quickly\u00a0realized\u00a0that you can’t actually select a perfect set of notes<\/span> – some combinations will mesh well, others will be just a little bit odd. This\u00a0realization\u00a0was probably a bitter pill for early musician-scientists to swallow.<\/p>\n In the end, they came up with many competing options, each designed \u00a0to maximise the occurrence of good ratios \u00a0– a good example is the just intonation<\/a>\u00a0scale:<\/p>\n![\"\"](\"http:\/\/jarrodhart.files.wordpress.com\/2011\/10\/loudspeaker-waveform.gif\" "\\"Sound")
<\/a><\/p>\n![\"String](\"http:\/\/theprovincialscientist.com\/wp-content\/uploads\/2011\/10\/harmonics-2.png\")
<\/a><\/p>\n![\"\"](\"http:\/\/jarrodhart.files.wordpress.com\/2011\/10\/sum-sine-waves.jpg\" "\\"Summing")
<\/a>![\"\"](\"http:\/\/jarrodhart.files.wordpress.com\/2011\/10\/wave-additions.jpg\" "\\"wave")
<\/a><\/div>\n![\"\"](\"http:\/\/jarrodhart.files.wordpress.com\/2011\/10\/beats.gif\" "\\"Beats\\"")
<\/a>Beating can sound awful, though of course, the skilled musician can actually use it to create useful effects.<\/p>\n
![\"\"](\"http:\/\/jarrodhart.files.wordpress.com\/2011\/10\/522px-majorscales-svg.png\" "\\"Major")
<\/a>