Re: [Harp-L] Evolution of Temperaments

["Vern Smith" <jevern@xxxxxxx>]

Thank you, Iceman, for that clear, articulate explanation of 
the need for equal temperament and how it arose.

Now, for the mathematically inclined, (if any), here are 
some formulas that will relate frequency to haltone notes 
and cents.  They will work in Xcel, Basic, or on any 
scientific pocket calculator.

Definitions:
N = musical interval in number of halftones, a + or - 
number
C = musical interval in number of cents, a + or - number
Fo = known starting frequency/pitch in Hertz (cycles per 
second)
f = unknown frequency/ pitch in Hz at the other end of an 
interval.
^ indicates exponentiation
* indicates multiply
/ indicates divide
+ and - indicate add and subtract
log indicates the base-ten logarithm

To find the frequency (f) at the end of any interval as a 
function of the starting frequency Fo and N halftones.
f = Fo * 2 ^ ( N/12)
Note that when N =12 halftones, then N/12 =1 and f = Fo * 2, 
an octave.

If you assign Fo the value of 440 Hz, then f is the 
frequency of any musical note where N is the number of 
halftones counting from the note A4, (A above middle-C)
Example: N = 12 at A5, 14 at B5, etc.

To find the number of halftones N in an interval from Fo to 
f:
N = 12 / log(2) * ( log(f) - log(Fo) )

A cent is perceived by the ear as 1/100th of a halftone. 
Small deviations from musical notes in discussions of tuning 
are usually quantified in cents.

To find the frequency at the end any interval as a function 
of the starting frequency Fo and the mumber of cents:
f = Fo * 2 ^ ( C / 1200)

Example: 24 cents of pitch deviation has been mentioned in 
Iceman's email.
f = 440 * 2 ^ (24 / 1200)  =  478.16 Hz. or 38.16 Hz out of 
tune.
At an octave up Fo = 880, then f = 956.32 Hz or 76.32 Hz out 
of tune.

To find the number of cents C in the interval Fo to f:
C = 1200 / log(2) * ( log(f) - log(Fo) )

Now that's probably a lot more than anyone wanted to know 
about equal temperament.  That is what the "DELETE" key is 
for.   ;o)

Vern


----- Original Message ----- 
From: <icemanle@xxxxxxx>
To: <harp-l@xxxxxxxxxx>
Sent: Friday, October 30, 2009 6:38 AM
Subject: [Harp-L] Evolution of Temperaments

In lab tests, the human hear doesn't hear a difference until 
3 cents or
more. The test consisted of playing two tones - one after 
the other. It
was only at 3 cents and beyond that a difference was noticed 
by the
test subjects.



In nature, pure intervals are what you would naturally sing, 
or what a
violin player uses, when unaccompanied. It's kinda the 
natural order of
things. When keyboard instruments entered the picture and 
composers
wanted the freedom to modulate into any key they chose in 
their
compositions, Nature ran smack dab into Human Desire and 
something had
to give.


Having been a piano tech/tuner for over 30 years, and also 
having had an avid interest in acoustic science during my 
formative years, I've been fascinated by this subject. As a 
piano tech, tuning temperaments are part of what you learn - 
the history, evolution and differences between them..

INTERVALS 101

A perfect (pure) 5th, can also be considered an inverted 
perfect (pure) 4th. Middle "C" up to "G" is a perfect 5th. 
Take that "G" and move it down an octave. Middle "C" to this 
new "G" is now a perfect 4th. When you take a perfect 5th, 
created by going from a reference note UP, and invert it, it 
becomes a perfect 4th going down.

TEMPERAMENT 101

You are given one octave of notes to play with - visually 
imagine a keyboard and ignore any thought of temperaments - 
middle C and an octave up - all 12 chromatic notes. Here is 
how you get to each note one at a time using the interval of 
a perfect 5th. It's just like the Circle of 5ths. Start on 
middle "C". Move up a perfect 5th to "G". Instead of moving 
up another perfect 5th to "D", which would put you OUTSIDE 
of the one octave you are given to use, move DOWN a perfect 
4th, inverting that perfect 5th. Now you've arrived at a "D" 
which is within your one octave. Go up another perfect 5th 
to "A". Instead of going up ANOTHER perfect 5th (which would 
once again take you out of your one octave), invert your 
interval and go down a perfect 4th to "E".

Can you see a pattern developing? Go up a perfect 5th, down 
a perfect 4th, up a perfect 5th, down a perfect 4th, up a 
perfect 5th, down a perf......uh, I think you get it by now.

In this way, you will "create" all 12 notes of the chromatic 
scale without duplication until you finally arrive at your 
starting point, "C", which will be up one octave from where 
you began, but still within the one octave you get to play 
with.

NOW, if you transpose this "C" down an octave and compare it 
with the"C" you started with, the last "C" will be 24 cents 
SHARPER than the first one.

This is Nature at work in her mysterious ways. Using perfect 
(pure) intervals seems to add 24 cents to the octave. With 
the advent of keyboard instruments, this discrepancy just 
wouldn't do.

Oh my, what to do, what to do. Somehow 24 cents had to be 
subtracted from all these intervals so that your ending note 
would be the same as your starting one. It's these pesky 
extra 24 cents that created all the complications. One 
solution was to divide these 24 cents by two and subtract 12 
cents from two of those perfect 5ths. This resulted in a 
really sweet sounding keyboard tuning with chords ringing 
richly UNTIL you got to those two intervals that were 
squeezed by 12 cents each. When these notes were used in 
chords or in the melody, it sounded horrible. One solution 
was to make sure compositions just didn't go there. This 
worked for a minute, but not for very long. Other solutions 
had to be explored.

This excess 24 cents was sliced and diced up many different 
ways and subracted from many different intervals. All 
solutions had advantages and disadvantages. What was finally 
agreed upon as a standard was to treat all notes equally by 
dividing the 24 cents by 12, coming up with 2 cents for each 
chromatic note. So, when creating all 12 notes through that 
cycle of upward 5ths and inverted intervals of downward 
4ths, these perfect intervals were SQUEEZED smaller by 2 
cents each - perfect 5ths were contracted by 2 cents and 
perfect fourths, being inversions, were expanded by 2 cents 
each. The result was that your ending note now matched 
perfectly your starting one. The intervals used became 
PERFECT IMPERFECT intervals.

Since the human hear can't really hear a difference until 3 
or more cents, this 2 cent shaving was not really apparent 
and did solve the problem of weird ugly intervals and the 
inability to freely transpose music into any key. It 
equalized the playing field in a compromise with Mother 
Nature.

This is the background to the entity of equal temperament.

How it applies to a specific instrument, the harmonica, and 
its vibrating reed, is a whole other story that includes the 
stiffness of the reed changing the overtone series 
relationships and how upper partials interact with each 
other.

But, that's enough schoolwork for one day.

Time for recess.

The Iceman





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