Literature:Elements of Harmony: Difference between revisions
m (→Contents) |
m (→Contents) |
||
Line 2: | Line 2: | ||
==Contents== | ==Contents== | ||
*Book 1 discusses | *Book 1 discusses mathematical results: | ||
**Basically the ones in Euclid's Elements plus... | **Basically the ones in Euclid's Elements plus... | ||
**Continued fractions | **Continued fractions | ||
*Book 2 discusses basic acoustics | **Calculus? | ||
*Book 2 discusses basic acoustics using the number theory proved in Book 1. | |||
**harmonic series | **harmonic series | ||
**intervals as string length ratios (given equal thickness and tension) | |||
**motivates logs; gives computation of logs | |||
*Book 3 discusses harmonic properties of various scales. | |||
**odd- and prime-limit | **odd- and prime-limit | ||
** | |||
**chord voicings | |||
***writes the intervals in a given prime-limit as tuples/monzos | ***writes the intervals in a given prime-limit as tuples/monzos | ||
**otonal and utonal chords | **otonal and utonal chords | ||
'''Motivation for log''': Assume strings 1 and 2 have equal tension and thickness, and have lengths $L_1$ and $L_2$ respectively. Find a function $\log$ that, given the ratio between $L_1$ and $L_2$, measures the corresponding subjective difference in pitch, i.e. is an isomorphism from the multiplicative group of positive real numbers to the additive group of real numbers. | |||
$\log(\frac{L_1}/{L_2})$ gives the subjective intervallic change when moving from string 1 to string 2. | |||
Thus: if $r_1$ and $r_2$ are string length ratios, then we want | |||
$\log(1) = 0;$ $\log(a) > 0$ when $a > 1;$ $\log(r_1 r_2) = \log(r_1) + \log(r_2).$ | |||
The area $A(t)$ under the hyperbola $y = \frac{1}/{x}$ from $x = 1$ to $x = t$ satisfies the desired properties: $A(1) = 0; A(tu) = A(t) + A(u)$. | |||
Ts-T derives that the desired function is well-approximated by Taylor polynomials: namely, $log(x+1) = A(x+1) ≈ \sum_{n=1}^{N} (-1)^n \frac{x^n}/{n}$, when $|x| < 1$. (Need calculus?) | |||
==Full text (in English)== | ==Full text (in English)== |
Revision as of 10:16, 9 June 2017
Elements of Harmony (placeholder name) is a collection of Netagin-language textbooks covering elementary number theory, acoustics, and just intonation music theory.
Contents
- Book 1 discusses mathematical results:
- Basically the ones in Euclid's Elements plus...
- Continued fractions
- Calculus?
- Book 2 discusses basic acoustics using the number theory proved in Book 1.
- harmonic series
- intervals as string length ratios (given equal thickness and tension)
- motivates logs; gives computation of logs
- Book 3 discusses harmonic properties of various scales.
- odd- and prime-limit
- chord voicings
- writes the intervals in a given prime-limit as tuples/monzos
- otonal and utonal chords
Motivation for log: Assume strings 1 and 2 have equal tension and thickness, and have lengths $L_1$ and $L_2$ respectively. Find a function $\log$ that, given the ratio between $L_1$ and $L_2$, measures the corresponding subjective difference in pitch, i.e. is an isomorphism from the multiplicative group of positive real numbers to the additive group of real numbers.
$\log(\frac{L_1}/{L_2})$ gives the subjective intervallic change when moving from string 1 to string 2.
Thus: if $r_1$ and $r_2$ are string length ratios, then we want
$\log(1) = 0;$ $\log(a) > 0$ when $a > 1;$ $\log(r_1 r_2) = \log(r_1) + \log(r_2).$
The area $A(t)$ under the hyperbola $y = \frac{1}/{x}$ from $x = 1$ to $x = t$ satisfies the desired properties: $A(1) = 0; A(tu) = A(t) + A(u)$.
Ts-T derives that the desired function is well-approximated by Taylor polynomials: namely, $log(x+1) = A(x+1) ≈ \sum_{n=1}^{N} (-1)^n \frac{x^n}/{n}$, when $|x| < 1$. (Need calculus?)