Crates.io | tune-cli |
lib.rs | tune-cli |
version | 0.28.0 |
source | src |
created_at | 2020-05-17 19:18:46.004793 |
updated_at | 2024-07-11 11:51:21.60399 |
description | Explore musical tunings and create synthesizer tuning files for microtonal scales. |
homepage | |
repository | https://github.com/Woyten/tune/tree/main/tune-cli |
max_upload_size | |
id | 242759 |
size | 214,657 |
Explore musical tunings and create synthesizer tuning files for microtonal scales.
tune-cli
is the command line tool for the microtonal tune library.
Option A: Try out the browser app to get a very first impression:
Option B: Download a precompiled version of tune-cli
for the supported target architectures:
Option C: Use Rust and Cargo to build a fresh binary from scratch for your specific target architecture:
cargo install -f tune-cli
Those two numbers seem arbitrary but, in fact, they can be shown to be a reasonable choice by applying first principles. To cook western tuning soup we only need a few ingredients:
tune-cli
can find valid step numbers and sizes based on the above requirements:
tune mos find --per 2 3
This will print all xLys (x large steps, y small steps) configurations up to some cutoff limit:
(+) num_notes = 2, 1L1s, L = +702c, s = +498c, L/s = 1.41 (*)
(-) num_notes = 3, 2L1s, L = +498c, s = +204c, L/s = 2.44
(-) num_notes = 5, 2L3s, L = +294c, s = +204c, L/s = 1.44
(+) num_notes = 7, 5L2s, L = +204c, s = +90c, L/s = 2.26
(+) num_notes = 12, 5L7s, L = +114c, s = +90c, L/s = 1.26 (*)
(-) num_notes = 17, 12L5s, L = +90c, s = +23c, L/s = 3.85
(-) num_notes = 29, 12L17s, L = +67c, s = +23c, L/s = 2.85
(-) num_notes = 41, 12L29s, L = +43c, s = +23c, L/s = 1.85
(+) num_notes = 53, 41L12s, L = +23c, s = +20c, L/s = 1.18 (*)
(-) num_notes = 94, 53L41s, L = +20c, s = +4c, L/s = 5.49
(-) num_notes = 147, 53L94s, L = +16c, s = +4c, L/s = 4.49
(-) num_notes = 200, 53L147s, L = +13c, s = +4c, L/s = 3.49
(-) num_notes = 253, 53L200s, L = +9c, s = +4c, L/s = 2.49
(-) num_notes = 306, 53L253s, L = +5c, s = +4c, L/s = 1.49
(+) num_notes = 359, 306L53s, L = +4c, s = +2c, L/s = 2.04
(+) num_notes = 665, 306L359s, L = +2c, s = +2c, L/s = 1.04 (*)
(+/-) = bright / dark generator
(*) = best equal-step approximation so far
We can see that there is a preference for certain reasonable numbers of scale steps:
In western tuning, the 12-tone 5L7s configuration has been chosen to be the sweet spot between expressiveness and complexity. It contains the diatonic 7-tone (5L2s) white-key configuration but leaves enough room for 5 black-key modulations. In order to arrive at an unbounded modulation circle, 5L7s has been equalized (L = s). The result is what we call 12 equal divisions of the octave (12-EDO) or just Modern Western Tuning.
A straightforward xen tuning to explore is 7-EDO since its diatonic MOS (5L2s) is a subset of the 12-EDO MOS (5L7s). It can be treated as an equalized diatonic scale without any modes i.e. major, minor, dorian, etc. sound the same.
tune-cli
can assist you in tuning your piano to 7-EDO. Just use the following command:
tune dump ref-note 62 --lo-key 61 --up-key 71 steps 1:7:2
This instructs tune
to print the frequencies and approximate notes of a 7-EDO scale starting at D4 (MIDI number 62). Output:
----------Source Scale----------- ‖ ----Pitch----- ‖ --------Target Scale--------
61 | IDX -1 | 20/11 -6¢ -1o ‖ 265.979 Hz ‖ 60 | C 4 | +28.571¢
> 62 | IDX 0 | 1/1 +0¢ +0o ‖ 293.665 Hz ‖ 62 | D 4 | +0.000¢
63 | IDX 1 | 11/10 +6¢ +0o ‖ 324.232 Hz ‖ 64 | E 4 | -28.571¢
64 | IDX 2 | 11/9 -5¢ +0o ‖ 357.981 Hz ‖ 65 | F 4 | +42.857¢
65 | IDX 3 | 4/3 +16¢ +0o ‖ 395.243 Hz ‖ 67 | G 4 | +14.286¢
66 | IDX 4 | 3/2 -16¢ +0o ‖ 436.384 Hz ‖ 69 | A 4 | -14.286¢
67 | IDX 5 | 18/11 +5¢ +0o ‖ 481.807 Hz ‖ 71 | B 4 | -42.857¢
68 | IDX 6 | 20/11 -6¢ +0o ‖ 531.958 Hz ‖ 72 | C 5 | +28.571¢
69 | IDX 7 | 2/1 -0¢ +0o ‖ 587.330 Hz ‖ 74 | D 5 | -0.000¢
70 | IDX 8 | 11/10 +6¢ +1o ‖ 648.464 Hz ‖ 76 | E 5 | -28.571¢
The table tells us that the first step of the 7-EDO scale (IDX 0
) has a frequency of 293.655 Hz and matches D4 exactly. This is obvious since we chose D4 be the origin of the 7-EDO scale. IDX 1
, the second step of the scale, is reported to be close to E4 but with an offset of -28.571¢.
You can now detune every note D on your piano by -28.571¢. On an electric piano with octave-based tuning support, this is a very easy task. It is also possible to retune a real piano using a tuning device.
Retune every note of the 7-EDO scale according to the table and the 7-EDO scale will be playable on the white keys!
If you do not want to retune your electric piano manually you can instruct tune-cli
to send a MIDI Tuning Standard (MTS) message to your synthesizer. To do so, locate your target MIDI device first:
tune devices
This will list all available MIDI devices:
Readable MIDI devices:
- Foo Synthesizer:Output 128:0
- Bar Synthesizer:Output 128:0
Writable MIDI devices:
- Foo Synthesizer:Input 128:0
- Bar Synthesizer:Input 128:0
You can now send a 7-EDO Scale/Octave Tuning message to Foo Synthesizer:
tune mts --send-to foo octave-1 ref-note 62 steps 1:7:2
Moreover, the command will print the tuning message to stdout
:
== SysEx start (channel 0) ==
0xf0
0x7e
0x7f
0x08
..
0x32
0x40
0x15
0xf7
Sending MIDI data to Foo Synthesizer:Input 128:0
== SysEx end ==
The Scale/Octave Tuning message is of very limited use: It can only slightly detune the 12 note letters within an octave which means that it is impossible to squeeze more than 12 notes into an octave or to model a non-octave-based tuning like Bohlen-Pierce or a stretched EDO.
To overcome this limitation, synthesizers can respond to the Single Note Tuning Change message. It provides full control over the pitch of each individual MIDI note s.t. any tuning scenario becomes achievable. Unfortunately, many synthesizers do not respond to this tuning message.
To send a Single Note Tuning Change message to a synthesizer use:
tune mts --send-to foo full ref-note 62 steps 1:7:2
Output:
== SysEx start ==
0xf0
0x7f
0x7f
0x08
..
0x7f
0x12
0x25
0xf7
Sending MIDI data to Foo Synthesizer:Input 128:0
Number of retuned notes: 75
Number of out-of-range notes: 13
== SysEx end ==
Some notes are reported to be out of range. This is because 7-EDO has a stronger per-step increase in frequency than 12-EDO does s.t. some (inaudible) frequencies become unmappable.
Unlike the octave-based mapping, the full keyboard mapping by default maps adjacent keys to adjacent degrees of your tuning. For 7-EDO, however, it would be convenient to skip/ignore the black keys in the mapping.
To specify a white-key-only keyboard mapping use the following syntax:
tune mts --send-to 1 full ref-note 62 --key-map 0,x,1,2,x,3,x,4,x,5,6,x --octave 7 steps 1:7:2
The --key-map
parameter specifies that key D is mapped to degree 0, key D# is unmapped, E is mapped to degree 1, F is mapped to degree 2 and so on. The parameter --octave
tells us that the 12th keyboard degree (D plus one octave) should be mapped to scale degree 7 (one octave in 7-EDO).
The risk is high that you are not satisfied with your synth's tuning capabilities because:
The Live Retuning feature is where tune-cli
shines. tune-cli
can apply a couple of workarounds to make even a very basic keyboard with a pitch-bend wheel play Bohlen-Pierce scales.
This, of course, comes at some cost. Your virtual instrument will either consume multiple MIDI channels instead of only one or you have to accept that simultaneously played notes can get in a conflict situation.
To understand what live retuning does, have a look at the CLI help of the live
subcommand:
tune live --help
The following command enables 31-EDO ahead-of-time live retuning with Scale/Octave (1-Byte) tuning messages:
tune live --midi-in foo --midi-out bar aot octave-1 ref-note 62 steps 1:31:2
Example Output:
Tuning requires 3 MIDI channels
Sending MIDI data to Bar Synthesizer:Input 128:0
in-channels {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15} -> out-channels {0, 1, 2, 3, 4, 5, 6, 7, 8}
[MIDI-in] Waiting for MIDI device `foo` to come online...
[MIDI-in] Connected to Foo Synthesizer:Input 128:0```
The term "ahead-of-time" reflects the fact that several channels will be retuned in a first stage where the number of required MIDI channels is fixed and depends on the selected tuning and tuning method (tune live aot --help
for more info). By default, all channels from 0 to 8 are considered useable. The given tuning, however only requires 3 of them. Note that tune-cli
uses 0-based channels and right-exclusive ranges – a convention which effectively avoids programming errors.
The second stage is the live performance stage. No further tuning message will be sent. Instead, each incoming MIDI message will be transformed into another message or a batch of outgoing MIDI messages on the channels that have the appropriate tuning applied.
Ahead-of-time live retuning always allocates enough channels s.t. any combination of notes can be played simultaneously.
If you want to allocate fewer channels than aot
does (let's say two instead of three) you can apply just-in-time live retuning:
tune live --midi-in foo --midi-out bar --out-chans 2 jit octave-1 ref-note 62 steps 1:31:2
Example Output:
Sending MIDI data to Bar Synthesizer:Input 128:0
in-channels {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15} -> out-channels {0, 1}
[MIDI-in] Waiting for MIDI device `foo` to come online...
[MIDI-in] Connected to Foo Synthesizer:Input 128:0```
On the surface, jit
just looks very similar to aot
. However, there is a big difference in its implementation: While aot
uses a fixed mapping with a fixed number of channels, jit
uses a dynamic mapping that gets updated whenever a new note is triggered.
In the given example we decided to use two jit
channels instead of three aot
channels. This means some combinations of three notes cannot be played simultaneously in the correct tuning. Although this sounds like a hard limitation, in our case it isn't. The reason is that in order for a clash of three notes to occur, all notes must map to the same note letter. This would be the case for the notes 61, 62 and 63, all of which are an 31-EDO-step apart. Usually, the limitation only comes into play when a very dissonant note cluster is pressed.
If your synthesizer has no support for complex tuning messages at all chances are that your synth understands one of the following message types:
The above messages have an effect on all notes in a channel. This means, when your tuning contains m different deviations from 12-EDO, the corresponding aot
live retuning command will require m channels. 16-EDO has 4 different deviations from 12-EDO s.t. the aot
command works reasonably well:
tune live --midi-in foo --midi-out bar aot fine-tuning ref-note 62 steps 1:16:2
tune live --midi-in foo --midi-out bar aot pitch-bend ref-note 62 steps 1:16:2
Example Output:
Tuning requires 4 MIDI channels
Sending MIDI data to Bar Synthesizer:Input 128:0
in-channels {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15} -> out-channels {0, 1, 2, 3, 4, 5, 6, 7, 8}
[MIDI-in] Waiting for MIDI device `foo` to come online...
[MIDI-in] Connected to Foo Synthesizer:Input 128:0```
In general, the number of aot
channels can grow quite large as is the case for 17-EDO. In that case, use jit
.
tune live --midi-in foo --midi-out bar --out-chans 8 jit fine-tuning ref-note 62 steps 1:17:2
tune live --midi-in foo --midi-out bar --out-chans 8 jit pitch-bend ref-note 62 steps 1:17:2
In the whole-channel tuning scenario --out-chans
can be directly associated with the degree of polyphony.
It is completely up to you to set the balance between channel consumption and tuning conflict prevention. The rules of thumb are:
Tips:
aot/jit full(-rt)
over aot/jit octave-n(-rt)
.aot/jit octave-n(-rt)
over aot/jit fine-tuning
.aot/jit fine-tuning
over aot/jit pitch-bend
.aot full(-rt)/octave-n(-rt)
allocates more than 3 channels: Consider using jit
with --out-chans=3
to save channels.ref-note --lo-key/--up-key/--key-map
/ YAML scale) is an option.jit
if you select less channels than aot
would use.aot fine-tuning/pitch-bend
works well for n-EDOs where gcd(n, 12) is large.aot fine-tuning/pitch-bend
can work for ED1900cents (quasi-EDTs) e.g. steps 1:13:1900c
.jit
will always work in some way. Configure your polyphony options with the --out-chans
and --clash
parameters.Some keyboards like the Lumatone contain more than 128 keys which is beyond what a single MIDI channel supports. To overcome this limitation tune-cli
can listen to multiple channels, each of which adds an offset to the original MIDI key number. The resulting key is obtained via key = midi_note + midi_channel * offset
.
As an example, execute the following command to connect the Lumatone using its default 31-EDO preset to FLUID Synth.
tune live --midi-in lumatone --luma-offs 31 --midi-out fluid aot full ref-note 62 --root 57 --lo-key 0 --up-key 155 steps 1:31:2
where --luma-offs
specifies the offset per channel and --lo-key
/ --up-key
override the default 88-key piano keyboard range.
An alternative tuning method, mostly on software-based synthesizers, is to upload an scl and kbm file to your synthesizer.
The Scala scale file format defines a scale in terms of relative pitches. It does not reveal any information about the root pitch of a scale.
Equal temperament
tune scl steps --help # Print help for the `steps` subcommand
tune scl steps 1:12:2 # 12-EDO
tune scl steps 100c # 12-EDO
tune scl steps 1:36:2 # Sixth-tone
tune scl steps '(100/3)c' # Sixth-tone
tune scl steps 1:13:3 # Bohlen-Pierce
Meantone temperament
tune scl rank2 --help # Print help for the `rank2` subcommand
tune scl rank2 3/2 6 # Pythagorean (lydian)
tune scl rank2 1.5 6 6 # Pythagorean (12-note)
tune scl rank2 1:4:5 5 1 # quarter-comma meantone (major)
tune scl rank2 18:31:2 3 3 # 31-EDO meantone (dorian)
Harmonic series
tune scl harm --help # Print help for the `harm` subcommand
tune scl harm 8 # 8:9:10:11:12:13:14:15:16 scale
tune scl harm -u 8 # 16/(16:15:14:13:12:11:10:9:8) scale
tune scl harm 27 --neji 12 # 27:29:30:32:34:36:38:40:43:45:48:51:54 scale
Imported scale
tune scl scl-file --help # Print help for the `scl-file` subcommand
tune scl scl-file my_scale.scl # Import my_scale.scl
Name the scale
tune scl --name "Just intonation" steps 9/8 5/4 4/3 3/2 5/3 15/8 2
Write the scale to a file
tune --of edo-22.scl scl steps 1:22:2
Ordered by precedence:
<num>:<denom>:<int>
evaluates to int^(num/denom)
<num>/<denom>
evaluates to num/denom
<cents>c
evaluates to 2^(cents/1200)
(<expr>)
evaluates to expr
Keyboard mappings specify the roots and reference pitches of microtonal scales. In addition, the format defines a mapping between (physical) keys and the scale degree to use for the given key. If no such mapping is provided a linear mapping is used as a default.
Print help for the kbm
subcommand
tune kbm ref-note --help
Start scale at C4 at its usual frequency
tune kbm ref-note 60
Start scale at C4, 20 cents higher than usual
tune kbm ref-note 60+20c
Start scale at A4 at 450 Hz
tune kbm ref-note 69@450Hz
Start scale at 9 steps below A4, A4 should sound at 450 Hz
tune kbm ref-note 69@450Hz --root 60
Start scale at two steps below C4, use D4 as a reference note, white keys only
tune kbm ref-note 62 --root 60 --key-map 0,x,1,2,x,3,x,4,x,5,6,x --octave 7
Write the keyboard mapping to a file
tune --of root-at-d4.kbm kbm ref-note 62
The dump
command provides information about the qualities of a scale. Let's have a look at the 19-EDO scale:
dump ref-note 62 --lo-key 61 --up-key 71 steps 1:19:2
The output reveals that some rational intervals are well approximated. Especially the just minor third (6/5) which is approximated by less than than 1¢ and, therefore, displayed as 0¢:
----------Source Scale----------- ‖ ----Pitch----- ‖ --------Target Scale--------
61 | IDX -1 | 2/1 -63¢ -1o ‖ 283.145 Hz ‖ 61 | C#/Db 4 | +36.842¢
> 62 | IDX 0 | 1/1 +0¢ +0o ‖ 293.665 Hz ‖ 62 | D 4 | +0.000¢
63 | IDX 1 | 1/1 +63¢ +0o ‖ 304.576 Hz ‖ 63 | D#/Eb 4 | -36.842¢
64 | IDX 2 | 12/11 -24¢ +0o ‖ 315.892 Hz ‖ 63 | D#/Eb 4 | +26.316¢
65 | IDX 3 | 10/9 +7¢ +0o ‖ 327.629 Hz ‖ 64 | E 4 | -10.526¢
66 | IDX 4 | 7/6 -14¢ +0o ‖ 339.803 Hz ‖ 65 | F 4 | -47.368¢
67 | IDX 5 | 6/5 +0¢ +0o ‖ 352.428 Hz ‖ 65 | F 4 | +15.789¢
68 | IDX 6 | 5/4 -7¢ +0o ‖ 365.522 Hz ‖ 66 | F#/Gb 4 | -21.053¢
69 | IDX 7 | 9/7 +7¢ +0o ‖ 379.103 Hz ‖ 66 | F#/Gb 4 | +42.105¢
70 | IDX 8 | 4/3 +7¢ +0o ‖ 393.189 Hz ‖ 67 | G 4 | +5.263¢
Imagine, you want to know how well quarter-comma meantone is represented in 31-EDO. All you need to do is create the quarter-comma meantone scale (tune scale
) and tune diff
it against the 31-EDO scale.
In quarter-comma meantone the fifths are tempered in such a way that four of them match up a frequency ratio of 5. This makes the generator of the scale equal to 5^(1/4) or 1:4:5
in tune
expression notation. To obtain a full scale, let's say ionian/major, you need to walk 5 generators/fifths upwards and one downwards which translates to the scale expression rank2 1:4:5 5 1
.
The scale expression for the 31-EDO scale is steps 1:31:2
, s.t. the full scale comparison command becomes:
tune scale ref-note 62 --lo-key 61 --up-key 71 rank2 1:4:5 5 1 | tune diff stdin ref-note 62 steps 1:31:2
This will print:
----------Source Scale----------- ‖ ----Pitch----- ‖ --------Target Scale--------
61 | IDX -1 | 11/6 +34¢ -1o ‖ 274.457 Hz ‖ 59 | IDX -3 | -0.979¢
> 62 | IDX 0 | 1/1 +0¢ +0o ‖ 293.665 Hz ‖ 62 | IDX 0 | +0.000¢
63 | IDX 1 | 9/8 -11¢ +0o ‖ 328.327 Hz ‖ 67 | IDX 5 | -0.392¢
64 | IDX 2 | 5/4 +0¢ +0o ‖ 367.081 Hz ‖ 72 | IDX 10 | -0.783¢
65 | IDX 3 | 4/3 +5¢ +0o ‖ 392.771 Hz ‖ 75 | IDX 13 | +0.196¢
66 | IDX 4 | 3/2 -5¢ +0o ‖ 439.131 Hz ‖ 80 | IDX 18 | -0.196¢
67 | IDX 5 | 5/3 +5¢ +0o ‖ 490.964 Hz ‖ 85 | IDX 23 | -0.587¢
68 | IDX 6 | 11/6 +34¢ +0o ‖ 548.914 Hz ‖ 90 | IDX 28 | -0.979¢
69 | IDX 7 | 1/1 +0¢ +1o ‖ 587.330 Hz ‖ 93 | IDX 31 | +0.000¢
70 | IDX 8 | 9/8 -11¢ +1o ‖ 656.654 Hz ‖ 98 | IDX 36 | -0.392¢
You can see that 31-EDO is a very good approximation of quarter-comma meantone with a maximum deviation of -0.979¢. You can also see that the step sizes of the corresponding 31-EDO scale are 5, 5, 3, 5, 5, 5 and 3.
The tune est
command prints basic information about any equal-step tuning.
Example output of tune est 1:19:2
:
==== Properties of 19-EDO ====
- step size: +63.2c
- fret constant: 27.914
---- Val (13-limit) ----
- notation: <19, 30, 44, 53, 66, 70|
- errors (absolute): [-0.0c, -7.2c, -7.4c, -21.5c, +17.1c, -19.5c]
- errors (relative): [-0.0%, -11.4%, -11.7%, -34.0%, +27.1%, -30.8%]
- TE simple badness: 35.440‰
- subgroup: 2.3.5.7.11.13
- tempers out 3-limit 1162261467/1073741824 (Pythagorean-19 comma)
- tempers out 5-limit 81/80 (syntonic comma, Didymus comma)
- tempers out 5-limit 3125/3072 (small diesis, magic comma)
- tempers out 5-limit 6561/6400 (Mathieu superdiesis)
- tempers out 5-limit 15625/15552 (kleisma, semicomma majeur)
- tempers out 5-limit 16875/16384 (double augmentation diesis, Negri comma)
- tempers out 5-limit 78732/78125 (medium semicomma, Sensi comma)
- tempers out 5-limit 1594323/1562500 (Unicorn comma)
- tempers out 5-limit 48828125/47775744 (Sycamore comma)
- tempers out 5-limit 1224440064/1220703125 (parakleisma)
- tempers out 5-limit 19073486328125/19042491875328 ('19-tone' comma)
- tempers out 7-limit 49/48 (slendro diesis, septimal 1/6-tone)
- tempers out 7-limit 126/125 (septimal semicomma, Starling comma)
- tempers out 7-limit 225/224 (septimal kleisma)
- tempers out 7-limit 245/243 (minor BP diesis, Sensamagic comma)
- tempers out 7-limit 525/512 (Avicenna enharmonic diesis)
- tempers out 7-limit 686/675 (senga)
- tempers out 7-limit 875/864 (keema)
- tempers out 7-limit 1029/1000 (keega)
- tempers out 7-limit 3136/3125 (middle second comma)
- tempers out 7-limit 4375/4374 (ragisma)
- tempers out 7-limit 10976/10935 (hemimage)
- tempers out 7-limit 19683/19600 (cataharry comma)
- tempers out 7-limit 59049/57344 (Harrison's comma)
- tempers out 11-limit 45/44 (1/5-tone)
- tempers out 11-limit 56/55 (undecimal diesis, konbini comma)
- tempers out 11-limit 100/99 (Ptolemy's comma)
- tempers out 11-limit 385/384 (undecimal kleisma, Keemun comma)
- tempers out 11-limit 540/539 (Swets' comma)
- tempers out 11-limit 729/704 (undecimal major diesis)
- tempers out 11-limit 896/891 (undecimal semicomma, pentacircle)
- tempers out 11-limit 26411/26244 (mechanism comma)
- tempers out 11-limit 65536/65219 (orgonisma)
- tempers out 13-limit 65/64 (13th-partial chroma)
- tempers out 13-limit 78/77 (tridecimal minor third comma)
- tempers out 13-limit 91/90 (medium tridecimal comma, superleap)
- tempers out 13-limit 105/104 (small tridecimal comma)
- tempers out 13-limit 144/143 (Grossma)
- tempers out 13-limit 169/168 (Schulter's comma)
- tempers out 13-limit 196/195 (mynucuma)
- tempers out 13-limit 325/324 (marveltwin)
- tempers out 13-limit 351/350 (ratwolf comma)
- tempers out 13-limit 676/675 (island comma)
- tempers out 13-limit 729/728 (squbema)
- tempers out 13-limit 1001/1000 (fairytale comma)
- tempers out 13-limit 1053/1024 (tridecimal major diesis)
- tempers out 13-limit 2080/2079 (ibnsinma)
- tempers out 13-limit 10985/10976 (cantonisma)
- tempered vs. patent location of 7/6: 4 vs. 4
- tempered vs. patent location of 6/5: 5 vs. 5
- tempered vs. patent location of 5/4: 6 vs. 6
- tempered vs. patent location of 4/3: 8 vs. 8
- tempered vs. patent location of 3/2: 11 vs. 11
- tempered vs. patent location of 7/4: 15 vs. 15
- tempered vs. patent location of 2/1: 19 vs. 19
==== Meantone[7] notation ====
- number of cycles: 1
- 1 primary step = 3 EDO steps
- 1 secondary step = 2 EDO steps
- 1 sharp (# or -) = 1 EDO steps (diatonic)
---- Note names ----
0. D
1. D#
2. Eb
3. E
4. E#/Fb
5. F
6. F#
7. Gb
8. G
9. G#
10. Ab
11. A
12. A#
13. Bb
14. B
15. B#/Cb
16. C
17. C#
18. Db
---- Keyboard layout ----
9 12 15 18 2 5 8 11 14 17
11 14 17 1 4 7 10 13 16 0
13 16 0 3 6 9 12 15 18 2
15 18 2 5 8 11 14 17 1 4
17 1 4 7 10 13 16 0 3 6
0 3 6 9 12 15 18 2 5 8
2 5 8 11 14 17 1 4 7 10
4 7 10 13 16 0 3 6 9 12
6 9 12 15 18 2 5 8 11 14
8 11 14 17 1 4 7 10 13 16
10 13 16 0 3 6 9 12 15 18
==== Meantone[5] notation ====
- number of cycles: 1
- 1 primary step = 3 EDO steps
- 1 secondary step = 5 EDO steps
- 1 sharp (# or -) = -2 EDO steps (pentic)
---- Note names ----
0. D
1. E-
2. D+
3. E
4. D++/G--
5. E+
6. G-
7. E++/A--
8. G
9. A-
10. G+
11. A
12. G++/C--
13. A+
14. C-
15. A++/D--
16. C
17. D-
18. C+
---- Keyboard layout ----
13 16 0 3 6 9 12 15 18 2
18 2 5 8 11 14 17 1 4 7
4 7 10 13 16 0 3 6 9 12
9 12 15 18 2 5 8 11 14 17
14 17 1 4 7 10 13 16 0 3
0 3 6 9 12 15 18 2 5 8
5 8 11 14 17 1 4 7 10 13
10 13 16 0 3 6 9 12 15 18
15 18 2 5 8 11 14 17 1 4
1 4 7 10 13 16 0 3 6 9
6 9 12 15 18 2 5 8 11 14
==== Hanson[7] notation ====
- number of cycles: 1
- 1 primary step = 4 EDO steps
- 1 secondary step = 1 EDO steps
- 1 sharp (# or -) = 3 EDO steps (smitonic)
---- Note names ----
0. D
1. Eb
2. Fb
3. D#
4. E
5. F
6. Gb
7. E#/Ab
8. F#
9. G
10. A
11. Bb
12. G#/Cb
13. A#
14. B
15. C
16. Db
17. B#
18. C#
---- Keyboard layout ----
14 18 3 7 11 15 0 4 8 12
15 0 4 8 12 16 1 5 9 13
16 1 5 9 13 17 2 6 10 14
17 2 6 10 14 18 3 7 11 15
18 3 7 11 15 0 4 8 12 16
0 4 8 12 16 1 5 9 13 17
1 5 9 13 17 2 6 10 14 18
2 6 10 14 18 3 7 11 15 0
3 7 11 15 0 4 8 12 16 1
4 8 12 16 1 5 9 13 17 2
5 9 13 17 2 6 10 14 18 3
tune
uses YAML as an explicit scale format. You can use tune
's output as an input for an external application or the other way around. It is possible to export a scale first, then modify it and, finally use it as in input parameter for another tune
command.
tune scale ref-note 62 --lo-key 61 --up-key 64 steps 1:7:2
Output
---
Scale:
root_key_midi_number: 62
root_pitch_in_hz: 293.6647679174076
items:
- key_midi_number: 61
pitch_in_hz: 265.9791296633641
- key_midi_number: 62
pitch_in_hz: 293.6647679174076
- key_midi_number: 63
pitch_in_hz: 324.23219079306349