- Escape the
[dev-bot]
spam of a watch by a filtered removal of[dev-bot]
Current development on Linux ARM Chromebook.
Version: RACK_VERSION.WORKING_MACHINES_COUNT.FIX_INCREMENT
supplied in tags. Any commit not tagged is not a version for compile, although it may work it could also be quite dangerous. The index is numbered so that WORKING_MACHINES_COUNT
makes sense given the development ordering of the index.
Current public version: here archives for older versions of the demos maybe available here.
Compiled with: gcc version 12.2.0 (Debian 12.2.0-14)
or later. Any issues due to edge case optimizations of float
may be corrected if they are problems.
Less technical: Captain's log for less detail and more of an overview.
KRTPluginJ might be an interesting idea. It must be GPL3 however due to licence restrictions.
The version number indicates the API build compatibility and feature use. So 1 is VCVRack V1 API. These will be changed as higher API number features are used and adapted to.
- A - 2 - DA
- ÎĽ - 2 - crisp
- T - 2 - I shat the she riff
- L - 2 - boring
- ;D - 2 - DA
- R - 2 - No demo required
- Ω - 2 - Omicron
- V - 2 - Omicron
- F - 2 - morph
- W - 2 - W
- Y - 2 - Y
- O - 2 - parabolic
- S - 2 - SE
- E - 2 - SE
- X - 2 - wave
- M - 2 - M
- Q - 2 - Q
- C - 2 - No demo required
- U - 2
- B - 2 - I seems to be adding to patch B
- J - 2
- K - 2
- H - 2
- I - 2
- G - 2
- Z - 2
Easy Access Demo Archive includes all the demos above as a .zip file for easy downloading and none of that cut, paste, save and rename business.
49% Transparent Module - Made with sexspex plastique
- Frequency (-12dB)
FRQ
- Resonance
REZ
- Frequency Modulation Gain
MOD
- Relative Plate (-6 dB)
OFF
- Plate Gain
AM
- Plate Modulation Gain
MAM
- -18 dB In (HP on
XP12
)IN1
- -18 dB Predictive (LP on
XP12
)LP1
- Frequency CV
CV
- -12 dB In (No Plate)
IN2
- -6 dB HP In (Plate Ring)
HP1
- Modulation
MOD
- -6 dB LP Out
LP1
- Tracking Out
CV
- -12/-18 dB Out
LP12
- -6 dB HP Out
HP1
- Plate Out
AM
- -12/-18 dB Inverse Extended Filter Out
XP12
A generic filter with some nice fun additions for a characteristic sound. How much fun can you have with 4 poles and some other DSP functions? Yes, it is by design digital, although it might be possible to make an analogue version of most if not all of the implied circuit.
The filter poles are ZDF (Zero Delay Filter) arithmetic. The LP1
predictive input creates a
ninth order estimate one sample into the future. This has the effect of a bit of phasing and given that it is not equally fed into the ring modulation too, makes it spectrally different. The 45 degree lead lag of the ring makes for a ninety on the AM, for even harmonic self AM power.
If some controls appear not to operate use IN1
and LP12
out, with CV
for tracking, and then all the controls work. Some specific inserts are pre or post certain controls. The plate AM tracking stacks on the filter corner tracking.
The Gold One - Summation generative additive synthesis
SIGNATURE
- Master Gain
dB
- Slew Limit
Hz
- Halflife
λ
- Gain 1
G1
- Gain 2
G2
- Gain 3
G3
- 1V/6dB
CVdB
- 1V/Oct
CVHz
- 1V/halflife
CVλ
- In 1
IN1
- In 2
IN2
- In 3
IN3
- Differential
Δ
- Differential
ΔΔ
- Differential
ΔΔΔ
- Integral Linear
ÎŁ
- Integral Pole
1/ÎŁ
- Integral Log
LNÎŁ
Some weird calculus module. It really depends what it can be made to do. It might become unstable if you feedback connections. It might not as well. The λ
control only affects the last 5 outputs, as the 3 integral representations should converge to the same value and λ
affects the effective sample timing offset next to a potential singular solution.
All the estimators are predictive one sample into the future (with λ
kind of being a sophisticated constant of integration), a pre slew filter is set as a 6 dB/Oct zero delay filter. This filter may work opposite to how you might expect for some outputs.
So the inputs IN1
, IN3
and IN3
are controlled by centred dB scaling gainuverters for gain, amplified by an exponential dB
, slew limited and then processed for calculus estimates (9th order FIR).
The integrals are further processed by 3 point series accelerations (a tiny effect but interesting) to occur at a sample in the future. λ
applies an effective modulation of this integral time step from a fraction of a sample to multiple samples. The half-life then is measured in exponential inverse octaves.
I mean why a 9th order FIR, and the number 27 of the sporadic simple groups connection? From 2 comes 2 to the power of all N. From 3 comes all odd numbers? This likely explains the choice of cube root to control the range of output voltage.
He's irresponsible :D https://en.wikipedia.org/wiki/Jacques_Tits ... roll on (Monster Moonshine)[https://en.wikipedia.org/wiki/Monstrous_moonshine] and let's not confuse maths with physics "speculated" on maths. Hope I got all the integration by parts and collection of approximants in limited terms right? (Some 2's, some 3's, some hopeful sporadics on the elliptic). Did I mention the congruants div 3 and the determinants (count 44 (18n+26 (Groupies)[https://en.wikipedia.org/wiki/Sporadic_group])) with Z(p) and alternating groups to a 42 which the circle and ellipse are the alternating or not on the major minor radius?
Initialize the big bang with differential estimates of the future captain, so obviating the definitional requirements at the singularity Captain. Well Gamma Bob, well gamma. A form of precision series truncation crusher, nice! None of that chucking away an abstract precision and getting right in there with truncation of summation generative additive synthesis, for that timbrel union.
But isn't it about the singularity context of integration in a set of limits x, x+y where x is unknown but guesstimated in a relative context Captain? Yes Bob all error in the calculus should be reported as this module is not about error, and others maybe built.
But shouldn't a sine converge to sin(x)? And and truncation of terms provide a controlled deviation from sin(x) for Fourier harmonics? Exactly Boz, the sweet low power law alias summands.
"Proxy off a dirty hole of unknown gain? How dare you? Must fix the incoming to be at least pleasant." -- Captain of the Exponential.
The White One - A harmonic pitch down and up delay
- Course Tune
NOTE
- Fine Tune
FINE
- In
IN
- Trigger
TRIG
- High Trigger
HI
- Out
OUT
The trigger TRIG
resets the delay and produces a down shifted OUT
until the up shift starts causing HI
to output a rising edge and the delay switches an octave up until the expected retrigger point. The delay plays regular speed until a retrigger. The delay will reset itself if the delay buffer becomes full.
Going down is always a prerequisite before rising to the top! And normal is very overdue. The maximal delay length is divided by polyphony. What's the cache flush GB/s on this thing? I'm thinking 4 bars and a bit or so?
Polyphonic triggers occur at the optimal octave intercept per trigger, and so the outputs become phasic to the triggers. HI
can off trigger a trigger to sync with the up speed clearing of the precision down beat zero delay. No trigger equals no effect and no delay after the "blip" as there is a trigger need on TRIG
.
Try NOTE
at 5 semitones, and alter the trigger rate for a sync chord arpy sound. In this sense other semitone values are better at lower TRIG
rates. Try some drums on the HI
out for an interesting timing effect too.
A White One - A synchronized delay with pre-trigger end
- Pre-trigger Delay
PRE
- Fine Tune
FINE
- In
IN
- Trigger
TRIG
- Pre-trigger
PRE
- Out
OUT
A synchronized delay with a PRE
control to remove a time dependant on sample latency so as to match timing one synchronization trigger later. So suppose you wish to synchronize to some live play and are prepared to time up one TRIG
later (say a bar for arguments sake), then you can increase PRE
to achieve that less than the bar delay with latency compensating the rest of the bar delay which PRE
removed on OUT
. The output PRE
gates high before the bar end to allow down module to trigger other things with the need to be triggered before the bar start.
Another White One - A future estimator VCA with error
- Level
dB
- Level Modulation
CVdB
- Frequency
FRQ
- In
IN
- Level Modulation
CVdB
- Out
OUT
Exponential amplitude modulation with a future projection estimate 2 samples into the future for phase critical all pass when used with modules that have a 1 sample delay. The CVdB
control is a centred dB scaling gainuverter.
Also useful for pointing out transients in IN
as the estimator is excited by the parts of the signal with aliasing potential.
The Final White One - A simple mixer split
- On Level
ON
- As Level
AS
- In
IN
- Mix Some On
ON
- Get As
AS
- Out
OUT
Mix some ON
into the IN
making an OUT
with control of it AS
for easy modulation mixing. The controls are centred dB scaling gainuverters.
The 70% Grey One (With A Display) - Clock distribution randomizer
SIGNATURE
- Bird
BIRD
- Seed
SEED
- Randomize
RAND
- Clock (Polyphony Master)
CLK
- Reset (Polyphonic OR)
RST
AN
,BO
,CP
,DQ
,ER
,FS
,GT
,HU
,IV
,JW
,KX
,LY
,MZ
RST
starts a sequence of gate activations, from the beginning, on the outputs AN
to MZ
advanced by the CLK
trigger. The SEED
controls the initial symbol and some randomness of the following symbols. RAND
increases the chaos of randomization from the initial SEED
. The magic of BIRD
(the word) applies some modal operator lambda calculus to modify the sequence with the very discrete occasional stall in the MM
Omega bird. This is not the differential calculus of Newton fame, but the one with names such as Godel and Church.
There is a great book on modal logic called To Mock a Mocking Bird, itself a follow up to Forever Undecided. A lay person introduction to the subject.
Higher polyphony using CLK
copies the mono output one from the lowest channel to the highest given a CLK
on a channel. For example when clocked the second channel takes the output of the first channel.
The 70% Grey One - Envelope VCA and CV producer
DEPRECATED
- Base Frequency
Hz
- Envelope Attack
ATK
- Envelope Decay
DCY
- Frequency Modulation
CVHz
- Amplitude Modulation
CVdB
- Envelope Time Modulation
CVs
- 3 of
- Oscillator In
IN
- Up 5 Semitones Trigger
T5
- Up 7 Semitones Trigger
T7
- Oscillator In
- 3 of
- Frequency CV to Oscillator
CV
- Envelope Shaped Output
OUT
- Frequency CV to Oscillator
Takes in triggers on T5
and T7
to trigger one of the three vertical envelopes. IN
is from the oscillator source, and OUT
is that signal modified by the envelope. CV
can be tuned dependant on the trigger pair combination. I thought it would help with using Ω. Although it might be quite useful on its own. The two outer OUT
signals are normalized to the centre OUT
channel for less cables.
The Blue One - Morph filter
SIGNATURE
- Pole Spread
SPD
- Pole Skew
SKW
- Frequency
FRQ
- Low All High
LAH
- Invert
INV
- Drive
DRV
- Frequency Modulation
FRQ
- Spread Modulation
SPD
- Skew Modulation
SKW
- Low All High Modulation
LAH
- Invert Modulation
INV
- Drive Modulation
DRV
- Input
IN
- Output
OUT
A filter with some internal gain processing to handle filter k values into self-oscillation. The four corners set by spread and skew form Linkwitz to Butterworth on spread when skew is full off, and Legendre to Bessel when skew is full on. The concept is stabilized by soft clipping.
The Red One - Gate transposer
- None
- Input
IN
- Gates Transpose
1
,2
,3
,4
,5
,6
,7
,8
,9
,10
,11
- Output Add
+
- Output Subtract
-
To assist in turning patterned gates into CV chromatic sequences. Simple.
The White Buttons One - Gate sequencer
- Tempo
TEMPO
- Gate Length
G.LEN
- Four Mode Buttons
PAT
,SEQ
,MUTE
,NOW
- The Main Buttons (28 for notes and triples)
- Run and Stop
RUN
- Reset
RST
- Copy Pattern
CPY
(makes note of active channel forPAT
paste channel copies) - Paste Pattern
PST
(only pastes into current channel inPAT
mode) - Shuffle Jazz
JAZZ
(three altering micro timings)
- CV
CV
- Gate
GATE
- Position Jazz
JAZZ
(later versions)
- Clock
CLK
- Reset
RST
A gate pattern sequencer. An obvious layout, but the modes might be complicated.
PAT
a pattern edit mode similar to a standard drum machine.SEQ
triggers and selects various sequences. For performance play. Alters assigned pattern on pattern change controls of triples.MUTE
allows channel mutes while maintaining some pattern change control on triples.NOW
puts direct channel gates on the notes (also selects active channel via last pressed channel), while maintaining some pattern change control on triples.
The CPY
light indicates when the copy source is the same as the paste source. The PST
light indicates if the copy channel source is the same as the current paste channel.
The C2
to B5
keyboard MIDI range on CV
triggered by GATE
operate the buttons.
C#
,D#
pair operate function and mode buttons left to right (in pairs).C
,D
,E
operate triple buttons.F#
,G#
,A#
also operate triple buttons for utility.F
,G
,A
,B
operate quarter buttons.
The Beige-ish One - Triple parabolic skew feedback oscillator
- Frequency
FRQ
(three) - Feedback
FBK
(three)
- CV
CV
- Output
OUT
An algorithm for sound. Simple to use.
A 30% Grey One - MIDI clock signalling to position CV
- BPM Estimate
BPM
- Divide
DIV
- Clock
CLK
- Start
STRT
- Stop
STOP
- Continue
CONT
(suitable forY
moduleJAZZ
input)
- Out
OUT
For interfacing with a MIDI clock provided as an output by the MIDI-CV system module. 64 beats equals 10V and reset back to 0V unipolar signal.
Another 30% Grey One - Envelope and VCA
- Attack
ATK
- Release
REL
- Modulation Level
MOD
- In
IN
- Trigger
TRIG
- Modulation
MOD
- Out
OUT
A simple AR envelope with a VCA. The MOD
control is a centred dB scaling gainuverter.
Another 30% Grey One - Wave-folder
- Fold
FOLD
- Kind
KIND
- Mash Noise
MASH
- Wet Mix
WET
- In
IN
- Modulate Fold
MFLD
- Out
OUT
An over-sampled wave-folder based on Chebychev polynomials and some extras for a bit of a difference.
Another 30% Grey One - Emphasis filter
- Low Frequency
LOW
- Low Gain
LOdB
- High Frequency
HIGH
- High Gain
HIdB
- CV Low
LO
- CV High
HI
- In
IN
(send filter input) - Return
RTN
(return filter input)
- Send
SND
(send filter output) - Out
OUT
(return filter output)
An equalization filter to decrease the effect of non-linear signal processing on high frequencies throwing them into alias distortion. A return filter removes the emphasis. So the base is amplified and treble reduced on the forward send filter, and the opposite for the return filter. It may make interfacing a "phono" deck easier, but does not amplify the tiny signals from a deck.
It reduces the non-linear shaping of high frequencies in the send return path from injecting harmonics into the alias band above the sampling Nyquist frequency. So good for base harmonic generation. The headroom of VCV rack should support the +/- 50V peak to peak. But you might need a bit of gain reduction before this module.
WARNING The default gain settings are good for RIAA equalization, but could be reduced closer to 0 dB for general use. As the return filter is the opposite, that HIdB
value can be misleading on what the return filter is doing. Under some circumstances it could destroy tweeter speakers just as the send filter could wobble the neighborhood walls.
A Green One - Quantum gravimitator The Big Manual?
SIGNATURE
- Omega Frequency
OM
- Singularity Management
SING
- Plank
PLK
- Newton
NTN
- Mass Ratio
MASS
- Radial Tangential Angle
ANG
- Omega Frequency Modulation
OM
- Singularity Management Modulation
SING
- Plank Modulation
PLK
- Newton Modulation
NTN
- Mass Ratio Modulation
MASS
- Radial Tangential Angle Modulation
ANG
- Input
IN
- Output
OUT
A physical model simulation. Treats the input as a driven mass radius and calculates the uncertainty of the mass using a quantum and gravity connection.
I could explain by (https://drive.google.com/file/d/0B-avx1luFGRbRTVFOFhSWkluQWM/view?usp=sharing&resourcekey=0-YsVFVTBgEFU-1QAJ1hYz8A)[Mistakes and genius] as yes something are wrong, and something being applied have an error less than Planks constant cubed which is very small as to be immeasurable, yet defined as certain by fixing the constant as a committee committed to, and so ...
Is dark matter the integral over an average on a non-linear 1/r^2 law of an uncertainty in radial potential energy? Is dark energy a tangential version? As distances get smaller the F=kr of quark confinement something that 1/r maps to r becomes a strong force unseen equivalent? Dark strong? A prediction or just a tune from finding sub-harmonic greatest common division of the natural omega frequency of matter?
How to connect your modular to a scanning tunnelling microscope? Contact a physical? Enjoy!
To H
or not to wage? Das ist da krewestion? Wether it is better to enter into mass statistic of global endomology or to find yourself under a hierarchy of perfection?
A Purple One - Mixer sixer
SIGNATURE
- Channel 1 Polarity
G1
- Channel 1 Low Pass
F1
- Channel 2 Polarity
G2
- Channel 2 Low Pass
F2
- Channel 3 Polarity
G3
- Channel 3 Low Pass
F3
- Channel 1 In
IN1
- Channel 2 In
IN2
- Channel 3 In
IN3
- Input
LINK
- Channel 1 Out
OUT1
- Channel 2 Out
OUT2
- Channel 3 Out
OUT3
- Output Mix
MIX
The G1
, G2
and G3
controls are centred dB scaling gainuverters. Each channel has a low pass single pole filter and an independent output. The LINK
input is combined with all the outputs not connected to make the MIX
output. Connecting to an output OUT1
, OUT2
or OUT3
removes it form the MIX
for utility as an attenuverter.
A Pink One - Sample and hold quantizer
- Quantize
QUNT
(in semitones) - Noise
NSE
(when no input color filter)
- Clock Sample
CLK
- Input
IN
- Output
OUT
- Quantized Output
QOUT
A simple triple sample and hold with semitone quantizer.
A White One with Buttons - Performance switch
- 18 Route Buttons
- Mode
MODE
1
,2
,3
,4
,5
and6
A
,B
andC
Performance controller switch. The MODE
cycles through GREEN
, RED
and BLUE
modes.
GREEN
mode: the routing buttons select switching of the inputs to the outputs. Multiple inputs can be selected and merged.RED
mode: the routing buttons select one of 18 recorded patterns to recall. The active pattern is shownRED
perhaps mixed withGREEN
andBLUE
if other data is shown.BLUE
mode: the routing buttons select function merge processing. Each of the three outputs can have the different functions applied in all combinations (top to bottom application order).
A Cyan One - All-pass filter
- Frequency
FRQ
- Order
ODR
- Bypass, High, All
BHA
- Wet Mix
WET
- LFO Frequency
LFO
- LFO Depth
LVL
- Frequency CV
FRQ
- Order CV
ODR
- Bypass, High, All CV
BHA
- Wet Mix CV
WET
- LFO Frequency CV
LFO
- Input
IN
- LFO Out
LFO
- Output
OUT
An all-pass filter with some phaser style effect possibilities. A direct LFO
output is available, as this is more important than CV control over the LVL
sweep range.
A Black One - Phase modulation oscillator
- Frequency
FRQ
- Filter
LPF
- Ratio
RT1
- Ratio
RT2
- Modulation Depth
MD1
- Modulation Depth
MD2
- Frequency CV
FRQ
- Filter CV
LPF
- Ratio CV
RT1
- Ratio CV
RT2
- Modulation Depth CV
MD1
- Modulation Depth CV
MD2
- Modulation Out
MOD
- Output
OUT
Another Grey One - Base Gimpathizer
SIGNATURE
- 9 Hammond Harmonics
16'
,5 1/3'
,8'
,4'
,2 2/3'
,2'
,1 3/5'
,1 1/3'
and1'
- 9 Hammond Harmonic CV
16'
,5 1/3'
,8'
,4'
,2 2/3'
,2'
,1 3/5'
,1 1/3'
and1'
- Frequency CV
FRQ
- Phase Modulation CV
PM
- Out
OUT
Classic organ harmonics. Add a little phase modulation weighted more for the base harmonics, and make some interesting timbrel textures. Hold on to your base bins. To not weight the phase modulation gets harmonically (n+1) very fast.
A Light Grey One - Clock divider
- 3 Dividers
D1
,D2
,D3
- 3 Phases
P1
,P2
,P3
- Clock
CLK
- Reset
RST
- Down Beat
DWN
- All But Down Beat
SANS
- 3 Outs
O1
,O2
,O3
- Exclusive Or of All 3 Outputs
XOR
Apart from being 3 variable clock dividers which maintain a synchronization phase this module also extracts the down beat for modules when high RST
does not override CLK
and so need the first clock extracting (the downbeat) to synchronize them. Such "armed before play" (rising edge reset) modules should copy the MIDI standard but are different from the normal electronic logic synchronous convention of hold in the first state on RST
and so don't ignore the first CLK
. They should use an extra state (called "armed" here) and then need a CLK
to enter the first state.
If a module resets on rising edge RST
but also reacts after to rising edge CLK
and also doesn't have an "armed" state, it jump forward one step out of sync. If it has an "armed" state and RST
is slightly delayed compared to CLK
is spend one step in the "armed" state based on a race of signals through wiring.
If the CLK
is before the RST
: the clock is the downbeat. DWN
and SANS
can be used as RST
and CLK
for downstream modules without confusion if they reset into the first state not needing a clock to transition from an "armed" state. The clock is truncated on RST
and sent out DWN
and is a glitch on SANS
.
If the CLK
is after the RST
(but RST
is still high): the clock is the downbeat. DWN
and SANS
can be used as RST
and CLK
for downstream modules without confusion if they reset into the first state not needing a clock to transition from an "armed" state. The clock is sent out DWN
and does not appear out of SANS
.
So basically that part of the module helps when synchronizing modules with a rising edge RST
instead of a high continuous RST
(with CLK
ignore). Extracting the downbeat is in a sense a clock ignore on SANS
. DWN
is in a sense a RST
but delayed until after CLK
.
Another Grey One - Compressor
- Attack
ATK
- Decay
DCY
- Threshold
THR
- Ratio of compression
RTO
(or expansion -ve ratios) - High Pass Cut
CUT
- High Pass Resonance
Q
- Mix to Makeup Level
MIX
- Envelope Follower to CV
ENV
- Frequency
FRQ
- Side-chain
SCH
(normalized fromIN
) - Input
IN
- Frequency
FRQ
(withENV
mixed in with control gain) - Envelope Follower
ENV
- Compressed Output
OUT
A normal compressor with a side-chain input. The envelope follower can be mixed with the FRQ
in to produce some pinging harmonics by the output FRQ
(modified by the envelope), along with a high pass filter which can be tuned down for a Q
boost and sub-base cut. The MIX
brings a compressed OUT
back upto normalized levels like an auto-computed make up gain. The amount of applied compression could more accurately be the envelope applied via the ENV
control to the FRQ
chain. This chain also applies to the CUT
to slide up the corner frequency of the high-pass filter.
The CUT
filter is perhaps the most interesting bit of the design. The range of the control is slanted towards sun-octaves, while the Q
has been somewhat limited as it is applied post compression. It makes a nice effect when compression "breathing" is swept using CUT
and ENV
controls to balance the style.
in development
SIGNATURE
Currently displaying the GUI design elements with no processing.