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tapin~
| External |
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Input to signal delay line
tapin~ receives a signal in and copies into a delay line. Using tapout~ objects, you can read from the delay line at various delay times. You must connect the outlet of a tapin~ object to the tapout~ objects you want to use with the delay line. Note that this is not a signal connection, since no signal travels between the objects. It is merely a way to indicate that the objects share the same delay memory. |
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tapout~
| External |
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Output from signal delay line
tapout~ outputs a delayed signal that was fed to tapin~. You connect a tapin~ object to one or more tapout~ objects. tapout~ has one or more inputs to specify delay time and a signal output for each input. You type an initial delay time argument in milliseconds for each input/output you want (maximum 64). If you connect a signal to a delay time input, a continuously variable delay algorithm is used that has the effect of transposing the original signal up when the delay time is gradually decreasing and transposing it down when the delay time is gradually increasing. If you connect a float to a delay time input, the output signal doesn't transpose but you may hear clicks when changing the delay time. In either case, the delay time is specified in milliseconds. If you're not going to change the delay time, just using a float to specify the delay time is much more efficient. |
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terrain~
| External |
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linear wavetable terrain interpolation / model |
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text
| External |
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Collect and format messages as a text file, output single lines of text |
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thisTimeline
| External |
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Send messages to a timeline
Send control messages to the timeline object from within an action patcher |
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thisTrack
| External |
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Send messages to a timeline track
Send control messages to a timeline track object from within an action patcher |
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tiCmd
| External |
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Interface between the timeline and its action patchers
The tiCmd object receives messages from the timeline and passes them to a patcher which is serving as an action. It is analogous to an inlet object (but note that inlet objects do not work with the timeline). It takes the following arguments: first, a message selector which is a symbol that serves to identify the tiCmd object. The selector is followed by any number of arguments that to specify the expected types in the message. Each type specifier argument produces an outlet in the tiCmd object. If a type in the message contained in the timeline is different than what is specified in the tiCmd object, tiCmd tries to convert it. If it doesn't exist, there will be no output at the corresponding outlet. In addition, there are two outlets which send the message bang, the leftmost (triggered after the argument outlets have fired) and the rightmost (triggered when time passes the right edge of the message box in the timeline track). |
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TimeLagAccumulator
| Patch |
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A replica of the San Francisco Tape Music Center "Time Lag Accumulator"
A replica of the San Francisco Tape Music Center "Time Lag Accumulator," hereafter referred to as TLA, because of the inherent joke, and because of impending repetitive stress issues. The TLA was originally a long tape delay scheme used by Terry Riley, Pauline Oliveros and others at the San Francisco Tape Music Center. It involved a couple of well calibrated tape recorders, one to record onto, and the other placed some distance away for playback. This same basic scheme was later utilized by Fripp & Eno, and forms the basis of "Frippertronics." |
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timeline
| External |
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Time-based score of Max messages - sequencer
Score of timed messages for patchers and other objects |
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timeline.js
| Javascript (jsui) |
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The timeline is a graphical jsui object in a bpatcher which allows the graphical arrangement of events in time. These events can be edited with the mouse or with messages to the left inlet.
The messages are sent to a reference coll each time they a
Timeline.js works in conjunction with the "timelineBP.maxpat" bpatcher.
All operations are carried out in this bpatcher and
all timeline events are written to a coll inside the bpatcher.
The timeline does not sequence any events.
All it does is to provide a GUI which lets you create and edit events. These events are then written to a coll inside the timeline bpatcher. There's no fixed project length, you can add as many events in a time span as you wish--you just have to set the offset accordingly to see them (use the length message).
The same applies to the number of rows. They are not limited, just select the correct row offset (use the depth message).
There are currently two shortcuts:
"Backspace" will delete the selected elements
"i" will open the inspector for the selected event
Shortcuts only work if mouse is over the timeline-object!
The inspector will let you edit events. If used in conjuction with a pattrstorage, the inspector will grab a pattrstorage client list and display it in a menu. |
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tiOut
| External |
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Output values from the outlet of a parent timeline object
Send messages out of a timeline object.�tiOut accepts any message and sends it to the specified outlet of the timeline object, where 1 is the leftmost, 2 is the next one to the right, etc. up to the number of outlets in the timeline object (specified as timeline object's second argument). Note that the tiOut object only works with timeline objects that have been created inside patchers, i.e., not those that are opened directly from files or using the menu item New Timeline. |
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tl.envExp
| External |
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Envelope with linear rise and exponential decay |
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tl.jit.atodb
| Abstraction |
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Convert jitter Matrix values from linear to decibel values |
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tl.jit.dbtoa
| Abstraction |
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Convert jitter matrix values from decibel to linear values |
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tl.list.line
| External |
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Straight line as list |
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| Libraries | |
A-Chaos Lib
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='21' Sier |
library of non-linear strange attractors for max under macintosh sys, extended from Richard Dudas Chaos Collection, including the source (24 dynamic non-linear systems:: a-baker, a-clifford, a-collatz, a-duffing, a-fibonacci, a-ginger, a-henon-heilles, a-henon, a-henonf, a-henonphase, a-ikeda, a-jong, a-logistic, a-logistic1, a-lorenz, a-lorenz.e,a-lyapunov, a-navier-stokes, a-navier-stokes.e, a-rossler, a-stein, a-stein1, a-torus and a-verhulst) |
cv.jit
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='19'Jean-Marc Pelletier |
cv.jit is a collection of max/msp/jitter tools for computer vision applications. The goals of this project are to provide externals and abstractions to assist users in tasks such as image segmentation, shape and gesture recognition, motion tracking, etc. as well as to provide educational tools that outline the basics of computer vision techniques. |
Jeroen_ChaosLib
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='98'Jeroen Liebregts |
This set of objects is capable of generating an infinite amount of attractors by automatically constructing nonlinear equations. These formulas are of the type quadratic and cubic, so their highest term is to the power of two (quadratic) or three (cubic). The quadratic equations go up to four dimensions, the cubic up to three.
Example patches are included. |
p.jit.gl.tools
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='123' Pelado |
the p.jit.gl tools are designed to provide for easier learning of and experimenting with the many attributes that are available to jitter's gl objects by making them a whole lot more transparent and accessible. patches expose jitter gl object's attributes to interfaces that allow you to immediately edit and change an attribute's value. many of the parameters are attached to blines, which provide smooth changes while rendering, and all settings can be saved and recalled as presets using the pattrs that are embedded in the patches. |
SFA Max/MSP Library
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debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='172'Stefano Fasciani |
The SFA-MaxLib is a collection of Max/MSP objects developed in the context of the VCI4DMI. It includes functions and utilities in the form of FTM externals, FTM abstractions and Max abstractions. FTM is a shared library for Max/MSP developed by IRCAM, which provides a small and simple real-time object system and a set of optimized services to be used within Max/MSP externals.
List of FTM Externals: sfa.eig - eigenvalues; sfa.inputcombinations - combination generator; sfa.levinson - levinson-durbin recursion; sfa.lpc2cep - lpc to cepstra conversion; sfa.rastafilt - rasta filter; sfa.rmd - relative mean difference; sfa.roots - polynomial roots;
List of Abstractions: sfa.bark.maxpat - energy of the Bark bands from time domain frame;sfa.bark2hz_vect.maxpat - Herts to Bark conversion;sfa.barkspect.maxpat - energy of the Bark bands from spectrum; sfa.ceil.maxpat - ceil function; sfa.featfluxgate.maxpat - gated distance on stream of feature vectors; sfa.fft2barkmx.maxpat - utility sub-abstraction of sfa.bark; sfa.fft2barkmxN.maxpat - utility sub-abstraction of sfa.barkspect; sfa.hynek_eq_coeff.maxpat - hynek equalization coefficients; sfa.hz2bark.maxpat - Hertz to Bark conversion; sfa.hz2bark_vect.maxpat - Hertz to Bark conversion for vectors; sfa.hz2mel.maxpat - Hertz to Mel conversion; sfa.idft_real_coeff.maxpat - utility sub-abstraction of sfa.rasta-plp; sfa.maxminmem.maxpat - minimum and maximum of a stream of data; sfa.mfcc.maxpat - MFCC coefficients; sfa.modalphafilter.maxpat - 1st order IIR lowpass on a stream of vectors; sfa.nonlinfeqscale.maxpat - linear spectrum to Bark or Mel scale conversion; sfa.rasta-plp.maxpat - PLP and RASTA-PLP coefficients; sfa.spectmoments.maxpat - 4 spectral moments (centroid, deviation, skewness, kurtosis); sfa.3spectmoments+flatness.maxpat - 3 spectral moments (centroid, deviation, skewness) and the spectral flatness; sfa.spectralflux.maxpat - spectral flux on stream of spectrum vectors; sfa.spectralfluxgate.maxpat - gated spectral flux on stream of spectrum vectors; sfa.std.maxpat - standard deviation; sfa.win_to_fft_size.maxpat - smaller FFT size given frame size; sfa.GCemulator.maxpat – 3D gestural controller emulator; |
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