Objects			page : 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35
jit.print	External		Print a matrix as text in the Max window The jit.print object prints matrix values for display in the Max window. Due to limitations of the Max window, it works best for smaller matrices. To see larger matrices, see the jit.fprint, which works similarly, but prints to a file. Delimiters may be set for plane, column and row. Dimensions are delimited by , where N = the current dimension.
jit.repos	External		Reposition spatially The jit.repos object performs cell positioning on an input matrix received in its left inlet using the input from a second input matrix received in its right Inlet as a spatial map. The spatial map should be a 2 plane matrix, where plane 0 specifies the x offset and plane 1 specifies the y offset. You can do Fractional repositioning by setting the interpbits attribute to a non-zero value -- the spatial map values are considered to be fixed point values with a fractional component of interpbits.
jit.rgb2luma	External		Convert RGB to monochrome (luminance) The jit.rgb2luma object converts a 4-plane char ARGB (alpha, red, green, blue) matrix into a 1-plane char monochrome matrix containing the luminosity of the original matrix using the equation L = (.299 * R value) + (.587 * G value) + (.114 * B value).
jit.roy	External		Convert image to halftone image The jit.roy object is a halftone screen emulator. It takes an input matrix and splits it into a grid. Each element in the grid is then replaced by regions of a second matrix based on the mean value of each slot in the grid. The second matrix (which defines the halftone screen) is a series of submatrices set next to one another along a horizontal axis. These matrices replace regions of the first matrix in ascending order.
jit.rubix	External		Reorder grid of rectangles The jit.rubix object segments a matrix into a grid of rectangular cells. The resulting cells can reordered, flipped both horizontally and vertically, frozen, and filled with a single color value derived from a cell in the grid area (monochromatic).
jit.scalebias	External		Multply and add The jit.scalebias object scales the values of a 4 plane input matrix of type char (ARGB) and adds to an offset value (bias).
jit.shade	External		Map-based crossfader The jit.shade performs a linear crossfade between corresponding cells in two input matrices at a rate determined by the values of the cells of a third matrix (the "map"). The rate of the crossfade is calculated in terms of frames, rather than units of time.
jit.spill	External		Unroll a matrix into a list The jit.spill object outputs matrix values as a Max list, starting from a particular offset. The object will only wrap around two dimensions.
jit.sprinkle	External		Introduce spatial noise The jit.sprinkle object uses a specified probability to determine the chance that a given matrix cell will be displaced by a random amount along the horizontal or vertical axes. The result is a noisy "cloud" of data surrounding the original cell values.
jit.streak	External		Probability lines The jit.streak object uses a specified probability to determine the chance that a given matrix cell's value will be extended to subsequent cells (with an optional scaling factor). The result is a streaky good time.
jit.tiffany	External		Arbitrary rectangular resampling The jit.tiffany object performs an arbitrary rectangular resampling of a matrix. Thexrange and yrange values represent a percentage of the total matrix size, and are used as an upward limit on facet sizes when jit.tiffany assigns them randomly. The jit.tiffanyobject will generate random values across the x, y or x and y (respectively) axes, limited by the xrange and yrange attributes unless you explicitly specify values using the x, y, or xy messages. Values you do not specify will be randomly generated
jit.turtle	External		2-d turtle graphics interpreter The jit.turtle object emulates simple LOGO-style graphics. It interprets single char values in its inlet as ASCII letters that describe turtle graphics commands. A valid ASCII input will generate appropriate drawing commands for use with either the Max lcd object or the jit.lcd object
jit.wake	External		Feedback with convolution stage The jit.wake object performs video feedback with a convolution stage. The feedback, feed forward, gain, and convolution kernel values down, left, right, and up) for red, green, and blue planes are all separately controllable. Additional controls for feedback, feed forward, and gain for all colors considered together, as well as convolution kernel value control for all colors (upper, lower, left, and right).
jit.wake	External		Feedback with convolution stage The jit.wake object performs video feedback with a convolution stage. The feedback, feed forward, gain, and convolution kernel values down, left, right, and up) for red, green, and blue planes are all separately controllable. Additional controls for feedback, feed forward, and gain for all colors considered together, as well as convolution kernel value control for all colors (upper, lower, left, and right).
jit.xfade	External		Crossfade between 2 matrices The jit.xfade object crossfades between two matrices. A crossfade value of 0 results in output values equivalent to the left input values, while a crossfade value of 1 results in output values equivalent to the right input matrix.
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Libraries
BulkStore	debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='62'Tom Mays	bulk storage memory device for all values (any message)
FuzzyLib	debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='139'Alain Bonardi Isis Truck	When manipulating human knowledge such as perception, feelings, appreciation, veracity of facts, etc., the classical logic that recognize only two truth degrees (true or false) is not always the most suitable. To solve this problem, more than two degrees are considered in the non-classical logics. The fuzzy logic is one of these logics. In this logic, facts are represented through membership functions: when the membership value is equal to 1 the fact is exactly true; when it is equal to 0 the fact is exactly false; in between there is an uncertainty about the veracity of the fact. These membership functions are called "fuzzy subsets". They can be of different shapes: gaussian, trapezoidal, triangular, etc. Thus the aim of the fuzzy logic is to propose a theoretical framework for the manipulation - representation and reasoning - of such facts. The Fuzzy Lib library implements all the tools that are necessary to handle this manipulation: representation of a fuzzy subset (among them are the fuzzification, defuzzification and partitioning), reasoning process (generalized modus ponens, fuzzy implications, t-norms, t-conorms, etc.). This version 1 of the Fuzzy Lib enables to implement fuzzification, uncertain reasoning and defuzzification for any number of data in the framework of Max/MSP environment.
Litter Power Pro Package	debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='54'Peter Castine	The Litter Power package consists of over 60 external objects, including a number of new MSP noise sources, externals that produce values from a wide variety of random number distributions, and externals for mutation and cross-synthesis.
p.jit.gl.tools	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.
Panaiotis Objects	debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='122' Panaiotis	The Mac version is UB. These Max objects have been enhanced since the documentation to the left was written. Help files for the objects provide information on enhancements. The matrix object has been substantially upgraded. It now combines features of unpack, spray, funnel, append, and prepend into one object. This makes a great object to place between controllers and jit objects because it acts like a multi-prepend. There are new configuration commands and enhancements to the old: even, odd, mod,and range, among others). Most commands can be applied to inlets of outlets. There is also a mute function that adds another layer of control. Matrixctrl support has been enhanced. See the help file for full details and examples. Most other objects now fully support floats. RCer and autocount will count in float values, not just integers. Notegen16 is a 16 channel version of its predecessor: notegen. It is more generalized and much more efficient.
SFA Max/MSP Library	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;
suivi	debug: SELECT prenom, nom FROM auteurs RIGHT JOIN auteur_libraries USING (id_auteur) WHERE auteur_libraries.id_library='88' Ircam	Two externals performing score following on soloist performances using Hidden Markov Models (HMM) Suivi is based on FTM and requires the shared library FTMlib for Max/MSP. Both externals use an FTM track object - a sequence of time-tagged FTM values - to store the score of the soloist performance to be followed. Notes, trills and other elements of the score are represented by FTM score objects (FTM scoob class). For the moment, scores can be imported from standard MIDI files only. An editor for the FTM track class, which will also provide a graphical control interface for the score follower is under development as well as the import of MusicXML files. The suivi object set is distributed within the IRCAM Forum.