Algorithmic composition

Algorithmic composition is the technique of using algorithms to create music.

Algorithms (or, at the very least, formal sets of rules) have been used to compose music for centuries; the procedures used to plot voice-leading in Western counterpoint, for example, can often be reduced to algorithmic determinacy. The term is usually reserved, however, for the use of formal procedures to make music without human intervention, either through the introduction of chance procedures or the use of computers.

Some algorithms or data that have no immediate musical relevance are used by composers[1] as creative inspiration for their music. Algorithms such as fractals, L-systems, statistical models, and even arbitrary data (e.g. census figures, GIS coordinates, or magnetic field measurements) have been used as source materials.

Models for algorithmic composition

There is no universal method to sort different compositional algorithms into categories. One way to do this is to look at the way an algorithm takes part in the compositional process. The results of the process can then be divided into 1) music composed by computer and 2) music composed with the aid of computer. Music may be considered composed by computer when the algorithm is able to make choices of its own during the creation process.

Another way to sort compositional algorithms is to examine the results of their compositional processes. Algorithms can either 1) provide notational information (sheet music or MIDI) for other instruments or 2) provide an independent way of sound synthesis (playing the composition by itself). There are also algorithms creating both notational data and sound synthesis.

One way to categorize compositional algorithms is by their structure and the way of processing data, as seen in this model of six partly overlapping types:[2]

Translational Models

This is an approach to music synthesis that involves "translating" information from an existing non-musical medium into a new sound. The translation can either rule-based or stochastic. For example, when translating a picture into sound, a jpeg image of a horizontal line may be interpreted in sound as a constant pitch, while an upwards-slanted line may be an ascending scale. Oftentimes, the software seeks to extract concepts or metaphors from the medium, (such as height or sentiment) and apply the extracted information to generate songs using the ways music theory typically represents those concepts. Another example is the translation of text into music, which can approach composition by extracting sentiment (positive or negative) from the text using machine learning methods like sentiment analysis and represents that sentiment in terms of chord quality such as minor (sad) or major (happy) chords in the musical output generated.[3]

Mathematical models

Mathematical models are based on mathematical equations and random events. The most common way to create compositions through mathematics is stochastic processes. In stochastic models a piece of music is composed as a result of non-deterministic methods. The compositional process is only partially controlled by the composer by weighting the possibilities of random events. Prominent examples of stochastic algorithms are Markov chains and various uses of Gaussian distributions. Stochastic algorithms are often used together with other algorithms in various decision-making processes.

Music has also been composed through natural phenomena. These chaotic models create compositions from the harmonic and inharmonic phenomena of nature. For example, since the 1970s fractals have been studied also as models for algorithmic composition.

As an example of deterministic compositions through mathematical models, the On-Line Encyclopedia of Integer Sequences provides an option to play an integer sequence as 12-tone equal temperament music. (It is initially set to convert each integer to a note on an 88-key musical keyboard by computing the integer modulo 88, at a steady rhythm. Thus 123456, the natural numbers, equals half of a chromatic scale.)

Knowledge-based systems

One way to create compositions is to isolate the aesthetic code of a certain musical genre and use this code to create new similar compositions. Knowledge-based systems are based on a pre-made set of arguments that can be used to compose new works of the same style or genre. Usually this is accomplished by a set of tests or rules requiring fulfillment for the composition to be complete.[4]


Music can also be examined as a language with a distinctive grammar set. Compositions are created by first constructing a musical grammar, which is then used to create comprehensible musical pieces. Grammars often include rules for macro-level composing, for instance harmonies and rhythm, rather than single notes.

Evolutionary methods

Evolutionary methods of composing music are based on genetic algorithms.[5] The composition is being built by the means of evolutionary process. Through mutation and natural selection, different solutions evolve towards a suitable musical piece. Iterative action of the algorithm cuts out bad solutions and creates new ones from those surviving the process. The results of the process are supervised by the critic, a vital part of the algorithm controlling the quality of created compositions.

Evo-Devo approach

Evolutionary methods, combined with developmental processes, constitute the evo-devo approach for generation and optimization of complex structures. These methods have also been applied to music composition, where the musical structure is obtained by an iterative process that transform a very simple composition (made of a few notes) into a complex fully-fledged piece (be it a score, or a MIDI file).[6][7]

Systems that learn

Learning systems are programs that have no given knowledge of the genre of music they are working with. Instead, they collect the learning material by themselves from the example material supplied by the user or programmer. The material is then processed into a piece of music similar to the example material. This method of algorithmic composition is strongly linked to algorithmic modeling of style,[8] machine improvisation, and such studies as cognitive science and the study of neural networks. Assayag and Dubnov [9] proposed a variable length Markov model to learn motif and phrase continuations of different length. Marchini and Purwins [10] presented a system that learns the structure of an audio recording of a rhythmical percussion fragment using unsupervised clustering and variable length Markov chains and that synthesizes musical variations from it.

Hybrid systems

Programs based on a single algorithmic model rarely succeed in creating aesthetically satisfying results. For that reason algorithms of different type are often used together to combine the strengths and diminish the weaknesses of these algorithms. Creating hybrid systems for music composition has opened up the field of algorithmic composition and created also many brand new ways to construct compositions algorithmically. The only major problem with hybrid systems is their growing complexity and the need of resources to combine and test these algorithms.

See also


  1. Jacob, Bruce L. (December 1996). "Algorithmic Composition as a Model of Creativity". Organised Sound. Cambridge University Press. 1 (3): 157–165. doi:10.1017/S1355771896000222. Retrieved 3 January 2013.
  2. Papadopoulos, George; Wiggins, Geraint (1999). "AI Methods for Algorithmic Composition: A Survey, a Critical View and Future Prospects" (PDF). Proceedings from the AISB’99 Symposium on Musical Creativity, Edinburgh, Scotland. pp. 110–117.
  3. "Tambr Music From Literature".
  4. Brown, Silas (1997). "Algorithmic Composition and Reductionist Analysis: Can a Machine Compose?". CamNotes. Cambridge University New Music Society. Retrieved 28 October 2016.
  5. Charles Fox 2006 Genetic Hierarchical Music Structures (American Association for Artificial Intelligence)
  6. Ball, Philip (2012). "Algorithmic Rapture". Nature. 188: 456. doi:10.1038/488458a.
  7. Fernandez, JD; Vico, F (2013). "AI Methods in Algorithmic Composition: A Comprehensive Survey." (PDF). Journal of Artificial Intelligence Research. 48: 513–582. doi:10.1613/jair.3908.
  8. S. Dubnov, G. Assayag, O. Lartillot, G. Bejerano, "Using Machine-Learning Methods for Musical Style Modeling", IEEE Computers, 36 (10), pp. 73-80, Oct. 2003.
  9. G. Assayag, S. Dubnov, O. Delerue, "Guessing the Composer's Mind : Applying Universal Prediction to Musical Style", In Proceedings of International Computer Music Conference, Beijing, 1999.
  10. Marchini, Marco; Purwins, Hendrik (2011). Unsupervised Analysis and Generation of Audio Percussion Sequences. pp. 205–218. doi:10.1007/978-3-642-23126-1_14.



Further reading

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