Impro-Visor

Impro-Visor is an educational tool for creating and playing a lead sheet, with a particular orientation toward representing jazz solos.

Impro-Visor
Developer(s)Robert M. (Bob) Keller and others at Harvey Mudd College and elsewhere
Initial release2006 March
Stable release
10.2 / August 1, 2019 (2019-08-01)
Repository
Operating systemWindows, macOS, Linux
TypeScorewriter
LicenseGPLv2
Websitecs.hmc.edu/~keller/jazz/improvisor/

Improvisation Advisor

The philosophy of Impro-Visor is to provide a tool to help musicians construct jazz solos over chord progressions. It includes a database capability for creating, saving, and recalling licks, as well as a lick generation capability based on a user-modifiable grammar. More recent versions of Impro-Visor include auto-generated playback accompaniment in various styles, and a style extraction (from MIDI) capability. Most musical knowledge, including lick generation, database, lead sheets, styles, and other information, is represented as text files, permitting the tool to be customized.

Leadsheet Notation

Rendering Leadsheet Notation

Impro-Visor saves lead sheets in a textual notation,[1] and lead sheets may be created from that notation as well as by point-and-click. The notation was designed to be friendly to the jazz musician, by resembling directly what appears on the lead sheet staff. For example, the lead sheet fragment to the right, similar to that in article lead sheet, can be created by the following text:

C C7 | F |
c+2 bb2 bb8 a8 f2.

The reading of this text is: Chords C and C7 equally spaced in the first bar, and F in the second bar. A melody of c (the + means an octave above middle C, the 2 means a half-note), bb2, meaning a B-flat half-note, bb8, meaning a B-flat eighth-note, f2., meaning an F dotted half-note. Other meta-data can be supplied, such as for style specification, but is not required.

Tone Categorization

Using colors for tone categories

Impro-Visor categorizes tones that can be played over any chord into one of four categories.[2] This serves two purposes: (i) as visual feedback to the user, where each category is rendered as a different color, and (ii) as a basis for lick generation. The categories are:

  • Chord tones: tones that are in the chord, and which are thus the most consonant with it (shown as black on the right)
  • Color tones: tones that are not in the chord, but which are also consonant with it (shown as green on the right)
  • Approach tones: tones that are neither of the above, but which approach one of the above chromatically (shown as blue on the right)
  • Other tones: none of the above (shown as red on the right)

The idea is that, aided by visual clues, the musician can learn to appreciate the degree to which a melody will be sonorous over a chord progression prior to hearing it.

Grammatical Lick Generation

Lick generated using grammar to produce notes

Categories of notes discussed above are one of the key ingredients in automating the generation of melodies, which can be used by the musician in constructing solos. The other key ingredient is a context-free grammar having terminal symbols for each of the four categories, along with a few other terminal symbols for convenience. The grammar defines ways in which the melody space can be filled probabilistically by tones of various durations. By associating a probability with each grammar rule, the distribution of generated melodies can be controlled, for example to create melodies that are simple or complex, relatively consonant or dissonant, etc. The user indicates the chord progression, and the grammar drives the melody generation over that progression.[3]

The figure at the right demonstrates an example generated lick. This particular grammar is  constructed so as not to produce any discordant notes (notes in the "other" category above), thus no red notes appear in the figure.

Grammar Learning

Version 4 added a feature for learning a grammar from a corpus of transcribed solos.[4][5] The learned grammar loosely approximates the playing style of the soloist by creating abstract melodies from the solos, which can be re-instantiated into similar melodies through the grammar. Connections between learned abstract melodic fragments are represented as a Markov chain, which is encoded into the stochastic context-free grammar.

Auto-Accompaniment

Impro-Visor automatically creates accompaniment, such as piano, bass, and drums, from the chord sequence on a leadsheet (a capability similar to, but currently not as full-featured as that of Band-in-a-Box). The style of accompaniment is derived from a set of pattern specifications using a textual notation similar to that for melodies.[6] For example, a ride cymbal pattern common to swing jazz would be notated as

x4 x8 x8 x4 x8 x8

with x4 signifying a quarter-note hit and x8 an eighth-note hit. The swung note aspect, wherein eighth-notes on the beat get approximately twice the value of the beat, is rendered automatically by a numeric swing parameter, such as .67, which indicates that the beat is divided as .67 + .33 = 1. A similar pattern notation is used for chord comping and bassline patterns. In the latter type of pattern, a note category coding scheme similar to that for the grammatical notation is used to provide probabilistic creation of basslines.

Roadmaps and Analysis of Chord Progressions

Roadmap produced by Impro-Visor

Impro-Visor analyzes jazz lead sheets to produce a roadmap of the tune. A roadmap is a sequence of bricks that represent harmonic idioms.[7] The nomenclature for this approach is derived from that of Conrad Cork[8] and John Elliott.[9]

See also

References

  1. Keller, Robert M. (5 October 2005). "Impro-Visor Leadsheet Notation" (PDF). Harvey Mudd College. p. 10. Retrieved 5 January 2016.
  2. Rober M., Keller; David Morrison; Stephen Jones; Belinda Thom; Aaron Wolin. "A Computational Framework Enhancing Jazz Creativity" (PDF). Harvey Mudd College. p. 6. Retrieved 5 January 2016.
  3. Keller, Rober M.; David R. Morrison (11 July 2007). "A Grammatical Approach to Automatic Improvisation" (PDF). 4th Sound and Music Computing Conference. p. 8. Retrieved 5 January 2016.
  4. Gillick, Jon; Kevin Tang; Robert M. Keller (23 July 2009). "Learning Jazz Grammars" (PDF). 6th Sound and Music Computing Conference. p. 6. Retrieved 5 January 2016.
  5. Gillick, Jon; Kevin Tang; Robert M. Keller (Fall 2010). "Machine Learning of Jazz Grammars". Computer Music Journal. 34 (3): 56–66. doi:10.1162/COMJ_a_00006. Retrieved 5 January 2016.
  6. Keller, Robert M.; Martin Hunt; Stephen Jones; David Morrison; Aaron Wolin; Steven Gomez (2007). "Blues for Gary: Design Abstractions for a Jazz Improvisation Assistant" (PDF). Electronic Notes in Theoretical Computer Science (193): 47–60. doi:10.1016/j.entcs.2007.10.007. Retrieved 5 January 2016.
  7. Keller, Robert M.; Alexandra Schofield; August Toman-Yih; Zachary Merritt; John Elliott (Winter 2012). "Automating the Explanation of Jazz Chord Progressions Using Idiomatic Analysis". Computer Music Journal. 37 (4): 54–69. doi:10.1162/COMJ_a_00201. Retrieved 5 January 2016.
  8. Cork, Conrad (2008). The New Guide to Harmony with Lego® Bricks.
  9. Elliot, John A. (2009). Insights in Jazz: An Inside View of Jazz Standard Chord Progressions. London: Jazzwise Publications. p. 2. ISBN 9780956403117.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.