2006:Audio Music Similarity and Retrieval
- 1 Results
- 2 Introduction
- 3 Evalutron 6000 Issues
- 4 Important Dates
- 5 Runtime (Computational Resources)
- 6 Outstanding Issues
- 7 Packaging your Submission
- 8 The Evaluation Database
- 9 Evaluation Methodology
- 10 Submission Format
- 11 File Formats
- 12 Example Submission
- 13 Evaluation Background
- 14 Related Papers
- 15 Opt-in survey of Audio music similarity researchers
- 16 Moderators
Results are on Audio Music Similarity and Retrieval Results page.
As the size of digitial music collections grow, music similarity has an increasingly important role as an aid to music discovery. A music similarity system can help a music consumer find new music by finding the music that is most musically similar to specific query songs (or is nearest to songs that the consumer already likes). However, evaluating music similarity systems is inherently difficult since music similarity is a subjective characteristic. Some attempts have been made to evaluate similarity systems with some degree of success (See the #Related Papers). In general, due, to the lack of ground truth for music similarity, other evaluations such as genre and artist identification have been used as surrogates for music similarity.
This year, for the first time, we are attempting a large scale music similarity evaluation as part of MIREX. This evaluation will rely primarily on human judgement to rank the various submission. We will also collect various objective measures related to genre and artist clustering, with the hope that we will find some correlation between these objective measures and the human evaluations.
This page presents the Audio Music Similarity Evaluation, including the submission rules and formats. Additionally background information can be found here that should help explain some of the reasoning behind the approach taken in the evaluation.
- We will be soliciting contribution to two distinct tracks: Audio Music Search & Audio Cover Song
- The division between these two tracks will be emphasized in the evaluation results, although results will be directly comparable (all evaluations will be performed for both tracks).
- The intention of the Music Audio Search track is to evaluate music similarity searches (A music search engine that takes a single song as a query), not playlist generation or music recommendation.
- Any criteria may be used to implement the search although we are not really considering socio-cultural context or lyrics.
- Any models, codebooks etc. must be trained in advance. No collection specific optimisations should be used.
- Please avoid use of the [USPOP] and USCRAP collections in your training as they will form the test database. Please also avoid any other overlap with the test data that you can identify.
Evalutron 6000 Issues
Please go to the Evalutron6000 Issues page for detailed information about how the human evaluations component will be undertaken.
- Before August 14th: test and then submit algorithms, start running computations on the DB.
- Before August 21th: finish running all submissions.
- After August 21st: start human evaluations.
(See also the MIREX 2006 Main Page.)
All runs must be complete by August 21st in order to take part in the human evaluation. This means that the final submission deadline falls on August 14th at the absolute latest! No submission will be considered after this date (there will be absolutely no extensions to this deadline) and your submission must actually work by the 14th (no additional debugging time). Therefore, it is highly recommended that you submit before this date and ensure that you have run the DistanceMatrix test on the Wiki. Remember this is not a flexible deadline and you should submit long before it falls. (Announced by Kris on July 28)
Runtime (Computational Resources)
We have not really discussed runtimes this year. This year's competition database will contain ~5000 files and I suspect some systems may need quite a long while to process this. If your system is likely to take more than 36 hours to process this collection this should be clearly stated in your readme file and you should make its likely runtime known on the list now. Given these long runtimes it would also be preferable to make your run resumable, i.e. save your extracted feature files to the supplied cache dir location (or a sub-directory of it). Please include details of any directory structures to be created in the cache dir in your readme file and ensure you acknowledge any training/tuning data that you have used in the development of your submission. (Announced by Kris on July 28)
There are still a few issues that need to be resolved before this task is finalized:
- Binary relative judgements vs. Absolute - we've had much debate over this. Most researchers seem to prefer the binary relative approach, but that places an extreme burden on the evaluators.
- We are awaiting the final description of the Evalutron
Packaging your Submission
- Be sure that your submission follows the #Submission_Format outlined below.
- Be sure that your submission accepts the proper #Input_File format
- Be sure that your submission produces the proper #Output_File format, which can be tested with the DistanceMatrix test harness #Test_harness
- Be sure to follow the [Best Coding Practices for MIREX]
- Be sure to follow the MIREX 2006 Submission Instructions
- In the README file that is included with your submission, please answer the following additional questions:
- Was the submission trained or tuned?
- What was the source of the data used?
- Are you aware of any overlap between the data and either the USCRAP, USPOP or Cover song collections?
- Approximately how long will the submission take to process ~5000 wav files?
- Approximately how much scratch disk space will the submission need to store any feature/cache files?
- Submit your system via the URL located at the bottom of MIREX 2006 Submission Instructions page
Note that the information that you place in the README file is extremely important in ensuring that your submission is evaluated properly.
The Evaluation Database
The specifications of the evaluation database will be as follows:
- 22.05kHz, mono, 16bit, WAV files
- The WAV files will be decoded from 192kbit Variable-bit-rate, stereo, 44.1kHz, MP3 files, produced with the lame codec
- Will contain ~5000 tracks
- Selected from both the USPOP and USCRAP collections
- No tracks shorter than 30 seconds
- No tracks longer than 10 minutes
- A maximum of 20 tracks per artist
- A minimum of 50 tracks per labelled genre
- Will contain the ~350 songs from the IMIRSEL cover songs collections (30 distinct pieces - ~10-12 versions of each)
- Cover songs, USPOP and USCRAP files will all be handled in the exactly the same way (archival quality copy > 192k VBR MP3 > 22kHz WAV
Two distinct evaluations will be performed
- Human Evaluation
- Objective statistics derived from the distance matrix
Note that the Audio Cover Song task will be using the same framework to run the computations. However, the evaluation metholody is very different.
The primary evaluation will involve subjective judgments by human evaluators of the retrieved sets using Stephen Downie's Evalutron 6000 (Final description of the Evalutron is pending).
- Evaluator question: Given a search based on track A, which of these two tracks (B or C) is a better result. (Note, there is still some question as to whether using binary relative comparisons is a viable approach when the amount of comparisons required is considerd)
- ~40 randomly selected queries, 5 results per query, 3 sets of eyes, ~10 participating labs
- Higher number of queries preferred as IR research indicates variance is in queries
- The cover songs and songs by the same artist as the query will be filtered out of each result list to avoid colouring an evaluators judgement (a cover song or song by the same artist in a result list is likely to reduce the relative ranking of other similar but independent songs - use of songs by the same artist may allow over-fitting to affect the results)
- These numbers can change as we are extracting the full distance matrices
- It might be possible for researchers to use this data for other types of system comparisons after MIREX 2006 results have been finalized.
- Human evaluation to be designed and led by IMIRSEL
- Human evaluators will be drawn from the participating labs (and any volunteers from IMIRSEL or on the MIREX lists)
Objective Statistics derived from the distance matrix
Statistics of each distance matrix will be calculated including:
- Average % of Genre, Artist and Album matches in the top 5, 10, 20 & 50 results - Precision at 5, 10, 20 & 50
- Average % of Genre matches in the top 5, 10, 20 & 50 results after artist filtering of results
- Average % of available Genre, Artist and Album matches in the top 5, 10, 20 & 50 results - Recall at 5, 10, 20 & 50 (just normalising scores when less than 20 matches for an artist, album or genre are available in the database)
- Normalised average distance between examples of the same Genre, Artist or Album
- Always similar - Maximum # times a file was in the top 5, 10, 20 & 50 results
- % File never similar (never in a top 5, 10, 20 & 50 result list)
- % of song triplets where triangular inequality holds
- Plot of the "number of times similar curve" - plot of song number vs. number of times it appeared in a top 20 list with songs sorted according to number times it appeared in a top 20 list (to produce the curve). Systems with a sharp rise at the end of this plot have "hubs", while a long 'zero' tail shows many never similar results.
- Ratio of the average artist distance to the average genre distance
Additional Data Reported
- Runtimes - Where possible accurate runtimes will be recorded. The two call format allows separation of feature extraction/indexing runtimes from the final query runtimes.
A submission to the Audio Music Similarity and Retrieval evaluation is expected to follow the Best Coding Practices for MIREX and must conform to the following for execution:
One Call Format
The one call format is appropriate for systems that perform all phases of the evaluation (typically features extraction, and evaluation) in one step. A submission should be an executable program that takes 3 arguments:
- path/to/fileContainingListOfAudioFiles - the path to the list of audio files (seen the format below)
- path/to/cacheDir - a directory where the submission can place temporary or scratch files. Note that the contents of this directory can be retained across runs, so if, for whatever reason, the submission needs to be restarted, the submission could make use of the contents of this directory to eliminate the need for reprocessing some inputs.
- path/to/output/DistMatrix - the file where the output distance matrix should be placed. The format is described below
doAudioSim "path/to/fileContainingListOfFilesInDB" "path/to/cacheDir" "path/to/output/DistMatrix"
Two Call Format
The two call format is appropriate for systems that break their processing into two phases (typically a feature extraction phase and an evaluation phase. The submission should consist of two programs:
- doFeatureExtraction - this takes two arguments:
- path/to/fileContainingListOfAudioFiles - the path to the ldist of audio files (seen the format below)
- path/to/cacheDir - a directory where the submission can place the output of the first stage
- outputDistMatrix - this takes two arguments
- path/to/cacheDir - a directory where the first stage has placed its output.
- path/to/output/DistMatrix - the file where the output distance matrix should be placed. The format is described below.
doFeatureExtraction "path/to/fileContainingListOfFilesOfAudioFiles" "path/to/cacheDir" outputDistMatrix "path/to/cacheDir" "path/to/output/DistMatrix
Matlab will also be supported in the form of functions in the following formats:
Matlab One call format
Matlab Two call format
The input list file format will be of the form:
path/to/audio/file/000001.wav path/to/audio/file/000002.wav path/to/audio/file/000003.wav ... path/to/audio/file/00000N.wav
The only output will be a distance matrix file in the following format:
Example distance matrix 0.1 (replace this line with your system name) 1 path/to/audio/file/1.wav 2 path/to/audio/file/2.wav 3 path/to/audio/file/3.wav ... N path/to/audio/file/N.wav Q/R 1 2 3 ... N 1 0.0 1.241 0.2e-4 ... 0.4255934 2 1.241 0.000 0.6264 ... 0.2356447 3 50.2e-4 0.6264 0.0000 ... 0.3800000 ... ... ... ... ... 0.7172300 5 0.42559 0.23567 0.38 ... 0.000
The following java application loads a distance matrix in the file format above and checks it for any errors. An M2K DistanceMatrix Object is initialized from this data and written back to a file, whose name is created by appending '.copy' to the original filename. This copy can be used to visually check that all the distances were correctly interpreted. Source for the DistaceMatrix reader and representation is also enclosed.
Please report any problems to Kris West (kw at cmp dot uea dot ac dot uk).
Elias Pampalk has kindly contributed a simple example Matlab Audio Similarity (distance) calculator. This example calculates similarity based on Zero-crossing rates and outputs a DistanceMatrix in the specified format.
Please report any problems to Elias (elias dot pampalk at gmail dot com)
Numerous discussion have taken place on the AudioSim mailing list. Some of the threads are summarized here: Important threads for Audio Similarity
- Logan and Salomon (ICME 2001), A Music Similarity Function Based On Signal Analysis.
One of the first papers on this topic. Reports a small scale listening test (2 users) which rate items in a playlists as similar or not similar to the query song. In addition automatic evaluation is reported: percentage of top 5, 10, 20 most similar songs in the same genre/artist/album as query. A must read! You might also want to check out the US patent 7,031,980 that was granted April 2006 (filed October 2001).
- Aucouturier and Pachet (ISMIR 2002), Music Similarity Measures : WhatΓÇÖs the use?.
Similar in some ways to the work of Logan and Salomon. Evaluation includes percentage of retrieved songs in the same genre (for top 1, 5, 10, 20, 100 songs) and some cluster (genre) overlap measures. Excellent paper!
- Ellis, Whitman, Berenzweig, and Lawrence (ISMIR 2002), The Quest for Ground Truth in Music Similarity.
The MusicSeer survey is reported. (MusicSeer was a very clever way to get lots of users to rate artists by similarity.)
- Berenzweig, Logan, Ellis, and Whitman (ISMIR 2003), A Large-Scale Evaluation of Acoustic and Subjective Music Similarity Measures.
Artist similarity measures are evaluated based on data from All Music Guide, from a survey (musicseer.com), and from playlists and personal collections.
- Logan, Ellis, and Berenzweig (SIGIR 2003), Toward Evaluation Techniques for Music Similarity.
Evaluating artist similarity (similar to the ISMIR 2003 version).
- Pampalk, Dixon, and Widmer (DAFx 2003), On the Evaluation of Perceptual Similarity Measures for Music
An attempt was made to compare similarity measures published by different authors. Artist, album, tones, style, and genre (the last three from AMG) were used for the evaluations. The average distance between all songs vs the average distance within a group (e.g. genre) was used as quality criteria.
- Aucouturier and Pachet (JNRSAS 2004), Timbre Similarity: How high is the sky?.
Follow up to their ISMIR 2002 paper. Contains detailed results of experiments on the optimization of spectral similarity. Reports a glass ceiling. Excellent article!
- Pampalk, Flexer, and Widmer (ISMIR 2005), Improvements of Audio-based Music Similarity and Genre Classification.
The need for an artist filter (ie, not having the same artists in the test and training set) is described in this paper.
- Vignoli and Pauws (ISMIR 2005), A Music Retrieval System Based on User-Driven Similarity and its Evaluation.
User evaluation based on a playlist generation system (which partly uses audio-based similarity).
Opt-in survey of Audio music similarity researchers
In this section we would like to take a brief 'opt-in' survey of researchers actively working in this field. Please feel free to add yourself to the list (or email your details to the moderators listed above).
- Kris West (University of East Anglia, UK) - homepage publications
- Elias Pampalk (AIST, Japan) - homepage
- Paul Lamere (Sun Labs, Sun Microsystems) - Project overview
- Rebecca Fiebrink (McGill University, Montreal) - homepage