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MMDB-8 J. Teuhola 2012184 8. Audio databases About digital audio: Advent of digital audio CD in 1983. Order of magnitude improvement in overall sound quality.

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Presentation on theme: "MMDB-8 J. Teuhola 2012184 8. Audio databases About digital audio: Advent of digital audio CD in 1983. Order of magnitude improvement in overall sound quality."— Presentation transcript:

1 MMDB-8 J. Teuhola 2012184 8. Audio databases About digital audio: Advent of digital audio CD in 1983. Order of magnitude improvement in overall sound quality and signal-to-noise ratio over the best analog systems. Wide bandwidth required in on-line transmission. Converting an analog signal into digital form: Linear Pulse Code Modulation (PCM) Two-stage process: (a) Sampling: Observing the signal amplitude at certain time intervals; typical sampling frequencies: 16-48 kHz (b) Quantization: discrete scale for observed amplitudes, typically 16 bits per sample  65536 possible values. Audio-CD: 16-bit samples at 44.1 kHz rate, with two (stereo) channels: 2 x 16 x 44 100  1.4 Mbits per second

2 MMDB-8 J. Teuhola 2012185 Illustration of audio concepts amplitude time wavelength sampling interval

3 MMDB-8 J. Teuhola 2012186 Audio compression techniques (a) Delta modulation:  Extremely simple, used sometimes for speech coding  1-bit quantizer for amplitude differences: 0 = - , 1=+  (b) Adaptive Differential Pulse Code Modulation (ADPCM)  The next sample value is predicted on the basis of recent history; the prediction error is quantized and coded  Used mainly for speech coding, e.g. ITU-T G.726 (c) Subband coding Division of the signal into frequency components (bands) Encoding of bands separately E.g. ITU-T recommendation G.722: High-quality speech at 64 Kbits per second

4 MMDB-8 J. Teuhola 2012187 MPEG audio Sampling rates 32, 44.1 or 48 kHz (or half of these); samples processed in frames; 384/1152 samples per frame. Subband coding with a bank of 32 filters, each with a bandwidth of 1/64 of the sampling frequency. Samples coded with variable quantization steps. Psychoacoustics uses the masking properties of the human ear Compressed bitrates range from 32 to 224 Kbits per second. Compression factor from 2.7 to 24. MPEG Layer I: best for bitrates > 128 Kbits per sec (per channel). MPEG Layer II: best for bitrates  128 Kbits per sec (per channel). MPEG Layer III: best for bitrates  64 Kbits per sec (per channel) = MP3 music in the Internet (compression  12:1). Discrete Cosine Transform (DCT) on subband signals.

5 MMDB-8 J. Teuhola 2012188 Audio data retrieval (a) Based on metadata Additional attributes can be attached to voice data (such as to images and video), e.g. speaker, date, duration, composer, orchestra, instrument,... Attributes can be connected to the whole audio sequence or some parts of it (e.g. parts of a symphony). General document retrieval techniques usually apply.

6 MMDB-8 J. Teuhola 2012189 Audio data retrieval (cont.) (b) Speech recognition: Proximity search of the waveform; feature extraction e.g. from coefficients of DCT-transformed signal. Some fuzzyness involved Simple application:  Giving voice commands to a user interface. Advanced application:  Parsing of spoken sentences and conversion e.g. to database queries  Can be coupled with natural language understanding techniques.  Usually based on a predefined set of patterns and associated phonetic rules.

7 MMDB-8 J. Teuhola 2012190 Audio data retrieval (cont.) (c) Speaker recognition: Application: security systems. Sensitive to the physical condition (e.g. flu) of the speaker. Variations:  Text-dependent recognition (simpler): Restricted set of possible words/sentences Comparison of digital waveforms.  Text-independent recognition (more difficult): Based e.g. on voice pitch recognition. More elaborate sentences from particular users must be stored, and complex verification algorithms are run against the spoken samples.

8 MMDB-8 J. Teuhola 2012191 Audio data retrieval (cont.) (d) Recognition and retrieval of songs (recorded music) Query input alternatives: Query-by-humming: Succeeds for clearly distinguishable melodies (or themes), in spite of small pitch errors. Similarity measure uses some kind of edit distance Tapping the tempo: Complements humming/singing Playing a (virtual) keyboard Output: Ranked list of candidate songs Example search engine: Musipedia (http://www.musipedia.org/)

9 MMDB-8 J. Teuhola 2012192 Encoding and retrieval of (synthetic) music Music encoding:  For digital electronic instruments (no singing!)  Timing of note-on/note-off events,  Control of instrument and playback parameters (pitch, loudness)  Can be played with a syntherizer Encoding formats:  MIDI (Musical Instrument Digital Interface)  MPEG-4 SA (Structured Audio) Music XML (Notes represented using structured markup) Retrieval criteria:  Notes: Generalization of string matching (but: polyphony!)  Time-dependent parameters: Instruments, tempo, volume,...  Textual metadata: Title, composer, artist, genre, date,...

10 MMDB-8 J. Teuhola 2012193 Indexing of audio data Indexing of metadata (external attributes):  As with any other documents: Inverted indexes, multi- attribute indexes, signature files, etc. Indexing of audio signal:  First split into segments (= frames, windows). Segmentation requires some rules, e.g. ‘quiet’ zones are possibly good split points.  Transformation (e.g. DCT) of each segment into features  A multidimensional index is built from groups of the features (e.g. main DCT coefficients).  Proximity queries (nearest neighbor, or k nearest neighbors of the query sample) should be supported by the index.


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