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Liverpool University. The Department. Centre for Cognitive Neuroscience Department of Psychology Liverpool University Overall Aim Understanding Human Information Processing. Expertise. Auditory Scene Analysis (ASA) Perception experiments Modelling Speech Perception
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The Department • Centre for Cognitive NeuroscienceDepartment of PsychologyLiverpool University • Overall AimUnderstanding Human Information Processing
Expertise • Auditory Scene Analysis (ASA) • Perception experiments • Modelling • Speech Perception • Audio-Visual Integration • Models of AV information fusion • Applying these models to ASA
Work at Liverpool Task 1.3, active/passive speech perception. Research Question:Do human listeners actively predict the time course of background noise to aid speech recognition? Current state: Perceptual evidence for ‘predictive scene analysis’ : Elvira Perez will explain all Planned work: Database of environmental noise to test computational models
Work at Liverpool Task 1.4 Envelope Information & Binaural Proc Research Question: What features do listeners use to track a target speaker in the presence of competing signals? Patti Adank (Aug.03-July.04) Current State: Tested the hypothesis that ‘jitter’ is a stream segregation or stream formation cue: Tech report finalised in July 04
Work at Liverpool Task 2.2 Reliability of auditory cues in multi-cue scenarios Research Question:How are cues perceptually integrated? Combination of experimentation and modelling Current state: Experimental data and models on audio-visual motion signal integration (non Hoarse) Ongoing work: MLE models for speech feature integration. Elvira Planned work: Collaboration with Patras (John Worley) on location and pitch segregation cue integration
Work at Liverpool Task 4.1: Informing speech recognitionResearch Question:How to apply data derived from perception experiments to machine learning? Current State:Just starting to ‘predict’ environmental noises (using Aurora noises) Recording database of natural scenes for analysis and modelling. (with Sheffield)
Environmental Noise • Two-pronged approach • Elvira: is perceptual evidence for active noise modelling in listeners • Georg (+ Sheffield): noise modelling based on database
Baseline Data • Typical noise databases not very representative • Size severely limited (e.g. Aurora) • Unrealistsic scenarios (fighter jets, foundries) • Database of environmental noise • Transport noises: A320-200, ICE, Saab 9-3, • Social Places: Departure lounges, Hotel Lobby, Pub • Private Journeys: urban walk, country walk • Buildings: offices, corridors • … • Aim is to have about 10-20 mins of representative data for typical situations.
Recordings • Soundman OKMII binaural microphones • Sony D3 DAT recorder • 48kHz stereo recordings • Digital transfer to PC mics
Analysis • Previous work • Auditory filterbank (linear, Mel-Scale, 32 ch.) • Linear prediction • Within channels • Across channels • Planned work • Aud filterbank • Non-linear prediction using Nnets
Using Envelope Informationfor ASA (Patti Adank) • Background • Brungard & Darwin (resource allocation task?)Two simultaneous sentences: track one • Segregation benefits from • Pitch differences • Speaker differences • Key question: operational definition of speaker characteristics
Speaker characteristics • Vocal tract shape • Difficult to quantify / computationally extract • Speaking style (intonation, stress, accent…) • Difficult to extract measures for very short segments • Voice characteristics • F0 – of course… • Shimmer (amp modulation) • Jitter (roughness - random GCI variation) • Breathiness (open quotient duing voiced speech) • All relatively easy to extract computationally • All relatively easy to control in speech re-synthesis
No one choice: Jitter • Dan Ellis • Computational model is segregation by glottal closure instance • Model groups coincident energy in auditory filterbank • Could ‘Jitter’ be useful for segregation?
Jitter as a primary segregation cue • Double vowel experiment: • 5 synthetic vowels (Assmann & Summerfield) • Synthesized with range of • 5 pitch levels • 5 jitter levels • Results • Pitch difference aids segregation • Jitter difference does not
70 65 60 Mean +- 1 SE percent 55 50 45 0.5% 1% 2% 4% baseline (0%) % Jitter
Jitter analogous to location cues • Location cues not primary segregation cues • Segregate on pitch first, then • Use location cues for stream formation • Experiment • Brungard, Darwin (e.g. 2001) Task, E.g. “Ready Tiger go to White One now”, And “Ready Arrow go to Red Four now”, but • Speech resynthesized using Praat • Same speaker, different sentences • Jitter does not aid stream formation
Informing Speech Recognition • Jitter not no.1 candidate for informing speech recognition…
Task 2.2 Reliability of auditory cues in multi-cue scenarios. • Ernst & Banks (Nature 2002) • Maximum likelihood estimation good model for visual/somatosensory cue integration • Adapted this for AV integration: mouse catching experiment: MLE good modelHofbauer et al., JPP: HPP 2004 • Want to look at speech cue integration in collaboration with Sheffield
Hypothesis • If listeners organise formants by continuity, then • the /o/ should lead to /m/ , while • the /e/ should lead to /n/, with the secondformant of the nasal remaining unassigned • if proximity is a cue then there should bea changeover at around 1400 Hz 2700 2000 800 375 200ms 100
F time Formants as a representation? If sequential grouping of formants explains the perceptual change from /m/ to /n/ for high vowel F2s. Then transitions should ‘undo’ this change.
1.0 0.8 0.6 heard as /em/ 0.4 0.2 0.0 0 5 10 15 20 transition duration (ms) Transitions in /vm/ syllables • Synthetic /v-m/ segments as before, but 0, 2.5, 5, 10, 20ms formant transitions • 7 fluent German speakers, 200 trials each • Experimental results fit prediction
Transitions ?? • ‘Format transitions’ of 5 ms have an effect • Synthetic speech was synthesized at 100 Hz • formant transitions: half glottal period ?? • Confirmed that transition has to coincide with energetic bit of glottal period • Do subjects use a ‘transition’ or just energy in the appropriate band (1-2 kHz) ?
Formant transitions? • Take /em/ stimulus without transitions (heard as /en/) • add a chirp in place of F2 transition (0-,5,10,20,40ms) • down chirp is FM sinusoid 2kHz-1kHz • control is FM sinusoid 1kHz-2kHz
Model prediction • ASA: Chirp should be segregated • listeners should hear ‘vowel-nasal’ plus chirp • listeners should find to difficult to report ‘time of chirp’
1.0 0.8 0.6 p(/m/) 0.4 0.2 0.0 0 10 20 30 40 DOWN chirp duration (ms) Down Chirp • 7 listeners 200 trialseach. • Result: • chirp is perceived by listeners • and integrated into percept/en/ is heard as /em/
What does it all mean • Subjects • Hear /em/ when the chirp is added (any chirp!) • Hear the chirp as a separate sound • Can identify direction of chirp • Chirps are able to replace formant • Spectral and fine time structure different • Up-direction inconsistent with expected F2
Multiresolution scene analysis • Speech recognition does not require detail • Scene analysis does…
MLE framework ASA says: Ignore thisbit • Propose to testMLE model forASA cue integration • Cue integration as weighted sum () of component probability F time
F time Hypothetical Example F F time time Labial transition p(m) = 0.8 = 0.7 Formant structure p(m) = 0.7 = 0.3 velar transition p(n) = 0.8 = 0.7 Formant structure p(m) = 0.7 = 0.3 unknown transition p(n/m) = 0 = 0.0 Formant structure p(m) = 0.7 = 1.0 /m/ /n/ /m/
F F F time time time MLE experiment (Elvira)
Taking it further (back) • Transition cues • Prior prob speech high non-speech low • Localisationcues is low
What does it all mean • Duplex Perception is • Nothing special • Entirely consistent with a probablistic scene analysis viewpoint • Could imagine a fairly high impact publication on this topic • Training activity on ‘Data fusion’?
Where to go from here • Would like to collaborate on principled testing of these (and related) ideas • Sheffield ?? IDIAP ?? • Is this any different from missing data recognition? • Bochum ?? • Want to ‘warm up’ duplex perception? • Most useful: a hands-on modeller
EEG / MEG Study • We argue that • Scene analysis informs speech perception • Therefore would expect non-speech signals to be processed/evaluated before speech is recognised • EEG / MEG data should show • Differential processing of speech / non-speech signals • Perhaps show an effect of the chirps on the latency of speech driven auditory evoked potential (field) • We have • A really neat stimulus • Emen signals can be listened to as speechnon-speech signal • Non-speech changes speech identity
(very!) Preliminary data • Four conditions • /em/ with 20 ms formant transitions • /em/ no formant transitions (en percept) • /em/ no formant transition + 20 ms up chirp (em) • /em/ no formant transition + 20 ms dn chirp (em) • Two tasks • Identify /em/ s • Identify signals containing chirps • 16 channel EEG recordings 200 stim each
Predictions • If ‘speech is special’ then should see significant task dependent differences • May also see significant differences between stimuli leading to same percept • Effect of chirp might delay speech recognition? • Here we go:
T7 T8 non-speech RHS LHS Speech
TP7 TP8 non-speech RHS Speech LHS
F1 F2 non-speech Speech
O1 O2 (control…) No evidencefor differences In early (sensory) procesing
EEG Conclusions • (very!) preliminary data looks very promising • Need to get more subjects • Refine paradigm (sequence currently too fast) • Would a MME study be appropriate • Would like to • Look at source localisation (MEG Helsinki, fMRI Liverpool) • Get more channels (MEG Helsinki)
