![]() ![]() The release burst of the (which I pronounced as released for the purposes of this spectrogram) Right at the end of the vowel, you can see F2 and F3 start to approach one another in a formant transition pattern (often called the "velar pinch") that usually marks the onset phase of a velar consonant. The aspiration (delay of the onset of voicing for ) The above spectrogram is of the English word attack. The period of aspiration (which only some voiceless plosives have) is much longer than the very short release burst (which all released plosives have). NB: Aspiration is not the same as the release burst. (Recall that the tongue body is in position for the following vowel and that aspiration is just a delay in the onset of voicing.) The formant transitions (if you can see them) look like the formants have been distorted away from the frequencies they have during most of the vowel.Īspiration will look like a period of between the blank gap and the vowel - specifically, a voiceless version of the following vowel. On a spectrogram, the release burst looks like a very, very thin fricative. To tell the difference between plosives, listeners rely on the release burst and on formant transitions. (But very often you won't see anything there, either because the voicing got lost in the background noise or because the recording or computer equipment cut off frequencies that low.) The quiet vocal fold vibrations in a voiced plosive will sometimes appear as a faint band along the bottom of the spectrogram at the frequency of f0. On a spectrogram, this will appear as a white blank. The medial phase of a voiceless plosive is complete silence. It will have a lot of random noise that looks like static, but through the static you can usually see the faint bands of the voiceless vowel's formants. On a spectrogram, it looks a little like a cross between a fricative and a vowel. is really a voiceless version of the preceding or following vowel. Voiced fricatives show aspects of both regular vocal fold vibrations and a randomly turbulent airstream. has a higher average frequency than does and both are higher than or. While each momentary burst of energy occurs at a random frequency, there are tendencies in which frequencies the random bursts cluster around. The result sounds much like static noise, and on a spectrogram it looks like the kind of static noise you might see on a TV screen. The turbulent airstream of fricatives creates a chaotic mix of random frequencies, each lasting for a very brief time. In, F2 and F3 also often appear merged together in a single wide band.) Fricativesįricatives are easy. In, and sometimes other back vowels, F1 and F2 are often so close together that they appear as a single wide formant band. (There are some especially common difficulties in identifying formants. But the existence of formants is usually obvious enough that you can at least be sure you're looking at a vowel. unless you already have a good idea of where to expect them. You can't always tell reliably which formant you're looking at - F1, F2, F3, etc. In dipthongs, you can see the formants change frequency as the tongue body moves through the mouth: Vowels usually have very clearly defined formant bars, as in the following: Let's look at how various kinds of sounds appear on a spectrogram. Identifying sounds in spectrograms Identifying sounds in spectrograms ![]()
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