2.1 Participants and procedure

Three native speakers of Georgian participated in the study, two female (F1 and F2) and one male (M1). Data collection was limited to the three speakers because of the Covid-19 pandemic. All three were in their twenties and living in southern California at the time of their participation. All three were in their twenties and living in southern California at the time of their participation. They were recruited via word of mouth and an announcement circulated by the Georgian Cultural and Educational Center of Southern California. Data collection was limited to the three speakers because of the Covid-19 pandemic.

Data were collected using an Electromagnetic Articulograph AG501 (Carstens Medizinelektronik GmbH). Electromagnetic articulograph (EMA) data allows us to track the movement of the tongue and lips at a millisecond level of temporal resolution. This tracking is done by affixing sensors to key points in the vocal tract. The sensors’ movement is recorded as they move through a weak electromagnetic field generated by the EMA. Participants are seated in the center of the field, so all movements of interest occur within the electromagnetic field and are recorded.

For this study, we attached sensors at three points along the midsagittal line of the tongue: one on the tongue tip (TT), one on the tongue dorsum (TD), and one on the midpoint between TT and TD, referred to as TB. This means that TB was on the anterior and TD on the posterior part of the tongue dorsum. Vertical displacement of the TT sensor was used for coronal (dental and alveolar) segments; the vertical displacement of the TB sensor for palato-alveolar segments, and the vertical displacement of the TD sensors was used for velar segments. Two sensors were attached on the lip, one on the upper and one on the lower lip. The Euclidean distance between these sensors at each timepoint was calculated during data analysis, and the resulting variable – Lip Aperture (LA) – was used for labial segments. Sensors were also attached on the upper and lower incisor for reference and jaw movement respectively, and on the bridge of the nose and behind each ear for head correction. Audio was recorded with a Shure SCM262 microphone mixer at a 16 kHz sampling rate, with a Sennheiser shotgun microphone positioned a foot away from the participant’s mouth. Kinematic data was automatically synchronized with the external audio data.

Participants read the stimuli off of a computer screen placed approximately three to four feet from the EMA. Stimuli were presented in the Georgian orthography, but we present here the IPA transcription. Georgian orthographic versions are available in the appendix.

2.2 Experimental design and stimuli

Each test word appeared first in isolation and then in a frame sentence, without the isolated word disappearing from the screen. The phrase-medial tokens were analyzed for this study. The following frames were used:

The frame sentence was changed after participant F1 in order to simplify the phonetic material immediately following the test word (i.e. removing the somewhat unwieldy four consonant onset in ‘I said’) and to bracket the test word with syllables of the form m + vowel to avoid as much gestural blending as possible.

Tables 2 and 3 show the test words used in the experiment. Along with sonority shape, we include order of place of articulation as an independent variable, since previous research has shown that this factor does affect overlap in Georgian (Chitoran et al. Reference Chitoran, Goldstein, Byrd, Gussenhoven and Warner2002). After speaker F1’s participation, the test words from Table 2 were revised and expanded to the set in Table 3 in order increase the diversity of manner combinations and remove ejectives in order for all test consonants to be pulmonic. In both tables, words in opposite corners mirror one another. For example, front-to-back sonority rises contain the same consonants as back-to-front sonority falls. Plateau clusters across order conditions are also mirrors of one another where possible.

Table 2 Test words for speaker F1. Bold marks the clusters analyzed in this study.

Table 3 Test words for speakers F2 and M1. Bold marks the clusters analyzed in this study.

These stimuli were presented in blocks that included randomized stimuli for two other parallel studies, for a total of 67 stimulus sentences per block. Each block presented a different randomization of the stimuli. Speakers F1 and F2 had eight blocks, while M1 had seven due to time constraints.

Figure 7 Timepoints labelled for each gesture.

2.3 Analyses

Collected data were post-processed; they were head-corrected and rotated relative to the occlusal plane, which was recorded by having participants bite down on a hard plastic plane designed precisely for this purpose. Then, all data were semi-automatically labelled based on velocity criteria using the custom software Mview (Mark Tiede, Haskins Laboratory).

Figure 7 shows the relevant timepoints used for the analysis. From left to right, they are: the onset of the gesture; the constriction target achievement; the constriction release; and the offset of the gesture. The figure also shows the point of maximum constriction during the closure, as well as the points of peak velocity for the formation phase (i.e. the interval between gestural onset and release) and the release phase (i.e. the interval between release and offset) of the gesture. The stretch of time between the target and the release is referred to hereafter as the constriction duration. Constriction maxima were identified using velocity minima, and all other timepoints were identified using thresholds of velocity ranges between alternating velocity extrema (i.e. between a maximum and a minimum or vice versa). Velocity threshold was set to 20 $\%$ for all cases.

For every test cluster, we calculated two distinct measures of overlap. The first quantifies what we are terming relative overlap, following Chitoran et al. (Reference Chitoran, Goldstein, Byrd, Gussenhoven and Warner2002) and Gafos et al. (Reference Gafos, Philip Hoole, Chakir Zeroual, Kühnert, D’Imperio and Vallée2010): when C2 gesture starts with respect to C1 constriction, measured as the temporal interval between the onset of C2 and the target achievement of C1 relative to the constriction duration of C1. The following equation and Figure 8 show how relative overlap was calculated, and how that measure can be visualized:

\begin{equation*}{{\left( {{C_2}Onset} \right) - \left( {{C_1}Target} \right)} \over {{C_1}Constriction\;Duration}}\end{equation*}

Figure 8 Relative overlap schematization. Solid horizontal line (blue) indicates the interval measured, dotted horizontal line (green) marks the normalizing interval.

For relative overlap, negative values indicate more overlap; C2 begins before C1 reaches its target. A value of zero means that C2 begins when C1 reaches its target, and positive values indicate that C2 begins after C1 reaches its target.

The second measure quantifies constriction duration overlap, per Hoole et al. (Reference Hoole, Pouplier, Benus, Bombien, Spreafico and Vietti2013): the overlap of the constriction duration of the two consonant gestures, as defined in the following equation and Figure 9:

\begin{equation*}{{\left( {{C_1}Release - {C_2}Target} \right)} \over {\left( {{C_2}Release - {C_1}Target} \right)}}\end{equation*}

Figure 9 Constriction duration overlap schematization. Solid horizontal line (blue) indicates the interval measured, dotted horizontal line (green) marks the normalizing interval.

For constriction duration overlap, positive values indicate overlap between the two constriction durations. A value of zero means that C2’s target and C1’s release coincide. Negative values indicate that C2 achieves its target after C1 is released. We use both constriction duration overlap and relative overlap because they measure overlap between different parts of gestures, allowing us to better approach the question of gestural timing.

Of the 442 tokens initially measured, 19 were removed from the data set due to issues with sensor tracking or participant speech error, and two outliers that were more than three standard deviations from the mean were removed as well. The final data set had 413 total observations.

Statistical analysis was done in R (R Core Team 2018) using linear mixed effects models from the lmerTest package (Kuznetsova, Brockhoff & Christensen Reference Kuznetsova, Brockhoff and Christensen2017), followed by post-hoc pairwise comparisons with Holm corrections, using the emmeans package (Lenth Reference Lenth2019). Plots were generated using the ggplot2 package (Wickham Reference Wickham2009). Model selection for both measures was done by starting with the maximal model both in terms of random and fixed effects. The maximal fixed effects structure was Sonority (with three levels: Rise, Plateau, and Fall), Order (with two levels: Front-to-Back and Back-to-Front), and their interaction. The maximal random effects structure had random slopes by Word, Speaker, and Frame Sentence. The minimal adequate random effects structure was determined using rePCA from the lme4 package (Bates et al. Reference Bates, Mächler, Bolker and Walker2015), and the minimal adequate fixed effects structure was determined using drop1 from the basic R stats package (R Core Team 2018).

To assess the variability of gestural overlap with respect to sonority shape, we calculated the standard deviation for each measure per word, per speaker, and ran linear mixed effects models on the resulting data set. We opted to use the standard deviation rather than a normed measure of variability (e.g. residual standard deviation) because the measures we used are already normalized. Model selection was done following the procedure described in the previous paragraph.

3.1 Relative overlap results

The final model for relative overlap has fixed effects of Sonority and Order, and random intercepts by Speaker, Word, and Frame Sentence. Sonority (F(2) = 17.56, p < .0001, with Falls as the baseline) and Order (F(1) = 4.45, β = −.53, SE = .25, p < .05, with Back-to-Front as the baseline) are significant in the overall model. Table 4 summarizes the fixed effects results. Each pair of sonority shapes is significantly different from one another (β = −.89, SE = .31, p < .01 for Plateau vs. Rise; β = −.99, SE = .35, p < .01 for Fall vs. Plateau; β = −1.89, SE = .35, p < .001 for Fall vs. Rise). Falls are the only sonority shape in which C2’s movement to target does overlap with C1’s constriction. In plateaus and rises, there is no overlap; C2 begins after the release of C1. This is not the pattern predicted by either hypothesis. In fact, it is an exact reversal of the prediction of H1.

Table 4 Summary of the linear mixed effects model for relative overlap, with Falls as the baseline for Sonority, and Back-to-Front as the baseline for Order. Bold indicates significant comparisons.

Back-to-front clusters (such as [t^hm] or [gd]) are less overlapped than front-to-back clusters (such as [mt^h] or [bg]). This replicates findings for stop–stop sequences in previous research on Georgian (Chitoran et al. Reference Chitoran, Goldstein, Byrd, Gussenhoven and Warner2002) and extends them to a wider range of cluster types, even those where neither consonant requires an audible release, like fricative–fricative clusters. As seen in Figure 10, this pattern occurs in all three sonority shapes.

Figure 10 Relative overlap as a function of Sonority Shape.

3.2 Constriction duration overlap results

The final model for constriction duration overlap had a fixed effect of Sonority, and random intercepts by Speaker, Word, and Frame Sentence. Table 5 summarizes this model. The only significantly different pairwise comparison is between sonority rises and sonority falls (β = .21, SE = .08, p < .05), though the fall-plateau comparison is marginally significant (p = .052). It is possible that with more data each pairwise comparison would reach significance We see (Figure 11) a trace of the same hierarchy, in the same direction, that was found in the relative overlap measure. Constriction durations overlap more in falls than in plateaus, and in plateaus more than rises. As mentioned in Section 3.1, this is not what is predicted by either hypothesis but is an exact reversal of the pattern predicted by H1 (see Figure 6 left, above). Of further interest is that the values of constriction duration overlap are negative across all sonority shapes; the uniformity suggests that this may be a language-wide timing pattern, which is consistent with the findings of Pouplier et al. (Reference Pouplier, Manfred Pastätter, Stefania Marin, Lentz and Kochetov2022).

Table 5 Summary of the linear mixed effects model for relative overlap, with Falls as the baseline for Sonority. Bold indicates significant comparisons.

Figure 11 Constriction overlap by sonority shape. The y-axis shows normalized overlap values. They are all negative, indicating constriction duration lag in all sonority shapes.

Figure 12 shows a schematization of constriction duration overlap, as in Figure 9 above, but it illustrates lag, which is representative of the reduced overlap values we actually find.

Figure 12 Constriction duration overlap schematization with lag between the constriction durations. Solid horizontal line (blue) indicates the interval measured, dotted horizontal line (green) marks the normalizing interval.

As a result of the reduced overlap between consonant gestures, intrusive vocoids sometimes emerge between them.

3.3 Vocoids

Vocoids have been reported before in research on Georgian (Goldstein et al. Reference Goldstein, Chitoran and Selkirk2007), and we find vocoids in other data collected from these same participants for a different study (Crouch et al. Reference Crouch, Katsika and Chitoran2022). For purposes of counting and measuring the duration of vocoids, we defined them as vocalizations that occurred between the release of C1 and the target achievement of C2, that have a voicing bar and a distinct formant structure. Visibility of F2 determined the onset and offset of the measured interval. Vocoids are much shorter than full vowels: the mean duration of all intrusive vocoids in the data reported in this paper is 29 ms, with a standard deviation of 12.5 ms. Their distribution also differs by sonority shape: 56 $\%$ of sonority rises produced have intrusive vocoids, as do 25 $\%$ of sonority plateaus. Only 9 $\%$ of sonority falls have intrusive vocoids, and over half of those occur in productions of the word /mdare/ ‘worthless’. Vocoids occur in words with all possible laryngeal settings for C1. However, our test words all have voiced consonants in C2 positions, so a voiced C2 could be a prerequisite for intrusive vocoids in Georgian, but the data here cannot answer that question. We do not investigate any further acoustic properties (e.g. formant structure) of the intrusive vocoids, because our experiments were not designed for this purpose. Crucially, knowledge of these properties, such as the exact quality of the vocoid, does not affect our following discussion. This is, however, a fruitful avenue for future research.

Figure 13 shows the spectrogram and sensory trajectories for /bneda/ ‘epilepsy’ as produced by speaker F2. The vocoid is delimited on the spectrogram with dotted lines. Underneath the spectrogram are (bottom to top) trajectories for lip aperture, tongue tip vertical displacement, and tongue dorsum vertical displacement, with the gestures for /b/, /n/, and /e/, respectively, marked by rectangles. The shaded box in the rectangle is the constriction. The vocoid occurs when the vocal tract is relatively open (see Catford Reference Catford1988 on open transitions) as the lips release the closure for /b/ and the tongue tip is moving towards the target for /n/. Crucially, there is no tongue dorsum gesture associated with the vocoid; it is not a planned vowel but an artifact of the vocal tract configuration at that point in time.

Figure 13 Spectrogram and articulatory trajectories for /bneda/ with vocoid between dotted lines.

3.4 Variability

Our primary hypothesis (H1) proposes that the cross-linguistic preference for sonority rises will also be reflected in Georgian in the amount of variability in the timing of each sonority shape. We specifically predict that sonority rises will be the least variable shape, sonority plateaus an intermediate case, and sonority falls the most variable.

For relative overlap (Section 3.1), there was no difference in variability between sonority shapes. For constriction duration overlap (Section 3.2), however, there was. Table 6 shows the model summary, with sonority falls as the baseline. Sonority rises were significantly less variable than sonority falls, and a post-hoc pairwise comparison with a Holm correction showed that rises were also significantly less variable than plateaus (p = .01). This suggests that in complex onsets, the timing pattern for moving from more constricted to less constricted articulatory targets (i.e. as in rises) is, as predicted, more stable than the timing patterns in falls and plateaus. Strikingly, this is the case despite the fact the sonority rises have the highest number of intrusive vocoids. This further supports the analysis of vocoids as intrusive, without a gestural target.

Table 6 Summary of the linear mixed effects model for standard deviation of constriction duration overlap, with Falls as the baseline for Sonority. Bold indicates significant comparisons.

Table 7 shows the means and standard deviations for constriction duration overlap by speaker and by sonority shape. Of note is the similarity across speakers, despite the use of different stimuli.

Table 7 Means and standard deviations (SDs) of constriction duration overlap presented by speaker (F1, F2, and M1) and by sonority shape. Asterisk marks the pilot speaker, who had a different set of test words.

4.1 Sonority and articulatory timing

Our results on gestural timing show a hierarchical effect of sonority shape. As the measure of constriction duration overlap shows, in all shapes, there is a lag between the constrictions of the two consecutive consonants in the onset. The lag is longest in rises and shortest in falls. Moreover, according to the measure of relative overlap, the movement to C2 constriction is initiated after C1 constriction is released in rises and plateaus, but during C1 constriction in falls. As an illustration of these timing relationships, the reader is referred to Figure 13, which depicts the gestures for the first syllable of /bneda/ ‘epilepsy’. The constrictions for /b/ and /n/, marked by the filled boxes on the lip aperture and tongue tip vertical displacement trajectories respectively, do not overlap. Furthermore, the movement of the tongue tip to the constriction for /n/ is not even initiated until after the /b/ constriction is released.

The detected hierarchical effect of sonority shape discussed above is reflected in the distribution of intrusive vocoids: they are most frequent in rises and least frequent in falls. Interestingly, despite having both the longest lags and the highest number of vocoids, sonority rises have the most stable timing between their C gestures, as reflected in the measure of variability of constriction duration overlap.

The observed hierarchical effect allows us to reject Hypothesis 2 (H2), which predicted that sonority plateaus would show more lag than rises or falls and that rises and falls would not differ significantly from one another. H2 proposed consonant recoverability as the sole motivation for timing patterns, and although the long lag in Georgian favors consonant recoverability, this is an across-the-board pattern, and not a case of timing modulation occurring in specific clusters to preserve consonant identity. It is likely a language-wide setting, which may have first arisen to ensure consonant recoverability in stop–stop sequences and was then phonologized and generalized to all sequences.

Hypothesis 1 (H1) did predict a hierarchical effect of sonority shape on gestural overlap. However, the observed direction of the effect – falls have the least lag, rises the most – is the opposite of what was predicted. H1 also predicted that sonority rises would present the least variable gestural overlap, and this is confirmed for the measure of constriction duration overlap (Section 3.2). These results suggest a principled relationship between sonority shape and gestural timing, but not one necessarily motivated by maximizing parallel transmission of information, as suggested in H1. Were this the case, sonority rises should have been the most overlapped because they are best suited to parallel transmission (Mattingly Reference Mattingly, Myers, Laver and Anderson1981). Further evidence that maximizing parallel transmission does not drive gestural timing in Georgian comes from the fact that consecutive C constrictions do not overlap regardless of sonority shape. This means that transmission is not parallel: the first constriction is released before the second is formed. This in turn gives rise to the overall prevalence of open transitions (Catford Reference Catford1988) in Georgian, and the tolerance for resulting vocoids can be related to the lack of phonemic schwa and of any widespread pattern of phonological vowel reduction. In a language without any of these features, we might expect less opportunity for open transitions because the resulting intrusive vocoid is more likely to be interpreted as a phonemic vowel.

Despite the prevalence of vocoids, our data show a clear difference in their occurrence depending on sonority shape (Section 3.3), which suggests that speakers time consonantal gestures differently depending on the order of constriction degree. When C2 begins after C1’s constriction is released, as is the case for all sonority rises and plateaus, the vocal tract is more open for C2’s formation. If phonation for C2 has already begun, during the movement to target, a vocoid can appear, as shown in Figure 13. The relatively earlier C2 onsets in sonority falls prevent these conditions from emerging even in the presence of a voiced C2. The question that then arises is what motivates the uneven distribution of vocoids across sonority shapes.

We argue that these differences originate in syllable-level, rather than either gesture- or segment-level concerns. Speakers plan their syllables with a single nucleus, which is a peak in the amplitude envelope. In kris, the presence of a vocoid would add sonority at around the same location as the nucleus (see Figure 14 left panel), but in rkebs the vocoid would enhance sonority closer to the left edge of the syllable, away from the nucleus, resulting in a pattern with two equally high sonority peaks, as illustrated in the right panel in Figure 14.

Figure 14 Sonority curves for /k^hris/ ‘blow-3sg.subj’ (left) and /rk^hebs/ ‘antler-pl-dat’ (right), with intrusive vocoids.

We propose that this pattern of two peaks is more likely to be misinterpreted as a disyllabic sequence. It then follows that the presence of a vocoid in a fall is perceptually more disruptive than the presence of a vocoid in a rise. If that is the case, speakers could be relying on gestural overlap to avoid open transitions and thus an additional sonority peak in falls.

4.2 Typological versus language-specific perspectives

Our hypotheses and our discussion in Section 4.1 assume that typological markedness of sonority shapes would be relevant even for speakers of a language where sonority sequencing does not play a meaningful role. A hard form of this hypothesis would be one advanced in generative grammar, that universal markedness constraints are active for all speakers of all languages (e.g. Berent, Harder & Lennertz Reference Berent, Harder and Lennertz2011). A more nuanced view would be that these patterns may be further affected by language-specific pressures, and in languages like Georgian, which have sonority plateaus and falls, the efficient production–perception balance afforded by sonority rises can be outweighed or modulated by other factors, such as the need to ensure perception of all consonants in multimorphemic CC(…) sequences.

We could also take, however, a strictly language-specific perspective. If we consider only Georgian, markedness is no longer relevant to the discussion about sonority. From the viewpoint of a Georgian speaker, there is nothing ill-formed about a syllable onset like [rb] or [lp’] or longer sequences with sonority reversals, such as [k’rb]. Rather than being sensitive to the markedness of sonority shapes or completely uniform in cluster timing, Georgian speakers are modulating timing according to a different concern. As proposed in Section 4.1, speakers plan syllables to have a peak in the amplitude envelop and control the amount of consonant gesture overlap to achieve this plan. It is possible that syllables are identified solely by the presence of a vowel and the presence of a vocoid puts syllabification at risk in specific contexts. For this reason, recoverability of the syllable as a unit is the primary factor behind consonantal overlap in Georgian. Ensuring a felicitous syllabification also works to maintain lexical recoverability, since there are minimal or near-minimal pairs such as /p^ht^hila/ ‘lock of hair’ and /p^hit^hila/ ‘wick’.

This articulatory timing control is not expected to affect the coordinative structure of the syllable, as shown for other languages discussed in Section 1.3. This means there should not be phasing differences between the components of the syllable in Georgian, a hypothesis that is tested and supported in Crouch Reference Crouch2022 and Crouch et al. Reference Crouch, Katsika and Chitoran2022. This work presents evidence that C gestures in Georgian onsets are timed sequentially with each other. This coordination, although non-conforming to the cross-linguistic expectation for the c-center effect, is systematic, holding regardless of sonority shape, and possibly originated in the morphological system of Georgian (see Crouch Reference Crouch2022 for further argumentation). The absence of the c-center effect (Crouch Reference Crouch2022, Crouch et al. Reference Crouch, Katsika and Chitoran2022) and the failure of H1 to correctly predict the nature of the relationship between sonority and timing in this study are likely entwined. In languages with c-centering in complex onsets, syllables can be and likely are distinguished by having distinct right- and left-edge timing patterns (shown in Section 1.2.2). The competitive coupling in complex onsets specifically results in considerable overlap between the onset consonants (Figure 5). In these languages, we would also expect to see the hierarchical effect of sonority on overlap as predicted in H1; sonority rises are better able to preserve consonant recoverability while allowing for overlap (Mattingly Reference Mattingly, Myers, Laver and Anderson1981). Georgian, however, does not clearly distinguish onsets and codas in this way, and instead the relationship between sonority shape and timing is modulated by a need to preserve the syllable parse in the absence of the c-center. This perspective also provides a set of testable hypotheses about perception, to be examined in future research. For example, if our syllable perception-driven hypothesis is correct, we should expect different rates of CVCV (mis)perceptions for CCV sequences based on sonority shape and relative overlap value. We predict that, given the same low relative overlap value, sonority rises will be less likely to be perceived as CVCV disyllables than sonority falls.

In general, from a typological perspective, both cross-linguistic generalizations of SSP-driven markedness for sonority rises and AP-driven c-center effect on the onset are not directly applicable to the specific linguistic system of Georgian. Taking a language-specific approach, however, reveals that sonority concerns affect articulatory timing in a way that ensures the lexically specified syllabic parsing.