2.3.1 Distance measure

The focus on bidirectional connections between segment distributions, which we represent as binary vectors with 1's for languages that have a particular segment and 0's for languages that do not have it, makes Pearson's correlation coefficient a natural measure of the strength of the association. The value of the coefficient ranges from ―1 (the presence of one segment predicts the absence of another with absolute certainty, and vice versa, i.e. they are never found together) to +1 (the presence of one segment predicts the presence of another with absolute certainty, and vice versa, i.e. they are always found together). The middle value of 0 indicates the absence of any association (i.e. for any segment of the two, we are as likely to find an inventory that contains only this segment as to find an inventory containing both). Cases of an implicational universal – segment A strongly predicts segment B, but not vice versa – give rise to small positive values of the coefficient (which, unfortunately, makes them indistinguishable from chance relationships between segment distributions).

The next step is to divide segments into co-occurrence classes based on their pairwise distributional similarities. Given the high number of segments, it is hardly feasible to do this by manually investigating several thousand correlation coefficients. Methods for dimensionality reduction and clustering offer a convenient shortcut, but in order to use them we need to convert correlational similarity values to a non-negative dissimilarity (more precisely, distance) measure.

The simple step of adding 1 to all the coefficients and subtracting the result from 2 will produce a distance measure satisfying non-negativity, symmetry and zero distance from the object to itself. However, this measure does not obey triangle inequality (a rule that the distance between points A and C cannot be larger than the sum of distances from A to B and from B to C for any point B), which may lead to nonsensical results. Fortunately, there are several methods for converting Pearson's correlation coefficient to a proper distance measure (van Dongen & Enright Reference Dongen and Enright2012). One of them is the simple arccosine transformation D = arccos(Cor(x, y)), and we therefore use it in our analysis.Footnote ⁵

2.3.2 Dimensionality reduction and clustering

Every segment in our dataset is represented as a binary vector of length 2761. The data are very high-dimensional, which makes it impossible to directly visualise them or even to use Principle Components Analysis, which prohibits the number of variables from being larger than the number of data points (2761 vs. 193, in our case).

For the analysis of our dataset, we used ‘Uniform Manifold Approximation and Projection’ (UMAP; McInnes et al. Reference McInnes, Healy, Saul and Großberger2018), a novel method for dimensionality reduction which has been adopted in the machine-learning and bioinformatics communities, thanks to its ability to uncover hidden structure in high-dimensional data, both at the level of immediate neighbourhoods of individual points and at the level of larger clusters, if these can be detected.Footnote ⁶

UMAP takes as input a table with the original data points or a matrix of pairwise distances between them (in our case, arccosine-transformed Pearson's correlation coefficients) and chooses a lower-dimensional representation of the point assemblage in such a way that neighbourhoods of individual points and relative positions of larger clusters are preserved, as far as possible. UMAP has fairly involved mathematical foundations, but in practice its operation boils down to several transparent steps:

(i) A number of neighbouring points, k, is selected, guided by the researcher's guess as to how many points constitute a valid neighbourhood. In this case, this corresponds to the intuition as to how many points constitute a minimal cluster. In the extreme case, k can be taken to be equal to 1, giving rise to two-point clusters. Larger values essentially prohibit small clusters, and make the macro-structure more homogeneous and ‘lumpy’ (we can also force the algorithm to never lump individual points together by setting a non-negative value for the min_dist parameter, which dictates how far individual points should be from each other in the resulting embedding; this parameter, however, has a weaker influence on the overall structure). k = 3 and min_dist = 1 were used for the analysis.

(ii) A multidimensional ball is drawn around each data point, such that it includes its k neighbours. A neighbour graph is then created, where each point is connected to its k neighbours.

(iii) The edges in this graph have varying weights, depending on how far from the target point its neighbours are. Mathematically, the neighbourhood of the points are regarded as fuzzy sets (i.e. sets with probabilistic membership), and the UMAP algorithm defines a way to combine them where the edge lengths are regarded as probabilities of the fact that an edge really exists (if two nodes are not immediate neighbours, the probability that an edge between them exists is set to 0).

(iv) An arrangement of points in a lower-dimensional space is selected in such a way that, when we construct the same union of fuzzy sets based on Euclidean distances, the cross entropy between the probability distributions of the existence of edges in this lower-dimensional neighbour graph and the original high-dimensional neighbour-graph is minimised.

For further details of the mathematical foundations of the method and the implementation details, readers are referred to McInnes et al. (Reference McInnes, Healy, Saul and Großberger2018).

UMAP does not propose a ready-made clustering of the points. The latter can be created either (i) on an ad hoc basis, inspecting the scatter plot of the points if the representation is two-dimensional (the most commonly used trade-off between interpretability and the possibility of preserving complex configurations) or (ii) by using a clustering algorithm.

To separate points into clusters, we used the density-based clustering algorithm DBSCAN (Ester et al. Reference Ester, Kriegel, Sander, Xu, Simoudis, Han and Fayyad1996). It divides the space (in our case, the space of segment distributions interpreted as points on the two-dimensional plane) into regions of high density (those around core points of clusters) surrounded by peripheral points (those reachable from core points) and noise points (those not reachable from core points and not belonging to any cluster).

To summarise, in order to derive co-occurrence classes of consonants in the world's languages, we constructed an analytical pipeline from four well-defined mathematical procedures (Pearson's correlation coefficient → arccosine transform → UMAP dimensionality reduction → DBSCAN clustering). The pipeline separates data points into groups without any prior knowledge about their nature or properties. It should be noted that we have a margin of freedom in our choice of the parameters for these procedures. For UMAP, this is the number of nearest neighbours and minimal distance between resulting points; for DBSCAN, it is the minimal number of neighbouring points (again set at 3) and the reachability distance (set at 1.8). The choice of the distance measure for the initial data points is even more important. This freedom, however, is not nearly enough to create an easily interpretable structure from chaos in the initial data: in any case, the pipeline will cluster the points that are closest to each other, and separate them from points lying further afield.Footnote ⁷

3.1.1 Palatalised segments

Two classes of palatalised segments were picked out by the pipeline: coronal /tʲ dʲ lʲ nʲ sʲ/ and non-coronal /pʲ bʲ mʲ gʲ kʲ/, together with /rʲ/.

The marginal position of the rhotic with respect to other coronals is relatively easy to account for: it has been observed that palatalised liquids do not form a recurrent pair: /lʲ/ is more typologically frequent and more diachronically stable than /rʲ/ (Kochetov Reference Kochetov2005). Similarly, Hall (Reference Hall2000: 1) claims that /rʲ/ is ‘far more marked’ than other palatalised coronals. Indeed, /rʲ/ (N = 31) is more than twice as rare as /lʲ/ (N = 66) in our data, as shown in (2).

1. (2)

   

The general coronal vs. the rest split, however, is less expected. Palatalised labial segments are considered to be rarer than both palatalised coronals and dorsals, and both coronals and dorsals are evidently more likely than labials to undergo ‘full palatalisation’, which in most cases means affrication (Bateman Reference Bateman2011).

Inspection of the plot of the correlations of distributions of palatalised segments in Fig. 3, however, shows that there is indeed a noticeable affinity between palatalised dorsals and bilabials on the one hand and between palatalised bilabials and /rʲ/ on the other, suggesting a centre vs. periphery articulatory split, with coronals serving as a default locus for palatalisation; this should be explored further.

Figure 3 The plot of the correlations between distributions of palatalised segments. The sizes of the circles are proportional to the values of correlation coefficients. Thick frames denote groups of segments with high pairwise mutual correlations established using Ward's clustering algorithm.

3.1.2 Phonologically long consonants

These are split into the voiced stops, /bː dː gː/, and everything else. As shown in (3), they are largely in the same frequency range as the palatalised segments.

1. (3)

   

It is tempting to assume that this split can be explained by the well-known observation that it is hard to maintain voicing in long stops, which makes long voiced plosives susceptible to shortening, loss of voicing or implosion (Ohala Reference Ohala and MacNeilage1983), but the fact that /bː/ is more frequent than /pː/ makes this explanation rather weak.

Bilabial long voiced stops are indeed easier to produce, due to the larger oral cavity available for maintaining higher subglottal pressure. Nevertheless, this does not explain why /bː/ does not pattern with /pː tː/. Moreover, /gː/ is arguably the most disfavoured voiced long plosive, characterised by the smallest oral cavity, and yet it is more prevalent than /dː/.

A simpler, albeit clearly incomplete, explanation in terms of the layering principle presents itself: when adding voiced long plosives, languages tend to exhaust this segment class despite differences in the articulatory difficulty of different segments. In other words, languages are more likely to acquire /bː dː gː/ as a group, rather than the individual pairs /bː pː/, /dː tː/ and /gː kː/.

The strength of connections between segments on the same level of the layering hierarchy can be illustrated by the fact that there are more languages with /bː/ but no /pː/ (N = 29) than there are with /bː/ but no /dː/ (N = 19), even though /pː/ is nearly 1.5 times as frequent as /dː/.

3.1.3 Labialised segments

A further divergent cluster is formed by a subset of labialised segments, together with the palatalised glottal fricative, as shown in (4).

1. (4)

   

It is notable that this cluster is coherent, despite substantial frequency disparities between its elements (/kʷ/ is more than ten times as frequent as /ʃʷ/, and nine times as frequent as /tʷ/, for example). The visual structure of this cluster in Fig. 1, further supported by the correlation coefficients, suggests four subgroups, mostly corresponding to frequency bands and exactly corresponding to place of articulation: /hʲ hʷ/, /ŋʷ gʷ kʷ/, /ʃʷ tʷ sʷ/ and /pʷ fʷ bʷ mʷ/.

Three tendencies are discernible. First, different regions of articulation are more productive for labialised stops and fricatives respectively. Second, the use of particular values of the place feature for labialised segments (especially the postvelar articulations, cf. §3.2) is dependent on whether there are other segments with the same value of this feature, rather on whether there are other labialised segments in general. Third, the glottal fricative /h/ either (i) lacks any additional articulation or (ii) tends to have both palatalised and labialised versions.

3.1.4 Voiceless approximants, liquids and nasals.  The small group in (5) consists of low-frequency and, on average, rather tightly correlated sounds, except for /r ʍ/, which rarely appear together (r = 0.13). /m n/, on the contrary, are nearly inseparable (r = 0.847).

1. (5)

   

3.1.5 Other clusters

The remaining groups consist of truly marginal sounds:

(i) Tense and weakly articulated stops, /p ˜ Ç ˙ á ¯ É ˘/, are very rarely described outside Australia and are almost exclusively found together.Footnote ⁸

(ii) Phonologically apical stops and liquids, /ˆ û ¢ ı ´/, are also predominantly found in Australia, whose languages are famous for their extended range of place oppositions (Butcher Reference Butcher, Harrington and Tabain2006).

(iii) The voiceless prenasalised stops /mp nt ŋk/ are found in Africa, Eurasia and South America, but are rare (N = 36, 42, 41 respectively), and are twice as likely as not to be found in inventories that also have corresponding voiced prenasalised stops; see the contingency tables in Table I.

Table I Contingency tables for the co-occurrence of voiced and voiceless prenasalised stops. Cells contain counts of inventories with (+) or without (−) a particular segment.

3.2.1 The basic consonant inventory

The cluster consisting of /p t k n l r/ and, although it is just outside the core group, /m/ (the most common segment in the dataset) can be considered a serious contender for the title ‘basic consonant inventory’ (a group of consonantal sounds that we expect to find in a randomly picked language).

The question of which set of segments can be considered basic one has been raised by many scholars, recent notable contributions including Hyman (Reference Hyman2008) and Gordon (Reference Gordon2016). The main stumbling blocks are the facts that (i) there are no really universal segments (even the most frequent segment, /m/, is found in only 96% of the languages), and (ii) raw frequency counts make it impossible to draw the boundary between quasi-universal segments and merely very frequent ones. Should the boundary be drawn between, say /s/ (frequency 72%, as shown in Fig. 4) and /ŋ/ (63%), or between /g/ (56%) and /d/ (49%)?

Figure 4 The 40 most frequent segments in the sample.

The approach based on the identification of co-occurrence classes seems to provide a way of overcoming this impasse. If there is a single co-occurrence cluster consisting of some of the most frequent segments, this means that inventories lacking any of these sounds are somehow statistically anomalous. Such a cluster, therefore, is a good contender for the title of the basic consonant inventory.

A somewhat unexpected feature of the basic inventory cluster in Fig. 2 is the fact that /j/ and /w/, which are also exceedingly common (N = 2485, 2322 respectively), do not form part of this cluster, and are grouped together with alveolo-palatal stops, which are found predominantly in Australian languages. What we see here is probably the case of macro-areal influence being strong enough to skew the worldwide distribution of basic segments.Footnote ⁹ In order to test this hypothesis, we first re-ran the analyses on the same dataset, but with Australian languages (N = 384) excluded. In the resulting clustering, /j w/ are grouped together with /p t k m n l r/. To further ascertain their status vis-à-vis the ‘basic set’, we then conducted a cluster analysis on the segments from it together with /j w/, based on two versions of the dataset: one with and one without the Australian languages.Footnote ¹⁰

The results are shown in Fig. 5. They indicate that in both cases /j w/, /p k/ and /t n/ form basic pairings, and that /p k/ are then merged together with /t n/; this cluster is then augmented by /l r m/ and finally merged with /j w/. The only difference is in the order in which the segments are added: /l/ > /r/ > /m/ in the full dataset, and /m/ > /l/ > /r/ when Australian languages are left out.

Figure 5 Single-linkage clustering of the most common segments based on arccosine-transformed correlations.

Thus it seems that even though /j w/ are very frequent, languages care mostly about having both these segments. Losing a segment from the /p t k m n l r/ set, on the other hand, even though clearly possible, leads to a statistically marginal configuration.

3.2.2 The Australian extension set

The cluster in Fig. 2 that includes /j w/ otherwise consists of three types of segments: retroflexes, /ɭ ɳ ɽ ʈ/, forming a counterpart to the subset of the basic inventory, alveolo-palatal /ȴ ȵ ȶ/, and /ŋ/. In a worldwide perspective, these sounds fall into three different frequency bands:

(i) /ŋ/ is a very frequent segment (N = 1751), but its overall relative frequency (63%) pales in comparison to its relative frequency in Australia (it is present in all Australian languages in the sample). The same applies to /j w/, found in all Australian languages in the sample.

(ii) Retroflex segments are traditionally associated with South Asia and the Himalayas, where a greater variety is indeed found than elsewhere. The relative frequencies of /ɭ ɳ ɽ ʈ/ in Australia, however, are all very high (≈ 0.6), while in other regions retroflex inventories display more variation (Nikolaev & Grossman Reference Nikolaev and Grossman2018).

(iii) Alveolo-palatal /ȴ ȵ ȶ/ are not reported outside Australia.

Other retroflex segments, /ɖ ʈʰ ɽ/, are found with similar frequencies in Australian and South Asian languages. As a consequence, they are classified as noise points.

3.2.3 The non-Australian extension set

Whereas Australian languages expand the basic inventory by means of an extended set of places of articulation, avoiding both voiced plosives and voiced fricatives, languages from outside Australia almost universally add to the basic set using some or most of the segments in (6). We refer to the resulting set as the first extension set.

1. (6)

   

The hierarchical clustering plot for these segments shown in Fig. 6 demonstrates that there is more structure to this extension than mere frequencies: the voiced plosives /b d g/ cluster together, as do /f v z/ and the postalveolar pairs /ʃ ʒ/ and /ʧ ʤ/. /s/ is placed separately, presumably because its very high frequency dilutes correlations with other segments, while other less frequent ‘semi-basic’ segments do not form pairs. The most notable observation is a relatively weak correlation between the glottal segments /h/ and /Ɂ/ (r = 0.257). /Ɂ/ is more than twice as likely to appear with /h/ than on its own (283 vs. 756 cases), but /h/ appears with and without /Ɂ/ with nearly equal frequencies, with a slight preference for inventories without /Ɂ/ (756 vs. 799 cases). It must be noted, however, that a great number of languages are postulated to have a non-phonemic glottal stop. The influence of this factor on the distribution is unclear.

Figure 6 Single-linkage hierarchical clustering of the first major extension to the basic inventory based on arccosine-transformed correlations.

Close to the extension set but not inside it are the tap /ɾ/ and two groups of what the algorithm deems to be noise points, although they seem to form subclusters of their own:

(i) The affricates /ʦ ʣ pf/ have widely different frequencies (N = 652, 297, 39 respectively), but /ʦ ʣ/ are strongly correlated (r = 0.52), and out of 39 occurrences of /pf/, 35 are in languages with /ʦ/; all the exceptions are found in Africa.

(ii) The palatal plosives /c ɟ/ have comparable frequencies (N = 360, 320). Similarly to fricatives and in contrast to basic plosives, they are grouped on the basis of their place of articulation, rather than voice. The position of the much rarer /cʰ/ (N = 83) is ambiguous: it is situated between the palatal plosives and the prominent cluster of voiceless aspirates.

Voiceless aspirated plosives and affricates cluster together. The addition of a non-basic VOT feature seems in this case to be more important than place and manner differences. This is not true, however, for the retroflex affricates /Ú Úʰ ó/, which are separated by their place–manner combination, disregarding VOT. Retroflex affricates form a tight co-occurrence class mostly associated with the affricate-rich languages of Eurasia (see Nikolaev & Grossman Reference Nikolaev and Grossman2018).

The retroflex fricatives /ʂ ʐ/, treated as noise points by the clustering algorithm, enjoy a much wider and geographically unstructured distribution (languages with retroflex affricates tend to also have corresponding fricatives, but this connection is one-directional).

The alveolo-palatal fricatives and affricates /ɕ ʑ ʨ ʨʰ ʥ/ are medium-frequency segments forming the cluster characterised exclusively by place of articulation in (7).

1. (7)

   

They are found in all major areas, and seem to be especially prevalent in the Circum-Tibetan area. The frequencies, however, may be unreliable, as the frequency of reports of alveolo-palatal segments in descriptions has increased in recent years, replacing earlier reports of postalveolar /ʃ ʒ ʧ ʤ/.

Languages rarely have both alveolo-palatals and postalveolars, and it has even been suggested that this is impossible, due to their acoustic and articulatory similarity (Hall Reference Hall1997). However, there are 16 languages – nearly all of them Eurasian, and mostly Circum-Tibetan – that have both /ʃ/ and /ɕ/, and 13, mostly from the same set, with both /ʧ/ and /ʨ/.

The breathy voiced/murmured stops /b d  G/ are found predominantly in South Asia and the surrounding regions. They were evidently inherited in the Indo-Aryan languages of the area, and later spread, due to phonological borrowing and convergent processes of sound change. A similar scenario has been proposed to account for the distribution of retroflex segments, which presumably spread from their homeland in the Dravidian southern periphery of South Asia (Bomhard Reference Bomhard1986, Bohnert et al. Reference Bohnert, Myers, Smith and Berkson2018).

Another group of segments augmenting the extension set are the bilabial and interdental fricatives together with the voiced velar fricative and, surprisingly, the retracted dental nasal stop /ṉ/, as in (8).

1. (8)

   

The appearance of /ṉ/ here is probably a statistical artefact: it is very weakly correlated with other segments (no r ≥ 0.06), which, it must be said, are generally rather weakly interconnected, except for /θ ð/ (r = 0.44).

Interestingly, voiced bilabial and interdental fricatives seem to be more common than their voiceless counterparts. /x/ (N = 491) does trump /ɣ/, but it also tends to co-occur with the ‘guttural segments’ (cf. below), which separates it from this cluster. Another possible peripheral member of this cluster is the alveolar approximant /ɹ/, a surprisingly rare segment (N = 54). It is known, however, that the description of rhotic segments often suffers from overnormalisation, with taps and approximants being inaccurately described as trills (Catford Reference Catford2001), so this datum is unreliable.

Postvelar (uvular and pharyngeal segments) have low to mid frequencies, as in (9).

1. (9)

   

Uvulars are generally more common than pharyngeals, with the notable exception of the voiced uvular stop /ɢ/, which suffers from the same kind of articulatory disadvantage as described above for /g/ (an extremely small cavity for maintaining high subglottal pressure for voicing). The interleaving of frequencies, however, does not influence the internal structure of the cluster, where the two pharyngeals are opposed to all the uvulars (cf. Fig. 7); uvular fricatives form a tight unit, but uvular stops, due to a wide discrepancy in frequencies, do not.

Figure 7 Single-linkage clustering of guttural segments based on arccosine-transformed correlations.

Ejective segments, whose geographic distribution has been debated since the publication of Everett (Reference Everett2013) (see Hammarström Reference Hammarström2013 and Roberts Reference Roberts2013, for example), undoubtedly form a clearly delineated group subsuming different places and manners of articulation, as in (10) (‘R’ is a symbol for an underspecified rhotic used in UPSID, one of the sources for PHOIBLE).

1. (10)

   

Interestingly, /R/ tends to co-occur with ejective segments. It is also notable that the non-ejective voiceless lateral affricate occurs more rarely than its ejective counterpart, and does not pass the 30-language threshold.

The labialised velar and uvular segments in (11) form a cluster of their own, midway between ejectives and plain (i.e. non-labialised) postvelars. /xʷ/, a nearby noise point, can also probably be considered a part of this cluster.

1. (11)

   

These segments tend to appear in large inventories, which, in addition to sporting a wide range of places of articulation in the postvelar region, also employ labialisation, in accordance with the layering principle.

The appearance of the ejective /kʷ’/ in this cluster can be explained by the fact that labialised velar and uvular segments tend to appear in large inventories, especially those with ejectives, i.e. in the Caucasus and parts of North America. It should be pointed out that some languages with extremely large inventories (Saamic languages and some Tibetan dialects) lack both labialised plosives and ejectives.

Lateral fricatives and creaky voiced approximants form a surprising grouping. /J/ and /W/ are both quite rare (appearing in 30 languages each), and are very highly correlated (r = 0.9). /ɬ/ appears in half of the languages in which they appear in (14 for /J/ and 15 for /W/); these languages are all from North America, making this connection a localised one.

3.2.4 Other clusters

The remaining subgroups of the large cluster are:

(i) The implosives /ɓ ɖ ʄ/ (N = 293, 254, 44), which form a natural group. /ʄ/ is mostly found in Africa, but /ɓ ɖ/ have an intriguing distribution: they are found in Africa, Eurasia, both Americas and in Oceania, but never above the 41st northern parallel.

(ii) The labial-velar segments /kp gb ŋm/, together with /ɥ/, the former almost exclusive to Africa.

(iii) The prenasalised segments /mb nd ŋg nʤ ŋmgb ŋgʷ nʣ nz ɱv ɲɟ/ (N = 284, 278, 264, 127, 93, 57, 53, 46, 46, 36), which are also confined to the southern hemisphere, with /mb nd ŋg/ enjoying a rather wide distribution, and others found predominantly in Africa.

(iv) The palatal affricates /cç cçʰ ɟʝ/ (N = 112, 43, 97), which occur primarily in languages of the Indian subcontinent, together with the palatal fricatives /ç ʝ/ (N = 116, 54), which have a much wider unstructured distribution.

(v) The dental segments /t̪ n̪ l̪/, together with nearby /d̪/ (N = 615, 473, 191, 354). Common descriptive practices may suppress the real frequency of these segments, which are often described as alveolar or ‘denti-alveolar’, but there is little doubt about the status of this cluster.

4.2.1 Classes defined by a particular value for place

Several classes violate the layering principle by being defined not by an additional feature or a combination of features, but by a particular value for place. Most place values do not determine their own co-occurrence classes, and are subsumed under broader conformant classes.

The alveolo-palatal segments /ʑ ɕ ʥ ʨ ʨʰ/, in addition to being defined by a particular place value, contain only a single element with an additional articulation (aspiration).

The uvular segments /qʰ ɢ q χ/ are similar to alveolo-palatals in consisting of voiced and voiceless segments with different manners of articulation and including one aspirated segment.

4.2.2 Classes defined by a particular value of the manner feature

The group /θ ɸ ð ꞵ ɣ/, together with /ṉ/, whose presence may be a statistical artefact due to its relatively low frequency, constitutes an intriguing extension to the basic inventory. Most notably, three groups of fricatives defined by different places of articulation – interdental, bilabial and voiced velar – form a group, even though they are all comparatively rare, and do not have obvious features in common which distinguish them from other modally voiced fricatives. A further violation of the layering principle is the fact that even though bilabial fricatives are in nearly complementary distribution with labiodental fricatives, it seems that precisely those languages which have bilabial fricatives tend to also have interdental fricatives and the voiced velar fricative.

The voiceless prenasalised stops /mp nt ŋk/ form a separate class by virtue of occurring in a small subset of languages with voiced prenasalised stops. This may be regarded as a prominent violation of the layering principle, since most languages with prenasalised stops do not have voiced ones, and therefore underutilise the available feature combinations.

A prenasalised stop, however, may be also regarded as voiced by default in the same way as a sonorant, as one of its constituent elements is sonorant. In this scenario, voiceless prenasalised stops are characterised by an additional feature [―voice], making them a conformant class.

4.2.3 Classes defined by a combination of place and manner features

The two small classes of palatal and retroflex affricates are defined by their combination of place and manner features and their ability to incorporate voiceless aspirated segments (under the layering principle, voiceless aspirated fricatives are expected to cluster with voiceless aspirated stops, as we see at other places of articulation). These segments tend to appear as a group in large inventories (cf. the analysis of retroflex affricates by Nikolaev & Grossman Reference Nikolaev and Grossman2018), and are largely geographically concentrated in and around South Asia. In the dimensionality-reduction plot in Fig. 2, both classes are also connected with respective fricative segments, which enjoy much wider and less structured distributions.

4.2.4 Mixed classes

Labialised segments are a complex case. The clearly separated class of non-guttural labialised segments in Fig. 1 is largely conformant. At the same time, the analysis shows that /hʲ/ forms a part of this cluster, due to its tight distributional connection with /hʷ/. This can be considered a minor violation of the layering principle. The predictive power of the principle is severely damaged, however, by the existence of a separate cluster of labialised segments consisting of /kʰʷ kʷ’ χʷ qʷ/. These segments do not have a common distinguishing feature (one of them is aspirated, one is ejective and the other two are plain voiceless labialised). It is evident that this particular region of feature space tends to be adopted in its entirety by languages with rich inventories, including ejective sounds.

The lateral fricatives and creaky voiced approximants, /ɬ ɮ J W/, form a rather surprising grouping, as they have nothing in common. Languages underlying this connection are North American, and it may have arisen due to geographically and phylogenetically restricted sound-change processes.

The featural analysis of the labial-velar segments, /kp gb ŋm/, presents difficulties, due to their dual nature. However, Cahill (Reference Cahill1999) presents evidence in favour treating them as underlyingly labial segments with an additional velar coarticulation. In our data they strongly pattern with /ɥ/, which can also be analysed as a labial sound with an additional coarticulation. However, as this coarticulation is palatal, the class is non-conformant.