The paper presents an analysis of the results of three perception experiments that aimed to investigate the scope of postverbal quantifiers in Hungarian. These experiments found no correlations between wide vs. narrow scope readings of postverbal quantifiers and their stressed vs. unstressed pronunciations, contradicting a widespread assumption. In addition to the dominance of scope interpretation that corresponds to the linear order of constituents, previously unnoticed effects of the syntactic or thematic role of the postverbal quantifier and of the type of preverbal operator in the same sentence were found. These might indicate a more complex interaction of several factors or point to a greater role of extra-grammatical effects in determining the scope of quantifiers in Hungarian than previously assumed. The paper also addresses methodological issues that arise in the course of eliciting scope judgments experimentally.
The study of factors influencing the relative scope of operators in natural languages constitutes an important field of research at the syntax-semantics interface, which profited in recent years from a variety of experimental studies on different languages (cf. Szabolcsi 2010 and Bott et al. 2011 for overviews). The Hungarian language has traditionally been assumed to “wear its LF on its sleeve” (Szabolcsi 1997: 111), since, with the exception of the case of two postverbal expressions, the linear order of quantificational expressions (and other operators) reflects their relative scope. These data have been accounted for in the generative syntactic tradition by postulating a hierarchically structured preverbal field, where a constituent that precedes another one also c-commands it, and a non-hierarchical postverbal field (cf. É. Kiss 2002 for an overview).
This paper is concerned with one of the special cases where the default scope relations described above seem to be modifiable through different prosodic realizations of the constituents concerned. Katalin É. Kiss and László Hunyadi argued in several papers (to be discussed below) that postverbal quantifiers bearing heavy stress scope over preverbal operators either obligatorily or optionally in Hungarian (depending on certain properties of the quantifier and of the preverbal operator, discussed below). The aims of our investigations reported on here were i) to see whether the scope reversal effect discussed by the above authors can in fact be confirmed experimentally, and ii) to find out whether the effect is really due to prosody or should be attributed to some other factors known to influence the scope of operators cross-linguistically.
In what follows, we introduce the basic assumptions about Hungarian sentence structure and scope from the literature that we have taken for granted in the course of planning the experiments.
(1) below illustrates the hierarchical structure of the Hungarian preverbal field, following É. Kiss (2002).1 In this framework, [Spec,TopP] is the projection that is assumed to host topical DPs, i.e. those that can introduce individual discourse referents, whereas [Spec,DistP] is the projection where only distributive quantifiers can appear. The [Spec,FocP] projection hosts the focus constituent (to be discussed below). The ‘*’ marks iterable projections.
In the following example, which contains a DP in each of the preverbal positions indicated above, the scopes of the quantificational expressions are unambiguous: a quantifier c-commanding and preceding another one also has scope over it (É. Kiss 2002: 111).2
Other things being equal, “the heaviest grammatical stress” of the Hungarian sentence is assumed to fall on the first accentable position of the predicate part of the sentence, the latter being identical to the highest of the DistP, FocP and VP constituents (cf. É. Kiss 2002: 111). In (2), this stress falls on the first syllable of the determiner minden ‘every’.
In the literature, significant attention has been devoted to consequences of the observation that the range of quantificational expressions that can appear in [Spec,TopP], or the topic position for short, and [Spec,DistP], or the quantifier position for short, are not identical, and the interpretations of DPs that are allowed to appear in two different positions change according to the position itself. (Cf. Szabolcsi 1997; 2010; É. Kiss 2002 and Csirmaz & Szabolcsi 2012 for overviews.)
(3) illustrates some of the DP types Szabolcsi (1997) lists among the possible occupants of the topic and the quantifier positions, respectively.
|(3)||a.||topic position: valamely fiú/bizonyos fiúk ‘some boy(s)’, Péter, Péter és Mária ‘Peter and Maria’, a fiú(k) ‘the boy(s)’, hat fiú ‘six boys’, sok fiú ‘many boys’, a legtöbb fiú ‘most boys’|
|b.||quantifier position: sok fiú ‘many boys’, minden fiú ‘every boy’, valamennyi fiú ‘each boy’, hat fiú is ‘even/as many as six boys’, legalább hat fiú ‘at least six boys’, több mint hat fiú ‘more than six boys’|
According to the characterization provided by Szabolcsi (1997: 122), DPs in the topic position “contribute an individual to the interpretation of the sentence”, and the DPs in the quantifier position, denoting right monotone increasing, distributive quantifiers “contribute a set to the interpretation of the sentence”.
It was pointed out first by Szabolcsi (1981) that the constituents situated in the [Spec,FocP] position, traditionally referred to as the focus position of the Hungarian sentence, are associated with an exhaustive interpretation. This means that whenever the person answering the wh-question in (4-a) knows that János not only missed the bus but also the train, her utterance of (4-b) is not only considered inappropriate but is downright false:
Szabolcsi (1994) formalized this intuition (based on suggestions by Kenesei 1986) by postulating an operator responsible for the exhaustive/identificational reading, shown in (5). This means that the meaning of (6-a), with the DP két ember ‘two people’ in focus position, is to be represented as in (6-b):
|(5)||Szabolcsi (1994: 181, ex. (22))|
|λzλP[z = ιx [P(x) & ∀y [P(y) → y ⊆ x]]]|
In plain English, (6-b) means that there is a plural individual in the denotation of man that has two atomic parts and is identical to the maximal individual that runs. The use of the ι-operator reflects the intuition that sentences with preverbal focus presuppose that there is a unique (possibly plural) individual that possesses the property characterized by the rest of the sentence, and assert that the latter is identical to the denotation of the constituent in focus position.5
This observation is reflected in the practice of translating Hungarian sentences containing a preverbal focus into English with the help of a cleft or pseudocleft construction, as in Szabolcsi (1994) and É. Kiss (1998; 2002), which will also be followed in this paper. Although the above solution might give the impression that a declarative containing a preverbal focus in Hungarian is not a congruent answer to an ordinary wh-question, it reflects the truth-conditional meaning of the relevant construction better than an English declarative where the focus is marked prosodically. (Note that it is due to the obligatory exhaustive/identificational reading of the preverbal focus that DPs with bare numeral determiners in this position, like két ember ‘two people’ in (6-a), are interpreted as if the numeral were modified by exactly.)
The interpretation of Hungarian sentences containing a preverbal focus given above might appear analogous to the interpretation of sentences containing the exclusive particle csak ‘only’, as in (7):
Szabolcsi (1994) convincingly argues that the structures shown in (6-a) and (7) differ as to where the dividing line between presupposed and asserted content lies. (This can be proven by comparing negated versions of (6-a) and (7), which, crucially, are not synonymous.) According to her proposal, (7) presupposes that two people run, and asserts that these two people are not part of a larger plural individual that runs.6
Given that the constituent in the preverbal focus position is associated with an exhaustive/identificational operator, it can enter into scope relations with other operators in the sentence.7 Exhaustive/identificational focus is c-commanded by and thus takes narrow scope with respect to preceding quantificational expressions, illustrated in (2) and (8):
As illustrated above, the focus position can host non-quantificational DPs, as in (4-b) and (8), as well as DPs with (modified) numeral determiners, as in (2) or (6-a).
On the assumption that scope is determined by c-command relations at overt structure, the relative scopes of the two preverbal operators in (9) and of the preverbal and postverbal operators in (10), where main stress falls on the sentence-initial constituents, have to correspond to their linear order, which is indeed the case:
Having reviewed some basic assumptions on the syntactic structure of the Hungarian sentence and the interpretation of constituents in the preverbal operator positions, in the next section we turn to the discussion of the specific claims of four theoretical studies regarding the scope properties of different kinds of postverbal quantifiers depending on their prosody. Sections 3 and 4 present the perception experiments we conducted in order to gain information about how speakers interpret Hungarian sentences containing postverbal quantifiers. The theoretical implications are discussed in Section 5, and the paper ends with the conclusions in Section 6.
Hunyadi (1981) argued that stress on a postverbal universal DP can overwrite the predictions concerning scopal relations that are made on the basis of c-command relations at overt syntax, forcing the constituent in question to take wide scope over preverbal exhaustive/identificational focus. Thus, in his judgment, the only reading of (11) is identical to that of (9): ‘Every picture is such that it was Peter who looked at it.’ (In this and the following examples, stress on a postverbal constituent is marked by small capitals.)
É. Kiss (1987; 1992; 2002; 2010a) extends Hunyadi’s predictions on the effect of stress to all types of postverbal distributive quantifiers. Regarding topical DPs in postverbal position, she claims that they are capable of taking inverse scope with respect to preverbal quantifiers independently of whether they are stressed. É. Kiss (1987; 1992; 2002) accounts for these data by assuming that at Spell-Out, the postverbal stressed quantificational expressions occupy the preverbal operator positions that are available for them (i.e. [Spec,TopP] or [Spec,DistP], respectively). At PF, they undergo stress-assignment in these positions, but after that, they are moved back to postverbal position by a stylistic postposing rule. A different approach is proposed by É. Kiss (2010a), which assumes that the stress of postverbal distributive, upward monotonic quantifiers indicates that they are right-adjoined to FocP and thus c-command the latter, deriving the wide scope reading on standard assumptions.
Hunyadi (1996; 1999; 2002) breaks with the view that the scope of operators in Hungarian is determined by c-command relations. In his theory, scope is derived from the interaction of stress and certain properties of operators, such as their place within an independently given operator hierarchy (Hunyadi 2002: 90).
Brody and Szabolcsi (2003) assume a hierarchical VP, where sequences of the operator projections RefP (corresponding to TopP in other frameworks, cf. (1) above), DistP and FocP are iterated. (This enables postverbal quantifiers to occur in any order, since adjacent constituents may always belong to different scopal series.) The theory predicts that for a pair consisting of a preverbal and a postverbal quantifier an inverse scope reading is possible, provided the latter precedes the former in the following ranking of quantificational expressions: topical indefinites, most-phrases > distributive quantifiers > counters (including focused number words). The authors claim that for speakers of one dialect “high stress” is a necessary condition of the wide scope of a postverbal quantifier.
Surányi (2002; 2004; 2006) proposes that distributive universals, increasing “modified numeral indefinites”, and “increasing proportionals” like many N occupy their scope positions in Hungarian not as a result of Q-feature checking but as a result of quantifier raising. Quantifier raising can optionally be overt or covert, and does not depend on stress.
Here we cannot go into a detailed discussion of how exactly the theories mentioned above derive the wide scope readings of postverbal quantifiers for the cases they predict such readings to exist. We limit ourselves to presenting their different predictions regarding the relative scopes of pairs of operators in two configurations: i) a non-quantificational DP in preverbal focus position is followed by a stressed or unstressed postverbal quantificational DP, cf. Table 1, and ii) a DP containing a bare numeral determiner in preverbal focus position is followed by a stressed or unstressed postverbal quantificational DP, cf. Table 2. The following two examples illustrate the structure of the sentences under discussion, for the case where the postverbal quantifier is a universal one. With the non-quantificational expression Klára in the focus position, (12) represents configuration i) above, whereas (13), with the DP két lány ‘two girls’ in the focus position, illustrates configuration ii). The two potential readings of (12)–(13), which differ as to the relative scopes of the exhaustive/identificational focus and the postverbal quantificational DP, are both shown in the translations. Linear scope (abbreviated as ‘LS’) refers to the configuration where the linearly first constituent (i.e. the one situated in the focus position) takes scope over the postverbal quantifier, where the former also c-commands the latter, and inverse scope (abbreviated as ‘IS’) to the one where the preverbal focus constituent takes narrow scope with respect to the quantifier.
|Prosody of QDP||Type of QDP||Scope of QDP|
|stressed||topical||É. Kiss: inverse
|distributive||É. Kiss: inverse
|unstressed||topical||É. Kiss: ambiguous
|distributive||É. Kiss: linear
|Prosody of QDP||Type of QDP||Scope of QDP|
|stressed||topical||É. Kiss: inverse
Brody & and Szabolcsi: ambiguous
|distributive||É. Kiss: inverse
Brody & Szabolcsi: ambiguous
|unstressed||topical||É. Kiss: ambiguous
Brody & Szabolcsi: linear/inverse
|distributive||É. Kiss: linear
Brody & Szabolcsi: linear/ambiguous
In Tables 1 and 2, the top row lists properties of the postverbal quantiicational DP (abbreviated as QDP), also referred to as quantifier in what follows, such as its prosody, its type and its scope. For brevity, we have only indicated the authors’ names in the tables without explicit reference to the publications, since the predictions of the individual authors concerning the scope relations between a preverbal focus and a postverbal quantifier do not change across their different publications. Since Brody & Szabolcsi do not make predictions for the case of non-quantificational expressions in the focus position, their suggestions are not included in Table 1.
As Tables 1 and 2 show, the four approaches make different predictions as to whether the availability of the inverse scope reading depends on the postverbal quantifier being stressed. Whereas the proposals by É. Kiss and Surányi do not differentiate between quantificational and non-quantificational DPs in the preverbal focus position, Hunyadi makes different predictions for them. As mentioned above, Brody & Szabolcsi only consider quantificational foci, and assume that speakers of two different dialects assign scope differently to postverbal unstressed quantifiers.
As the tables indicate, among the four approaches discussed here, É. Kiss and Hunyadi predict for the majority of the configurations that the prosody of the postverbal quantifier determines its scope with respect to an exhaustive/identificational focus. Brody & Szabolcsi argue that stress only has an impact on scope for speakers of one dialect, whereas Surányi does not attribute any significance to it.8
Interestingly, all the theories assume that there is no distinction within the classes of the topical and distributive DPs themselves regarding the availability of the inverse scope reading in postverbal position. These theories do not discuss the impact of any other potential factors on scope, such as the grammatical or thematic roles of the relevant scope-taking expressions, for example. The next section describes the experiments we carried out to test the above predictions.
The aim of the experiments reported on in this section was to systematically test the scope of postverbal QDPs with respect to exhaustive/identificational focus. Specifically, we wanted to find out whether i) inverse scope readings are possible for postverbal QDPs at all, and, if they are, ii) whether these readings arise as a result of the QDPs being stressed. We hypothesized, based on previous discussions in the literature, that the answer to both of these questions will be positive. We considered the possibility that the syntactic/thematic role of the postverbal quantificational expression or the type of constituent in the preverbal focus position will also make a difference regarding the availability of the relevant readings, and thus the experimental items were created in a manner that makes a comparison along these parameters to be possible, but we did not formulate specific hypotheses concerning them.
Experiments 1 and 2 were designed to elicit scope judgments using non-verbal forced-choice responses. They were identical except for minor adjustments, which were deemed necessary due to the fact that in Experiment 1 no evidence was found of an effect of prosodic stress on scope judgments. For the above reasons, we present these two experiments together.
Inspired by previous work, e.g. Hunyadi (2002), suggesting that rich discourse environments may be crucial in allowing participants to make valid scope judgments, we presented the critical sentences together with an introductory context that we considered ambiguous and unbiased as to the relative scopes of the operators in question.
An item consisted of a context description with a particular critical sentence frame. The critical QDP whose scope was being tested was always postverbal, and the other scope bearing element was a constituent in the preverbal focus position (thus, having an exhaustive/identificational reading).
The experimental items were of four types, to be referred to by the letters A, B, C, and D. They differed in the grammatical/thematic status of the critical QDP, as well as in the type of the phrase in the focus position within the critical sentence frame, as described in (14). Each type was represented by 16 items.
|(14)||A: QDP – object or theme; focus – DP with a numeral determiner|
|B: QDP – subject (and agent); focus – DP with a numeral determiner|
|C: QDP – object or theme; focus – non-quantificational DP|
|D: QDP – subject (and agent); focus – non-quantificational DP|
There were two experimental factors: the type of the QDP (QuantType) and Prosody. The first factor had four levels: the QDP could contain the determiners minden ‘every’, legalább n ‘at least n’, több mint n ‘more than n’ and sok ‘many’. All DPs containing the determiners above are right upward monotonic, and can appear in the preverbal quantifier position. Among them, DPs with minden ‘every’ can only occupy the quantifier position in the preverbal field; DPs with legalább ‘at least’ and több mint ‘more than’ can additionally appear in the focus position; and those with sok ‘many’ may occupy both the topic and the focus positions in addition. The second factor, Prosody, had two levels: the QDP could be stressed or unstressed. The combination of the two factors resulted in 8 conditions, numbered as shown in Table 3.
|every N||at least n N||more than n N||many N|
Each sentence frame containing a particular QDP was associated with a pair of diagrams intended to depict the two possible readings of the sentence (LS vs. IS), presented side-by-side. The diagrams contained representations of individuals arranged in two columns, and arrows that aimed to indicate which individuals the relation described by the verbs is assumed to hold between. In all diagrams, the first column corresponded to the subject noun phrase and the second column to the object/patient noun phrase. The side of the linear scope interpretation was balanced: half of the items in each set are linear-left, and half are linear-right.
Below we illustrate one experimental item of type A, which consists of a context description, whose English translation is shown in (15), and the sentence frame filled in according to the requirements of the eight conditions in (16)–(19). The pair of diagrams that were used to represent the two readings of the two prosodic variants of the critical sentence in (16) is shown in Figure 1. The two readings of the prosodic variants of the critical sentences in (17)–(19) were represented with identical pairs of diagrams, shown in Figure 2. In these examples, the diagram on the left corresponds to the linear scope reading of the respective sentence and the diagram on the right corresponds to the inverse scope reading. The English translations of oktatók and dolgozatok are professors and papers, respectively.
|(15)||This year the papers for the Student Research Competition were evaluated locally by a committee consisting of three professors. Since the members of the committee are not on good terms with each other, the other faculty members at the department were wondering about how they distributed the work among themselves. Fortunately, the reviewers wrote a detailed report, from which the following also became evident:|
The next examples illustrate an item of type B, in Conditions 1 and 5 (without the introductory context):
(12) above, repeated here as (22), illustrates an item of type C, in Conditions 1 and 2. (23) illustrates the same item in Condition 3:
Figure 3 shows the pair of diagrams used in the trials where variants of (22) appear, where the labels lányok and ruhák stand for girlfriends and dresses, respectively.
As a comparison of Figures 1, 2 and 3 shows, there was a difference between the diagrams associated with items of types A–B and of types C–D: in the case of the latter, the column representing the set of individuals in the domain introduced by the focus constituent contained names of individuals, whereas in the case of the former the same column only contained numbers that were supposed to stand for different individuals in the domain.
Here we would like to call attention to one feature of the diagrams associated with items of types C–D, which could have led to unwanted effects: whenever there is a non-quantificational DP in focus position, the linear scope reading is true in both situations represented by the diagrams. According to the linear scope reading of (22), Klára is identical to the individual that tried on every dress (which is compatible with the fact that others tried on some but not all dresses, too), thus this reading is true in both situations depicted in Figure 3. The inverse scope reading says that for every dress, Klára is identical to the individual that tried on that dress (thus being incompatible with a situation where any of the dresses were tried on by somebody other than Klára). This reading is only true in the situation represented by the second diagram in Figure 3. As a result, whereas the first diagram is only compatible with the linear scope reading, the second diagram is compatible with both readings. This means that the choice of the second diagram among the two does not necessarily indicate that the speaker is opting for an inverse scope reading. Thus, it is expected that the higher rate of choices of the second diagram does not mean that the participants prefer the inverse scope reading. Moreover, the second diagram in Figure 3 is the simpler one among the two,9 thus it is quite likely that when speakers contemplate their choice, they first check whether the simpler diagram matches the reading they have in mind, and if it does, they do not study the other one. We come back to this issue in the course of discussing the results of the experiment.
The fillers used in the experiments consisted of a context description, an unambiguous sentence containing one or two QDPs, and two diagrams, presented side-by-side. The sentences appearing in the fillers realized three types of structure. In nine fillers, a proper name or adverbial in the topic position was followed by a verb and a postverbal QDP, illustrated in (24) below:
In nine other fillers sentences with one preverbal quantificational expression were used, as illustrated in (25):
The critical sentences in the third group of 18 fillers contained two preverbal quantificational expressions: the first one was situated in the topic or quantifier positions, and the second one in another quantifier position or in the preverbal focus position, illustrated in (26):
For fillers, there was a correct and an incorrect diagram choice, and this was also balanced left-right, though fixed for each filler.10
Eight presentation lists were created according to a latin square design, eight items per condition. Each list consisted of 100 trials, 64 of which were experimental trials and 36 fillers.
Order was a fixed pseudo-random order, such that critical quantifiers were not repeated next to each other, conditions per set were divided evenly between the first half and second half of the experiment, and diagram order was not repeated more than three times in a row.
Four fillers were used as practice items, and the remaining fillers were spread throughout the experiment pseudo-randomly.
In Experiments 1 and 2, participants were tested individually, with the help of a laptop computer and headphones. In Experiment 1, the procedure was the following. First, the three-sentence introductory text was displayed on the screen. Participants were asked to press a button after they had read the text, and then were presented with an experimental item or filler aurally. Next, a screen with the two diagrams appeared. Participants were asked to choose the diagram that corresponded better to the meaning of the critical or filler sentence in their opinion, by pressing the appropriate button on the keyboard. On the next screen, they were asked to provide ratings (between “1” and “7”, the latter being the best) as to their confidence in their choice. The intent of the confidence ratings was to help confirm that participants were not confused by the diagrams and simply guessing.
The experiments were put together using the software package DMDX (Forster & Forster 2003), which controlled stimulus presentation and recorded responses.
The procedure in Experiment 2 differed in one respect from the one described above. In this case, participants were asked to listen to the test sentences twice, both before and after seeing the diagrams (in case they were merely “forgetting” how the critical sentence was pronounced). As mentioned above, phonological stress was exaggerated by the recorded speaker in Experiment 2, to rule out the possibility that the stress manipulation in Experiment 1 was simply too subtle to be noticed.
For the two experiments, participants were recruited from various universities in Budapest (43 and 33 persons, mean ages: 23.6 and 24.3, respectively). They were all native speakers of Hungarian, and had received no previous training in linguistics. They received instructions on paper, and then were tested individually. Testing took approximately 50 minutes, and participants were paid 2500 HUF. Detailed instructions were given at the beginning of the protocol, and participants were allowed to ask questions following the practice items.
The results of the two experiments turned out to be interesting in several ways. First, they contradict the view according to which stress has an effect on the scope of postverbal quantifiers, and second, they indicate that scope judgments might be influenced by other grammatical features whose effects have not yet been investigated for Hungarian.
Figure 4 shows the overall proportion of inverse scope judgments across the two experiments. For both stressed and unstressed postverbal quantifiers, inverse scope judgments were given roughly 25 per cent of the time. This is in stark contrast with those reports in the literature that consider inverse scope judgments to arise exactly in those cases where the postverbal quantifier is stressed. As is also evident from Figure 4, the different prosodic realizations of the stimuli in Experiment 2 had virtually no impact on the results.
More interestingly, as Figure 5 indicates, there were some differences in scope judgments across the different postverbal QDPs: those containing the universal determiner minden ‘every’ received more inverse scope judgments than the others. However, the lack of effect of prosody on scope appears to hold across all of the quantifiers investigated. Finally, Figure 6 shows that these patterns are similar across Experiments 1 and 2.
The overall accuracy rate of fillers was 95% in Experiment 1 and 97% in Experiment 2. Thus, there were no concerns that response patterns may have been a result of participants simply not paying attention, or their inability to decipher the diagram stimuli.
We analyzed these results statistically with logistic mixed-effects (Gelman & Hill 2007; Jaeger 2008), using the lme4 package in the statistical software platform R (Bates et al. 2014; R Development Core Team 2011). We fit several models, corresponding to different sets of predictors, predicting the binary response of scope judgment (i.e. 0 = linear scope, 1= inverse scope). The most striking result here is a null result, demonstrating no effect of prosody. However, p-values obtained from standard null-hypothesis significance testing can only inform when a null hypothesis should be rejected, and cannot assess the degree of evidence for a null effect. That is, especially since these results run counter to strong claims by certain authors in the literature, it is not sufficient to merely demonstrate “non-significance” of the effect of prosody. Therefore, we carried out an Akaike weight analysis (see Burnham and Anderson 2002 for a comprehensive review, and Wagenmakers and Farrell 2004 for a brief, accessible tutorial), using the AICcmodavg package for R (Mazerolle 2015). In this type of analysis, model comparisons are made on the basis of the (corrected) Akaike Information Criterion (AICc), a commonly-used model-fit statistic. All candidate models are compared at once, and Akaike weights are computed, which represent the relative strength of evidence for each model as compared to the set of models, and which sum to 1 over the set of candidate models. The ratio of the Akaike weights between different models can be interpreted as relative strength of evidence.
In logistic mixed-effects models, random effects are specified in order to capture the hierarchical (e.g. repeated-measures) nature of the data. Following the recommendations of Barr et al. (2013), we fit random intercepts for subjects and items, but also the “maximal” random slopes for each model. That is, for any within-subject factor, we fit a random slope that allowed the effect to vary by subject, and the same for items. This is arguably the most appropriate way to model standard assumptions about possible between-item and between-subject variation, and the best way to generalize beyond the current set of subjects and items.
The first set of model comparison results is summarized in Table 4. Each row corresponds to a fit model, and marks indicate which factors and interactions were included in that model. The models are given in order from best (top) to worst (bottom), and the corresponding AICc values and Akaike weights are given in the rightmost columns.
The results in Table 4 very clearly rank the model with only QuantType as a factor (Model 1 in the table) as the best model. The next best model has QuantType and Prosody as predictors (without the interaction), but the ratio of Akaike weights between these models is 26-to-1 in favor of the model without Prosody. This indicates that not only is there a lack of evidence for a robust effect of prosody on scope judgments, there is strong evidence against an effect of prosody, such that among the factors investigated here (including prosody and its interactions with quantifier and experiment), a model with only QuantType as an explanatory factor is the far superior model.
For completeness, we also provide a coefficient table for Model 6 in Table 5, which is the model including the effects of Prosody, QuantType, and their interaction. Estimates, standard errors, and p-values are provided for each effect in the model, and on the right side of the table, the standard deviations are provided for the random effects in the model. Note that these random effect standard deviations are on the same scale as the effect estimates, thus giving a sense of how much variability was observed in the effects across items and subjects. The estimates themselves indicate the size of the effect in (log-odds) probability of an inverse scope judgment due to that factor, such that positive coefficients mean a greater probability of inverse scope judgments. Note also that because QuantType is a four-level factor, it must be dummy-coded into three effect coefficients. In the model represented in Table 5, legalább ‘at least’ is used as the “reference” level, and the coefficients represent how the other quantifiers differ from this one. Table 5 confirms what is shown in the graphs above, that inverse scope judgments are significantly more likely for the universal quantifiers, but there is no evidence of effects of prosody.
|Coefficients||Random effect std devs|
|QuantType (more than)||–0.02||0.21||.94||0.55||0.53|
|Pros × Q (every)||–0.20||0.27||.45||0.75||0.44|
|Pros × Q (many)||–0.34||0.35||.33||1.26||1.13|
|Pros × Q (more than)||–0.02||0.28||.95||0.56||0.77|
In contrast to this pattern of null effects for prosody, we found consistent effects of both the grammatical/thematic role of the postverbal quantifier and the type of preverbal operator, such that postverbal subjects (agents) took inverse scope more readily than objects/themes, illustrated in Figure 7, and postverbal quantifiers took inverse scope more easily over a non-quantificational focus than over focused number phrases, shown in Figure 8.
We conducted a similar analysis for these factors as before, applying the Akaike weight analysis for a series of logistic mixed-effects models. For these models, we included QuantType as a factor, but in order to simplify the models, we simplified the QuantType factor to a binary factor, since in the results above, the effect of QuantType reduced to a difference between minden ‘every’ and the others. In order to confirm that this simplification was justified, we carried out a larger set of model comparisons, and all of the models that reduced QuantType to a binary variable (minden ‘every’ vs. the others) were superior to models which kept them all separate. For reasons of space, we do not give the full details here, but the Akaike weight evidence ratio was well over 1000-to-1 for the binary-factor models, indicating very clear results. Therefore, in the following analyses we collapse the QuantType factor into a binary factor. Additionally, since no effects of Experiment or Prosody were observed above, we do not examine those factors here. The table of models is given in Table 6, along with the corresponding AICc values and Akaike weights. Since our items were constructed such that all grammatical subjects were also agents, we simply term this factor “Role.”
The results in Table 6 suggest that Role and FocType both play a role in affecting scope judgments, and furthermore that there is some interaction between these effects and the QuantType. The model coefficient table for the best model (Model 1 in Table 6) is given in Table 7. The statistical results confirm what is apparent in Figures 7 and 8, namely that there are clear effects of Role and FocType when the determiner of the critical postverbal QDP is minden ‘every,’ but with the other quantifiers, the effect is smaller for Role and not apparent at all for FocType.
|Coefficients||Random effect std devs|
|Role × Q (minden)||1.15||0.32||<.01||*||0.47|
|FocType × Q (minden)||1.56||0.36||<.01||*||1.53|
The results of the first two experiments can be summarized as follows. First, there appears to be no effect of prosody on scope judgments, even taking into account the exaggerated prosodic manipulations in Experiment 2. The results of the Akaike weight analysis indicate that this is not merely a “failure to reject” the null hypothesis, but rather that there is strong evidence for a null effect of prosody, at least in the context of this experimental paradigm.
Second, there is an overall bias towards linear scope interpretation, since inverse scope interpretations were chosen in much less than 50% of the cases. The fact that roughly a quarter of the responses indicated an inverse scope reading, even in the canonical structures where the postverbal quantifier is not stressed, appears problematic for the theories that postulate lack of ambiguity for a given prosodic realisation, e.g. those by É. Kiss and Hunyadi. The data are compatible with approaches that consider postverbal quantificational expressions to be scopally ambiguous with respect to preverbal focus, such as the ones proposed by Brody & Szabolcsi and by Surányi.
Third, universal DPs containing the determiner minden ‘every’ received many more inverse scope judgments than the other QDPs containing the determiners legalább n ‘at least n,’ több mint n ‘more than n,’ and sok ‘many.’ We discuss this further when we turn to certain methodological issues below. However, the null effect of prosody appeared to be the same across all quantifiers.
Finally, we observed effects of the Role of the postverbal QDP (subject/agent vs. object/theme) and the type of the focus constituent (non-quantificational DP vs. DP with a numeral determiner). However, these effects appeared to differ among the different postverbal QDPs. For DPs containing minden ‘every,’ there were robust effects: inverse scope readings were much more frequent when the postverbal DP was a subject/agent, and when the focus constituent was a non-quantificational DP (proper name). However, the effect of Role appeared to be much milder for the other quantifiers, and the effect of FocType appeared not to obtain for the other quantifiers at all.
While the experimental paradigm was based on previous work using these kinds of line-drawings to represent scope judgments (Gillen 1991; Jackson & Lewis 2005; Bott & Radó 2007), the technique is still somewhat novel, especially with such complex judgments as those in these experiments. Thus we raise several potential issues that might explain some of the results as methodological artifacts, and address them in turn.
First, there is the question of why universal DPs containing minden ‘every’ appear to behave differently. It seems that the QuantType effect in particular sentence frames can be accounted for in terms of the structure of the associated diagrams. As discussed in Section 3.1.1, in the case of sentence-frames of type C–D, where a non-quantificational DP occupies the focus position, the diagram that is supposed to represent the inverse scope reading (e.g. the second one in Figure 3) is actually compatible with both of the readings. Thus, the choice of this diagram, which is the simpler one among the two, in addition, is compatible with the speaker’s preference for a linear scope reading. These considerations suggest that the effect of FocType, which was only discernible in the case of DPs with minden ‘every’ is due to the particular methodology.
Second, with respect to the effect of Role, the finding that postverbal subjects take wide scope more easily over preverbal objects might also plausibly be due to the design of the diagrams: the entities in the set referred to by the subject DP were always on the left, with arrows pointing towards the entities referred to by the object/theme on the right. While this would not necessarily induce a bias, it is plausible that participants have mentally rehearsed the critical sentences in a way that matched the visual layout, which could lead to a bias. It is, however, unclear to us why such a bias would have a greater effect on universal DPs than on the others.
An anonymous reviewer for the paper notes, however, that since it is “intuitively inherently easier to judge that a predicate holds of a full set of items than that it holds for a subset of it” the pictures associated with the sentences containing universal DPs were easier to judge.11 We believe that these observations might reasonably account for why the effect of Role differs across the various quantifiers in the two experiments. The above considerations suggest that the effects of FocType and Role that were found in the course of the statistical analysis for QDPs with minden ‘every’ can be accounted for in terms of extra-grammatical (processing) and methodological factors.12
More generally, one might question the complexity of the methodology in effectively eliciting scope judgments. That is, one concern is that making judgments on complex line drawings like the ones used in these experiments is too difficult, and thus the results do not really reflect speakers’ intuitions. Although we cannot explicitly contradict this suggestion, there are some indications against it. First, the very low error rate with filler sentences, as discussed above, indicates that participants were closely attending to the stimuli and could interpret the diagrams appropriately. Second, participants provided extremely high confidence ratings, as shown in Figure 9, which might not have been the case if the task had been confusing.
Nonetheless, given the unexpected patterns of results, both the null effect of prosody as well as the novel effects of Role and FocType, we carried out a third experiment using the same materials, but in a different task, to see whether the same patterns would obtain.
The third experiment was designed to avoid potential difficulties arising from the use of diagrams to represent scope; it was based instead on a simple metalinguistic judgment task.
In Experiment 3, the same experimental items and fillers were used as in Experiments 1 and 2, including the 3-sentence texts setting up the context. The audio files were identical to those used in Experiment 1. For each item in each condition, we created an unambiguous paraphrase of the inverse scope reading that consisted of two preverbal QDPs, the scope of which is assumed by all theoretical accounts in the literature to be unambiguous. (27-a)–(27-d) illustrate the unambiguous13 paraphrases provided for (16)–(19) above:
In response to concerns about participants being fatigued by the length of Experiments 1 and 2, we took the same experimental lists that we used in the previous experiments, but only used the first half of each. This resulted in having 32 experimental trials (four in each condition) and 16 fillers in each list.
The participants were tested again individually with the help of a computer. First, the three-sentence context-description appeared on the screen. Next, the critical sentence was presented aurally. After this, the written paraphrase of the inverse scope reading appeared on the screen. On the next screen, the participants were asked to indicate on a five-point scale how well they thought the critical sentence matched the meaning of the (unambiguous) sentence presented in writing. (“1” stood for minimal and “5” for a great deal of similarity.)
Thirty-three participants (mean age: 27.2) without previous training in linguistics took part in the experiment, recruited again from universities in Budapest. They received 1500 HUF for their participation.
In order to simplify the discussion and analysis of results, we dichotomized the ratings such that responses of “1” or “2” were coded as “linear scope” judgments and responses of “4” or “5” as “inverse scope” judgments. Ratings of “3” were taken to be ambiguous or undecided, and were excluded from the statistical analysis. This decision is justified in part by the fact that the distributions of ratings peaked at “1” and “5”, indicating that the judgments were essentially binary judgments with some uncertainty superimposed. The patterns shown in the dichotomized results are the same as revealed by the full ordinal scale, and are easier to read and interpret. Therefore in the statistical analysis, we report the results of logistic mixed-effects models, comparable to the models fit for Experiments 1 and 2. We also fit ordinal mixed-effects models (using the ordinal package, Christensen 2015), which showed the same pattern of results as the logistic models reported below. But again, because the dichotomized results are easier to follow and interpret, we present only those here. Likewise, we focus on the binary QuantType variable, comparing the pattern of results for DPs with minden ‘every’ vs. the rest of the quantificational expressions, following the approach taken in the case of Experiments 1 and 2.
First we consider the effect of prosody on scope readings. Figure 10 shows the pattern of judgments, broken down by quantifier. If prosody had the effect reported in É. Kiss’s and Hunyadi’s works, the heights of the darker bars should be close to 1.00 (“inverse” judgment), and the heights of the lighter bars should be close to 0.00 (“linear” judgment). As Figure 10 shows, still no effect of prosody is observed. The only (non-significant) numerical trend is for minden ‘every’, in the opposite direction than expected.
The results of the model comparison analysis are given in Table 8, and the model coefficients for the full prosody by quantifier interaction (Model 5 in Table 8) in Table 9. Note that Experiment is no longer a factor because we are examining only the results of Experiment 3. These results unambiguously replicate the pattern of results from the first two experiments. Notably, the overall rates of inverse scope judgments are much higher than in Experiments 1 and 2. As in Experiments 1 and 2, inverse judgments are more acceptable with postverbal DPs containing the determiner minden ‘every’, though the effect is milder, and just shy of p < .05 significance (see Table 9). And just as in the other experiments, the Akaike weight analysis indicates strong evidence for a null effect of prosody. The model with only QuantType as a predictor is a much better model than a model with both QuantType and Prosody, with a 55-to-1 evidence ratio.
|Coefficients||Random effect std devs|
|Pros × Q (minden)||–0.57||0.52||.27||1.33||0.23|
Experiment 3 also replicated the pattern of results regarding the effects of Role and FocType. Figures 11 and 12 show that postverbal subjects take inverse scope more easily, and that inverse scope is more acceptable when the constituent in focus position is a non-quantificational DP. Interestingly, in this experiment, these effects are evident across the different quantifiers, and not exaggerated for minden ‘every’ DPs.
The statistical analysis also reflects this pattern. The model comparison results are given in Table 10. The two best models are the model with only simple effects of QuantType, Role, and FocType, and the model with the addition of the QuantType × Role interaction. The Akaike weights are not strong enough for either of these to decide between them. However, the evidence is extremely strong for the top five models together, which all have in common the effects of QuantType, Role, and FocType. Thus, we cannot make strong claims as to the presence of possible interactions between these, but clearly these factors are important for explaining the data. As mentioned above, Experiment 3 used only half the items as Experiment 1 and 2. The cost of this reduction is a loss in power to be able to clearly test the various potential interactions between these factors. However, the simple effects of the factors are still very evident.
In order to more easily compare these results to the previous results, we give the coefficients and random effects for Model 3 in Table 11, which corresponds to the same model that is given above in Table 7. The differences between these corroborate what we see in the figures, namely, that the effects of Role and FocType in Experiment 3 appear to be very consistent across types of postverbal quantifiers.
|Coefficients||Random effect std devs|
|Role × Q (minden)||–0.46||0.92||.62||2.60|
|FocType × Q (minden)||1.50||1.33||.26||3.19|
The results of Experiment 3 can be summarized as follows. First, there is strong evidence, again, against any effect of prosody on scope judgments. Second, inverse scope readings appear to be overall more tolerated compared to Experiments 1 and 2. Third, inverse scope readings appear more acceptable for minden ‘every’ DPs than for the rest, but with a milder difference than what was observed in Experiments 1 and 2. Fourth, the effects of Role and FocType are in the same pattern as in Experiments 1 and 2, but more consistent across the various types of postverbal quantifiers, with no difference between the effects observed for minden ‘every’ DPs vs. the others.
The most important finding of the current experiment is the lack of any effect of prosody on inverse scope, which replicates the findings of Experiments 1 and 2. The apparent “inflation” of inverse scope judgments is most certainly due to the methodology, since the judgments requested from the participants were concerned with the issue of whether inverse scope readings were possible, and not whether they were preferred, as in the previous experiments.
It is particularly interesting that in this last experiment DPs with legalább ‘at least’, több mint ‘more than’ and sok ‘many’ turned out to be less different from those containing minden ‘every’, regarding the acceptability of inverse scope readings. This fact seems to provide additional support for the views discussed in sections 3.1.1. and 3.2, according to which the larger proportion of “inverse” judgments for QDPs containing minden ‘every’ in the case of Experiments 1 and 2 were due to extra-grammatical factors, namely, the nature of the experimental task, particularly the structure of the diagrams. Role and FocType, however, do seem to influence the proportion of “inverse” judgments in Experiment 3, where their effect cannot be attributed to features of the graphical representation. This finding is in need of explanation.14
In Section 2 the claim by Brody & Szabolcsi (2003) was mentioned, according to which some speakers are sensitive to the presence of stress on a postverbal QDP, and opt for an inverse scope reading only in the latter case, while others are insensitive to prosody. The question arises whether the proportions of “inverse” judgments shown in Figure 10 are the result of averaging the answers by two different dialect groups displaying distinct behaviour.15
In order to provide an answer, the data based on the generalized linear mixed models for Experiment 3 were inspected, where both Subject and Item were included as random effects.
The distribution of random slopes for each subject is shown in Figure 13 as a histogram. Positive slopes indicate that listeners more frequently accept inverse scope interpretations if the quantifier is stressed. Slopes around 0 show no bias in the answers, i.e. no influence of stress on the responses. Negative slopes indicate that the presence of stress increases the preference of linear scope interpretations. Based on this, if participants belonged to two separate dialects based on their sensitivity to the presence of stress, one peak with positive values for slopes and another one around 0 would be expected.
As can be seen in Figure 13, this is not the case. In fact, most slopes center around 0. Slightly negative slopes between –0.2 and –0.1 are the most frequent. Thus, these values do not show that slope values would cluster in two groups.
The three experiments discussed here provide new empirical results regarding scope judgments in Hungarian. On the one hand, all three experiments showed a greater degree of scopal ambiguity than predicted by influential work by É. Kiss (1987; 1992; 2002; 2010a) and Hunyadi (1996; 1999; 2002), reviewed in Section 2. On the other hand, we found a clear general preference for linear scope in the particular domain we investigated. It is possible that these results are due to the sheer difficulty of rendering scope judgments, but this raises a general problem with assessing scope judgments empirically. If it is difficult to elicit complex scope judgments, then to what extent can we argue that they are “underlyingly” clear and unambiguous, when that does not appear to match observed behavior?
All three experiments presented here show evidence for a complete lack of effect of stress on the scope of postverbal quantificational expresssions in Hungarian over a preverbal exhaustive/identificational focus. This raises the question of why our results clash with previous reports from the literature. One possibility is that the phonology of the items was not correct. We undertook Experiment 2 in order to exaggerate the phonological stress on the postverbal quantifier, but this had no effect. Therefore, if it is the case that the phonological stress was not sufficient to induce the expected inverse scope judgments, then there must be some more subtle phonological difference between the prosody in our materials and the prosody necessary for the previously reported effect. This would be somewhat surprising, but if true, could provide some interesting insight into the nature of the prosodic representation necessary for the effect.
Another possibility is that the previously reported effect of prosody is a type of illusion. It is possible that speakers “feel” a difference between inverse -scope and linear scope readings, and when trying to make a distinction, they produce the inverse scope with a non-canonical stress pattern. However, even if true, this does not necessarily mean that listeners will consistently interpret this phonological change as a change in scope. That is, there may be a dissociation between production and perception when it comes to a link between prosody and scope in Hungarian. In introspective judgments, the fact that the speaker and listener/judge are the same person could give rise to an illusory connection.
Either of these possibilities suggests future research, which is beyond the scope of the present paper. Thus, at this juncture we can conclude at least that if an effect of prosody on scope judgments exists in Hungarian, it is more delicate than typically reported in É. Kiss’s and Hunyadi’s works, and the precise conditions under which it holds should reveal a great deal about the nature of the effect.
The preference for the linear scope interpretation that we have observed in all of our experiments seems to be in line with traditional accounts like Fodor (1982), Johnson-Laird (1969) and Lakoff (1971), or recent accounts that assume a soft constraint favoring correspondence between word order and scope interpretation, independently of syntactic hierarchy, including Bobaljik (1995; 2002), Bobaljik & Wurmbrand (2012), Broekhuis (2008), Reinhart (2005), Müller (2000; 2002), and Williams (2003).16 The processing experiments discussed in Tunstall (1998) and Anderson (2004) involving doubly quantified sentences indicated a “default preference” for the linear scope interpretation, which the authors attribute to a lower degree of processing complexity.
In addition to the lack of effect of prosody, our results identified two new factors influencing scope judgments in Hungarian, the role of which has not yet been discussed widely in the literature. On the one hand, postverbal quantifiers appear to take scope over a non-quantificational (exhaustive/identificational) focus more easily than over a focused DP containing a numeral determiner. On the other hand, postverbal quantifiers that are grammatical subjects (and also agents, in our materials) appear to take wide scope more easily than grammatical objects/themes. This was the most robust effect replicated across all three experiments. In section 3.2, we considered how the construction of the diagrams in Experiments 1 and 2 could have given rise to these results. The fact that the results of Experiment 3 very clearly replicated the same effects suggests that they cannot merely be artifacts of the diagram methodology.
It appears that the effect of Role described above is more compatible with a hierarchical VP, proposed in Surányi (2006) and É. Kiss (2008), where the base positions of subjects c-command those of objects. A discussion of the exact mechanisms that would enable postverbal subjects taking scope over preverbal focus more often than postverbal objects in these frameworks, however, will have to be left for a future occasion.
The research reported on in this paper aimed to test the claim that postverbal distributive quantifiers take wide scope over preverbal focus in Hungarian if and only if they are stressed. It was shown that the results of three perception experiments, which followed two different experimental paradigms, lead to a null effect of stress on scope, but point to a complex interaction of quantifier type, thematic/grammatical role of quantifier and type of constituent in the focus position in determining the scope of postverbal quantifiers, which is discussed here for the first time. The discussion leaves many issues open for the moment, including the question of the theoretical modelling of the findings, or the role of other factors (e.g. that of context) in determining scope interpretation.17
1The other frameworks discussed in Section 2 share É. Kiss’s assumptions on the preverbal ordering of different constituent types, though not necessarily her views on how it should be modeled.
2Note that the reason why the immediately preverbal constituent in (2) is taken to occupy [Spec,FocP], and not a second [Spec,DistP] position, for example, is that the verbal prefix meg, situated immediately in front of the verb in the absence of focus, is found in a postverbal position. Verbal prefixes belong to the class of verbal modifiers, and are thus glossed as ‘VM’ here.
3The specifics of the interpretation of the constituent in [Spec,FocP], which are also reflected in the English translations, will be discussed below.
4Szabolcsi does not provide an English translation for this sentence. The translation given here is modeled after her translation of an analogous example.
5An analogous proposal in a different framework is made by van Leusen & Kálmán (1993). The same observation, namely, that the preverbal focus constituent (or an accented subconstituent thereof) identifies the unique holder of the property described by the rest of the sentence underlies the proposal defended in É. Kiss (2006; 2009) about focus being an identificational predicate. For a detailed summary of the reasons why structural focus in Hungarian must be attributed an exhaustive interpretation see É. Kiss (2010b).
6Readers who find translations like the one in (4-b) or (6-a) clumsy can, however, substitute the cleft for an only-phrase for comprehensibility, since it will not lead to truth-conditional differences in the case of the examples discussed in this paper. Thus, an alternative translation for (4-b) would be the following: János only missed the bus.
7The assumption that the constituents in the preverbal focus position of the Hungarian sentence have an exhaustive or identificational reading has recently been called into question by researchers on the basis of certain processing experiments, e.g. Onea & Beaver (2011), Kas & Lukács (2013), and Gerőcs et al. (2014). However, we are not convinced that the experimental data reported on in these papers necessarily forces one to the conclusions drawn by the respective authors. It appears to us that they can also be accounted for by attributing special flexibility to the domain of alternatives activated by the constituent in focus position. Experimental support for the latter approach is provided by É. Kiss & Zétényi (2017).
9We thank an anonymous reviewer for calling attention to this fact.
10The full list of the original Hungarian experimental items and fillers, together with their English translations, can be found in a supplementary file referenced in Section 6.
11This suggestion is corroborated by the fact that confidence ratings are in general significantly higher for sentences containing minden- ‘every’ phrases than for the others, and that they drop slightly (by about half a point) in the case of inverse scope judgments for quantificational expressions other than those containing minden ‘every’.
12We thank an anonymous reviewer for suggestions regarding possible interpretations of the relevant data.
13A reviewer points out a potential problem with the paraphrases used for sentences containing universal DPs, illustrated in (27-a). As noted first in Szabolcsi (1981), and discussed by É. Kiss (2002) and Gyuris (2009), among others, if universal quantifiers preceding the focus or the negative particle are pronounced with a specific, (fall)-rise (“contrastive topic”) intonation, they get a narrow scope reading with respect to these operators. The reviewer argues that since the paraphrases were presented in writing, the experiment did not control for their pronunciation, and thus it is possible that the participants assigned them a reading where the universal quantifier actually took narrow scope. Although we were aware of this problem, we still opted for presenting the paraphrases containing the universal DP with the help of the simpler structure illustrated in (27-a), instead of the more complex one shown in (27-b)–(27-d) because we assumed, following the literature, that in the absence of contextual support for the contrastive topic interpretation, speakers will have no reason to believe that the paraphrases were intended to be pronounced with the (fall-)rise.
14One of the anonymous reviewers of the paper challenges the view that if a result that can be shown by the statistical model to be relevant it should indeed be treated as interesting and requiring an explanation. Although we do find this approach reasonable, we would prefer to have some explanations for the results obtained in the course of the experiments. In the next section we consider some possibilities.
15Analysing the data from this perspective was recommended to us by two anonymous reviewers.
16We thank one of the anonymous reviewers for pointing out this connection to us.
17The results of a rating study by Surányi & Turi (2017), which aimed to test the suggestions made in Gyuris (2006) on the possible interactions between the scope of postverbal QDPs and their information structural properties, however, argue against there being a consistent pragmatic effect of the focus status on the scope of postverbal universal quantifiers.
ACC = accusative, DAT = dative, 3SG = third person singular, 3PL = third person plural, VM = verbal modifier
All participants gave their informed consent to participate in this study. The research protocol was approved by the Ethics Committee of the Research Institute for Linguistics, HAS (28 February 2010).
We thank the three anonymous reviewers for their detailed comments on two previous versions of the paper, the editors of the special issue for their support, and the participants of the Workshop on “Quantifier Scope: Syntactic, Semantic, and Experimental Approaches” at IKER, Bayonne, in June 2014, the participants of a mini-workshop on quantifier scope in Tübingen in March 2013, particularly Oliver Bott and Janina Radó, and audiences at the Research Institute for Linguistics, Budapest, for advice and criticism. We are indebted to Janina Radó for her support of the project throughout its various stages, to Katalin Mády for her invaluable help with the statistic analysis in Section 4.2, to Zoltán G. Kiss for assisting us with formatting issues, as well as to Oliver Bott, Csaba Olsvay, Frank Richter, Uli Sauerland, Wolfgang Sternefeld, Balázs Surányi, Gergő Turi and Kazuko Yatsushiro for discussions, and to Gabriella Felhősi, Angelika Kiss, and Cecília Sarolta Molnár for their help in the course of preparing and conducting the experiments.
The research reported on in the paper was supported by the Hungarian Scientific Research Fund (OTKA), under projects F 68139 and NF 84217.
The authors have no competing interests to declare.
Barr, Dale J., Roger Levy, Christoph Scheepers & Harry J. Tily. 2013. Random effects structure for confirmatory hypothesis testing: Keep it maximal. Journal of Memory and Language 68(3). 255–278. DOI: https://doi.org/10.1016/j.jml.2012.11.001
Bates, Douglas, Martin Mächler, Ben Bolker & Steve Walker. 2014. lme4: Linear mixed-effects models using eigen and s4. https://cran.r-project.org/web/packages/lme4/index.html. R package version 1.1-7.
Bobaljik, Jonathan David. 2002. A-chains at the PF-interface: Copies and ‘covert’ movement. Natural Language and Linguistic Theory 20(3). 197–267. DOI: https://doi.org/10.1023/A:1015059006439
Bobaljik, Jonathan David & Susi Wurmbrand. 2012. Word order and scope: Transparent interfaces and the 3/4 signature. Linguistic Inquiry 43(3). 371–421. DOI: https://doi.org/10.1162/LING_a_00094
Bott, Oliver & Janina Radó. 2007. Quantifying quantifier scope: A crossmethodological comparison. In Sam Featherson & Wolfgang Sternefeld (eds.), Roots: Linguistics in search of its evidential base, 53–74. Berlin/New York: Mouton de Gruyter.
Bott, Oliver, Sam Featherston, Janina Radó & Britta Stolterfoht. 2011. The application of experimental methods in semantics. In Claudia Maienborn, Klaus von Heusinger & Paul Portner (eds.), Semantics: An international handbook of natural language meaning 1. 305–321. Berlin: de Gruyter. DOI: https://doi.org/10.1515/9783110226614.305
Brody, Michael & Anna Szabolcsi. 2003. Overt scope in Hungarian. Syntax 6. 19–51. DOI: https://doi.org/10.1111/1467-9612.00055
Christensen, Rune Haubo Bojesen. 2015. ordinal: Regression models for ordinal data. https://cran.r-project.org/web/packages/ordinal/index.html. R package version 2015.1-21.
Csirmaz, Anikó & Anna Szabolcsi. 2012. Quantification in Hungarian. In Edward L. Keenan & Denis Paperno (eds.), Handbook of quantifiers in natural language, 399–465. Dordrecht: Springer. DOI: https://doi.org/10.1007/978-94-007-2681-9_8
É. Kiss, Katalin. 1992. Az egyszerű mondat szerkezete [The structure of the simple sentence]. In Ferenc Kiefer (ed.), Strukturális magyar nyelvtan I: Mondattan [A structural grammar of Hungarian I: Syntax], 79–177. Budapest: Akadémiai Kiadó.
É. Kiss, Katalin. 1998. Identificational focus versus information focus. Language 74. 245–273. DOI: https://doi.org/10.1353/lan.1998.0211
É. Kiss, Katalin. 2006. Focussing as predication. In Valéria Molnár & Susanna Winkler (eds.), The architecture of focus, 169–193. Berlin/New York: de Gruyter. DOI: https://doi.org/10.1515/9783110922011.169
É. Kiss, Katalin. 2008. Free word order, (non)configurationality, and phases. Linguistic Inquiry 39. 441–475. DOI: https://doi.org/10.1162/ling.2008.39.3.441
É. Kiss, Katalin. 2010a. An adjunction analysis of quantifiers and adverbials in the Hungarian sentence. Lingua 120. 506–526. DOI: https://doi.org/10.1016/j.lingua.2009.01.003
É. Kiss, Katalin. 2010b. Structural focus and exhaustivity. In Malte Zimmermann & Caroline Féry (eds.), Information structure: Theoretical, typological, and experimental perspectives, 64–88. Oxford: Oxford University Press. DOI: https://doi.org/10.1093/acprof:oso/9780199570959.003.0004
Fodor, Janet D. 1982. The mental representation of quantifiers. In Stanley Peters & Esa Saarinen (eds.), Processes, beliefs and questions, 129–164. Dordrecht: Reidel. DOI: https://doi.org/10.1007/978-94-015-7668-0_5
Forster, Kenneth I. & Jonathan C. Forster. 2003. DMDX: A windows display program with millisecond accuracy. Behavior Research Methods, Instruments, & Computers 35(1). 116–124. DOI: https://doi.org/10.3758/BF03195503
Gerőcs, Mátyás, Anna Babarczy & Balázs Surányi. 2014. Exhaustivity in focus: Experimental evidence from Hungarian. In Joseph Emonds & Marketa Janebova (eds.), Language use and linguistic structure, 181–194. Olomoucz: Palacky University. DOI: https://doi.org/10.5507/ff.14.24440606.13
Gyuris, Beáta. 2006. Esettanulmány a hatókör és az információs szerkezet kapcsolatáról [A case study on the connection between scope and information structure]. In László Kálmán (ed.), KB 120 – a titkos kötet: Nyelvészeti tanulmányok Bánréti Zoltán és Komlósy András tiszteletére [KB 120 – the secret volume: Linguistic studies in honour of Zoltán Bánréti and András Komlósy], 103–116. Budapest: MTA Nyelvtudományi Intézet – Tinta Könyvkiadó.
Gyuris, Beáta. 2008. Stylistic postposing or something else? In Christopher Piñón & Szilárd Szentgyörgyi (eds.), Approaches to Hungarian 10: Papers from the Veszprém conference, 187–216. Budapest: Akadémiai Kiadó.
Hunyadi, László. 1996. Hungarian sentence structure and metrical prosody. Language Sciences 18. 139–152. DOI: https://doi.org/10.1016/0388-0001(96)00012-5
Hunyadi, László. 1999. The outlines of a metrical syntax of Hungarian. Acta Linguistica Hungarica 46. 69–93. DOI: https://doi.org/10.1023/A:1009677808603
Jaeger, T. Florian. 2008. Categorical data analysis: Away from ANOVAs (transformation or not) and towards logit mixed models. Journal of Memory and Language 59(4). 434–446. DOI: https://doi.org/10.1016/j.jml.2007.11.007
Johnson-Laird, Philip. 1969. On understanding logically complex sentences. Quarterly Journal of Experimental Psychology 21. 1–13. DOI: https://doi.org/10.1080/14640746908400187
Kas, Bence & Ágnes Lukács. 2013. Focus sensitivity in Hungarian adults and children. Acta Linguistica Hungarica 60(2). 217–245. DOI: https://doi.org/10.1556/ALing.60.2013.2.4
Kenesei, István. 1986. On the logic of word order in Hungarian. In Werner Abraham & Sjaak de Meij (eds.), Topic, focus and configurationality, 143–159. Amsterdam: John Benjamins. DOI: https://doi.org/10.1075/la.4.08ken
Lakoff, George. 1971. On generative semantics. In Danny D. Steinberg & Leon A. Jakobovits (eds.), Beyond expressives: Explorations in conventional non-truthconditional meaning, 232–296. Cambridge: Cambridge University Press.
Mazerolle, Marc J. 2015. AICcmodavg: Model selection and multimodel inference based on (Q)AIC(c). https://CRAN.R-project.org/package=AICcmodavg. R package version 2.0-3.
Müller, Gereon. 2002. Two types of remnant movement. In Artemis Alexiadou, Elena Anagnostopoulou, Sjef Barbiers & Hans-Martin Gärtner (eds.), Dimensions of movement: From features to remnants, 209–242. Amsterdam: John Benjamins. DOI: https://doi.org/10.1075/la.48.10mul
Onea, Edgar & David Beaver. 2011. Hungarian focus in not exhausted. In Satoshi Ito Cormany & David Lutz (eds.), Proceedings of the 19th semantics and linguistic theory conference: SALT 19, 342–359. Ithaca: Cornell University. DOI: https://doi.org/10.3765/salt.v19i0.2524
R Development Core Team. 2011. R: A language and environment for statistical computing. The R Foundation for Statistical Computing, Vienna, Austria. https://www.R-project.org.
Surányi, Balázs. 2004. The left periphery and cyclic spellout: The case of Hungarian. In David Adger, Cécile de Cat & George Tsoulas (eds.), Peripheries: Syntactic edges and their effects, 49–73. New York, Boston, Dordrecht, London, Moscow: Kluwer. DOI: https://doi.org/10.1007/1-4020-1910-6_3
Surányi, Balázs. 2006. Scrambling in Hungarian. Acta Linguistica Hungarica 53. 393–432. DOI: https://doi.org/10.1556/ALing.53.2006.4.2
Surányi, Balázs & Gergő Turi. 2017. Focus and quantifier scope: An experimental study of Hungarian. In Harry van der Hulst & Anikó Lipták (eds.), Approaches to Hungarian 15: Papers from the 2015 Leiden conference, 209–238. Amsterdam: John Benjamins. DOI: https://doi.org/10.1075/atoh.15.08sur
Szabolcsi, Anna. 1981. Compositionality in focus. Folia Linguistica 15. 145–165. DOI: https://doi.org/10.1515/flin.1981.15.1-2.141
Szabolcsi, Anna. 1997. Strategies for scope taking. In Anna Szabolcsi (ed.), Ways of scope taking, 109–154. Amsterdam: Kluwer. DOI: https://doi.org/10.1007/978-94-011-5814-5_4
Szabolcsi, Anna. 2010. Quantification. Cambridge: Cambridge University Press. DOI: https://doi.org/10.1017/CBO9780511781681
Wagenmakers, Eric-Jan & Simon Farrell. 2004. AIC model selection using Akaike weights. Psychonomic Bulletin & Review 11(1). 192–196. DOI: https://doi.org/10.3758/BF03206482