A central question in translation studies (TS) has been whether translation is a sequential or a parallel process. The sequential view (Seleskovitch 1976; see also Gile 1995 and Angelone 2010) holds that source text (ST) content is decoded and deverbalised before being reformulated as target text (TT); according to this so-called deverbalisation hypothesis, the form of the ST is lost before target language processing occurs. In this view, processing would shift back and forth between ST and TT at certain intervals, each interval including processing in one of the two languages only. By contrast, the parallel view (Gerver 1976) states that ST and TT processing occur in parallel, with the consequence that purely formal aspects of the ST may be transferred to the TT.

The traditional distinction between sequential and parallel processing provides two opposing but simplified views of possible information processing routes during translation. However, the distinction falls short of capturing the complex nature of translation processing. In this paper, we will discuss and refine the traditional TS definitions of parallel and sequential processing and consider the distinction between parallel and sequential processing from a cognitive perspective. A cognitive approach to translation processing is likely to offer a richer and more nuanced basis for considering the matter of parallel and serial processing in translation and for understanding translation as a function of cognitive activity.

From a cognitive viewpoint, parallel processing in translation is when translation processes overlap, and sequential processing is when translation processes do not overlap. While it is not possible for a person to devote attention to two tasks at the same time, it is possible for a person to devote cognitive resources to two tasks at the same time where one of those tasks is at the centre of attention and the other task is performed without attentional resources being devoted to its execution. In translation, the ability to use such subconscious processing, or automaticity, has been suggested as an explanation of why skilled translators can produce translation faster and better than novice ones (Jääskeläinen and Tirkkonen-Condit 1991; Hvelplund 2011).

Based on work by Kintsch (1998) and Kellogg (1996), Hvelplund (2011: 48-58) provides an itemisation of (some of) the cognitive processes involved in translation. The stages involved in ST processing include initial orthographic analysis of the characters manifested in the ST and lexical and propositional analyses of the ST meaning. The stages involved in TT processing include identification of target language equivalents to represent the meaning of the ST words and verification of meaning congruence between the TT representation and the ST representation. Thus, in parallel processing, several processes which are relevant to the processing of the translation run simultaneously. For instance, when reading a ST word, a TT processing stream is triggered, during which possible target language realisations of the ST word or segment are considered more or less at the same time. Conversely, in sequential processing, any consideration of possible target language realisations of the ST word or segment is postponed until comprehension of the ST segment is finalised.

Hvelplund (2011) found that translators regularly engage in simultaneous source text reading and target text typing during the translation process; though parallel processing is not necessarily restricted to situations where it is so explicitly manifested, this is clear evidence that parallel processing does actually take place, for both the student and the experienced translators involved in Hvelplund’s study. Dragsted (2010) reports similar evidence of simultaneous ST reading and TT typing (which she calls integrated processing), especially for professionals. Further, the differences between reading for comprehension and reading for translation observed by Jakobsen and Jensen (2008) also point in the direction of parallel processing.

We hypothesise that parallel processing is not restricted to such explicit cases as those shown by Hvelplund (2011) and Dragsted (2010), but that anticipation of the TT is ubiquitous during source language processing. There is some support for this hypothesis in the work of Ruiz, Paredes et al. (2008) and Macizo and Bajo (2006) from the University of Granada. These authors present evidence that properties of words (cognateness and ST frequency) and syntactic structures (congruence of adjective-noun order) in the source language affect target language processing. The evidence comes from experiments where ST sentences were presented to translators one word at a time, using self-paced presentation, and the translators were asked to either repeat the sentence or translate it orally into English. When participants were reading source language words with the object of translating them later, the frequency of target language translations, which was manipulated in Experiment 1 of Ruiz and colleagues (2008), affected the reading of the source language words, whose frequency was kept constant. Similarly, Macizo and Bajo (2006) found effects of cognateness between source and target language words on source language reading when participants were reading for later translation, but not for normal monolingual reading. Thus, the results of the Granada group are in line with our hypothesis, but the evidence comes from a rather artificial task.

In contrast to the Granada group, we tested the hypothesis that processing is parallel in a naturalistic experimental setup, asking professional translators to translate while their eye movements were monitored. There are several advantages to this: In addition to the fact that a naturalistic task is desirable, this setup allows us to measure processing online. Further, the task relates specifically to translation, whereas the task used by the Granada group is in a way a hybrid between translation and interpreting, because the source text is presented one word at a time and because the target text is produced orally.

The hypothesis that translation is parallel is tested using differences in subject-verb (SV) order between English and Danish declarative clauses. English declarative main clauses have what we call SV order, the subject always precedes the verb. In Danish declarative main clauses, by contrast, the order of subject and verb is determined by the principle of verb second or V2, which refers to the fact that the finite verb is always the second constituent of the sentence. V2 has the consequence that if the subject is the first constituent of the main clause, Danish has SV order, which is categorised as the canonical word order. An example could be the sentence Det sker i dag (literally: It happens today). Very often, however, an adverbial is the first constituent in the main clause, the verb is still in second position and the subject third, that is, verb-subject (VS) order as in the clause I dag sker det (literally: Today happens it). In other words, the order of subject and verb in a Danish declarative main clause may be congruent with its English translation if it has SV order, or incongruent if it has VS order. If translation is sequential, this congruence should not affect processing time in translation from Danish to English, while we would expect differences between congruent and incongruent segments if translation is a parallel process.

The subject-verb order variation between Danish and English is well-suited for this investigation because it is purely formal; although VS order contributes to marking non-subject focus in Danish sentences, a similar focus is achieved in English translation equivalents that have SV order purely by fronting of the adverbial. Interestingly, although VS order is normally categorised as non-canonical in Danish, it is quite frequent – large-scale statistics of this for Danish do not exist, but in the other V2 languages, including Swedish, which is closely related to Danish, VSorder is found in approximately 40% of declarative main clauses (Håkansson 1997).

The main hypothesis of the experiments reported below is that translation is a parallel process. The parallel processing would apply to both congruent and non-congruent segments, but would have the consequence for non-congruent segments that they should be more difficult to process, because they require a reordering of constituents. We test this using professional translators as participants in Experiment 1 (see section 2). Because our participants were professional translators and the difference between English and Danish that we are investigating is a very basic one, we do not expect a large congruence effect on production time – and much less an effect on the actual product, resulting in grammatical errors – but we do expect an effect on ST reading time. Such an effect would indicate that the translators anticipate the TT structure while reading the ST and as such would provide evidence of parallel processing.

We index processing difficulty in three different ways: Firstly, we analyse for how long the translators gaze at the congruent (SV) as opposed to the non-congruent (VS) segments in the ST. Based on the eye-mind assumption (Just and Carpenter 1980), longer gaze times are taken as evidence of more difficult processing. Therefore, we hypothesise that VS segments will elicit longer gaze times than SV segments, when a range of other variables are controlled (see section 2.2 below). The total gaze time measure includes all fixations on the given segment, but excludes saccadic activity because the eye is generally believed to be blind during saccades (Rayner 1998: 378). There are alternative indicators of fixation activity, for example length of single fixations and first pass reading time which may be obtained with the equipment used here (see Balling 2013), but for the reading of clause-level segments, the more aggregated total gaze time is the more meaningful measure. The number of fixations on the segments may also be analysed, but this does not provide any new information compared to the total gaze time.

Secondly, variation in pupil dilation during attention to the relevant ST segments is analysed. Generally, larger pupils are associated with heavier cognitive load (Iqbal, Adamczyk et al. 2005) and we hypothesise that participants’ pupils will be more dilated during reading of VS segments in the ST than during reading of SV segments. Pupil dilation is an interesting supplementary measure because, in contrast to gaze time, it is not under conscious control. Pupil dilation was registered for each 20 ms gaze sample on the critical segments, so, in contrast to total gaze time, pupil dilation is not an aggregate measure. This means that the pupil dilation analyses are based on a larger number of datapoints which is an advantage for the statistical techniques. Previous research has shown that pupils constrict and dilate with some delay relative to the presentation of a stimulus (see Hvelplund 2011: 70 for an overview). It was necessary to take this delay into account; therefore the pupil size values that were used to calculate pupil dilation variation were taken from gaze samples which occurred 100 ms after a fixation inside a critical segment, based on the approach by Hvelplund (2011).

Thirdly, the translation product is considered in an analysis of what the translators typed during the task, using Translog (Jakobsen and Schou 1999). In a quantitative analysis, which is our focus here, we may observe longer production time for the non-congruent VS segments than for the congruent SVsegments as a consequence of longer pauses between key presses and more mistakes made in the non-congruent segments, but given the experience of the participants, we do not expect a large effect.

In order to test whether the effects observed in Experiment 1 are specific to translation, Experiments 2 and 3 investigate reading of the source texts of Experiment 1 by first (L1) and second (L2) language readers (see sections 3 and 4).

The results were analysed using linear mixed-effects regression models in the statistical environment R (version 2.13.1, R development core team 2011),[3] using the packages lme4[4] and languageR.[5] There are several advantages to this analysis approach. On the most general level, the use of inferential rather than purely descriptive statistics (such as percentages and means) allows us to say much more confidently whether any effects observed in our data are likely to apply more generally to the translation process; if effects are significant at the .05-level, we assume that this is the case.

More specifically, a regression approach is useful because it allows statistical control of a range of variables which would otherwise have to be controlled experimentally or constitute noise in the analysis. This means that we can investigate the effect of congruence once we have taken other relevant factors, such as word frequency and segment length, into account. If such variables had to be controlled experimentally, the result would be fewer and more unrepresentative items. For a formal discussion of these issues, see Baayen, Davidson et al. (2008), for a more informal one, see Balling (2008). The fact that these variables can be included in the analysis also serves to make the experiments more informative, an advantage in any kind of research but perhaps especially in a relatively young field such as translation process research.

For the present experiments, we analyse three dependent variables – the indicators of translation processing load outlined in section 1.2 – and different categories of independent variables, or predictors. Both the dependent variable total gaze time and the predictor word frequency had skewed distributions that are typical of reaction times and lexical frequencies; in order to minimise the harmful impact of outliers, gaze time was logarithmically transformed (but shown untransformed in the Figures for ease of interpretation) and word frequency was square root transformed. Both transformations are standard practice in psycholinguistics, experimental psychology and a range of other disciplines where real data are involved (Bartlett 1947; Box and Cox 1964; Howell 2007; Johnson 2008; Myers and Well 2003; see also the guidelines for dealing with skewed data from the Royal Society of Medicine Press).[6] What the transformations do is equate larger distances at the higher end of the scale with smaller distances at the lower end of the scale of a given variable. This is particularly intuitive for a measure like frequency where the difference in speakers’ and readers’ familiarity is likely to be bigger when frequency jumps from 1 to 10 occurrences per million words than when it jumps from 101 to 110 occurrences. For the reading times, the log transformation means that differences in reading time at the lower end of the scale have more weight than reading times at the higher end of the scale; though primarily motivated by the fact that it is necessary for the statistical procedure, this also makes some sense since very long reading times may reflect processes other than the ones we are most interested in.

Turning to the predictors, our most important predictor is of course congruence, which is a factor with two levels: congruent (SV) vs. incongruent (VS). Additionally, we included two categories of control predictors.

First, we have predictors that are inherent to the words and AOIs, namely the mean frequencies of words and letter bigrams in the AOIs, the length of the AOIs in letters and whether the AOIs contained words that were cognate between ST and TT. The frequencies were extracted from a combination of two corpora of contemporary Danish, Korpus90[7] and Korpus2000;[8] the word frequencies used were the frequencies of the whole word forms, rather than the lemmas. For the mean word frequency, we included only the content words in the AOI, since function words are likely to be skipped by the eye (Rayner 1998) and moreover are generally of such high frequency as to distort the mean frequency considerably. These ST related predictors are likely to be more important in the analyses of gaze time and pupil dilation than in the analysis of typing time, but we test their significance in all analyses.

Secondly, we include two variables which arise during the experiment or as a result of the presentation of the AOIs in context. The first context variable is the position of the segment in the text, where we may observe speeding up (priming) or slowing down (fatigue or relaxation) as the experiment progresses. The second context variable is the effect of repetition of words, which arises because we present sentences in a textual context rather than individually. Repetition of words was measured as the mean number of times the content words in each AOI had occurred in the preceding parts of the text.

The choice of control variables is based on an analysis of the characteristics of the naturalistic experimental situation that we used and on the literature on experimental effects in translation and reading. Thus, we know from a large number of studies that word frequency affects reading time across different languages (for example Taft 1979 for English; Baayen, Dijkstra et al. 1997 for Dutch; Moscoso del Prado Martín, Bertram et al. (2004) for Finnish; Balling and Baayen 2012 for Danish) as well as a range of other cognitive processes (see Hasher and Zacks 1984), making it a reasonable variable to control. Similarly with cognateness (see for instance Dijkstra, Miwa et al. 2010; Kroll and Tokowicz 2005), where special circumstances may hold for translation as opposed to reading since translators may have a tendency to avoid using cognates where possible (Jakobsen, Jensen et al. 2007). The control predictors in the present study do not constitute all possible influences on the translation process, but together with the fact that we generalise across at least eight participants in all analyses, they provide a reasonable level of control of factors that influence the naturalistic task the participants undertook.

A further advantage of using linear mixed-effects models is the fact that these allow us to model the considerable variation between participants and items which is not captured by the predictors included in the analysis. This is done by the inclusion of so-called random effects of participant and item, which are adjustments to the intercept of the regression model for each participant and item. The intercept of the model may be informally described as the point where the regression line – which may describe the relation between a dependent variable such as total gaze time and a predictor such as word frequency – crosses the vertical axis (for illustration, see for instance Figure 2). The model adjusts this intercept up for relatively slow participants (those with longer total gaze times) and down for relatively fast participants and in this way takes the variation between participants into account. Similarly, random intercepts for AOIs account for the random variation between the different AOIs.

Different models were run for the different indicators or dependent variables, that is, total gaze time, pupil dilation and production time. In each case, the dependent variable was analysed as a function of a range of different predictor variables. We started each analysis by including the most control-oriented variables and then gradually adding the more interesting ones, ending with the congruence variable. Variables that turned out to be non-significant were excluded from the final analyses and are therefore not shown in Tables 1 to 7, but they are mentioned where relevant. All analyses and the variables tested in each are summarised in Table 8 and considered in the general discussion. Using this procedure, we were able to investigate the effect of congruence once other relevant variables were taken into account.

In some of the final models, the residuals (the differences between each actual gaze time, pupil dilation or production time and the prediction of the model) showed a marked deviation from normality which could be remedied by removing data points whose residuals were more than 2 standard deviations from the mean. This was done for the final models for Experiment 1 (translation gaze time, pupil dilation and production time), removing between 2.4% and 4.9% of the data points from the analysis. It results in more robust models and effects that are less likely to be driven by outliers. For the remaining analyses, such trimming of the data was unnecessary.

In regression analyses, especially in models with many predictors, it is necessary to consider collinearity between the predictors, which springs from multiple correlations between the predictors in the models. If collinearity between predictors is high, it becomes impossible to disentangle the contributions of each individual predictor. In all our models, all pairwise correlations between predictors were below 0.2 (where the traditional point for starting to do something about collinearity is 0.5) and the condition number of each model was below 18, which is well below the condition number 30 which Baayen (2008) defines as indicating harmful collinearity.

The results of the three analyses, for total gaze time, pupil dilation and production time, are shown in Tables 1 to 3. These Tables, and those for the next two experiments, show the name of each predictor in the first column and its effect size (estimate) in the second column. The remaining columns are based on a run of 10,000 Markov chain Monte Carlo (MCMC) simulations for each analysis; these are simulations based on the data and the analysis of the data and provide more accurate p-values and confidence intervals than those based on the t-distribution (see Baayen, Davidson et al. 2008), especially for smaller data sets. The third and fourth columns show the credible intervals within which 95% of the observations are expected to lie; they are similar to standard confidence intervals but provide superior accuracy. Finally, the p-value in the fifth column is also based on the MCMC-sampling.

Most of the analyses include both categorical predictors such as congruence and numerical predictors such as frequency. The regression analysis includes categorical predictors by letting the intercept of the model represent one level of the factor, the so-called reference level, while the other level of the factor is represented in the model as the difference of this other level relative to the reference level. To give an example, in the models summarized in Tables 1 to 3, SV is represented by the intercept while the line ‘Congruence: VS’ shows the estimated difference of VS relative to SV and the significance of that difference. For numerical predictors, the estimate column represents the slope of the regression line (which is also illustrated, for instance, in the top left Figure 2); when the effect of the categorical predictor is non-linear, it is represented by two lines in the Tables, one for the linear and one for the quadratic parameter.

We first discuss the results with respect to congruence and then the different control predictors, which also provide information about the translation process.

In sum, our translation experiment shows that segments that are incongruent between the source and target texts are looked at longer than congruent segments, indicating that processing is parallel, since the necessity for transposition of word order in the TT seems to be anticipated during reading of the ST. However, the pupil dilation analysis showed no difference between congruent and incongruent segments, indicating that – although they take longer to process – the incongruent segments may not be inherently more difficult to process, at least not for the experienced translators taking part in this experiment. Alternatively, the absence of any effects in the pupil dilation analysis may be a sign that this indicator is not sensitive enough for the present purposes, or that the delay between the occurrence of a stimulus and the reaction of the pupils is more variable between participants than we can model. Finally, the analysis of production time showed effects of various control predictors, but no effects of congruence, which is perhaps not surprising given the experience of the translators and the fundamentality and prominence of the difference between English and Danish that is expressed in the congruence variable.

Although the results point in the direction of parallel processing, two questions remain before we can firmly conclude that processing during translation is parallel. The first question is based on the syntactic difference investigated: Since the incongruent segments in Danish are categorized as non-canonical, it may be that the effect observed in the translation experiment is not a translation effect at all, but simply the result of the non-canonical Danish segments, which represent the incongruent category here, being inherently more difficult to read. Given the high frequency of VS-constructions in Danish, we would expect that this is not the case, but that is an empirical question which should be investigated. In Experiment 2 (see section 3), we therefore asked L1 Danish participants to read the Danish texts that were translated in Experiment 1, in order to establish whether the VS segments are more difficult to process than the SV segments in a reading task.

The second question comes from the perspective of research on general L2 processing. There is evidence that both lexical and syntactic structures of a language user’s first language affect processing in their second language (see for example De Groot and Nas 1991; Hartsuiker, Pickering et al. 2004; and Balling 2013 for an experiment with a similar population to that of Experiment 2) and, at least to some extent, vice versa (Van Hell and Dijkstra 2002; Costa, Caramazza et al. 2000). Therefore, the question arises whether the transfer of L1 syntactic structure that we observed in Experiment 1 is a translation phenomenon or the result of more general characteristics of bilingual processing. We address this question in Experiment 3 (see section 4), where the same texts as in the previous experiments were read by a group of participants whose L1 was English and whose highly proficient L2 was Danish.

Fourteen native speakers of Danish participated in the experiment. All were MA students of English at the Copenhagen Business School with English as a highly proficient second language, but none of them had grown up as bilinguals. Further information on these participants is included in Appendix B.

The participants were asked to read the source texts from Experiment 1 with the object of comprehending them and being able to answer a few simple comprehension questions after reading (none were actually asked, the warning about questions was merely given in order to ensure that the participants did not read too superficially). No warm-up task was deemed necessary.

The experiment was run using the same equipment as in Experiment 1. Since participants were only reading the two texts, the experiment was quite short, five to ten minutes including calibration, and we observed no problems with data quality according to the criteria outlined in section 2.1.4.

The results of the analyses are summarized in Tables 4 and 5. The final models summarized in the Tables were reached in the same way as in Experiment 1: The predictors were added to the model in order of their importance to the hypothesis, starting with the most peripheral control predictors and ending with the central congruence predictor. Non-significant predictors were excluded from the analysis, with the exception of congruence, which is included to allow the reader to verify the size and (non-) significance of the effect.

Neither analysis shows any significant effect of congruence, though the effect on pupil dilation approaches significance (p = 0.0638), with a tendency for readers’ pupils to be larger when reading the incongruent VS-segments. Generally, one should be careful about interpreting non-significant results, since the non-significance could be an issue of measurement error or insufficient statistical power. Such care should also be taken here, but given the relatively large effect in Experiment 1 and the very small one here, it appears that the translation effect observed in Experiment 1 is not an artefact of the non-canonical VS-segments being inherently more difficult to process for L1 language users than the canonical SV segments. The question remains whether the delay for the VS segments also holds more generally in bilingual processing; this question is addressed in Experiment 3, which is reported below.

In the present experiment, only two of the control variables had significant effects on gaze time, namely the position of the AOI, with slightly longer gaze times but slightly reduced pupil dilation early in the experiment, as illustrated in the top row of Figure 3. This may be understood as a relaxation effect. It suggests that reading becomes slower as the experiment progresses, while the cognitive effort as indicated by pupil dilation becomes smaller (this and other differences between effects in the gaze time and pupil dilation analyses are examined in the general discussion, section 5).

More interestingly, the gaze time analysis showed an effect of cognateness with English, the L2 of the participants, as illustrated in the bottom panel of Figure 3. A simple count of the number of cognates in each AOI had a highly skewed distribution; therefore the cognateness variable was reconstructed as a binary indicator of whether the AOI contained cognate words or not. The effect in the gaze time shows that AOIs that did not contain cognates (Cognateness: NO in Table 5) were looked at longer than AOIs that did contain cognates. This is remarkable because the task is reading in the L1 where awareness of L1-L2 correspondences is not in any way relevant or encouraged. It provides further evidence of the effect of cross-linguistic influences on the processing even in the L1 of late bilinguals like the participants in the present experiment (see for example Van Hell and Dijkstra 2002; Costa, Caramazza et al. 2000). Although interesting, we interpret this with some caution, since this is the only analysis that shows this effect.

The method of this experiment was the same as for Experiment 2, except that the participants were nine native speakers of English (both British and American) who had lived for a long time in Denmark (13-41 years, mean 26) and were highly proficient L2 speakers of Danish that function in Danish society using the Danish language on a daily basis. Information about these participants and their own assessment of their Danish skills is included in Appendix B.

The results of Experiment 3 are shown in Tables 6 and 7. Crucially, the congruence variable had no effect at any stage of the analyses. We did, however, observe effects of several of the control predictors: Firstly, we found a non-linear effect of the mean frequency of the content words, which is illustrated for gaze time in the top left panel of Figure 4 and for pupil dilation in the top right panel. The difference between these effects is discussed in section 5.

Secondly, word repetition, the mean number of times the content words in an AOI had occurred previously in the text, had an effect on total gaze time, which is illustrated in the bottom left panel of Figure 4. The non-linearity of this effect is somewhat puzzling: It seems that optimal processing occurs for AOIs with few or many repeated words, while AOIs with a medium number of repetitions are the most difficult.

Finally, the pupil dilation analysis showed a small effect of AOI position, as in Experiment 2, with smaller pupil dilation later in the experiment, this being the result of a habituation effect.

This experiment with L2 readers of Danish tested whether the congruence effect observed in the translation experiment generalized to L2 processing in general. The translation effect is not directly an L2 effect, since it is an effect on the reading of the L1 before translating into the L2, but the question does arise how far the effect generalizes and whether it is possible to “escape” the syntax of one’s L1 at all – a topic which is also hotly debated in the bilingualism literature (see for example Clahsen and Felser, 2006; Frenck-Mestre, 2005). If the syntax of one’s L1 is inescapable, we would expect an effect of congruence for our group of very experienced L2 users of Danish. This was clearly not the case in this experiment, where the effect of congruence was far from significant, indicating that the syntax of the L1 is not activated to any measurable extent.