The experiments were conducted in a sound-proof video recording studio. Initially, the participants were given a brief written outline of the project, including an instruction to the experimental set-up and to the tasks they were expected to complete, as well as a brief oral introduction to the eye-tracker and Translog (see below). In order to capture eye movement data, each participant was subjected to a calibration procedure (see O’Brien 2006a).

Gaze data from all participants were collected with a Tobii eye-tracker,[2] a system which registers a person’s eye movements on a computer screen throughout any given process. The recordings from the eye-tracker were analysed with Tobii’s ClearView software to track and study the participants’ visual orientation and gaze behaviour. (For a more thorough introduction to the Tobii eye-tracking system and its use in translation research, see O’Brien 2006a, and for an introduction to the use of eye-tracking during reading, see Radach et al. 2004; Rayner 1998.)

Eye-tracking is a relatively new technology in translation studies, and we encountered various problems related to our research design. Firstly, our pilot tests revealed that the system’s registration of gaze fixation was sometimes imprecise. This could be off-set by increasing the line spacing and/or the font size. Secondly, synchronization of gaze data with oral output had to be done “manually.” Finally, we had to manually determine the lexical content related to a given gaze fixation on the screen. In the Eye-to-IT project,[3] additional modules have been developed which enable: 1) automatic synchronization of gaze data and audio output (integration of an audio component in Translog); 2) automatic identification of words on the basis of gaze fixations (with the Gaze-to-Word Mapping [GWM] module). For a discussion of research design methodology using eye-tracking in translation and reading studies, see Göpferich et al. 2008).

The translators’ written translation process was logged in Translog, a program which performs keystroke logging and registers pauses in the translation process (Jakobsen and Schou 1999).

Furthermore, each participant’s performance was video-recorded, and finally, after conducting the actual experiments, we interviewed the participants about the tasks they had completed.

The experimental set-up was far from identical to the normal working conditions of translators and interpreters, and it must be borne in mind that factors such as video monitoring, keystroke logging and, in the case of the interpreters, the absence of an audience impinge upon the data. This was reflected in comments made by some of the participants in the subsequent interviews.

What is presented here is a small-scale study, and our findings are preliminary. A larger number of participants, more language pairs and a range of different text types would make our results more generalizable, and enhanced technology (GWM and audio components, see above) would strengthen the reliability of our data.

All participants (four interpreters and four translators) were native speakers of Danish with at least 10 years’ experience as professional interpreters and translators. The interpreters work primarily as interpreters, but two of them are also practising translators. None of the translators take on interpreting jobs although they are all sworn translators and interpreters.

The participants were instructed to perform the tasks as they would have done if they had been commissioned by a customer.

The source text was a political speech given in English in an EU context (1289 words). For the purpose of the present study, the interpreters performed only one task: a sight translation into Danish of the first 634 words.[4] The translators performed two different tasks and were divided into two groups of two; one group was asked to make a sight translation of the first 634 words and a written translation of the next 655 words, and vice versa for the other group.

The data from the eight sight translations (four interpreters and four translators) were transcribed using the ‘bysoc’ criteria developed for a national corpus of spoken Danish[5] (adapted version). The raw transcriptions were then transformed into texts which resembled written translations in that punctuation was added and off-the-cuff remarks were deleted. However, apart from these changes, the texts were not improved or amended in any way.

“Quality is an elusive concept, if ever there was one” (Shlesinger 1997: 123), and quality assessment in translation and interpreting immediately raises the question of quality for whom and from which perspective. Various models, sets of assessment criteria and norms for evaluation of the quality of written translation and interpreting respectively have been developed and discussed extensively (see e.g., Garzone 2002; House 1997; Kalina 2002; Pöchhacker 2002; Schjoldager 1996), but there is no overarching definition of quality applicable to both modalities of translation – see Anderman’s proposal to “set up a project to decide on criteria for the assessment of translation and interpretation” (Schäffner 2004: 46, see also Setton and Motta 2007: 201-202).

Hence, our choice of evaluation criteria and method was not easy in that our data comprise both written translations (by translators) and an artificial/hybrid product, i.e., transcript-based texts produced from oral translations delivered by both translators and interpreters.

In quality assessments, we have taken a product-oriented approach (Pöchhacker 2002: 96). Pöchhacker cites core criteria of interpreting quality such as accuracy, clarity and fidelity and refers to Gile’s notion of the target text as “a ‘faithful’ image” of the original discourse. In written translation the notion of fidelity has also been central in the discussion of quality (e.g., Kalina 2002: 120).

In our attempt to find common ground, we decided to ask three raters to evaluate the eight sight translations and the four written translations. One of the raters is a professor and translation teacher at Copenhagen Business School (CBS), one is an external lecturer at CBS as well as a freelance translator/interpreter, and one is a full-time translator. Information on whether the texts were produced by an interpreter or a translator and whether it was a sight translation or a written translation was not available to the raters. The three raters were asked to assess the quality of the translation/sight translation products as follows:

1. Give an overall assessment of the adequacy of the target text (as a translation of the source text) (on a scale from 1-5, 1 = highest quality, 5 = lowest quality).

2. Indicate the proximity of the target text to the source text (on a scale from 1-5, 1 = very close to source text, 5 = very free).

3. Indicate errors in the text and state the severity of the error on a scale from 1-5 (5 = most serious). Please take into account that the text is a speech (political).[6]

4. Indicate on a scale from 1-5 the approximate time it will take to edit/revise the text so that it will be an adequate translation of the source text (1 = approx. 0-10 min., 5 = approx. 40-50 min.).

Pause analysis of the written translation output was performed on the basis of pause data from Translog supplemented by eye-tracking data. The analyses of the oral translations were based on the video recordings of each participant combined with eye-tracking data. Audio files (wav) of the output texts were extracted from the videos and analysed in the speech analysis and synthesis program PRAAT[7] using an add-on script developed for pause detection.[8]

Our definition of a pause was based on written translation output, where pauses of 1‑2 seconds have been shown to indicate some translation task-related cognitive processing (Baddeley 1986; Dragsted 2005; Jakobsen 1998, O’Brien 2006b). For purposes of comparison between written and oral output, we have defined a pause in both written and sight translation as an interruption in the writing or speech process of 2 seconds or more. When analyzing oral output, a distinction is often made between filled and unfilled pauses (Ahrens 2005; Mead 2000), where filled pauses typically consist of hesitation markers, while unfilled pauses are defined as silence intervals. In the present analysis we will focus on unfilled pauses.

Table 1 below shows significant differences in processing time between the two groups.

The translators produced the written translation at a rate of 11-34 words per minute. Under the sight translation condition the translators worked considerably faster (35-114 WPM) but on average only about half as fast as the interpreters who processed the text under the same task conditions at a pace of 127-160 WPM (see also Jakobsen, Jensen et al. 2007: 233). Note that the interpreters constitute a fairly homogeneous group, whereas one translator, T4, stands out by working faster than the other translators both under the written and the sight translation condition. Yet, all translators, including T4, worked at a considerably lower output rate than the interpreters when completing both tasks, in particular when producing the written translation.

In order to measure whether the additional time spent by translators producing written translations seems worthwhile, i.e. whether the quality of their written output is correspondingly higher than that of the interpreters’ – and their own – sight translation output, we correlated the time data in Table 1 with the quality assessments given by the raters.

As appears from the ratings in Table 2, the translators’ written translations are not unambiguously better than the interpreters’ sight translations or the translators’ own sight translations. Thus, the additional time spent under the written translation condition does not seem to be justified by a considerably higher quality of the translation product.

I1, who is the fastest of all the participants, is also the one who gets the best quality score, whereas I3 and I4 are closer to the other end of the 1-5 quality scale. In the written condition, T1 spends almost an hour to complete the written translation task, and gets a very low score.

The picture with respect to the interpreters’ quality ratings is uneven in that the group comprises both the highest and the lowest scores. Two of the interpreters produce high quality output at high speed, and I1 in particular stands out as an “elite interpreter” (Ericsson 2000: 211) whose performance is remarkable, but looking at the performance of the group as a whole it cannot unambiguously be maintained that working in the oral modality enhances the quality of the translation product. However, the striking differences in output rate shown in Table 1 suggest that an analysis of differences in strategic behaviour under the oral and written translation modalities may be worthwhile.

An intra-subject comparison of the translators’ performance under the sight vs. the written condition shows that T1 performs marginally better in the sight translation than in the written translation even though she sight translates 3 times faster. The other three translators take 3-7 times longer processing the written translation, and receive marginally better scores under this condition. In two cases, T1 and T2, the time consumption to correct the TT and bring it up to an acceptable standard is higher for the written translation than for the sight translation.

Generally, it might be argued that the substantially lower output rate in the translators’ written translation compared with their sight translation does not seem to be justified by higher quality output. This lends support to the idea of speaking one’s translation and exploring the potential of oral translation to play a more prominent role in translator training curricula by incorporating sight translation as a deliberate practice activity (Ericsson 2000: 212).

In this and the following sections we will analyse and discuss differences in strategic behaviour among translators and interpreters. In view of the results on the output rate/quality-relationship reported above, we will discuss whether it may be useful for translators to draw on some of the strategies typically associated with interpreters and the oral modality, and whether it may even be worthwhile to include interpreting strategies and tasks in our curricula for translator training (see Hansen and Shlesinger 2007 on interpreter training at CBS).

The eye-tracking data provided us with insights into the participants’ orientation on the screen during the translation process. The figures below show so-called hotspot analyses highlighting focus areas of a selected segment, i.e., the gaze behaviour for a paragraph of the text in the interpreters’ sight translations and the translators’ written translations. The hotspot image shows a grey background with highlighted areas indicating where the participants have been looking. The gaze intensity is reflected in the size and the colour of the spots, i.e., the longer the gaze, the darker and larger the spot (the “hotter” the spot).

This visual representation of the participants’ gaze behaviour indicates that the interpreters’ (I1-I4) reading and comprehension proceeds in a fairly “controlled” and linear manner where the gaze stays on the area of the source text that is currently being translated. Hotspot analyses for the translators’ sight translation (not displayed here) reveal a pattern similar to the one found in the interpreters’ sight translation. The translators’ (T1-T4) gaze fixations, by contrast, are split between the source and target text window (ST and TT), but the gaze pattern in the source text window (also when seen in isolation) is characterized by scattered fixations, indicating that the translators are not focussed solely on the segment being translated. Generally, interpreters seem to concentrate more linearly on comprehension and production than translators, who adopt a more global strategy with plenty of regressions and backtracking (Rayner 1998).

A possible explanation for this behavioural difference may be that the interpreters were affected by time pressure and the concern for smooth delivery, whereas the translators, who felt no time constraint, searched larger areas of the screen in order to look for help in previously translated TT segments or further down in the ST.

Further support for the distinction between the interpreters’ focussed and continuous reading vs. the translators’ more discontinuous and disrupted reading of the ST was found when calculating the number of fixations in the source text window (see Figure 3). For the interpreters, we looked at source text fixations (I1 ST, I2 ST etc.) and for the translators we divided our analysis into fixations on the source text (T1 ST, T2 ST etc.) and on the target text (T1 TT, T2 TT etc.).

With one exception (T4), the translators had far more ST fixations than the interpreters. This indicates, again, that the interpreters proceed in a more linear manner. In broad terms, once they have completed the translation of a segment, they move on to the next without further backtracking. The translators, on the other hand, return to the same word or segment repeatedly, reconsidering and sometimes rephrasing it. This behavioural difference is in line with Gile (1995) (see section 2).

There seems to be a tendency for the TT fixation count to follow the ST fixation count. For instance, T2, who has the highest number of ST fixations, also has the highest number of TT fixations. At the other end of the scale, we find T4 with the same pattern, but remarkably few fixations in both the ST and the TT window. This explains T4’s hotspot analysis (Figure 2), which resembles the interpreters’ gaze behaviour (in a selected paragraph) with fixations concentrated almost exclusively in the ST window. The video recordings showed that T4 is a skilled touch typist, and it may be the case that the automation of the typing process frees resources for other efforts, and minimizes the need for ongoing TT editing.[12] When interviewed, T4 stated that she teaches oral communication and is comfortable with working in the oral modality. These competencies might explain why T4 stands out as an “elite” translator (Ericsson 2000: 211) both under the oral and the written condition.

As a final parameter for gaze behaviour, we analyzed the average fixation duration (see Figure 4).

The interpreters constitute a very homogeneous group in this respect, with average fixation durations between 240 ms and 260 ms averaging 252 ms. By comparison, Rayner cites mean fixation duration values of 225 ms for silent reading and 275 for oral reading (Rayner 1998: 373). There is a slight tendency for the translators to have shorter average fixation durations on the source text (average 228 ms) than the interpreters; the translators are generally more focussed on the TT output with average fixation durations generally between 300-400 ms, which is close to the average fixation duration of 400 ms found for typing (Rayner 1998: 373).

A comparison of the ST fixation count and fixation duration values reveals that interpreters had few but slightly longer gaze fixations whereas the translators had a higher number of ST fixations of shorter average duration. The eye movement record as a whole (hotspot analysis, fixation count and fixation duration) generally points to the same conclusion, that is to say, the interpreters’ translation process is more continuous than that of the translators. The translators’ gaze behaviour is disrupted, reflecting that they have to relate to two texts on the screen. Also, since translators are not under immediate time pressure, they have time to scan other segments than the one being translated to retrieve information.

According to Clifton, Staub et al. (2007) predictable words “are looked at for less time than words that are not predictable” and readers more frequently skip over high predictable words than low predictable words (Clifton, Staub et al. 2007: 347). The interpreters’ lower number of gaze fixations and more focussed fixation pattern in general may perhaps be explained by their application of anticipation strategies, which, when successful, enable them to generate expectations guiding the comprehension process (Pöchhacker 2004: 119, 133) and allowing them to quickly scan or even skip words in the text. According to Ericsson, skilled interpreters can be expected to behave like top pianists, who are able to sight-read music, leaving out less important notes but preserving the core melody, and to continue playing the music and successfully predict notes that were blacked out (Ericsson 2000: 213).

Clifton, Staub et al. go on to argue that “[…] how long readers look at a word is influenced by the ease or difficulty associated with accessing the meaning of the word” (Clifton, Staub et al. 2007: 248). The translators’ high number of gaze fixations and their long fixation duration on ST and TT collectively reflect higher cognitive effort associated with the comprehension and production processes than is apparently exhibited by the interpreters.

Putting more emphasis on the oral modality in translator training might force translators to become more focussed and opt for their first choice (like the interpreters) rather than searching meticulously for the perfect word. In some cases, the fast-and-ready solution may not be preferable, and will have to be corrected afterwards (Schäffner 2004: 1-2), but quite often, the translator’s first intuition may also result in the best translation.

In an attempt to take the gaze analysis one step further, we have experimented with calculating the participants’ “eye-voice span” in sight translation (see ear-voice span in simultaneous interpreting). Future perspectives for our research include new experiments to elicit data on the coordination between comprehension and production in oral and written translation.

As shown in Table 1, the interpreters completed their tasks substantially faster than the translators, which is also reflected in the number and duration of pauses registered by Translog and PRAAT. In addition to the unfilled pauses detected by PRAAT, the transcriptions of the oral (sight translation) output revealed that, unlike the interpreters, the translators had a large number of filled pauses, which will not be included in our analysis at this point.

The remarkable differences in Figure 5 reflect that the translators had considerably more and longer pauses than the interpreters. For example, I1 and I4 had only one pause of more than 2 seconds, whereas T1 and T2 had 213 and 188 pauses respectively. The pause ratios are indicative of fundamental behavioural differences between translators and interpreters. The translators producing written translation appear to be hesitant, pausing sometimes before each word, whereas the interpreters seem more self-assured producing the text fluently with very few pauses. An intra-subject comparison of the translators indicates less hesitation in the oral mode for all translators, although all except T4 still have a considerably higher pause ratio than the interpreters also under the sight translation condition.

The differences between pause patterns in the written and oral modalities may be ascribed to many factors. The time constraint felt by both interpreters and translators when working in the oral modality is the most obvious, along with the fact that in order to produce coherent oral discourse without having the target text on the screen, the translator/interpreter has to produce and monitor larger units of meaning rather than smaller segments.

But the pause patterns and disfluencies observed in the translators’ oral output may also be explained by the translators’ working habits and tradition of focussing almost exclusively on the written modality of translation, which is reflected in the way translation is taught. There is no clear-cut relationship between the pause/hesitation pattern and the quality of the output; yet, T3 and T4, who have the lowest number of pauses in the translator group, are also the ones who receive the best quality scores (Table 2). A tentative conclusion could be that very hesitant and disfluent production compromises the quality of the output, which again lends support to the recommendation to emphasize the oral modality in translator training.

By contrast to the process-oriented aspects discussed so far, the analysis of proximity is based on the written and oral translation products.

When asked to give their judgments of the proximity of the target text to the source text, the raters gave the scores shown in Figure 6, where 1 indicates that the translation is very close to the ST, and 5 indicates a very free translation. The notion of proximity was not explained or defined to the raters, and we did not ask our raters to consider whether a very free translation, for instance, indicated high or low quality. Yet, the inter-rater agreement was high, with SD between 0 and 0.5 (in two cases 1), indicating a shared perception of the notion of proximity among the raters.

The interpreters’ target texts (with averages between 3 and 4.3) are more free than the translators’ target texts in general, and the translators’ sight translations are slightly more free than their written translations. Hence, there is a slight tendency for the translation product to become freer as the orientation towards the oral modality becomes more prominent. This is in accordance with what we expected based on Schäffner (2004) and Pöchhacker (2004). Although Shlesinger and Malkiel (2005: 179-182) found that, compared with translators, interpreters apply a more form-based strategy when processing cognates, their findings were limited to the lexical level and did not necessarily generate any conclusions with regard to strategies on a broader textual level.

Of all the translation products, T1’s written translation is considered to be closest to the ST, whereas I1’s (sight) translation is considered to be very free. It is interesting to note that T1’s written translation received a very low quality score, and I1’s sight translation received the highest quality score (Table 2). However, I3 and I4, who received the lowest quality scores, also produced the most free translations. Hence, there seems to be no correlation between quality and the level of proximity in our data, and the tendency for oral translations to be more free speaks neither for nor against augmenting the oral modality in translator training.