The idea for simultaneous consecutive interpreting is claimed by several professional interpreters. The first successful use of “digitally mastered consecutive” was reported by EU staff interpreter Michele Ferrari (2001: 3), who used his palm-size PC to interpret a press conference in Rome by Neil Kinnock, then Vice-president of the European Commission, in March 1999. Shortly after his report of this first trial in a real setting, Ferrari carried out a series of tests within the EU Joint Interpreting and Conference Service (SCIC; now DG Interpretation) (Ferrari 2002).

The aim of these tests was not only to compare traditional and simultaneous consecutive interpreting, but also to examine different devices, such as a handheld PC, a notebook with digital audio-editing software, and a digital voice recorder. The results can be summarized as follows: while simultaneous consecutive is objectively more complete and precise, it sounds “too artificial” for some language combinations (Ferrari 2002: 7). Especially when the source and target languages belong to the same linguistic family, as is the case for Spanish and Italian, for instance, Ferrari concludes that it is essential to find an appropriate playback acceleration rate in order to sound natural.

The second series of tests was also carried out within SCIC and took place in June 2003. This session, parts of which were also video-recorded, led to the general conclusion that simultaneous consecutive was a “viable possibility” and that the use of electronic devices required some practice (Vivas 2003). It is also interesting to note that the report of this second comparison session contains a note by J. Martin, another SCIC interpreter, about his successful use of a digital voice recorder in a real interpreting assignment.

Two court interpreters in the United States, John Lombardi (2003) and Erik Camayd-Freixas (2005), have also reported efforts to use a digital voice recorder for consecutive interpreting in court. While Lombardi tested “digital recorder assisted consecutive (DRAC)” interpreting informally and published an article about the functioning, advantages and possible drawbacks of the method in the spring edition of the NAJIT newsletter (Lombardi 2003), Camayd-Freixas carried out an experiment at Florida International University and even established an equipment label marketed by his language consulting firm (Camayd-Freixas 2005).

The experiment at Florida International University was conducted in April 2003 with 24 advanced interpreting students and beginning professional interpreters with the language combination English/Spanish. The subjects were divided into two groups and presented with a series of unrelated statements of increasing length to be interpreted in either mode and direction, i.e., from English into Spanish and Spanish into English, using either notes or the digital voice recorder. The experiment, in which both groups served as their own controls, was centred on accuracy, measured in terms of “the percentage of words missed in each statement” (Camayd-Freixas 2005: 43). Results showed higher accuracy rates when using the digital voice recorder and a decline in accuracy with conventional note-taking as statement length increased (Camayd-Freixas 2005: 43).

All interpreters who tested the simultaneous consecutive interpreting technique have reported an improvement in quality. Technology-assisted consecutive interpreting is generally praised for its increased accuracy and completeness (Gomes 2002: 8). The resulting rendition is also considered more faithful to the original in terms of intonation and liveliness (Camayd-Freixas 2005: 42). The fact that note-taking is no longer necessary allows the interpreter to devote more attention to listening and comprehension.

Technology-assisted consecutive interpreting is said to be especially useful in court, even though ethical issues, such as the question of confidentiality, have to be considered.

The fact that the interpreter would not need to ask a witness to pause for interpretation and could more accurately convey expressions of emotion is seen as one of the most striking advantages of using an electronic recording and playback device in court interpreting (Lombardi 2003: 8).

Based in particular on Ferrari’s (2001, 2003) tests of technology-assisted consecutive interpreting, a small-scale experiment was carried out at the Vienna University Center for Translation Studies in the context of a Master’s thesis (Hamidi 2006). The study focused on the language combination French/German and was designed to address three main questions:

1. Does technology-assisted consecutive interpreting yield better results than the conventional consecutive method?

2. How does the audience respond to the new consecutive technique compared to the traditional one?

3. Is simultaneous consecutive likely to be adopted by professional interpreters as an interpreting method in its own right?

Answering the research questions required an experimental comparison of the two consecutive interpreting modes. Professional conference interpreters were to interpret two comparable speeches (of just under ten minutes’ duration in two takes of roughly equal length), rendering the first one in the conventional consecutive mode and the second with the aid of a digital voice recorder.

To ensure the same conditions for all participating subjects, the two speeches were videotaped and the recordings subsequently shown as source material in three separate experimental sessions, which took place in late June 2005. At the end of each session, a debriefing interview was conducted with the interpreter on the basis of seven questions relating to his/her professional experience and preferred working mode as well as his/her own assessment of the two performances and the new technique.

In order to study audience response, we asked two dozen students in the B.A. programme in International Communication at the Center for Translation Studies to serve as listeners in the experimental sessions. As a result of time constraints, however, the majority of them, busy with end-of-term exams, were unable to participate. Therefore, the video-recorded interpreting performances were presented to a small and heterogeneous experimental audience, with each of three groups responding to one interpreter’s performances on the basis of a questionnaire.

Out of the relatively small group of interpreters who met our criteria for participation (university-degree in interpreting; German as A language, French B; extensive professional experience in both interpreting modes), only three were able and willing to participate in the experiment in June 2005. The subjects, two women and one man, had at least ten years of professional experience. Two of them are members of AIIC and work mainly in the simultaneous mode, following a decline in the number of consecutive assignments in the course of their careers. The third subject does nearly as much consecutive as simultaneous interpreting. Two interpreters expressed a preference for the consecutive mode, indicating that it permits more contact with the audience and can give greater professional satisfaction. One interpreter had previously experimented with using a digital tape recorder in a real consecutive setting.

The source speeches, which were scripted for the purpose of the experiment on the basis of authentic material, were comparable in terms of content and level of language use. Both were delivered by a French native-speaker at a rate of some 130 words per minute (articulation rate: 138 and 144 wpm, respectively). The speeches dealt with French-American relations (Speech 1) and France’s role in the European Union (Speech 2) and contained a comparable number of proper names (8/10), dates (6/9) and figures (6/7). On account of the differences in the number of such potential problem triggers as well as the higher articulation rate, Speech 2 may have been slightly more difficult, thus raising the challenge for working in the simultaneous consecutive mode.

The audience, who had hardly any knowledge of interpreting, consisted of a sample of nine persons aged 20 to 56 years and included two translation students, two lawyers, two psychoanalysts, a student of Arabic, a student of mathematics and a computer scientist. The audience was divided into three groups, with two female and one male listener for each experimental session.

The eight-page questionnaire given to the listeners in the course of the experimental sessions first elicited their general impression of the interpreter’s performances. They were asked to indicate whether they had been able to follow the German interpretation of the original French speech ‘very well,’ ‘well,’ ‘with some difficulty,’ ‘badly’ or ‘very badly’ and were given space to add comments. The questionnaire also included three comprehension questions (one free recall and two multiple-choice questions) and seven-point Likert scales for rating the following six quality criteria: ‘fluency of delivery,’ ‘clarity and cohesion,’ ‘quality of expression (language),’ ‘intonation and emphasis,’ ‘contact with audience’ and ‘confidence and professionalism.’ (The seven points on the scale, labeled only with anchors for the lowest (-) and the highest assessment (+), were interpreted as numerical ratings – from ‘1’ to ‘7’ – in the subsequent analysis.) Having evaluated the two performances, the listeners were asked to state which of the interpretations they liked better, and why.

The electronic device used in our experiment had to be user-friendly and reasonably priced. We opted for an Olympus VN-480PC digital voice recorder with a built-in flash memory (64 MB) and a recording time capacity of up to 177 minutes in the high-quality mode. During the experiment the subjects had to operate three buttons, REC, STOP and PLAY, aside from controlling the volume; they were given a short warm-up period to test the equipment. Replay speed was set to “normal.” To offset the loss in sound quality resulting from the video playback of the source speech, we used a free-standing condenser microphone instead of the clip-on microphone supplied with the voice-recorder.

The experimental setup and materials were tested in a pilot study involving a recent interpreting graduate and a live student audience, four of whom (second semester; no French) filled in the questionnaire. No problems with the procedure were found.

In addition to the post-test interviews conducted with the interpreters and the questionnaire-based evaluation by the audience, we used output analysis to permit triangulation of data and implement a multi-method approach to interpreting quality assessment (cf. Pöchhacker 2001). For this purpose, the source speeches and video-recorded interpretations were transcribed (orthographically) and analysed with regard to such parameters as quality of expression, fluency and prosody. All pauses with a duration of more than one second were marked in the transcript and measured with the help of audio analysis software (PRAAT). In the case of filled pauses, the hesitation sounds were also noted. Pitch movement was first analysed on an auditive basis and subsequently checked with PRAAT. (For a detailed description and illustrations, see Ahrens 2005).

Except for the sound quality, which was considered quite poor in two of the three experimental sessions, all three subjects were relatively comfortable with the simultaneous consecutive interpreting technique. The post-test interviews also showed that Int-1 and Int-3 felt more comfortable with the second speech and interpreting mode, whereas Int-2 felt better with Speech 1 and the conventional consecutive mode. Asked which of their performances had been superior, Int-1 and Int-3 indicated for Speech 2, interpreted in the simultaneous consecutive mode.

According to the interpreters, the main advantages of the simultaneous consecutive technique are that it is “less strenuous” and that it permits the interpreter to listen to the original twice, which is especially relevant when speakers do not express themselves in their mother tongue and have a strong accent. The fact that one has to “translate everything,” even in long and redundant speeches, was seen as the most important drawback. One interpreter criticised a certain loss of the “human element” in simultaneous consecutive. Nevertheless, all three subjects agreed that they could imagine using digital equipment for real consecutive interpreting assignments.

Source–target correspondence was assessed in terms of substantial departures of the interpretation from the original. Based on the three classic types of deviations identified by Barik (1975/2002), the transcripts were examined for two levels of omission, addition, and substitution: those that do not substantially alter the meaning, and those that do (‘meaning-relevant’ changes).

Example of a meaning-relevant omission:

The following example, in contrast, was not considered a meaning-relevant omission:

While the three interpreters made relatively few meaning-relevant departures from the original, the number of substantial additions was generally higher in conventional consecutive than in the simultaneous consecutive mode. For each of the interpreters, fewer additions were found in Speech 2.

While Int-1 made more additions and substitutions in Speech 1 (56 and 49), the number of omissions is quite even for both speeches, with more meaning-relevant omissions in Speech 2 than in Speech 1 (8 vs. 1).

Similar results were found for Int-3, who made more additions (58), substitutions (56) and omissions (24) in the conventional consecutive version. The number of meaning-relevant additions in the rendition of Speech 1 (12) is three times higher than for the simultaneous consecutive mode (4).

The incidence of Int-2’s meaning-relevant omissions (8 in Speech 1 vs. 12 in Speech 2), total substitutions (71 vs. 50) and total additions (39 vs. 27) is comparable to those of Int-1, though the difference between the two renditions is less pronounced.

Prosodic phenomena were analysed with reference to the features used in Shlesinger’s (1994) study of “interpretational intonation,” in particular tentative final pauses, pauses within constituents, incompatible stress, segment lengthening and acceleration (Table 4).

The overall pattern of prosodic deviations is rather variable, but a number of categories show fewer occurrences in the simultaneous consecutive mode. In the interpretations by Int-1, where such phenomena were most numerous, there were fewer instances of lengthened segments (20 vs. 4) and incompatibility of stress with semantic contrast (21 vs. 16) in Speech 2. The number of accelerations was the same in both speeches, as was the number of tentative final pauses (19 vs. 20).

Int-2 and Int-3 showed fewer salient prosodic features, their number being indeed negligible for Int-2, whose renditions contained neither lengthening of segments nor accelerations. For Int-3, the number of tentative final pauses (13 vs. 10) and instances of stress incompatibility (6 vs. 4) is higher in Speech 1; the opposite is true for accelerations (0 vs. 2) and segment lengthening (0 vs. 3). Pauses within constituents (“non-functional pauses”) were predominant in the conventional consecutive performances of Int-1 (28) and Int-3 (18), whereas Int-2 paused more often within constituents in Speech 2 (10 vs. 28).

The video recordings of the interpreters’ performances enabled us to analyse the subjects’ eye contact with the audience. While Int-3 did not look up even once, neither in the conventional consecutive nor in the simultaneous mode, Int-1 and Int-2 made more or less regular eye contact with their listeners.

In this respect, Int-1 was the most communicative by far, with 160 instances of eye contact in Speech 1 and 63 in Speech 2 (Table 5). Int-2 had 51 instances of eye contact during Speech 1 and only 9 during Speech 2. Most of these glances at the audience were of very short duration, but there were also quite a few ‘long eye contacts,’ lasting some three or four seconds. Most of these – as well as the longest – were recorded for Int-1. Int-2 had 12 instances of long eye contact during conventional consecutive and only 3 in the simultaneous consecutive mode.

The video recordings were a rich source for the analysis of the interpreters’ body language (used as an indicator of confidence and professionalism) and showed that body movements were generally more vivid and apparently unconscious in the simultaneous consecutive mode.

The most conspicuous kinesic behaviour was recorded for Int-1, who made 17 different types of body movement during each rendition. These movements, which also involved nearby objects, were rather frequent (about 40 for each speech) and reflected some regularity. While Int-1’s “object-adaptors” (Poyatos 1987/2002) in the conventional consecutive mode were directed to utensils like pencil, glasses and notepad, they mainly involved the voice recorder and its accessories during Speech 2. The most salient feature was the incidence of apparently unconscious movements during simultaneous consecutive (e.g., foot-tapping), which conveyed a sense of agitation that was noted also in the audience assessment.

Int-2, by comparison, seemed calmer and showed far less kinesic behaviour. During the renditions of the two speeches, Int-2 only used “language-markers” (Poyatos 1987/2002), i.e., finger or hand movements to support the meaning of the concurrently pronounced words. Int-2’s body language was nonetheless more intense during simultaneous consecutive. While interpreting Speech 2, Int-2 also touched the notebook and other objects on the table.

Int-3’s monotonous intonation and the absence of eye contact in both interpreting situations was matched by relatively passive body language. The few salient movements made by this interpreter seemed nevertheless more vivid in the rendition of Speech 2 (pulling at voice recorder and microphone cord, pushing back pullover sleeves, rocking the chair).