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Information Processing and Design

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In designing equipment it is of the utmost importance to take full account of the fact that a human operator has both capabilities and limitations in processing information, which are of a varying nature and which are found on various levels. Performance in actual work conditions strongly depends on the extent to which a design has either attended to or ignored these potentials and their limits. In the following a brief sketch will be offered of some of the chief issues. Reference will be made to other contributions of this volume, where an issue will be discussed in greater detail.

It is common to distinguish three main levels in the analysis of human information processing, namely, the perceptual level, the decision level and the motor level. The perceptual level is subdivided into three further levels, relating to sensory processing, feature extraction and identification of the percept. On the decision level, the operator receives perceptual information and chooses a reaction to it which is finally programmed and actualized on the motor level. This describes only the information flow in the simplest case of a choice reaction. It is evident, though, that perceptual information may accumulate and be combined and diagnosed before eliciting an action. Again, there may arise a need for selecting information in view of perceptual overload. Finally, choosing an appropriate action becomes more of a problem when there are several options some of which may be more appropriate than others. In the present discussion, the emphasis will be on the perceptual and decisional factors of information processing.

Perceptual Capabilities and Limits

Sensory limits

The first category of processing limits is sensory. Their relevance to information processing is obvious since processing becomes less reliable as information approaches threshold limits. This may seem a fairly trivial statement, but nonetheless, sensory problems are not always clearly recognized in designs. For example, alphanumerical characters in sign posting systems should be sufficiently large to be legible at a distance consistent with the need for appropriate action. Legibility, in turn, depends not only on the absolute size of the alphanumericals but also on contrast and—in view of lateral inhibition—also on the total amount of information on the sign. In particular, in conditions of low visibility (e.g., rain or fog during driving or flying) legibility is a considerable problem requiring additional measures. More recently developed traffic signposts and road markers are usually well designed, but signposts near and within buildings are often illegible. Visual display units are another example in which sensory limits of size, contrast and amount of information play an important role. In the auditory domain some main sensory problems are related to understanding speech in noisy environments or in poor quality audio transmission systems.

Feature extraction

Provided sufficient sensory information, the next set of information processing issues relates to extracting features from the information presented. Most recent research has shown ample evidence that an analysis of features precedes the perception of meaningful wholes. Feature analysis is particularly useful in locating a special deviant object amidst many others. For instance, an essential value on a display containing many values may be represented by a single deviant colour or size, which feature then draws immediate attention or “pops out”. Theoretically, there is the common assumption of “feature maps” for different colours, sizes, forms and other physical features. The attention value of a feature depends on the difference in activation of the feature maps that belong to the same class, for example, colour. Thus, the activation of a feature map depends on the discriminability of the deviant features. This means that when there are a few instances of many colours on a screen, most colour feature maps are about equally activated, which has the effect that none of the colours pops out.

In the same way a single moving advertisement pops out, but this effect disappears altogether when there are several moving stimuli in the field of view. The principle of the different activation of feature maps is also applied when aligning pointers that indicate ideal parameter values. A deviation of a pointer is indicated by a deviant slope which is rapidly detected. If this is impossible to realize, a dangerous deviation might be indicated by a change in colour. Thus, the general rule for design is to use only a very few deviant features on a screen and to reserve them only for the most essential information. Searching for relevant information becomes cumbersome in the case of conjunctions of features. For example, it is hard to locate a large red object amidst small red objects and large and small green objects. If possible, conjunctions should be avoided when trying to design for efficient search.

Separable versus integral dimensions

Features are separable when they can be changed without affecting the perception of other features of an object. Line lengths of histograms are a case in point. On the other hand, integral features refer to features which, when changed, change the total appearance of the object. For instance, one cannot change features of the mouth in a schematic drawing of a face without altering the total appearance of the picture. Again, colour and brightness are integral in the sense that one cannot change a colour without altering the brightness impression at the same time. The principles of separable and integral features, and of emergent properties evolving from changes of single features of an object, are applied in so-called integrated or diagnostic displays. The rationale of these displays is that, rather than displaying individual parameters, different parameters are integrated into a single display, the total composition of which indicates what may be actually wrong with a system.

Data presentation in control rooms is still often dominated by the philosophy that each individual measure should have its own indicator. Piecemeal presentation of the measures means that the operator has the task of integrating the evidence from the various individual displays so as to diagnose a potential problem. At the time of the problems in the Three Mile Island nuclear power plant in the United States some forty to fifty displays were registering some form of disorder. Thus, the operator had the task of diagnosing what was actually wrong by integrating the information from that myriad of displays. Integral displays may be helpful in diagnosing the kind of error, since they combine various measures into a single pattern. Different patterns of the integrated display, then, may be diagnostic with regard to specific errors.

A classical example of a diagnostic display, which has been proposed for nuclear control rooms, is shown in figure 1. It displays a number of measures as spokes of equal length so that a regular polygon always represents normal conditions, while different distortions may be connected with different types of problems in the process.

Figure 1. In the normal situation all parameter values are equal, creating a hexagon. In the deviation, some of the values have changed creating a specific distortion.

ERG220F1Not all integral displays are equally discriminable. To illustrate the issue, a positive correlation between the two dimensions of a rectangle creates differences in surface, while maintaining an equal shape. Alternatively, a negative correlation creates differences in shape while maintaining an equal surface. The case in which variation of integral dimensions creates a new shape has been referred to as revealing an emergent property of the patterning, which adds to the operator’s ability to discriminate the patterns. Emergent properties depend upon the identity and arrangement of parts but are not identifiable with any single part.

Object and configural displays are not always beneficial. The very fact that they are integral means that the characteristics of the individual variables are harder to perceive. The point is that, by definition, integral dimensions are mutually dependent, thus clouding their individual constituents. There may be circumstances in which this is unacceptable, while one may still wish to profit from the diagnostic patternlike properties, which are typical for the object display. One compromise might be a traditional bar graph display. On the one hand, bar graphs are quite separable. Yet, when positioned in sufficiently close vicinity, the differential lengths of the bars may together constitute an object-like pattern which may well serve a diagnostic aim.

Some diagnostic displays are better than others. Their quality depends on the extent that the display corresponds to the mental model of the task. For example, fault diagnosis on the basis of distortions of a regular polygon, as in figure 1, may still bear little relationship to the domain semantics or to the concept of the operator of the processes in a power plant. Thus, various types of deviations of the polygon do not obviously refer to a specific problem in the plant. Therefore, the design of the most suitable configural display is one that corresponds to the specific mental model of the task. Thus it should be emphasized that the surface of a rectangle is only a useful object display when the product of length and width is the variable of interest!

Interesting object displays stem from three-dimensional representations. For instance, a three-dimensional representation of air traffic—rather than the traditional two-dimensional radar representation—may provide the pilot with a greater “situational awareness” of other traffic. The three-dimensional display has been shown to be much superior to a two-dimensional one since its symbols indicate whether another aircraft is above or below one’s own.

Degraded conditions

Degraded viewing occurs under a variety of conditions. For some purposes, as with camouflage, objects are intentionally degraded so as to prevent their identification. On other occasions, for example in brightness amplification, features may become too blurred to allow one to identify the object. One research issue has concerned the minimal number of “lines” required on a screen or “the amount of detail” needed in order to avoid degradation. Unfortunately, this approach to image quality has not led to unequivocal results. The problem is that identifying degraded stimuli (e.g., a camouflaged armoured vehicle) depends too much on the presence or absence of minor object-specific details. The consequence is that no general prescription about line density can be formulated, except for the trivial statement that degradation decreases as the density increases.

Features of alphanumeric symbols

A major issue in the process of feature extraction concerns the actual number of features which together define a stimulus. Thus, the legibility of ornate characters like Gothic letters is poor because of the many redundant curves. In order to avoid confusion, the difference between letters with very similar features—like the i and the l, and the c and the e—should be accentuated. For the same reason, it is recommended to make the stroke and tail length of ascenders and descenders at least 40% of the total letter height.

It is evident that discrimination among letters is mainly determined by the number of features which they do not share. These mainly consist of straight line and circular segments which may have horizontal, vertical and oblique orientation and which may differ in size, as in lower- and upper-case letters.

It is obvious that, even when alphanumericals are well discriminable, they may easily lose that property in combination with other items. Thus, the digits 4 and 7 share only a few features but they do not do well in the context of larger otherwise identical groups (e.g., 384 versus 387) There is unanimous evidence that reading text in lower case is faster than in capitals. This is usually ascribed to the fact that lower case letters have more distinct features (e.g., dog, cat versus DOG, CAT). The superiority of lower case letters has not only been established for reading text but also for road signs such as those used for indicating towns at the exits of motorways.

Identification

The final perceptual process is concerned with identification and interpretation of percepts. Human limits arising on this level are usually related to discrimination and finding the appropriate interpretation of the percept. The applications of research on visual discrimination are manifold, relating to alphanumerical patterns as well as to more general stimulus identification. The design of brake lights in cars will serve as an example of the last category. Rear-end accidents account for a considerable proportion of traffic accidents, and are due in part to the fact that the traditional location of the brake light next to the rear lights makes it poorly discriminable and therefore extends the driver’s reaction time. As an alternative, a single light has been developed which appears to reduce the accident rate. It is mounted in the centre of the rear window at approximately eye level. In experimental studies on the road, the effect of the central braking light appears to be less when subjects are aware of the aim of the study, suggesting that stimulus identification in the traditional configuration improves when subjects focus on the task. Despite the positive effect of the isolated brake light, its identification might still be further improved by making the brake light more meaningful, giving it the form of an exclamation mark, “!”, or even an icon.

Absolute judgement

Very strict and often counterintuitive performance limits arise in cases of absolute judgement of physical dimensions. Examples occur in connection with colour coding of objects and the use of tones in auditory call systems. The point is that relative judgement is far superior to absolute judgement. The problem with absolute judgement is that the code has to be translated into another category. Thus a specific colour may be linked with an electrical resistance value or a specific tone may be intended for a person for which an ensuing message is meant. In fact, therefore, the problem is not one of perceptual identification but rather of response choice, which will be discussed later in this article. At this point it suffices to remark that one should not use more than four or five colours or pitches so as to avoid errors. When more alternatives are needed one may add extra dimensions, like loudness, duration and components of tones.

Word reading

The relevance of reading separate word units in traditional print is demonstrated by various widely experienced evidence, such as the fact that reading is very much hampered when spaces are omitted, printing errors remain often undetected, and it is very hard to read words in alternating cases (e.g., ALTeRnAtInG). Some investigators have emphasized the role of word shape in reading word units and suggested that spatial frequency analysers may be relevant in identifying word shape. In this view meaning would be derived from total word shape rather than by letter-by-letter analysis. Yet, the contribution of word shape analysis is probably limited to small common words—articles and endings—which is consistent with the finding that printing errors in small words and endings have a relatively low probability of detection.

Text in lower case has an advantage over upper case which is due to a loss of features in the upper case. Yet, the advantage of lower case words is absent or may even be reversed when searching for a single word. It could be that factors of letter size and letter case are confounded in searching: Larger-sized letters are detected more rapidly, which may offset the disadvantage of less distinctive features. Thus, a single word may be about equally legible in upper case as in lower case, while continuous text is read faster in lower case. Detecting a SINGLE capital word amidst many lower case words is very efficient, since it evokes pop-out. An even more efficient fast detection can be achieved by printing a single lower case word in bold, in which case the advantages of pop-out and of more distinctive features are combined.

The role of encoding features in reading is also clear from the impaired legibility of older low-resolution visual display unit screens, which consisted of fairly rough dot matrices and could portray alphanumericals only as straight lines. The common finding was that reading text or searching from a low-resolution monitor was considerably slower than from a paper-printed copy. The problem has largely disappeared with the present-day higher-resolution screens. Besides letter form there are a number of additional differences between reading from paper and reading from a screen. The spacing of the lines, the size of the characters, the type face, the contrast ratio between characters and background, the viewing distance, the amount of flicker and the fact that changing pages on a screen is done by scrolling are some examples. The common finding that reading is slower from computer screens—although comprehension seems about equal—may be due to some combination of these factors. Present-day text processors usually offer a variety of options in font, size, colour, format and style; such choices could give the false impression that personal taste is the major reason.

Icons versus words

In some studies the time taken by a subject in naming a printed word was found to be faster than that for a corresponding icon, while both times were about equally fast in other studies. It has been suggested that words are read faster than icons since they are less ambiguous. Even a fairly simple icon, like a house, may still elicit different responses among subjects, resulting in response conflict and, hence, a decrease in reaction speed. If response conflict is avoided by using really unambiguous icons the difference in response speed is likely to disappear. It is interesting to note that as traffic signs, icons are usually much superior to words, even in the case where the issue of understanding language is not seen as a problem. This paradox may be due to the fact that the legibility of traffic signs is largely a matter of the distance at which a sign can be identified. If properly designed, this distance is larger for symbols than for words, since pictures can provide considerably larger differences in shape and contain less fine details than words. The advantage of pictures, then, arises from the fact that discrimination of letters requires some ten to twelve minutes of arc and that feature detection is the initial prerequisite for discrimination. At the same time it is clear that the superiority of symbols is only guaranteed when (1) they do indeed contain little detail, (2) they are sufficiently distinct in shape and (3) they are unambiguous.

Capabilities and Limits for Decision

Once a precept has been identified and interpreted it may call for an action. In this context the discussion will be limited to deterministic stimulus-response relations, or, in other words, to conditions in which each stimulus has its own fixed response. In that case the major problems for equipment design arise from issues of compatibility, that is, the extent to which the identified stimulus and its related response have a “natural” or well-practised relationship. There are conditions in which an optimal relation is intentionally aborted, as in the case of abbreviations. Usually a contraction like abrvtin is much worse than a truncation like abbrev. Theoretically, this is due to the increasing redundancy of successive letters in a word, which allows “filling out” final letters on the basis of earlier ones; a truncated word can profit from this principle while a contracted one cannot.

Mental models and compatibility

In most compatibility problems there are stereotypical responses derived from generalized mental models. Choosing the null position in a circular display is a case in point. The 12 o’clock and 9 o’clock positions appear to be corrected faster than the 6 o’clock and 3 o’clock positions. The reason may be that a clockwise deviation and a movement in the upper part in the display are experienced as “increases” requiring a response that reduces the value. In the 3 and 6 o’clock positions both principles conflict and they may therefore be handled less efficiently. A similar stereotype is found in locking or opening the rear door of a car. Most people act on the stereotype that locking requires a clockwise movement. If the lock is designed in the opposite way, continuous errors and frustration in trying to lock the door are the most likely result.

With respect to control movements the well-known Warrick’s principle on compatibility describes the relation between the location of a control knob and the direction of the movement on a display. If the control knob is located to the right of the display, a clockwise movement is supposed to move the scale marker up. Or consider moving window displays. According to most people’s mental model, the upward direction of a moving display suggests that the values go up in the same way in which a rising temperature in a thermometer is indicated by a higher mercury column. There are problems in implementing this principle with a “fixed pointer-moving scale” indicator. When the scale in such an indicator moves down, its value is intended to increasing. Thus a conflict with the common stereotype occurs. If the values are inverted, the low values are on the top of the scale, which is also contrary to most stereotypes.

The term proximity compatibility refers to the correspondence of symbolic representations to people’s mental models of functional or even spatial relationships within a system. Issues of proximity compatibility are more pressing as the mental model of a situation is more primitive, global or distorted. Thus, a flow diagram of a complex automated industrial process is often displayed on the basis of a technical model which may not correspond at all with the mental model of the process. In particular, when the mental model of a process is incomplete or distorted, a technical representation of the progress adds little to develop or correct it. A daily-life example of poor proximity compatibility is an architectural map of a building that is intended for viewer orientation or for showing fire escape routes. These maps are usually entirely inadequate—full of irrelevant details—in particular for people who have only a global mental model of the building. Such convergence between map reading and orientation comes close to what has been called “situational awareness”, which is particularly relevant in three-dimensional space during an air flight. There have been interesting recent developments in three-dimensional object displays, representing attempts to achieve optimal proximity compatibility in this domain.

Stimulus-response compatibility

An example of stimulus-response (S-R) compatibility is typically found in the case of most text processing programs, which assume that operators know how commands correspond to specific key combinations. The problem is that a command and its corresponding key combination usually fail to have any pre-existing relation, which means that the S-R relations must be learned by a painstaking process of paired-associate learning. The result is that, even after the skill has been acquired, the task remains error-prone. The internal model of the program remains incomplete since less practised operations are liable to be forgotten, so that the operator can simply not come up with the appropriate response. Also, the text produced on the screen usually does not correspond in all respects to what finally appears on the printed page, which is another example of inferior proximity compatibility. Only a few programs utilize a stereotypical spatial internal model in connection with stimulus-response relations for controlling commands.

It has been correctly argued that there are much better pre-existing relations between spatial stimuli and manual responses—like the relation between a pointing response and a spatial location, or like that between verbal stimuli and vocal responses. There is ample evidence that spatial and verbal representations are relatively separate cognitive categories with little mutual interference but also with little mutual correspondence. Hence, a spatial task, like formatting a text, is most easily performed by spatial mouse-type movement, thus leaving the keyboard for verbal commands.

This does not mean that the keyboard is ideal for carrying out verbal commands. Typing remains a matter of manually operating arbitrary spatial locations which are basically incompatible with processing letters. It is actually another example of a highly incompatible task which is only mastered by extensive practise, and the skill is easily lost without continuous practice. A similar argument can be made for shorthand writing, which also consists of connecting arbitrary written symbols to verbal stimuli. An interesting example of an alternative method of keyboard operation is a chording keyboard.

The operator handles two keyboards (one for the left and one for the right hand) both consisting of six keys. Each letter of the alphabet corresponds to a chording response, that is, a combination of keys. The results of studies on such a keyboard showed striking savings in the time needed for acquiring typing skills. Motor limitations limited the maximal speed of the chording technique but, still, once learned, operator performance approached the speed of the conventional technique quite closely.

A classical example of a spatial compatibility effect concerns the traditional arrangements of stove burner controls: four burners in a 2 ´ 2 matrix, with the controls in a horizontal row. In this configuration, the relations between burner and control are not obvious and are poorly learned. However, despite many errors, the problem of lighting the stove, given time, can usually be solved. The situation is worse when one is faced with undefined display-control relations. Other examples of poor S-R compatibility are found in the display-control relations of video cameras, video recorders and television sets. The effect is that many options are never used or must be studied anew at each new trial. The claim that “it is all explained in the manual”, while true, is not useful since, in practice, most manuals are incomprehensible to the average user, in particular when they attempt to describe actions using incompatible verbal terms.

Stimulus-stimulus (S-S) and response-response (R-R) compatibility

Originally S-S and R-R compatibility were distinguished from S-R compatibility. A classical illustration of S-S compatibility concerns attempts in the late forties to support auditory sonar by a visual display in an effort to enhance signal detection. One solution was sought in a horizontal light beam with vertical perturbations travelling from left to right and reflecting a visual translation of the auditory background noise and potential signal. A signal consisted of a slightly larger vertical perturbation. The experiments showed that a combination of the auditory and visual displays did not do better than the single auditory display. The reason was sought in a poor S-S compatibility: the auditory signal is perceived as a loudness change; hence visual support should correspond most when provided in the form of a brightness change, since that is the compatible visual analogue of a loudness change.

It is of interest that the degree of S-S compatibility corresponds directly to how skilled subjects are in cross-modality matching. In a cross-modality match, subjects may be asked to indicate which auditory loudness corresponds to a certain brightness or to a certain weight; this approach has been popular in research on scaling sensory dimensions, since it allows one to avoid mapping sensory stimuli to numerals. R-R compatibility refers to correspondence of simultaneous and also of successive movements. Some movements are more easily coordinated than others, which provides clear constraints for the way a succession of actions—for example, successive operation of controls—is most efficiently done.

The above examples show clearly how compatibility issues pervade all user-machine interfaces. The problem is that the effects of poor compatibility are often softened by extended practice and so may remain unnoticed or underestimated. Yet, even when incompatible display-control relations are well-practised and do not seem to affect performance, there remains the point of a larger error probability. The incorrect compatible response remains a competitor for the correct incompatible one and is likely to come through on occasion, with the obvious risk of an accident. In addition, the amount of practice required for mastering incompatible S-R relations is formidable and a waste of time.

Limits of Motor Programming and Execution

One limit in motor programming was already briefly touched upon in the remarks on R-R compatibility. The human operator has clear problems in carrying out incongruent movement sequences, and in particular, changing from the one to another incongruent sequence is hard to accomplish. The results of studies on motor coordination are relevant to the design of controls in which both hands are active. Yet, practice can overcome much in this regard, as is clear from the surprising levels of acrobatic skills.

Many common principles in the design of controls derive from motor programming. They include the incorporation of resistance in a control and the provision of feedback indicating that it has been properly operated. A preparatory motor state is a highly relevant determinant of reaction time. Reacting to an unexpected sudden stimulus may take an additional second or so, which is considerable when a fast reaction is needed—as in reacting to a lead car’s brake light. Unprepared reactions are probably a main cause of chain collisions. Early warning signals are beneficial in preventing such collisions. A major application of research on movement execution concerns Fitt’s law, which relates movement, distance and the size of the target that is aimed at. This law appears to be quite general, applying equally to an operating lever, a joystick, a mouse or a light pen. Among others, it has been applied to estimate the time needed to make corrections on computer screens.

There is obviously much more to say than the above sketchy remarks. For instance, the discussion has been almost fully limited to issues of information flow on the level of a simple choice reaction. Issues beyond choice reactions have not been touched upon, nor problems of feedback and feed forward in the ongoing monitoring of information and motor activity. Many of the issues mentioned bear a strong relation to problems of memory and of planning of behaviour, which have not been addressed either. More extensive discussions are found in Wickens (1992), for example.

 

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Contents

Ergonomics References

Abeysekera, JDA, H Shahnavaz, and LJ Chapman. 1990. Ergonomics in developing countries. In Advances in Industrial Ergonomics and Safety, edited by B Das. London: Taylor & Francis.

Ahonen, M, M Launis, and T Kuorinka. 1989. Ergonomic Workplace Analysis. Helsinki: Finnish Institute of Occupational Health.

Alvares, C. 1980. Homo Faber: Technology and Culture in India, China and the West from 1500 to Present Day. The Hague: Martinus Nijhoff.

Amalberti, R. 1991. Savoir-faire de l’opérateur: aspects théoriques et pratiques en ergonomie. In Modèle en analyse du travail, edited by R Amalberti, M de Montmollin, and J Thereau. Liège: Mardaga.

Amalberti, R, M Bataille, G Deblon, A Guengant, JM Paquay, C Valot, and JP Menu. 1989. Développement d’aides intelligentes au pilotage: Formalisation psychologique et informatique d’un modèle de comportement du pologage de combat engagé en mission de pènètration. Paris: Rapport CERMA.

Åstrand, I. 1960. Aerobic work capacity in men and women with special reference to age. Acta Physiol Scand 49 Suppl. 169:1-92.

Bainbridge, L. 1981. Le contrôleur de processus. B Psychol XXXIV:813-832.

—. 1986. Asking questions and accessing knowledge. Future Comput Sys 1:143-149.

Baitsch, C. 1985. Kompetenzentwicklung und partizipative Arbeitsgestaltung. Bern: Huber.

Banks, MH and RL Miller. 1984. Reliability and convergent validity of the job component inventory. J Occup Psychol 57:181-184.

Baranson, J. 1969. Industrial Technology for Developing Economies. New York: Praeger.

Bartenwerfer, H. 1970. Psychische Beanspruchung und Erdmüdung. In Handbuch der Psychologie, edited by A Mayer and B Herwig. Göttingen: Hogrefe.

Bartlem, CS and E Locke. 1981. The Coch and French study: A critique and reinterpretation. Hum Relat 34:555-566.

Blumberg, M. 1988. Towards a new theory of job design. In Ergonomics of Hybrid Automated Systems, edited by W Karwowski, HR Parsaei, and MR Wilhelm. Amsterdam: Elsevier.

Bourdon, F and A Weill Fassina. 1994. Réseau et processus de coopération dans la gestion du trafic ferroviaire. Travail Hum. Numéro spécial consacré au travail collectif.

Brehmer, B. 1990. Towards a taxonomy for microworlds. In Taxonomy for an Analysis of Work Domains. Proceedings of the First MOHAWC Workshop, edited by B Brehmer, M de Montmollin and J Leplat. Roskilde: Riso National Laboratory.

Brown DA and R Mitchell. 1986. The Pocket Ergonomist. Sydney: Group Occupational Health Centre.

Bruder. 1993. Entwicklung eines wissensbusierten Systems zur belastungsanalytisch unterscheidbaren Erholungszeit. Düsseldorf: VDI-Verlag.

Caverni, JP. 1988. La verbalisation comme source d’observables pour l’étude du fonctionnnement cognitif. In Psychologie cognitive: Modèles et méthodes, edited by JP
Caverni, C Bastien, P Mendelson, and G Tiberghien. Grenoble: Presses Univ. de Grenoble.

Campion, MA. 1988. Interdisciplinary approaches to job design: A constructive replication with extensions. J Appl Psychol 73:467-481.

Campion, MA and PW Thayer. 1985. Development and field evaluation of an inter-disciplinary measure of job design. J Appl Psychol 70:29-43.

Carter, RC and RJ Biersner. 1987. Job requirements derived from the Position Analysis Questionnaire and validity using military aptitude test scores. J Occup Psychol 60:311-321.

Chaffin, DB. 1969. A computerized biomechanical model-development of and use in studying gross body actions. J Biomech 2:429-441.

Chaffin, DB and G Andersson. 1984. Occupational Biomechanics. New York: Wiley.

Chapanis, A. 1975. Ethnic Variables in Human Factors Engineering. Baltimore: Johns Hopkins University.

Coch, L and JRP French. 1948. Overcoming resistance to change. Hum Relat 1:512-532.

Corlett, EN and RP Bishop. 1976. A technique for assessing postural discomfort. Ergonomics 19:175-182.

Corlett, N. 1988. The investigation and evaluation of work and workplaces. Ergonomics 31:727-734.

Costa, G, G Cesana, K Kogi, and A Wedderburn. 1990. Shiftwork: health, sleep and performance. Frankfurt: Peter Lang.

Cotton, JL, DA Vollrath, KL Froggatt, ML Lengnick-Hall, and KR Jennings. 1988. Employee participation: Diverse forms and different outcomes. Acad Manage Rev 13:8-22.

Cushman, WH and DJ Rosenberg. 1991. Human Factors in Product Design. Amsterdam: Elsevier.

Dachler, HP and B Wilpert. 1978. Conceptual dimensions and boundaries of participation in organizations: A critical evaluation. Adm Sci Q 23:1-39.

Daftuar, CN. 1975. The role of human factors in underdeveloped countries, with special reference to India. In Ethnic Variable in Human Factor Engineering, edited by Chapanis. Baltimore: Johns Hopkins University.

Das, B and RM Grady. 1983a. Industrial workplace layout design. An application of engineering anthropometry. Ergonomics 26:433-447.

—. 1983b. The normal working area in the horizontal plane. A comparative study between Farley’s and Squire’s concepts. Ergonomics 26:449-459.

Deci, EL. 1975. Intrinsic Motivation. New York: Plenum Press.

Decortis, F and PC Cacciabue. 1990. Modèlisation cognitive et analyse de l’activité. In Modèles et pratiques de l’analyse du travail, edited by R Amalberti, M Montmollin, and J Theureau. Brussels: Mardaga.

DeGreve, TB and MM Ayoub. 1987. A workplace design expert system. Int J Ind Erg 2:37-48.

De Keyser, V. 1986. De l’évolution des métiers. In Traité de psychologie du travail, edited by C Levy- Leboyer and JC Sperandio. Paris: Presses Universitaires de France.

—. 1992. Man within the Production Line. Proceedings of the Fourth Brite-EuRam Conference, 25-27 May, Séville, Spain. Brussels: EEC.

De Keyser, V and A Housiaux. 1989. The Nature of Human Expertise. Rapport Intermédiaire Politique Scientifique. Liège: Université de Liège.

De Keyser, V and AS Nyssen. 1993. Les erreurs humaines en anesthésie. Travail Hum 56:243-266.

De Lisi, PS. 1990. Lesson from the steel axe: Culture, technology and organizational change. Sloan Manage Rev 32:83-93.

Dillon, A. 1992. Reading from paper versus screen: A critical review of the empirical literature. Ergonomics 35:1297-1326.

Dinges, DF. 1992. Probing the limits of functional capacity: The effects of sleep loss on short-duration tasks. In Sleep, Arousal, and Performance, edited by RJ Broughton and RD Ogilvie. Boston: Birkhäuser.

Drury, CG. 1987. A biomechanical evaluation of the repetitive motion injury potential of industrial jobs. Sem Occup Med 2:41-49.

Edholm, OG. 1966. The assessment of habitual activity. In Physical Activity in Health and Disease, edited by K Evang and K Lange-Andersen. Oslo: Universitetterlaget.

Eilers, K, F Nachreiner, and K Hänicke. 1986. Entwicklung und Überprüfung einer Skala zur Erfassung subjektiv erlebter Anstrengung. Zeitschrift für Arbeitswissenschaft 40:215-224.

Elias, R. 1978. A medicobiological approach to workload. Note No. 1118-9178 in Cahiers De Notes Documentaires—Sécurité Et Hygiène Du Travail. Paris: INRS.

Elzinga, A and A Jamison. 1981. Cultural Components in the Scientific Attitude to Nature: Eastern and Western Mode. Discussion paper No. 146. Lund: Univ. of Lund, Research Policy Institute.

Emery, FE. 1959. Characteristics of Socio-Technical Systems. Document No. 527. London: Tavistock.

Empson, J. 1993. Sleep and Dreaming. New York: Harvester Wheatsheaf.

Ericson, KA and HA Simon. 1984. Protocol Analysis: Verbal Reports As Data. Cambridge, Mass.: MIT Press.

European Committee for Standardization (CEN). 1990. Ergonomic Principles of the Design of Work Systems. EEC Council Directive 90/269/EEC, The Minimum Health and Safety Requirements for the Manual Handling of Loads. Brussels: CEN.

—. 1991. CEN Catalogue 1991: Catalogue of European Standards. Brussels: CEN.

—. 1994. Safety of Machinery: Ergonomic Design Principles. Part 1: Terminology and General Principles. Brussels: CEN.

Fadier, E. 1990. Fiabilité humaine: méthodes d’analyse et domaines d’application. In Les facteurs humains de la fiabilité dans les systèmes complexes, edited by J Leplat and G De Terssac. Marseilles: Octares.

Falzon, P. 1991. Cooperative dialogues. In Distributed Decision Making. Cognitive Models for Cooperative Works, edited by J Rasmussen, B Brehmer, and J Leplat. Chichester: Wiley.

Faverge, JM. 1972. L’analyse du travail. In Traité de psychologie appliqueé, edited by M Reuchlin. Paris: Presses Universitaires de France.

Fisher, S. 1986. Stress and Strategy. London: Erlbaum.

Flanagan, JL. 1954. The critical incident technique. Psychol Bull 51:327-358.

Fleishman, EA and MK Quaintance. 1984. Toxonomies of Human Performance: The Description of Human Tasks. New York: Academic Press.

Flügel, B, H Greil, and K Sommer. 1986. Anthropologischer Atlas. Grundlagen und Daten. Deutsche Demokratische Republik. Berlin: Verlag tribüne.

Folkard, S and T Akerstedt. 1992. A three-process model of the regulation of alertness sleepiness. In Sleep, Arousal and Performance, edited by RJ Broughton and BD Ogilvie. Boston: Birkhäuser.

Folkard, S and TH Monk. 1985.  Hours of work: Temporal factors in work scheduling . Chichester: Wiley.

Folkard, S, TH Monk, and MC Lobban. 1978. Short and long-term adjustment of circadian rhythms in “permanent” night nurses. Ergonomics 21:785-799.

Folkard, S, P Totterdell, D Minors and J Waterhouse. 1993. Dissecting circadian performance rhythms: Implications for shiftwork.  Ergonomics  36(1-3):283-88.

Fröberg, JE. 1985. Sleep deprivation and prolonged working hours. In Hours of Work: Temporal Factors in Work Scheduling, edited by S Folkard and TH Monk. Chichester: Wiley.

Fuglesang, A. 1982. About Understanding Ideas and Observations on Cross-Cultural
Communication. Uppsala: Dag Hammarskjöld Foundation.

Geertz, C. 1973. The Interpretation of Cultures. New York: Basic Books.

Gilad, I. 1993. Methodology for functional ergonomic evaluation of repetitive operations. In Advances in Industrial Egonomics and Safety, edited by Nielsen and Jorgensen. London: Taylor & Francis.

Gilad, I and E Messer. 1992. Biomechanics considerations and ergonomic design in diamond polishing. In Advances in Industrial Ergonomics and Safety, edited by Kumar. London: Taylor & Francis.

Glenn, ES and CG Glenn. 1981. Man and Mankind: Conflict and Communication between Cultures. Norwood, NJ: Ablex.

Gopher, D and E Donchin. 1986. Workload—An examination of the concept. In Handbook of Perception and Human Performance, edited by K Boff, L Kaufman, and JP Thomas. New York: Wiley.

Gould, JD. 1988. How to design usable systems. In Handbook of Human Computer Interaction, edited by M Helander. Amsterdam: Elsevier.

Gould, JD and C Lewis. 1985. Designing for usability: Key principles and what designers think. Commun ACM 28:300-311.

Gould, JD, SJ Boies, S Levy, JT Richards, and J Schoonard. 1987. The 1984 Olympic message system: A test of behavioral principles of the design. Commun ACM 30:758-769.

Gowler, D and K Legge. 1978. Participation in context: Towards a synthesis of the theory and practice of organizational change, part I. J Manage Stud 16:150-175.

Grady, JK and J de Vries. 1994. RAM: The Rehabilitation Technology Acceptance Model as a Base for an Integral Product Evaluation. Instituut voor Research, Ontwikkeling en Nascholing in de Gezondheidszorg (IRON) and University Twente, Department of Biomedical Engineering.

Grandjean, E. 1988. Fitting the Task to the Man. London: Taylor & Francis.

Grant, S and T Mayes. 1991. Cognitive task analysis? In Human-Computer Interactionand Complex Systems, edited by GS Weir and J Alty. London: Academic Press.

Greenbaum, J and M Kyng. 1991. Design At Work: Cooperative Design of Computer Systems. Hillsdale, NJ: Lawrence Erlbaum.

Greuter, MA and JA Algera. 1989. Criterion development and job analysis. In Assessment and Selection in Organizations, edited by P Herlot. Chichester: Wiley.

Grote, G. 1994. A participatory approach to the complementary design of highly automated work systems. In Human Factors in Organizational Design and Management, edited by G Bradley and HW Hendrick. Amsterdam: Elsevier.

Guelaud, F, M-N Beauchesne, J Gautrat, and G Roustang. 1977. Pour une analyse des conditions du travail ouvrier dans l’entreprise. Paris: A. Colin.

Guillerm, R, E Radziszewski, and A Reinberg. 1975. Circadian rhythms of six healthy young men over a 4-week period with night-work every 48 h and a 2 per cent Co2 atmosphere. In Experimental Studies of Shiftwork, edited by P Colquhoun, S Folkard, P Knauth, and J Rutenfranz. Opladen: Westdeutscher Werlag.

Hacker, W. 1986. Arbeitspsychologie. In Schriften zur Arbeitpsychologie, edited by E Ulich. Bern: Huber.

Hacker, W and P Richter. 1994. Psychische Fehlbeanspruchung. Ermüdung, Monotonie, Sättigung, Stress. Heidelberg: Springer.

Hackman, JR and GR Oldham. 1975. Development of the job diagnostic survey. J Appl Psychol 60:159-170.

Hancock, PA and MH Chignell. 1986. Toward a Theory of Mental Work Load: Stress and Adaptability in Human-Machine Systems. Proceedings of the IEEE International Conference On Systems, Man, and Cybernetics. New York: IEEE Society.

Hancock, PA and N Meshkati. 1988. Human Mental Workload. Amsterdam: North Holland.

Hanna, A (ed.). 1990. Annual Design Review ID. 37 (4).

Härmä, M. 1993. Individual differences in tolerance to shiftwork: a review.  Ergonomics  36:101-109.

Hart, S and LE Staveland. 1988. Development of NASA-TLX (Task Load Index): Results of empirical and theoretical research. In Human Mental Work Load, edited by PA Hancock and N Meshkati. Amsterdam: North Holland.

Hirschheim, R and HK Klein. 1989. Four paradigms of information systems development. Commun ACM 32:1199-1216.

Hoc, JM. 1989. Cognitive approaches to process control. In Advances in Cognitive Science, edited by G Tiberghein. Chichester: Horwood.

Hofstede, G. 1980. Culture’s Consequences: International Differences in Work-Related Values. Beverly Hills, Calif.: Sage Univ. Press.

—. 1983. The cultural relativity of organizational practices and theories. J Int Stud :75-89.

Hornby, P and C Clegg. 1992. User participation in context: A case study in a UK bank. Behav Inf Technol 11:293-307.

Hosni, DE. 1988. The transfer of microelectronics technology to the third world. Tech Manage Pub TM 1:391-3997.

Hsu, S-H and Y Peng. 1993. Control/display relationship of the four-burner stove: A reexamination. Hum Factors 35:745-749.

International Labour Organization (ILO). 1990.The hours we work: new work schedules in policy and practice. Cond Wor Dig 9.

International Organization for Standardization (ISO). 1980. Draft Proposal for Core List of Anthropometric Measurements ISO/TC 159/SC 3 N 28 DP 7250. Geneva: ISO.

—. 1996. ISO/DIS 7250 Basic Human Body Measurements for Technological Design. Geneva: ISO.
Japan Industrial Design Promotion Organization (JIDPO). 1990. Good Design Products 1989. Tokyo: JIDPO.

Jastrzebowski, W. 1857. Rys ergonomiji czyli Nauki o Pracy, opartej naprawdach poczerpnietych z Nauki Przyrody. Przyoda i Przemysl 29:227-231.

Jeanneret, PR. 1980. Equitable job evaluation and classification with the Position Analysis Questionnaire. Compens Rev 1:32-42.

Jürgens, HW, IA Aune, and U Pieper. 1990. International data on anthropometry. Occupational Safety and Health Series. Geneva: ILO.

Kadefors, R. 1993. A model for assessment and design of workplaces for manual welding. In The Ergonomics of Manual Work, edited by WS Marras, W Karwowski, and L Pacholski. London: Taylor & Francis.

Kahneman, D. 1973. Attention and Effort. Englewood Cliffs, NJ: Prentice Hall.

Karhu, O, P Kansi, and I Kuorinka. 1977. Correcting working postures in industry: A practical method for analysis. Appl Ergon 8:199-201.

Karhu, O, R Harkonen, P Sorvali, and P Vepsalainen. 1981. Observing working postures in industry: Examples of OWAS application. Appl Ergon 12:13-17.

Kedia, BL and RS Bhagat. 1988. Cultural constraints on transfer of technology across nations: Implications for research in international and comparative management. Acad Manage Rev 13:559-571.

Keesing, RM. 1974. Theories of culture. Annu Rev Anthropol 3:73-79.

Kepenne, P. 1984. La charge de travail dans une unité de soins de médecine. Mémoire. Liège: Université de Liège.

Kerguelen, A. 1986. L’observation systématique en ergonomie: Élaboration d’un logiciel d’aide au recueil et à l’analyse des données. Diploma in Ergonomics Thesis, Conservatoire National des Arts et Métiers, Paris.

Ketchum, L. 1984. Sociotechnical design in a third world country: The railway maintenance depot at Sennar in Sudan. Hum Relat 37:135-154.

Keyserling, WM. 1986. A computer-aided system to evaluate postural stress in the workplace. Am Ind Hyg Assoc J 47:641-649.

Kingsley, PR. 1983. Technological development: Issues, roles and orientation for social psychology. In Social Psychology and Developing Countries, edited by Blacker. New York: Wiley.

Kinney, JS and BM Huey. 1990. Application Principles for Multicolored Displays. Washington, DC: National Academy Press.

Kivi, P and M Mattila. 1991. Analysis and improvement of work postures in building industry: Application of the computerized OWAS method. Appl Ergon 22:43-48.

Knauth, P, W Rohmert and J Rutenfranz. 1979. Systemic selection of shift plans for continuous production with the aid of work-physiological criteria. Appl Ergon 10(1):9-15.

Knauth, P. and J Rutenfranz. 1981. Duration of sleep related to the type of shift work, in  Night and shiftwork: biological and social aspects , edited by A Reinberg, N Vieux, and P Andlauer. Oxford Pergamon Press.

Kogi, K. 1982. Sleep problems in night and shift work. II. Shiftwork: Its practice and improvement . J Hum Ergol:217-231.

—. 1981. Comparison of resting conditions between various shift rotation systems for industrial workers, in  Night and shift work. Biological and social aspects , edited by A Reinberg, N Vieux, and P Andlauer. Oxford: Pergamon.

—. 1985. Introduction to the problems of shiftwork. In Hours of Work: Temporal Factors in Work-Scheduling, edited by S Folkard and TH Monk. Chichester: Wiley.

—. 1991. Job content and working time: The scope for joint change. Ergonomics 34:757-773.

Kogi, K and JE Thurman. 1993. Trends in approaches to night and shiftwork and new international standards. Ergonomics 36:3-13.

Köhler, C, M von Behr, H Hirsch-Kreinsen, B Lutz, C Nuber, and R Schultz-Wild. 1989. Alternativen der Gestaltung von Arbeits- und Personalstrukturen bei rechnerintegrierter Fertigung. In Strategische Optionen der Organisations- und Personalentwicklung bei CIM Forschungsbericht KfK-PFT 148, edited by Institut für Sozialwissenschaftliche Forschung. Karlsruhe: Projektträgerschaft Fertigungstechnik.

Koller, M. 1983. Health risks related to shift work. An example of time-contingent effects of long-term stress. Int Arch Occ Env Health 53:59-75.

Konz, S. 1990. Workstation organization and design. Ergonomics 32:795-811.

Kroeber, AL and C Kluckhohn. 1952. Culture, a critical review of concepts and definitions. In Papers of the Peabody Museum. Boston: Harvard Univ.

Kroemer, KHE. 1993. Operation of ternary chorded keys. Int J Hum Comput Interact 5:267-288.

—. 1994a. Locating the computer screen: How high, how far? Ergonomics in Design (January):40.

—. 1994b. Alternative keyboards. In Proceedings of the Fourth International Scientific Conference WWDU ‘94. Milan: Univ. of Milan.

—. 1995. Ergonomics. In Fundamentals of Industrial Hygiene, edited by BA Ploog. Chicago: National Safety Council.

Kroemer, KHE, HB Kroemer, and KE Kroemer-Elbert. 1994. Ergonomics: How to Design for Ease and Efficiency. Englewood Cliffs, NJ: Prentice Hall.

Kwon, KS, SY Lee, and BH Ahn. 1993. An approach to fuzzy expert systems for product colour design. In The Ergonomics of Manual Work, edited by Maras, Karwowski, Smith, and Pacholski. London: Taylor & Francis.

Lacoste, M. 1983. Des situations de parole aux activités interprétives. Psychol Franç 28:231-238.

Landau, K and W Rohmert. 1981. AET-A New Job Analysis Method. Detroit, Mich.: AIIE Annual Conference.

Laurig, W. 1970. Elektromyographie als arbeitswissenschaftliche Untersuchungsmethode zur Beurteilung von statischer Muskelarbeit. Berlin: Beuth.

—. 1974. Beurteilung einseitig dynamischer Muskelarbeit. Berlin: Beuth.

—. 1981. Belastung, Beanspruchung und Erholungszeit bei energetisch-muskulärer Arbeit—Literaturexpertise. In Forschungsbericht Nr. 272 der Bundesanstalt für Arbeitsschutz und Unfallforschung Dortmund. Bremerhaven: Wirtschaftsverlag NW.

—. 1992. Grundzüge der Ergonomie. Erkenntnisse und Prinzipien. Berlin, Köln: Beuth Verlag.

Laurig, W and V Rombach. 1989. Expert systems in ergonomics: Requirements and an approach. Ergonomics 32:795-811.

Leach, ER. 1965. Culture and social cohesion: An anthropologist’s view. In Science and Culture, edited by Holten. Boston: Houghton Mifflin.

Leana, CR, EA Locke, and DM Schweiger. 1990. Fact and fiction in analyzing research on participative decision making: A critique of Cotton, Vollrath, Froggatt, Lengnick-Hall, and Jennings. Acad Manage Rev 15:137-146.

Lewin, K. 1951. Field Theory in Social Science. New York: Harper.

Liker, JK, M Nagamachi, and YR Lifshitz. 1988. A Comparitive Analysis of Participatory Programs in US and Japan Manufacturing Plants. Ann Arbor, Mich.: Univ. of Michigan, Center for Ergonomics, Industrial and Operational Engineering.

Lillrank, B and N Kano. 1989. Continuous Improvement: Quality Control Circles in Japanese Industries. Ann Arbor, Mich.: Univ. of Michigan, Center for Japanese Studies.

Locke, EA and DM Schweiger. 1979. Participation in decision making: One more look. In Research in Organizational Behavior, edited by BM Staw. Greenwich, Conn.: JAI Press.

Louhevaara, V, T Hakola, and H Ollila. 1990. Physical work and strain involved in manual sorting of postal parcels. Ergonomics 33:1115-1130.

Luczak, H. 1982.  Belastung, Beanspruchung und Erholungszeit bei informatorisch- mentaler Arbeit — Literaturexpertise. Forschungsbericht der Bundesanstalt für Arbeitsschutz und Unfallforschung Dortmund . Bremerhaven: Wirtschaftsverlag NW.

—. 1983. Ermüdung. In Praktische Arbeitsphysiologie, edited by W Rohmert and J Rutenfranz. Stuttgart: Georg Thieme Verlag.

—. 1993. Arbeitswissenschaft. Berlin: Springer Verlag.

Majchrzak, A. 1988. The Human Side of Factory Automation. San Francisco: Jossey-Bass.

Martin, T, J Kivinen, JE Rijnsdorp, MG Rodd, and WB Rouse. 1991. Appropriate automation-integrating technical, human, organization, economic and cultural factors. Automatica 27:901-917.

Matsumoto, K and M Harada. 1994. The effect of night-time naps on recovery from fatigue following night work. Ergonomics 37:899-907.

Matthews, R. 1982. Divergent conditions in the technological development of India and Japan. Lund Letters on Technology and Culture, No. 4. Lund: Univ. of Lund, Research Policy Institute.

McCormick, EJ. 1979. Job Analysis: Methods and Applications. New York: American Management Association.

McIntosh, DJ. 1994. Integration of VDUs into the US office work environment. In Proceedings of the Fourth International Scientific Conference WWDU ‘94. Milan: Univ. of Milan.

McWhinney. 1990. The Power of Myth in Planning and Organizational Change, 1989 IEEE Technics, Culture and Consequences. Torrence, Calif.: IEEE Los Angeles Council.

Meshkati, N. 1989. An etiological investigation of micro and macroergonomics factors in the Bhopal disaster: Lessons for industries of both industrialized and developing countries. Int J Ind Erg 4:161-175.

Minors, DS and JM Waterhouse. 1981. Anchor sleep as a synchronizer of rhythms on abnormal routines.  Int J Chronobiology : 165-188.

Mital, A and W Karwowski. 1991. Advances in Human Factors/Ergonomics. Amsterdam: Elsevier.

Monk, TH. 1991.  Sleep, Sleepiness and Performance . Chichester: Wiley.

Moray, N, PM Sanderson, and K Vincente. 1989. Cognitive task analysis for a team in a complex work domain: A case study. Proceedings of the Second European Meeting On Cognitive Science Approaches to Process Control, Siena, Italy.

Morgan, CT, A Chapanis, JS III Cork, and MW Lund. 1963. Human Engineering Guide to Equipment Design. New York: McGraw-Hill.

Mossholder, KW and RD Arvey. 1984. Synthetic validity: A conceptual and comparative review. J Appl Psychol 69:322-333.

Mumford, E and Henshall. 1979. A Participative Approach to Computer Systems Design. London: Associated Business Press.

Nagamachi, M. 1992. Pleasantness and Kansei engineering. In Measurement Standards. Taejon, Korea: Korean Research Institute of Standards and Science Publishing.

National Institute for Occupational Safety and Health (NIOSH). 1981. Work Practices Guide for Manual Lifting. Cincinnati, Ohio: US Department of Health and Human Services.

—. 1990. OSHA Instruction CPL 2.85: Directorate of Compliance Programs: Appendix C, Guidelines Auggested By NIOSH for Videotape Evaluation of Work Station for Upper Extremities Cumulative Trauma Disorders. Washington, DC: US Department of Health and Human Services.

Navarro, C. 1990. Functional communication and problem-solving in a bus traffic-regulation task. Psychol Rep 67:403-409.

Negandhi, ART. 1975. Modern Organizational Behaviour. Kent: Kent Univ..

Nisbett, RE and TD De Camp Wilson. 1977. Telling more than we know. Psychol Rev 84:231-259.

Norman, DA. 1993. Things That Make Us Smart. Reading: Addison-Wesley.

Noro, K and AS Imada. 1991. Participatory Ergonomics. London: Taylor & Francis.

O’Donnell, RD and FT Eggemeier. 1986. Work load assessment methodology. In Handbook of Perception and Human Performance. Cognitive Processes and Performance, edited by K Boff, L Kaufman, and JP Thomas. New York: Wiley.

Pagels, HR. 1984. Computer culture: The scientific, intellectual and social impact of the computer. Ann NY Acad Sci :426.

Persson, J and Å Kilbom. 1983. VIRA—En Enkel Videofilmteknik För Registrering OchAnalys Av Arbetsställningar Och—Rörelser. Solna, Sweden: Undersökningsrapport,Arbetraskyddsstyrelsen.

Pham, DT and HH Onder. 1992. A knowledge-based system for optimizing workplace layouts using a genetic algorithm. Ergonomics 35:1479-1487.

Pheasant, S. 1986. Bodyspace, Anthropometry, Ergonomics and Design. London: Taylor & Francis.

Poole, CJM. 1993. Seamstress’ finger. Brit J Ind Med 50:668-669.

Putz-Anderson, V. 1988. Cumulative Trauma Disorders. A Manual for Musculoskeletal Diseases of the Upper Limbs. London: Taylor & Francis.

Rasmussen, J. 1983. Skills, rules, and knowledge: Sinds, signs, symbols and other distinctions in human performance models. IEEE T Syst Man Cyb 13:257-266.

—. 1986. A framework for cognitive task analysis in systems design. In Intelligent Decision Support in Process Environments, edited by E Hollnagel, G Mancini, and DD Woods. Berlin: Springer.

Rasmussen, J, A Pejtersen, and K Schmidts. 1990. In Taxonomy for Analysis of Work Domains. Proceedings of the First MOHAWC Workshop, edited by B Brehmer, M de Montmollin and J Leplat. Roskilde: Riso National Laboratory.

Reason, J. 1989. Human Error. Cambridge: CUP.

Rebiffé, R, O Zayana, and C Tarrière. 1969. Détermination des zones optimales pour l’emplacement des commandes manuelles dans l’espace de travail. Ergonomics 12:913-924.

Régie nationale des usines Renault (RNUR). 1976. Les profils de poste: Methode d’analyse des conditions de travail. Paris: Masson-Sirtes.

Rogalski, J. 1991. Distributed decision making in emergency management: Using a method as a framework for analysing cooperative work and as a decision aid. In Distributed Decision Making. Cognitive Models for Cooperative Work, edited by J Rasmussen, B Brehmer, and J Leplat. Chichester: Wiley.

Rohmert, W. 1962. Untersuchungen über Muskelermüdung und Arbeitsgestaltung. Bern: Beuth-Vertrieb.

—. 1973. Problems in determining rest allowances. Part I: Use of modern methods to evaluate stress and strain in static muscular work. Appl Ergon 4(2):91-95.

—. 1984. Das Belastungs-Beanspruchungs-Konzept. Z Arb wiss 38:193-200.

Rohmert, W and K Landau. 1985. A New Technique of Job Analysis. London: Taylor & Francis.

Rolland, C. 1986. Introduction à la conception des systèmes d’information et panorama des méthodes disponibles. Génie Logiciel 4:6-11.

Roth, EM and DD Woods. 1988. Aiding human performance. I. Cognitive analysis. Travail Hum 51:39-54.

Rudolph, E, E Schönfelder, and W Hacker. 1987. Tätigkeitsbewertungssystem für geistige arbeit mit und ohne Rechnerunterstützung (TBS-GA). Berlin: Psychodiagnostisches Zentrum der Humboldt-Universität.

Rutenfranz, J. 1982. Occupational health measures for night- and shiftworkers. II. Shiftwork: Its practice and improvement. J Hum Ergol:67-86.

Rutenfranz, J, J Ilmarinen, F Klimmer, and H Kylian. 1990. Work load and demanded physical performance capacity under different industrial working conditions. In Fitness for Aged, Disabled, and Industrial Workers, edited by M Kaneko. Champaign, Ill.: Human Kinetics Books.

Rutenfranz, J, P Knauth, and D Angersbach. 1981. Shift work research issues. In  Biological Rhythms, Sleep and Shift Work , edited by LC Johnson, DI Tepas, WP Colquhoun, and MJ Colligan. New York: Spectrum Publications Medical and Scientific Books.

Saito, Y. and K Matsumoto. 1988. Variations of physiological functions and psychological measures and their relationship on delayed shift of sleeping time.  Jap J Ind Health  30:196-205.

Sakai, K, A Watanabe, N Onishi, H Shindo, K Kimotsuki, H Saito, and K Kogl. 1984. Conditions of night naps effective to facilitate recovery from night work fatigue.  J Sci  Lab 60: 451-478.

Savage, CM and D Appleton. 1988. CIM and Fifth Generation Management. Dearborn: CASA/SME Technical Council.

Savoyant, A and J Leplat. 1983. Statut et fonction des communications dans l’activité des équipes de travail. Psychol Franç 28:247-253.

Scarbrough, H and JM Corbett. 1992. Technology and Organization. London: Routledge.

Schmidtke, H. 1965. Die Ermüdung. Bern: Huber.

—. 1971. Untersuchungen über den Erholunggszeitbedarf bei verschiedenen Arten gewerblicher Tätigkeit. Berlin: Beuth-Vertrieb.

Sen, RN. 1984. Application of ergonomics to industrially developing countries. Ergonomics 27:1021-1032.

Sergean, R. 1971. Managing Shiftwork. London: Gower Press.

Sethi, AA, DHJ Caro, and RS Schuler. 1987. Strategic Management of Technostress in an Information Society. Lewiston: Hogrefe.

Shackel, B. 1986. Ergonomics in design for usability. In People and Computer: Design for Usability, edited by MD Harrison and AF Monk. Cambridge: Cambridge Univ. Press.

Shahnavaz, H. 1991. Transfer of Technology to Industrially Developing Countries and Human Factors Consideration TULEÅ 1991: 22, 23024. Luleå Univ., Luleå, Sweden: Center for Ergonomics of Developing Countries.

Shahnavaz, H, J Abeysekera, and A Johansson. 1993. Solving multi-factorial work-environment problems through participatory ergonomics: Case study: VDT operators. In Ergonomics of Manual Work, edited by E Williams, S Marrs, W Karwowski, JL Smith, and L Pacholski. London: Taylor & Francis.

Shaw, JB and JH Riskind. 1983. Predicting job stress using data from the Position Analysis Questionnaire (PAQ). J Appl Psychol 68:253-261.

Shugaar, A. 1990. Ecodesign: New products for a greener culture. Int Herald Trib, 17.

Sinaiko, WH. 1975. Verbal factors in human engineering: Some cultural and psychological data. In Ethnic Variables in Human Factors Engineering, edited by A Chapanis. Baltimore: Johns Hopkins Univ..

Singleton, WT. 1982. The Body At Work. Cambridge: CUP.

Snyder, HL. 1985a. Image quality: Measures and visual performance. In Flat Panel Displays and CRTs, edited by LE Tannas. New York: Van Nostrand Reinhold.

—. 1985b. The visual system: Capabilities and limitations. In Flat Panel Displays and CRTs, edited by LE Tannas. New York: Van Nostrand Reinhold.

Solomon, CM. 1989. The corporate response to work force diversity. Pers J 68:42-53.

Sparke, P. 1987. Modern Japanese Design. New York: EP Dutton.

Sperandio, JC. 1972. Charge de travail et régulation des processus opératoires. Travail Hum 35:85-98.

Sperling, L, S Dahlman, L Wikström, A Kilbom, and R Kadefors. 1993. A cube model for the classification of work with hand tools and the formulation of functional requirements. Appl Ergon 34:203-211.

Spinas, P. 1989. User oriented software development and dialogue design. In Work With Computers: Organizational, Management, Stress and Health Aspects, edited by MJ Smith and G Salvendy. Amsterdam: Elsevier.

Staramler, JH. 1993. The Dictionary of Human Factors Ergonomics. Boca Raton: CRC Press.

Strohm, O, JK Kuark, and A Schilling. 1993. Integrierte Produktion: Arbeitspsychologische Konzepte und empirische Befunde, Schriftenreihe Mensch, Technik, Organisation. In CIM—Herausforderung an Mensch, Technik, Organisation, edited by G Cyranek and E Ulich. Stuttgart, Zürich: Verlag der Fachvereine.

Strohm, O, P Troxler and E Ulich. 1994. Vorschlag für die Restrukturierung eines
Produktionsbetriebes. Zürich: Institut für Arbietspsychologie der ETH.

Sullivan, LP. 1986. Quality function deployment: A system to assure that customer needs drive the product design and production process. Quality Progr :39-50.

Sundin, A, J Laring, J Bäck, G Nengtsson, and R Kadefors. 1994. An Ambulatory Workplace for Manual Welding: Productivity through Ergonomics. Manuscript. Göteborg: Lindholmen Development.

Tardieu, H, D Nanci, and D Pascot. 1985. Conception d’un système d’information. Paris: Editions d’Organisation.

Teiger, C, A Laville, and J Durafourg. 1974. Taches répétitives sous contrainte de temps et charge de travail. Rapport no 39. Laboratoire de physiologie du travail et d’ergonomie du CNAM.

Torsvall, L, T Akerstedt, and M. Gillberg. 1981. Age, sleep and irregular workhours: a field study with EEG recording, catecholamine excretion and self-ratings.  Scand J Wor Env Health  7:196-203.

Ulich, E. 1994. Arbeitspsychologie 3. Auflage. Zürich: Verlag der Fachvereine and Schäffer-Poeschel.

Ulich, E, M Rauterberg, T Moll, T Greutmann, and O Strohm. 1991. Task orientation and user-oriented dialogue design. In  Int J Human-Computer Interaction  3:117-144.

United Nations Educational, Scientific and Cultural Organization (UNESCO). 1992. Ergonomics Impact of Science on Society. Vol. 165. London: Taylor & Francis.

Van Daele, A. 1988. L’écran de visualisation ou la communication verbale? Analyse comparative de leur utilisation par des opérateurs de salle de contrôle en sidérurgie. Travail Hum 51(1):65-80.

—. 1992. La réduction de la complexité par les opérateurs dans le contrôle de processus continus. contribution à l’étude du contrôle par anticipation et de ses conditions de mise en œuvre. Liège: Université de Liège.

Van der Beek, AJ, LC Van Gaalen, and MHW Frings-Dresen. 1992. Working postures and activities of lorry drivers: A reliability study of on-site observation and recording on a pocket computer. Appl Ergon 23:331-336.

Vleeschdrager, E. 1986.  Hardness 10: diamonds . Paris.

Volpert, W. 1987. Psychische Regulation von Arbeitstätigkeiten. In Arbeitspsychologie. Enzklopüdie der Psychologie, edited by U Kleinbeck and J Rutenfranz. Göttingen: Hogrefe.

Wagner, R. 1985. Job analysis at ARBED. Ergonomics 28:255-273.

Wagner, JA and RZ Gooding. 1987. Effects of societal trends on participation research. Adm Sci Q 32:241-262.

Wall, TD and JA Lischeron. 1977. Worker Participation: A Critique of the Literature and Some Fresh Evidence. London: McGraw-Hill.

Wang, WM-Y. 1992. Usability Evaluation for Human-Computer Interaction (HCI). Luleå, Sweden: Luleå Univ. of Technology.

Waters, TR, V Putz-Anderson, A Garg, and LJ Fine. 1993. Revised NIOSH equation for the design and evaluation of manual handling tasks. Ergonomics 36:749-776.

Wedderburn, A. 1991. Guidelines for shiftworkers. Bulletin of European Shiftwork Topics (BEST) No. 3. Dublin: European Foundation for the Improvement of Living and Working Conditions.

Welford, AT. 1986. Mental workload as a function of demand, capacity, strategy and skill. Ergonomics 21:151-176.

White, PA. 1988. Knowing more about what we tell: ‘Introspective access’ and causal report accuracy, 10 years later. Brit J Psychol 79:13-45.

Wickens, C. 1992. Engineering Psychology and Human Performance. New York: Harper Collins.

Wickens, CD and YY Yeh. 1983. The dissociation between subjective work load and performance: A multiple resources approach. In Proceedings of the Human Factors Society 27th Annual Meeting. Santa Monica, Calif.: Human Factors Society.

Wieland-Eckelmann, R. 1992. Kognition, Emotion und Psychische Beanspruchung. Göttingen: Hogrefe.

Wikström.L, S Byström, S Dahlman, C Fransson, R Kadefors, Å Kilbom, E Landervik, L Lieberg, L Sperling, and J Öster. 1991. Criterion for Selection and Development of Hand Tools. Stockholm: National Institute of Occupational Health.

Wilkinson, RT. 1964. Effects of up to 60 hours sleep deprivation on different types of work. Ergonomics 7:63-72.

Williams, R. 1976. Keywords: A Vocabulary of Culture and Society. Glasgow: Fontana.

Wilpert, B. 1989. Mitbestimmung. In Arbeits- und Organisationspsychologie. Internationales Handbuch in Schlüsselbegriffen, edited by S Greif, H Holling, and N Nicholson. Munich: Psychologie Verlags Union.

Wilson, JR. 1991. Participation: A framework and foundation for ergonomics. J Occup Psychol 64:67-80.

Wilson, JR and EN Corlett. 1990. Evaluation of Human Work: A Practical Ergonomics Methodology. London: Taylor & Francis.

Wisner, A. 1983. Ergonomics or anthropology: A limited or wide approach to working condition in technology transfer. In Proceedings of the First International Conference On Ergonomics of Developing Countries, edited by Shahnavaz and Babri. Luleå, Sweden: Luleå Univ. of Technology.

Womack, J, T Jones, and D Roos. 1990. The Machine That Changed the World. New York: Macmillan.

Woodson, WE, B Tillman, and P Tillman. 1991. Human Factors Design Handbook. New York: McGraw-Hill.

Zhang, YK and JS Tyler. 1990. The establishment of a modern telephone cable production facility in a developing country. A case study. In International Wire and Cable Symposium Proceedings. Illinois.

Zinchenko, V and V Munipov. 1989. Fundamentals of Ergonomics. Moscow: Progress.