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A Comparison of Still, Animated, or Nonillustrated On-Line Help with Written or Spoken Instructions in a Graphical User Interface

Susan M. Harrison

Department of Computer Science
University of Wisconsin-Eau Claire
Eau Claire, WI 54702
(715) 836-5381
harrison@uwec.edu

© ACM

Abstract

Current forms of on-line help do not adequately reflect the graphical and dynamic nature of modern graphical user interfaces. Many of today's software applications provide text-based on-line help to assist users in performing a specific task. This report describes a study in which 176 undergraduates received on-line help instructions for completing seven computer-based tasks. Instructions were provided in either written or spoken form with or without still graphic or animated visuals. Results consistently revealed that visuals, either still graphic or animated, in the on-line help instructions enabled the users to significantly perform more tasks in less time and with fewer errors than did users who did not have visuals accompanying the on-line help instructions. Although users receiving spoken instructions were faster and more accurate for the initial set of tasks than were users receiving written instructions, the majority of subjects preferred written instructions over spoken instructions. The results of this study suggest additional empirically-based guidelines to designers for the development of effective on-line help.

Keywords:

Graphical user interfaces, on-line help, visuals, user interface components.

Introduction

With the advancement of microcomputer technology and the use of graphical user interfaces, the number of features available within software applications has rapidly increased. Word 5.0a [22] for example, is a word processing package for the Macintosh that presents the user with a choice of 97 features in the opening screen of the text-based on- line help system. The Excel 4.0 spreadsheet package [23] lists 22 features in the first level of the text-based help directory, and a second listing appears containing 111 features for the spreadsheet's worksheet.

Unfortunately, advances in the design of on-line help systems have not matched recent advances in the design of interface technology. Researchers have observed that subjects in need of assistance often do not utilize the on-line help available [9,20,32]. Subjects cited "poor quality of the help information" as a common reason for avoiding on-line help. Researchers have found that the common textual form of on-line help tends to hinder rather than help the user in the performance of procedural tasks [9,10,15,32]. The visual and dynamic nature of modern graphical user interfaces is not captured by the traditional form of on-line help [33,37].

The on-line help of this study presented instructions for completing procedures involving the creation, editing, and deletion of five types of objects within a HyperCard environment. HyperCard is an integrated object-oriented programming system for the development of documents with linked segments of information of text, sound, and graphics [25]. The visual illustrations presented within the on-line help of this study included still graphics and animated visuals in the form of a computer-generated demonstration using animation.

The relative effectiveness of each design of the on-line help within this study was evaluated by the speed and accuracy in which the user performed each procedure. As suggested in performance measurement guidelines by Bovair and Kieras [8], dependent measures of completion rates, elapsed time, and error rates were used to evaluate the effectiveness of written or spoken instructions with or without still graphic or animated visuals in enhancing the user's performance of computer-based procedures within a graphical user interface environment.

BACKGROUND

Designers of on-line help presenting procedural instructions "should concentrate on ensuring that the procedure construction goes smoothly" [8,p.227]. Procedure construction is part of the process of acquiring a procedural skill - a process that researchers recognize as an aggregate of three phases. In the first phase relevant facts for performing the skill are encoded and committed to memory in a declarative form [3]. The learner focuses on understanding the skill by often verbally rehearsing the information as the skill is performed. Strategies for executing the procedure are formulated, tested, and executed in a consciously controlled way [31] during this phase, resulting in slow and error-prone performance [1]. During the second phase, execution errors are gradually detected and eliminated as the learner practices the skill [24]. The execution of the procedure becomes automated and faster through extensive additional practice as the set of individual steps are collapsed into one large unit during the third phase [2].

The amount of practice the user invests in learning a procedural skill is the user's choice, not the researcher's or the software designer's. This study investigated the effectiveness of design elements in on-line help without the variable of practice. By excluding the use of practice, this study was able to focus on the design effects of on-line help rather than on practice effects.

PREVIOUS RESEARCH

Only a few studies reported in the literature employed the use of on-line help for computer-based procedures and only three of those studies [27,28,37] investigated the use of graphics and animation in on-line help. These studies incorporated the use of practice in addition to the on-line help as a means of aiding the user in acquiring the procedural skills.

Shneiderman [33] contends that use of a graphical demonstration is the most direct way for novices to learn the basic functionality and steps necessary to perform procedures within the graphical user interface environment. A few researchers [26,28,37] have investigated the potential use of demonstrations within on-line help for presenting procedural information. Such demonstrations of real-time instantiations of computer-based procedures have been termed "animated demonstrations" [28]. Like still graphics, animated demonstrations immediately show what objects are used within the procedures. This approach was shown to be partially effective [27,28]. Segmented animated demonstrations, presenting one step of a multi- step task at a time, may aid the user in developing discrete steps of the procedure. Unless the animation is segmented, the user may not be able to identify and encode specific aspects of the procedure [8,26]. No studies were found, however, that investigated the use of segmented animated demonstrations.

Overall, the research with on-line help indicates that the current use of text-based on-line help is generally ineffective [10,11,12,15,18]. Researchers agree, however, that the effectiveness of on-line help may be improved if on-line help was properly developed using empirically based guidelines. The empirical evidence from research investigating the use of instructions, audio, visuals, and animation in the design of on-line help suggest that on-line help for procedural tasks may be more effective when:

By following these guidelines for the design of the on-line help, the user's mental representation of the procedure should be more accurately constructed, the referential links to the physical objects should be better connected, and the individual segmented steps of the procedure should be better organized within memory thus providing a proper foundation for the successful performance of the procedure.

EMPIRICALLY-BASED ON-LINE HELP DESIGN

The design of the elements in the on-line help adhered as close as possible to the empirically-based guidelines listed. The order and the language of the instructions, in both written and spoken forms, were based on the guidelines presented. Still graphic or animated visuals were added to the instructions. The spoken instructions accompanying the still graphics or animation were designed to begin immediately after the first visual appeared on the screen or as soon as the animation sequence started. The step-by-step procedural information was presented in a segmented form. In-depth information pertaining to the studies associated with the guidelines listed is found in [17].

The combinations of written or spoken instructions with or without still graphics or animated visuals in a segmented form made this study one of the first experiments of its kind to investigate the effectiveness of on-line help on the performance of computer-based procedures within a graphical user interface environment. This study was designed to investigate the relative effectiveness between:

METHODOLOGY

The experimental context of this study was a HyperCard emulator with on-line help in which subjects received instructions for completing seven procedural tasks. This study used a 2 x 3 randomized factorial design with Verbal Instruction and Visual Illustration as the two treatment factors. The Verbal Instruction factor was the presentation of instructions either in spoken or written form. The Visual Illustration factor presented either no illustrations, still graphic illustrations, or animated graphics.

Participants

Participants for this study were drawn from an available pool of 215 undergraduate students enrolled in the Science Curriculum and Instruction course within the School of Education and in the Introduction to Computers and Their Uses course within the School of Arts and Science at a university of approximately 10,000 students. To be eligible to participate in the study, each student was required: (a) to demonstrate a basic ability in the use of a Macintosh computer, keyboard, mouse, and pull-down menus; (b) to have no previous experience in the authoring techniques of HyperCard [5]; (c) to have completed the HyperCard Tour 2.0v2 tutorial [4]; and (d) to have demonstrated an understanding of the basic computer and HyperCard concepts. These requirements reduced the potential sample size to 198. Equipment failures, language barriers, and lack of attendance during the experiment resulted in 176 participants being randomly assigned to one of the six treatment groups.

Materials

All materials used in this study, including the computer program, were designed and developed by the experimenter in consultation with experts in the areas of survey construction and simulation programming. A set of eight HyperCard authoring tasks were used in this study. An example of a task explanation, specific task description, and task steps for one of the tasks is shown in FIGURE 1.

FIGURE 1. Details of Change Button Icon Task.

HyperCard Emulator Design. A HyperCard emulator was developed in SuperCard [34] to avoid potential difficulties involved in programming and controlling menu responses and capturing timing information and mouse locations while using the actual HyperCard application. The HyperCard emulator included the screen images, menu options, and dialog boxes normally seen during the process of performing the HyperCard procedures used as tasks in the study. The basic layout of the screen shown in FIGURE 2 was divided into four functional areas [16].

FIGURE 2: Screen Design with Four Functional Areas.

The large main functional area, the work space, covered three-fourths of the upper portion of the screen. The work space was used to display the simulated HyperCard menu bar and all still or animated graphics. Subjects performed all tasks in this area using the simulated menu bar and related dialog boxes. Welcome Information and Task Explanations covered this area when such information was displayed.

Information and options relating to the current step of a task being explained or performed were placed in the second functional area positioned at the bottom of the screen. To the left of this area, the number of the current step and the option to repeat a step were located. The main portion of the informational area contained the current step instruction. An abbreviated version of the task requirement was shown below the current step instruction.

Supplemental information concerning the current phase of the study was displayed in the third area located in the upper right corner of the screen. When the Abort option appeared after four incorrect attempts were made to complete a step, it also appeared in this area. The fourth area located at the bottom right of the screen contained the current navigational option. Options, displayed one at a time, included advancing to the next step, beginning the task test, continuing, beginning Help, and exiting.

Color was added to the screen design to help divide the functional areas. The dark areas shown on the screen were displayed as a medium to light blue. The background of any informational field was a light yellow. The colors for the screen design were specifically selected as a result of the user evaluations. The final version of the emulator, complete with all sounds for the spoken instructions and converted to a stand-alone application consumed 1,287K on a high-density diskette.

Treatment Designs. All steps for a given task were presented consecutively in all treatments. To maintain a sense of realism, a simulated HyperCard menu bar was visible across the top of the screen for all treatment groups. Subjects using spoken forms of the Verbal Help or seeing animated forms of the Visual Help were allowed to replay the current step of the task. Immediately after the Help presentation for the task, subjects were required to complete the task once without additional access to help. The completion of the task was part of the Immediate Exercise set, and the screens that were accessed were the same for all treatment groups.

The Written, Animated Treatment, WA, animated the cursor movement required to perform the instruction. This movement provided subjects with a visual cue to the important point of the instruction. Options on pull-down menus were highlighted as the cursor moved down through the choices. FIGURE 3 demonstrates the way the cursor moved across the screen and activated a pull-down menu on the help screen for the WA treatment. Although four screens are used in FIGURE 3, all cursor movement in the treatment occurred on the same screen.

FIGURE 3: Four Screens Demonstrating an Example of Written Animated Help Screens.

A still graphic that corresponded only to the written step instruction was shown in the work area of the screen for the Written, Still Graphic Treatment, WS. The graphic illustrated the way the screen looked as that step of the procedure was completed, screen (d) of FIGURE 3.

Subjects assigned to the Written, Nonillustrated Treatment, WN, were provided written step instructions, one at a time, in the same location at the bottom of the screen as illustrated in screen (a) of FIGURE 3. As in other written treatments, the task requirement was displayed below the written instruction and the step indicator was located to the left of the written instruction. Graphic examples were not provided for the WN treatment.

Subjects in all spoken treatments were presented each step instruction through a set of headphones. Spoken instructions were identical to the written instructions presented to written treatment groups.

No written instructions appeared on the screen in the Spoken, Nonillustrated Treatment, SN, treatment. The area normally used for written instructions was covered with a medium blue color. The task requirement, however, was shown at the bottom of the screen Graphic examples were not provided for the SN treatment. The Repeat Step option, located below the step indicator, was available to allow the subjects to replay the instruction.

Both the Spoken, Still Graphic Treatment, SS, shown in FIGURE 4 and the Spoken, Animated Treatment, SA, provided visuals similar to those described for the WS and WA treatments, respectively. Like the SN treatment, step instructions were verbally presented through a set of headphones and no written instructions appeared on the screen.

FIGURE 4: Spoken, Still Graphic Treatment Screen.

Questionnaire. Seven sets of mirror images of statements assessing the subjects' reactions to the help instructions were created. For example, if the original statement said "I prefer to receive help instructions in a written rather than spoken form," the mirror image said "I prefer to receive help instructions in a spoken rather than written form." The questionnaire used a six-point scale ranging from Strongly Agree to Strongly Disagree.

Procedures

Eight groups of subjects, composed of 20 to 30 people, completed the study using Macintosh LC II computers in the university computer laboratory. The experimenter arranged the subjects in the room so that subjects assigned nonillustrated help could not see the screens displaying of illustrated help and subjects assigned still graphic help could not see the screens displaying animated help. Subjects were guided through the steps of completing one practice task using the on-line help instructions. After all subjects had tried the task and questions were answered by the experimenter, subjects continued with the seven tasks of the Immediate Exercise set.

The following steps were repeated for each task in the set.

Dependent Measures

Audit trails, commonly used in analyzing learner-computer interactions [38], were included in the HyperCard Emulator to record completion rate, elapsed time, and error rate. Values for each category were directly collected or calculated by the HyperCard Emulator for each step of a task and for each task of the set. Responses to the questionnaire were entered into a data file and verified by the experimenter.

RESULTS

Data were analyzed for 176 subjects randomly assigned to the six treatment groups as shown in FIGURE 5.

FIGURE 5: Two by Three Randomized Design of the Study.

A priori orthogonal contrasts, shown in FIGURE 6, were used for analyzing the data of the six treatment cells. Contrast Visual (1) compared treatment groups receiving nonillustrated and illustrated (still graphic and animated) forms of help. Visual (2) compared treatment groups receiving still graphic and animated forms of help.

FIGURE 6: A Priori Orthogonal Contrasts Used in Analysis.

Although multiple contrasts were used in the analysis, only the comparison of the nonillustrated and illustrated groups revealed any significant differences in the study.

Effectiveness was measured in terms of the dependent variables for completion rate and error rate. Efficiency was measured in terms of the dependent variable for the time the subject used in attempting to complete a task or set of tasks.

Completion Rates for Exercise Sets

Completion rates were inspected in two ways: the percent of each treatment group completing all seven procedural tasks of the set and the average percent of tasks completed within each treatment group.

Percent of treatment group completing all tasks. A log-linear comparison of the cell proportions across treatment groups for subjects who completed all seven tasks of the Immediate Exercise set with subjects who did not complete all seven tasks revealed a significant difference for the nonillustrated versus illustrated contrast (coef. = .19, 95% CI = .08 to .30). An examination of cell frequencies showed that only 22 of the 58 subjects or 37.9% of the nonillustrated groups (WN, SN) completed the entire Immediate Exercise set. With the illustrated (WS, SS, WA, SA) groups, 78 of the 118 subjects or 66.1% completed the entire Immediate Exercise set.

Average percent of tasks completed. The number of tasks completed out of the seven possible tasks of the exercise set was converted to a percentage for each subject. A significant difference for the nonillustrated versus illustrated contrast was detected (F(1, 170) = 12.99, p < .001). Cell means for the percent of tasks completed within the Immediate Exercise set by treatment group reveal that the nonillustrated groups (WN, SN) have a combined mean completion rate of 83.5% (n = 58, SD = 18.69). The illustrated groups (WS, WA, SS, WA) have a combined mean completion rate of 92.5% (n = 118, SD = 13.82).

Error Rates for Exercise Sets

Since subjects were allowed to abort the performance of a procedural task on any step of the procedure, calculations for error rates were based on errors per step attempted. When error rates were evaluated, a significant difference was found for the nonillustrated versus illustrated contrast (F(1, 170) = 22.48, p < .001) when an a level of .01 was used. An evaluation of cell means shows the combined nonillustrated (WN, SN) conditions to have a higher error rate (M = 1.83, SD = 1.33, n = 58) than the error rate (M = .95, SD = 1.08, n = 118) of the combined illustrated conditions (WS, WA, SS, WA).

Elapsed Time for Exercise Sets

Because subjects did not always complete all of the steps of a given procedural task within the exercise set, elapsed times were measured based on the number of seconds a subject spent in attempting to complete a step of a procedure. To calculate elapsed time per step, the total amount of time elapsed while the subject attempted to complete all task steps was divided by the total number of steps the subject attempted to complete. Results of the MANOVA test for the illustration contrast and an inspection of the cell means indicated that the significant differences occurred (F(1, 170) = 28.99, p < .001) with nonillustrated groups having a mean elapsed time of 13.80 seconds and illustrated groups having a mean of 9.58 seconds.

DISCUSSION

Nonillustrated versus Illustrated The findings of this study add support to the notion that the presence of a visual, either a still graphic or an animation, aids the subjects in acquiring accurate representations of the steps involved in the procedure. At least two possible explanations exist for why subjects receiving illustrated on-line help exhibited faster and more accurate initial performances of the procedural tasks than did the other subjects.

First, the visuals contained pictures of the objects in the graphical user interface that were to be used in performing the procedure. Phrases such as Edit Menu, the OK button, and Field tool, scroll down arrow, and Shared Text box, mentioned in the instructions, could have been internally mapped to the actual object. Second, the visuals provided an example of the system response to the user input so the subject would not be surprised by the screen image displayed. Subjects in the illustrated groups were perhaps more prepared for the next step of the procedure since they would have known what image would appear as a result of their action. The presentation of the illustrations during the on-line help may have allowed subjects to visually rehearse and plan the actions necessary for the completion of the procedure. It is likely that subjects in the nonillustrated groups were unable to be prepared since they lacked the ability to mentally picture the screen image associated with the action's response.

Still Graphic versus Animated Illustrations

An unexpected result of this study was the lack of a significant difference between the subjects' performance in the still- graphic conditions and the animated conditions. However, the data suggested a slight advantage for animation over still graphics as expected. One possible explanation for the lack of difference is that the task performed in this study did not require the coding of motion information which would have been provided by the animation. In this study, the main difference between the information provided by the still graphic condition and the information provided by the animated condition was the movement of the cursor. It is likely that subjects inferred the movement of the cursor by mentally noting the change in cursor location from the graphic image illustrating the first step to the graphic image illustrating the second step. If the procedural tasks had involved the movement of an actual object such as the resizing of a button or the changing of a picture's location, it is possible that significant differences would have been found between the still- graphic and animated conditions.

A second possible explanation for the similar results between the still-graphics condition and the animated condition relates to the use of segmentation. Individual task steps were emphasized by each image presented in the still- graphics condition. If the animated presentation had been presented in a continuous form, like the animated demonstrations in the Palmiter [26] study, it may have been difficult for the subjects to identify the individual procedural steps. However, since the animation provided in this study was segmented to emphasize each step of the procedural task, subjects in both the still-graphics and animated conditions probably were equally able to identify each procedural step. The segmentation of the animated illustration may be one reason why the animated conditions consistently performed better than the other conditions across time and type of tasks. Although the better performance was nonsignificant when compared to the other groups, results showing that the animated groups tended to maintain their high performance across time are noteworthy since those results contradict the findings of the Palmiter [26] studies.

Implications of the Findings

Caution should be exercised in generalizing from this population to a larger population of college students and from the procedural tasks included in this study to other computer-based procedures. The robustness of the findings of this study, however, provides a strong basis for suggesting that instructions for computer-based procedures presented via on-line help should be accompanied by some form of visual illustration. Designers of current on-line help facilities in the graphical user interface environment should be encouraged to consider changing from the standard from of text-based on- line help to a form of on-line help that incorporates graphics.

Recommendations for Future Research

Based on the results of this study, the review of the literature, and the general observations made by the experimenter during this study, two areas of research for investigating the effectiveness of on-line help are recommended. Since tasks in this study did not involve the aspect of motion beyond the movement of the cursor, no significant advantages were revealed for the use of animation. Research needs to be conducted using a set of computer-based procedures involving the movement of different objects on the screen to help determine the effectiveness of animation in on-line help.

When the on-line help information in this study was presented, the work space on the subject's monitor was completely filled. Since the size of the typical computer monitor is rapidly increasing as technology advances, different conclusions about the effectiveness of on-line help may have been reached if the on-line help information remained visible on the screen as the subject completed the procedure. A study could be conducted to compare how the presence or absence of the on-line help during task performance affects the completion of a computer-based procedure.

The results from this study can be summarized in one statement: The use of visuals within on-line help instructions for computer-based procedures enabled adult subjects to perform more procedural steps in less time and with fewer errors than subjects who received no visuals within on-line help instructions. Insights gained from this investigation should contribute to the current knowledge base used by designers to guide their development of on-line help and ultimately help the end-user.

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