STUDY FOR ESTABLISHING DESIGN GUIDELINES FOR
MANUALS USING AUGMENTED REALITY TECHNOLOGY
Verification and Expansion of the Basic Model Describing “Effective Complexity”
Miwa Nakanishi
Facuty of Engineering, Chiba University, 1-33 Yayoi, Inage, Chiba, Japan
Shun-ichro Tamamushi and Yusaku Okada
Faculty of Science and Technology, Keio University, 3-14-1, Hiyoshi, Kohoku, Yokohama, Japan
Keywords: Augmented Reality, Information design, Mathematical modeling, Task performance.
Abstract: Augmented reality (AR), a technology that enables users to see an overlay of digital information on the real
view, is expected to be applied more and more to human factor innovation. It has been suggested that a
manual using AR (AR manual) improves accuracy and efficiency in actual work situations. To make an AR
manual practical, hardware such as see-through display or retinal scanning display has been actively
developed. However, software, i.e., information provided by the AR manual, has not been sufficiently
examined. In a recent study, the authors built a mathematical model that describes the “effective
complexity” of an AR manual according to the complexity of the real view. In this study, the basic model is
verified by applying it to the AR manual for a realistic task. Furthermore, the applicability of the basic
model is examined by assuming two different situations where either accuracy or efficiency has high
priority. The objective of this study is to establish rough but practical guidelines for designing an AR
manual.
1 INTRODUCTION
In recent years, the applicability of augmented
reality (AR), a technology that enables
superimposition of the real view and digital
information (Wellne et al., 1993) to manuals used in
actual work situations, has been discussed. For
example, when a manual is available to a worker
through a see-through head-mounted display
(HMD), he/she can see it superimposed on his/her
real view. Such AR manuals are considered to
reduce human errors and enhance task efficiency,
because they allow workers to easily compare a real
object with related information (Azuma,
1997)(Feiner, 2002). Moreover, as HMD technology
is improving rapidly, the hardware for AR manuals
has become almost ready for practical use. However,
the software has not yet reached this stage, because
requirements for designing information provided by
HMDs are not sufficiently clear. Thus, it is
necessary to establish guidelines for designing AR
manuals, which will differ from those for paper-
based manuals.
In a previous study (Nakanishi et al., 2008), the
authors examined how workers’ performance
changed depending on the layout of information
given by an AR manual through an experiment in
which real-world conditions were generated by a
computer program and presented on a monitor. From
the results, the authors built a model that provided
the most effective design of AR manuals according
to the real-world conditions (described more
specifically in the next section). We have positioned
that model as the basic model, which will be
fundamental to the guidelines for designing AR
manuals.
As the next step, we verify and expand the basic
model through another experiment in which a task
was performed not under computer-generated
conditions, but under real conditions. The objective
of this study is to analyze the relationship between
the design of AR manuals and task performance in
21
Nakanishi M., Tamamushi S. and Okada Y. (2009).
STUDY FOR ESTABLISHING DESIGN GUIDELINES FOR MANUALS USING AUGMENTED REALITY TECHNOLOGY - Verification and Expansion of
the Basic Model Describing “Effective Complexity”.
In Proceedings of the 11th International Conference on Enterprise Information Systems - Human-Computer Interaction, pages 21-26
DOI: 10.5220/0001856300210026
Copyright
c
SciTePress
conditions similar to actual work situations, and
suggest how to expand the basic model to practical
guidelines for designing AR manuals.
2 KEY IDEA OF THE BASIC
MODEL
In general, the real-world conditions in front of a
worker’s eyes cannot be controlled. Thus, we
attempt to clarify how AR manuals should be
designed when a condition of the real view is given.
For example, when excess information is
overlaid on an object in the real view, visibility may
decrease. On the other hand, when information is
overlaid on an object unit by unit, the worker is
required to switch the overlay repeatedly in a task
sequence.
In our previous study (Nakanishi and Okada,
2006), we performed an experiment in which
different real-world conditions were virtually
generated. We found that when the real view was
relatively uncomplicated, task performance was
affected more by switching images of the AR
manual than by seeing excess information.
Conversely, when the real view was complicated,
task performance was affected more by seeing
excess information than by switching images of the
AR manual. When these two factors were balanced,
task performance was the highest. Based on these
results, we built a model that describes the most
effective design of AR manuals according to real-
world conditions, as follows.
First, we considered two aspects of task
performance, “accuracy” (lack of errors) and
“efficiency” (speed). Assuming that both accuracy
and efficiency were equally necessary and important,
we defined “damage to task performance” (DP)
using both error rates (E) and unit operation time (T).
)T(S5.0)E(S5.0DP +=
(1)
S(E): Standardized E
S(T): Standardized T
Second, we quantified the conditions of visual
information based on the idea of “complexity.” In
general, the more crowded the items are, the more
complex the information looks. Thus, we defined
complexity (C) as the number of items to be
attended to (n) divided by their dispersion (M). M
was defined as the standard deviation of the distance
from each item to the center of them (d
i
: i = 1, 2,...,
n) divided by the mean of the distances (
d
), so that
C did not depend on measurement of d
i
.
∑
=
−−==
n
1i
2
i
)1n/()dd(/dnM/nC
(2)
We examined the data obtained from the
experiment and found that the relationship between
the complexity of the real view (C
R
), complexity of
the AR manual (C
A
), and DP could be expressed by
the following equation.
4131
(2.57 10 8.71 10 )(6.63 10 8.76 10 )
2
1.00 10
41
(1 (2.57 10 8.71 10 )( ) 3.00)
6.22
DP
CC
RA
C
R
C
A
=
−
−− −
×+× ×−×
+
×
−−
+− × + × −
+
(3)
Moreover, we suggested that when C
R
was
given, C
A
that minimized
DP
could be determined
by the following equation.
min.
DP
22.6
))1071.8C1057.2(1063.6
))1071.8C1057.2(1(1000.1
C
ˆ
1
R
43
1
R
42
A
−
×+××
×+×−×
=
−−−
−−+
(4)
Equation (4) provides the “effective complexity”
of AR manuals according to the complexity of the
real view. Accordingly, it can be regarded as the
basic model, which describes effective design of AR
manuals using the number and dispersion of
information items.
3 METHOD
In this study, we applied an AR manual that was
designed according to the basic model, not to a
computer-generated task but to a realistic task, and
examined the practicability of the model by
evaluating task performance.
3.1 Experimental Task
A wiring task, in which a subject plugged many
lines into a panel, was chosen as the experimental
task, because it has been proven that task
performance improved when subjects used an AR
manual compared to when they used a paper-based
manual in the same task.
The fixed panel (280 mm × 300 mm) included
randomly arranged holes (r = 3.5 mm) to be plugged.
Figure 1 shows an example pattern of the panel. An
HMD displayed the AR manual corresponding to
each pattern. Figure 2 shows an image of the AR
manual. The AR manual indicated which colored
lines should be plugged into which holes on the
ICEIS 2009 - International Conference on Enterprise Information Systems
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Figure 1: Example of panel pattern.
Figure 2: Image of AR manual. Figure 3: Superimposition. Figure 4: HMD.
Figure 5: Experimental environment.
panel. (Y: yellow, G: green, R: red, W: white, B:
blue).
A subject wearing the HMD faced the panel and
performed the task. The frames were drawn on both
the panel and the AR manual, so that he/she could
see them superimposed by adjusting his/her own
position and angle according to it (see Figures 3–5).
The subject’s task was to plug lines into all the
holes on the panel according to the AR manual. The
subjects were required to complete the task correctly
and quickly. Even if they recognized their own
errors, they were not allowed to correct them. A
subject started the task when the AR manual was
displayed on the HMD, and finished when all of the
holes on the panel were plugged.
3.2 Experimental Conditions
To set different conditions for the real view, five
panel patterns were prepared (Figures 6-1–6-5). The
AR manual was displayed in the following three
ways: “one-by-one indication” (each hole was
indicated one by one), “all-once indication” (all
holes were indicated at once), and “model-based
indication” (which holes were indicated at once was
determined according to the basic model).
Specifically, model-based indication was given as
follows. First, substituting each value of complexity
for each panel pattern (C
R
= {44.8, 96.3, 174.6,
271.4, 391.2}) in equation (4), the value of the
effective complexity of the AR manual (C
An
:
n = 24,
Figure 6-1: Pattern of panel (CR
= 44.8, n = 24).
Figure 6-2: Pattern of panel
(CR = 96.3, n = 40).
Figure 6-3: Pattern of panel
(CR = 174.6, n = 70).
Figure 6-4: Pattern of panel
(CR = 271.4, n=100)
Figure 6-5: Pattern of panel (CR
= 391.2, n=144).
Figure 7-1: One-by-one
indication (CR = 174.6).
Figure 7-2: Model-based
indication (CR = 174.6).
Figure 7-3: All-once
indication (CR = 174.6).
Y
R W G
R B
Y W
W
G Y
R R
Y
Y
R W G
R B
Y W
W
G Y
R R
Y
750mm
Subject
Panel
Line
45 deg.
Y
R W G
R B
Y W
W
G Y
R R
Y
WRY
GB B WR Y G
BWYG
RYWBGR
YWBGY
BRGWR
BW GY GY B WR
GY RB
WW R B G Y B
GW Y B R
WYBGGBY
BWYR
GBYG
W
STUDY FOR ESTABLISHING DESIGN GUIDELINES FOR MANUALS USING AUGMENTED REALITY
TECHNOLOGY - Verification and Expansion of the Basic Model Describing "Effective Complexity"
23
Table 1: Complexity of panels, effective complexity of AR manuals, and frequency of switching indication.
Number of holes Complexity of Panels Efective Complexity Frequency of Switching Indication
(n) (C
R
) (C
A
) (one-by-one) (model-based) (all-once)
24 44.8 33.3 23 2 0
40 93.6 31.3 39 3 0
70 174.6 27.9 69 5 0
100 271.4 22.8 99 8 0
144 391.2 14.2 143 14 0
follows. First, substituting each value of complexity
for each panel pattern (C
R
= {44.8, 96.3, 174.6,
271.4, 391.2}) in equation (4), the value of the
effective complexity of the AR manual (C
An
:
n = 24,
40, 70, 100, 144) was given for each panel pattern.
Second, the dispersion of the holes on each panel
pattern (M
n
:
n = 24, 40, 70, 100, 144) was given as
described in section 2. Third, substituting each M
n
in
equation (2), the number of holes to be
approximately indicated at once was determined for
each panel pattern. Table 1 shows the values of C
A
the “effective complexity” of the AR manual,
corresponding to each panel pattern. Moreover,
Figures 7-1–7-3 show example images of the one-
by-one, all-once, and model-based indication
corresponding to one of the panel patterns.
In this experiment, 15 conditions (5 real-world
conditions * 3 conditions of the AR manual) were
tested.
In the case of one-by-one or model-based
indication, the subject had to switch the image from
one hole to the next or from one part of the panel to
the next with a handy button. Table 1 shows how
many times the indication image was required to be
switched in each condition.
3.3 Experimental Settings
Eighteen students (age 21 to 25 years) with good
vision participated in the experiment. After they
repeated the procedure of the task in each condition
for training, they performed the task once in each
condition for data recording. Then the order of the
three indication patterns of the AR manual was
alternated within each condition of the real view.
The HMD was a retinal scanning device (NOMAD,
made by Microvision, Inc.). The transparency to the
real view was almost 100%. The image of the AR
manual was drawn in monochrome red.
During the task, subjects’ actions were recorded
with a digital video camera, and the time taken for
the task was automatically recorded. Moreover, after
the task, the panel with lines was compared with the
AR manual, and errors were noted.
4 RESULTS
To examine the task performance for each condition,
in particular, the condition in which model-based
indications were provided by the AR manual, we
analyzed the data in terms of accuracy and
efficiency.
4.1 Error Rate
The following errors were observed: omitting
plugging, plugging wrong-colored lines, and
plugging to wrong holes. The solid lines in Figures
8-1–8-5 show the error rates for each condition of
the real view (C
R
= {44.8, 96.3, 174.6, 271.4,
391.2}). In each chart, the left vertical axis is scaled
individually, in order to focus on how the error rates
changed according to the indication pattern of the
AR manual under the given condition of the real
view.
The error rate was high in the case of all-once
indication for any condition of the real view.
However, it tended to be low in the case of one-by-
one indication for most real-world conditions. In
addition, it was not always that the error rate became
low in the case of model-based indication.
4.2 Unit Operation Time
Plugging a line into a hole was defined as the unit
operation. The dotted lines in Figures 8-1–8-5 show
the unit operation time in each condition of the real
view (C
R
= {44.8, 96.3, 174.6, 271.4, 391.2}). In
each chart, the right vertical axis is scaled
individually, for the same reason as above.
The unit operation time tended to be short in the
case of model-based indication, however, it was
longer in the case of one-by-one indication that
required subjects to switch the image of the AR
manual, than in the other cases, in particular, when
the complexity of the real view was comparatively
low.
ICEIS 2009 - International Conference on Enterprise Information Systems
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Figure 8-1: Error rate per
task and unit operation
time (CR=44.8, n=24).
Figure 8-2: Error rate per
task and unit operation
time (CR=96.3, n=40).
Figure 8-3: Error rate per
task and unit operation
time (CR=174.6, n=70).
Figure 8-4: Error rate per
task and unit operation
time (CR=271.4, n=100).
Figure 8-5: Error rate per task and unit operation time
(CR=391.2, n=144).
* In Figures 8-1 to 8-5, the left-hand axis corresponds to
error rate (%), expressed by the solid line, and the right-
hand axis corresponds to unit operation time (s), expressed
by the dotted line.
5 VERIFICATION & EXPANSION
OF THE BASIC MODEL
As described in section 2, the basic model was built
under the assumption that accuracy and efficiency
are equally significant for evaluating task
performance. However, in actual situations, there are
cases in which workers absolutely should not make
errors even if it takes time to do so, and cases in
which they have to complete a task within a limited
time, wherein a few errors are permitted.
Figure 9-1: Damage to
task performance
(CR=44.8, n=24).
Figure 9-2: Damage to tas
k
p
erformance (CR=96.3,
n=40).
Figure 9-3: Damage to
task performance
(CR=174.6, n=70).
Figure 9-4: Damage to tas
k
p
erformance (CR=271.4,
n=100).
Figure 9-5: Damage to task performance (CR=391.2,
n=144).
** In Figure 9-1 to 9-5, the solid line shows DP(w = 0.5),
the dotted line shows DP(w = 0.2), and the dashed line
shows DP(w = 0.8). The horizontal axis indicates the
complexity of the AR manual. Accordingly, in any chart,
the middle plot indicates the value of DP in the case of
model-based indication.
In this section, first the applicability of the basic
model is checked under the assumption that
accuracy and efficiency are equally weighted.
Second, the applicability of the basic model is
discussed under the assumption that either accuracy
or efficiency is more heavily weighted.
5.1 Verification of the Basic Model
According to the basic model, DP can be calculated
for each condition by substituting E and T data in
3.0
3.5
4.0
0.000
0.005
0.010
0.015
one‐by‐one model‐based all‐once
Errorrate(%)
Unitoperationtime(sec)
3.5
4.0
4.5
0.000
0.005
0.010
one‐by‐one model‐based all‐once
Errorrate(%)
Unitoperationtime(sec)
4.0
4.5
0.000
0.005
0.010
one‐by‐one model‐based all‐once
Err orrate(%)
Unitoperationtime(sec)
4.0
4.1
4.2
0.000
0.005
0.010
one‐by‐one model‐based all‐once
Errorrate(%)
Unitoperationtime(sec)
4.0
4.5
5.0
0.000
0.005
0.010
one‐by‐one model‐based all‐once
Err orrate(%)
Unitoperationtime(sec)
‐1.0
‐0.5
0.0
0.5
1.0
0 1020304050
DP
CA
DP(0.5) DP(0.2) DP(0.8)
‐1.0
‐0.5
0.0
0.5
1.0
050100
DP
CA
DP(0.5) DP(0.2) DP(0.8)
‐1.0
‐0.5
0.0
0.5
1.0
0100200
DP
CA
DP(0.5) DP(0.2) DP(0.8)
‐1.0
‐0.5
0.0
0.5
1.0
0 100 200 300
DP
CA
DP(0.5) DP(0.2) DP(0.8)
‐1.0
‐0.5
0.0
0.5
1.0
0 100 200 300 400
DP
CA
DP(0.5) DP(0.2) DP(0.8)
STUDY FOR ESTABLISHING DESIGN GUIDELINES FOR MANUALS USING AUGMENTED REALITY
TECHNOLOGY - Verification and Expansion of the Basic Model Describing "Effective Complexity"
25
equation (1) (see section 2). The solid lines in
Figures 9-1–9-5 show the values of DP in this case.
DP is minimized in the case of model-based
indication for any condition of the real view,
indicating that the AR manual designed according to
the basic model enhances task performance. This
suggests that the basic model describes effective
design of an AR manual not under computer-
generated conditions, but also under the real
conditions, if it is assumed that accuracy and
efficiency are equally important for the situation.
5.2 Expanding the Applicability of the
Basic Model
Assuming cases where either accuracy or efficiency
is more heavily weighted, damage to performance
(DP (w)) is redefined as follows.
)T(S)w1()E(wS)w(DP −+=
(5)
In the discussion below, two different cases are
simulated.
Case 1) Efficiency is weighted more heavily than
accuracy (w = 0.2).
)T(S8.0)E(S2.0)w(DP +=
(6)
Substituting the data of E and T in equation (6),
DP(0.2) in each condition of the real view (C
R
=
{44.8, 96.3, 174.6, 271.4, 391.2}) is calculated, as
shown by the dotted lines in Figures 9-1–9-5.
Like DP(0.5), which is expressed by the solid
line, DP(0.2) is lowest in the case of model-based
indication for any condition of the real view. This
indicates that the basic model is also applicable to
cases where efficiency has higher priority than
accuracy.
Case 2) Accuracy is weighted more heavily than
efficiency (w = 0.8).
)T(S2.0)E(S8.0)w(DP +=
(7)
Substituting the data of E and T in equation (7),
DP(0.8) for each condition of the real view (C
R
=
{44.8, 96.3, 174.6, 271.4, 391.2}) is calculated, as
shown by the dashed lines in Figures 9-1–9-5.
In some real-world conditions (C
R
= 44.8 and
271.4), DP(0.8) is minimized in cases other than
model-based indication. However, DP(0.8) tends to
be low in the case of one-by-one indication for any
condition of the real view. This suggests that one-
by-one indication should be used in situations where
accuracy has higher priority than efficiency.
In summary, the effectiveness of the basic model
depends on whether accuracy or efficiency is more
important in a particular situation. In fact, it is
difficult to quantitatively estimate the weight of each
in real situations. However, we roughly recommend
that AR manuals designed according to the basic
model should be used in most situations, but AR
manuals should provide information unit by unit in
situations where errors have to be strictly avoided.
6 CONCLUSIONS
In this study, we applied the basic model not to
computer-generated conditions, but to realistic
conditions and verified its effectiveness. Further, we
examined the applicability of the basic model to
different situations.
Essentially, both accuracy and efficiency are
important in actual situations, and it is not
appropriate to determine the weight of each.
However, AR manuals are expected to be widely
used. Thus, even rough guidelines considering
different situations in designing such a manual will
be helpful. In future studies, we will validate the
model, and demonstrate feasibility for actual field
use.
ACKNOWLEDGEMENTS
This work was supported in part by the Ministry of
Education, Science, Sports and Culture, a Grant-in-
Aid for Young Scientists (B), 20710130.
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P.Wellner, W.Mackay, R.Gold, 1993.Computer-Augmented
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R.T.Azuma, 1997. A Survey of Augmented Reality,
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385.
S.K.Feiner, 2002, Augmented Reality: A New Way of
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that can enhance and enrich a user's view of the world,
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M.Nakanishi, T.Akasaka, Y.Okada, 2008. Modeling
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