wong-kt.pdf


Australasian Journal of
Educational Technology

2012, 28(7), 1190-1207

Influence of gender and computer teaching efficacy on
computer acceptance among Malaysian student teachers:
An extended technology acceptance model
Kung-Teck Wong
Sultan Idris Education University, Malaysia

Timothy Teo
University of Auckland

Sharon Russo
University of South Australia

The purpose of this study is to validate the technology acceptance model (TAM) in an
educational context and explore the role of gender and computer teaching efficacy as
external variables. From the literature, it appeared that only limited studies had
developed models to explain statistically the chain of influence of computer teaching
efficacy and gender on the intention of student teachers to use computers. A total of
302 student-teachers completed the questionnaire measuring their responses to
computer teaching efficacy (CTE), perceived usefulness (PU), perceived ease of use
(PEU), attitude toward computer use (ATCU), and behavioural intention (BI).
Structural equation modelling (SEM) was used as the main technique for data analysis.
The findings from this study suggest that the model was adequately explained by the
data. Overall, the model accounted for 36.8% of the variance in intention to use
computers among student teachers. The results have also provided support for
computer teaching efficacy and gender as significant variables in the TAM. Finally, the
implications for theory development, practices, and policy making are discussed.

Introduction

Since the mid-1960s, technologies have had revolutionary impacts upon teaching and
learning. Technologies have extended the ability of teachers to manage and
disseminate knowledge, and provided new opportunities for students to enhance the
new knowledge in various aspects (Chai, Koh & Tsai, 2010; Hong & Songan, 2011).  In
this information age, Malaysia, like other developed countries, has a clear vision that
information and communications technology (ICT) can transform conventional
education systems and bring advantages and benefits to the country as a whole,
especially for the younger generation (Wong, Goh, Hanafi & Osman, 2010). For a
while, Malaysian schools have devoted considerable resources to make computer
technology an integral part of students’ learning experiences, with a view to equipping
them with the skills and knowledge necessary to succeed in the 21st century.

The push to incorporate and integrate technology in classroom teaching at all levels
became much stronger in the Malaysian education system after the introduction of
Smart School. The Smart School is one of the seven flagship applications underlying the



Wong, Teo and Russo 1191

Multimedia Super Corridor (MSC) which began its operations in 1997. The establishment
of the MSC program is to transform Malaysia into a modern state by the year 2020. The
objectives of the Smart School are to develop technology savvy individuals and
eradicate computer illiteracy. Such strategies began with a sum of 150 million
Malaysian Ringgit allocated for 1340 schools to develop their multimedia facilities and
computer laboratories, thus paving the way for a revised school curriculum.

The success of integrating technology in teaching and learning depends strongly upon
the engagement of teachers. Having teachers who are competent in using and
managing educational technology is important. Teachers are expected to be on the
frontline of this educational reform.  As such, the groundwork must be laid at student
teacher’s level. There is a growing corpus of research suggesting the importance of
understanding the levels of technology acceptance among student teachers, as it is the
key factor associated with classroom use of technology in the future. It is important to
ensure that the new upcoming teachers are comfortable and capable in integrating ICT
into our students’ education.

The Malaysian Government has also injected millions of Ringgit to equip student
teachers with a range of computer skills and knowledge, and simultaneously ensure a
higher level of technology integration in teaching and learning. They must be well
trained in order to integrate computers into their curricula. Today, numerous teacher
education providers in Malaysia have made extensive efforts to implement effective
and meaningful use of technology in their teacher education programs (Wong et al.,
2010).

Focus of the present study

While Malaysian stakeholders in education expect a high level of technology adoption
in the classrooms, there is also a growing concern that many Malaysian student
teachers lack the experience or skills to integrate this new technology in teaching and
learning (Wong et al., 2010). Researchers from other parts of the world and from
Malaysia have provided evidence to support the crucial role that student teachers play
in the process of implementing computers in the classrooms (Almekhlafi &
Almeqdadi, 2010; Rasimah, Ahmad & Zaman, 2011; Wong & Teo, 2009), implying that
an understanding of how student teachers react is essential for any successful
implementation of computer use in the classroom. This will also in turn, provide
insight into issues relating to the acceptance of technology among student teachers.
The need to explore factors influencing Malaysian student teachers’ acceptance of
computing has become a crucial issue and it needs to be addressed urgently.

In this study, the theoretical grounding for exploring factors influencing student
teachers’ use of computers is drawn from the technology acceptance model (TAM)
(Davis, 1989) (Figure 1). The TAM posits that perceived usefulness and perceived ease
of use are the two key fundamental predictors of user acceptance of a system.
Perceived usefulness is defined as the degree to which a person believes that using a
particular technology will enhance his or her job performance. Perceived ease of use is
considered the extent to which a person believes that using the system will be free of
effort (Davis, 1989). This means that both perceived usefulness and perceived ease of
use are the determinants that extrinsically motivate student teachers to use technology.
Since its inception, many studies have expanded this model to include study of a broad
range of end users (Teo & Noyes, 2011; Venkatesh & Davis, 2000). King & He (2006)



1192 Australasian Journal of Educational Technology, 2012, 28(7)

conducted a meta-analysis on TAM and found 88 published studies supporting the
validation of the TAM.

Figure 1: Technology acceptance model (TAM)

Despite the accolades given to the TAM for its predictive ability, it is crucial to explore
further into the contribution of external variables. Indeed, many recent studies have
found the effects of the external variables, which include perceived enjoyment (Teo &
Noyes, 2011), facilitating conditions (Terzis & Economides, 2011), social influence
(Moran, Hawkes & El Gayar, 2010; Terzis & Economides, 2011), self-efficacy (Ahmad,
Basha, Marzuki, Hisham & Sahari, 2010; Chen, 2010; Moran et al., 2010; Terzis &
Economides, 2011), as extension variables toward the TAM to explain the intention to
use technology. Thus, in this research, the researchers believe that using generic TAM
might result in inconsistent outcomes. Furthermore, Venkatesh and Morris (2000)
suggested that self-efficacy or computer self-efficacy should be included as a
determinant to explain the acceptance behaviours of its users.

From the literature, it appeared that some technology acceptance studies have
highlighted the importance of computer self-efficacy, in explaining the chain of
influence toward the attitude and behavioural intention among Malaysian student
teachers (Ahmad et al., 2010; Teo, 2009a). However, none was directly related to
teachers’ computer teaching efficacy. Thus, those findings are unable to contribute
much in the field of educational technology in the Malaysian context. This study has
gone a step further to address a specific pedagogical self-efficacy issue; that is, the
influence of student teachers’ computer teaching efficacy on their intention to use
computers. Computer teaching efficacy is referred to as an evaluation of their
capability to teach with computers and their personal belief in using computers as an
effective teaching tool to improve students’ performance in learning.

Examining student teachers’ intention to use technology is yet another area in which
gender may manifest itself. However, generally it has been neglected in technology
acceptance studies (Gefen & Straub, 1997). Having that, this study further understands
the moderating effect of gender on the relationship between the determinants and
behavioural intention. Over decades, although many studies have investigated the role
of gender in computer related attitudes and its use, very few studies have incorporated
gender as moderator in assessing the correlations between computer teaching efficacy,
perceived ease of use, and perceived usefulness towards the intention of computer use
in an educational context. Chu (2010) revealed that gender differences in the use of the

External
variables

Perceived
usefulness

Perceived ease
of use

Attitudes
toward using

Behavioural
intention to

use

Actual
system

use



Wong, Teo and Russo 1193

technology should be carefully examined, rather than merely demonstrating
differences. Understanding gender differences in the strength of the path coefficients
could bring further insight into stereotypical beliefs regarding gender issues especially
in developing countries. Furthermore, the magnitude of gender differences may vary
across cultures (Gefen & Straub, 1997). Premised on the above mentioned situation, the
present study was conducted to explore the applicability of the TAM in an educational
context with gender and computer teaching efficacy as external variables in the TAM.

Theoretical framework and hypotheses

With the ongoing development of educational technologies, various theoretical models
have emerged to explore and explain factors that influence users’ acceptance, rejection
or continuing use of new technology   (Ajzen, 1985; Ajzen & Fishbein, 1980; Venkatesh
& Davis, 2000; Venkatesh, Morris, Davis, & Davis, 2003). Rooted in the work of Ajzen
and Fishbein’s model, Theory of Reasoned Action (TRA), Davis (1989) introduced and
developed the Technology Acceptance Model (TAM) and provided a theoretical context
that explained the relationship of attitude-intention-behaviour (Figure 1). Based on the
TAM, perceived usefulness and perceived ease of use are hypothesised to be
fundamental determinants of user acceptance.

Many reports provide evidence of the impact of perceived usefulness and perceived
ease of use on attitude toward usage and behavioural intention (Rasimah et al., 2011;
Teo, 2011; Wong & Teo, 2009; Sumak, Hericko, Pusnik & Polancic, 2011). Wong and
Teo found that those variables were significant determinants of the attitude and
intention to use technology among student teachers. Furthermore, perceived
usefulness had a direct impact on intention to use, while perceived ease of use
influenced intention to use indirectly through attitude.

Sumak et al. (2011) revealed that perceived usefulness and perceived ease of use were
factors that directly affected students’ attitude, and perceived usefulness was the
strongest and most significant determinant of students’ attitude toward using
technology in learning. This finding was in congruence with that of Davis (1989), and
Davis, Bagozzi and Warshaw (1989). Davis et al. (1989) also found that perceived ease
of use would have only one direction towards perceived usefulness and this has been
confirmed by recent studies (Shroff, Deneen & Ng, 2011; Teo, 2011; Sumak et al., 2011).
The following hypotheses were generated:

H1a Perceived usefulness will significantly and positively influence student teachers’
attitude toward computer use.

H1b Perceived usefulness will significantly and positively influence student teachers’
behavioural intention to use computer.

H2a Perceived ease of use will significantly and positively influence student teachers’
perceived usefulness.

H2b Perceived ease of use will significantly and positively influence student teachers’
attitude toward computer use.

H3 Attitude toward computer use will significantly and positively influence student
teachers’ behavioural intention to use computers.



1194 Australasian Journal of Educational Technology, 2012, 28(7)

External variables

Computer teaching efficacy

Computer teaching efficacy refers to student teachers’ evaluation of their capability to
teach with computers (self-efficacy belief), and their personal beliefs in using
computers as an effective teaching method to improve students’ performance in
learning (outcomes expectation). Computer teaching efficacy is drawn from Bandura’s
self-efficacy theory (Bandura, 1977), which advocated a belief in one’s capability for
performing a specific task. Bandura’s theory states that people will be motivated to
perform an action if they are confident that they can perform that action successfully,
and believe that the action will have a favourable result (outcome expectation).

There is a growing corpus of studies which suggest that a causal link exists between
self-efficacy and perceived usefulness (Ahmad et al., 2010; Chen, 2010; Compeau &
Higgins, 1995; Hayes, 2007; Venkatesh, 2000; Wong et al., 2010; Wozney, Venkatesh &
Abrami, 2006). Chen (2010) found that pre-service teachers’ self-efficacy of teaching
with technology had the strongest influence on technology use, which was mediated
by their belief about the usefulness of technology in teaching and learning with
technology. This was coherent with Wong et al. (2010) who found that that self-efficacy
was a good predictor for computer use among mathematics, science and English
language teachers in Malaysia. Wozney et al. (2006) found that teachers’ expectancy of
success and prediction of positive outcomes of their actions were the vital
determinants for their levels of computer use. Venkatesh (2000) and Hayes (2007)
noted that self-efficacy had a direct effect on perceived ease of use. Hayes conducted a
study in Australian classrooms and revealed that the more confident an instructor was
in his or her abilities to use information systems, the more the instructor believed that
the system could be used easily. This finding is consistent with Ahmad et al. (2010)
who found that computer self-efficacy was an important determinant in affecting
faculty members’ use of computer technology.

H4a Computer teaching efficacy will significantly and positively influence student
teachers’ perceived usefulness.

H4b Computer teaching efficacy will significantly and positively influence student
teachers’ perceived ease of use.

H4c Computer teaching efficacy will significantly and positively influence student-
teachers’ attitude toward computer use.

Gender

The debate over the gender gap that started in the 1980s still persists in the new
millennium. Recently, many researchers have revisited the issue of its role in different
perspectives in the educational technology context. Gender differences in terms of
teacher belief, teacher self-efficacy, and attitude towards computers is an important
research field (Sang, Valcke, van Braak & Tondeur, 2010). Sieverding and Koch (2009)
investigated gender differences in computer self-efficacy and revealed that women
have lower computer self-efficacy than men. This finding was in line with the findings
of Koch, Muller and Sieverding (2008) and Ong and Lai (2006).

Gefen and Straub (1997), Venkatesh and Morris (2000), Venkatesh et al. (2003), Wang
and Shih (2009) and Wang and Wang (2010) investigated the effect of gender on



Wong, Teo and Russo 1195

technology acceptance and determined that gender significantly moderated the effects
of perceived usefulness and perceived ease of use towards behavioural intention.
Studies found that men were more task-oriented and affected by perceived usefulness,
while women were more affected by perceived ease of use which was related to their
self-efficacy (Venkatesh, et al., 2003; Wang & Shih, 2009). The following hypotheses
were generated, giving the research model in Figure 2:

H5a Computer teaching efficacy influences perceived usefulness more strongly for
men than for women.

H5b Computer teaching efficacy influences perceived ease of use more strongly for
men than for women.

H5c Computer teaching efficacy influences attitude toward computer use more
strongly for men than for women.

H6a Perceived usefulness influences attitude toward computer use more strongly for
men than for women.

H6b Perceived usefulness influences behavioural intention more strongly for men
than for women.

H7a Perceived ease of use influences attitude toward computer use more strongly for
women than for men.

H8 Attitude toward computer use influences behavioural intention more strongly
for men than for women.

   H4c

Figure 2: Research model

Research method
Research design

Data were gathered by means of a survey questionnaire, containing questions focusing
on demographics and scales measuring the variables in the research model (Figure 2):
computer teaching efficacy, perceived usefulness, perceived ease of use, attitude

Computer
teaching
efficacy

Perceived
ease of use

Perceived
usefulness

Attitude toward
computer use

Behavioural
intention

Moderating effects: gender (H5a, H5b, H5c, H6a, H6b, H7a, H8)

H4a

H2b

H1b

H4b

H4c

H3

H1a

H2a



1196 Australasian Journal of Educational Technology, 2012, 28(7)

toward computer use, and behavioural intention. Methodologically, structural
equation modelling (SEM) has been used to assess the validity of the TAM in the
Malaysian student teachers’ context and explore the impacts of extended variables,
gender and computer teaching self-efficacy, on the suggested model. From the
literature, SEM is widely used to predict or explain the determinants of a user’s
intention or use of technology in an educational setting (Terzis & Economides, 2011;
Sumak et al., 2011). The AMOS statistics software program was employed in this
study.

Participants and data collection

Participants were student teachers from the Sultan Idris Education University (UPSI)
in Malaysia. A total of 302 respondents, representing a response rate of 86.4%,
completed the survey questionnaire. Some questionnaires were discarded due to being
only partially complete.  Among these participants, 64.2% (194) were female, and the
mean age of all participants was 22.9 years (SD=2.12). Most of them frequently
accessed a computer at home (77.33%). Participation was wholly voluntary and no
course credits were given. All participants were briefed on the purpose of the study
and told of their right to withdraw during or after the data collection. The
questionnaires were distributed and collected during the final hour on the last day of
lectures. Participants were given about 20 minutes to complete the questionnaire.

Instruments

A self-report questionnaire was developed for the survey. The survey measured five
constructs and a total of 13 items on computer teaching efficacy, perceived usefulness,
perceived ease of use, attitude toward computer use and behavioural intention.
Respondents were asked to indicate the items on a four-point Likert scale ranging from
strongly disagree (1), slightly disagree (2), slightly agree (3), to strongly agree (4). Each
item was coded so that the higher the score, the more positive the level of entire
constructs would be. These items were adapted from various published sources and
were found to be reliable and valid (Compeau & Higgins, 1995; Davis, 1989; Gibson &
Dembo, 1984; Riggs & Enochs, 1990; Thompson, Higgins & Howell, 1991; Venkatesh et
al., 2003). For example, the items measuring perceived usefulness, perceived ease of
use, and attitude toward computer use were employed in Teo (2009) with good
coefficients of .96, .95, and .93 respectively. Furthermore, the questionnaire was piloted
on 51 student teachers and the results revealed acceptable reliability of all constructs.
The Cronbach alphas were .89 for perceived usefulness; .77 for computer teaching
efficacy; .96 for perceived ease of use; .66 for attitude toward computer use, and .78 for
behavioural intention. All items were presented in English. The 13 items in this study
are listed in the Appendix.

Results

Analysis of the data in this study was conducted in two phases. The first phase
examined the descriptive statistics and assessed the reliability and validity of the
measurement items. This was to ensure that the data would be adequate for structural
equation modelling. For the second phase, assessments on the contributions and
significance of the predictors towards computer use among student teachers were
performed.



Wong, Teo and Russo 1197

Descriptive statistics

A descriptive analysis was carried out on computer teaching efficacy, perceived
usefulness, perceived ease of use, attitude toward computer use and behavioural
intention, and their mean and standard deviation are shown in Table 1. All means
scores are above the midpoint of 2.5, ranging from 2.5 to 3.1. This indicates an overall
positive response to the constructs in the study. The standard deviation (SD) values
suggest a narrow spread around the mean. Univariate normality was assessed through
the inspection of the skewness and kurtosis, with values less than 3.0 and 10
respectively, indicative of acceptable normality (Kline, 2005). The skewness and
kurtosis indices for all constructs are acceptable and internal reliability is also
adequate. The data in this study are regarded as normal for the purpose of structural
equation modelling.

Table 1: Descriptive statistics of the study constructs
Construct Mean Std dev Skewness Kurtosis

CTE 2.53 .99 .083 -1.14
PU 2.54 .93 -.021 .28

PEU 3.06 .90 -.75 -.53
ATCU 3.11 .81 -.32 -1.04

BI 2.86 .93 -.11 -1.37

Evaluation of the measurement model

A confirmatory factor analysis (CFA) was conducted to test the measurement model.
Table 2 shows the result of the measurement model. The factor loadings of the
individual items in the five constructs are all above .50. Together, the principal
component analysis showed that these five constructs in the proposed model
explained 87.87% of the total variance. All standardised regression weights are above
.70 and range from .786 to .970. Furthermore, the multiple square correlation (R2) of all
items ranged from .640 to .940, suggesting that these items were explained by their
predictors at a range from 64% to 94%. A value of .50 or greater is considered
appropriate (Hair, Black, Babin & Anderson, 2010).

The test of convergent validity was conducted using average variance extracted (AVE)
and composite reliability measurement. According to Hair, Black, Babin and Anderson
(2010), in order to ensure the AVEs index are adequate for testing structural equation
modelling, they should equal or exceed 0.50. Table 2 shows that the AVE for each
measure is above 0.50. This means that more than one-half of the variances observed in
the items were accounted for by their hypothesised factors. The composite reliability
(CR) of each construct was assessed using Cronbach’s alpha. The composite reliability
for all the factors in the measurement model ranges from .85 to .97 and it exceeds the
recommended threshold value (Hair et al., 2010).

Table 3 shows the results of discriminant validity of the measured items. Discriminant
validity is present when the variance shared between a construct and any other
construct in the model is less than the variance that construct shares with its indicators.
If the square roots of the AVEs are greater than the off-diagonal elements in the
corresponding rows and columns, it shows that the construct has stronger correlation
with its indicators than with the other constructs in the model (Teo, 2009). From Table
3, the values in the matrix diagonals, representing the square roots of the AVEs, are



1198 Australasian Journal of Educational Technology, 2012, 28(7)

greater than the off-diagonal elements in their corresponding rows and columns,
suggesting that discriminant validity was present in the proposed research model.

Table 2: Results of the measurement model

Latent
variable Item

Factor
loading
(>.60)*

SE t-value(a) R
2

Average
variance extracted

(≥.50)* (b)

Composite
reliability(c)

(≥.50)*
CTE1 .873 .919 22.671 .844
CTE2 .850 .887 - .788

CTE

CTE3 .830 .853 20.044 .727

.72 .91

PU1 .768 .932 17.631 .869
PU2 .662 .800 15.070 .640

PU

PU3 .838 .786 - .618

.58 .87

PEU1 .891 .970 37.198 .940
PEU2 .892 .939 32.731 .882

PEU

PEU3 .907 .940 - .884

.80 .97

ATCU1 .838 .898 - .807ATCU
ATCU2 .854 .819 14.136 .671

.72 .89

BI1 .890 .930 - .748BI
BI2 .877 .865 14.775 .866

.78 .85

a. t-value(critical ratio) shows whether the parameter is significant at the .05 level.
b. AVE: Average variance extracted = [sigma(λ2)]/n
c. Composite reliability = [sigma(λ)]2/[sigma(λ)]2 + sigma(λ)[1-sigma(λ2)]
* Indicates an acceptance level or validity.
- This value was fixed at 1.00 for model identification purposes
SE: Standard estimate

Table 3: Discriminant validity for measurement model

CTE PU PEU ATCU BI
CTE (.85)
PU .52** (.76)

PEU .47** .65** (.90)
ATCU .57* .51* .35** (.85)

BI .41** .50* .41** .42** (.88)

Notes: Diagonal in parentheses: square root of average variance extracted from
observed variables (items); Off-diagonal: correlations between constructs.
*p < .05; **p < .01

The five absolute fit indices: ratio of χ2 to its degree of freedom (χ2/df), Goodness of Fit
(GFI), Comparative Fit Index (CFI), Tucker-Lewis Index (TLI), and Standardised Root
Mean Square Error of Approximation (RMSEA) were employed in order to check the
model fit of the measurement model. Absolute fit indices measure how well the
proposed model reproduces the observed data. According to Hair et al. (2010), the
value of GFI and CFI should be more than 0.95 and that of the RMSEA smaller than
0.05 to be considered a good fit. For χ2/df (ratio of χ2 to its degrees of freedom), the
value below 3 is considered acceptable. Finally, the TLI value should be greater than
0.90. As shown in Table 4, all values are above the recommended thresholds for
acceptable model fit and it confirms that the measurement model has exhibited a good
fit.



Wong, Teo and Russo 1199

Table 4: Goodness of fit indices for the measurement model

Fit indices Values Criteria(a)
χ2 statistic 138.31** Insignificant, but significant

p-value can be expected.
χ2/df (ratio of χ2 to its
degrees of freedom)

2.51 <3

RMSEA 0.07 <0.08
GFI 0.93 ≥0.90
CFI 0.98 ≥0.90
TLI 0.97 ≥0.90
a. References are taken from Hair et al.(2010), Kline (2005) and
McDonald and Ho (2002).
**p < .01

Hypotheses testing

Figure 3 shows the parameter estimates for the hypothesised model. Hypotheses H1a,
H1b, H2a, H2b, H3, H4a, H4b and H4c were supported by the data. The exogenous
variable shows that computer teaching efficacy was a significant influence on
perceived usefulness (β=.22, p<.00), perceived ease of use (β=.48, p<.00) and attitude
toward computer use (β=.38, p<.00). Perceived usefulness was a significant influence
on attitude toward computer use (β=.47, p<.00) and behavioural intention BI (β=.52,
p<.00). Perceived ease of use was a significant influence on perceived usefulness
(β=.50, p<.00) and attitude toward computer use (β=-.14, p<.00). Finally, behavioural
intention was found to be influenced by attitude toward computer use (β=.23, p<.01).

Figure 3: Standardised path coefficients for all respondents

Attitude toward computer use was found to be significantly determined by computer
teaching efficacy, perceived usefulness and perceived ease of use, resulting in an R2 of
0.506. In other words, computer teaching efficacy, perceived usefulness and perceived
ease of use have explained 50.6% of the variance in attitude toward computer use.
Perceived usefulness was significantly determined by computer teaching efficacy, and
perceived ease of use and the percent of variance explained was 53.4% (R2 = 0.534).
Perceived ease of use was significantly determined by computer teaching efficacy,
resulting in an R2 = .248. Altogether, the model accounted for 36.8% of the variance in
behavioural intention.

CTE

PEU
R2 = 0.248

PU
R2 = 0.534

ATCU
R2 = 0.506

BI
R2 = 0.368

0.52**

0.47**
0.22**

0.23*0.38**

0.50**

-0.14*
0.48**

*p < .05; **p < .01



1200 Australasian Journal of Educational Technology, 2012, 28(7)

Assessment of total, direct, and indirect effects

To test and estimate confidence intervals for the indirect effect, a bootstrapping test
was conducted. Table 5 shows the standardised total effects, direct and indirect effects
associated with each of the endogenous and exogenous variables toward intention for
computer use. According to MacKinnon (2008), standardised path coefficients with
values near to 1 are considered to be large values impact. The most dominant
determinant of behavioural intention is perceived usefulness, with a total effect of
0.629. This is followed by computer teaching efficacy, perceived ease of use, and
attitude toward computer use with a total effect of 0.361, 0.281, and 0.23 respectively.
Together, these four determinants account for approximately 36.8% of the variance in
behavioural intention in computer use. Additionally, computer teaching efficacy
performed as a good determinant for all endogenous variables in the model.

Table 5: Direct, indirect and total effects of the research model

Standardised estimatesOutcome Determinant
R2 Direct Indirect Total(a)

CTE 0.222 0.238 0.460**PU
PEU

0.534
0.500 - 0.500**

PEU CTE 0.248 0.476 - 0.476**
CTE 0.383 0.147 0.530*
PEU -.149 0.237 0.08*

ATCU

PU

0.506

0.473 - 0.473*
CTE - 0.361 0.361**
PEU - 0.281 0.281**
PU 0.520 0.109 0.629**

BI

ATCU

0.368

0.230 - 0.230*
*p < .05; **p < .01
a. 200 samples bootstrapping test with 95% of confidence interval (CI)

Table 6: Path-by-path comparison for gender

χ2 df Δχ2 from revised model
Unconstrained model(a) 243.148

CTEPU 251.221 8.073**
CTEPEU 251.057 7.909**
CTEATCU 255.959 12.811**
PUATCU 243.300 0.152 (ns)
PUBI 246.197 3.049 (ns)
PEUATCU 243.209 0.061(ns)

Constrained paths(b)

ACTUBI 243.288

114

0.140 (ns)
a. Paths for the groups were allowed to be freely estimated.
b. The path specified was constrained to be equal across the two groups.
*p < .05; **p < .01

In order to explore the gender differences, multi-sample (sub-group) tests were carried
out to verify whether significant difference existed between males and females in the
strength of part coefficients. This was done by constraining each path coefficient to be
equal across the two groups. Based on the Δχ2, the resulting model fit was compared to
the unconstrained model. The results of the analyses of gender difference are shown in
Table 6 and Figure 4. Unexpectedly, only CTEPU, CTEPEU, and CTEATCU



Wong, Teo and Russo 1201

were found to be significantly different. Therefore, it shows that the path coefficients
for PUATCU, PUBI, PEUATCU, and ATCU BI did not differ between the
groups. Hence, hypotheses H6a, H6b, H7b, and H8 were not supported in this study.
Table 7 shows the results of the hypotheses testing.

Figure 4: Significant differences standardised
path coefficients for males and females

Table 7: Hypothesis testing results

Hypotheses Path Hypothesis Results
H1a PUATCU Positive Supported
H1b PUBI Positive Supported
H2a PEUPU Positive Supported
H2b PEUATCU Negative Partially supported
H3 ATCUBI Positive Supported

H4a CTEPU Positive Supported
H4b CTEPEU Positive Supported

Main
effect

H4c CTEATCU Positive Supported
H5a CTEPU Men > Women Not supported (women > men)
H5b CTEPEU Men > Women Not Supported (women > men)
H5c CTEATCU Men > Women Not supported (women > men)
H6a PUATCU Men > Women Not supported (not different)
H6b PUBI Men > Women Not supported (not different)
H7a PEUATCU Women > Men Not supported (not different)

Gender
difference

H8 ACTUBI Men > Women Not supported (not different)

Discussion

This study empirically validated the TAM in an educational context by going a step
further to explore the role of gender and computer teaching efficacy as external
variables. The findings of this research offer several important implications for the
research and practice of educational technology development. Overall, the model
accounted for 36.8% of the variance in behavioural intention to use computers among

0.08(ns)

0.33**

0.11(ns)

0.54**

0.20**

0.54*

Computer
teaching
efficacy

Perceived
ease of use

Perceived
usefulness

Attitude toward
computer use

Behavioural
intention

Coefficients for males are in the grey shaded boxes.
*p < .05; **p < .01; ns = not significant.



1202 Australasian Journal of Educational Technology, 2012, 28(7)

Malaysian student teachers. According to the result of goodness-of-fit test, the findings
of this study led to the conclusion that the model did represent the collected data and
its determinants well, towards student teachers’ intention to use computers in teaching
and learning.

As anticipated, perceived usefulness, perceived ease of use, and attitude toward
computer use were found to have a significant positive influence on behavioural
intention to use computer in teaching and learning. The findings support current
research that suggests the positive and strong relationship among perceived
usefulness, perceived ease of use, and attitude toward computer use towards
behavioural intention (Moran et al., 2010; Pynoo et al., 2011; Rasimah et al., 2011; Teo,
2011; Sumak et al., 2011). From the effect sizes, the most dominant determinant of
behavioural intention is perceived usefulness, followed by computer teaching efficacy,
perceived ease of use and attitude toward computer use. Attitude toward computer
use accounted for the least variance among four determinants (β=.230, p<.05),
probably due to the fact that student teachers have not seen the importance of
computer engagement in their teaching activities.

With regards to specific efficacy determinants, it was also noted conclusively that
computer teaching efficacy has a significant positive effect on perceived usefulness,
perceived ease of use, and attitude toward computer use. Furthermore, computer
teaching efficacy has the largest effect on attitude toward computer use, followed by
perceived ease of use and perceived usefulness. Noteworthy is the fact that computer
teaching efficacy has indirect effects on attitude toward computer use and behavioural
intention to use computers. This result has provided an additional insight into the
importance of computer teaching efficacy, and made a new contribution to the
educational field. Due to the importance of computer teaching efficacy in stimulating
higher intentions towards use of computers among student teachers, policymakers and
curriculum designers should pay extra attention to increasing student teachers’ belief
and confidence in using computers in teaching and learning, especially in designing
the curriculum for teacher educational programs. Updating the national educational
technology standards in teacher educational programs from time to time is vital, as
technologies continue to grow and develop rapidly. This serves as guidelines for
preparing and updating courses for student teachers, towards appropriate knowledge
acquisition and effective use of computers in teaching and learning, in the near future.

An unexpected interesting finding from this study is that perceived ease of use has
significantly and negatively influenced student-teachers’ attitude toward computer
use, but the impact is very limited (β=-.14, p<.05). This may be due to the fact that
student teachers are very familiar with relatively advanced and complex computer
applications such as Web 2.0, Gapminder World, Google SketchUp or SMART Notebook
software and other related software. They might prefer to encounter challenges when
using it for planning teaching and learning activities. This implies that the level of
attitude toward computer use will decrease when individuals feel bored with the
technology. This is also documented in Hong and Songan (2011), that developing
countries in the Southeast Asian region are moving towards mobile technology, virtual
world and cloud computing. Another plausible explanation is that this finding might
have resulted from the limitations of the TAM’s applicability to different user
populations. The analysis showed that the majority (89.4%) of the participating student
teachers were between 21 and 23 years old and most of them frequently accessed the
computer at home (77.33%). This statistic implies that student teachers tend to have a
significant degree of confidence in computer applications based on their prior



Wong, Teo and Russo 1203

experience in using the technology. However, further studies are required to validate
it. This implies that teacher education should be reviewed and the curriculum should
introduce more sophisticated software for student teachers. This will help them to face
challenges of using computer for teaching and learning in the near future.

This study further investigates if any gender difference exists in the effect of the
determinants on behavioural intention. Findings obtained in this study fail to verify
the predictions about gender difference having moderating effects on those
relationships. The findings showed that gender did not moderate the effects of PUBI,
PUATCU, PEUATCU, and ACTUBI. This indicates that irrespective of gender,
those with higher perceived usefulness, perceived ease of use, and attitude toward
computer use towards using computers had higher levels of intention to use computer
than those with lower perceived usefulness, perceived ease of use, and attitude toward
computer use. This result is contradictory to the previous studies which revealed that
gender significantly moderated the effects of perceived usefulness and perceived ease
of use towards intention to use technology (Gefen & Straub, 1997; Venkatesh et al.,
2003; Y.-S. Wang & Shih, 2009). This may due to the fact that computers-in-education
have permeated the everyday lives of pre-service teachers and differences in the use
between male and female have been narrowed till it was no longer be significant
(Chou, Wu, & Chen, 2011; Teo, 2010).

However, an interesting finding from this study is that the effect of computer teaching
efficacy on perceived usefulness and attitude toward computer use was significant for
women, but insignificant for men. Also, computer teaching efficacy affected perceived
ease of use more strongly for women rather than for men. This means that compared
to men, women will be more strongly influenced by their own ability to teach with
computers, and also by their belief about using computers as effective teaching
methods to improve students’ performance in learning. This may be due to the fact
that men tend to have higher computer self-efficacy, and thus computer teaching
efficacy does not influence their perceptions towards perceived usefulness and attitude
toward computer use. Many studies have noted that women showed lower computer
self-efficacy than men (Koch et al., 2008; Ong & Lai, 2006; Sieverding & Koch, 2009).
The lower self-efficacy belief of women towards technologies may have consequences
for their own ability beliefs in the use of computers for teaching. Specific pedagogical-
technology courses need to be introduced for women to allow them to gain confidence,
and a belief that using computers could improve students’ performance. However, this
justification needs further examination and evaluation, as well as a larger group of
participating student teachers.

Limitations and direction for future research

It is important to state the limitations of the study to frame the above discussions and
recommendations. Firstly, the population of this study was student teachers only.
Therefore, the findings derived from the analyses may not reflect adequately the
perceptions of in-service teachers, who are presumed to be more likely than student
teachers to be exposed to demands in the use of computers for teaching and learning.
Secondly, the selected determinants used in this study were not able to reflect the
overall intention towards use of computers among student teachers, as the total
variance accounting for behavioural intention was only 36.8%, leaving 63.2%
unexplained. Congruent with these findings, future research should include different
types of contextual variables in the study, to account for the unexplained variance for



1204 Australasian Journal of Educational Technology, 2012, 28(7)

intentions towards use of computers among student-teachers. As noted above, some
questionnaires have been discarded, due to being only partially completed, thus future
studies should consider giving more time for student teachers to fill out the survey
question, maybe a week, instead of distributing and collecting the questionnaire within
the final hour on the last day of lectures.

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Appendix: Constructs and corresponding items

Item Statement References
PU1 I could improve my performance by using

computers.
PU2 I could increase my productivity by using

computers.

PU

PU3 I could enhance my effectiveness by using
computers.

Davis (1989);
Teo (2009b);
Venkatesh et al. (2003)

PEU1 It is easy for me to do works that I want to do by
using computers.

PEU2 I find computers easy to use.

PEU

PEU3 My interaction with computers is clear and
understandable.

Davis (1989);
Teo (2009b);
Venkatesh et al. (2003)

ATCU1 Working with computers make learning more
interesting.

ATCU

ATCU2 Working with computers is fun.

Compeau and Higgins (1995);
Teo (2009b);
Thompson et al. (1991)

CTE1 I believe teaching with computer would help
students achieve.

CTE2 I am very unsure of my abilities to teach with
computers.

CTE

CTE3 In the future, if the performance of my students
improves, I believe it is usually because of
effective teaching with computers.

Gibson and Dembo (1984);
Riggs and Enochs (1990)

BI1 Whenever possible, I intend to use computers for
teaching and learning.

BI

BI2 I plan to use computers during my teaching
practicum.

Davis (1989);
Teo (2009b);
Venkatesh et al. (2003)

Authors: Dr Kung-Teck, Wong (Corresponding author)
Sultan Idris Education University
Tanjong Malim, 35900, Perak, Malaysia
Email: thomas@fppm.upsi.edu.my Web: http://www.upsi.edu.my/en/

Dr Timothy Teo, Associate Professor
University of Auckland, New Zealand
Email: t.teo@auckland.ac.nz
http://www.education.auckland.ac.nz/uoa/timothy-teo

Dr Sharon Russo, Senior Lecturer
University of South Australia, Australia
Email: Sharon.Russo@unisa.edu.au

Please cite as: Wong, K. T., Teo, T. & Russo, S. (2012). Influence of gender and
computer teaching efficacy on computer acceptance among Malaysian student
teachers: An extended technology acceptance model. Australasian Journal of Educational
Technology, 28(7), 1190-1207. http://www.ascilite.org.au/ajet/ajet28/wong-kt.html