Revista Electrónica de Investigación Educativa
Vol. 17, Núm. 3, 2015
TIMSS 2011: Relationship between self-confidence and cognitive achievement for Serbia and Slovenia1
Gordana Miscevic-Kadijevic (*) gordana.miscevic@uf.ac.rs
* University of Belgrade
(Recibido: November 19, 2013; Aceptado para su publicación: January 15, 2015)
Abstract
By using TIMSS Grade 4 2011 science data for Serbia and Slovenia, this study examined which of two dimensions towards science learning (self-confidence in learning science, or liking learning science), if any, was primarily related to students' cognitive achievement in science. This achievement was considered for three cognitive domains, namely: Knowing, Applying, and Reasoning. The analysis revealed that, in both countries, achievement was mainly linked to self-confidence in each of the three cognitive domains. Because of positive correlations, classroom work may be improved by including, whenever possible, activities aimed at strengthening students' beliefs in their own abilities to learn science.
Keywords: Cognitive achievement, Fourth grade, Self-confidence, TIMSS.
I. Introducción
TIMSS is a widely-known project of the International Association for the Evaluation of Educational Achievement. It is one of the largest international comparative education studies. Since 1995, the TIMSS research has been carried out in four-year cycles, and TIMSS 2011 belongs to the fifth cycle (see http://timssandpirls.bc.edu/). In Serbia, this kind of study has been conducted since 2003. The third and fourth cycles were carried out with eighth-grade students, whereas the fifth cycle in 2011 included fourth-grade students for the first time. A total of 4,379 students were tested from 219 classes in 156 primary schools. Contrary to the science outcomes in TIMSS 2007, the TIMSS 2011 results in science were very encouraging because Serbia’s fourth-grade students achieved 516 points, which was significantly higher than the TIMSS scale average (Martin, Mullis, and Foy, 2008; Martin, Mullis, Foy, and Stanco, 2012). The cognitive achievements of Serbian students in 2011 were also very good. These achievements –determined by using three variables for cognitive domains regarding knowledge, application, and reasoning– were better than the overall average results of all the countries that participated in the testing (see table 1). It can thus be said that, in general, primary school teachers in Serbia have done their job well for the content of science courses. However, the categorization of TIMSS test items is just based on an acceptable approximation, which means that the ranking of nations should not be viewed in an absolute but rather an approximate sense (Nixon and Barth, 2014).
Let us first focus on three TIMSS cognitive domains. They can be described as follows: “Knowing covers the student’s knowledge of science facts, procedures, and concepts. Applying focuses on the student’s ability to apply knowledge and conceptual understanding in a science problem situation. Reasoning goes beyond the solution of routine science problems to encompass unfamiliar situations, complex contexts, and multi-step problems.” (Martin et al., 2012, p. 142). Although these domains were not based upon an elaborate theoretical framework, it is relatively easy to recognize that they are related to cognitive domains found in the well-known Bloom’s taxonomy. Bearing in mind their definitions below, it is clear that Knowing and Applying include Bloom’s Knowledge, Comprehension, and Application levels, whereas Reasoning is based on Bloom’s Analysis, Evaluation and Synthesis levels (Gutvajn, Dinovic, and Pavlovic, 2011).
Let us now move to TIMSS contextual variables that have been found to be related to TIMSS achievement in general. They are, for example, self-confidence in learning a subject, and liking the subject, which are both positively related to achievement (e.g., Martin et al., 2012; Mullis, Martin. Foy, and Arora, 2012). In the context of science, these TIMSS variables (i.e. the constructs underlying them) may be briefly defined as follows.
Although an elaborate theoretical framework is also missing here, it is clear that these two constructs are important dimensions of student attitude towards science learning (cf. Kadijevich, 2008).
Let us finally return to the cognitive achievements for Serbian students. Bearing in mind that self-confidence and liking learning are both positively related to achievement, we focused on the question of which is more highly correlated to cognitive achievements. Furthermore, we were interested in comparing the answer to this question for Serbia to the answer for Slovenia. (Slovenia is one of the countries in the region where students traditionally have good TIMSS results in science (Martin et al., 2008, 2012); the average overall achievements in 2007 and 2011 were 518 and 520, respectively). Although achievement and any such dominant variable are probably mutually dependent (i.e. their relationship is bidirectional), it is reasonable to assume that investing in this variable would result in better achievement.
II. Design and variables
This study applied a correlative design. It used six variables described below.
(totwgt is the
student’s weight provided in the official files, whereas 59,204.93
and 16,100.96 are sums of these students’ weights).
III. Results
Table II reports the means of the measured variables by country. Serbian and Slovenian students did not differ much with regards to the two attitudinal dimensions measured, especially Self-confidence (3.3 vs. 3.2).
The correlations between Self-confidence and Liking on the one hand, and the four attainment variables on the other hand, are presented in table 3. Although almost all correlations regarding Liking were significant, they could explain less than 1% of the variation in each attainment variable (e.g., 0.0712 * 100% = 0.5%). The extent of this explanation for Self-confidence was between 9% (0.2952 * 100%) and 16% (0.3952 * 100%).
IV. Discussion
To recall the question used in this study, it was found that, in both Serbia and Slovenia, cognitive achievement was primarily linked to self-confidence. As expected, this relationship was positive, and for Achievement (i.e. overall achievement), Knowing and Applying, stronger in Slovenia then in Serbia (0.374 vs. 0.312; Z = 3.184, p = 0.0015). However, the two variables (Self-confidence and each of the achievement variables) did have a modest common variation. The dominance of the relationship between self-confidence and overall achievement was also found in Kadijevich (2008) for example, albeit for mathematics.
As already mentioned in the introduction, although self-confidence and achievement are probably mutually dependent, it is reasonable to assume that investing in self-confidence would result in better achievement. This can be achieved by a variety of techniques to boost self-confidence – for example, through discussions about one’s own gains in learning science, such as what knowledge and skills students have mastered with ease, and the content they enjoyed learning. Students with low self-confidence in learning science should be helped with approaches to learning that elicit their initiative, encourage and scaffold their problem solving, and encourage them to state their opinions. Perhaps the most important thing is to create a respectful and encouraging atmosphere in the classroom where students support each other and want to talk openly about their experience rather than just passively receive ready-made knowledge and skills. Furthermore, negative emotional responses should be avoided in learning activities because emotional responses have considerable influence on the development of self-concept (Mujtaba, Reiss, and Hodgson, 2014). Because of that, activities for strengthening self-concept should mainly generate positive emotional responses (compare “Look, I can complete this task!” with “I am again unsuccessful at problem solving!”). Finally, when designing activities to strengthen self-confidence, the teacher should bear in mind that “a strong self-concept encourages students to engage with the instruction and show persistence, effort, and attentiveness.” (Martin et al., 2012; p. 331)
To conclude, the results for Serbia and Slovenia show that self-confidence may be a major dimension of attitude when the relationship between this confidence and achievement is in focus. Further research may examine whether this pattern applies to a larger group of countries when science learning is in question. Because this relationship is positive, it is very likely that, in general, developing students’ self-confidence in a (more) positive direction would improve his or her achievement. However, as the relationship between the two is bidirectional, further research may focus on uncovering, to some extent, the nature of the relationship between self-confidence in learning science and science achievement (how one influences the other), which can then be used as a basis for designing successful ways of using one to improve the other.
References
Gutvajn, N., Dinovic, V., & Pavlovic, J. (2011). From knowing facts to knowledge in application: Cognitive domains in natural sciences (in Serbian). In Gašic-Pavišic, S., & Stankovic, D. (Eds.), TIMSS 2007 in Serbia (pp. 211–225). Belgrade: Institute for Educational Research.
Kadijevich, Dj. (2008). TIMSS 2003: Relating dimensions of mathematics attitude to mathematics achievement. Zbornik instituta za pedagoška istraivanja, 40(2), 327-346. Retrieved from www.doiserbia.nb.rs/img/doi/0579-6431/2008/0579-64310802327K.pdf
Martin, M.O., Mullis, I.V.S., & Foy, P. (with Olson, J.F., Preuschoff, C., Erberber, E., Arora, A., & Galia, J.). (2008). TIMSS 2007 international science report: Findings from IEA’s trends in international mathematics and science study at the fourth and eighth grades. Chestnut Hill, MA: TIMSS & PIRLS International Study Center, Boston College. Retrieved from http://timssandpirls.bc.edu/TIMSS2007/sciencereport.html
Martin, M.O., Mullis, I.V.S., Foy, P., & Stanco, G.M. (2012). The TIMSS 2011 international results in science. Chestnut Hill, MA: TIMSS & PIRLS International Study Center, Boston College. Retrieved from http://timssandpirls.bc.edu/timss2011/internationalresults-science.html
Mullis, I.V.S., Martin, M.O., Foy, P., & Arora, A. (2012). The TIMSS 2011 international results in mathematics. Chestnut Hill, MA: TIMSS & PIRLS International Study Center, Boston College. Retrieved from http://timssandpirls.bc.edu/timss2011/international-resultsmathematics.html
Mujtaba, T., Reiss, M. J., Hodgson, A. (2014). Motivating and supporting young people to study mathematics: A London perspective. London Review of Education, 12(1), 121-142. Retrieved from http://eprints.ioe.ac.uk/18489/1/Mujtaba_et_al_2014_LRE_Motivating_ mathematics.pdf
Nixon, R. S., Barth, K. N. (2014). A comparison of TIMSS
items using cognitive domains. School Science & Mathematics, 114(2),
65-75.
1The research reported in this article was financially supported by the Ministry of Education, Science and Technological Development of the Republic of Serbia under project No. 179020 (Conceptions and strategies that provide the quality of basic education).
Cómo citar: Miscevic-Kadijevic, G. (2015). TIMMS 2011: Relationship between self-confidence and cognitive achievement for Serbia and Slovenia. Revista Electrónica de Investigación Educativa, 17(3), 00-00. Retrieved from http://redie.uabc.mx/vol17no3/contents-miscevic.html