This study investigated the efectiveness of the proposed didactic conditions and structural-functional model for developing pre-service teachers' digital competence through informatics disciplines. The positive dynamics observed in the experimental group's digital competence levels, particularly in the cognitive-informational and motivational-value components, contribute to growing research advocating for the systematic development of digital competence within teacher education programs. The findings underscore the importance of adopting a holistic, integrated approach to informatics disciplines, combining technical skills, pedagogical knowledge, and practical application through authentic, project-based learning experiences.
The rapid digitalisation of society and education has highlighted the need for educators to possess
a high level of digital competence to efectively integrate digital technologies into their professional
practice [
However, studies have revealed that pre-service teachers often lack suficient digital competence,
despite exposure to various informatics disciplines during their teacher education programs [
To address this issue, a structural-functional model was developed, incorporating specific didactic conditions that aim to foster digital competence development in pre-service teachers through the study of informatics disciplines. These conditions include: 1. Motivational conditionality of subjects’ interaction in the digital learning environment. 2. Structuring of educational information in problematic, heuristic and integrative learning. models and its translation into project activities 3. Ensuring a systematic, complicating nature of students’ learning activities with diagnostics and timely correction of outcomes using modern ICT.
This study’s purpose was to test the efectiveness of the proposed didactic conditions and structuralfunctional model in developing pre-service teachers’ digital competence through a pedagogical experiment. The findings contribute to the growing body of research on digital competence development in teacher education and provide insights into efective strategies for preparing future teachers to integrate digital technologies into their professional practice.
The importance of developing pre-service teachers’ digital competence has been increasingly recognized,
as evidenced by the inclusion of digital competence frameworks in teacher education policies and
curricula worldwide [
Research has shown that pre-service teachers’ digital competence is influenced by various factors,
such as their personal experiences with technology, self-eficacy beliefs, and the quality of technology
integration in their teacher education programs [
Informatics (computer science) disciplines, such as programming, and information technology, play
a crucial role in developing pre-service teachers’ digital competence [
To better support pre-service teachers’ digital competence development, informatics disciplines in
teacher education need to adopt a more holistic, integrated approach that combines technical skills
with pedagogical knowledge and practical application [
A pedagogical experiment was conducted to test the efectiveness of the proposed didactic conditions and structural-functional model for developing pre-service teachers’ digital competence through informatics disciplines. The experiment followed a quasi-experimental design, with a control group and an experimental group of pre-service teachers from two Ukrainian pedagogical universities.
The control group (n=93) studied according to traditional informatics discipline programs, while the experimental group (n=95) followed an experimental program that implemented the proposed didactic conditions and structural-functional model. The experiment was conducted over four academic years, from 2016 to 2020.
The study participants were 188 pre-service teachers enrolled in pedagogical specialties at two Ukrainian pedagogical universities. The control group consisted of 93 students (71% female, 29% male), while the experimental group comprised 95 students (69% female, 31% male). The participants’ ages ranged from 18 to 23, with a mean age of 20.2 years ( =1.4).
All participants were enrolled in informatics disciplines as part of their teacher education programs, which included courses such as computer science, programming, and information technology. The participants’ prior experience with digital technologies varied, but all had basic computer literacy skills.
Digital competence formation was assessed according to four structural-criterial components: motivationalvalue, cognitive-informational, operational-activity, and personal-reflexive. A range of diagnostic methods were employed to measure pre-service teachers’ digital competence development: • A series of tests were administered to assess participants’ knowledge and understanding of digital technologies, computer science concepts, and pedagogical applications of technology. • Participants completed questionnaires designed to gauge their attitudes, beliefs, and self-eficacy regarding the use of digital technologies in educational contexts. • Semi-structured interviews were conducted with a subset of participants to gather more indepth insights into their experiences, challenges, and growth in relation to digital competence development. • Participants completed practical tasks and projects that required them to demonstrate their skills in using digital tools, creating digital content, and solving technology-related problems. • Competency matrices were used to assess participants’ performance in various aspects of digital competence, such as digital literacy, digital communication and collaboration, and digital content creation. • Expert evaluations were conducted by university faculty and experienced teachers to assess participants’ digital competence based on their performance in informatics disciplines and educational practice. • Participants analyzed and discussed real-world case studies related to technology integration in education, allowing for the assessment of their critical thinking and problem-solving skills. • Participants designed and implemented educational projects that demonstrated their ability to integrate digital technologies into teaching and learning activities. • Participants maintained a reflective blog throughout the experiment, documenting their experiences, insights, and growth in relation to digital competence development.
These diverse diagnostic methods provided a comprehensive assessment of pre-service teachers’ digital competence development throughout the pedagogical experiment.
The pedagogical experiment was conducted in three stages: organizational, formative, and corrective. In the organizational stage, the experimental program was developed, incorporating the proposed didactic conditions and structural-functional model. The content of informatics disciplines was updated, and an author’s electronic special course, “Digital Technologies in Education” (3 ECTS credits), was prepared. Diagnostic instruments were also developed and validated during this stage.
During the formative stage, the experimental group studied according to the experimental program, which implemented the three didactic conditions: 1. Motivational conditionality of subjects’ interaction in the digital learning environment: This condition aimed to foster efective collaboration and co-creation among students and teachers in the digital learning environment. Problematic and developmental learning technologies, success situations, emotional stimulation, and gamified rating control were used to enhance students’ motivation to master digital competence. 2. Structuring of educational information in problematic, heuristic and integrative learning models and its translation into project activities: This condition involved structuring educational information in problematic, heuristic, and integrative learning models and translating it into project activities. A technological scheme for forming digital competence was developed, serving as the basis for creating a system of learning tasks, contextual, game, and problem situations, web-quests, and case studies. These activities covered the motivational-value, cognitive-informational, operationalactivity, and personal-reflexive aspects of students’ activity in the virtual space. 3. Ensuring a systematic, complicating nature of students’ learning activities with diagnostics and timely correction of outcomes using modern ICT : This condition involved introducing digital tools and technologies that optimized and intensified the learning of informatics disciplines. New ways of organizing training sessions, technological models of mobile, distance, and blended learning, game design, video and teleconferences, web forums, and workshops in synchronous and asynchronous modes were employed.
In the corrective stage, the results of the students’ learning activities were monitored and corrected using both general (testing, questionnaires, interviews, control tasks) and specific methods (competency matrices, expert cards, case studies, educational projects, and blogs).
Quantitative data collected through tests, questionnaires, control tasks, and competency matrices were analyzed using descriptive and inferential statistics. Paired-sample t-tests were used to compare the pre-and post-experiment scores within each group, while independent-sample t-tests were employed to compare the experimental and control groups’ post-experiment scores. Efect sizes (Cohen’s d) were calculated to determine the magnitude of the diferences between groups.
Qualitative data gathered through interviews, case studies, educational projects, and blog entries were
analyzed using thematic analysis [
The experimental group demonstrated positive, statistically significant dynamics in the levels of digital competence formation compared to the control group (table 1). The greatest development was observed in the cognitive-informational (+35.79%) and motivational-value (+25.26%) components of digital competence.
Paired-sample t-tests revealed significant improvements in the experimental group’s digital competence scores from the initial to the final assessment across all four structural-criterial components (p<0.001). The efect sizes ranged from d=0.68 to d=1.24, indicating moderate to large efects.
Independent-sample t-tests showed that the experimental group’s post-experiment scores were significantly higher than those of the control group in the cognitive-informational ( t(186)=6.84, p<0.001, d=1.00) and motivational-value (t(186)=5.21, p<0.001, d=0.76) components. The diferences in the operational-activity and personal-reflexive components were also significant but with smaller efect sizes (d=0.42 and d=0.51, respectively).
The thematic analysis of interviews, case studies, educational projects, and blog entries revealed several key themes related to the development of digital competence in pre-service teachers: • Enhanced motivation and engagement: participants in the experimental group reported increased motivation and engagement in learning informatics disciplines due to the interactive, projectbased nature of the activities and the authentic use of digital tools. • Improved understanding of digital technologies: experimental group participants demonstrated a deeper understanding of digital technologies, their applications in education, and the pedagogical implications of technology integration. • Increased confidence in using digital tools : pre-service teachers in the experimental group expressed greater confidence in their ability to use digital tools for teaching and learning, as well as for personal and professional development. • Collaborative learning and peer support: the experimental program fostered a strong sense of collaboration and peer support among pre-service teachers, facilitating the sharing of knowledge, skills, and experiences related to digital competence development. • Reflective practice and self-awareness : participants in the experimental group demonstrated higher levels of reflective practice and self-awareness regarding their digital competence development, as evidenced by their blog entries and discussions during interviews.
These qualitative findings provide further evidence of the efectiveness of the proposed didactic conditions and structural-functional model in fostering digital competence development in pre-service teachers.
The results of this pedagogical experiment confirm the efectiveness of the proposed didactic conditions
and structural-functional model for developing pre-service teachers’ digital competence through
informatics disciplines. The positive dynamics observed in the experimental group’s digital competence
levels, particularly in the cognitive-informational and motivational-value components, align with recent
research emphasizing the importance of intentional and systematic digital competence development in
teacher education [
The significant improvements in the experimental group’s cognitive-informational component suggest
that the problematic, heuristic, and integrative learning models, coupled with project-based activities,
efectively facilitated the acquisition of knowledge and understanding related to digital technologies
and their pedagogical applications. This finding supports the notion that informatics disciplines in
teacher education should adopt a more holistic, integrated approach that combines technical skills with
pedagogical knowledge and practical application [
The substantial growth in the motivational-value component among experimental group participants
highlights the importance of creating an engaging, collaborative digital learning environment that fosters
motivation and positive attitudes towards technology integration. This finding aligns with research
indicating that pre-service teachers’ digital competence is influenced by their personal experiences,
self-eficacy beliefs, and the quality of technology integration in their teacher education programs
[
The qualitative findings provide further insights into the factors contributing to the efectiveness of
the experimental program. The enhanced motivation, improved understanding of digital technologies,
increased confidence, collaborative learning, and reflective practice reported by experimental group
participants underscore the value of authentic, meaningful learning experiences in developing digital
competence [
The substantial growth in the motivational-value component among experimental group participants
highlights the importance of creating an engaging, collaborative digital learning environment that fosters
motivation and positive attitudes towards technology integration. This finding aligns with research
indicating that pre-service teachers’ digital competence is influenced by their personal experiences,
self-eficacy beliefs, and the quality of technology integration in their teacher education programs
[
The qualitative findings provide further insights into the factors contributing to the efectiveness of
the experimental program. The enhanced motivation, improved understanding of digital technologies,
increased confidence, collaborative learning, and reflective practice reported by experimental group
participants underscore the value of authentic, meaningful learning experiences in developing digital
competence [
While the operational-activity and personal-reflexive components also showed significant improvements in the experimental group, the smaller efect sizes suggest that these aspects of digital competence may require additional attention and support. Future research could explore strategies for further enhancing pre-service teachers’ practical skills and reflective capabilities in relation to digital competence development.
This pedagogical experiment provides evidence for the efectiveness of the proposed didactic conditions and structural-functional model in developing pre-service teachers’ digital competence through informatics disciplines. The positive dynamics observed in the experimental group’s digital competence levels, particularly in the cognitive-informational and motivational-value components, contribute to the growing body of research advocating for the systematic, intentional development of digital competence within teacher education programs.
The findings underscore the importance of adopting a holistic, integrated approach to informatics disciplines in teacher education, combining technical skills, pedagogical knowledge, and practical application through authentic, project-based learning experiences. The study also highlights the value of creating an engaging, collaborative digital learning environment that fosters motivation, confidence, and reflective practice among pre-service teachers.
The results of this experiment have several implications for teacher education policy and practice. First, teacher education programs should prioritize the intentional and systematic development of pre-service teachers’ digital competence, recognizing its critical role in preparing future educators for the digitalized educational landscape. This may involve reforming existing informatics disciplines to better align with the holistic, integrated approach demonstrated in this study.
Second, teacher educators should adopt evidence-based strategies, such as the didactic conditions and structural-functional model proposed in this study, to efectively foster digital competence development in pre-service teachers. This may require professional development for teacher educators to enhance their own digital competence and pedagogical skills in integrating technology into their teaching practice.
Third, policymakers and educational institutions should invest in the necessary infrastructure, resources, and support systems to facilitate the efective integration of digital technologies in teacher education programs. This includes providing access to up-to-date digital tools, learning management systems, and online resources and ofering technical and pedagogical support to both pre-service teachers and teacher educators.
Future research could explore the long-term impact of digital competence development interventions on pre-service teachers’ technology integration practices during their induction phase and early career years. Longitudinal studies could provide valuable insights into the sustainability and transferability of the skills and knowledge acquired through such interventions.
Additionally, the proposed structural-functional model could be adapted and tested in diferent contexts and specializations within teacher education, such as primary education, secondary education, and subject-specific domains. Comparative studies could also investigate the efectiveness of diferent approaches to digital competence development in teacher education across various countries and educational systems.