DATA ANALYTICS AND PERSUASIVE TECHNOLOGY TO PROMOTE STUDENTS’ ENGAGEMENT AND LEARNING

The use of interactive systems and internet technology nowadays enhance the process of learning as they allow educational resources to be effectively distributed and delivered to students. This gives students the opportunity to learn at their own pace and convenience. Hence, universities employ these computing technologies to aid in teaching and learning in order to meet the needs of diverse learners. Thus, students could engage in learning activities at any time and even outside the four walls of universities. Despite the usefulness of these systems, students find it hard to engage for a long time with these learning resources. They are distracted by so many activities such as chatting, playing games, listening to music, watching movies, etc. As a result, a wide gap exists in academic performance between successful students and unsuccessful one (those that drop out of universities). Therefore, there is a need for research on how to increase students’ motivation to learn. The level of motivation of students to learn and progress in their education determine the length of time they spend on learning-related activities. This research investigated the use of persuasive technology in encouraging students to spend quality time in their learning resources. Persuasive technology describes computer applications which change users’ behaviour or opinion without using coercion or deception. Specifically, this research examined the effect of three social influence strategies of persuasive technology (social comparison, social learning, and competition) on students’ engagement in their learning activities. Socially-oriented strategies recognize the fact that humans are socially-driven and thus, our feeling, behaviour or opinion is affected by that of others (social influence). The strategies were operationalized in a persuasive system as three versions of visualization using students’ assessment grades. The persuasive system was applied to a real university course-based setting to determine its effect on students’ engagement in their learning activities. Quantitative and qualitative approaches were used in determining the effectiveness of the persuasive system versions implementing the three strategies in motivating the students to engage actively in learning activities. The results of this research show that the three socially-oriented strategies of persuasive technology employed can be used in educational software to influence students to achieve a positive goal in their learning. Precisely, the persuasive system attracted and motivated students to spend more time in their learning activities

Designing Culture-Tailored Persuasive Technology to Promote Physical Activity

Physical inactivity has been recognized as one of the leading risk factors that account for cardiovascular disease, type-2 diabetes, stroke, hypertension, etc., with the World Health Organization labeling it as the fourth leading risk factor for global mortality. Research has shown that persuasive technology (PT) can be leveraged as a motivational/supportive tool in tackling the physical-inactivity problem. In particular, research shows that persuasive health applications (PHAs) are more likely to be effective if they are theorydriven and tailored to the target audience. Yet, most existing PHAs on the market are neither theory-driven nor tailored to the target audience. Rather, their designers often employ a one-size- fits-all approach. This makes it difficult to know what design decisions are effective or ineffective among a given target audience. To bridge this gap, I proposed a framework, called the "EMVE-DeCK Framework," grounded in Bandura's Triad of Reciprocal Determinism, for designing, implementing and evaluating tailored PT interventions. Basically, the EMVE-DeCK Framework employs "Theory" and "Technology" to explain and change "Behavior." Moreover, research shows that culture can be leveraged as a personalization mechanism for tailoring PHAs to the target users to make them more effective. However, there is limited cross-cultural research|grounded in theory and empirical evidence|on the effectiveness of culture-based tailoring, especially comparative studies involving understudied populations in the PT research landscape. Hence, using the Hofstede's cultural framework (individualism vs. collectivism), Social Cognitive Theory, Technology Acceptance Model and the EMVE-DeCK Framework, I conducted a number of comparative studies to understand the culture-speci c determinants of physical-activity behavior and the acceptance of a proposed PHA. I used the ndings to inform the design, implementation and evaluation of two versions of a tness app called BEN'FIT - personal version (PV) and social version (SV) - aimed to motivate bodyweight exercise at home. In this dissertation, using the EMVE-DeCK Framework and Canada/United States (individualist culture) and Nigeria (collectivist culture) as a case study, I describe: (1) the cross-cultural user studies and empirical f indings that informed the PT intervention; (2) the design and implementation of the culture-tailored PHA; (3) the evaluation of the overall and culture-tailoring e ectiveness of the PHA in a eld setting. Finally, based on empirical evidence, I present a set of validated PT design guidelines in the eld for designing and tailoring PHAs to users in the individualist and collectivist cultures. This dissertation makes three major contributions to PT research in the Human-Computer-Interaction domain. Firstly, it demonstrates how theory and culture can be employed in the design and development of PT interventions to motivate behavior change. Secondly, it reveals and validates in the eld how the individualist and collectivist cultures fundamentally differ in their motivational mechanism of behavior change. Thirdly, it provides an in-the- field validates PT design guidelines for developing tailored PHAs for the two main types of culture. In the physical-activity domain, the dissertation is the rst to conduct a theory-driven, in-the-fi eld cross-cultural PT research that focuses on an understudied population from Africa (Nigeria) and compare its ndings with those of a widely studied population from North America (Canada/United States)

Designing Culture-Tailored Persuasive Technology to Promote Physical Activity

Physical inactivity has been recognized as one of the leading risk factors that account for cardiovascular disease, type-2 diabetes, stroke, hypertension, etc., with the World Health Organization labeling it as the fourth leading risk factor for global mortality. Research has shown that persuasive technology (PT) can be leveraged as a motivational/supportive tool in tackling the physical-inactivity problem. In particular, research shows that persuasive health applications (PHAs) are more likely to be effective if they are theory-driven and tailored to the target audience. Yet, most existing PHAs on the market are neither theory-driven nor tailored to the target audience. Rather, their designers often employ a one-size-fits-all approach. This makes it difficult to know what design decisions are effective or ineffective among a given target audience. To bridge this gap, I proposed a framework, called the “EMVE-DeCK Framework,” grounded in Bandura’s Triad of Reciprocal Determinism, for designing, implementing and evaluating tailored PT interventions. Basically, the EMVE-DeCK Framework employs “Theory” and “Technology” to explain and change “Behavior.” Moreover, research shows that culture can be leveraged as a personalization mechanism for tailoring PHAs to the target users to make them more effective. However, there is limited cross-cultural research—grounded in theory and empirical evidence—on the effectiveness of culture-based tailoring, especially comparative studies involving understudied populations in the PT research landscape. Hence, using the Hofstede’s cultural framework (individualism vs. collectivism), Social Cognitive Theory, Technology Acceptance Model and the EMVE-DeCK Framework, I conducted a number of comparative studies to understand the culture-specific determinants of physical-activity behavior and the acceptance of a proposed PHA. I used the findings to inform the design, implementation and evaluation of two versions of a fitness app called BEN’FIT—personal version (PV) and social version (SV)—aimed to motivate bodyweight exercise at home. In this dissertation, using the EMVE-DeCK Framework and Canada/United States (individualist culture) and Nigeria (collectivist culture) as a case study, I describe: (1) the cross-cultural user studies and empirical findings that informed the PT intervention; (2) the design and implementation of the culture-tailored PHA; and (3) the evaluation of the overall and culture-tailoring effectiveness of the PHA in a field setting. Finally, based on empirical evidence, I present a set of validated PT design guidelines in the field for designing and tailoring PHAs to users in the individualist and collectivist cultures. This dissertation makes three major contributions to PT research in the Human-Computer-Interaction domain. Firstly, it demonstrates how theory and culture can be employed in the design and development of PT interventions to motivate behavior change. Secondly, it reveals and validates in the field how the individualist and collectivist cultures fundamentally differ in their motivational mechanism of behavior change. Thirdly, it provides an in-the-field validated PT design guidelines for developing tailored PHAs for the two main types of culture. In the physical-activity domain, the dissertation is the first to conduct a theory-driven, in-the-field cross-cultural PT research that focuses on an understudied population from Africa (Nigeria) and compare its findings with those of a widely studied population from North America (Canada/United States)

Dynamic Personalization of Gameful Interactive Systems

Gameful design, the process of creating a system with affordances for gameful experiences, can be used to increase user engagement and enjoyment of digital interactive systems. It can also be used to create applications for behaviour change in areas such as health, wellness, education, customer loyalty, and employee management. However, existing research suggests that the qualities of users, such as their personality traits, preferences, or identification with a task, can influence gamification outcomes. It is important to understand how to personalize gameful systems, given how user qualities shape the gameful experience. Current evidence suggests that personalized gameful systems can lead to increased user engagement and be more effective in helping users achieve their goals than generic ones. However, to create these kinds of systems, designers need a specific method to guide them in personalizing the gameful experience to their target audience. To address this need, this thesis proposes a novel method for personalized gameful design divided into three steps: (1) classification of user preferences, (2) classification and selection of gameful design elements, and (3) heuristic evaluation of the design. Regarding the classification of user preferences, this thesis evaluates and validates the Hexad Gamification User Types Scale, which scores a person in six user types: philanthropist, socialiser, free spirit, achiever, player, and disruptor. Results show that the scale’s structural validity is acceptable for gamification studies through reliability analysis and factor analysis. For classification and selection of gameful design elements, this thesis presents a conceptual framework based on participants’ self-reported preferences, which classifies elements in eight groups organized into three categories: individual motivations (immersion and progression), external motivations (risk/reward, customization, and incentives), and social motivations (socialization, altruism, and assistance). And to evaluate the design of gameful applications, this thesis introduces a set of 28 gameful design heuristics, which are based on motivational theories and gameful design methods and enable user experience professionals to conduct a heuristic evaluation of a gameful application. Furthermore, this thesis describes the design, implementation, and pilot evaluation of a software platform for the study of personalized gameful design. It integrates nine gameful design elements built around a main instrumental task, enabling researchers to observe and study the gameful experience of participants. The platform is flexible so the instrumental task can be changed, game elements can be added or removed, and the level and type of personalization or customization can be controlled. This allows researchers to generate different experimental conditions to study a broad range of research questions. Our personalized gameful design method provides practical tools and clear guidelines to help designers effectively build personalized gameful systems