Using Visualizations of Students' Coding Processes to Detect Patterns Related to Computational Thinking

Markus Iseli; Tianying Feng; Gregory Chung; Ziyue Ruan; Joe Shochet; Amy Strachman

Download Paper | Permalink

Conference: 2021 ASEE Virtual Annual Conference Content Access
Location: Virtual Conference
Publication Date: July 26, 2021
Start Date: July 26, 2021
End Date: July 19, 2022
Conference Session: Computers in Education 8 - Video Technology
Tagged Division: Computers in Education
Tagged Topic: Diversity
Page Count: 13
DOI: 10.18260/1-2--38006
Permanent URL: https://peer.asee.org/38006
Download Count: 335

Request a correction

Paper Authors

biography

Markus Iseli University of California, Los Angeles

visit author page

Dr. Iseli is a Senior Research Scientist for CRESST with a focus on integration of engineering and technology for educational purposes. His specialization is in digital signal processing, speech and image analysis, pattern recognition, acoustics, and natural language processing. He has over 15 years of practical expertise as a technology and engineering consultant, applying data analysis and artificial intelligence algorithms for technology-based learning and knowledge assessment systems. Currently, he is involved as a knowledge engineer in various private and publicly funded projects. Dr. Iseli holds a PhD and an MS in electrical engineering from UCLA and from ETH Zürich, Switzerland.

visit author page

author page

Joe Shochet has been developing award-winning interactive experiences for 25 years. In 2014 he co-founded codeSpark, an edtech startup to teach kids the ABCs of computer science. His career started at Disney Imagineering building virtual reality attractions for the theme parks and designing ride concepts. Joe was a lead designer and developer of several virtual worlds including the popular Toontown Online, one of the first 3D virtual worlds for children. More recently he was Vice President at Rebel Entertainment, a division of IAC, focused on social and mobile games. Joe has a Computer Science degree from the University of Virginia, where his research focused on virtual reality, user interface design, and developing Alice3D.

visit author page

author page

Amy Strachman codeSpark

Download Paper | Permalink

Abstract

Computational thinking (CT) has emerged as a key topic of interest in K-12 education. Children that are exposed at an early age to STEM curriculum, such as computer programming and computational thinking, demonstrate fewer obstacles entering technical fields (Madill et al., 2007). Increased knowledge of programming and computation in early childhood is also associated with better problem solving, decision-making, basic number sense, language skills, and visual memory (Flannery et al., 2013). As a digital competence, coding is explicitly regarded as a key 21st Century Skill, as the “literacy of today,” such that its acquisition is regarded as essential to sustain economic development and competitiveness (Bocconi et al., 2016). Therefore, the reliable evaluation of students’ coding process data, in context of problem solving tasks that require CT, is of great importance. Prior research has analyzed overall action sequences or code snapshots, but has not interpreted student actions in context of a situation during the problem solving process -- i.e. while creating the solution. A more fine-grained analysis of coding process data is needed, where relevant actions are interpreted as a part of the student’s problem solving process. We introduce a novel visualization approach for the analysis of coding process data. This approach has the following benefits: (a) It does not require the definition of process states; (b) It does not accumulate data (either across students or over time) and thus preserves the raw information aspect of the data; (c) It is goal-oriented, by being based on well-defined and measurable performance objectives; (d) It facilitates the definition of specific performance similarity measures for each performance objective (e.g. distance to optimal path or similarity to optimal event sequence), and thus facilitates scoring; (e) It is independent of sequence data length and thus enables time series analysis (e.g. frequency, pauses, etc.) (f) It can visualize each student’s performance for each measure as a function of time; and (g) It can be used to inform the feature extraction process by facilitating pattern identification. We present our visualizations of student process data, collected using codeSpark Academy, which introduces children to programming and computational concepts (sequencing, parameters, loops, events, and conditionals) and combines carefully scaffolded puzzles aligned with the curriculum. Our findings clearly show groups of patterns that represent different strategies related to the computational thinking constructs abstraction, decomposition, generalization, modeling, algorithmic thinking, and evaluation.

Citation
Format

Iseli, M., & Feng, T., & Chung, G., & Ruan, Z., & Shochet, J., & Strachman, A. (2021, July), Using Visualizations of Students' Coding Processes to Detect Patterns Related to Computational Thinking Paper presented at 2021 ASEE Virtual Annual Conference Content Access, Virtual Conference. 10.18260/1-2--38006

TY  - CPAPER
AB  - Computational thinking (CT) has emerged as a key topic of interest in K-12 education. Children that are exposed at an early age to STEM curriculum, such as computer programming and computational thinking, demonstrate fewer obstacles entering technical fields (Madill et al., 2007). Increased knowledge of programming and computation in early childhood is also associated with better problem solving, decision-making, basic number sense, language skills, and visual memory (Flannery et al., 2013).
As a digital competence, coding is explicitly regarded as a key 21st Century Skill, as the “literacy of today,” such that its acquisition is regarded as essential to sustain economic development and competitiveness (Bocconi et al., 2016). Therefore, the reliable evaluation of students’ coding process data, in context of problem solving tasks that require CT, is of great importance.
Prior research has analyzed overall action sequences or code snapshots, but has not interpreted student actions in context of a situation during the problem solving process -- i.e. while creating the solution. A more fine-grained analysis of coding process data is needed, where relevant actions are interpreted as a part of the student’s problem solving process.
We introduce a novel visualization approach for the analysis of coding process data. This approach has the following benefits: (a) It does not require the definition of process states; (b) It does not accumulate data (either across students or over time) and thus preserves the raw information aspect of the data; (c) It is goal-oriented, by being based on well-defined and measurable performance objectives; (d) It facilitates the definition of specific performance similarity measures for each performance objective (e.g. distance to optimal path or similarity to optimal event sequence), and thus facilitates scoring; (e) It is independent of sequence data length and thus enables time series analysis (e.g. frequency, pauses, etc.) (f) It can visualize each student’s performance for each measure as a function of time; and (g) It can be used to inform the feature extraction process by facilitating pattern identification.
We present our visualizations of student process data, collected using codeSpark Academy, which introduces children to programming and computational concepts (sequencing, parameters, loops, events, and conditionals) and combines carefully scaffolded puzzles aligned with the curriculum. Our findings clearly show groups of patterns that represent different strategies related to the computational thinking constructs abstraction, decomposition, generalization, modeling, algorithmic thinking, and evaluation.
AU  - Markus Iseli
AU  - Tianying Feng
AU  - Gregory Chung
AU  - Ziyue Ruan
AU  - Joe Shochet
AU  - Amy Strachman
CY  - Virtual Conference
DA  - 2021/07/26
PB  - ASEE Conferences
TI  - Using Visualizations of Students' Coding Processes to Detect Patterns Related to Computational Thinking
UR  - https://peer.asee.org/38006
DO  - 10.18260/1-2--38006
ER  -