WIP: Skip the Lecture: A Decoding First Approach to Introductory Computing Education

David Zabner; Trevion S Henderson

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Conference: 2023 ASEE Annual Conference & Exposition
Location: Baltimore , Maryland
Publication Date: June 25, 2023
Start Date: June 25, 2023
End Date: June 28, 2023
Conference Session: Computing and Information Technology Division (CIT) Technical Session 5
Tagged Division: Computing and Information Technology Division (CIT)
Page Count: 8
DOI: 10.18260/1-2--44101
Permanent URL: https://peer.asee.org/44101
Download Count: 136

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Trevion Henderson is Assistant Professor of Mechanical Engineering at Tufts University. He earned his Ph.D. in Higher Education at the University of Michigan.

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Abstract

This is a work in progress paper for CIT Existing research suggests introductory computing courses (i.e., CS1) constitute a significant barrier for students’ entry into computer science and related disciplines. For example, extant literature suggests as high as 33% of students fail or drop out of introductory computing courses (Bennedsen & Caspersen, 2007), precluding these students from pursuing computer science education in college. Computing educators must balance several, at times competing, pedagogical and learning goals. For example, introductory computing education must foster students’ learning about fundamental computing concepts like loops, variables, and recursion, as well as prepare students for professional practice by developing learning activities that resemble real-world computing work. Thus, it is important that computing educators, especially those teaching introductory computing courses that might serve as gatekeepers to continuing computing education, draw on frameworks that support these various goals.

The purpose of this work in progress is twofold. First, we describe the development and implementation of a pedagogical approach to computing education that draws and expands on two frameworks for supporting students’ learning in introductory computing courses. First, we draw on the Use-Modify-Create (UMC) framework described by Lytle and colleagues (2019), which supports students’ learning of new programming languages by positioning them to (a) use fully functional programs in that language, (b) modify partially functional programs, and (c) create new, original programs. Second, we draw on Xie and colleagues’ (2019) four step theory of coding instruction which identifies four distinct skills (reading code, debugging syntax, comprehending templates, and building code from templates) and suggests that they should be taught in that order. The course we developed uses these frameworks to support better learning while also more fully preparing students for professional practice.

In this work in progress paper, we discuss the structure of the course, as well as the learning activities (e.g., computing assignments and reflection activities) designed to support students’ learning. We hypothesize that these learning activities positively support students’ sense making, computing competencies, and computing self-efficacy. Thus, drawing on unique quantitative and qualitative data sources, such as student-produced lists of python’s rules, students’ code annotations produced during the “use” phase of UMC, and ethnographic fieldnotes, we describe a mixed-methods study examining students’ sense-making, competency, and computing self-efficacy.

In this work in progress paper, we describe preliminary examination of data from the pilot phase of the study, as well as preparations for the study phase of the research. For example, our preliminary examination of rules notebooks indicated that some students developed code tracing strategies and that most were able to discover many of the rules that underlie Python’s runtime execution.

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Zabner, D., & Henderson, T. S. (2023, June), WIP: Skip the Lecture: A Decoding First Approach to Introductory Computing Education Paper presented at 2023 ASEE Annual Conference & Exposition, Baltimore , Maryland. 10.18260/1-2--44101

TY  - CPAPER
AB  - This is a work in progress paper for CIT
Existing research suggests introductory computing courses (i.e., CS1) constitute a significant barrier for students’ entry into computer science and related disciplines. For example, extant literature suggests as high as 33% of students fail or drop out of introductory computing courses (Bennedsen &amp;amp; Caspersen, 2007), precluding these students from pursuing computer science education in college. 
 
Computing educators must balance several, at times competing, pedagogical and learning goals. For example, introductory computing education must foster students’ learning about fundamental computing concepts like loops, variables, and recursion, as well as prepare students for professional practice by developing learning activities that resemble real-world computing work. Thus, it is important that computing educators, especially those teaching introductory computing courses that might serve as gatekeepers to continuing computing education, draw on frameworks that support these various goals. 

The purpose of this work in progress is twofold. First, we describe the development and implementation of a pedagogical approach to computing education that draws and expands on two frameworks for supporting students’ learning in introductory computing courses. First, we draw on the Use-Modify-Create (UMC) framework described by Lytle and colleagues (2019), which supports students’ learning of new programming languages by positioning them to (a) use fully functional programs in that language, (b) modify partially functional programs, and (c) create new, original programs. Second, we draw on  Xie and colleagues’ (2019) four step theory of coding instruction which identifies four distinct skills (reading code, debugging syntax, comprehending templates, and building code from templates) and suggests that they should be taught in that order. The course we developed uses these frameworks to support better learning while also more fully preparing students for professional practice.

In this work in progress paper, we discuss the structure of the course, as well as the learning activities (e.g., computing assignments and reflection activities) designed to support students’ learning. We hypothesize that these learning activities positively support students’ sense making, computing competencies, and computing self-efficacy. Thus, drawing on unique quantitative and qualitative data sources, such as student-produced lists of python’s rules, students’ code annotations produced during the “use” phase of UMC, and ethnographic fieldnotes, we describe a mixed-methods study examining students’ sense-making, competency, and computing self-efficacy. 

In this work in progress paper, we describe preliminary examination of data from the pilot phase of the study, as well as preparations for the study phase of the research. For example, our preliminary examination of rules notebooks indicated that some students developed code tracing strategies and that most were able to discover many of the rules that underlie Python’s runtime execution.

AU  - David Zabner
AU  - Trevion S Henderson
CY  - Baltimore , Maryland
DA  - 2023/06/25
PB  - ASEE Conferences
TI  - WIP: Skip the Lecture: A Decoding First Approach to Introductory Computing Education
UR  - https://peer.asee.org/44101
DO  - 10.18260/1-2--44101
ER  -

WIP: Skip the Lecture: A Decoding First Approach to Introductory Computing Education

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David Zabner Tufts University

Trevion S Henderson Tufts University orcid.org/0000-0003-4319-1700

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