Conference Session

K-12 & Pre-College Engineering Division Poster Session: Works in Progress

Collection

2016 ASEE Annual Conference & Exposition

Authors

Bradley Bowen, North Dakota State University

Tagged Divisions

Pre-College Engineering Education Division

your students engage in the following learning activities?  Defining a problem when given probable scenarios  Brainstorming  Exploring multiple solutions to a problem  Evaluating criteria or constraints to a problem  Designing models or prototypes  Building physical models or prototypes  Testing possible solutions to a problem  Communicating solutions to a problem in written format  Communicating solutions to a problem in oral format  Communicating solutions to a problem by formal presentation  Reflecting in a notebook or journal  Developing a design portfolio  Critiquing their own work  Critiquing other students' work  Reworking solutions based on self or peer evaluation  Listening to

Conference Session

K-12 & Pre-College Engineering Division: Fundamental; K-12 Students & Engineering Division: Fundamental; K-12 Students & Engineering Design Practices: Best Paper Session

Collection

2016 ASEE Annual Conference & Exposition

Authors

Chelsea Joy Andrews, Tufts Center for Engineering Education and Outreach

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

groups are not synced, so times do not line up with each otherperfectly (up to 5-minute offsets are likely). The bottom group, Julian and Alex, only have sixcoded turns; this group was difficult to hear on the camera because they spoke very softly,answered many facilitator questions with “I don’t know,” and spent much of the task time offtask building “launchers.” Even so, they had the most successful designs of any group (threeunique designs, one was tested twice).Note that ideas, factors, and designs are related but distinct. While ideas are often reflected indesigns, designs include a multitude of ideas of varying scale, many of which are not explicitlyexpressed. Ideas may or may not be expressed as factors about a design or the test related

Conference Session

K-12 & Pre-College Engineering Division: Home, Parents, and Other Out-of-School Issues Related to K-12 and Pre-College Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Matthew Dickens, Arizona State University; Shawn S. Jordan, Arizona State University; Micah Lande, Arizona State University

Tagged Divisions

Pre-College Engineering Education Division

foryoung makers and families and how educational learning objectives match up with the attributesof making and values expressed by maker families.This will be addressed by both qualitative analysis of ongoing interviews with Young Makersand the parents of Young Makers. Emergent thematic analysis is be used to highlight themesrelevant to Maker families working together. Additionally, this work will explore the goals andpractices of informal science education museum community and establish a baseline and rangeof making activities and makerspaces in childrens’ museums.There is a trend for museums and science/technology centers to establish Makerspaces. ThePittsburgh Children's Museum has created Makeshop, a makerspace reflecting 7 specific

Conference Session

K-12 & Pre-College Engineering Division: Fundemental and Evaluation: Embedded Programs in Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Corey A. Mathis, Purdue University, West Lafayette; Emilie A. Siverling, Purdue University, West Lafayette; Aran W. Glancy, University of Minnesota, Twin Cities; Siddika Selcen Guzey, Purdue University, West Lafayette; Tamara J. Moore, Purdue University, West Lafayette

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

included a claim inan engineering context, which was a suggestion or decision related to the engineering design,plus at least one other element of an argument (data, warrants, backing, modal qualifiers, orrebuttals) was coded as EBR for this paper.Coding for EBR occurred within two types of data: student conversations and worksheets.Conversational instances of EBR were identified in terms of episodes since they reflect the back-and-forth dynamics of conversation. As such, some episodes contain multiple interweavinginstances of reasoning from evidence, but because of this interrelated nature, each episode wascoded as one instance of EBR. When coding worksheets for EBR, each individual instance ofEBR was coded separately since worksheets are a form

Conference Session

K-12 & Pre-College Engineering Division: Sustainability and Interdisciplinary Practices in K-12 Engineering Education Curriculum

Collection

2016 ASEE Annual Conference & Exposition

Authors

Skot Wiedmann, University of Illinois, Urbana-Champaign

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

with theircurriculum10.Pedagogical GoalsThe touch synthesizer workshop began as a means to fill a gap in the existing UniversityElectrical and Computer Education and to enrich student experiences beyond the classroom byteaching surface mount soldering techniques. By introducing electronic assembly, analysis, andrework, in the context of making sound and music, we aimed to inspire students to connect theirinterests, hobbies, and passions with their chosen field of study, even if they are traditionallyisolated practices11. We hoped to draw a diverse audience that reflected the varying perspectiveson these practices, and encouraged high school outreach and pre-college involvement. Wewanted participants to gain exposure to manufacturing processes

Conference Session

K-12 & Pre-College Engineering Division: Fundamental: K-12 Student Beliefs, Motivation, and Self Efficacy

Collection

2016 ASEE Annual Conference & Exposition

Authors

Brenda Capobianco, Purdue University, West Lafayette; James D. Lehman, Purdue University; Qiming Huang, Purdue University; Chell Nyquist, Purdue University

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

- Pre-/post- with students’ science learning? based Classroom Knowledge Tests Observational RubricTeacher participant dataInterviews. Semi-structured interviews (n=20 total) were conducted at the beginning and end ofthe school year to identify and characterize teachers’ perceptions of engineering design,expectations and reflections of task implementation, and challenges they experienced throughoutthe year. Analysis and interpretation of teacher interviews involved the use of grounded theory.18During this process, members of the research team focused on identifying indicators of conceptsand categories that fit the data. Repeatedly

Conference Session

K-12 & Pre-College Engineering Division: Research-to-Practice: Principles of K-12 Engineering Education and Practice

Collection

2016 ASEE Annual Conference & Exposition

Authors

Julie Steimle, University of Cincinnati; Anant R. Kukreti, University of Cincinnati; Catherine Maltbie, University of Cincinnati

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

, completed two of her four professional development requirementsby presenting at High Schools That Work and in a department meeting at her school, Felicity-Franklin. However, she also chose to provide one-on-one mentoring to a fellow teacher from herschool by meeting with her and explaining the pedagogies associated with the program. Thatsame teacher, BF, decided to apply to the program, was accepted, and now serves as an advocateof program pedagogies throughout Felicity-Franklin.BF made a tremendous impact on one particular science teacher in her rural school throughprofessional development. She mentored “Holly” through the process of creating andimplementing two engineering design challenge units and reflected upon the experience: My first

Conference Session

K-12 & Pre-College Engineering Division: Professional Development for Students and Teachers

Collection

2016 ASEE Annual Conference & Exposition

Authors

Matthew Moorhead, New York University; Colin Hennessy Elliott, New York University; Jennifer B. Listman, New York University; Catherine E. Milne, New York University; Vikram Kapila, New York University

Tagged Divisions

Pre-College Engineering Education Division

with the help of teachers to address problems they identified. Figure 1: Final, collaboratively designed, activity-bot.Besides the individual lesson refinement, the structure of the PD was adapted to increase teacherinvolvement in the construction of the lessons. With a few examples of fully developed lessonsthe teachers were involved in cognitive apprenticeship and, through reflection, were able to seehow an expert would create lessons using the robotic kit.31,32 The important consideration wasthat the teachers worked through all three units from a novice’s perspective of integratingrobotics activities into the development of a lesson.Week 2At the beginning of the second week, the teachers were introduced to DBR and given

Conference Session

K-12 & Pre-College Engineering Division Poster Session: Works in Progress

Collection

2016 ASEE Annual Conference & Exposition

Authors

Gina Navoa Svarovsky, University of Notre Dame; Marjorie B. Bequette, Science Museum of Minnesota; Lauren Causey

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

Movement isdefined by the Maker Media brand may be excluding the culturally-embedded making practicesfound in communities of color. Early analysis of focus group and interview data with membersof communities of color reflect this lack of alignment between their perceptions of making intheir every day lives and what is commonly portrayed as Making within the Maker community.Using Gee’s theory on Discourses, it is possible that the branding of Making by MAKEMagazine results in a limited definition of making focused heavily on electronics andmechanics. We argue that a return to a more inclusive view of making – one characterized bycreative, innovative, and generative processes found within all cultures, and values andhighlights examples of innovation

Conference Session

K-12 & Pre-College Engineering Division: Diversity Issues in K-12 and Pre-College Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Brynn Kasper, University of St. Thomas; Alison Haugh Nowariak, University of St. Thomas; Noah Kasper, University of St. Thomas; Brett D. Gunderson, University of St. Thomas; AnnMarie Polsenberg Thomas, University of St. Thomas; Deborah Besser P.E., University of St. Thomas

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

into the Metro Deaf School science club made use of SquishyCircuits ©, MaKey MaKey ©, and incorporated other electronic design challenges such as an e-textiles workshop. The team was able to reflect on the initial Creative Circuitry program and itsreception with the middle school students in order to build more engaging programs in the future.A fall 2014 program was also run and involved a concentration on individual engineeringdisciplines with each week focusing on a different discipline. This curriculum was built tointroduce and expose the deaf students to six different disciplines in enjoyable ways. During thedevelopment of this after-school program, several goals were built into each module of theengineering curriculum. The main goal was

Conference Session

K-12 & Pre-College Engineering Division: Fundemental and Evaluation: Embedded Programs in Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Ibrahim Halil Yeter, Texas Tech University; Hansel Burley, Texas Tech University; Terrance Denard Youngblood, Texas Tech University; Casey Michael Williams, Texas Tech University

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

materials in a timely manner, fabricating parts, strengtheningteamwork and communication skills, managing funding/schedules and developing rocketscapable of stable flight. Once a school achieves success at the Tsiolkovsky step, it moves to theOberth step. At this step, the curriculum focuses on incorporating all the knowledge andexperience from the first year, while students work toward achieving a greater understanding ofmass fractions and aerodynamic loads. Students also develop skills needed to design andconstruct the rocket vehicle. The curriculum at the Goddard step focuses on understanding whatis needed to develop high altitude flight time as well as reflecting on the entire process and thelearning it took to get there. SystemsGo charges

Conference Session

K-12 & Pre-College Engineering Division: Outreach in K12 through College Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Tony Lee Kerzmann, Robert Morris University; John Howard Walker, University of Pittsburgh; David V.P. Sanchez, University of Pittsburgh

Tagged Divisions

Pre-College Engineering Education Division

ideally should have a greater interest in the topics covered. 4) Enthusiasm: Enthusiasm is often positively correlated to attitude and motivation however; the former is often better defined as enjoyment while the latter reflects more on their reasoning and behaviors. 5) Creativity: This item is more abstract and its assessment will be discussed in another section. However, the intended gains in this area include develop a greater sense to design something unique and original. 6) Self-Efficacy: Self-efficacy has many of the above focus areas wrapped into it, but with a stronger connection to the students’ confidence and anxiety to take on and complete specific objectives in the field of sustainability

Conference Session

K-12 & Pre-College Engineering Division: Student-Centered Activities and Maker Spaces in Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

James Larson, Arizona State University; Micah Lande, Arizona State University, Polytechnic campus; Shawn S. Jordan, Arizona State University, Polytechnic campus

Tagged Divisions

Pre-College Engineering Education Division

skills anddispositions of engineers are as important to their success as the knowledge that comes withyears of study of math and science, and the frustrations along the way. Stevens describes theengineering educational experience as one of a “meritocracy of difficulty,” 1 the generalperception that the journey needs to be difficult to be worthwhile. A reflection of this on the K-12 student, and primary and secondary education at large, makes one consider where and howthe requisite “grit” 2 is forged.Makers are those who use technology to solve problems and invent solutions. The problems arepersonal in nature to the individual Maker, resulting in passionate, self-directed work towards asolution. With this work, we investigate youth actively

Conference Session

K-12 & Pre-College Engineering Division: Robotics in Pre-K-12 Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Fethiye Ozis, Northern Arizona University; Anna Danielle Newley, Sonoran Science Academy - Phoenix; Erdogan Kaya, University of Nevada - Las Vegas

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

compared to their peers,who were members of other clubs instead8. Schools can run successful programs if district anduniversity partnerships are established to train teachers on the best approach and receive mentorsupport from people whom share familiar backgrounds8. Unfortunately, this was not the case forour group, we lacked available mentors that reflect the culture of our student body in addition tothe lack of established partnerships with our charter school and nearby universities due to highturnover rate of coaches. To the best of our knowledge, this is the first time that data has beencollected on a FTC team comprised of 83% girls, 80% of students on refugee status, and 100%of students on national free and reduced lunch program.The need to

Conference Session

K-12 & Pre-College Engineering Division: Fundamental & Research-to-Practice: K-12 Engineering Resources: Best Practices in Curriculum Design (Part 2)

Collection

2016 ASEE Annual Conference & Exposition

Authors

Mary Ann Jacobs, Manhattan College; Kathleen Christal Mancuso, Manhattan College ; Zahra Shahbazi, Manhattan College; Alexandra Emma Lehnes, Manhattan College; Anthony Scotti, Manhattan College

Tagged Divisions

Pre-College Engineering Education Division

both parties to what is occurring outside of their respective fields and ways thateach can benefit from the other. The final product of a lesson plan may not be directly applicableto the engineering faculty; however, the professors are positively impacted in their ownprofessional development by being able to creatively think and influence students before theyreach college. They experience the effort required to make the material applicable and interestingand watch it come to life in their team members’ classrooms, while allowing them to evaluatetheir own teaching styles through the eyes of the teachers to reflect upon.Procedure & Methods Thirty-four public and private schools in close proximity to Manhattan College

Conference Session

K-12 & Pre-College Engineering Division: Fundamental & Research-to-Practice: K-12 Engineering Resources: Best Practices in Curriculum Design (Part 2)

Collection

2016 ASEE Annual Conference & Exposition

Authors

Louis Nadelson, Utah State University; Christina Marie Sias, Utah State University; Anne Seifert, Idaho National Laboratory

Tagged Divisions

Pre-College Engineering Education Division

deviate from the design cycle. For example,instead of developing prototypes that provided solutions to problems, the teacher generatedengineering lessons evolved to a focus on building models of processes (e.g., the sprouting of aseed) or tinkering to make a product, without documentation, testing, evaluation, or redesign aspart of the process. While students were engaged in these activities, many of the lessons werenot aligned with basic engineering principles and design, but did involve hands-on building of aproduct or tool in response to provided criteria. However, the notion that engaging students inhands-on activities to build something as engineering reflects a limited understanding of trueengineering design.36 The research of Nadelson et

Conference Session

K-12 & Pre-College Engineering Division: Evaluation: Impact of Curriculum for PreK-12 Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Amy Trauth, University of Delaware; Jenni Buckley, University of Delaware; Manuela Restrepo Parra, The Perry Initiative

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

variables such as gender, race, ethnicity, family’seducational background, and socioeconomic status. English et al. (2013) reported findings from a STEM-based lesson in whichstudents explored engineering concepts and principles pertaining to simple machines.The students clearly indicated how the machines were simulated by the materials. Thestudents were also able to reflect on different aspects of their design, especially onmaterial properties and how they affected stability. Allowing students to suggest ways toimprove their designs provided opportunities for further reflection in subsequent designprocesses. In general, students did not make explicit references to underlyingengineering and science principles, but they were able to link

Conference Session

K-12 & Pre-College Engineering Division: Addressing the NGSS: Supporting K12 Teachers in Engineering Pedagogy, Engineering Science, Careers, and Technical Pathways

Collection

2016 ASEE Annual Conference & Exposition

Authors

Julie Cafarella, University of Colorado - Boulder; Kevin O'Connor, University of Colorado - Boulder; Jacob (Jenna) McWilliams, University of Colorado - Boulder

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

applicable to asignificant population of students and educators. Further, this case study is relevant toengineering education in that it centers around a classroom that is engaged in “application ofscientific knowledge to an engineering problem,” and NGSS frames this case study as anexample of its “vision of blending disciplinary core ideas, scientific and engineering practices,and crosscutting concepts.” Throughout this paper the authors examine and reflect on the purposes of science andengineering education as well as the ways in which large-scale science reforms (such as NGSS)attempt to address issues of access and equity that continue to persist in science and engineeringeducation. In future, the authors hope to analyze other NGSS case

Conference Session

K-12 & Pre-College Engineering Division: Research-to-Practice: Principles of K-12 Engineering Education and Practice

Collection

2016 ASEE Annual Conference & Exposition

Authors

Malinda S. Zarske, University of Colorado - Boulder; Maia Lisa Vadeen, University of Colorado - Boulder; Janet Y. Tsai, University of Colorado - Boulder; Jacquelyn F. Sullivan Ph.D. , University of Colorado - Boulder; Denise W. Carlson, University of Colorado - Boulder

Tagged Divisions

Pre-College Engineering Education Division

of the authors) read and color-coded the transcripts according to the11 themes listed in Table 1. Related text was classified by giving each fragment of color-codedtranscript a unique identification number, and entered into spreadsheet columns and rows forindexing and to facilitate comparison of each coder’s responses. The inter-rater reliability wasdetermined through visual comparison of lines of coded text from each coder. Findings reportedin this paper reflect only the text with unanimous thematic agreement by all three readers.FindingsSurvey and focus group analysis showed that CU Teach Engineering students are enthusiastic toexplore their interests in both engineering and teaching. They view engineers and teachers asdifferent, but find

Conference Session

K-12 & Pre-College Engineering Division: Research to Practice: K-12 Engineering Resources: Best Practices in Curriculum Design (Part 1)

Collection

2016 ASEE Annual Conference & Exposition

Authors

Michael Grubbs, Baltimore County Public Schools; Greg J. Strimel, West Virginia University

Tagged Divisions

Pre-College Engineering Education Division

engineering designers: The role of reflective practice. Design Studies, 24(3), 275-294.Bilda, Z. & Gero, J. S. (2007). The impact of working memory limitations on the conceptual design process, Design Studies, 28(4), 343-367.Brookhart, S. M. (2010). How to assess higher-order thinking skills in your classroom. ASCD.Crismond, D.P., & Adams, R.S. (2012). The informed design teaching & learning matrix. Journal of Engineering Education, 101(4), 738-797.Cross, N. (2001). Design cognition: results from protocol and other empirical studies of design activity. In C. Eastman, W. Newstatter, & M. McCracken. (Eds.), Design knowing and learning: cognition in design education. (pp. 79-103). Oxford, UK

Conference Session

K-12 & Pre-College Engineering Division: Diversity Issues in K-12 and Pre-College Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Miles J. Mabey, Arizona State University; Micah Lande, Arizona State University; Shawn S. Jordan, Arizona State University

Tagged Divisions

Pre-College Engineering Education Division

prestigious awards. Maker Faires do have a small blue ribbon award that isgiven out but it is not competitive and there is no selective next level. This difference especiallyimpacts the overall social environment of the event.Advantages of Maker FairesThe atmosphere surrounding the Maker Faire creates different opportunities than a science fair,these differing opportunities are an advantage of Maker Faires. Maker Faire projects are oftenself-motivated and with fewer requirements than a science fair young makers can pick a projectthat reflects exactly what they are interested in and not what education dictates, We are particularly interested in how our approach might reach students who don’t fit well into the existing system or who have

Conference Session

K-12 & Pre-College Engineering Division: Addressing the NGSS: Supporting K12 Teachers in Engineering Pedagogy, Engineering Science, Careers, and Technical Pathways

Collection

2016 ASEE Annual Conference & Exposition

Authors

So Yoon Yoon, Texas A&M University; Johannes Strobel, University of Missouri

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

, there were exceptions in severalcourses and gender and racial/ethnic differences in the trends. Based on the findings, weidentified several interesting characteristics in the trends of student course-taking in CTE-STEMcourses and addressed each characteristics one by one with discussion.A. Overall, Student Enrollment Rates Increase across Time in CTE-STEM CoursesAs shown in Figures 2 through 5, overall over a six-year time frame, Texas high school studentenrollment rates were increasing in CTE-STEM courses when the effects of natural increase ofpopulation were controlled in enrollment rates. Even though the proportion of students taking theCTE-STEM courses is relatively small, the trends are promising as it reflects a continuousincrease of

Conference Session

Women in Engineering Division Technical Session - Pre-college Programs for Women

Collection

2016 ASEE Annual Conference & Exposition

Authors

Jenni Buckley, University of Delaware; Amy Trauth, University of Delaware; Laura Meszaros Dearolf, The Perry Initiative ; Amy C Bucha, The Perry Initiative; Lisa L Lattanza MD, University of California San Francisco

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division, Women in Engineering

to 5-pt Likert Scale. Whiskers represent ±1 standard deviation.Table 1: College majors for program alumnae and controls for both high school (intended major)and college (actual major). Students were permitted multiple responses to reflect dual majors andinterdisciplinary areas of study. Choice of college major was compared between alumnae andcontrols using chi-square test for independence (df=1, N=627 for high school, N=324 forcollege). High School CollegeCollge Major Program Control p value Program Control p valuePhysics, Chemistry, Math 29.4% 30.8% 0.68 7.3% 8.3% 0.86Biology or Biosciences 80.8

Conference Session

K-12 & Pre-College Engineering Division Poster Session: Works in Progress

Collection

2016 ASEE Annual Conference & Exposition

Authors

Brian Patrick O'Connell, Tufts University Center for Engineering Education and Outreach

Tagged Divisions

Pre-College Engineering Education Division

arethose of the author(s) and do not necessarily reflect the views of the National ScienceFoundation. The author would also like to thank the Center for Engineering Education andOutreach at Tufts University for their support.Bibliography1. Ashby, M. F., & Johnson, K. (2013). Materials and design: the art and science of material selection in product design: Butterworth-Heinemann.2. Lipson, H., & Kurman, M. (2010). Factory@ home: The emerging economy of personal fabrication. A report commissioned by the US Office of Science and Technology Policy.3. Klahr, D., Triona, L. M., & Williams, C. (2007). Hands on what? The relative effectiveness of physical versus virtual materials in an engineering design project

Conference Session

K-12 & Pre-College Engineering Division: Robotics in Pre-K-12 Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Shawna Fletcher, Texas A&M University; Susan Haag

Tagged Divisions

Pre-College Engineering Education Division

and four-years to reflect key ABET student outcomes.Finding 1: FIRST® Positively Impacts Student Interest, Skills and Abilities in STEMABET Student Outcomes: (a) an ability to apply knowledge of mathematics, science, andengineering; (k) an ability to use the techniques, skills, and modern engineering tools necessaryfor engineering practice.From the team leaders’ perspective, FIRST® had an impact in areas such as team members’interest in computers and technology, interest in jobs or careers in science and technology, andinterest in or awareness of how math and science are used in the real world. Overall, coachresponses suggested that FIRST® participants’ skills, interests, and abilities increased “a lot”during the program. As a result

Conference Session

K-12 & Pre-College Engineering Division: Student-Centered Activities and Maker Spaces in Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

James Holly Jr., Purdue University, West Lafayette; Cole H. Joslyn, Purdue University, West Lafayette; Avneet Hira, Purdue University, West Lafayette; Morgan M. Hynes, Purdue University, West Lafayette; Chanel Beebe, Purdue University, West Lafayette

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

engineering and investigating how engineering habits of mind can enhance pre-college students’ learning abilities.Cole H. Joslyn, Purdue University, West Lafayette Cole Joslyn is a PhD student in the School of Engineering Education at Purdue University. His research interests include holistic approaches to humanizing engineering education (such as ethics of care, human- istic education, contemplative and reflective practices, and spirituality) and how they can shape engineer- ing as a socially just profession in service to humanity. He holds a B.S. in Industrial Engineering and a M.Ed. specializing in mathematics education and has worked as an engineer, a pastor, and a high school math teacher.Miss Avneet Hira, Purdue

Conference Session

K-12 & Pre-College Engineering Division Poster Session: Works in Progress

Collection

2016 ASEE Annual Conference & Exposition

Authors

Nicholas Robert Stambach, Colorado School of Mines; Barbara M. Moskal, Colorado School of Mines

Tagged Divisions

Pre-College Engineering Education Division

) have been created in a flexible manner that supports theiradaption to multiple venues and grade levels. The design presented here simplifies the lessoncreation process while supporting a broad dissemination to pre-college teachers and students.The importance of this effort is reflected in the research findings that many young students donot know what engineers do.3 The proposed approach supports faculty and graduate students inmaximizing the potential impact of their outreach efforts, reaching a broader population of youngstudents. Two specific lesson plans are presented, Mining Coal and Bridge Building. These lessonswere selected because they illustrate flexibility in design and our initial efforts at embeddingsuch flexibility

Conference Session

K-12 & Pre-College Engineering Division: Outreach in K12 through College Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Eric Iversen, Start Engineering

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

participate in anoutreach survey than those not. We could well have a disproportionate data set. But outreach certainly“feels” like a nearly pervasive activity among universities, and this magnitude of extrapolation is likelyto be generally valid.Three programs reported about 65,000 of the 147,000-plus student total, each with about 20,000participants. The median figure for student programs was 200. The spiky-ness of participation numberspoints up something fundamental about the nature of the field. Outreach is a highly varied undertaking.Different schools have different goals, capabilities, and opportunities. Programs come in all shapes andalso all sizes.The community member total does reflect one unusually large program total that might bear

Conference Session

K-12 & Pre-College Engineering Division: Fundemental and Evaluation: Embedded Programs in Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Lelli Van Den Einde, University of California, San Diego; Heidi A. Tremayne, Earthquake Engineering Research Institute; Thalia Anagnos, San Jose State University; James Mallard, UC San Diego

Tagged Divisions

Pre-College Engineering Education Division

3-5-ETS1-1 Define a simple design problem reflecting a need or a want that includes specified criteria for success and constraints on materials, time or cost. 3-5-ETS1-2 Generate and compare multiple possible solutions to a problem based on how well each is likely to meet the criteria and constraints of the problem. 3-5-ETS1-3 Plan and carry out fair tests in which the variables are controlled and failureAdditional description and resources related to this K’Nex™ structure design activity can befound in the educational resources in NEESacademy on the NEES website[12], PacificEarthquake Engineering Research Center (PEER) website[9] and in a paper[7].During the

Conference Session

K-12 & Pre-College Engineering Division: Use of Technology and Tools for K-12 Engineering Education

Collection

2016 ASEE Annual Conference & Exposition

Authors

Henry M. Clever, New York University; Allison Graham Brown, New York University ; Vikram Kapila, New York University

Tagged Topics

Diversity

Tagged Divisions

Pre-College Engineering Education Division

by incorporating real work: real-worldrelevant assignments, ill-defined problems, sustained investigation, collaboration, and reflection.The AR Drone lab targeted all of these real work elements with its inherent real-worldimportance in technology, ill-defined experimental process, sustained investigation of errorsources, and continuous collaboration and reflection between teams. Simultaneously, it promotedthe three categories within quantitative research through this real work scenario: actualexperimental design and setup, theoretical calculations of ground speed from distance and time,and descriptive analysis of a real-world scenario.Within the “real work” learning process, it is essential to account for how the Net Generationlearns.21 The