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Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Student Technology Access in an Urban STEM High School: The Missing Variable Brian L. Sersion Cincinnati Public Schools Douglas M. Stevens University of Cincinnati and Cincinnati Public Schools ABSTRACT This case study focuses on school technology access for low-income students enrolled in Hughes STEM High School, a large urban science, technology, engineering, and mathematics (STEM) secondary school. In order to meet the high expectations of the STEM curriculum, students need access to information and communication technology (ICT) outside of school, especially at home. Our objective is to develop a better understanding of the expectations that schools have for students regarding the use of technology, the level of access students have outside of school, and whether students feel they have adequate access to and training in the appropriate technologies to meet the
expectations of their teachers and school. Teachers, staff, and school administrators need to be aware of the technology access limitations of their students to complete work. Our findings describe the technology access gap (TAG), a missing variable in educational technology research, and highlight results from an innovative student technology survey and school administrator interview. Keywords: STEM, Conference Proceedings, Assessment/Survey, Technology INTRODUCTION The research school in this case study is Hughes STEM High School, a newly established 7-12 secondary school in a large, Midwestern urban public school district. The science, technology, engineering, and mathematics (STEM) school relies on technology to achieve a project-based and outcome-driven curriculum. Effective use of technology as a learning tool suffers greatly when access to information and communication technology (ICT) is inadequate. ICT refers to technologies that provide access to information via
telecommunications media, such as the internet, wireless networks, computers and computing devices, such as “smart” phones (TechTerms.com, 2012) The potential technology tools have for transforming education is evident in the findings of multiple studies. The importance of educational technology is clear in the meta-analysis findings of Sivin-Kachala (1998), who found that when computers were used for instruction, the attitudes of students toward learning improved, along with their own self-concept. Positive effects in student achievement were shown in all major subject areas for those being educated in technology rich environments. In their research on technology-based education, Ringstaff and Kelley (2002) found using technology-based methods have a positive impact on student achievement. Robyler and Knezek (2003) consider access to technology for pedagogy essential for a quality education. The sociological significance of our study is evident in Frederick and Shockley who
conclude, “The utilization and reliance on computer technology in society has a devastating impact on many African-American students, who have limited access and/or limited experiences using computer technologies” (2008, p. 3) This opens the door to the question of equity in education and the so-called digital divide. Students with inadequate access to technology could easily be forced to the sidelines of the 21st century playing field. One of the goals of STEM education is to promote science, technology engineering and mathematics literacy, defined as “an individual’s ability to apply his or her understanding of how the world works within and across four interrelated domains” (Corn et al, 2010). How is this possible if 1 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 students don’t have adequate access to technology beyond the classroom? When a technology
access gap exists, students are at a disadvantage, particularly when there is a deficiency at home. Motivation for learning suffers when students are frustrated by inadequate resources to complete their school work. For this reason, it is important for educators to be aware of the technology access gap, which compares student access to technology at school and away from school. With this knowledge, educators can avoid unrealistic expectations and unnecessary frustration for students. But awareness is just the first step. Once awareness of the gap is established, teachers can then work to understand what constitutes realistic expectations and what support mechanisms are needed to aid students with lower levels of access. The impact differential access to technology resources has on student learning is described through a mixed-methods approach. The qualitative assessment tools used in this study provide a deeper understanding through a student survey and a semi-structured administrator
interview. Quantitative analysis and validation through other studies provide additional descriptive information in support of the qualitative findings. Educators at the research school will be in a better position to know the technology capacity of their students and classroom as a result of this case study. BACKGROUND The research school was founded in 2009 as a teacher-led school after a team of teachers, in partnership with a local university worked outside the classroom for over a year planning the new program in conjunction with business community partners and the Ohio STEM Learning Network. STEM-focused schools tend to share four characteristics: small size, project-based learning, integrated-curriculum, and a focus on serving underrepresented groups (Hanover Research, 2011). Unlike other STEM secondary schools in the state, this school has an open enrollment policy with no selective application process. The district’s high schools, with a handful of historic exceptions, are
“schools of choice” and as such, operate on a first-come, first-served basis for enrollment. The student population is predominantly African-American, and the vast majority of students receive free or reduced price lunch, which is the standard used by the State of Ohio to identify economically disadvantaged students. The school was designed using a scale-up model. Starting in the fall of 2009 during its first year, the school served ninth grade students only. In the fall of 2010, the initial cohort of students moved up to the newly formed tenth grade and another group of ninth grade students enrolled. Most recently, in the fall of 2011, that initial cohort began their junior year, while grades seven and eight were also added as the district restructured some of its elementary schools. The long-range plan for the school is to complement the kindergarten through sixth grade primary structure of many of the district’s elementary schools with a seventh through twelfth grade secondary
structure. Significant organizational structures within the school involve interdisciplinary teams at each of the grade levels, strong teacher leadership, and a democratic framework with strong ties to the surrounding community, businesses, and post-secondary institutions. The school’s curriculum makes heavy use of project-based learning (PBL), and has a custom, articulated curriculum which weaves not only content areas together in purposeful ways, but also integrates technology and 21st Century Skills into the STEM curriculum. Our project began with the design and implementation of a student technology survey. The survey includes scales for 21st Century Skills, use of technology for learning, and home access. Existing research regarding teacher adoption of technology (Knezek & Christensen, 2008) indicated that home access to the internet was critical to the adoption and mastery of technologies. Technology access requires the availability and reliability of computer resources,
including the internet. Internet access can be a limiting factor to a student’s capacity to participate in the 21st century learning environment. Furthermore, internet access can be viewed as a form of social capital, separating the “haves” from the “have nots” (DiMaggio & Hargittai, 2001). Our objective is to develop a better 2 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 understanding of the expectations schools have for students regarding: the use of technology, the level of access students have outside of school, and whether or not students feel they have adequate access to and training in the appropriate technologies to meet the expectations of their teachers and school. LITERATURE REVIEW The research study originated after identifying an omission in the educational technology research literature. Little research was found in the area of student
access to technology outside of school It became clear the “black box” needed to be opened to fully understand the technology access domain of students. This requires describing the overall exposure students have to technology The case study concentrates on the student access aspect of educational technology at the research school. Technology Access Students in urban schools have long struggled to gain access to technology (Walker, 1997). Partnerships are one way that schools can increase student access, but partnerships are initially dependent on the individuals who form them. Institutionalization of the roles of those involved in partnerships is required for them to become ingrained in organizational cultures. Nevens (2001) describes a framework for understanding and describing levels of technology access in schools. The four stages in this framework are: early tech, developing tech, advanced tech, and target tech. Early tech schools have very limited access to computers and the
internet, with computer to student ratios on the order of one to ten. Developing tech schools have slightly better access, but the technology tools are mainly used for accessing reference information. In advanced tech schools, student access increases but more importantly, teachers develop curriculum with technology woven into the curriculum not only as a research tool, but as a tool for collaboration and presentation. Target tech schools approach a one-to-one level of computer access, and have a wide range of technology tools beyond networked computers including digital cameras, scanners, video editing suites, and technology for data collection in the mathematics and science content areas. Technology access in urban schools with high poverty levels still falls well behind schools in districts with higher property values because of, among other reasons, school funding formulas which are outdated (Garland and Wotton, 2001). Public-private partnerships can assist schools, but it will be
difficult to close the gap without some type of government intervention. Legislators continue to resist wholesale changes to school funding structures, even when they have repeatedly been ruled unconstitutional by state supreme courts (Phillis, 2005). Downes and Pogue (1994) published extensive calculations of the additional cost for educating low-income students and determined that amount to be nearly $800 per year per student, and this amount has certainly increased due to inflation since their research was published. With current technology costs, simply one year of investing this money into the families of low income students could provide these families with the access they lack. Technology access and ethnicity are hard to differentiate from accompanying societal factors such as peer group dynamics and socioeconomic status (Clifton, 2006). Becker (2000) describes the need to expand technology resources for low income families. The need for universal broadband internet access
appears as a common theme in the literature. The definition of technology access is extended beyond hardware and software to include use, training, experience and application in Chisholm, Carey and Hernandez’s (2002) discussion of the importance of information technology skills in a pluralistic society. Assessing Technology Access Work began on a general student survey in early 2011 as part of a related research project focusing on classroom technology. Previous research in the area of educational technology (Carstens & Pelgrum, 2009) and 21st Century Skills (U.S Department of Education, 2010) established a foundation for the 3 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 survey. Composition of the student technology survey involved a thorough review of contemporary student technology surveys through educational technology journals, online resources and
personal archives. While working on the first version of the student technology survey, no instrument was found covering the construct of ICT access and use outside of school. A parallel set of questions was added to complement existing questions for student technology use in school, resulting in two constructs at this stage of development. Two additional constructs were identified and found to be important for assessing how students experience and relate to ICT. As a result, questions were added for 21st Century Skills (Corn et al, 2010) and use of technology for learning (Panhandle Area Education Consortium, 2011). The survey design process resulted in a comprehensive student survey covering four constructs: student technology use in school, student technology use and access outside of school, 21st Century Skills, and use of technology for learning. Methodology The educational technology literature suggests a logic model for exploring access to technology, developed through use of
technology and ultimately concluding with outcomes (Warschauer & Matuchniak, 2010). The single descriptive case study presented here concentrates on the technology access aspect of this model. In particular, the study concentrates on student access to computers and the internet. The principal methods used are case study and sequential explanatory research designs, supported by a student survey and school leader semi-structured interview. Using a mixed methods case study framework provides a mechanism for triangulating data to support conclusions and validate findings. One of the benefits of the mixed methods case study method is that it produces data from multiple sources, including researcher notes, documents, tables, narratives, and archival materials (Yin, 2008). Evidence was collected from the research school in a database with relevant materials presented as supporting documentation for the descriptions and accounts of the case. One of the limitations of the singular case
study method is that results can’t be generalized beyond the research school. In addition, since survey responses are self-reported, there is the possibility that students did not respond honestly. The fact that the school is composed of grades seven through eleven could make it hard to compare these findings to other STEM schools having a different structure. The following propositions were evaluated and they directed the initial phase of the research: Student use of ICT is controlled by access limitations. Student access to ICT differs based on the availability and location of resources. Realistic teacher expectations are informed by understanding the overall technology exposure of students, thereby grounding expectations in the students’ reality. Course and project requirements should be aligned with student access limitations, or accommodations should be made to promote student access. These initial propositions were expounded upon after identifying a technology
access gap (TAG) at the research school - the access students have to technology at school is significantly greater than it is away from school. TAG is not defined clearly in educational technology research and is therefore introduced here as a missing variable. Further inquiry was guided by two principal research questions, which are the key drivers for the data collection and analysis stage of the study. Is the TAG relevant to educators, and if so, how can this information be used to improve pedagogy? Student Technology Access and Use Survey The relevant issues for student technology access were enumerated through the survey design process, which helped define the context for the case study. For example, the researchers determined it was insufficient to simply ask about technology access “at home” since it omits possible exposures elsewhere. Since access to technology in the school was already known through school administrators, 4 University of Wisconsin-Stout July 16-17, 2012
Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 asking students about this aspect of technology access was excluded from the final survey. The Student Technology Access and Use Survey (STAUS) covers four constructs, as previously described (see Appendix A). Survey testing began a few months prior to administering the survey. The feedback received from school administrators, teachers and students during testing helped refine the survey. Student comments resulted in better defined terminology and response scales, and other comments clarified item ambiguity. Subsequently, the skip logic in the survey was revised and response scales were simplified, resulting in reduction in the overall length of the instrument. The time to complete the survey using an online survey tool (Sersion & Stevens, 2011) was approximately ten minutes. The survey was administered to students at the research school during their regular
technology class over a three week period in late 2011. After administering the survey, a computer software package was used for data analysis and reporting purposes (IBM SPSS Statistics, version 19). School Leader Interview Protocol The school leader interview protocol was developed to facilitate a semi-structured interview with either school principals or other school leaders. The research school culture emphasizes teacher leadership and therefore the focus was not solely on traditional models of administration and leadership. The questions assess the selection of the student population, school resources including both hardware and software, 21st Century Skills, and networking of the school to the larger community (see Appendix B). FINDINGS Student Technology Access and Use Survey The research school is located in a large urban district and has a student population of 31,989 students. It is located in a district composed of 40 elementary, twelve secondary (some with grades seven
through twelve) and three kindergarten through grade twelve schools. The research school is composed of grades seven through eleven, it is the only STEM school in the district, and has a student population of 774 students. This is somewhat larger than the average secondary school in the district, which has a median enrollment of 690 students. This study concentrates on the results from African-American and White students, representing over 95% of the total population. Other ethnicities are not described because their contribution is negligible. The final data set used in the analysis contained valid records for 570 students. This represents a 736% response rate The results indicate the research school and district are somewhat dissimilar in terms of demographics. In particular, the percentages of African-American and economically disadvantaged students at the research school are significantly higher than the district averages; 19.3% and 83% higher respectively. The research school is
located in a state that uses free and reduced price lunch records as a measure for student socioeconomic status, which may result in under-reporting of economically disadvantaged students since the information is self-reported and requires parents to complete and return paperwork in order to be included in the program. Gaines (1996) found “Inequities of class, gender, ethnicity and economic disparity correlate highly with denied or restricted access to the tools of technology” (p. 1) The last demographic variable considered is mobility, which is used to measure the number of students moving between schools during an academic year. In the district, 17% of students enrolled at the beginning of the year changed schools before the end of the year, some of which may have moved multiple times. The research school has significantly lower mobility at 6.8%, indicating a more stable student population compared to other schools in the district Key demographics for the school and district are
summarized in Table 1. 5 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Table 1: Student Demographics Demographic School * (%) District * (%) African-American White Economically Disadvantaged Students with Disabilities Mobility 86.5 9.1 67.2 24.4 78.2 69.9 23.2 20.4 6.8 17.0 Sources: * research school (November 2011) * 2010-11 District Needs Assessment (May 2011) The following variables were evaluated to describe technology access in school: computer to student ratio, computer reliability, and internet access. A wide range was found when comparing computer to student ratios in the district (results include Macintosh and Windows-based computers), from low access (six students per computer) to high access (one computer per student). Two schools, including the research school, technically have a one to one ratio. However, students are not carrying computers
with them throughout the day and not every classroom is set up as a computer lab. When discussing computer access it is also important to consider the reliability of computers. Age of computers was used to describe this aspect of in-school access. The median age of computers for the district during the period of this study was six years old. The median age of computers at the research school was better than average at five years old. Based on this profile, the research school is considered a target tech school (Nevens, 2001). Technology access away from school was evaluated using results from the student technology survey. The student technology survey provides two indicators by first asking students if they have adequate access to computers and then asking if they have adequate access to the internet. The results of the survey provide firsthand evidence of student access to technology resources away from school. Survey results indicate that 76.5% of students at the research school
have a computer at home (Question 2). A closer look by ethnicity shows that 861% of White students have a computer at home compared to 75.5% of African-American students When asked “How often do you use a computer outside of school” (Question 4), 21.1% of students responded “Less than weekly” Less than weekly computer use is considered to be a drastically low level for 21st century learners. Comparing student ethnicity on this response shows little difference between White and African-American students but on the other end of the response scale there is a great difference. Overall, 40% of students responded they use a computer outside of a school on a daily basis: 39% of African-American and 55.6% of White students. These findings are partially validated by national census results, although the question was asked differently (U.S Department of Commerce, 2009) Families without home internet were asked why they did not have internet access. Select STAUS results are presented in
Table 2 and Figure 1 6 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Table 2: Student Technology Access and Use Survey, Select School Results Question 3: Students that have enough computer access to complete school assignments Question 5: Students that have enough computer access to complete school assignments outside of school Question 7: Students that have internet access at home AfricanAmerican 71.4% (n = 360) 65.1% (n = 330) 73.4% (n = 372) White 75.0% (n = 27) 55.6% (n = 20) 91.7% (n = 33) All Students 72.3% (n = 410) 64.9% (n = 370) 75.3% (n = 429) Ethnicity Figure 1: Student Technology Access Locations for School Survey results indicate a significant difference in internet access for students based on ethnicity. We found 91.7% of White students from the research school had internet access at home, compared to 73.4% of African-American; 183%
internet access gap Comparing this to national results from a few years prior shows a similar gap for all comparison groups (U.S Department of Commerce, 2009) For the high school subgroup, 93.2% of White students had internet access at home, compared to 770% of African-American; 16.2% internet access gap (see Figure 2) The similarity in results between the research school and national comparison group is striking. 7 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Percent African-American 100.0 95.0 90.0 85.0 80.0 75.0 70.0 65.0 60.0 55.0 50.0 White 78.6 73.4 School * 92.9 92.9 93.2 91.7 81.0 77.0 HS Only PreK - 12 All Persons Source: U.S Dept of Commerce 2009 and STAUS 2011* Figure 2: Internet Access by Ethnicity School Leader Interview Despite the challenges to technology access outside of school for some students, both survey results and the school
leader interview indicate high levels of technology integration during the school day. Ninety-nine percent of Hughes STEM High School students reported using technology most or every day, as compared with only 45% of the district-wide population. This is tempered by the fact that conversely, only 68% of students in the school use a computer outside of school, compared with 71.5% district-wide. This pervasiveness of technology partially accounts for what we describe as the technology access gap. The district student survey indicated that most students have better technology access at home than they do at school. However, students at the research school have 40% greater technology access at school than at home compared to the district average. This means that although the research school is far more successful in giving students access to technology during the school day, this has only exacerbated the lack of access outside of school. The administrator interview with the program
facilitator revealed that project-based learning is the foundation for the use of technology at the research school and the 21st Century Skills of critical thinking, communication, collaboration, and creativity are evident in the projects students participate in to demonstrate their learning to authentic audiences. In addition to traditional software packages like Microsoft Office and Adobe Design Premium Creative Suite, students use software as a service resources. For example, Wikispaces allows students to collaborate asynchronously and develop interdisciplinary presentations for a local museum. Students use Google SketchUp during the process of building and designing an ecologically green town for their STEM Foundations class project. Field science experiment toolkits contain digital cameras, Livescribe pens, and laptops in a single digital backpack and allow students to learn outside the school, collecting data and creating presentations in the field and with community partners. At
the end of their sophomore year, students must create a Gateway presentation in which they petition to enter into one of four career pathways for their junior and senior years. This presentation empowers students to creatively choose from any of dozens of digital presentation techniques they have learned in their curricular projects to advocate for their future. Based on Nevens’ technology adoption framework, the research school is clearly in the “target tech” 8 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 phase of adoption with both its wide range of technology tools as well as the seamless integration of technology through multidisciplinary, project-based learning. CONCLUSIONS In order to advance pedagogy, researchers need to provide educators with relevant information to help advance practice. It is important to obtain a complete picture of student
technology access by understanding how and where students access ICT away from school. Students can access computer technology in many locations outside of school, including home, relatives’ or friends’ computers, the public library, community centers, and virtually anywhere else they have access to the internet through smart devices (i.e “the cloud”) Increased access to technology in education is a double-edged sword, resulting in greater opportunities and advantages for those students with adequate resources to participate. As teacher expectations increase with the expansion of technology-based tools, the pressure on students to competently use these tools also increases. The pressure may even be greater for students that have limited access to technology. Knowing a student’s technology exposure at school provides limited information for understanding how students are exposed to technology in their everyday lives. Teachers have the power to close the technology access gap
by using assessment tools to understand the resource limitations of their students. Knowing their students beyond the classroom will enable teachers to adopt realistic expectations for technology access away from school and enable students to reach their potential. This case has identified a missing variable in educational research by describing technology use and access at a large urban STEM high school, and answered the principal research questions initially postulated. The Technology Access Gap (TAG) is relevant to any educator concerned with understanding the ICT limitations of their students and it can be used to improve pedagogy. Improvement is possible by educating teachers who need to know about the technology resource limitations of their students. Teachers are already familiar with the process and utility of making accommodations for students with disabilities. A similar practice could be followed for limited technology access students. In the 21st century learning
environment, learning options are required to meet the diverse needs of students, and this condition is extended to students having limited access to technology. Once the need for accommodations is established at the school level, the scope for accommodations can be broadened to the district level. Accommodation programs, such as free Wi-Fi and laptop check-out, and creative solutions such as flexible transportation to allow students to stay after school, are necessary to fill the gap so that educators provide equitable access to information and communication technologies. This is an important step towards opening the playing field for all 21st century learners. SUGGESTIONS FOR BEST PRACTICES In a high poverty urban school, it is difficult to overestimate the amount of effort that is necessary to support a modern, project-based STEM curriculum. Downes and Pogue (1994) document the additional costs associated with educating disadvantaged students, but even their analysis is based on a
traditional academic curriculum and not a STEM-focused one. Any STEM school needs to build equipment maintenance, repair, and replacement costs into its budget, as well as costs for subscriptions to internet-based software and services. Our survey suggests, however, that accommodations also need to be made for students lacking ICT access outside of school. Through partnerships with businesses and universities, grants or donations may be able to cover some of the costs of properly resourcing students. In order for schools to know what technology support and services are needed and by whom, some type of survey or assessment should be conducted. STAUS offers schools a tool to assess technology access and use at school and away from school, in addition to measuring integration of 21st 9 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Century Skills. The school in this case
study provides high levels of technical support to both students and staff. This is critical to avoid frustration and encourage innovation The hiring process for staff at the research school included assessing prospective teachers’ comfort with adoption of technology and collaborative skills. Other STEM schools would do well to have similar hiring filters in place Write-in responses on STAUS indicated students’ frustration with not being able to take technology from school home with them. The initial cohort of students at the research school was told that part of the STEM program involved permission to take laptop computers home. Although the business community has been generous in providing the school with laptop and desktop computers, there is not yet a process in place for students to take equipment home. In order for a check-out program to be successful, efforts should be made to expand the existing partnership with a local university and tap into ICT resources such as
undergraduate assistants. Additional grants could cover the cost of developing and maintaining a check-out program for low-income students and upper class students from the research school could be trained for leadership positions to handle much of the program in-house. FUTURE WORK Although the implemented technology access survey produced the desired results, examination of the findings has still left us with an incomplete understanding of student’s technology access. Additional work is needed to understand in greater detail both the problems leading up to the lack of student technology access, and we need to learn more about teachers’ understanding of student technology access and how accommodations are being made to fill the gap. Semi-structured, qualitative interviews with students and teachers would help to create a richer description of technology access issues. From the perspective of the researchers, we would be able to more fully describe teacher implementation of
accommodations for students with limited access to technology. Currently, the school offers study tables after school three days a week, during which students have access to computer labs. Teachers also make individual agreements with students to increase their technology access in more creative ways. However, because the research school is openenrollment and students come from a large urban area, not all students can stay late due to transportation limitations. Still other students are unable to stay late because they have younger siblings to care for after school. The process of conducting interviews would serve to increase teacher awareness of student technology access issues. A clear extension of the current study is to explore the other constructs of the student technology survey which were not covered in this case study. Completing a validation study of the Student Technology Use and Access Survey (STAUS) would enhance educational technology practice by providing a validated
instrument for researchers’ use. In addition, defining the technology access gap as an educational metric would contribute to educational research by providing a standard measure for educators, allowing comparisons across schools and districts. Initial thoughts in this line of research include exploring ICT exposure scales and the fact that conceptually, the “gap” may be better understood in terms of a balance. 10 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 APPENDIX A - STAUS INSTRUMENT 11 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 12 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 13 University of Wisconsin-Stout
July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 14 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 APPENDIX B - ADMINISTRATOR SURVEY QUESTIONS Technology Access and Use at an Emerging Urban STEM High School Principal/Program Facilitator Interview Questions 1. How are students selected for this school? 2. What prerequisites are there for students attending this school? 3. How did this school acquire the technology that students use? 4. Describe the major pieces of hardware used on a regular basis by teachers and students 5. Describe the major software packages used on a regular basis by teachers and students 6. What 21st Century Skills does this school incorporate into the curriculum? 7. What support mechanisms are in place for students needing additional time or training with the
technology? 8. What is the documented poverty rate at your school? How does this impact instruction? 9. Describe your school’s connections to the statewide and/or national STEM networks of schools. 10. What are some of the major project-based learning (PBL) activities for students at your school which integrate technology? 15 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 REFERENCES Becker, H. J 2000 Whos wired and whos not: Childrens access to and use of computer technology. The Future of Children, 10(2), 44-75 Carstens, R., Ed, & Pelgrum, W J 2009 Second information technology in education study: SITES 2006 technical report. Amdsterdam, NL: International Association for the Evaluation of Educational Achievement. Chisholm, I., Carey, J, & Hernandez, A 2002 Information technology skills for a pluralistic society: Is the playing field level? Journal of
Research on Technology in Education, 35(1), 58. Christensen, R., & Knezek, G 2008 Self-report measures and findings for information technology attitudes and competencies. In (pp 349-365) Boston, MA: Springer US doi:101007/978-0-38773315-9 21 Clifton, N. S 2006 An examination of home and school technology access and usage in relation to urban high school students and the achievement gap. Harvard University) Corn, J., Stallings, T, Stanhope, D, Townsend, M, Patel, R, Argueta, R, & Kleiman, G 2010 Governor Perdues North Carolina student learning conditions (SLCS); survey validation study - phase II. Raleigh: North Carolina State University DiMaggio, P., & Hargittai, E 2001 From the digital divide to digital inequality: Studying internet use as penetration increases. Princeton, NJ: Princeton University Center for Arts and Cultural Policy Studies. Downes, T., & Pogue, T 1994 Adjusting school aid formulas for the higher cost of educating disadvantaged students. National Tax
Journal, 47(1), 89-110 Frederick, R. & Shockley, K 2008 Culturally responsive uses of technology: A portrait of three teachers working in urban schools. Electronic Journal for the Integration of Technology in Education, 7(1), 3-21. Garland, V. E, & Wotton, S E 2002 Bridging the digital divide in public schools Journal of Educational Technology Systems, 30(2), 115-23. Hanover Research. 2011 K-12 STEM education overview Washington, DC: Hanover Research Knezek, G., & Christensen, R 2008 The importance of information technology attitudes and competencies in primary and secondary education. In International handbook of information technology in primary and secondary education (pp. 321-331) Boston, MA: Springer US doi:10.1007/978-0-387-73315-9 19 Nevens, T. M 2001 Fast lines at digital high IEEE Spectrum, 38(4), 16-17 doi:10.1109/MSPEC2001915196 Panhandle Area Education Consortium. 2011 Student technology survey http://www.paecorg/teacher2teacher/studentnetssurveyt2tpdf Phillis,
W. L 2005 Ohios school funding litigation saga: More money and some new buildings but the same unconstitutional school funding structure. Journal of Education Finance, 30(3), 313 Ringstaff, C., & Kelley, L 2002 The learning return on our educational technology investment: A review of findings from research. San Francisco, CA Roblyer, M., & Knezek, G 2003 New millennium research for educational technology: A call for a national research agenda. Journal of Research on Technology in Education, 36(1), 60 Sivin-Kachala, J., Bialo, E R, & Langford, J 1997 The effectiveness of technology in schools: 90-97 report. New York, NY: Software Publishers Association SPSS Statistics 19. 2011 Release Version 1900, SPSS, Inc, 2009, Chicago, IL, (available at: http://www.spsscom) TechTerms.com 2010 from http://wwwtechtermscom/definitions/ict 16 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and
Society Session 1-1 Sersion, B. L, & Stevens, DM 2011 Student technology access and use survey (STAUS) http://www.zoomerangcom U. S Department of Commerce 2009 Current population survey Washington, DC: Census Bureau. U. S Department of Education 2006 Computer and internet use by students in 2003: Statistical analysis report. Washington, DC: National Center for Education Statistics U. S Department of Education 2010 Transforming american education: Learning powered by technology. national education technology plan, 2010 (No ED512681) U S Department of Education. U. S Department of Education 2011 Digital nation: Expanding internet usage Washington, D.C: National Telecommunications and Information Administration Walker, V. A 1997 The great technology divide: How urban schools lose The Education Digest, 62(6), 47. Warschauer, M. 2003 Technology and social inclusion: Rethinking the digital divide Cambridge, MA: MIT Press. Warschauer, M., & Matuchniak, T 2010 New technology and
digital worlds: Analyzing evidence of equity in access, use, and outcomes. Review of Research in Education, 34(1), 179-225 Yin, R. K 2009 Case study research: Design and methods Los Angeles, CA: Sage Publications AUTHORS INFORMATION Brian L. Sersion is a program evaluator and research analyst at Cincinnati Public Schools, Research and Evaluation Department. He holds a MS in Quantitative Analysis from the University of Cincinnati (1999) and BS in Geological Sciences from Ohio University (1988). Brian is an ASQ Certified Quality Engineer and his leadership in the Statistics Division has led to numerous awards from the Society. He can be contacted at: sersiob@cps-k12.org Douglas M. Stevens is a doctoral student at the University of Cincinnati in educational studies and teaches English and technology at Hughes STEM High School, part of Cincinnati Public Schools. His current research focuses on technology access and equity, student voice empowerment, and school organizational culture with
a focus on relational theory and teacher leadership. He can be contacted at: stevend@cps-k12.org 17 University of Wisconsin-Stout July 16-17, 2012
expectations of their teachers and school. Teachers, staff, and school administrators need to be aware of the technology access limitations of their students to complete work. Our findings describe the technology access gap (TAG), a missing variable in educational technology research, and highlight results from an innovative student technology survey and school administrator interview. Keywords: STEM, Conference Proceedings, Assessment/Survey, Technology INTRODUCTION The research school in this case study is Hughes STEM High School, a newly established 7-12 secondary school in a large, Midwestern urban public school district. The science, technology, engineering, and mathematics (STEM) school relies on technology to achieve a project-based and outcome-driven curriculum. Effective use of technology as a learning tool suffers greatly when access to information and communication technology (ICT) is inadequate. ICT refers to technologies that provide access to information via
telecommunications media, such as the internet, wireless networks, computers and computing devices, such as “smart” phones (TechTerms.com, 2012) The potential technology tools have for transforming education is evident in the findings of multiple studies. The importance of educational technology is clear in the meta-analysis findings of Sivin-Kachala (1998), who found that when computers were used for instruction, the attitudes of students toward learning improved, along with their own self-concept. Positive effects in student achievement were shown in all major subject areas for those being educated in technology rich environments. In their research on technology-based education, Ringstaff and Kelley (2002) found using technology-based methods have a positive impact on student achievement. Robyler and Knezek (2003) consider access to technology for pedagogy essential for a quality education. The sociological significance of our study is evident in Frederick and Shockley who
conclude, “The utilization and reliance on computer technology in society has a devastating impact on many African-American students, who have limited access and/or limited experiences using computer technologies” (2008, p. 3) This opens the door to the question of equity in education and the so-called digital divide. Students with inadequate access to technology could easily be forced to the sidelines of the 21st century playing field. One of the goals of STEM education is to promote science, technology engineering and mathematics literacy, defined as “an individual’s ability to apply his or her understanding of how the world works within and across four interrelated domains” (Corn et al, 2010). How is this possible if 1 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 students don’t have adequate access to technology beyond the classroom? When a technology
access gap exists, students are at a disadvantage, particularly when there is a deficiency at home. Motivation for learning suffers when students are frustrated by inadequate resources to complete their school work. For this reason, it is important for educators to be aware of the technology access gap, which compares student access to technology at school and away from school. With this knowledge, educators can avoid unrealistic expectations and unnecessary frustration for students. But awareness is just the first step. Once awareness of the gap is established, teachers can then work to understand what constitutes realistic expectations and what support mechanisms are needed to aid students with lower levels of access. The impact differential access to technology resources has on student learning is described through a mixed-methods approach. The qualitative assessment tools used in this study provide a deeper understanding through a student survey and a semi-structured administrator
interview. Quantitative analysis and validation through other studies provide additional descriptive information in support of the qualitative findings. Educators at the research school will be in a better position to know the technology capacity of their students and classroom as a result of this case study. BACKGROUND The research school was founded in 2009 as a teacher-led school after a team of teachers, in partnership with a local university worked outside the classroom for over a year planning the new program in conjunction with business community partners and the Ohio STEM Learning Network. STEM-focused schools tend to share four characteristics: small size, project-based learning, integrated-curriculum, and a focus on serving underrepresented groups (Hanover Research, 2011). Unlike other STEM secondary schools in the state, this school has an open enrollment policy with no selective application process. The district’s high schools, with a handful of historic exceptions, are
“schools of choice” and as such, operate on a first-come, first-served basis for enrollment. The student population is predominantly African-American, and the vast majority of students receive free or reduced price lunch, which is the standard used by the State of Ohio to identify economically disadvantaged students. The school was designed using a scale-up model. Starting in the fall of 2009 during its first year, the school served ninth grade students only. In the fall of 2010, the initial cohort of students moved up to the newly formed tenth grade and another group of ninth grade students enrolled. Most recently, in the fall of 2011, that initial cohort began their junior year, while grades seven and eight were also added as the district restructured some of its elementary schools. The long-range plan for the school is to complement the kindergarten through sixth grade primary structure of many of the district’s elementary schools with a seventh through twelfth grade secondary
structure. Significant organizational structures within the school involve interdisciplinary teams at each of the grade levels, strong teacher leadership, and a democratic framework with strong ties to the surrounding community, businesses, and post-secondary institutions. The school’s curriculum makes heavy use of project-based learning (PBL), and has a custom, articulated curriculum which weaves not only content areas together in purposeful ways, but also integrates technology and 21st Century Skills into the STEM curriculum. Our project began with the design and implementation of a student technology survey. The survey includes scales for 21st Century Skills, use of technology for learning, and home access. Existing research regarding teacher adoption of technology (Knezek & Christensen, 2008) indicated that home access to the internet was critical to the adoption and mastery of technologies. Technology access requires the availability and reliability of computer resources,
including the internet. Internet access can be a limiting factor to a student’s capacity to participate in the 21st century learning environment. Furthermore, internet access can be viewed as a form of social capital, separating the “haves” from the “have nots” (DiMaggio & Hargittai, 2001). Our objective is to develop a better 2 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 understanding of the expectations schools have for students regarding: the use of technology, the level of access students have outside of school, and whether or not students feel they have adequate access to and training in the appropriate technologies to meet the expectations of their teachers and school. LITERATURE REVIEW The research study originated after identifying an omission in the educational technology research literature. Little research was found in the area of student
access to technology outside of school It became clear the “black box” needed to be opened to fully understand the technology access domain of students. This requires describing the overall exposure students have to technology The case study concentrates on the student access aspect of educational technology at the research school. Technology Access Students in urban schools have long struggled to gain access to technology (Walker, 1997). Partnerships are one way that schools can increase student access, but partnerships are initially dependent on the individuals who form them. Institutionalization of the roles of those involved in partnerships is required for them to become ingrained in organizational cultures. Nevens (2001) describes a framework for understanding and describing levels of technology access in schools. The four stages in this framework are: early tech, developing tech, advanced tech, and target tech. Early tech schools have very limited access to computers and the
internet, with computer to student ratios on the order of one to ten. Developing tech schools have slightly better access, but the technology tools are mainly used for accessing reference information. In advanced tech schools, student access increases but more importantly, teachers develop curriculum with technology woven into the curriculum not only as a research tool, but as a tool for collaboration and presentation. Target tech schools approach a one-to-one level of computer access, and have a wide range of technology tools beyond networked computers including digital cameras, scanners, video editing suites, and technology for data collection in the mathematics and science content areas. Technology access in urban schools with high poverty levels still falls well behind schools in districts with higher property values because of, among other reasons, school funding formulas which are outdated (Garland and Wotton, 2001). Public-private partnerships can assist schools, but it will be
difficult to close the gap without some type of government intervention. Legislators continue to resist wholesale changes to school funding structures, even when they have repeatedly been ruled unconstitutional by state supreme courts (Phillis, 2005). Downes and Pogue (1994) published extensive calculations of the additional cost for educating low-income students and determined that amount to be nearly $800 per year per student, and this amount has certainly increased due to inflation since their research was published. With current technology costs, simply one year of investing this money into the families of low income students could provide these families with the access they lack. Technology access and ethnicity are hard to differentiate from accompanying societal factors such as peer group dynamics and socioeconomic status (Clifton, 2006). Becker (2000) describes the need to expand technology resources for low income families. The need for universal broadband internet access
appears as a common theme in the literature. The definition of technology access is extended beyond hardware and software to include use, training, experience and application in Chisholm, Carey and Hernandez’s (2002) discussion of the importance of information technology skills in a pluralistic society. Assessing Technology Access Work began on a general student survey in early 2011 as part of a related research project focusing on classroom technology. Previous research in the area of educational technology (Carstens & Pelgrum, 2009) and 21st Century Skills (U.S Department of Education, 2010) established a foundation for the 3 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 survey. Composition of the student technology survey involved a thorough review of contemporary student technology surveys through educational technology journals, online resources and
personal archives. While working on the first version of the student technology survey, no instrument was found covering the construct of ICT access and use outside of school. A parallel set of questions was added to complement existing questions for student technology use in school, resulting in two constructs at this stage of development. Two additional constructs were identified and found to be important for assessing how students experience and relate to ICT. As a result, questions were added for 21st Century Skills (Corn et al, 2010) and use of technology for learning (Panhandle Area Education Consortium, 2011). The survey design process resulted in a comprehensive student survey covering four constructs: student technology use in school, student technology use and access outside of school, 21st Century Skills, and use of technology for learning. Methodology The educational technology literature suggests a logic model for exploring access to technology, developed through use of
technology and ultimately concluding with outcomes (Warschauer & Matuchniak, 2010). The single descriptive case study presented here concentrates on the technology access aspect of this model. In particular, the study concentrates on student access to computers and the internet. The principal methods used are case study and sequential explanatory research designs, supported by a student survey and school leader semi-structured interview. Using a mixed methods case study framework provides a mechanism for triangulating data to support conclusions and validate findings. One of the benefits of the mixed methods case study method is that it produces data from multiple sources, including researcher notes, documents, tables, narratives, and archival materials (Yin, 2008). Evidence was collected from the research school in a database with relevant materials presented as supporting documentation for the descriptions and accounts of the case. One of the limitations of the singular case
study method is that results can’t be generalized beyond the research school. In addition, since survey responses are self-reported, there is the possibility that students did not respond honestly. The fact that the school is composed of grades seven through eleven could make it hard to compare these findings to other STEM schools having a different structure. The following propositions were evaluated and they directed the initial phase of the research: Student use of ICT is controlled by access limitations. Student access to ICT differs based on the availability and location of resources. Realistic teacher expectations are informed by understanding the overall technology exposure of students, thereby grounding expectations in the students’ reality. Course and project requirements should be aligned with student access limitations, or accommodations should be made to promote student access. These initial propositions were expounded upon after identifying a technology
access gap (TAG) at the research school - the access students have to technology at school is significantly greater than it is away from school. TAG is not defined clearly in educational technology research and is therefore introduced here as a missing variable. Further inquiry was guided by two principal research questions, which are the key drivers for the data collection and analysis stage of the study. Is the TAG relevant to educators, and if so, how can this information be used to improve pedagogy? Student Technology Access and Use Survey The relevant issues for student technology access were enumerated through the survey design process, which helped define the context for the case study. For example, the researchers determined it was insufficient to simply ask about technology access “at home” since it omits possible exposures elsewhere. Since access to technology in the school was already known through school administrators, 4 University of Wisconsin-Stout July 16-17, 2012
Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 asking students about this aspect of technology access was excluded from the final survey. The Student Technology Access and Use Survey (STAUS) covers four constructs, as previously described (see Appendix A). Survey testing began a few months prior to administering the survey. The feedback received from school administrators, teachers and students during testing helped refine the survey. Student comments resulted in better defined terminology and response scales, and other comments clarified item ambiguity. Subsequently, the skip logic in the survey was revised and response scales were simplified, resulting in reduction in the overall length of the instrument. The time to complete the survey using an online survey tool (Sersion & Stevens, 2011) was approximately ten minutes. The survey was administered to students at the research school during their regular
technology class over a three week period in late 2011. After administering the survey, a computer software package was used for data analysis and reporting purposes (IBM SPSS Statistics, version 19). School Leader Interview Protocol The school leader interview protocol was developed to facilitate a semi-structured interview with either school principals or other school leaders. The research school culture emphasizes teacher leadership and therefore the focus was not solely on traditional models of administration and leadership. The questions assess the selection of the student population, school resources including both hardware and software, 21st Century Skills, and networking of the school to the larger community (see Appendix B). FINDINGS Student Technology Access and Use Survey The research school is located in a large urban district and has a student population of 31,989 students. It is located in a district composed of 40 elementary, twelve secondary (some with grades seven
through twelve) and three kindergarten through grade twelve schools. The research school is composed of grades seven through eleven, it is the only STEM school in the district, and has a student population of 774 students. This is somewhat larger than the average secondary school in the district, which has a median enrollment of 690 students. This study concentrates on the results from African-American and White students, representing over 95% of the total population. Other ethnicities are not described because their contribution is negligible. The final data set used in the analysis contained valid records for 570 students. This represents a 736% response rate The results indicate the research school and district are somewhat dissimilar in terms of demographics. In particular, the percentages of African-American and economically disadvantaged students at the research school are significantly higher than the district averages; 19.3% and 83% higher respectively. The research school is
located in a state that uses free and reduced price lunch records as a measure for student socioeconomic status, which may result in under-reporting of economically disadvantaged students since the information is self-reported and requires parents to complete and return paperwork in order to be included in the program. Gaines (1996) found “Inequities of class, gender, ethnicity and economic disparity correlate highly with denied or restricted access to the tools of technology” (p. 1) The last demographic variable considered is mobility, which is used to measure the number of students moving between schools during an academic year. In the district, 17% of students enrolled at the beginning of the year changed schools before the end of the year, some of which may have moved multiple times. The research school has significantly lower mobility at 6.8%, indicating a more stable student population compared to other schools in the district Key demographics for the school and district are
summarized in Table 1. 5 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Table 1: Student Demographics Demographic School * (%) District * (%) African-American White Economically Disadvantaged Students with Disabilities Mobility 86.5 9.1 67.2 24.4 78.2 69.9 23.2 20.4 6.8 17.0 Sources: * research school (November 2011) * 2010-11 District Needs Assessment (May 2011) The following variables were evaluated to describe technology access in school: computer to student ratio, computer reliability, and internet access. A wide range was found when comparing computer to student ratios in the district (results include Macintosh and Windows-based computers), from low access (six students per computer) to high access (one computer per student). Two schools, including the research school, technically have a one to one ratio. However, students are not carrying computers
with them throughout the day and not every classroom is set up as a computer lab. When discussing computer access it is also important to consider the reliability of computers. Age of computers was used to describe this aspect of in-school access. The median age of computers for the district during the period of this study was six years old. The median age of computers at the research school was better than average at five years old. Based on this profile, the research school is considered a target tech school (Nevens, 2001). Technology access away from school was evaluated using results from the student technology survey. The student technology survey provides two indicators by first asking students if they have adequate access to computers and then asking if they have adequate access to the internet. The results of the survey provide firsthand evidence of student access to technology resources away from school. Survey results indicate that 76.5% of students at the research school
have a computer at home (Question 2). A closer look by ethnicity shows that 861% of White students have a computer at home compared to 75.5% of African-American students When asked “How often do you use a computer outside of school” (Question 4), 21.1% of students responded “Less than weekly” Less than weekly computer use is considered to be a drastically low level for 21st century learners. Comparing student ethnicity on this response shows little difference between White and African-American students but on the other end of the response scale there is a great difference. Overall, 40% of students responded they use a computer outside of a school on a daily basis: 39% of African-American and 55.6% of White students. These findings are partially validated by national census results, although the question was asked differently (U.S Department of Commerce, 2009) Families without home internet were asked why they did not have internet access. Select STAUS results are presented in
Table 2 and Figure 1 6 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Table 2: Student Technology Access and Use Survey, Select School Results Question 3: Students that have enough computer access to complete school assignments Question 5: Students that have enough computer access to complete school assignments outside of school Question 7: Students that have internet access at home AfricanAmerican 71.4% (n = 360) 65.1% (n = 330) 73.4% (n = 372) White 75.0% (n = 27) 55.6% (n = 20) 91.7% (n = 33) All Students 72.3% (n = 410) 64.9% (n = 370) 75.3% (n = 429) Ethnicity Figure 1: Student Technology Access Locations for School Survey results indicate a significant difference in internet access for students based on ethnicity. We found 91.7% of White students from the research school had internet access at home, compared to 73.4% of African-American; 183%
internet access gap Comparing this to national results from a few years prior shows a similar gap for all comparison groups (U.S Department of Commerce, 2009) For the high school subgroup, 93.2% of White students had internet access at home, compared to 770% of African-American; 16.2% internet access gap (see Figure 2) The similarity in results between the research school and national comparison group is striking. 7 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Percent African-American 100.0 95.0 90.0 85.0 80.0 75.0 70.0 65.0 60.0 55.0 50.0 White 78.6 73.4 School * 92.9 92.9 93.2 91.7 81.0 77.0 HS Only PreK - 12 All Persons Source: U.S Dept of Commerce 2009 and STAUS 2011* Figure 2: Internet Access by Ethnicity School Leader Interview Despite the challenges to technology access outside of school for some students, both survey results and the school
leader interview indicate high levels of technology integration during the school day. Ninety-nine percent of Hughes STEM High School students reported using technology most or every day, as compared with only 45% of the district-wide population. This is tempered by the fact that conversely, only 68% of students in the school use a computer outside of school, compared with 71.5% district-wide. This pervasiveness of technology partially accounts for what we describe as the technology access gap. The district student survey indicated that most students have better technology access at home than they do at school. However, students at the research school have 40% greater technology access at school than at home compared to the district average. This means that although the research school is far more successful in giving students access to technology during the school day, this has only exacerbated the lack of access outside of school. The administrator interview with the program
facilitator revealed that project-based learning is the foundation for the use of technology at the research school and the 21st Century Skills of critical thinking, communication, collaboration, and creativity are evident in the projects students participate in to demonstrate their learning to authentic audiences. In addition to traditional software packages like Microsoft Office and Adobe Design Premium Creative Suite, students use software as a service resources. For example, Wikispaces allows students to collaborate asynchronously and develop interdisciplinary presentations for a local museum. Students use Google SketchUp during the process of building and designing an ecologically green town for their STEM Foundations class project. Field science experiment toolkits contain digital cameras, Livescribe pens, and laptops in a single digital backpack and allow students to learn outside the school, collecting data and creating presentations in the field and with community partners. At
the end of their sophomore year, students must create a Gateway presentation in which they petition to enter into one of four career pathways for their junior and senior years. This presentation empowers students to creatively choose from any of dozens of digital presentation techniques they have learned in their curricular projects to advocate for their future. Based on Nevens’ technology adoption framework, the research school is clearly in the “target tech” 8 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 phase of adoption with both its wide range of technology tools as well as the seamless integration of technology through multidisciplinary, project-based learning. CONCLUSIONS In order to advance pedagogy, researchers need to provide educators with relevant information to help advance practice. It is important to obtain a complete picture of student
technology access by understanding how and where students access ICT away from school. Students can access computer technology in many locations outside of school, including home, relatives’ or friends’ computers, the public library, community centers, and virtually anywhere else they have access to the internet through smart devices (i.e “the cloud”) Increased access to technology in education is a double-edged sword, resulting in greater opportunities and advantages for those students with adequate resources to participate. As teacher expectations increase with the expansion of technology-based tools, the pressure on students to competently use these tools also increases. The pressure may even be greater for students that have limited access to technology. Knowing a student’s technology exposure at school provides limited information for understanding how students are exposed to technology in their everyday lives. Teachers have the power to close the technology access gap
by using assessment tools to understand the resource limitations of their students. Knowing their students beyond the classroom will enable teachers to adopt realistic expectations for technology access away from school and enable students to reach their potential. This case has identified a missing variable in educational research by describing technology use and access at a large urban STEM high school, and answered the principal research questions initially postulated. The Technology Access Gap (TAG) is relevant to any educator concerned with understanding the ICT limitations of their students and it can be used to improve pedagogy. Improvement is possible by educating teachers who need to know about the technology resource limitations of their students. Teachers are already familiar with the process and utility of making accommodations for students with disabilities. A similar practice could be followed for limited technology access students. In the 21st century learning
environment, learning options are required to meet the diverse needs of students, and this condition is extended to students having limited access to technology. Once the need for accommodations is established at the school level, the scope for accommodations can be broadened to the district level. Accommodation programs, such as free Wi-Fi and laptop check-out, and creative solutions such as flexible transportation to allow students to stay after school, are necessary to fill the gap so that educators provide equitable access to information and communication technologies. This is an important step towards opening the playing field for all 21st century learners. SUGGESTIONS FOR BEST PRACTICES In a high poverty urban school, it is difficult to overestimate the amount of effort that is necessary to support a modern, project-based STEM curriculum. Downes and Pogue (1994) document the additional costs associated with educating disadvantaged students, but even their analysis is based on a
traditional academic curriculum and not a STEM-focused one. Any STEM school needs to build equipment maintenance, repair, and replacement costs into its budget, as well as costs for subscriptions to internet-based software and services. Our survey suggests, however, that accommodations also need to be made for students lacking ICT access outside of school. Through partnerships with businesses and universities, grants or donations may be able to cover some of the costs of properly resourcing students. In order for schools to know what technology support and services are needed and by whom, some type of survey or assessment should be conducted. STAUS offers schools a tool to assess technology access and use at school and away from school, in addition to measuring integration of 21st 9 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 Century Skills. The school in this case
study provides high levels of technical support to both students and staff. This is critical to avoid frustration and encourage innovation The hiring process for staff at the research school included assessing prospective teachers’ comfort with adoption of technology and collaborative skills. Other STEM schools would do well to have similar hiring filters in place Write-in responses on STAUS indicated students’ frustration with not being able to take technology from school home with them. The initial cohort of students at the research school was told that part of the STEM program involved permission to take laptop computers home. Although the business community has been generous in providing the school with laptop and desktop computers, there is not yet a process in place for students to take equipment home. In order for a check-out program to be successful, efforts should be made to expand the existing partnership with a local university and tap into ICT resources such as
undergraduate assistants. Additional grants could cover the cost of developing and maintaining a check-out program for low-income students and upper class students from the research school could be trained for leadership positions to handle much of the program in-house. FUTURE WORK Although the implemented technology access survey produced the desired results, examination of the findings has still left us with an incomplete understanding of student’s technology access. Additional work is needed to understand in greater detail both the problems leading up to the lack of student technology access, and we need to learn more about teachers’ understanding of student technology access and how accommodations are being made to fill the gap. Semi-structured, qualitative interviews with students and teachers would help to create a richer description of technology access issues. From the perspective of the researchers, we would be able to more fully describe teacher implementation of
accommodations for students with limited access to technology. Currently, the school offers study tables after school three days a week, during which students have access to computer labs. Teachers also make individual agreements with students to increase their technology access in more creative ways. However, because the research school is openenrollment and students come from a large urban area, not all students can stay late due to transportation limitations. Still other students are unable to stay late because they have younger siblings to care for after school. The process of conducting interviews would serve to increase teacher awareness of student technology access issues. A clear extension of the current study is to explore the other constructs of the student technology survey which were not covered in this case study. Completing a validation study of the Student Technology Use and Access Survey (STAUS) would enhance educational technology practice by providing a validated
instrument for researchers’ use. In addition, defining the technology access gap as an educational metric would contribute to educational research by providing a standard measure for educators, allowing comparisons across schools and districts. Initial thoughts in this line of research include exploring ICT exposure scales and the fact that conceptually, the “gap” may be better understood in terms of a balance. 10 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 APPENDIX A - STAUS INSTRUMENT 11 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 12 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 13 University of Wisconsin-Stout
July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 14 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 APPENDIX B - ADMINISTRATOR SURVEY QUESTIONS Technology Access and Use at an Emerging Urban STEM High School Principal/Program Facilitator Interview Questions 1. How are students selected for this school? 2. What prerequisites are there for students attending this school? 3. How did this school acquire the technology that students use? 4. Describe the major pieces of hardware used on a regular basis by teachers and students 5. Describe the major software packages used on a regular basis by teachers and students 6. What 21st Century Skills does this school incorporate into the curriculum? 7. What support mechanisms are in place for students needing additional time or training with the
technology? 8. What is the documented poverty rate at your school? How does this impact instruction? 9. Describe your school’s connections to the statewide and/or national STEM networks of schools. 10. What are some of the major project-based learning (PBL) activities for students at your school which integrate technology? 15 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and Society Session 1-1 REFERENCES Becker, H. J 2000 Whos wired and whos not: Childrens access to and use of computer technology. The Future of Children, 10(2), 44-75 Carstens, R., Ed, & Pelgrum, W J 2009 Second information technology in education study: SITES 2006 technical report. Amdsterdam, NL: International Association for the Evaluation of Educational Achievement. Chisholm, I., Carey, J, & Hernandez, A 2002 Information technology skills for a pluralistic society: Is the playing field level? Journal of
Research on Technology in Education, 35(1), 58. Christensen, R., & Knezek, G 2008 Self-report measures and findings for information technology attitudes and competencies. In (pp 349-365) Boston, MA: Springer US doi:101007/978-0-38773315-9 21 Clifton, N. S 2006 An examination of home and school technology access and usage in relation to urban high school students and the achievement gap. Harvard University) Corn, J., Stallings, T, Stanhope, D, Townsend, M, Patel, R, Argueta, R, & Kleiman, G 2010 Governor Perdues North Carolina student learning conditions (SLCS); survey validation study - phase II. Raleigh: North Carolina State University DiMaggio, P., & Hargittai, E 2001 From the digital divide to digital inequality: Studying internet use as penetration increases. Princeton, NJ: Princeton University Center for Arts and Cultural Policy Studies. Downes, T., & Pogue, T 1994 Adjusting school aid formulas for the higher cost of educating disadvantaged students. National Tax
Journal, 47(1), 89-110 Frederick, R. & Shockley, K 2008 Culturally responsive uses of technology: A portrait of three teachers working in urban schools. Electronic Journal for the Integration of Technology in Education, 7(1), 3-21. Garland, V. E, & Wotton, S E 2002 Bridging the digital divide in public schools Journal of Educational Technology Systems, 30(2), 115-23. Hanover Research. 2011 K-12 STEM education overview Washington, DC: Hanover Research Knezek, G., & Christensen, R 2008 The importance of information technology attitudes and competencies in primary and secondary education. In International handbook of information technology in primary and secondary education (pp. 321-331) Boston, MA: Springer US doi:10.1007/978-0-387-73315-9 19 Nevens, T. M 2001 Fast lines at digital high IEEE Spectrum, 38(4), 16-17 doi:10.1109/MSPEC2001915196 Panhandle Area Education Consortium. 2011 Student technology survey http://www.paecorg/teacher2teacher/studentnetssurveyt2tpdf Phillis,
W. L 2005 Ohios school funding litigation saga: More money and some new buildings but the same unconstitutional school funding structure. Journal of Education Finance, 30(3), 313 Ringstaff, C., & Kelley, L 2002 The learning return on our educational technology investment: A review of findings from research. San Francisco, CA Roblyer, M., & Knezek, G 2003 New millennium research for educational technology: A call for a national research agenda. Journal of Research on Technology in Education, 36(1), 60 Sivin-Kachala, J., Bialo, E R, & Langford, J 1997 The effectiveness of technology in schools: 90-97 report. New York, NY: Software Publishers Association SPSS Statistics 19. 2011 Release Version 1900, SPSS, Inc, 2009, Chicago, IL, (available at: http://www.spsscom) TechTerms.com 2010 from http://wwwtechtermscom/definitions/ict 16 University of Wisconsin-Stout July 16-17, 2012 Source: http://www.doksinet 2012 ASQ Advancing the STEM Agenda in Education, the Workplace and
Society Session 1-1 Sersion, B. L, & Stevens, DM 2011 Student technology access and use survey (STAUS) http://www.zoomerangcom U. S Department of Commerce 2009 Current population survey Washington, DC: Census Bureau. U. S Department of Education 2006 Computer and internet use by students in 2003: Statistical analysis report. Washington, DC: National Center for Education Statistics U. S Department of Education 2010 Transforming american education: Learning powered by technology. national education technology plan, 2010 (No ED512681) U S Department of Education. U. S Department of Education 2011 Digital nation: Expanding internet usage Washington, D.C: National Telecommunications and Information Administration Walker, V. A 1997 The great technology divide: How urban schools lose The Education Digest, 62(6), 47. Warschauer, M. 2003 Technology and social inclusion: Rethinking the digital divide Cambridge, MA: MIT Press. Warschauer, M., & Matuchniak, T 2010 New technology and
digital worlds: Analyzing evidence of equity in access, use, and outcomes. Review of Research in Education, 34(1), 179-225 Yin, R. K 2009 Case study research: Design and methods Los Angeles, CA: Sage Publications AUTHORS INFORMATION Brian L. Sersion is a program evaluator and research analyst at Cincinnati Public Schools, Research and Evaluation Department. He holds a MS in Quantitative Analysis from the University of Cincinnati (1999) and BS in Geological Sciences from Ohio University (1988). Brian is an ASQ Certified Quality Engineer and his leadership in the Statistics Division has led to numerous awards from the Society. He can be contacted at: sersiob@cps-k12.org Douglas M. Stevens is a doctoral student at the University of Cincinnati in educational studies and teaches English and technology at Hughes STEM High School, part of Cincinnati Public Schools. His current research focuses on technology access and equity, student voice empowerment, and school organizational culture with
a focus on relational theory and teacher leadership. He can be contacted at: stevend@cps-k12.org 17 University of Wisconsin-Stout July 16-17, 2012
