Electronics Engineering Technology Assessment Report

Transcription

1 Electronics Engineering Technology Assessment Report Aaron Scher & Cristina Crespo Electrical Engineering & Renewable Energy Department 1

2 Contents 1 Introduction Program Location Program Goals and Design Program Brief History Program Mission, Educational Objectives, and Outcomes Program Mission Program Educational Objectives Relationship Between Program Educational Objectives and Institutional Objectives Program Outcomes Cycle of Assessment for Program Outcomes Introduction and Methodology Assessment Cycle Summary of Assessment Activities & Evidence of Student Learning Introduction Methodology for Assessment of Program Outcomes Targeted Assessment Activities Targeted Assessment for Outcome c: an ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes Targeted Assessment for Outcome f: an ability to identify, analyze, and solve broadly-defined engineering technology problems Targeted Assessment for Outcome g: an ability to apply written, oral, and graphical communication in both technical and non-technical environments; and an ability to identify and use appropriate technical literature Targeted Assessment for Outcome h: an ability to engage in independent learning and recognize the need for continual professional development Targeted Assessment for Outcome k: a commitment to quality, timeliness, and continuous improvement Targeted Assessment for Outcome m: the ability to apply project management techniques to electrical/electronic(s) systems Indirect Assessment Changes Resulting From Assessment Changes Resulting from the Assessment Changes to Assessment Methodology

3 1 Introduction 1.1 Program Location The Bachelor of Science in Electronics Engineering Technology (BSEET) is offered at the Oregon Tech Wilsonville Campus on the south side of the Portland metropolitan area. The campus is situated in a wooded business park setting among several technology companies including Mentor Graphics, Rockwell Collins, and Xerox. The campus is conveniently located off Interstate 5 and a short walk away from the Wilsonville Station on the Westside Express Service (WES) commuter rail line that connects to Beaverton and the MAX Light Rail. In addition, several of the core courses for the degree and technical electives are available at the Willow Creek Center (WCC) in the Portland Westside to better accommodate degree-seeking professionals working for high-tech companies in the Hillsboro and Beaverton area. The WCC is located in the heart of the high-tech industry cluster (Silicon Forest), minutes away from companies such as Intel, Tektronix, MAXIM, Credence, Lattice, Synopsis, TriQuint, and ESI. Some of the core courses and technical electives are also available online. 1.2 Program Goals and Design The program is designed to prepare graduates to assume engineering and technology positions in the electronics industry. Graduates of the Electronics Engineering Technology program fulfill a wide range of functions within industry. Bachelor s degree graduates are currently placed in positions such as component and system design, test engineering, product engineering, field engineering, manufacturing engineering, sales or market engineering, and quality control engineering. The program also provides a solid preparation for students intending to continue to graduate school to pursue master s degrees in engineering, engineering management, and M.B.A.s. Employers of Electronics Engineering Technology graduates include research and development laboratories, electronic equipment manufacturers, public utilities, colleges and universities, government agencies, medical laboratories and hospitals, electronic equipment distributors, semiconductor companies, and automated electronic controlled processing companies. Recent graduates have been employed at companies such as MAXIM, TriQuint, Tektronix, Biotronik, and Intel. The BSEET degree at Oregon Tech Wilsonville is especially suited for working professionals with an associate s degree in Electronics Engineering Technology, Microelectronics Technology, or equivalent coursework. Students entering the B.S. degree in Electronics Engineering Technology program by transfer are requested to contact the EET Program Director concerning transfer of technical coursework. Oregon Tech has articulation agreements with various community colleges throughout Oregon. Students transferring to Oregon Tech under an articulation agreement are encouraged to work with an Oregon tech advisor after completion of their first year in the was degree to ensure 2+2 transferability. 1.3 Program Brief History The BSEET program at Oregon Tech was first accredited by ABET in ABET accreditation visit took place in Fall The last 3

4 Oregon Institute of Technology has offered a Bachelor of Science in Electronics Engineering Technology (BSEET) degree since The BSEET program served a need in the state for many years and was a successful program, with high enrollment and graduate placement rates. Since the 1990 s industries needs began to shift more towards hiring graduates of full electrical engineering programs and the BSEET program started to experience significant enrollment declines. A department committee, in consultation with the Industry Advisory Board, recommended that the program change from EET to EE in Klamath Falls, but continue as the BSEET program at OIT-Portland to continue serving degree completion students and working professionals with AAS EET (and similar) degrees. Once the decision to discontinue the BSEET program from Klamath Falls was made, the BSEET program underwent a major revision in order to optimize it to address the needs of working professionals and transfer students at Oregon Tech-Portland. These revisions were approved by the Curriculum Planning Commission (CPC) in In 2011, a decision was made by the department, in consultation with the industry advisory board, to enhance the upper division EET curriculum by converting some of the EET courses to traditional EE courses with a strong lab component. This change was implemented to better achieve the program educational objectives of preparing graduates to assume diverse roles in the engineering and engineering technology fields, as well as improve their access to graduate education. These changes were approved by the Curriculum Planning Commission (CPC) in 2011 and implemented in the academic year. In Fall 2012 the Oregon Tech Wilsonville campus opened as a result of the consolidation of the university s four Portland metro area sites. The BSEET courses are offered at the Wilsonville campus, and they also continue to be offered at the Willow Creek Center (on the Westside), in order to accommodate professionals working in the high-tech industry cluster in the Beaverton/Hillsboro area. In Fall 2012, a partnership with Portland State University (PSU) was launched. This partnership, referred to as the Westside Partnership, provides a path for students to complete the BSEET program at Oregon Tech, and gain direct admission to PSU s MS Electrical and Computer Engineering program by meeting a set of specified requirements. The Westside Partnership addresses the need for the high-tech industry on the Westside to upgrade its talent, by providing a path for AAS EET graduates to obtain an ABET-accredited BS degree in EET from Oregon Tech, and BS graduates to obtain a MS ECE from PSU. Both the BS EET and MS ECE programs are co-located on the Westside, and offered in the evening so that they are easily accessible to working professionals in the Westside high-tech companies. Oregon Tech also has a partnership with University of Oregon (UO), whereby BSEET students have access to a 4+1 program. Under this partnership, students can complete a BSEET degree from Oregon Tech, followed by a 12-month (Summer through Spring) industrial master?s program at UO. The graduate program includes coursework and an internship component, and leads to a MS Applied Physics or Applied Chemistry from UO. The MS tracks in Semiconductor Processing and Optics have been the most popular with BSEET students, as they align well with the BSEET courses offered at Oregon Tech. The BSEET program has strong relationships with industry, particularly through its Industry Advisory Board and alumni from the EET program. These relationships allow to keep the BSEET program relevant and current, to make sure it continues to meet the needs of the industry in this field. 4

5 2 Program Mission, Educational Objectives, and Outcomes 2.1 Program Mission The mission of the EET Program is to provide a comprehensive program of instruction that will enable graduates to obtain the knowledge and skills necessary for immediate employment and continued advancement in the field of electronics. The department will be a leader in providing career ready candidates for various electronics technology fields. Faculty and students will engage in applied research in emerging technologies and provide professional services to their communities. 2.2 Program Educational Objectives Program educational objectives are broad statements that describe the career and professional accomplishments that the program is preparing graduates to achieve. The Program Educational Objectives of OIT s Bachelor of Science in Electronics Engineering Technology are: The graduates of the program will possess a strong technical background as well as analytical and problem solving skills, and will contribute in a variety of technical roles within the electronics and high-tech industry. Within three years of graduation, BSEET graduates are expected to be employed as test engineers, characterization engineers, applications engineers, field engineers, hardware engineers, process engineers, and similar engineering technology positions within this industry. The graduates of the program will be working as effective team members with excellent oral and written communication skills, assuming technical and managerial leadership roles throughout their career. The graduates of the program will be committed to professional development and lifelong learning by engaging in professional and/or graduate education in order to stay current in their field and achieve continued professional growth. 2.3 Relationship Between Program Educational Objectives and Institutional Objectives The BSEET PEOs map strongly to the mission and core themes for the university. Specifically, the program objective relating to strong technical background as well as analytical and problem solving skills is tightly linked to the mission of offering rigorous applied degree programs in a hands-on learning environment, focusing on application of theory to practice. 5

6 2.4 Program Outcomes The BSEET Program Outcomes include ABET s ETAC a k outcomes as well as the electronics specific l m outcomes. The ABET ETAC student outcomes were revised in the accreditation cycle. The revisions included slight rewording of ETAC outcomes a k and elimination of two of the program-specific outcomes. The BSEET program adopted the new ABET student outcomes in the academic year. These are listed below: a an ability to select and apply the knowledge, techniques, skills, and modern tools of the discipline to broadly-defined engineering technology activities. b an ability to select and apply a knowledge of mathematics, science, engineering, and technology to engineering technology problems that require the application of principles and applied procedures or methodologies. c an ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes. d an ability to design systems, components, or processes for broadly-defined engineering technology problems appropriate to program educational objectives. e an ability to function effectively as a member or leader on a technical team. f an ability to identify, analyze, and solve broadly-defined engineering technology problems. g an ability to apply written, oral, and graphical communication in both technical and non-technical environments; and an ability to identify and use appropriate technical literature. h an understanding of the need for and an ability to engage in self-directed continuing professional development. i an understanding of and a commitment to address professional and ethical responsibilities including a respect for diversity. j a knowledge of the impact of engineering technology solutions in a societal and global context. k a commitment to quality, timeliness, and continuous improvement. l the ability to analyze, design, and implement control systems, instrumentation systems, communications systems, computer systems, or power systems. m the ability to apply project management techniques to electrical/electronic(s) systems. n the ability to utilize statistics/probability, transform methods, discrete mathematics, or applied differential equations in support of electrical/electronic(s) systems. 6

7 3 Cycle of Assessment for Program Outcomes 3.1 Introduction and Methodology Assessment of the program outcomes is conducted over a three year-cycle. Table 1 shows the outcomes assessed during each academic year. During the 2007/08 academic year almost all the outcomes were assessed in order to establish a baseline. Note that the student outcomes were revised in the academic year. For years prior to , assessed outcomes a k refer to the old version of these outcomes, and l n refer to the old outcomes n o (since old outcomes l, m have been eliminated as being contained in new outcomes (a), (b), (d), and (l), and being therefore redundant). 3.2 Assessment Cycle Table 1: BSEET Outcome Assessment Cycle Outcome 2008/9 2009/ / / / /14 a. Fundamentals b. Application c. Experimentation d. Design e. Teamwork f. Problem Solving g. Communication h. Lifelong Learning i. Eithics j. Impact k. Continuous Improvement l. Electronic Systems m. Project Management n. Advanced Mathematics 7

8 3.3 Summary of Assessment Activities & Evidence of Student Learning Introduction The Electronics Engineering Technology faculty members conducted formal assessment of four Student Outcomes during the academic year using direct measures such as course projects and assignments. Additionally, indirect assessment of Student Outcomes a n was conducted through a senior exit survey Methodology for Assessment of Program Outcomes At the beginning of the assessment cycle, an assessment plan is generated by the Assessment Coordinator in consultation with the faculty. This plan includes the outcomes to be assessed during that assessment cycle (according to table 1), as well as the courses and terms where these outcomes will be assessed. The BSEET mapping process links specific tasks within BSEET course projects and assignments to ABET program outcomes and on to program educational objectives in a systematic way. The program outcomes are evaluated as part of the course curriculum primarily by means of ABET assignments 1. The ABET assignments are then assessed based on ABET rubrics 2. These ABET assignments typically involve a short project or lab requiring the student to apply math, science, and engineering principles learned in the course to solve a particular problem requiring the use of modern CAD tools and engineering equipment, working in teams, writing a project report, and giving an oral presentation. The mapping process aims to systemize the assessment of engineering coursework, and to provide a mechanism that facilitates the design of engineering assignments that meet the ABET-relevant ( a through n ) outcomes, particularly those that are more distant from traditional engineering coursework. Rather than considering how the outcomes match the assignment, the assignment is designed to map to the program outcomes. A systematic, rubric-based process is then used to quickly assess the level of attainment of a given program outcome, based on a set of performance criteria. The work produced by each student is evaluated according to the different performance criteria, and assigned a level of 1-developing, 2-accomplished, or 3-exemplary. The results for each outcome are then summarized in a table, and reviewed by the faculty at the annual Closing-the-Loop meeting. The acceptable performance level is to have at least 80% of the students obtain a level of accomplished or exemplary in each of the performance criteria for any given program outcome. If any of the direct assessment methods reflects a performance below the established level, that triggers the continuous improvement process, where all the direct and indirect assessment measures associated with that outcome are evaluated by the faculty, and based on the evidence, the faculty decides the adequate course of action. The possible courses of action are: Collect more data (if there is insufficient data to reach a conclusion as to whether the outcome is being attained or not); this may be the appropriate course of action when 1 ABET assignments refer to assignments specifically designed to measure program-level outcomes 2 ABET rubrics refer to rubrics especially designed by Oregon Tech BSEET faculty to assess ABET assignments based on program-level outcomes. 8

9 assessment was conducted on a class with low enrollment, and it is recommendable to re-assess the outcome on the following year, even if it is out-of-cycle, in order to obtain more data. Make changes to the assessment methodology (if the faculty believe that missing the performance target on a specific outcome may be a result of the way the assessment is being conducted, and a more proper assessment methodology may lead to more accurate numbers); for example, this could be the suggested course of action if an outcome was assessed in a lower-level course, and the faculty decide that the outcome should be assessed in a higher-level course before determining whether curriculum changes are truly needed. Implement changes to the curriculum (if the faculty conclude that a curriculum change is needed to improve attainment of a particular outcome). A curriculum change will be the course of action taken when the performance on a given outcome is below the target level, and the evidence indicates that there is sufficient data and an adequate assessment methodology already in place, and therefore there is no reason to question the results obtained. If the faculty decide to take this last course of action and implement curriculum changes, the data from the direct assessments is analyzed and the faculty come up with a plan for continuous improvement, which specifies what changes will be implemented to the curriculum to improve outcome performance. In addition to direct assessment measures, indirect assessment of the student outcomes is performed on an annual basis through a senior exit survey. The results of the direct and indirect assessment, as well as the conclusions of the faculty discussion at the Closing-the-Loop meeting are included in the annual BSEET Assessment Report, which is reviewed by the Department Chair and the Director of Assessment for the university. The suggested changes to the curriculum are presented and discussed with all the department faculty at the annual Convocation meeting in Fall, as well as with the Industry Advisory Board at the following IAB meeting. If approved, these changes are implemented in the curriculum and submitted to the University Curriculum Planning Commission (if catalog changes are required) for the following academic year Targeted Assessment Activities The sections below describe the targeted assessment activities and detail the performance of students for each of the assessed outcomes. The tables report the number of students performing at a developing level, accomplished level, and exemplary level for each performance criteria, as well as the percentage of students performing at an accomplished level or above. 9

10 3.3.4 Targeted Assessment for Outcome c: an ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes. This outcome was assessed in EE320 - Advanced Circuits and Systems in Fall 2013 by means of a project, which involved the design, simulation, implementation, and validation of a 1KHz oscillator. The project required designing and measuring the performance of a square wave oscillator for generating a square wave and analog filters for converting the square wave into a sinusoid. Design constraints were imposed to encourage an efficient design (in terms of power efficiency, active component count, and size). The students experimentally measured delivered DC power and various voltages in the circuit in both time and frequency domains. The students were asked to analyze and interpret their results, calculate DC-to-signal efficiency, and explain ways to improve their design/measurement process based upon their experience with the project. Upon successful implementation of their design and experiment, students were required to submit their report in the form a PowerPoint presentation. A total of eighteen students were assessed in Fall 2013 using the performance criteria listed in the table below. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. The results indicate that the minimum acceptable performance level of 80% was not met on two of the three performance criteria for this program outcome; namely, the percentage of students who reached an accomplished level for criteria 2 (analyze/interpret) and 3 (improve) was 77.8% and 77.8%, respectively. Ideas on how to improve performance in these areas were discussed at the annual closing-the-loop meeting, and are presented in section 4. Table 2: Targeted Assessment for Outcome c: 1) Criterion 1-an ability to conduct experiments, 2) Criterion 2-an ability to analyze and interpret experimental results, and 3) Criterion 3-an ability to apply experimental results to improve processes. Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Conduct % 2 - Analyze/Interpret % 3 - Improve % 10

11 3.3.5 Targeted Assessment for Outcome f: an ability to identify, analyze, and solve broadly-defined engineering technology problems. This outcome was assessed in EE321 - Electronics I in Fall 2013 by means of a project. The project consisted of designing, simulating, implementing, and experimentally testing an AC to DC power supply and linear regulator with current boosting to provide an adjustable regulated output voltage with short circuit/overload protection. Students were provided with a series of design specifications and design constraints. Students were expected to select an initial topology within the given constraints, identify the limitations of this topology and work on improving the design through an iterative process of analyzing and solving technical problems until the given specifications were met. Once the design was finalized and the simulations indicated the results were met, students were required to physically implement their designs and experimentally test them. This additional step was intended to get students to identify, analyze, and solve an additional set of technical problems related to implementation and measurement of electronic designs. Finally, the students were required to write a complete report following the guidelines of the IEEE Transactions Journals (IEEE Transactions Publication-Ready Template and Instructions for Authors). Eleven students were assessed in Fall 2013 using the performance criteria listed in the table below. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. Table 3 summarizes the results of this targeted assessment. The results indicate that the minimum acceptable performance level of 80% was met on all performance criteria for this program outcome, that is, over 80% of students were able to identify, analyze, and solve technical problems. Hands-on laboratory skills are definitely a strength of the students in the BSEET program. This may be due to the strong emphasis placed on laboratory instruction and practical projects as part of most courses in the curriculum, as well as the fact that many of the students in the program are working professionals with experience as technicians, who are typically required to identify and solve technical problems as part of their job responsibilities. Table 3: Targeted Assessment for Outcome f: 1) Criterion 1-an ability to identify, 2) Criterion 2- an ability to analyze, and 3) Criterion 3-an ability to solve broadly-defined engineering technology problems. Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Identify % 2 - Analyze % 3 - Solve % 11

12 3.3.6 Targeted Assessment for Outcome g: an ability to apply written, oral, and graphical communication in both technical and non-technical environments; and an ability to identify and use appropriate technical literature. This outcome was assessed in the ENGR465 - Capstone Project, in Spring The Capstone Project is a year-long (three-term) project that students complete in their senior year, which involves a major design experience. Throughout the year, students are required to complete the definition, design, implementation, and verification of a major engineering design project. During the initial stage, students work under the supervision of their capstone project advisor to select a project of adequate scope, and submit a project proposal. The proposal typically includes an explanation of the project relevance, a project definition or specification, a timeline with major milestones, a list of resources needed to complete the project, and a projected cost analysis. Once the proposal is approved by the academic advisor, students go through the different phases of design, implementation, and verification of their project. During this time, students have regular meetings with their project advisor in order to report progress, notify of plan changes if needed, present results, and perform prototype demonstrations. Once the design, implementation, and verification process is completed, and there is a final working prototype, students are required to generate a poster for inclusion in the annual Student Project Symposium, deliver an oral presentation, and submit a formal written report. These three deliverables are used to determine the students ability to communicate according to the performance criteria listed in table 4. Eighteen students were assessed in Spring 2013, using the performance criteria listed in the table below. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. Table 4 summarizes the results of this targeted assessment. The results indicate that the minimum acceptable performance level of 80% was not met on three of the five performance criteria for this program outcome; namely, the percentage of students who reached an accomplished level for criteria 1 (written), 2 (literature), and 5 (audience), was 77.8%, 77.8%, and 72.2%, respectively. Ideas on how to improve performance in these areas were discussed at the annual closing-the-loop meeting, and are presented in section 4. Table 4: Targeted Assessment for Outcome g: 1) Criterion 1- an ability to apply written communication, 2) Criterion 2-an ability to apply oral communication, 3) Criterion 3-an ability to apply graphical communication 4) Criterion 4 - an ability to identify and use appropriate technical literature, and 5) Criterion 5 - an ability to communicate with technical and nontechnical audiences. Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Written % 2 - Oral % 3 - Graphical % 4 - Literature/Resources % 5 - Audience % 12

13 3.3.7 Targeted Assessment for Outcome h: an ability to engage in independent learning and recognize the need for continual professional development. This outcome was assessed in EE430 - Digital Signal Processing in Winter 2014 by requiring students to write an essay explaining the importance of independent learning, how they plan on staying current in their field and industry through independent learning, and how this relates to the need for continual professional development. A total of fifteen students were assessed. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. Table 5 summarizes the results of this targeted assessment, and corresponding criteria used for the assessment. The results indicate that the acceptable performance level was reached in all of the performance criteria. This suggests most students in the program have the ability to engage in independent learning and recognize the need for continual professional development. Table 5: Targeted Assessment for Outcome h: 1) Criterion 1- an ability to engage in independent learning, and 2) recognize the need for continual professional development Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Ability % 2 - Recognition % 13

14 3.3.8 Targeted Assessment for Outcome k: a commitment to quality, timeliness, and continuous improvement. This outcome was assessed in EE323 - Electronics II in Winter 2014 through a design project. The project involved the design of an operational amplifier at the transistor level using BJT and MOSFET transistors. The project was broken into three different stages, each one corresponding to a laboratory assignment for the course, to guide students through the design process, and provide an opportunity for students to get feedback through the quarter regarding their designs. Students were required to complete and submit each of the lab assignments by the deadline, as well as generate a final report by the end of the quarter describing and characterizing their design. The final report was to be submitted following the guidelines of the IEEE Transactions Journals (IEEE Transactions Publication-Ready Template and Instructions for Authors). The students commitment to quality, timeliness, and continuous improvement was measured by the quality of the final design, the timely submission of the lab assignments and final report, and the willingness of the students to use the feedback received through the term to make improvements to their design. A total of fourteen students were assessed in Winter 2014, using the performance criteria listed in the table below. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. Table 6 summarizes the assessment results. The results indicate that the minimum acceptable performance level of 80% was met on all performance criteria, except for performance criterion 1 - a commitment to quality, where only 78.6% of the students achieved a level of accomplished or exemplary. Ideas on how to improve performance in this area were discussed at the annual closing-the-loop meeting, and are presented in section 4. Table 6: Targeted Assessment for Outcome k: 1) Criterion 1 - commitment to quality, 2) Criterion 2 - commitment to timeliness, and 3) - commitment to continuous improvement. Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Quality % 2 - Timeliness % 3 - Cont. Improvement % 14

15 3.3.9 Targeted Assessment for Outcome m: the ability to apply project management techniques to electrical/electronic(s) systems. This outcome was assessed in the ENGR465 - Capstone Project in Spring As previously mentioned, the Capstone Project sequence is a three-term sequence that students take in their senior year, which involves the completion of a major engineering design project. The goal is to have students go through a normal design cycle, which in- cludes project definition, design, implementation, verification, and documentation. Good project management skills are essential to the successful completion of the senior capstone project. For this reason, emphasis is placed during the initial stages in project planning. Students work with their project advisor to generate a project proposal. As explained previously, in their proposal students must demonstrate that they have specific goals (a project definition or specification), as well as an execution plan which takes into account time and resource management. After the proposal has been approved by the project advisor, students start working on their project, periodically meeting with their advisor to report progress. During these meetings, students must demonstrate their ability to execute according to plan. Students are also expected to be able to dynamically adapt the project plan and timeline as needed, and properly justify and document if and when changes need to happen to the specification or timeline. Eighteen students were assessed in the ENGR465 - Capstone Project sequence in Spring 2013 using the performance criteria listed in the table below. The minimum acceptable performance level was to have above 80% of the students performing at the accomplished or exemplary level in all performance criteria. The results indicate that the acceptable performance level was reached in all of the performance criteria, with the exception of criterion 2 (ability to manage the design flow), where the percentage of students who reached an accomplished level was 77.8%. These results suggest that most students in the program are effective at applying project management techniques to electrical/electronic(s) systems. One area where the results suggest improvement is needed is the ability of students to use management tools such as Gantt charts and network diagrams. Ideas on how to improve performance in this area were discussed at the annual closing-the-loop meeting, and are presented in section 4. Table 7: Targeted Assessment for Outcome m: 1) Criterion 1-an ability to apply project management techniques, 2) Criterion 2- an ability to manage design flow, and 3) Criterion 3-an ability to document and present designs. Performance Criteria 1-Developing 2-Accomplished 3-Exemplary % Students Apply % 2 - Manage % 3 - Document % 15

16 Indirect Assessment In addition to direct assessment measures, the student outcomes a n were indirectly assessed through a senior exit survey. Question 16 in the survey asked students Below are the ABET student outcomes for the BS EET program. Please indicate how well the EET program prepared you in each of the following areas. Figures 1 and 2 show the results of the indirect assessment of the BSEET student outcomes for the graduating class. Seven BSEET graduating seniors completed the survey, with 80 % or more of the respondents indicating that as a result of completing the BSEET program they feel prepared or highly prepared in each of the student outcomes, except for outcome (m) Project Management, where 2 out of the 7 respondents (29%) felt inadequately prepared. These results suggest that a high proportion of the BSEET graduating students feels they have attained the BSEET student outcomes. Student Outcome (m) was discussed at the Closing-the- Loop meeting. Based on a comparison between the results from the direct and the indirect assessment, the BSEET faculty made some recommendations for changes in order to boost the level of attainment of this outcome. These recommendations are presented in section 4.1. Figure 1: Graph of results of the indirect assessment for the BSEET Student Outcomes as reported in the Senior Exit Survey (AY ). 16

17 Question a. An ability to select and apply the knowledge, techniques, skills, and modern tools of the discipline to broadly-defined engineering technology activities. b. An ability to select and apply a knowledge of mathematics, science, engineering, and technology to engineering technology problems that require the application of principles and applied procedures or methodologies. c. An ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes. d. An ability to design systems, components, or processes for broadly-defined engineering technology problems appropriate to program educational objectives. e. An ability to function effectively as a member or leader on a technical team. f. An ability to identify, analyze, and solve broadly-defined engineering technology problems. g. An ability to apply written, oral, and graphical communication in both technical and non-technical environments; and an ability to identify and use appropriate technical literature. h. An understanding of the need for and an ability to engage in self-directed continuing professional development. i. An understanding of and a commitment to address professional and ethical responsibilities including a respect for diversity. j. A knowledge of the impact of engineering technology solutions in a societal and global context. k. A commitment to quality, timeliness, and continuous improvement. l. The ability to analyze, design, and implement control systems, instrumentation systems, communications systems, computer systems, or power systems. m. The ability to apply project management techniques to electrical/electronic(s) systems. n. The ability to utilize statistics/probability, transform methods, discrete mathematics, or applied differential equations in support of electrical/electronic(s) systems. Inadequately prepared Prepared Highly prepared Figure 2: Table of results of the indirect assessment for the BSEET Student Outcomes as reported in the Senior Exit Survey (AY ). 17

18 4 Changes Resulting From Assessment This section describes the changes resulting from the assessment activities carried out during the year It includes any changes that have been implemented based on assessment in previous assessment cycles, from this or last year, as well as considerations for the next assessment cycle. The BSEET faculty met on May 20, 2013 to review the assessment results and determine whether any changes are needed to the BSEET curriculum or assessment methodology based on the results presented in this document. The objective set by the BSEET faculty was to have at least 80% of the students perform at the level of accomplished or exemplary in all performance criteria of the assessed outcomes. Table 8 provides a summary of the assessment results for the outcomes which were directly assessed. Table 8: Summary of BSEET direct assessment for AY Performance criteria where % Students 2 is less than 80% appear in bold. Total Students Students 2 % Students 2 c - Experimentation 1 - Conduct % 2 - Analyze/Interpret % 3 - Improve % f - Problem Solving 1 - Identify % 2 - Analyze % 3 - Solve % g - Communication 1 - Written % 2 - Oral % 3 - Graphical % 4 - Literature/Resources % 5 - Audience % h-lifelong Learning 1 - Ability % 2 - Recognition % k - Continuous Improvement 1 - Quality % 2 - Timeliness % 3 - Cont. Improvement % m - Project Management 1 - Apply % 2 - Manage % 3 - Document % 18

19 4.1 Changes Resulting from the Assessment The results of the Assessment indicate that the minimum acceptable performance level of 80% was not met on all performance criteria for all assessed outcomes. Areas of improvement to the curriculum were discussed during the Closing the Loop Meeting in May 2014 with respect to these results. These areas include: Outcome c (Experimentation): Results: The results obtained are consistent with those obtained the last time this outcome was assessed in the assessment cycle. The results in two of the performance criteria are slightly below the 80% threshold. However, the faculty noted that the results were close to the threshold, and that the resolution of these measurements is affected by the low sample size (i.e., a single measurement moving from the 1 to the 2 category would have yielded a result above the threshold). The faculty also noted that this outcome was evaluated in a different course in the assessment cycle (EE323, as opposed to EE320). Recommendation: The faculty concluded that no specific changes to the curriculum are needed at this point, but recommended reviewing the assessment methodology to identify ways to improve resolution of assessment results, as well as increase the consistency of the courses and assignments used for assessment of a given outcome, so that comparisons to previous assessment cycles can be more meaningful. The changes proposed to the assessment methodology are listed in section 4.2. Outcome f (Problem Solving): Results: The results show that the threshold of attainment of this outcome was exceeded in all performance criteria. These results are consistent with those obtained the last time this outcome was assessed in the assessment cycle. Recommendation: The faculty identified no problem with this outcome, and therefore recommended no changes at this time. Outcome g (Communication): Results: The results on this outcome are slightly below the threshold in three out of the five performance criteria. These results are somewhat consistent with those obtained the last two times this outcome was assessed (in the and assessment cycles, respectively), even though a good comparison is difficult due to the changes in the wording of this outcome (due to the ABET ETAC outcome revisions), which led to a corresponding update of the performance criteria. Some changes to the BSEET curriculum were implemented as a result of the assessment activity from the and assessment cycles, which included adding oral presentation and written report requirements to at least half of the courses in the upper division of the BSEET curriculum. Even though the faculty agreed that the 19

20 implementation of these recommendations has had a positive impact in the communication skills of the BSEET student population, there was a consensus that further improvement is needed in this area, since it is an area of particular relevance, based on the input received from the Industry Advisory Board, as well as employers and alumni. Recommendation: The faculty agreed that the requirements for oral presentations and written reports in the BSEET curriculum are sufficient to allow students to develop an adequate level of proficiency, but students should be able to get more feedback and an opportunity to improve their reports/presentations based on the feedback received. With respect to criterion 1 (written communication), students are already assigned multiple graded written reports throughout the curriculum to allow them to progressively improve their technical writing skills. In the future, students will be encouraged to use the free writing tutors, so that they can get early feedback beyond that provided by the course instructor, and they get a chance to improve their written assignments before they are submitted for grading. It will be emphasized that final drafts of reports should be written with enough time to allow students to go through the process of review with a writing tutor before final submission. With regards to criterion 4 (literature), faculty noted that free seminars on how to use the library, how to adequately cite sources, etc. are provided by the Library periodically. To foster improvement in this area, the BSEET faculty will consult with the Library for a schedule of seminars, and BSEET students will be encouraged to attend seminars that are relevant to this performance criteria. To foster improvement in criterion 5 (audience), students will be encouraged to participate in and attend technical talks, presentations, and seminars in nontechnical environments. There are multiple events like this on campus that students can participate in. Information regarding such events will be included in the syllabi of relevant courses so that students know of their availability. Outcome f (Lifelong Learning): Results: The results show that the threshold of attainment of this outcome was exceeded in all performance criteria. These results are consistent with those obtained the last time this outcome was assessed in the assessment cycle. Recommendation: The faculty identified no problem with this outcome, and therefore recommended no changes at this time. Outcome k (Continuous Improvement): Results: The results are consistent with those obtained the last time this outcome was assessed in the assessment cycle. The results in one of the performance 20

21 criteria are slightly below the 80% threshold. As with outcome c, the faculty noted that this could be a result of low resolution noise (i.e., a single measurement causing the result to fall below threshold). Likewise, the faculty noted that this outcome was evaluated in a different course in the assessment cycle (ENGR266, as opposed to EE323), which makes it difficult to identify any kind of trend in the results. Recommendation: The faculty concluded that no specific changes to the curriculum are needed at this point, but recommended reviewing the assessment methodology to identify ways to improve resolution of assessment results, as well as increase the consistency of the courses and assignments used for assessment of a given outcome, so that comparisons to previous assessment cycles can be more meaningful. The changes proposed to the assessment methodology are listed in section 4.2. Outcome m (Project Management): Results:: These results are somewhat consistent with those obtained the last time this outcome was assessed (in the assessment cycle). The results indicate that the acceptable performance level was reached in all of the performance criteria, with the exception of criterion 2 (ability to manage the design flow), where the percentage of students who reached an accomplished level was slightly below 80%. Recommendation: The results in criterion 2 are close to the threshold, but faculty agreed that some improvement is needed in this area, specially since this is the outcome that received the lowest rating in the indirect assessment as well. In order to improve the ability to manage the design flow, students will be encouraged to practice good time management skills by incorporating project management techniques and design flow management in courses earlier in the curriculum, so that students are exposed to these methods before the Capstone Project. This will be performed in courses that have a substantial project. 4.2 Changes to Assessment Methodology This section describes changes to the assessment methodology that were proposed in the assessment cycle for implementation in the assessment cycle. An Assessment Coordinators Meeting was held in February At this meeting, Assessment Coordinators from each program within the EERE Department aligned their assessment cycles so that each program assesses similar outcomes on the same years. The Assessment Coordinators also worked with the corresponding program faculty to generate a mapping of the program outcomes to the courses where assessment will be conducted for each outcome. As a result of this meeting, assessment of the student outcomes will still be conducted over a three year-cycle, but in a slightly different order compared to the previous cycle. Table 9 shows the outcomes assessed during each assessment cycle starting with the 2014/2015 assessment cycle. The intention for this change is to better organize the assessment process and produce more meaningful data for comparison between different programs in the EERE Department. 21

22 In order to better measure trends, the faculty also decided this year to standardize the process so that each student outcome is sampled at the same point in the curriculum using a similar assignment from one assessment cycle to the next. Table 10 maps the BSEET Student Outcomes assessed each year within the assessment cycle to the corresponding courses where assessment for the specific Student Outcome is performed. This map reflects a decision by the faculty to assess outcomes a g and l n in two different courses in the same assessment cycle (i.e., two direct measurements per outcome). These courses were chosen to correspond to different points in the curriculum in order to also provide an idea of progress made in these outcomes as students progress through the program. For outcomes h k, the faculty decided that a single measurement was most adequate. The reason for this is that these outcomes are less related to the specific BSEET curriculum, but are rather broader outcomes, and multiple measurements would require the use of substantially equivalent assignments. Table 9: BSEET Outcome Assessment Cycle effective 2014/2015 Outcome Year 1 (2014/15) Year 2(2015/16 Year 3 (2016/17) a. Fundamentals b. Application c. Experimentation d. Design e. Teamwork f. Problem Solving g. Communication h. Lifelong Learning i. Eithics j. Impact k. Continuous Improvement l. Electronic Systems m. Project Management n. Advanced Mathematics 22