The Bachelor of Science in Mechatronic Engineering

Mechatronic Engineering is a new discipline that combines many of the skills of a mechanical engineer with those of a computer engineer and an electrical engineer. The mechatronic engineering graduate is prepared to design "intelligent" products such as cars that drive themselves, laser printers, self-assembling machines and robots.

The Mechatronic Engineering program is accredited by the Engineering Accreditation Commission (EAC) of the ABET, http://www.abet.org.

Mechatronic Engineering Program Mission

The mechatronic engineering program has the primary mission of providing students a high-quality undergraduate engineering education with:

• A curriculum that is firmly grounded in engineering fundamentals.
• A faculty that provides superior teaching and mentoring both in and out of the classroom.
• A faculty whose focus is undergraduate education.
• Class sizes that encourage student participation.
• Project experiences that build on fundamentals and develop team skills.
• Facilities and equipment that are readily accessible.
• An environment that is conducive to learning and encourages students from different genders and backgrounds.

The faculty is committed to offering a broad undergraduate experience that will promote professional growth and prepare students for a variety of engineering careers, graduate studies, and continuing education

Mechatronic Engineering Program Educational Objectives

The Mechatronic Engineering Program’s Educational Objectives are goals for its graduates to achieve a few years after graduation. Mechatronic engineering graduates will be prepared to:

• Practice in engineering-related fields chosen from a broad range of industries.
• Recognize the need and have the ability to engage in continuing learning to adapt to evolving professions and to advance professionally.
• Become contributing members of the society with an understanding of the inherent and unavoidable impact of practicing engineering.

Mechatronic Engineering Program Outcomes

Program outcomes are narrower statements that describe what students are expected to know and be able to do by the time of graduation. Mechatronic Engineering Program graduates must demonstrate the following:

1. An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
2. An ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors.
3. An ability to communicate effectively with a range of audiences.
4. An ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts.
5. An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
6. An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
7. An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Mechatronic Engineering Design Experience

The design experience for mechatronic engineers is integrated throughout the curriculum. The courses which include design experiences are:

CSCI 111 - Programming and Algorithms I

EECE 144 - Logic Design Fundamentals

EECE 315 - Electronics I

EECE 237 - Embedded Systems Development

EECE 344 - Digital Systems Design

MECA 140 - Introduction to Engineering Design and Automation

MECA 440AW- Capstone Design Project I

MECA 440B- Capstone Design II

MECH 340 - Mechanical Engineering Design

At the freshman level, students learn about the design process and are introduced to designing automated systems in MECA 140 and logic networks are designed in EECE 144. At the sophomore level, software design experience teaches students to think logically in developing efficient, structured computer programs in CSCI 111. At the junior level, there is an opportunity to learn about safety, failure, reliability, codes and standards, and economic considerations, while carrying out detailed design of mechanical components in MECH 340, and electrical circuits and systems in EECE 237, EECE 315, and EECE 344. In the final senior project (MECA 440AW and MECA 440B), students are expected to exercise what they learned throughout the preceding design courses in a final project that includes assembly and testing, as well as the more global aspects of design including product realization, economic factors, environmental issues, and social impact. Together, these experiences prepare graduates to be successful practitioners with an awareness of the multitude of issues involved.

Total Course Requirements for the Bachelor's Degree: 128 units

See Bachelor's Degree Requirements in the University Catalog for complete details on general degree requirements. A minimum of 39 units, including those required for the major, must be upper division.

A suggested Major Academic Plan (MAP) has been prepared to help students meet all graduation requirements within four years. You can view MAPs on the Major Academic Plans page or you can request a plan from your major advisor.

Courses in this program may complete more than one graduation requirement.

General Education Pathway Requirements: 48 units

See General Education in the University Catalog and the Class Schedule for the most current information on General Education Pathway Requirements and course offerings.

This major has approved GE modification(s). See below for information on how to apply these modification(s).

• Take CMST 131 or CMST 132 for Oral Communication (A1)
• Critical Thinking (A3) is waived.
• Take only one course in either Arts (C1) or Humanities (C2). The other is waived.
• MECH 340 is an approved major course substitution for either Individual and Society (D1) or Societal Institutions (D2). You must complete one additional D1 or D2 course.
• MECA 440B is an approved major course substitution for Learning for Life (E).
• EECE 311 fulfills Upper-Division Natural Sciences.

Diversity Course Requirements: 6 units

See Diversity Requirements in the University Catalog. Most courses taken to satisfy these requirements may also apply to General Education .

Both courses must also satisfy one of the General Education Requirements in order for 127 units to fulfill all requirements for the Mechatronic Engineering degree.

Upper-Division Writing Requirement:

Writing Across the Curriculum (Executive Memorandum 17-009) is a graduation requirement and may be demonstrated through satisfactory completion of four Writing (W) courses, two of which are designated by the major department. See Mathematics/Quantitative Reasoning and Writing Requirements in the University Catalog for more details on the four courses.  The first of the major designated Writing (W) courses is listed below.

• Any upper-division GE Writing Course (W).

The second major-designated Writing course is the Graduation Writing Assessment Requirement (GW) (Executive Order 665). Students must earn a C- or higher to receive GW credit. The GE Written Communication (A2) requirement must be completed before a student is permitted to register for a GW course.

Grading Requirement:

All courses taken to fulfill major course requirements must be taken for a letter grade except those courses specified by the department as Credit/No Credit grading only.

A grade of C- or higher is required in MECH 340.

Enrollment in any mathematics course requires a grade of C- or higher in all prerequisite courses or their transfer equivalents.

Course Requirements for the Major: 101 units

Completion of the following courses, or their approved transfer equivalents, is required of all candidates for this degree.

Enrollment in any mathematics course requires a grade of C- or higher in all prerequisite courses or their transfer equivalents.

Lower-Division Requirements: 59 units

20 courses required:

Upper-Division Requirements: 42 units

11 courses required:

3 units selected from:

SUBJ NUM	Title	Sustainable	Units	Semester Offered	Course Flags
CIVL 302W	Engineering Sustainability and Economic Analysis (W)		3.0	FS	W
Prerequisites: MATH 121, junior standing. This course provides a foundation for green engineering design through life cycle assessment and life cycle cost analysis considering economically viable, socially just, and environmentally sustainable solutions (triple bottom line). This course teaches quantitative environmental and economic assessment tools. decision-making strategies, risk, sensitivity analysis, and uncertainty analysis. These skills are applied to real-world problems through group projects, emphasizing applied engineering, critical thinking, communication skills and teamwork. 3 hours discussion. This is an approved Writing Course. This course requires the use of a laptop computer and appropriate software. (001495)
CIVL 313	Structural Mechanics		3.0	FS
Prerequisites: Prerequisites: CIVL 311 with a grade of C- or higher; MECH 208 (may be taken concurrently). Fundamentals of structural analysis for beams, trusses, and frames. Topics include loading (including seismic), influence lines, approximate analysis methods, deflection analysis, and statically indeterminate structures. Methods applicable to computer analysis are introduced. 3 hours discussion. This course requires the use of a laptop computer and appropriate software. (001499)
CIVL 321	Fluid Mechanics		4.0	FS
Prerequisites: CIVL 211 with a grade of C- or higher. Recommended: MATH 260, MECH 320 (may be taken concurrently). Hydrostatics, principles of continuity, work-energy and momentum, viscous effects, dimensional analysis and similitude, flow in closed conduits, drag on objects. 3 hours discussion, 3 hours laboratory. (001496)
CIVL 431	Water and Wastewater Engineering		4.0	SP
Prerequisites: CIVL 231 or faculty permission; junior standing. Introduction to water quality, water supply, distribution, and drinking water treatment; wastewater collection, treatment, and disposal. Disease transmission; water quality parameters; physical, chemical, and biological processes in the treatment of water, wastewater, and biosolids. 3 hours discussion, 3 hours laboratory. This course requires the use of a laptop computer and appropriate software. (001529)
EECE 316	Electronics II		4.0	SP
Prerequisites: EECE 311, EECE 315. Op Amp circuits, waveform generation and shaping, sinusoidal oscillators, high frequency amplifiers, active filters, power supply regulators, power electronics, advanced linear ICs. 3 hours discussion, 3 hours laboratory. (002534)
EECE 320	System Architecture and Performance		3.0	FS
Prerequisites: CSCI 217, EECE 144, or MATH 217; CSCI 221 or EECE 237. Study of computing architecture and how the structure of various hardware and software modules affects the ultimate performance of the total system. Topics include qualitative and quantitative analysis of bandwidths, response times, error detection and recovery, interrupts, and system throughput; distributed systems and coprocessors; vector and parallel architectures. 3 hours discussion. (002104)
EECE 343	Computer Architecture Performance and Implementation		4.0	FA
Prerequisites: EECE 144, EECE 237. Exploration of computer architecture fundamentals through analysis and implementation in a hardware description language. Coverage includes instruction set architecture, macro and micro architecture, the memory hierarchy, and performance techniques. Implementation and testing occurs through the introduction of modern digital design techniques using a hardware description language and commercial tools. 3 hours lecture, 2 hours activity. This course requires the use of a laptop computer and appropriate software. (002105)
EECE 365	Signals, Systems, and Transforms		4.0	FS
Prerequisites: EECE 211, MATH 260. Modeling and analysis of Signals and Systems both continuous and discrete, in the time and frequency domains. Topics include theorey and application of Fourier series, Fourier transforms, Parseval's Theorem and the Convolution, Laplace Transform Sampling Theorem, Z transform, discrete Fourier Transform and FFT. 4 hours discussion. (002528)
EECE 375	Fields and Waves		3.0	SP
Prerequisites: MATH 260, PHYS 204B. Transmission lines. Frequency-domain techniques. Fields and field operators. Electrostatic fields and capacitance. Magneto-static fields and inductance. Time-varying fields and Maxwell equations. Skin effect. Plane electromagnetic waves. Reflection and refraction. Waveguides and optical fibers. Radiation and antennas. 3 hours lecture. (002529)
EECE 437	Real-Time Embedded Systems		4.0	FA
Prerequisite: EECE 344. Recommended: EECE 320. This course presents the concepts and techniques associated with designing, developing, and testing real-time and embedded systems. Topics include the nature and uses of real-time systems, architecture and design of real-time systems, embedded development and debugging environments, embedded programming techniques, real-time operating systems and real-time scheduling and algorithms. Special attention is given to the study of real-time process scheduling and performance, including mathematical analysis of scheduling algorithms. 4 hours discussion. (002118)
EECE 450	Optics		3.0	SP
Prerequisites: PHYS 204A, PHYS 204B, PHYS 204C. This course is also offered as PHYS 450. Geometrical and physical optics, interference, diffraction, reflection, dispersion, resolution, polarization, fiber optics, laser optics, and holography. 2 hours discussion, 3 hours laboratory. (002549)
EECE 451	Lasers and Their Applications		3.0	FA
Prerequisites: PHYS 204C. Recommended: EECE 450 or PHYS 450. This course is also offered as PHYS 451. The theory and mechanism of laser action, various types of lasers and their applications and future use. Laboratory involves measurements with lasers, fiber optics, data transmission, and holography. 2 hours discussion, 3 hours laboratory. (002550)
EECE 481	Electromechanical Conversion		4.0	FA
Prerequisite: EECE 211. Principles of electromechanical conversion, traditional and renewable energy sources, magnetic circuits and steady state performance of synchronous, dc and induction motors, state space models and dynamic performance of electric motors, linearized models and common control schemes for various motors. 4 hours lecture. (020256)
EECE 483	Power Systems Operation		4.0	FA
Prerequisites: EECE 311 (may be taken concurrently). Power system structure, components and single line diagrams, per unit calculations, transmission line modeling, network matrices and Y-bus, load flow, economic power dispatch, basic relays and system protection schemes. 4 hours lecture. (020499)
EECE 484	Power System Distribution and Analysis		4.0	SP
Prerequisites: EECE 311 (may be taken concurrently). Power system symmetrical components, fault analysis, transient stability analysis, sequence impedances of transmission systems, and distribution networks. 4 hours lecture. (020500)
EECE 544	Embedded Systems Design		4.0	FA
Prerequisites: EECE 144, EECE 211. An accelerated discussion of embedded systems design, including C programming, HDI, design, embedded systems, hardware and software debugging, and system design and implementation. Coverage of advanced digital design topics including hardware/software co-design, embedded and soft-core processors, multiprocessor architectures, and concurrent/parallel programming. Not available for students with credit for EECE 344 or equivalent. 3 hours lecture, 2 hours activity. (021523)
EECE 682	Computer Control of Dynamic Systems		4.0	SP
Prerequisites: EECE 482 or MECA 482. Fundamental techniques for designing computer control sytems for Single Input Single Output (SISO) and Multiple Input Multiple Output (MIMO) dynamic systems, introduction to adaptive control and self tuning regulators. 4 hours lecture. (020259)
MECA 398	Special Topic		1.0 -3.0	INQ
Prerequisites: To be established when course is formulated. Special topic generally offered one time only. Different sections may have different topics. See the Class Schedule for the specific topic being offered. 3 hours lecture. (005653)
MECA 399	Special Problems		1.0 -3.0	INQ
Prerequisites: Approval of supervising faculty member. This course is an independent study of special problems offered for 1.0-3.0 units. See the department office for information on registering. 9 hours supervision. You may take this course more than once for a maximum of 6.0 units. Credit/no credit grading. (005654)
MECA 470	Introduction to Robotics Engineering		3.0	FS
Prerequisites: CSCI 111 or MECH 208; MECH 320 (may be taken concurrently). This course introduces students to robotic manipulation design and control. Students apply the concepts in computer simulation and a physical system. 2 hours lecture, 2 hours activity. (021920)
MECA 498	Special Topic		1.0 -3.0	INQ
Prerequisites: To be established when course is formulated. Special topic generally offered one time only. Different sections may have different topics. See the Class Schedule for the specific topic being offered. 3 hours lecture. (005660)
MECA 499	Special Problems		1.0 -3.0	INQ
Prerequisites: Approval of supervising faculty member. Independent study of a special problem. See the department office for registration procedure. 9 hours supervision. You may take this course more than once for a maximum of 6.0 units. Credit/no credit grading. (015851)
MECH 332	Thermodynamics		3.0	FS
Prerequisites: PHYS 204A. Properties of substances, ideal gas equation of state, heat and work, first and second laws of thermodynamics, steady-state analysis of closed and open systems, entropy, gas and vapor power cycles, introduction to renewable energy sources. 3 hours discussion. (005414)
MECH 389	Industrial Internship		1.0 -3.0	FS
Prerequisites: Approval of faculty internship coordinator prior to off-campus assignment. Engineering experience in an industrial setting. Minimum duration of 400 hours of work under the direct supervision of an on-site engineering supervisor. On completion of the internship, a written report prepared under the direction of a faculty member is required. This course is an elective for the BS in Mechanical Engineering, a total of 3 units must be completed to receive elective credit. 9 hours supervision. You may take this course more than once for a maximum of 3.0 units. Credit/no credit grading. (005454)
MECH 398	Special Topic		1.0 -3.0	INQ
Prerequisites: To be established when course is formulated. Special topic generally offered one time only. Different sections may have different topics. See the Class Schedule for specific topic being offered. 3 hours lecture. (005424)
MECH 399	Special Problems		1.0 -3.0	INQ
Prerequisites: Approval of supervising faculty member. This course is an independent study of special problems offered for 1.0-3.0 units. See the department office for information on registering. 9 hours supervision. You may take this course more than once for a maximum of 6.0 units. Credit/no credit grading. (005426)
MECH 410	Advanced Materials Science and Engineering		3.0	INQ
Prerequisites: MATH 260, MECH 210. Recommended: CIVL 311. Design, manufacture, and practical applications of advanced engineering materials. Failure analysis and prevention of material failure in mechanical design. Microfabrication of micromechanical devices. 3 hours discussion. (005428)
MECH 424	Mechanical Vibrations		3.0	INQ
Prerequisites: MECH 320. Free and forced vibrations of lumped parameter systems, transient vibrations, systems with several degrees-of-freedom. 3 hours discussion. (005437)
MECH 430	Nanoscale Science and Engineering		3.0	INQ
Prerequisites: CHEM 111, MECH 210, and PHYS 204B, or consent of the instructor. This course introduces students to the interdisciplinary field of nanoscale science and engineering including the areas of engineering, materials science, chemistry, and physics. The topics covered include advanced materials, synthesis and modification of nanomaterials, properties of nanomaterials, materials characterization, nanofabrication methods, and applications. It has three modules which are formal lectures, guest speakers, and projects. For the projects student learn to conduct a literature search on a given topic and are asked to present their project. They further have a chance to propose their own ideas for potential applications and are asked to give detailed methodology to execute the project. 3 hours discussion. You may take this course more than once for a maximum of 9.0 units. (021952)
MECH 498	Special Topic		1.0 -3.0	INQ
Prerequisites: To be established when course is formulated. Special topic generally offered one time only. Different sections may have different topics. See the Class Schedule for the specific topic being offered. 3 hours lecture. (005456)
MECH 499	Special Problems		1.0 -3.0	INQ
Prerequisites: Approval of supervising faculty member. This course is an independent study of special problems offered for 1.0-3.0 units. See the department office for information on registering. 3 hours supervision. You may take this course more than once for a maximum of 6.0 units. Credit/no credit grading. (005457)
SMFG 347	Sustainable Polymer Composites		3.0	SP
Prerequisite: MECH 210. This course provides students an introduction to composite materials and processing by investigating thermoplastic and thermoset composites, glass and carbon fiber reinforcements, biobased polymers and natural fibers, core materials, tooling, and thermoset processing equipment. 2 hours lecture, 3 hours laboratory. (021724)
SMFG 451	Quality Management		3.0	FS
Prerequisites: OSCM 306 or faculty permission; MATH 105 or MATH 108 for Business majors only. This course is also offered as OSCM 451. The study and application of the quality management process in both the manufacturing and service sectors of the economy. Topics include process analysis and improvement, statistical process control, cost of quality, quality measurement, and quality in the global marketplace. 3 hours lecture. (005784)
SMFG 458	Project Management		3.0	FA
Prerequisites: Senior standing. This course familiarizes students with techniques for managing technical projects while they design, plan, and implement a manufacturing project through the mock-up stage. Students work in groups on projects of mutual interest to gain experience in planning and updating schedules. Students learn to define requirements, estimate and manage resources, and structure decisions and trade-offs. Discussion includes global project management and supply chain responsibility. Emphasis is placed on group dynamics in communication and problem solving. 3 hours lecture. (005291)
SMFG 477	Semiconductor Manufacturing		3.0	SP
Prerequisite: MECH 210. This course introduces the manufacturing processes for various classes of semiconductor electronic devices. Materials presented focus on solar cells and logic/memory semiconductor devices. The primary process covered is photoresist lithography, however during the various manufacturing steps of these devices parallel processes are introduced including silicon ingot growth, ion implantation, chemical vapor deposition, atomic layer deposition, and molecular beam epitaxy. In addition to the various processes, students learn the fundamental performance barriers for each material/device type and perform defect analysis to assess how defects can be used to improve or degrade these materials. Finally, students study the financial aspects of these industries including the capital equipment costs associated with the manufacturing of these materials/devices, the financial history of these industries, return on investment, amortization, and case studies of both industry failures and successes. 3 hours lecture. (021768)

Advising Requirement:

Advising is mandatory for all majors in this degree program. Consult your undergraduate advisor for specific information.

Honors in the Major:

Honors in the Major is a program of independent work in your major. It requires 6 units of honors course work completed over two semesters.

The Honors in the Major program allows you to work closely with a faculty mentor in your area of interest on an original performance or research project. This year-long collaboration allows you to work in your field at a professional level and culminates in a public presentation of your work. Students sometimes take their projects beyond the University for submission in professional journals, presentation at conferences, or academic competition. Such experience is valuable for graduate school and professional life. Your honors work will be recognized at your graduation, on your permanent transcripts, and on your diploma. It is often accompanied by letters of commendation from your mentor in the department or the department chair.

Some common features of Honors in the Major program are:

• You must take 6 units of Honors in the Major course work. All 6 units are honors classes (marked by a suffix of H), and at least 3 of these units are independent study (399H, 499H, 599H) as specified by your department. You must complete each class with a minimum grade of B.
• You must have completed 9 units of upper-division course work or 21 overall units in your major before you can be admitted to Honors in the Major. Check the requirements for your major carefully, as there may be specific courses that must be included in these units.
• Your cumulative GPA should be at least 3.5 or within the top 5% of majors in your department.
• Your GPA in your major should be at least 3.5 or within the top 5% of majors in your department.
• Most students apply for or are invited to participate in Honors in the Major during the second semester of their junior year. Then they complete the 6 units of course work over the two semesters of their senior year.
• Your honors work culminates with a public presentation of your honors project.

While Honors in the Major is part of the Honors Program, each department administers its own program. Please contact your major department or major advisor to apply.